Index: head/sys/cddl/contrib/opensolaris/uts/common/dtrace/dtrace.c =================================================================== --- head/sys/cddl/contrib/opensolaris/uts/common/dtrace/dtrace.c (revision 179197) +++ head/sys/cddl/contrib/opensolaris/uts/common/dtrace/dtrace.c (revision 179198) @@ -1,15521 +1,16395 @@ /* * CDDL HEADER START * * The contents of this file are subject to the terms of the * Common Development and Distribution License (the "License"). * You may not use this file except in compliance with the License. * * You can obtain a copy of the license at usr/src/OPENSOLARIS.LICENSE * or http://www.opensolaris.org/os/licensing. * See the License for the specific language governing permissions * and limitations under the License. * * When distributing Covered Code, include this CDDL HEADER in each * file and include the License file at usr/src/OPENSOLARIS.LICENSE. * If applicable, add the following below this CDDL HEADER, with the * fields enclosed by brackets "[]" replaced with your own identifying * information: Portions Copyright [yyyy] [name of copyright owner] * * CDDL HEADER END */ /* * Copyright 2008 Sun Microsystems, Inc. All rights reserved. * Use is subject to license terms. */ #pragma ident "%Z%%M% %I% %E% SMI" /* * DTrace - Dynamic Tracing for Solaris * * This is the implementation of the Solaris Dynamic Tracing framework * (DTrace). The user-visible interface to DTrace is described at length in * the "Solaris Dynamic Tracing Guide". The interfaces between the libdtrace * library, the in-kernel DTrace framework, and the DTrace providers are * described in the block comments in the header file. The * internal architecture of DTrace is described in the block comments in the * header file. The comments contained within the DTrace * implementation very much assume mastery of all of these sources; if one has * an unanswered question about the implementation, one should consult them * first. * * The functions here are ordered roughly as follows: * * - Probe context functions * - Probe hashing functions * - Non-probe context utility functions * - Matching functions * - Provider-to-Framework API functions * - Probe management functions * - DIF object functions * - Format functions * - Predicate functions * - ECB functions * - Buffer functions * - Enabling functions * - DOF functions * - Anonymous enabling functions * - Consumer state functions * - Helper functions * - Hook functions * - Driver cookbook functions * * Each group of functions begins with a block comment labelled the "DTrace * [Group] Functions", allowing one to find each block by searching forward * on capital-f functions. */ #include +#if !defined(sun) +#include +#endif #include #include #include #include +#if defined(sun) #include #include +#endif #include #include +#if defined(sun) #include +#endif #include #include #include #include +#if defined(sun) #include #include +#endif #include +#if defined(sun) #include #include +#endif #include +#if defined(sun) #include #include +#endif #include +#if defined(sun) #include #include +#endif #include #include #include +/* FreeBSD includes: */ +#if !defined(sun) +#include +#include +#include +#include +#include +#include +#include +#include +#include +#include +#include +#include "dtrace_cddl.h" +#include "dtrace_debug.c" +#endif + /* * DTrace Tunable Variables * * The following variables may be tuned by adding a line to /etc/system that * includes both the name of the DTrace module ("dtrace") and the name of the * variable. For example: * * set dtrace:dtrace_destructive_disallow = 1 * * In general, the only variables that one should be tuning this way are those * that affect system-wide DTrace behavior, and for which the default behavior * is undesirable. Most of these variables are tunable on a per-consumer * basis using DTrace options, and need not be tuned on a system-wide basis. * When tuning these variables, avoid pathological values; while some attempt * is made to verify the integrity of these variables, they are not considered * part of the supported interface to DTrace, and they are therefore not * checked comprehensively. Further, these variables should not be tuned * dynamically via "mdb -kw" or other means; they should only be tuned via * /etc/system. */ int dtrace_destructive_disallow = 0; dtrace_optval_t dtrace_nonroot_maxsize = (16 * 1024 * 1024); size_t dtrace_difo_maxsize = (256 * 1024); dtrace_optval_t dtrace_dof_maxsize = (256 * 1024); size_t dtrace_global_maxsize = (16 * 1024); size_t dtrace_actions_max = (16 * 1024); size_t dtrace_retain_max = 1024; dtrace_optval_t dtrace_helper_actions_max = 32; dtrace_optval_t dtrace_helper_providers_max = 32; dtrace_optval_t dtrace_dstate_defsize = (1 * 1024 * 1024); size_t dtrace_strsize_default = 256; dtrace_optval_t dtrace_cleanrate_default = 9900990; /* 101 hz */ dtrace_optval_t dtrace_cleanrate_min = 200000; /* 5000 hz */ dtrace_optval_t dtrace_cleanrate_max = (uint64_t)60 * NANOSEC; /* 1/minute */ dtrace_optval_t dtrace_aggrate_default = NANOSEC; /* 1 hz */ dtrace_optval_t dtrace_statusrate_default = NANOSEC; /* 1 hz */ dtrace_optval_t dtrace_statusrate_max = (hrtime_t)10 * NANOSEC; /* 6/minute */ dtrace_optval_t dtrace_switchrate_default = NANOSEC; /* 1 hz */ dtrace_optval_t dtrace_nspec_default = 1; dtrace_optval_t dtrace_specsize_default = 32 * 1024; dtrace_optval_t dtrace_stackframes_default = 20; dtrace_optval_t dtrace_ustackframes_default = 20; dtrace_optval_t dtrace_jstackframes_default = 50; dtrace_optval_t dtrace_jstackstrsize_default = 512; int dtrace_msgdsize_max = 128; hrtime_t dtrace_chill_max = 500 * (NANOSEC / MILLISEC); /* 500 ms */ hrtime_t dtrace_chill_interval = NANOSEC; /* 1000 ms */ int dtrace_devdepth_max = 32; int dtrace_err_verbose; hrtime_t dtrace_deadman_interval = NANOSEC; hrtime_t dtrace_deadman_timeout = (hrtime_t)10 * NANOSEC; hrtime_t dtrace_deadman_user = (hrtime_t)30 * NANOSEC; /* * DTrace External Variables * * As dtrace(7D) is a kernel module, any DTrace variables are obviously * available to DTrace consumers via the backtick (`) syntax. One of these, * dtrace_zero, is made deliberately so: it is provided as a source of * well-known, zero-filled memory. While this variable is not documented, * it is used by some translators as an implementation detail. */ const char dtrace_zero[256] = { 0 }; /* zero-filled memory */ /* * DTrace Internal Variables */ +#if defined(sun) static dev_info_t *dtrace_devi; /* device info */ +#endif +#if defined(sun) static vmem_t *dtrace_arena; /* probe ID arena */ static vmem_t *dtrace_minor; /* minor number arena */ static taskq_t *dtrace_taskq; /* task queue */ +#else +static struct unrhdr *dtrace_arena; /* Probe ID number. */ +#endif static dtrace_probe_t **dtrace_probes; /* array of all probes */ static int dtrace_nprobes; /* number of probes */ static dtrace_provider_t *dtrace_provider; /* provider list */ static dtrace_meta_t *dtrace_meta_pid; /* user-land meta provider */ static int dtrace_opens; /* number of opens */ static int dtrace_helpers; /* number of helpers */ +#if defined(sun) static void *dtrace_softstate; /* softstate pointer */ +#endif static dtrace_hash_t *dtrace_bymod; /* probes hashed by module */ static dtrace_hash_t *dtrace_byfunc; /* probes hashed by function */ static dtrace_hash_t *dtrace_byname; /* probes hashed by name */ static dtrace_toxrange_t *dtrace_toxrange; /* toxic range array */ static int dtrace_toxranges; /* number of toxic ranges */ static int dtrace_toxranges_max; /* size of toxic range array */ static dtrace_anon_t dtrace_anon; /* anonymous enabling */ static kmem_cache_t *dtrace_state_cache; /* cache for dynamic state */ static uint64_t dtrace_vtime_references; /* number of vtimestamp refs */ static kthread_t *dtrace_panicked; /* panicking thread */ static dtrace_ecb_t *dtrace_ecb_create_cache; /* cached created ECB */ static dtrace_genid_t dtrace_probegen; /* current probe generation */ static dtrace_helpers_t *dtrace_deferred_pid; /* deferred helper list */ static dtrace_enabling_t *dtrace_retained; /* list of retained enablings */ static dtrace_dynvar_t dtrace_dynhash_sink; /* end of dynamic hash chains */ +#if !defined(sun) +static struct mtx dtrace_unr_mtx; +MTX_SYSINIT(dtrace_unr_mtx, &dtrace_unr_mtx, "Unique resource identifier", MTX_DEF); +int dtrace_in_probe; /* non-zero if executing a probe */ +#if defined(__i386__) || defined(__amd64__) +uintptr_t dtrace_in_probe_addr; /* Address of invop when already in probe */ +#endif +#endif /* * DTrace Locking * DTrace is protected by three (relatively coarse-grained) locks: * * (1) dtrace_lock is required to manipulate essentially any DTrace state, * including enabling state, probes, ECBs, consumer state, helper state, * etc. Importantly, dtrace_lock is _not_ required when in probe context; * probe context is lock-free -- synchronization is handled via the * dtrace_sync() cross call mechanism. * * (2) dtrace_provider_lock is required when manipulating provider state, or * when provider state must be held constant. * * (3) dtrace_meta_lock is required when manipulating meta provider state, or * when meta provider state must be held constant. * * The lock ordering between these three locks is dtrace_meta_lock before * dtrace_provider_lock before dtrace_lock. (In particular, there are * several places where dtrace_provider_lock is held by the framework as it * calls into the providers -- which then call back into the framework, * grabbing dtrace_lock.) * * There are two other locks in the mix: mod_lock and cpu_lock. With respect * to dtrace_provider_lock and dtrace_lock, cpu_lock continues its historical * role as a coarse-grained lock; it is acquired before both of these locks. * With respect to dtrace_meta_lock, its behavior is stranger: cpu_lock must * be acquired _between_ dtrace_meta_lock and any other DTrace locks. * mod_lock is similar with respect to dtrace_provider_lock in that it must be * acquired _between_ dtrace_provider_lock and dtrace_lock. */ static kmutex_t dtrace_lock; /* probe state lock */ static kmutex_t dtrace_provider_lock; /* provider state lock */ static kmutex_t dtrace_meta_lock; /* meta-provider state lock */ +#if !defined(sun) +/* XXX FreeBSD hacks. */ +static kmutex_t mod_lock; + +#define cr_suid cr_svuid +#define cr_sgid cr_svgid +#define ipaddr_t in_addr_t +#define mod_modname pathname +#define vuprintf vprintf +#define ttoproc(_a) ((_a)->td_proc) +#define crgetzoneid(_a) 0 +#define NCPU MAXCPU +#define SNOCD 0 +#define CPU_ON_INTR(_a) 0 + +#define PRIV_EFFECTIVE (1 << 0) +#define PRIV_DTRACE_KERNEL (1 << 1) +#define PRIV_DTRACE_PROC (1 << 2) +#define PRIV_DTRACE_USER (1 << 3) +#define PRIV_PROC_OWNER (1 << 4) +#define PRIV_PROC_ZONE (1 << 5) +#define PRIV_ALL ~0 + +SYSCTL_NODE(_debug, OID_AUTO, dtrace, CTLFLAG_RD, 0, "DTrace Information"); +#endif + +#if defined(sun) +#define curcpu CPU->cpu_id +#endif + + /* * DTrace Provider Variables * * These are the variables relating to DTrace as a provider (that is, the * provider of the BEGIN, END, and ERROR probes). */ static dtrace_pattr_t dtrace_provider_attr = { { DTRACE_STABILITY_STABLE, DTRACE_STABILITY_STABLE, DTRACE_CLASS_COMMON }, { DTRACE_STABILITY_PRIVATE, DTRACE_STABILITY_PRIVATE, DTRACE_CLASS_UNKNOWN }, { DTRACE_STABILITY_PRIVATE, DTRACE_STABILITY_PRIVATE, DTRACE_CLASS_UNKNOWN }, { DTRACE_STABILITY_STABLE, DTRACE_STABILITY_STABLE, DTRACE_CLASS_COMMON }, { DTRACE_STABILITY_STABLE, DTRACE_STABILITY_STABLE, DTRACE_CLASS_COMMON }, }; static void dtrace_nullop(void) {} static dtrace_pops_t dtrace_provider_ops = { - (void (*)(void *, const dtrace_probedesc_t *))dtrace_nullop, - (void (*)(void *, struct modctl *))dtrace_nullop, + (void (*)(void *, dtrace_probedesc_t *))dtrace_nullop, + (void (*)(void *, modctl_t *))dtrace_nullop, (void (*)(void *, dtrace_id_t, void *))dtrace_nullop, (void (*)(void *, dtrace_id_t, void *))dtrace_nullop, (void (*)(void *, dtrace_id_t, void *))dtrace_nullop, (void (*)(void *, dtrace_id_t, void *))dtrace_nullop, NULL, NULL, NULL, (void (*)(void *, dtrace_id_t, void *))dtrace_nullop }; static dtrace_id_t dtrace_probeid_begin; /* special BEGIN probe */ static dtrace_id_t dtrace_probeid_end; /* special END probe */ dtrace_id_t dtrace_probeid_error; /* special ERROR probe */ /* * DTrace Helper Tracing Variables */ uint32_t dtrace_helptrace_next = 0; uint32_t dtrace_helptrace_nlocals; char *dtrace_helptrace_buffer; int dtrace_helptrace_bufsize = 512 * 1024; #ifdef DEBUG int dtrace_helptrace_enabled = 1; #else int dtrace_helptrace_enabled = 0; #endif /* * DTrace Error Hashing * * On DEBUG kernels, DTrace will track the errors that has seen in a hash * table. This is very useful for checking coverage of tests that are * expected to induce DIF or DOF processing errors, and may be useful for * debugging problems in the DIF code generator or in DOF generation . The * error hash may be examined with the ::dtrace_errhash MDB dcmd. */ #ifdef DEBUG static dtrace_errhash_t dtrace_errhash[DTRACE_ERRHASHSZ]; static const char *dtrace_errlast; static kthread_t *dtrace_errthread; static kmutex_t dtrace_errlock; #endif /* * DTrace Macros and Constants * * These are various macros that are useful in various spots in the * implementation, along with a few random constants that have no meaning * outside of the implementation. There is no real structure to this cpp * mishmash -- but is there ever? */ #define DTRACE_HASHSTR(hash, probe) \ dtrace_hash_str(*((char **)((uintptr_t)(probe) + (hash)->dth_stroffs))) #define DTRACE_HASHNEXT(hash, probe) \ (dtrace_probe_t **)((uintptr_t)(probe) + (hash)->dth_nextoffs) #define DTRACE_HASHPREV(hash, probe) \ (dtrace_probe_t **)((uintptr_t)(probe) + (hash)->dth_prevoffs) #define DTRACE_HASHEQ(hash, lhs, rhs) \ (strcmp(*((char **)((uintptr_t)(lhs) + (hash)->dth_stroffs)), \ *((char **)((uintptr_t)(rhs) + (hash)->dth_stroffs))) == 0) #define DTRACE_AGGHASHSIZE_SLEW 17 #define DTRACE_V4MAPPED_OFFSET (sizeof (uint32_t) * 3) /* * The key for a thread-local variable consists of the lower 61 bits of the * t_did, plus the 3 bits of the highest active interrupt above LOCK_LEVEL. * We add DIF_VARIABLE_MAX to t_did to assure that the thread key is never * equal to a variable identifier. This is necessary (but not sufficient) to * assure that global associative arrays never collide with thread-local * variables. To guarantee that they cannot collide, we must also define the * order for keying dynamic variables. That order is: * * [ key0 ] ... [ keyn ] [ variable-key ] [ tls-key ] * * Because the variable-key and the tls-key are in orthogonal spaces, there is * no way for a global variable key signature to match a thread-local key * signature. */ +#if defined(sun) #define DTRACE_TLS_THRKEY(where) { \ uint_t intr = 0; \ uint_t actv = CPU->cpu_intr_actv >> (LOCK_LEVEL + 1); \ for (; actv; actv >>= 1) \ intr++; \ ASSERT(intr < (1 << 3)); \ (where) = ((curthread->t_did + DIF_VARIABLE_MAX) & \ (((uint64_t)1 << 61) - 1)) | ((uint64_t)intr << 61); \ } +#else +#define DTRACE_TLS_THRKEY(where) { \ + solaris_cpu_t *_c = &solaris_cpu[curcpu]; \ + uint_t intr = 0; \ + uint_t actv = _c->cpu_intr_actv; \ + for (; actv; actv >>= 1) \ + intr++; \ + ASSERT(intr < (1 << 3)); \ + (where) = ((curthread->td_tid + DIF_VARIABLE_MAX) & \ + (((uint64_t)1 << 61) - 1)) | ((uint64_t)intr << 61); \ +} +#endif #define DT_BSWAP_8(x) ((x) & 0xff) #define DT_BSWAP_16(x) ((DT_BSWAP_8(x) << 8) | DT_BSWAP_8((x) >> 8)) #define DT_BSWAP_32(x) ((DT_BSWAP_16(x) << 16) | DT_BSWAP_16((x) >> 16)) #define DT_BSWAP_64(x) ((DT_BSWAP_32(x) << 32) | DT_BSWAP_32((x) >> 32)) #define DT_MASK_LO 0x00000000FFFFFFFFULL #define DTRACE_STORE(type, tomax, offset, what) \ *((type *)((uintptr_t)(tomax) + (uintptr_t)offset)) = (type)(what); #ifndef __i386 #define DTRACE_ALIGNCHECK(addr, size, flags) \ if (addr & (size - 1)) { \ *flags |= CPU_DTRACE_BADALIGN; \ - cpu_core[CPU->cpu_id].cpuc_dtrace_illval = addr; \ + cpu_core[curcpu].cpuc_dtrace_illval = addr; \ return (0); \ } #else #define DTRACE_ALIGNCHECK(addr, size, flags) #endif /* * Test whether a range of memory starting at testaddr of size testsz falls * within the range of memory described by addr, sz. We take care to avoid * problems with overflow and underflow of the unsigned quantities, and * disallow all negative sizes. Ranges of size 0 are allowed. */ #define DTRACE_INRANGE(testaddr, testsz, baseaddr, basesz) \ ((testaddr) - (baseaddr) < (basesz) && \ (testaddr) + (testsz) - (baseaddr) <= (basesz) && \ (testaddr) + (testsz) >= (testaddr)) /* * Test whether alloc_sz bytes will fit in the scratch region. We isolate * alloc_sz on the righthand side of the comparison in order to avoid overflow * or underflow in the comparison with it. This is simpler than the INRANGE * check above, because we know that the dtms_scratch_ptr is valid in the * range. Allocations of size zero are allowed. */ #define DTRACE_INSCRATCH(mstate, alloc_sz) \ ((mstate)->dtms_scratch_base + (mstate)->dtms_scratch_size - \ (mstate)->dtms_scratch_ptr >= (alloc_sz)) #define DTRACE_LOADFUNC(bits) \ /*CSTYLED*/ \ uint##bits##_t \ dtrace_load##bits(uintptr_t addr) \ { \ size_t size = bits / NBBY; \ /*CSTYLED*/ \ uint##bits##_t rval; \ int i; \ volatile uint16_t *flags = (volatile uint16_t *) \ - &cpu_core[CPU->cpu_id].cpuc_dtrace_flags; \ + &cpu_core[curcpu].cpuc_dtrace_flags; \ \ DTRACE_ALIGNCHECK(addr, size, flags); \ \ for (i = 0; i < dtrace_toxranges; i++) { \ if (addr >= dtrace_toxrange[i].dtt_limit) \ continue; \ \ if (addr + size <= dtrace_toxrange[i].dtt_base) \ continue; \ \ /* \ * This address falls within a toxic region; return 0. \ */ \ *flags |= CPU_DTRACE_BADADDR; \ - cpu_core[CPU->cpu_id].cpuc_dtrace_illval = addr; \ + cpu_core[curcpu].cpuc_dtrace_illval = addr; \ return (0); \ } \ \ *flags |= CPU_DTRACE_NOFAULT; \ /*CSTYLED*/ \ rval = *((volatile uint##bits##_t *)addr); \ *flags &= ~CPU_DTRACE_NOFAULT; \ \ return (!(*flags & CPU_DTRACE_FAULT) ? rval : 0); \ } #ifdef _LP64 #define dtrace_loadptr dtrace_load64 #else #define dtrace_loadptr dtrace_load32 #endif #define DTRACE_DYNHASH_FREE 0 #define DTRACE_DYNHASH_SINK 1 #define DTRACE_DYNHASH_VALID 2 #define DTRACE_MATCH_NEXT 0 #define DTRACE_MATCH_DONE 1 #define DTRACE_ANCHORED(probe) ((probe)->dtpr_func[0] != '\0') #define DTRACE_STATE_ALIGN 64 #define DTRACE_FLAGS2FLT(flags) \ (((flags) & CPU_DTRACE_BADADDR) ? DTRACEFLT_BADADDR : \ ((flags) & CPU_DTRACE_ILLOP) ? DTRACEFLT_ILLOP : \ ((flags) & CPU_DTRACE_DIVZERO) ? DTRACEFLT_DIVZERO : \ ((flags) & CPU_DTRACE_KPRIV) ? DTRACEFLT_KPRIV : \ ((flags) & CPU_DTRACE_UPRIV) ? DTRACEFLT_UPRIV : \ ((flags) & CPU_DTRACE_TUPOFLOW) ? DTRACEFLT_TUPOFLOW : \ ((flags) & CPU_DTRACE_BADALIGN) ? DTRACEFLT_BADALIGN : \ ((flags) & CPU_DTRACE_NOSCRATCH) ? DTRACEFLT_NOSCRATCH : \ ((flags) & CPU_DTRACE_BADSTACK) ? DTRACEFLT_BADSTACK : \ DTRACEFLT_UNKNOWN) #define DTRACEACT_ISSTRING(act) \ ((act)->dta_kind == DTRACEACT_DIFEXPR && \ (act)->dta_difo->dtdo_rtype.dtdt_kind == DIF_TYPE_STRING) +/* Function prototype definitions: */ static size_t dtrace_strlen(const char *, size_t); static dtrace_probe_t *dtrace_probe_lookup_id(dtrace_id_t id); static void dtrace_enabling_provide(dtrace_provider_t *); static int dtrace_enabling_match(dtrace_enabling_t *, int *); static void dtrace_enabling_matchall(void); static dtrace_state_t *dtrace_anon_grab(void); +#if defined(sun) static uint64_t dtrace_helper(int, dtrace_mstate_t *, dtrace_state_t *, uint64_t, uint64_t); static dtrace_helpers_t *dtrace_helpers_create(proc_t *); +#endif static void dtrace_buffer_drop(dtrace_buffer_t *); static intptr_t dtrace_buffer_reserve(dtrace_buffer_t *, size_t, size_t, dtrace_state_t *, dtrace_mstate_t *); static int dtrace_state_option(dtrace_state_t *, dtrace_optid_t, dtrace_optval_t); static int dtrace_ecb_create_enable(dtrace_probe_t *, void *); +#if defined(sun) static void dtrace_helper_provider_destroy(dtrace_helper_provider_t *); +#endif +uint16_t dtrace_load16(uintptr_t); +uint32_t dtrace_load32(uintptr_t); +uint64_t dtrace_load64(uintptr_t); +uint8_t dtrace_load8(uintptr_t); +void dtrace_dynvar_clean(dtrace_dstate_t *); +dtrace_dynvar_t *dtrace_dynvar(dtrace_dstate_t *, uint_t, dtrace_key_t *, + size_t, dtrace_dynvar_op_t, dtrace_mstate_t *, dtrace_vstate_t *); +uintptr_t dtrace_dif_varstr(uintptr_t, dtrace_state_t *, dtrace_mstate_t *); /* * DTrace Probe Context Functions * * These functions are called from probe context. Because probe context is * any context in which C may be called, arbitrarily locks may be held, * interrupts may be disabled, we may be in arbitrary dispatched state, etc. * As a result, functions called from probe context may only call other DTrace * support functions -- they may not interact at all with the system at large. * (Note that the ASSERT macro is made probe-context safe by redefining it in * terms of dtrace_assfail(), a probe-context safe function.) If arbitrary * loads are to be performed from probe context, they _must_ be in terms of * the safe dtrace_load*() variants. * * Some functions in this block are not actually called from probe context; * for these functions, there will be a comment above the function reading * "Note: not called from probe context." */ void dtrace_panic(const char *format, ...) { va_list alist; va_start(alist, format); dtrace_vpanic(format, alist); va_end(alist); } int dtrace_assfail(const char *a, const char *f, int l) { dtrace_panic("assertion failed: %s, file: %s, line: %d", a, f, l); /* * We just need something here that even the most clever compiler * cannot optimize away. */ return (a[(uintptr_t)f]); } /* * Atomically increment a specified error counter from probe context. */ static void dtrace_error(uint32_t *counter) { /* * Most counters stored to in probe context are per-CPU counters. * However, there are some error conditions that are sufficiently * arcane that they don't merit per-CPU storage. If these counters * are incremented concurrently on different CPUs, scalability will be * adversely affected -- but we don't expect them to be white-hot in a * correctly constructed enabling... */ uint32_t oval, nval; do { oval = *counter; if ((nval = oval + 1) == 0) { /* * If the counter would wrap, set it to 1 -- assuring * that the counter is never zero when we have seen * errors. (The counter must be 32-bits because we * aren't guaranteed a 64-bit compare&swap operation.) * To save this code both the infamy of being fingered * by a priggish news story and the indignity of being * the target of a neo-puritan witch trial, we're * carefully avoiding any colorful description of the * likelihood of this condition -- but suffice it to * say that it is only slightly more likely than the * overflow of predicate cache IDs, as discussed in * dtrace_predicate_create(). */ nval = 1; } } while (dtrace_cas32(counter, oval, nval) != oval); } /* * Use the DTRACE_LOADFUNC macro to define functions for each of loading a * uint8_t, a uint16_t, a uint32_t and a uint64_t. */ DTRACE_LOADFUNC(8) DTRACE_LOADFUNC(16) DTRACE_LOADFUNC(32) DTRACE_LOADFUNC(64) static int dtrace_inscratch(uintptr_t dest, size_t size, dtrace_mstate_t *mstate) { if (dest < mstate->dtms_scratch_base) return (0); if (dest + size < dest) return (0); if (dest + size > mstate->dtms_scratch_ptr) return (0); return (1); } static int dtrace_canstore_statvar(uint64_t addr, size_t sz, dtrace_statvar_t **svars, int nsvars) { int i; for (i = 0; i < nsvars; i++) { dtrace_statvar_t *svar = svars[i]; if (svar == NULL || svar->dtsv_size == 0) continue; if (DTRACE_INRANGE(addr, sz, svar->dtsv_data, svar->dtsv_size)) return (1); } return (0); } /* * Check to see if the address is within a memory region to which a store may * be issued. This includes the DTrace scratch areas, and any DTrace variable * region. The caller of dtrace_canstore() is responsible for performing any * alignment checks that are needed before stores are actually executed. */ static int dtrace_canstore(uint64_t addr, size_t sz, dtrace_mstate_t *mstate, dtrace_vstate_t *vstate) { /* * First, check to see if the address is in scratch space... */ if (DTRACE_INRANGE(addr, sz, mstate->dtms_scratch_base, mstate->dtms_scratch_size)) return (1); /* * Now check to see if it's a dynamic variable. This check will pick * up both thread-local variables and any global dynamically-allocated * variables. */ if (DTRACE_INRANGE(addr, sz, (uintptr_t)vstate->dtvs_dynvars.dtds_base, vstate->dtvs_dynvars.dtds_size)) { dtrace_dstate_t *dstate = &vstate->dtvs_dynvars; uintptr_t base = (uintptr_t)dstate->dtds_base + (dstate->dtds_hashsize * sizeof (dtrace_dynhash_t)); uintptr_t chunkoffs; /* * Before we assume that we can store here, we need to make * sure that it isn't in our metadata -- storing to our * dynamic variable metadata would corrupt our state. For * the range to not include any dynamic variable metadata, * it must: * * (1) Start above the hash table that is at the base of * the dynamic variable space * * (2) Have a starting chunk offset that is beyond the * dtrace_dynvar_t that is at the base of every chunk * * (3) Not span a chunk boundary * */ if (addr < base) return (0); chunkoffs = (addr - base) % dstate->dtds_chunksize; if (chunkoffs < sizeof (dtrace_dynvar_t)) return (0); if (chunkoffs + sz > dstate->dtds_chunksize) return (0); return (1); } /* * Finally, check the static local and global variables. These checks * take the longest, so we perform them last. */ if (dtrace_canstore_statvar(addr, sz, vstate->dtvs_locals, vstate->dtvs_nlocals)) return (1); if (dtrace_canstore_statvar(addr, sz, vstate->dtvs_globals, vstate->dtvs_nglobals)) return (1); return (0); } /* * Convenience routine to check to see if the address is within a memory * region in which a load may be issued given the user's privilege level; * if not, it sets the appropriate error flags and loads 'addr' into the * illegal value slot. * * DTrace subroutines (DIF_SUBR_*) should use this helper to implement * appropriate memory access protection. */ static int dtrace_canload(uint64_t addr, size_t sz, dtrace_mstate_t *mstate, dtrace_vstate_t *vstate) { - volatile uintptr_t *illval = &cpu_core[CPU->cpu_id].cpuc_dtrace_illval; + volatile uintptr_t *illval = &cpu_core[curcpu].cpuc_dtrace_illval; /* * If we hold the privilege to read from kernel memory, then * everything is readable. */ if ((mstate->dtms_access & DTRACE_ACCESS_KERNEL) != 0) return (1); /* * You can obviously read that which you can store. */ if (dtrace_canstore(addr, sz, mstate, vstate)) return (1); /* * We're allowed to read from our own string table. */ if (DTRACE_INRANGE(addr, sz, (uintptr_t)mstate->dtms_difo->dtdo_strtab, mstate->dtms_difo->dtdo_strlen)) return (1); DTRACE_CPUFLAG_SET(CPU_DTRACE_KPRIV); *illval = addr; return (0); } /* * Convenience routine to check to see if a given string is within a memory * region in which a load may be issued given the user's privilege level; * this exists so that we don't need to issue unnecessary dtrace_strlen() * calls in the event that the user has all privileges. */ static int dtrace_strcanload(uint64_t addr, size_t sz, dtrace_mstate_t *mstate, dtrace_vstate_t *vstate) { size_t strsz; /* * If we hold the privilege to read from kernel memory, then * everything is readable. */ if ((mstate->dtms_access & DTRACE_ACCESS_KERNEL) != 0) return (1); strsz = 1 + dtrace_strlen((char *)(uintptr_t)addr, sz); if (dtrace_canload(addr, strsz, mstate, vstate)) return (1); return (0); } /* * Convenience routine to check to see if a given variable is within a memory * region in which a load may be issued given the user's privilege level. */ static int dtrace_vcanload(void *src, dtrace_diftype_t *type, dtrace_mstate_t *mstate, dtrace_vstate_t *vstate) { size_t sz; ASSERT(type->dtdt_flags & DIF_TF_BYREF); /* * If we hold the privilege to read from kernel memory, then * everything is readable. */ if ((mstate->dtms_access & DTRACE_ACCESS_KERNEL) != 0) return (1); if (type->dtdt_kind == DIF_TYPE_STRING) sz = dtrace_strlen(src, vstate->dtvs_state->dts_options[DTRACEOPT_STRSIZE]) + 1; else sz = type->dtdt_size; return (dtrace_canload((uintptr_t)src, sz, mstate, vstate)); } /* * Compare two strings using safe loads. */ static int dtrace_strncmp(char *s1, char *s2, size_t limit) { uint8_t c1, c2; volatile uint16_t *flags; if (s1 == s2 || limit == 0) return (0); - flags = (volatile uint16_t *)&cpu_core[CPU->cpu_id].cpuc_dtrace_flags; + flags = (volatile uint16_t *)&cpu_core[curcpu].cpuc_dtrace_flags; do { if (s1 == NULL) { c1 = '\0'; } else { c1 = dtrace_load8((uintptr_t)s1++); } if (s2 == NULL) { c2 = '\0'; } else { c2 = dtrace_load8((uintptr_t)s2++); } if (c1 != c2) return (c1 - c2); } while (--limit && c1 != '\0' && !(*flags & CPU_DTRACE_FAULT)); return (0); } /* * Compute strlen(s) for a string using safe memory accesses. The additional * len parameter is used to specify a maximum length to ensure completion. */ static size_t dtrace_strlen(const char *s, size_t lim) { uint_t len; for (len = 0; len != lim; len++) { if (dtrace_load8((uintptr_t)s++) == '\0') break; } return (len); } /* * Check if an address falls within a toxic region. */ static int dtrace_istoxic(uintptr_t kaddr, size_t size) { uintptr_t taddr, tsize; int i; for (i = 0; i < dtrace_toxranges; i++) { taddr = dtrace_toxrange[i].dtt_base; tsize = dtrace_toxrange[i].dtt_limit - taddr; if (kaddr - taddr < tsize) { DTRACE_CPUFLAG_SET(CPU_DTRACE_BADADDR); - cpu_core[CPU->cpu_id].cpuc_dtrace_illval = kaddr; + cpu_core[curcpu].cpuc_dtrace_illval = kaddr; return (1); } if (taddr - kaddr < size) { DTRACE_CPUFLAG_SET(CPU_DTRACE_BADADDR); - cpu_core[CPU->cpu_id].cpuc_dtrace_illval = taddr; + cpu_core[curcpu].cpuc_dtrace_illval = taddr; return (1); } } return (0); } /* * Copy src to dst using safe memory accesses. The src is assumed to be unsafe * memory specified by the DIF program. The dst is assumed to be safe memory * that we can store to directly because it is managed by DTrace. As with * standard bcopy, overlapping copies are handled properly. */ static void dtrace_bcopy(const void *src, void *dst, size_t len) { if (len != 0) { uint8_t *s1 = dst; const uint8_t *s2 = src; if (s1 <= s2) { do { *s1++ = dtrace_load8((uintptr_t)s2++); } while (--len != 0); } else { s2 += len; s1 += len; do { *--s1 = dtrace_load8((uintptr_t)--s2); } while (--len != 0); } } } /* * Copy src to dst using safe memory accesses, up to either the specified * length, or the point that a nul byte is encountered. The src is assumed to * be unsafe memory specified by the DIF program. The dst is assumed to be * safe memory that we can store to directly because it is managed by DTrace. * Unlike dtrace_bcopy(), overlapping regions are not handled. */ static void dtrace_strcpy(const void *src, void *dst, size_t len) { if (len != 0) { uint8_t *s1 = dst, c; const uint8_t *s2 = src; do { *s1++ = c = dtrace_load8((uintptr_t)s2++); } while (--len != 0 && c != '\0'); } } /* * Copy src to dst, deriving the size and type from the specified (BYREF) * variable type. The src is assumed to be unsafe memory specified by the DIF * program. The dst is assumed to be DTrace variable memory that is of the * specified type; we assume that we can store to directly. */ static void dtrace_vcopy(void *src, void *dst, dtrace_diftype_t *type) { ASSERT(type->dtdt_flags & DIF_TF_BYREF); if (type->dtdt_kind == DIF_TYPE_STRING) { dtrace_strcpy(src, dst, type->dtdt_size); } else { dtrace_bcopy(src, dst, type->dtdt_size); } } /* * Compare s1 to s2 using safe memory accesses. The s1 data is assumed to be * unsafe memory specified by the DIF program. The s2 data is assumed to be * safe memory that we can access directly because it is managed by DTrace. */ static int dtrace_bcmp(const void *s1, const void *s2, size_t len) { volatile uint16_t *flags; - flags = (volatile uint16_t *)&cpu_core[CPU->cpu_id].cpuc_dtrace_flags; + flags = (volatile uint16_t *)&cpu_core[curcpu].cpuc_dtrace_flags; if (s1 == s2) return (0); if (s1 == NULL || s2 == NULL) return (1); if (s1 != s2 && len != 0) { const uint8_t *ps1 = s1; const uint8_t *ps2 = s2; do { if (dtrace_load8((uintptr_t)ps1++) != *ps2++) return (1); } while (--len != 0 && !(*flags & CPU_DTRACE_FAULT)); } return (0); } /* * Zero the specified region using a simple byte-by-byte loop. Note that this * is for safe DTrace-managed memory only. */ static void dtrace_bzero(void *dst, size_t len) { uchar_t *cp; for (cp = dst; len != 0; len--) *cp++ = 0; } static void dtrace_add_128(uint64_t *addend1, uint64_t *addend2, uint64_t *sum) { uint64_t result[2]; result[0] = addend1[0] + addend2[0]; result[1] = addend1[1] + addend2[1] + (result[0] < addend1[0] || result[0] < addend2[0] ? 1 : 0); sum[0] = result[0]; sum[1] = result[1]; } /* * Shift the 128-bit value in a by b. If b is positive, shift left. * If b is negative, shift right. */ static void dtrace_shift_128(uint64_t *a, int b) { uint64_t mask; if (b == 0) return; if (b < 0) { b = -b; if (b >= 64) { a[0] = a[1] >> (b - 64); a[1] = 0; } else { a[0] >>= b; mask = 1LL << (64 - b); mask -= 1; a[0] |= ((a[1] & mask) << (64 - b)); a[1] >>= b; } } else { if (b >= 64) { a[1] = a[0] << (b - 64); a[0] = 0; } else { a[1] <<= b; mask = a[0] >> (64 - b); a[1] |= mask; a[0] <<= b; } } } /* * The basic idea is to break the 2 64-bit values into 4 32-bit values, * use native multiplication on those, and then re-combine into the * resulting 128-bit value. * * (hi1 << 32 + lo1) * (hi2 << 32 + lo2) = * hi1 * hi2 << 64 + * hi1 * lo2 << 32 + * hi2 * lo1 << 32 + * lo1 * lo2 */ static void dtrace_multiply_128(uint64_t factor1, uint64_t factor2, uint64_t *product) { uint64_t hi1, hi2, lo1, lo2; uint64_t tmp[2]; hi1 = factor1 >> 32; hi2 = factor2 >> 32; lo1 = factor1 & DT_MASK_LO; lo2 = factor2 & DT_MASK_LO; product[0] = lo1 * lo2; product[1] = hi1 * hi2; tmp[0] = hi1 * lo2; tmp[1] = 0; dtrace_shift_128(tmp, 32); dtrace_add_128(product, tmp, product); tmp[0] = hi2 * lo1; tmp[1] = 0; dtrace_shift_128(tmp, 32); dtrace_add_128(product, tmp, product); } /* * This privilege check should be used by actions and subroutines to * verify that the user credentials of the process that enabled the * invoking ECB match the target credentials */ static int dtrace_priv_proc_common_user(dtrace_state_t *state) { cred_t *cr, *s_cr = state->dts_cred.dcr_cred; /* * We should always have a non-NULL state cred here, since if cred * is null (anonymous tracing), we fast-path bypass this routine. */ ASSERT(s_cr != NULL); if ((cr = CRED()) != NULL && s_cr->cr_uid == cr->cr_uid && s_cr->cr_uid == cr->cr_ruid && s_cr->cr_uid == cr->cr_suid && s_cr->cr_gid == cr->cr_gid && s_cr->cr_gid == cr->cr_rgid && s_cr->cr_gid == cr->cr_sgid) return (1); return (0); } /* * This privilege check should be used by actions and subroutines to * verify that the zone of the process that enabled the invoking ECB * matches the target credentials */ static int dtrace_priv_proc_common_zone(dtrace_state_t *state) { +#if defined(sun) cred_t *cr, *s_cr = state->dts_cred.dcr_cred; /* * We should always have a non-NULL state cred here, since if cred * is null (anonymous tracing), we fast-path bypass this routine. */ ASSERT(s_cr != NULL); if ((cr = CRED()) != NULL && s_cr->cr_zone == cr->cr_zone) return (1); return (0); +#else + return (1); +#endif } /* * This privilege check should be used by actions and subroutines to * verify that the process has not setuid or changed credentials. */ static int -dtrace_priv_proc_common_nocd() +dtrace_priv_proc_common_nocd(void) { proc_t *proc; if ((proc = ttoproc(curthread)) != NULL && !(proc->p_flag & SNOCD)) return (1); return (0); } static int dtrace_priv_proc_destructive(dtrace_state_t *state) { int action = state->dts_cred.dcr_action; if (((action & DTRACE_CRA_PROC_DESTRUCTIVE_ALLZONE) == 0) && dtrace_priv_proc_common_zone(state) == 0) goto bad; if (((action & DTRACE_CRA_PROC_DESTRUCTIVE_ALLUSER) == 0) && dtrace_priv_proc_common_user(state) == 0) goto bad; if (((action & DTRACE_CRA_PROC_DESTRUCTIVE_CREDCHG) == 0) && dtrace_priv_proc_common_nocd() == 0) goto bad; return (1); bad: - cpu_core[CPU->cpu_id].cpuc_dtrace_flags |= CPU_DTRACE_UPRIV; + cpu_core[curcpu].cpuc_dtrace_flags |= CPU_DTRACE_UPRIV; return (0); } static int dtrace_priv_proc_control(dtrace_state_t *state) { if (state->dts_cred.dcr_action & DTRACE_CRA_PROC_CONTROL) return (1); if (dtrace_priv_proc_common_zone(state) && dtrace_priv_proc_common_user(state) && dtrace_priv_proc_common_nocd()) return (1); - cpu_core[CPU->cpu_id].cpuc_dtrace_flags |= CPU_DTRACE_UPRIV; + cpu_core[curcpu].cpuc_dtrace_flags |= CPU_DTRACE_UPRIV; return (0); } static int dtrace_priv_proc(dtrace_state_t *state) { if (state->dts_cred.dcr_action & DTRACE_CRA_PROC) return (1); - cpu_core[CPU->cpu_id].cpuc_dtrace_flags |= CPU_DTRACE_UPRIV; + cpu_core[curcpu].cpuc_dtrace_flags |= CPU_DTRACE_UPRIV; return (0); } static int dtrace_priv_kernel(dtrace_state_t *state) { if (state->dts_cred.dcr_action & DTRACE_CRA_KERNEL) return (1); - cpu_core[CPU->cpu_id].cpuc_dtrace_flags |= CPU_DTRACE_KPRIV; + cpu_core[curcpu].cpuc_dtrace_flags |= CPU_DTRACE_KPRIV; return (0); } static int dtrace_priv_kernel_destructive(dtrace_state_t *state) { if (state->dts_cred.dcr_action & DTRACE_CRA_KERNEL_DESTRUCTIVE) return (1); - cpu_core[CPU->cpu_id].cpuc_dtrace_flags |= CPU_DTRACE_KPRIV; + cpu_core[curcpu].cpuc_dtrace_flags |= CPU_DTRACE_KPRIV; return (0); } /* * Note: not called from probe context. This function is called * asynchronously (and at a regular interval) from outside of probe context to * clean the dirty dynamic variable lists on all CPUs. Dynamic variable * cleaning is explained in detail in . */ void dtrace_dynvar_clean(dtrace_dstate_t *dstate) { dtrace_dynvar_t *dirty; dtrace_dstate_percpu_t *dcpu; int i, work = 0; for (i = 0; i < NCPU; i++) { dcpu = &dstate->dtds_percpu[i]; ASSERT(dcpu->dtdsc_rinsing == NULL); /* * If the dirty list is NULL, there is no dirty work to do. */ if (dcpu->dtdsc_dirty == NULL) continue; /* * If the clean list is non-NULL, then we're not going to do * any work for this CPU -- it means that there has not been * a dtrace_dynvar() allocation on this CPU (or from this CPU) * since the last time we cleaned house. */ if (dcpu->dtdsc_clean != NULL) continue; work = 1; /* * Atomically move the dirty list aside. */ do { dirty = dcpu->dtdsc_dirty; /* * Before we zap the dirty list, set the rinsing list. * (This allows for a potential assertion in * dtrace_dynvar(): if a free dynamic variable appears * on a hash chain, either the dirty list or the * rinsing list for some CPU must be non-NULL.) */ dcpu->dtdsc_rinsing = dirty; dtrace_membar_producer(); } while (dtrace_casptr(&dcpu->dtdsc_dirty, dirty, NULL) != dirty); } if (!work) { /* * We have no work to do; we can simply return. */ return; } dtrace_sync(); for (i = 0; i < NCPU; i++) { dcpu = &dstate->dtds_percpu[i]; if (dcpu->dtdsc_rinsing == NULL) continue; /* * We are now guaranteed that no hash chain contains a pointer * into this dirty list; we can make it clean. */ ASSERT(dcpu->dtdsc_clean == NULL); dcpu->dtdsc_clean = dcpu->dtdsc_rinsing; dcpu->dtdsc_rinsing = NULL; } /* * Before we actually set the state to be DTRACE_DSTATE_CLEAN, make * sure that all CPUs have seen all of the dtdsc_clean pointers. * This prevents a race whereby a CPU incorrectly decides that * the state should be something other than DTRACE_DSTATE_CLEAN * after dtrace_dynvar_clean() has completed. */ dtrace_sync(); dstate->dtds_state = DTRACE_DSTATE_CLEAN; } /* * Depending on the value of the op parameter, this function looks-up, * allocates or deallocates an arbitrarily-keyed dynamic variable. If an * allocation is requested, this function will return a pointer to a * dtrace_dynvar_t corresponding to the allocated variable -- or NULL if no * variable can be allocated. If NULL is returned, the appropriate counter * will be incremented. */ dtrace_dynvar_t * dtrace_dynvar(dtrace_dstate_t *dstate, uint_t nkeys, dtrace_key_t *key, size_t dsize, dtrace_dynvar_op_t op, dtrace_mstate_t *mstate, dtrace_vstate_t *vstate) { uint64_t hashval = DTRACE_DYNHASH_VALID; dtrace_dynhash_t *hash = dstate->dtds_hash; dtrace_dynvar_t *free, *new_free, *next, *dvar, *start, *prev = NULL; - processorid_t me = CPU->cpu_id, cpu = me; + processorid_t me = curcpu, cpu = me; dtrace_dstate_percpu_t *dcpu = &dstate->dtds_percpu[me]; size_t bucket, ksize; size_t chunksize = dstate->dtds_chunksize; uintptr_t kdata, lock, nstate; uint_t i; ASSERT(nkeys != 0); /* * Hash the key. As with aggregations, we use Jenkins' "One-at-a-time" * algorithm. For the by-value portions, we perform the algorithm in * 16-bit chunks (as opposed to 8-bit chunks). This speeds things up a * bit, and seems to have only a minute effect on distribution. For * the by-reference data, we perform "One-at-a-time" iterating (safely) * over each referenced byte. It's painful to do this, but it's much * better than pathological hash distribution. The efficacy of the * hashing algorithm (and a comparison with other algorithms) may be * found by running the ::dtrace_dynstat MDB dcmd. */ for (i = 0; i < nkeys; i++) { if (key[i].dttk_size == 0) { uint64_t val = key[i].dttk_value; hashval += (val >> 48) & 0xffff; hashval += (hashval << 10); hashval ^= (hashval >> 6); hashval += (val >> 32) & 0xffff; hashval += (hashval << 10); hashval ^= (hashval >> 6); hashval += (val >> 16) & 0xffff; hashval += (hashval << 10); hashval ^= (hashval >> 6); hashval += val & 0xffff; hashval += (hashval << 10); hashval ^= (hashval >> 6); } else { /* * This is incredibly painful, but it beats the hell * out of the alternative. */ uint64_t j, size = key[i].dttk_size; uintptr_t base = (uintptr_t)key[i].dttk_value; if (!dtrace_canload(base, size, mstate, vstate)) break; for (j = 0; j < size; j++) { hashval += dtrace_load8(base + j); hashval += (hashval << 10); hashval ^= (hashval >> 6); } } } if (DTRACE_CPUFLAG_ISSET(CPU_DTRACE_FAULT)) return (NULL); hashval += (hashval << 3); hashval ^= (hashval >> 11); hashval += (hashval << 15); /* * There is a remote chance (ideally, 1 in 2^31) that our hashval * comes out to be one of our two sentinel hash values. If this * actually happens, we set the hashval to be a value known to be a * non-sentinel value. */ if (hashval == DTRACE_DYNHASH_FREE || hashval == DTRACE_DYNHASH_SINK) hashval = DTRACE_DYNHASH_VALID; /* * Yes, it's painful to do a divide here. If the cycle count becomes * important here, tricks can be pulled to reduce it. (However, it's * critical that hash collisions be kept to an absolute minimum; * they're much more painful than a divide.) It's better to have a * solution that generates few collisions and still keeps things * relatively simple. */ bucket = hashval % dstate->dtds_hashsize; if (op == DTRACE_DYNVAR_DEALLOC) { volatile uintptr_t *lockp = &hash[bucket].dtdh_lock; for (;;) { while ((lock = *lockp) & 1) continue; - if (dtrace_casptr((void *)lockp, - (void *)lock, (void *)(lock + 1)) == (void *)lock) + if (dtrace_casptr((volatile void *)lockp, + (volatile void *)lock, (volatile void *)(lock + 1)) == (void *)lock) break; } dtrace_membar_producer(); } top: prev = NULL; lock = hash[bucket].dtdh_lock; dtrace_membar_consumer(); start = hash[bucket].dtdh_chain; ASSERT(start != NULL && (start->dtdv_hashval == DTRACE_DYNHASH_SINK || start->dtdv_hashval != DTRACE_DYNHASH_FREE || op != DTRACE_DYNVAR_DEALLOC)); for (dvar = start; dvar != NULL; dvar = dvar->dtdv_next) { dtrace_tuple_t *dtuple = &dvar->dtdv_tuple; dtrace_key_t *dkey = &dtuple->dtt_key[0]; if (dvar->dtdv_hashval != hashval) { if (dvar->dtdv_hashval == DTRACE_DYNHASH_SINK) { /* * We've reached the sink, and therefore the * end of the hash chain; we can kick out of * the loop knowing that we have seen a valid * snapshot of state. */ ASSERT(dvar->dtdv_next == NULL); ASSERT(dvar == &dtrace_dynhash_sink); break; } if (dvar->dtdv_hashval == DTRACE_DYNHASH_FREE) { /* * We've gone off the rails: somewhere along * the line, one of the members of this hash * chain was deleted. Note that we could also * detect this by simply letting this loop run * to completion, as we would eventually hit * the end of the dirty list. However, we * want to avoid running the length of the * dirty list unnecessarily (it might be quite * long), so we catch this as early as * possible by detecting the hash marker. In * this case, we simply set dvar to NULL and * break; the conditional after the loop will * send us back to top. */ dvar = NULL; break; } goto next; } if (dtuple->dtt_nkeys != nkeys) goto next; for (i = 0; i < nkeys; i++, dkey++) { if (dkey->dttk_size != key[i].dttk_size) goto next; /* size or type mismatch */ if (dkey->dttk_size != 0) { if (dtrace_bcmp( (void *)(uintptr_t)key[i].dttk_value, (void *)(uintptr_t)dkey->dttk_value, dkey->dttk_size)) goto next; } else { if (dkey->dttk_value != key[i].dttk_value) goto next; } } if (op != DTRACE_DYNVAR_DEALLOC) return (dvar); ASSERT(dvar->dtdv_next == NULL || dvar->dtdv_next->dtdv_hashval != DTRACE_DYNHASH_FREE); if (prev != NULL) { ASSERT(hash[bucket].dtdh_chain != dvar); ASSERT(start != dvar); ASSERT(prev->dtdv_next == dvar); prev->dtdv_next = dvar->dtdv_next; } else { if (dtrace_casptr(&hash[bucket].dtdh_chain, start, dvar->dtdv_next) != start) { /* * We have failed to atomically swing the * hash table head pointer, presumably because * of a conflicting allocation on another CPU. * We need to reread the hash chain and try * again. */ goto top; } } dtrace_membar_producer(); /* * Now set the hash value to indicate that it's free. */ ASSERT(hash[bucket].dtdh_chain != dvar); dvar->dtdv_hashval = DTRACE_DYNHASH_FREE; dtrace_membar_producer(); /* * Set the next pointer to point at the dirty list, and * atomically swing the dirty pointer to the newly freed dvar. */ do { next = dcpu->dtdsc_dirty; dvar->dtdv_next = next; } while (dtrace_casptr(&dcpu->dtdsc_dirty, next, dvar) != next); /* * Finally, unlock this hash bucket. */ ASSERT(hash[bucket].dtdh_lock == lock); ASSERT(lock & 1); hash[bucket].dtdh_lock++; return (NULL); next: prev = dvar; continue; } if (dvar == NULL) { /* * If dvar is NULL, it is because we went off the rails: * one of the elements that we traversed in the hash chain * was deleted while we were traversing it. In this case, * we assert that we aren't doing a dealloc (deallocs lock * the hash bucket to prevent themselves from racing with * one another), and retry the hash chain traversal. */ ASSERT(op != DTRACE_DYNVAR_DEALLOC); goto top; } if (op != DTRACE_DYNVAR_ALLOC) { /* * If we are not to allocate a new variable, we want to * return NULL now. Before we return, check that the value * of the lock word hasn't changed. If it has, we may have * seen an inconsistent snapshot. */ if (op == DTRACE_DYNVAR_NOALLOC) { if (hash[bucket].dtdh_lock != lock) goto top; } else { ASSERT(op == DTRACE_DYNVAR_DEALLOC); ASSERT(hash[bucket].dtdh_lock == lock); ASSERT(lock & 1); hash[bucket].dtdh_lock++; } return (NULL); } /* * We need to allocate a new dynamic variable. The size we need is the * size of dtrace_dynvar plus the size of nkeys dtrace_key_t's plus the * size of any auxiliary key data (rounded up to 8-byte alignment) plus * the size of any referred-to data (dsize). We then round the final * size up to the chunksize for allocation. */ for (ksize = 0, i = 0; i < nkeys; i++) ksize += P2ROUNDUP(key[i].dttk_size, sizeof (uint64_t)); /* * This should be pretty much impossible, but could happen if, say, * strange DIF specified the tuple. Ideally, this should be an * assertion and not an error condition -- but that requires that the * chunksize calculation in dtrace_difo_chunksize() be absolutely * bullet-proof. (That is, it must not be able to be fooled by * malicious DIF.) Given the lack of backwards branches in DIF, * solving this would presumably not amount to solving the Halting * Problem -- but it still seems awfully hard. */ if (sizeof (dtrace_dynvar_t) + sizeof (dtrace_key_t) * (nkeys - 1) + ksize + dsize > chunksize) { dcpu->dtdsc_drops++; return (NULL); } nstate = DTRACE_DSTATE_EMPTY; do { retry: free = dcpu->dtdsc_free; if (free == NULL) { dtrace_dynvar_t *clean = dcpu->dtdsc_clean; void *rval; if (clean == NULL) { /* * We're out of dynamic variable space on * this CPU. Unless we have tried all CPUs, * we'll try to allocate from a different * CPU. */ switch (dstate->dtds_state) { case DTRACE_DSTATE_CLEAN: { void *sp = &dstate->dtds_state; if (++cpu >= NCPU) cpu = 0; if (dcpu->dtdsc_dirty != NULL && nstate == DTRACE_DSTATE_EMPTY) nstate = DTRACE_DSTATE_DIRTY; if (dcpu->dtdsc_rinsing != NULL) nstate = DTRACE_DSTATE_RINSING; dcpu = &dstate->dtds_percpu[cpu]; if (cpu != me) goto retry; (void) dtrace_cas32(sp, DTRACE_DSTATE_CLEAN, nstate); /* * To increment the correct bean * counter, take another lap. */ goto retry; } case DTRACE_DSTATE_DIRTY: dcpu->dtdsc_dirty_drops++; break; case DTRACE_DSTATE_RINSING: dcpu->dtdsc_rinsing_drops++; break; case DTRACE_DSTATE_EMPTY: dcpu->dtdsc_drops++; break; } DTRACE_CPUFLAG_SET(CPU_DTRACE_DROP); return (NULL); } /* * The clean list appears to be non-empty. We want to * move the clean list to the free list; we start by * moving the clean pointer aside. */ if (dtrace_casptr(&dcpu->dtdsc_clean, clean, NULL) != clean) { /* * We are in one of two situations: * * (a) The clean list was switched to the * free list by another CPU. * * (b) The clean list was added to by the * cleansing cyclic. * * In either of these situations, we can * just reattempt the free list allocation. */ goto retry; } ASSERT(clean->dtdv_hashval == DTRACE_DYNHASH_FREE); /* * Now we'll move the clean list to the free list. * It's impossible for this to fail: the only way * the free list can be updated is through this * code path, and only one CPU can own the clean list. * Thus, it would only be possible for this to fail if * this code were racing with dtrace_dynvar_clean(). * (That is, if dtrace_dynvar_clean() updated the clean * list, and we ended up racing to update the free * list.) This race is prevented by the dtrace_sync() * in dtrace_dynvar_clean() -- which flushes the * owners of the clean lists out before resetting * the clean lists. */ rval = dtrace_casptr(&dcpu->dtdsc_free, NULL, clean); ASSERT(rval == NULL); goto retry; } dvar = free; new_free = dvar->dtdv_next; } while (dtrace_casptr(&dcpu->dtdsc_free, free, new_free) != free); /* * We have now allocated a new chunk. We copy the tuple keys into the * tuple array and copy any referenced key data into the data space * following the tuple array. As we do this, we relocate dttk_value * in the final tuple to point to the key data address in the chunk. */ kdata = (uintptr_t)&dvar->dtdv_tuple.dtt_key[nkeys]; dvar->dtdv_data = (void *)(kdata + ksize); dvar->dtdv_tuple.dtt_nkeys = nkeys; for (i = 0; i < nkeys; i++) { dtrace_key_t *dkey = &dvar->dtdv_tuple.dtt_key[i]; size_t kesize = key[i].dttk_size; if (kesize != 0) { dtrace_bcopy( (const void *)(uintptr_t)key[i].dttk_value, (void *)kdata, kesize); dkey->dttk_value = kdata; kdata += P2ROUNDUP(kesize, sizeof (uint64_t)); } else { dkey->dttk_value = key[i].dttk_value; } dkey->dttk_size = kesize; } ASSERT(dvar->dtdv_hashval == DTRACE_DYNHASH_FREE); dvar->dtdv_hashval = hashval; dvar->dtdv_next = start; if (dtrace_casptr(&hash[bucket].dtdh_chain, start, dvar) == start) return (dvar); /* * The cas has failed. Either another CPU is adding an element to * this hash chain, or another CPU is deleting an element from this * hash chain. The simplest way to deal with both of these cases * (though not necessarily the most efficient) is to free our * allocated block and tail-call ourselves. Note that the free is * to the dirty list and _not_ to the free list. This is to prevent * races with allocators, above. */ dvar->dtdv_hashval = DTRACE_DYNHASH_FREE; dtrace_membar_producer(); do { free = dcpu->dtdsc_dirty; dvar->dtdv_next = free; } while (dtrace_casptr(&dcpu->dtdsc_dirty, free, dvar) != free); return (dtrace_dynvar(dstate, nkeys, key, dsize, op, mstate, vstate)); } /*ARGSUSED*/ static void dtrace_aggregate_min(uint64_t *oval, uint64_t nval, uint64_t arg) { if ((int64_t)nval < (int64_t)*oval) *oval = nval; } /*ARGSUSED*/ static void dtrace_aggregate_max(uint64_t *oval, uint64_t nval, uint64_t arg) { if ((int64_t)nval > (int64_t)*oval) *oval = nval; } static void dtrace_aggregate_quantize(uint64_t *quanta, uint64_t nval, uint64_t incr) { int i, zero = DTRACE_QUANTIZE_ZEROBUCKET; int64_t val = (int64_t)nval; if (val < 0) { for (i = 0; i < zero; i++) { if (val <= DTRACE_QUANTIZE_BUCKETVAL(i)) { quanta[i] += incr; return; } } } else { for (i = zero + 1; i < DTRACE_QUANTIZE_NBUCKETS; i++) { if (val < DTRACE_QUANTIZE_BUCKETVAL(i)) { quanta[i - 1] += incr; return; } } quanta[DTRACE_QUANTIZE_NBUCKETS - 1] += incr; return; } ASSERT(0); } static void dtrace_aggregate_lquantize(uint64_t *lquanta, uint64_t nval, uint64_t incr) { uint64_t arg = *lquanta++; int32_t base = DTRACE_LQUANTIZE_BASE(arg); uint16_t step = DTRACE_LQUANTIZE_STEP(arg); uint16_t levels = DTRACE_LQUANTIZE_LEVELS(arg); int32_t val = (int32_t)nval, level; ASSERT(step != 0); ASSERT(levels != 0); if (val < base) { /* * This is an underflow. */ lquanta[0] += incr; return; } level = (val - base) / step; if (level < levels) { lquanta[level + 1] += incr; return; } /* * This is an overflow. */ lquanta[levels + 1] += incr; } /*ARGSUSED*/ static void dtrace_aggregate_avg(uint64_t *data, uint64_t nval, uint64_t arg) { data[0]++; data[1] += nval; } /*ARGSUSED*/ static void dtrace_aggregate_stddev(uint64_t *data, uint64_t nval, uint64_t arg) { int64_t snval = (int64_t)nval; uint64_t tmp[2]; data[0]++; data[1] += nval; /* * What we want to say here is: * * data[2] += nval * nval; * * But given that nval is 64-bit, we could easily overflow, so * we do this as 128-bit arithmetic. */ if (snval < 0) snval = -snval; dtrace_multiply_128((uint64_t)snval, (uint64_t)snval, tmp); dtrace_add_128(data + 2, tmp, data + 2); } /*ARGSUSED*/ static void dtrace_aggregate_count(uint64_t *oval, uint64_t nval, uint64_t arg) { *oval = *oval + 1; } /*ARGSUSED*/ static void dtrace_aggregate_sum(uint64_t *oval, uint64_t nval, uint64_t arg) { *oval += nval; } /* * Aggregate given the tuple in the principal data buffer, and the aggregating * action denoted by the specified dtrace_aggregation_t. The aggregation * buffer is specified as the buf parameter. This routine does not return * failure; if there is no space in the aggregation buffer, the data will be * dropped, and a corresponding counter incremented. */ static void dtrace_aggregate(dtrace_aggregation_t *agg, dtrace_buffer_t *dbuf, intptr_t offset, dtrace_buffer_t *buf, uint64_t expr, uint64_t arg) { dtrace_recdesc_t *rec = &agg->dtag_action.dta_rec; uint32_t i, ndx, size, fsize; uint32_t align = sizeof (uint64_t) - 1; dtrace_aggbuffer_t *agb; dtrace_aggkey_t *key; uint32_t hashval = 0, limit, isstr; caddr_t tomax, data, kdata; dtrace_actkind_t action; dtrace_action_t *act; uintptr_t offs; if (buf == NULL) return; if (!agg->dtag_hasarg) { /* * Currently, only quantize() and lquantize() take additional * arguments, and they have the same semantics: an increment * value that defaults to 1 when not present. If additional * aggregating actions take arguments, the setting of the * default argument value will presumably have to become more * sophisticated... */ arg = 1; } action = agg->dtag_action.dta_kind - DTRACEACT_AGGREGATION; size = rec->dtrd_offset - agg->dtag_base; fsize = size + rec->dtrd_size; ASSERT(dbuf->dtb_tomax != NULL); data = dbuf->dtb_tomax + offset + agg->dtag_base; if ((tomax = buf->dtb_tomax) == NULL) { dtrace_buffer_drop(buf); return; } /* * The metastructure is always at the bottom of the buffer. */ agb = (dtrace_aggbuffer_t *)(tomax + buf->dtb_size - sizeof (dtrace_aggbuffer_t)); if (buf->dtb_offset == 0) { /* * We just kludge up approximately 1/8th of the size to be * buckets. If this guess ends up being routinely * off-the-mark, we may need to dynamically readjust this * based on past performance. */ uintptr_t hashsize = (buf->dtb_size >> 3) / sizeof (uintptr_t); if ((uintptr_t)agb - hashsize * sizeof (dtrace_aggkey_t *) < (uintptr_t)tomax || hashsize == 0) { /* * We've been given a ludicrously small buffer; * increment our drop count and leave. */ dtrace_buffer_drop(buf); return; } /* * And now, a pathetic attempt to try to get a an odd (or * perchance, a prime) hash size for better hash distribution. */ if (hashsize > (DTRACE_AGGHASHSIZE_SLEW << 3)) hashsize -= DTRACE_AGGHASHSIZE_SLEW; agb->dtagb_hashsize = hashsize; agb->dtagb_hash = (dtrace_aggkey_t **)((uintptr_t)agb - agb->dtagb_hashsize * sizeof (dtrace_aggkey_t *)); agb->dtagb_free = (uintptr_t)agb->dtagb_hash; for (i = 0; i < agb->dtagb_hashsize; i++) agb->dtagb_hash[i] = NULL; } ASSERT(agg->dtag_first != NULL); ASSERT(agg->dtag_first->dta_intuple); /* * Calculate the hash value based on the key. Note that we _don't_ * include the aggid in the hashing (but we will store it as part of * the key). The hashing algorithm is Bob Jenkins' "One-at-a-time" * algorithm: a simple, quick algorithm that has no known funnels, and * gets good distribution in practice. The efficacy of the hashing * algorithm (and a comparison with other algorithms) may be found by * running the ::dtrace_aggstat MDB dcmd. */ for (act = agg->dtag_first; act->dta_intuple; act = act->dta_next) { i = act->dta_rec.dtrd_offset - agg->dtag_base; limit = i + act->dta_rec.dtrd_size; ASSERT(limit <= size); isstr = DTRACEACT_ISSTRING(act); for (; i < limit; i++) { hashval += data[i]; hashval += (hashval << 10); hashval ^= (hashval >> 6); if (isstr && data[i] == '\0') break; } } hashval += (hashval << 3); hashval ^= (hashval >> 11); hashval += (hashval << 15); /* * Yes, the divide here is expensive -- but it's generally the least * of the performance issues given the amount of data that we iterate * over to compute hash values, compare data, etc. */ ndx = hashval % agb->dtagb_hashsize; for (key = agb->dtagb_hash[ndx]; key != NULL; key = key->dtak_next) { ASSERT((caddr_t)key >= tomax); ASSERT((caddr_t)key < tomax + buf->dtb_size); if (hashval != key->dtak_hashval || key->dtak_size != size) continue; kdata = key->dtak_data; ASSERT(kdata >= tomax && kdata < tomax + buf->dtb_size); for (act = agg->dtag_first; act->dta_intuple; act = act->dta_next) { i = act->dta_rec.dtrd_offset - agg->dtag_base; limit = i + act->dta_rec.dtrd_size; ASSERT(limit <= size); isstr = DTRACEACT_ISSTRING(act); for (; i < limit; i++) { if (kdata[i] != data[i]) goto next; if (isstr && data[i] == '\0') break; } } if (action != key->dtak_action) { /* * We are aggregating on the same value in the same * aggregation with two different aggregating actions. * (This should have been picked up in the compiler, * so we may be dealing with errant or devious DIF.) * This is an error condition; we indicate as much, * and return. */ DTRACE_CPUFLAG_SET(CPU_DTRACE_ILLOP); return; } /* * This is a hit: we need to apply the aggregator to * the value at this key. */ agg->dtag_aggregate((uint64_t *)(kdata + size), expr, arg); return; next: continue; } /* * We didn't find it. We need to allocate some zero-filled space, * link it into the hash table appropriately, and apply the aggregator * to the (zero-filled) value. */ offs = buf->dtb_offset; while (offs & (align - 1)) offs += sizeof (uint32_t); /* * If we don't have enough room to both allocate a new key _and_ * its associated data, increment the drop count and return. */ if ((uintptr_t)tomax + offs + fsize > agb->dtagb_free - sizeof (dtrace_aggkey_t)) { dtrace_buffer_drop(buf); return; } /*CONSTCOND*/ ASSERT(!(sizeof (dtrace_aggkey_t) & (sizeof (uintptr_t) - 1))); key = (dtrace_aggkey_t *)(agb->dtagb_free - sizeof (dtrace_aggkey_t)); agb->dtagb_free -= sizeof (dtrace_aggkey_t); key->dtak_data = kdata = tomax + offs; buf->dtb_offset = offs + fsize; /* * Now copy the data across. */ *((dtrace_aggid_t *)kdata) = agg->dtag_id; for (i = sizeof (dtrace_aggid_t); i < size; i++) kdata[i] = data[i]; /* * Because strings are not zeroed out by default, we need to iterate * looking for actions that store strings, and we need to explicitly * pad these strings out with zeroes. */ for (act = agg->dtag_first; act->dta_intuple; act = act->dta_next) { int nul; if (!DTRACEACT_ISSTRING(act)) continue; i = act->dta_rec.dtrd_offset - agg->dtag_base; limit = i + act->dta_rec.dtrd_size; ASSERT(limit <= size); for (nul = 0; i < limit; i++) { if (nul) { kdata[i] = '\0'; continue; } if (data[i] != '\0') continue; nul = 1; } } for (i = size; i < fsize; i++) kdata[i] = 0; key->dtak_hashval = hashval; key->dtak_size = size; key->dtak_action = action; key->dtak_next = agb->dtagb_hash[ndx]; agb->dtagb_hash[ndx] = key; /* * Finally, apply the aggregator. */ *((uint64_t *)(key->dtak_data + size)) = agg->dtag_initial; agg->dtag_aggregate((uint64_t *)(key->dtak_data + size), expr, arg); } /* * Given consumer state, this routine finds a speculation in the INACTIVE * state and transitions it into the ACTIVE state. If there is no speculation * in the INACTIVE state, 0 is returned. In this case, no error counter is * incremented -- it is up to the caller to take appropriate action. */ static int dtrace_speculation(dtrace_state_t *state) { int i = 0; dtrace_speculation_state_t current; uint32_t *stat = &state->dts_speculations_unavail, count; while (i < state->dts_nspeculations) { dtrace_speculation_t *spec = &state->dts_speculations[i]; current = spec->dtsp_state; if (current != DTRACESPEC_INACTIVE) { if (current == DTRACESPEC_COMMITTINGMANY || current == DTRACESPEC_COMMITTING || current == DTRACESPEC_DISCARDING) stat = &state->dts_speculations_busy; i++; continue; } if (dtrace_cas32((uint32_t *)&spec->dtsp_state, current, DTRACESPEC_ACTIVE) == current) return (i + 1); } /* * We couldn't find a speculation. If we found as much as a single * busy speculation buffer, we'll attribute this failure as "busy" * instead of "unavail". */ do { count = *stat; } while (dtrace_cas32(stat, count, count + 1) != count); return (0); } /* * This routine commits an active speculation. If the specified speculation * is not in a valid state to perform a commit(), this routine will silently do * nothing. The state of the specified speculation is transitioned according * to the state transition diagram outlined in */ static void dtrace_speculation_commit(dtrace_state_t *state, processorid_t cpu, dtrace_specid_t which) { dtrace_speculation_t *spec; dtrace_buffer_t *src, *dest; uintptr_t daddr, saddr, dlimit; - dtrace_speculation_state_t current, new; + dtrace_speculation_state_t current, new = 0; intptr_t offs; if (which == 0) return; if (which > state->dts_nspeculations) { cpu_core[cpu].cpuc_dtrace_flags |= CPU_DTRACE_ILLOP; return; } spec = &state->dts_speculations[which - 1]; src = &spec->dtsp_buffer[cpu]; dest = &state->dts_buffer[cpu]; do { current = spec->dtsp_state; if (current == DTRACESPEC_COMMITTINGMANY) break; switch (current) { case DTRACESPEC_INACTIVE: case DTRACESPEC_DISCARDING: return; case DTRACESPEC_COMMITTING: /* * This is only possible if we are (a) commit()'ing * without having done a prior speculate() on this CPU * and (b) racing with another commit() on a different * CPU. There's nothing to do -- we just assert that * our offset is 0. */ ASSERT(src->dtb_offset == 0); return; case DTRACESPEC_ACTIVE: new = DTRACESPEC_COMMITTING; break; case DTRACESPEC_ACTIVEONE: /* * This speculation is active on one CPU. If our * buffer offset is non-zero, we know that the one CPU * must be us. Otherwise, we are committing on a * different CPU from the speculate(), and we must * rely on being asynchronously cleaned. */ if (src->dtb_offset != 0) { new = DTRACESPEC_COMMITTING; break; } /*FALLTHROUGH*/ case DTRACESPEC_ACTIVEMANY: new = DTRACESPEC_COMMITTINGMANY; break; default: ASSERT(0); } } while (dtrace_cas32((uint32_t *)&spec->dtsp_state, current, new) != current); /* * We have set the state to indicate that we are committing this * speculation. Now reserve the necessary space in the destination * buffer. */ if ((offs = dtrace_buffer_reserve(dest, src->dtb_offset, sizeof (uint64_t), state, NULL)) < 0) { dtrace_buffer_drop(dest); goto out; } /* * We have the space; copy the buffer across. (Note that this is a * highly subobtimal bcopy(); in the unlikely event that this becomes * a serious performance issue, a high-performance DTrace-specific * bcopy() should obviously be invented.) */ daddr = (uintptr_t)dest->dtb_tomax + offs; dlimit = daddr + src->dtb_offset; saddr = (uintptr_t)src->dtb_tomax; /* * First, the aligned portion. */ while (dlimit - daddr >= sizeof (uint64_t)) { *((uint64_t *)daddr) = *((uint64_t *)saddr); daddr += sizeof (uint64_t); saddr += sizeof (uint64_t); } /* * Now any left-over bit... */ while (dlimit - daddr) *((uint8_t *)daddr++) = *((uint8_t *)saddr++); /* * Finally, commit the reserved space in the destination buffer. */ dest->dtb_offset = offs + src->dtb_offset; out: /* * If we're lucky enough to be the only active CPU on this speculation * buffer, we can just set the state back to DTRACESPEC_INACTIVE. */ if (current == DTRACESPEC_ACTIVE || (current == DTRACESPEC_ACTIVEONE && new == DTRACESPEC_COMMITTING)) { uint32_t rval = dtrace_cas32((uint32_t *)&spec->dtsp_state, DTRACESPEC_COMMITTING, DTRACESPEC_INACTIVE); ASSERT(rval == DTRACESPEC_COMMITTING); } src->dtb_offset = 0; src->dtb_xamot_drops += src->dtb_drops; src->dtb_drops = 0; } /* * This routine discards an active speculation. If the specified speculation * is not in a valid state to perform a discard(), this routine will silently * do nothing. The state of the specified speculation is transitioned * according to the state transition diagram outlined in */ static void dtrace_speculation_discard(dtrace_state_t *state, processorid_t cpu, dtrace_specid_t which) { dtrace_speculation_t *spec; - dtrace_speculation_state_t current, new; + dtrace_speculation_state_t current, new = 0; dtrace_buffer_t *buf; if (which == 0) return; if (which > state->dts_nspeculations) { cpu_core[cpu].cpuc_dtrace_flags |= CPU_DTRACE_ILLOP; return; } spec = &state->dts_speculations[which - 1]; buf = &spec->dtsp_buffer[cpu]; do { current = spec->dtsp_state; switch (current) { case DTRACESPEC_INACTIVE: case DTRACESPEC_COMMITTINGMANY: case DTRACESPEC_COMMITTING: case DTRACESPEC_DISCARDING: return; case DTRACESPEC_ACTIVE: case DTRACESPEC_ACTIVEMANY: new = DTRACESPEC_DISCARDING; break; case DTRACESPEC_ACTIVEONE: if (buf->dtb_offset != 0) { new = DTRACESPEC_INACTIVE; } else { new = DTRACESPEC_DISCARDING; } break; default: ASSERT(0); } } while (dtrace_cas32((uint32_t *)&spec->dtsp_state, current, new) != current); buf->dtb_offset = 0; buf->dtb_drops = 0; } /* * Note: not called from probe context. This function is called * asynchronously from cross call context to clean any speculations that are * in the COMMITTINGMANY or DISCARDING states. These speculations may not be * transitioned back to the INACTIVE state until all CPUs have cleaned the * speculation. */ static void dtrace_speculation_clean_here(dtrace_state_t *state) { dtrace_icookie_t cookie; - processorid_t cpu = CPU->cpu_id; + processorid_t cpu = curcpu; dtrace_buffer_t *dest = &state->dts_buffer[cpu]; dtrace_specid_t i; cookie = dtrace_interrupt_disable(); if (dest->dtb_tomax == NULL) { dtrace_interrupt_enable(cookie); return; } for (i = 0; i < state->dts_nspeculations; i++) { dtrace_speculation_t *spec = &state->dts_speculations[i]; dtrace_buffer_t *src = &spec->dtsp_buffer[cpu]; if (src->dtb_tomax == NULL) continue; if (spec->dtsp_state == DTRACESPEC_DISCARDING) { src->dtb_offset = 0; continue; } if (spec->dtsp_state != DTRACESPEC_COMMITTINGMANY) continue; if (src->dtb_offset == 0) continue; dtrace_speculation_commit(state, cpu, i + 1); } dtrace_interrupt_enable(cookie); } /* * Note: not called from probe context. This function is called * asynchronously (and at a regular interval) to clean any speculations that * are in the COMMITTINGMANY or DISCARDING states. If it discovers that there * is work to be done, it cross calls all CPUs to perform that work; * COMMITMANY and DISCARDING speculations may not be transitioned back to the * INACTIVE state until they have been cleaned by all CPUs. */ static void dtrace_speculation_clean(dtrace_state_t *state) { int work = 0, rv; dtrace_specid_t i; for (i = 0; i < state->dts_nspeculations; i++) { dtrace_speculation_t *spec = &state->dts_speculations[i]; ASSERT(!spec->dtsp_cleaning); if (spec->dtsp_state != DTRACESPEC_DISCARDING && spec->dtsp_state != DTRACESPEC_COMMITTINGMANY) continue; work++; spec->dtsp_cleaning = 1; } if (!work) return; dtrace_xcall(DTRACE_CPUALL, (dtrace_xcall_t)dtrace_speculation_clean_here, state); /* * We now know that all CPUs have committed or discarded their * speculation buffers, as appropriate. We can now set the state * to inactive. */ for (i = 0; i < state->dts_nspeculations; i++) { dtrace_speculation_t *spec = &state->dts_speculations[i]; dtrace_speculation_state_t current, new; if (!spec->dtsp_cleaning) continue; current = spec->dtsp_state; ASSERT(current == DTRACESPEC_DISCARDING || current == DTRACESPEC_COMMITTINGMANY); new = DTRACESPEC_INACTIVE; rv = dtrace_cas32((uint32_t *)&spec->dtsp_state, current, new); ASSERT(rv == current); spec->dtsp_cleaning = 0; } } /* * Called as part of a speculate() to get the speculative buffer associated * with a given speculation. Returns NULL if the specified speculation is not * in an ACTIVE state. If the speculation is in the ACTIVEONE state -- and * the active CPU is not the specified CPU -- the speculation will be * atomically transitioned into the ACTIVEMANY state. */ static dtrace_buffer_t * dtrace_speculation_buffer(dtrace_state_t *state, processorid_t cpuid, dtrace_specid_t which) { dtrace_speculation_t *spec; - dtrace_speculation_state_t current, new; + dtrace_speculation_state_t current, new = 0; dtrace_buffer_t *buf; if (which == 0) return (NULL); if (which > state->dts_nspeculations) { cpu_core[cpuid].cpuc_dtrace_flags |= CPU_DTRACE_ILLOP; return (NULL); } spec = &state->dts_speculations[which - 1]; buf = &spec->dtsp_buffer[cpuid]; do { current = spec->dtsp_state; switch (current) { case DTRACESPEC_INACTIVE: case DTRACESPEC_COMMITTINGMANY: case DTRACESPEC_DISCARDING: return (NULL); case DTRACESPEC_COMMITTING: ASSERT(buf->dtb_offset == 0); return (NULL); case DTRACESPEC_ACTIVEONE: /* * This speculation is currently active on one CPU. * Check the offset in the buffer; if it's non-zero, * that CPU must be us (and we leave the state alone). * If it's zero, assume that we're starting on a new * CPU -- and change the state to indicate that the * speculation is active on more than one CPU. */ if (buf->dtb_offset != 0) return (buf); new = DTRACESPEC_ACTIVEMANY; break; case DTRACESPEC_ACTIVEMANY: return (buf); case DTRACESPEC_ACTIVE: new = DTRACESPEC_ACTIVEONE; break; default: ASSERT(0); } } while (dtrace_cas32((uint32_t *)&spec->dtsp_state, current, new) != current); ASSERT(new == DTRACESPEC_ACTIVEONE || new == DTRACESPEC_ACTIVEMANY); return (buf); } /* * Return a string. In the event that the user lacks the privilege to access * arbitrary kernel memory, we copy the string out to scratch memory so that we * don't fail access checking. * * dtrace_dif_variable() uses this routine as a helper for various * builtin values such as 'execname' and 'probefunc.' */ uintptr_t dtrace_dif_varstr(uintptr_t addr, dtrace_state_t *state, dtrace_mstate_t *mstate) { uint64_t size = state->dts_options[DTRACEOPT_STRSIZE]; uintptr_t ret; size_t strsz; /* * The easy case: this probe is allowed to read all of memory, so * we can just return this as a vanilla pointer. */ if ((mstate->dtms_access & DTRACE_ACCESS_KERNEL) != 0) return (addr); /* * This is the tougher case: we copy the string in question from * kernel memory into scratch memory and return it that way: this * ensures that we won't trip up when access checking tests the * BYREF return value. */ strsz = dtrace_strlen((char *)addr, size) + 1; if (mstate->dtms_scratch_ptr + strsz > mstate->dtms_scratch_base + mstate->dtms_scratch_size) { DTRACE_CPUFLAG_SET(CPU_DTRACE_NOSCRATCH); - return (NULL); + return (0); } dtrace_strcpy((const void *)addr, (void *)mstate->dtms_scratch_ptr, strsz); ret = mstate->dtms_scratch_ptr; mstate->dtms_scratch_ptr += strsz; return (ret); } /* + * Return a string from a memoy address which is known to have one or + * more concatenated, individually zero terminated, sub-strings. + * In the event that the user lacks the privilege to access + * arbitrary kernel memory, we copy the string out to scratch memory so that we + * don't fail access checking. + * + * dtrace_dif_variable() uses this routine as a helper for various + * builtin values such as 'execargs'. + */ +static uintptr_t +dtrace_dif_varstrz(uintptr_t addr, size_t strsz, dtrace_state_t *state, + dtrace_mstate_t *mstate) +{ + char *p; + size_t i; + uintptr_t ret; + + if (mstate->dtms_scratch_ptr + strsz > + mstate->dtms_scratch_base + mstate->dtms_scratch_size) { + DTRACE_CPUFLAG_SET(CPU_DTRACE_NOSCRATCH); + return (0); + } + + dtrace_bcopy((const void *)addr, (void *)mstate->dtms_scratch_ptr, + strsz); + + /* Replace sub-string termination characters with a space. */ + for (p = (char *) mstate->dtms_scratch_ptr, i = 0; i < strsz - 1; + p++, i++) + if (*p == '\0') + *p = ' '; + + ret = mstate->dtms_scratch_ptr; + mstate->dtms_scratch_ptr += strsz; + return (ret); +} + +/* * This function implements the DIF emulator's variable lookups. The emulator * passes a reserved variable identifier and optional built-in array index. */ static uint64_t dtrace_dif_variable(dtrace_mstate_t *mstate, dtrace_state_t *state, uint64_t v, uint64_t ndx) { /* * If we're accessing one of the uncached arguments, we'll turn this * into a reference in the args array. */ if (v >= DIF_VAR_ARG0 && v <= DIF_VAR_ARG9) { ndx = v - DIF_VAR_ARG0; v = DIF_VAR_ARGS; } switch (v) { case DIF_VAR_ARGS: ASSERT(mstate->dtms_present & DTRACE_MSTATE_ARGS); if (ndx >= sizeof (mstate->dtms_arg) / sizeof (mstate->dtms_arg[0])) { int aframes = mstate->dtms_probe->dtpr_aframes + 2; dtrace_provider_t *pv; uint64_t val; pv = mstate->dtms_probe->dtpr_provider; if (pv->dtpv_pops.dtps_getargval != NULL) val = pv->dtpv_pops.dtps_getargval(pv->dtpv_arg, mstate->dtms_probe->dtpr_id, mstate->dtms_probe->dtpr_arg, ndx, aframes); else val = dtrace_getarg(ndx, aframes); /* * This is regrettably required to keep the compiler * from tail-optimizing the call to dtrace_getarg(). * The condition always evaluates to true, but the * compiler has no way of figuring that out a priori. * (None of this would be necessary if the compiler * could be relied upon to _always_ tail-optimize * the call to dtrace_getarg() -- but it can't.) */ if (mstate->dtms_probe != NULL) return (val); ASSERT(0); } return (mstate->dtms_arg[ndx]); +#if defined(sun) case DIF_VAR_UREGS: { klwp_t *lwp; if (!dtrace_priv_proc(state)) return (0); if ((lwp = curthread->t_lwp) == NULL) { DTRACE_CPUFLAG_SET(CPU_DTRACE_BADADDR); - cpu_core[CPU->cpu_id].cpuc_dtrace_illval = NULL; + cpu_core[curcpu].cpuc_dtrace_illval = NULL; return (0); } return (dtrace_getreg(lwp->lwp_regs, ndx)); + return (0); } +#endif case DIF_VAR_CURTHREAD: if (!dtrace_priv_kernel(state)) return (0); return ((uint64_t)(uintptr_t)curthread); case DIF_VAR_TIMESTAMP: if (!(mstate->dtms_present & DTRACE_MSTATE_TIMESTAMP)) { mstate->dtms_timestamp = dtrace_gethrtime(); mstate->dtms_present |= DTRACE_MSTATE_TIMESTAMP; } return (mstate->dtms_timestamp); case DIF_VAR_VTIMESTAMP: ASSERT(dtrace_vtime_references != 0); return (curthread->t_dtrace_vtime); case DIF_VAR_WALLTIMESTAMP: if (!(mstate->dtms_present & DTRACE_MSTATE_WALLTIMESTAMP)) { mstate->dtms_walltimestamp = dtrace_gethrestime(); mstate->dtms_present |= DTRACE_MSTATE_WALLTIMESTAMP; } return (mstate->dtms_walltimestamp); +#if defined(sun) case DIF_VAR_IPL: if (!dtrace_priv_kernel(state)) return (0); if (!(mstate->dtms_present & DTRACE_MSTATE_IPL)) { mstate->dtms_ipl = dtrace_getipl(); mstate->dtms_present |= DTRACE_MSTATE_IPL; } return (mstate->dtms_ipl); +#endif case DIF_VAR_EPID: ASSERT(mstate->dtms_present & DTRACE_MSTATE_EPID); return (mstate->dtms_epid); case DIF_VAR_ID: ASSERT(mstate->dtms_present & DTRACE_MSTATE_PROBE); return (mstate->dtms_probe->dtpr_id); case DIF_VAR_STACKDEPTH: if (!dtrace_priv_kernel(state)) return (0); if (!(mstate->dtms_present & DTRACE_MSTATE_STACKDEPTH)) { int aframes = mstate->dtms_probe->dtpr_aframes + 2; mstate->dtms_stackdepth = dtrace_getstackdepth(aframes); mstate->dtms_present |= DTRACE_MSTATE_STACKDEPTH; } return (mstate->dtms_stackdepth); +#if defined(sun) case DIF_VAR_USTACKDEPTH: if (!dtrace_priv_proc(state)) return (0); if (!(mstate->dtms_present & DTRACE_MSTATE_USTACKDEPTH)) { /* * See comment in DIF_VAR_PID. */ if (DTRACE_ANCHORED(mstate->dtms_probe) && CPU_ON_INTR(CPU)) { mstate->dtms_ustackdepth = 0; } else { DTRACE_CPUFLAG_SET(CPU_DTRACE_NOFAULT); mstate->dtms_ustackdepth = dtrace_getustackdepth(); DTRACE_CPUFLAG_CLEAR(CPU_DTRACE_NOFAULT); } mstate->dtms_present |= DTRACE_MSTATE_USTACKDEPTH; } return (mstate->dtms_ustackdepth); +#endif case DIF_VAR_CALLER: if (!dtrace_priv_kernel(state)) return (0); if (!(mstate->dtms_present & DTRACE_MSTATE_CALLER)) { int aframes = mstate->dtms_probe->dtpr_aframes + 2; if (!DTRACE_ANCHORED(mstate->dtms_probe)) { /* * If this is an unanchored probe, we are * required to go through the slow path: * dtrace_caller() only guarantees correct * results for anchored probes. */ - pc_t caller[2]; + pc_t caller[2] = {0, 0}; dtrace_getpcstack(caller, 2, aframes, (uint32_t *)(uintptr_t)mstate->dtms_arg[0]); mstate->dtms_caller = caller[1]; } else if ((mstate->dtms_caller = dtrace_caller(aframes)) == -1) { /* * We have failed to do this the quick way; * we must resort to the slower approach of * calling dtrace_getpcstack(). */ - pc_t caller; + pc_t caller = 0; dtrace_getpcstack(&caller, 1, aframes, NULL); mstate->dtms_caller = caller; } mstate->dtms_present |= DTRACE_MSTATE_CALLER; } return (mstate->dtms_caller); +#if defined(sun) case DIF_VAR_UCALLER: if (!dtrace_priv_proc(state)) return (0); if (!(mstate->dtms_present & DTRACE_MSTATE_UCALLER)) { uint64_t ustack[3]; /* * dtrace_getupcstack() fills in the first uint64_t * with the current PID. The second uint64_t will * be the program counter at user-level. The third * uint64_t will contain the caller, which is what * we're after. */ - ustack[2] = NULL; + ustack[2] = 0; DTRACE_CPUFLAG_SET(CPU_DTRACE_NOFAULT); dtrace_getupcstack(ustack, 3); DTRACE_CPUFLAG_CLEAR(CPU_DTRACE_NOFAULT); mstate->dtms_ucaller = ustack[2]; mstate->dtms_present |= DTRACE_MSTATE_UCALLER; } return (mstate->dtms_ucaller); +#endif case DIF_VAR_PROBEPROV: ASSERT(mstate->dtms_present & DTRACE_MSTATE_PROBE); return (dtrace_dif_varstr( (uintptr_t)mstate->dtms_probe->dtpr_provider->dtpv_name, state, mstate)); case DIF_VAR_PROBEMOD: ASSERT(mstate->dtms_present & DTRACE_MSTATE_PROBE); return (dtrace_dif_varstr( (uintptr_t)mstate->dtms_probe->dtpr_mod, state, mstate)); case DIF_VAR_PROBEFUNC: ASSERT(mstate->dtms_present & DTRACE_MSTATE_PROBE); return (dtrace_dif_varstr( (uintptr_t)mstate->dtms_probe->dtpr_func, state, mstate)); case DIF_VAR_PROBENAME: ASSERT(mstate->dtms_present & DTRACE_MSTATE_PROBE); return (dtrace_dif_varstr( (uintptr_t)mstate->dtms_probe->dtpr_name, state, mstate)); case DIF_VAR_PID: if (!dtrace_priv_proc(state)) return (0); +#if defined(sun) /* * Note that we are assuming that an unanchored probe is * always due to a high-level interrupt. (And we're assuming * that there is only a single high level interrupt.) */ if (DTRACE_ANCHORED(mstate->dtms_probe) && CPU_ON_INTR(CPU)) return (pid0.pid_id); /* * It is always safe to dereference one's own t_procp pointer: * it always points to a valid, allocated proc structure. * Further, it is always safe to dereference the p_pidp member * of one's own proc structure. (These are truisms becuase * threads and processes don't clean up their own state -- * they leave that task to whomever reaps them.) */ return ((uint64_t)curthread->t_procp->p_pidp->pid_id); +#else + return ((uint64_t)curproc->p_pid); +#endif case DIF_VAR_PPID: if (!dtrace_priv_proc(state)) return (0); +#if defined(sun) /* * See comment in DIF_VAR_PID. */ if (DTRACE_ANCHORED(mstate->dtms_probe) && CPU_ON_INTR(CPU)) return (pid0.pid_id); /* * It is always safe to dereference one's own t_procp pointer: * it always points to a valid, allocated proc structure. * (This is true because threads don't clean up their own * state -- they leave that task to whomever reaps them.) */ return ((uint64_t)curthread->t_procp->p_ppid); +#else + return ((uint64_t)curproc->p_pptr->p_pid); +#endif case DIF_VAR_TID: +#if defined(sun) /* * See comment in DIF_VAR_PID. */ if (DTRACE_ANCHORED(mstate->dtms_probe) && CPU_ON_INTR(CPU)) return (0); +#endif return ((uint64_t)curthread->t_tid); + case DIF_VAR_EXECARGS: { + struct pargs *p_args = curthread->td_proc->p_args; + + return (dtrace_dif_varstrz( + (uintptr_t) p_args->ar_args, p_args->ar_length, state, mstate)); + } + case DIF_VAR_EXECNAME: +#if defined(sun) if (!dtrace_priv_proc(state)) return (0); /* * See comment in DIF_VAR_PID. */ if (DTRACE_ANCHORED(mstate->dtms_probe) && CPU_ON_INTR(CPU)) return ((uint64_t)(uintptr_t)p0.p_user.u_comm); /* * It is always safe to dereference one's own t_procp pointer: * it always points to a valid, allocated proc structure. * (This is true because threads don't clean up their own * state -- they leave that task to whomever reaps them.) */ return (dtrace_dif_varstr( (uintptr_t)curthread->t_procp->p_user.u_comm, state, mstate)); +#else + return (dtrace_dif_varstr( + (uintptr_t) curthread->td_proc->p_comm, state, mstate)); +#endif case DIF_VAR_ZONENAME: +#if defined(sun) if (!dtrace_priv_proc(state)) return (0); /* * See comment in DIF_VAR_PID. */ if (DTRACE_ANCHORED(mstate->dtms_probe) && CPU_ON_INTR(CPU)) return ((uint64_t)(uintptr_t)p0.p_zone->zone_name); /* * It is always safe to dereference one's own t_procp pointer: * it always points to a valid, allocated proc structure. * (This is true because threads don't clean up their own * state -- they leave that task to whomever reaps them.) */ return (dtrace_dif_varstr( (uintptr_t)curthread->t_procp->p_zone->zone_name, state, mstate)); +#else + return (0); +#endif case DIF_VAR_UID: if (!dtrace_priv_proc(state)) return (0); +#if defined(sun) /* * See comment in DIF_VAR_PID. */ if (DTRACE_ANCHORED(mstate->dtms_probe) && CPU_ON_INTR(CPU)) return ((uint64_t)p0.p_cred->cr_uid); +#endif /* * It is always safe to dereference one's own t_procp pointer: * it always points to a valid, allocated proc structure. * (This is true because threads don't clean up their own * state -- they leave that task to whomever reaps them.) * * Additionally, it is safe to dereference one's own process * credential, since this is never NULL after process birth. */ return ((uint64_t)curthread->t_procp->p_cred->cr_uid); case DIF_VAR_GID: if (!dtrace_priv_proc(state)) return (0); +#if defined(sun) /* * See comment in DIF_VAR_PID. */ if (DTRACE_ANCHORED(mstate->dtms_probe) && CPU_ON_INTR(CPU)) return ((uint64_t)p0.p_cred->cr_gid); +#endif /* * It is always safe to dereference one's own t_procp pointer: * it always points to a valid, allocated proc structure. * (This is true because threads don't clean up their own * state -- they leave that task to whomever reaps them.) * * Additionally, it is safe to dereference one's own process * credential, since this is never NULL after process birth. */ return ((uint64_t)curthread->t_procp->p_cred->cr_gid); case DIF_VAR_ERRNO: { +#if defined(sun) klwp_t *lwp; if (!dtrace_priv_proc(state)) return (0); /* * See comment in DIF_VAR_PID. */ if (DTRACE_ANCHORED(mstate->dtms_probe) && CPU_ON_INTR(CPU)) return (0); /* * It is always safe to dereference one's own t_lwp pointer in * the event that this pointer is non-NULL. (This is true * because threads and lwps don't clean up their own state -- * they leave that task to whomever reaps them.) */ if ((lwp = curthread->t_lwp) == NULL) return (0); return ((uint64_t)lwp->lwp_errno); +#else + return (curthread->td_errno); +#endif } default: DTRACE_CPUFLAG_SET(CPU_DTRACE_ILLOP); return (0); } } /* * Emulate the execution of DTrace ID subroutines invoked by the call opcode. * Notice that we don't bother validating the proper number of arguments or * their types in the tuple stack. This isn't needed because all argument * interpretation is safe because of our load safety -- the worst that can * happen is that a bogus program can obtain bogus results. */ static void dtrace_dif_subr(uint_t subr, uint_t rd, uint64_t *regs, dtrace_key_t *tupregs, int nargs, dtrace_mstate_t *mstate, dtrace_state_t *state) { - volatile uint16_t *flags = &cpu_core[CPU->cpu_id].cpuc_dtrace_flags; - volatile uintptr_t *illval = &cpu_core[CPU->cpu_id].cpuc_dtrace_illval; + volatile uint16_t *flags = &cpu_core[curcpu].cpuc_dtrace_flags; + volatile uintptr_t *illval = &cpu_core[curcpu].cpuc_dtrace_illval; dtrace_vstate_t *vstate = &state->dts_vstate; +#if defined(sun) union { mutex_impl_t mi; uint64_t mx; } m; union { krwlock_t ri; uintptr_t rw; } r; +#else + union { + struct mtx *mi; + uintptr_t mx; + } m; + union { + struct sx *si; + uintptr_t sx; + } s; +#endif switch (subr) { case DIF_SUBR_RAND: regs[rd] = (dtrace_gethrtime() * 2416 + 374441) % 1771875; break; +#if defined(sun) case DIF_SUBR_MUTEX_OWNED: if (!dtrace_canload(tupregs[0].dttk_value, sizeof (kmutex_t), mstate, vstate)) { - regs[rd] = NULL; + regs[rd] = 0; break; } m.mx = dtrace_load64(tupregs[0].dttk_value); if (MUTEX_TYPE_ADAPTIVE(&m.mi)) regs[rd] = MUTEX_OWNER(&m.mi) != MUTEX_NO_OWNER; else regs[rd] = LOCK_HELD(&m.mi.m_spin.m_spinlock); break; case DIF_SUBR_MUTEX_OWNER: if (!dtrace_canload(tupregs[0].dttk_value, sizeof (kmutex_t), mstate, vstate)) { - regs[rd] = NULL; + regs[rd] = 0; break; } m.mx = dtrace_load64(tupregs[0].dttk_value); if (MUTEX_TYPE_ADAPTIVE(&m.mi) && MUTEX_OWNER(&m.mi) != MUTEX_NO_OWNER) regs[rd] = (uintptr_t)MUTEX_OWNER(&m.mi); else regs[rd] = 0; break; case DIF_SUBR_MUTEX_TYPE_ADAPTIVE: if (!dtrace_canload(tupregs[0].dttk_value, sizeof (kmutex_t), mstate, vstate)) { - regs[rd] = NULL; + regs[rd] = 0; break; } m.mx = dtrace_load64(tupregs[0].dttk_value); regs[rd] = MUTEX_TYPE_ADAPTIVE(&m.mi); break; case DIF_SUBR_MUTEX_TYPE_SPIN: if (!dtrace_canload(tupregs[0].dttk_value, sizeof (kmutex_t), mstate, vstate)) { - regs[rd] = NULL; + regs[rd] = 0; break; } m.mx = dtrace_load64(tupregs[0].dttk_value); regs[rd] = MUTEX_TYPE_SPIN(&m.mi); break; case DIF_SUBR_RW_READ_HELD: { uintptr_t tmp; if (!dtrace_canload(tupregs[0].dttk_value, sizeof (uintptr_t), mstate, vstate)) { - regs[rd] = NULL; + regs[rd] = 0; break; } r.rw = dtrace_loadptr(tupregs[0].dttk_value); regs[rd] = _RW_READ_HELD(&r.ri, tmp); break; } case DIF_SUBR_RW_WRITE_HELD: if (!dtrace_canload(tupregs[0].dttk_value, sizeof (krwlock_t), mstate, vstate)) { - regs[rd] = NULL; + regs[rd] = 0; break; } r.rw = dtrace_loadptr(tupregs[0].dttk_value); regs[rd] = _RW_WRITE_HELD(&r.ri); break; case DIF_SUBR_RW_ISWRITER: if (!dtrace_canload(tupregs[0].dttk_value, sizeof (krwlock_t), mstate, vstate)) { - regs[rd] = NULL; + regs[rd] = 0; break; } r.rw = dtrace_loadptr(tupregs[0].dttk_value); regs[rd] = _RW_ISWRITER(&r.ri); break; +#else + /* + * XXX - The following code works because mutex, rwlocks, & sxlocks + * all have similar data structures in FreeBSD. This may not be + * good if someone changes one of the lock data structures. + * Ideally, it would be nice if all these shared a common lock + * object. + */ + case DIF_SUBR_MUTEX_OWNED: + /* XXX - need to use dtrace_canload() and dtrace_loadptr() */ + m.mx = tupregs[0].dttk_value; + + if (LO_CLASSINDEX(&(m.mi->lock_object)) < 2) { + regs[rd] = !(m.mi->mtx_lock & MTX_UNOWNED); + } else { + regs[rd] = !(m.mi->mtx_lock & SX_UNLOCKED); + } + break; + + case DIF_SUBR_MUTEX_OWNER: + /* XXX - need to use dtrace_canload() and dtrace_loadptr() */ + m.mx = tupregs[0].dttk_value; + + if (LO_CLASSINDEX(&(m.mi->lock_object)) < 2) { + regs[rd] = m.mi->mtx_lock & ~MTX_FLAGMASK; + } else { + if (!(m.mi->mtx_lock & SX_LOCK_SHARED)) + regs[rd] = SX_OWNER(m.mi->mtx_lock); + else + regs[rd] = 0; + } + break; + + case DIF_SUBR_MUTEX_TYPE_ADAPTIVE: + /* XXX - need to use dtrace_canload() and dtrace_loadptr() */ + m.mx = tupregs[0].dttk_value; + + regs[rd] = (LO_CLASSINDEX(&(m.mi->lock_object)) != 0); + break; + + case DIF_SUBR_MUTEX_TYPE_SPIN: + /* XXX - need to use dtrace_canload() and dtrace_loadptr() */ + m.mx = tupregs[0].dttk_value; + + regs[rd] = (LO_CLASSINDEX(&(m.mi->lock_object)) == 0); + break; + + case DIF_SUBR_RW_READ_HELD: + case DIF_SUBR_SX_SHARED_HELD: + /* XXX - need to use dtrace_canload() and dtrace_loadptr() */ + s.sx = tupregs[0].dttk_value; + regs[rd] = ((s.si->sx_lock & SX_LOCK_SHARED) && + (SX_OWNER(s.si->sx_lock) >> SX_SHARERS_SHIFT) != 0); + break; + + case DIF_SUBR_RW_WRITE_HELD: + case DIF_SUBR_SX_EXCLUSIVE_HELD: + /* XXX - need to use dtrace_canload() and dtrace_loadptr() */ + s.sx = tupregs[0].dttk_value; + regs[rd] = (SX_OWNER(s.si->sx_lock) == (uintptr_t) curthread); + break; + + case DIF_SUBR_RW_ISWRITER: + case DIF_SUBR_SX_ISEXCLUSIVE: + /* XXX - need to use dtrace_canload() and dtrace_loadptr() */ + s.sx = tupregs[0].dttk_value; + regs[rd] = ((s.si->sx_lock & SX_LOCK_EXCLUSIVE_WAITERS) || + !(s.si->sx_lock & SX_LOCK_SHARED)); + break; +#endif /* ! defined(sun) */ + case DIF_SUBR_BCOPY: { /* * We need to be sure that the destination is in the scratch * region -- no other region is allowed. */ uintptr_t src = tupregs[0].dttk_value; uintptr_t dest = tupregs[1].dttk_value; size_t size = tupregs[2].dttk_value; if (!dtrace_inscratch(dest, size, mstate)) { *flags |= CPU_DTRACE_BADADDR; *illval = regs[rd]; break; } if (!dtrace_canload(src, size, mstate, vstate)) { - regs[rd] = NULL; + regs[rd] = 0; break; } dtrace_bcopy((void *)src, (void *)dest, size); break; } case DIF_SUBR_ALLOCA: case DIF_SUBR_COPYIN: { uintptr_t dest = P2ROUNDUP(mstate->dtms_scratch_ptr, 8); uint64_t size = tupregs[subr == DIF_SUBR_ALLOCA ? 0 : 1].dttk_value; size_t scratch_size = (dest - mstate->dtms_scratch_ptr) + size; /* * This action doesn't require any credential checks since * probes will not activate in user contexts to which the * enabling user does not have permissions. */ /* * Rounding up the user allocation size could have overflowed * a large, bogus allocation (like -1ULL) to 0. */ if (scratch_size < size || !DTRACE_INSCRATCH(mstate, scratch_size)) { DTRACE_CPUFLAG_SET(CPU_DTRACE_NOSCRATCH); - regs[rd] = NULL; + regs[rd] = 0; break; } if (subr == DIF_SUBR_COPYIN) { DTRACE_CPUFLAG_SET(CPU_DTRACE_NOFAULT); dtrace_copyin(tupregs[0].dttk_value, dest, size, flags); DTRACE_CPUFLAG_CLEAR(CPU_DTRACE_NOFAULT); } mstate->dtms_scratch_ptr += scratch_size; regs[rd] = dest; break; } case DIF_SUBR_COPYINTO: { uint64_t size = tupregs[1].dttk_value; uintptr_t dest = tupregs[2].dttk_value; /* * This action doesn't require any credential checks since * probes will not activate in user contexts to which the * enabling user does not have permissions. */ if (!dtrace_inscratch(dest, size, mstate)) { *flags |= CPU_DTRACE_BADADDR; *illval = regs[rd]; break; } DTRACE_CPUFLAG_SET(CPU_DTRACE_NOFAULT); dtrace_copyin(tupregs[0].dttk_value, dest, size, flags); DTRACE_CPUFLAG_CLEAR(CPU_DTRACE_NOFAULT); break; } case DIF_SUBR_COPYINSTR: { uintptr_t dest = mstate->dtms_scratch_ptr; uint64_t size = state->dts_options[DTRACEOPT_STRSIZE]; if (nargs > 1 && tupregs[1].dttk_value < size) size = tupregs[1].dttk_value + 1; /* * This action doesn't require any credential checks since * probes will not activate in user contexts to which the * enabling user does not have permissions. */ if (!DTRACE_INSCRATCH(mstate, size)) { DTRACE_CPUFLAG_SET(CPU_DTRACE_NOSCRATCH); - regs[rd] = NULL; + regs[rd] = 0; break; } DTRACE_CPUFLAG_SET(CPU_DTRACE_NOFAULT); dtrace_copyinstr(tupregs[0].dttk_value, dest, size, flags); DTRACE_CPUFLAG_CLEAR(CPU_DTRACE_NOFAULT); ((char *)dest)[size - 1] = '\0'; mstate->dtms_scratch_ptr += size; regs[rd] = dest; break; } +#if defined(sun) case DIF_SUBR_MSGSIZE: case DIF_SUBR_MSGDSIZE: { uintptr_t baddr = tupregs[0].dttk_value, daddr; uintptr_t wptr, rptr; size_t count = 0; int cont = 0; - while (baddr != NULL && !(*flags & CPU_DTRACE_FAULT)) { + while (baddr != 0 && !(*flags & CPU_DTRACE_FAULT)) { if (!dtrace_canload(baddr, sizeof (mblk_t), mstate, vstate)) { - regs[rd] = NULL; + regs[rd] = 0; break; } wptr = dtrace_loadptr(baddr + offsetof(mblk_t, b_wptr)); rptr = dtrace_loadptr(baddr + offsetof(mblk_t, b_rptr)); if (wptr < rptr) { *flags |= CPU_DTRACE_BADADDR; *illval = tupregs[0].dttk_value; break; } daddr = dtrace_loadptr(baddr + offsetof(mblk_t, b_datap)); baddr = dtrace_loadptr(baddr + offsetof(mblk_t, b_cont)); /* * We want to prevent against denial-of-service here, * so we're only going to search the list for * dtrace_msgdsize_max mblks. */ if (cont++ > dtrace_msgdsize_max) { *flags |= CPU_DTRACE_ILLOP; break; } if (subr == DIF_SUBR_MSGDSIZE) { if (dtrace_load8(daddr + offsetof(dblk_t, db_type)) != M_DATA) continue; } count += wptr - rptr; } if (!(*flags & CPU_DTRACE_FAULT)) regs[rd] = count; break; } +#endif case DIF_SUBR_PROGENYOF: { pid_t pid = tupregs[0].dttk_value; proc_t *p; int rval = 0; DTRACE_CPUFLAG_SET(CPU_DTRACE_NOFAULT); for (p = curthread->t_procp; p != NULL; p = p->p_parent) { +#if defined(sun) if (p->p_pidp->pid_id == pid) { +#else + if (p->p_pid == pid) { +#endif rval = 1; break; } } DTRACE_CPUFLAG_CLEAR(CPU_DTRACE_NOFAULT); regs[rd] = rval; break; } case DIF_SUBR_SPECULATION: regs[rd] = dtrace_speculation(state); break; case DIF_SUBR_COPYOUT: { uintptr_t kaddr = tupregs[0].dttk_value; uintptr_t uaddr = tupregs[1].dttk_value; uint64_t size = tupregs[2].dttk_value; if (!dtrace_destructive_disallow && dtrace_priv_proc_control(state) && !dtrace_istoxic(kaddr, size)) { DTRACE_CPUFLAG_SET(CPU_DTRACE_NOFAULT); dtrace_copyout(kaddr, uaddr, size, flags); DTRACE_CPUFLAG_CLEAR(CPU_DTRACE_NOFAULT); } break; } case DIF_SUBR_COPYOUTSTR: { uintptr_t kaddr = tupregs[0].dttk_value; uintptr_t uaddr = tupregs[1].dttk_value; uint64_t size = tupregs[2].dttk_value; if (!dtrace_destructive_disallow && dtrace_priv_proc_control(state) && !dtrace_istoxic(kaddr, size)) { DTRACE_CPUFLAG_SET(CPU_DTRACE_NOFAULT); dtrace_copyoutstr(kaddr, uaddr, size, flags); DTRACE_CPUFLAG_CLEAR(CPU_DTRACE_NOFAULT); } break; } case DIF_SUBR_STRLEN: { size_t sz; uintptr_t addr = (uintptr_t)tupregs[0].dttk_value; sz = dtrace_strlen((char *)addr, state->dts_options[DTRACEOPT_STRSIZE]); if (!dtrace_canload(addr, sz + 1, mstate, vstate)) { - regs[rd] = NULL; + regs[rd] = 0; break; } regs[rd] = sz; break; } case DIF_SUBR_STRCHR: case DIF_SUBR_STRRCHR: { /* * We're going to iterate over the string looking for the * specified character. We will iterate until we have reached * the string length or we have found the character. If this * is DIF_SUBR_STRRCHR, we will look for the last occurrence * of the specified character instead of the first. */ uintptr_t saddr = tupregs[0].dttk_value; uintptr_t addr = tupregs[0].dttk_value; uintptr_t limit = addr + state->dts_options[DTRACEOPT_STRSIZE]; char c, target = (char)tupregs[1].dttk_value; - for (regs[rd] = NULL; addr < limit; addr++) { + for (regs[rd] = 0; addr < limit; addr++) { if ((c = dtrace_load8(addr)) == target) { regs[rd] = addr; if (subr == DIF_SUBR_STRCHR) break; } if (c == '\0') break; } if (!dtrace_canload(saddr, addr - saddr, mstate, vstate)) { - regs[rd] = NULL; + regs[rd] = 0; break; } break; } case DIF_SUBR_STRSTR: case DIF_SUBR_INDEX: case DIF_SUBR_RINDEX: { /* * We're going to iterate over the string looking for the * specified string. We will iterate until we have reached * the string length or we have found the string. (Yes, this * is done in the most naive way possible -- but considering * that the string we're searching for is likely to be * relatively short, the complexity of Rabin-Karp or similar * hardly seems merited.) */ char *addr = (char *)(uintptr_t)tupregs[0].dttk_value; char *substr = (char *)(uintptr_t)tupregs[1].dttk_value; uint64_t size = state->dts_options[DTRACEOPT_STRSIZE]; size_t len = dtrace_strlen(addr, size); size_t sublen = dtrace_strlen(substr, size); char *limit = addr + len, *orig = addr; int notfound = subr == DIF_SUBR_STRSTR ? 0 : -1; int inc = 1; regs[rd] = notfound; if (!dtrace_canload((uintptr_t)addr, len + 1, mstate, vstate)) { - regs[rd] = NULL; + regs[rd] = 0; break; } if (!dtrace_canload((uintptr_t)substr, sublen + 1, mstate, vstate)) { - regs[rd] = NULL; + regs[rd] = 0; break; } /* * strstr() and index()/rindex() have similar semantics if * both strings are the empty string: strstr() returns a * pointer to the (empty) string, and index() and rindex() * both return index 0 (regardless of any position argument). */ if (sublen == 0 && len == 0) { if (subr == DIF_SUBR_STRSTR) regs[rd] = (uintptr_t)addr; else regs[rd] = 0; break; } if (subr != DIF_SUBR_STRSTR) { if (subr == DIF_SUBR_RINDEX) { limit = orig - 1; addr += len; inc = -1; } /* * Both index() and rindex() take an optional position * argument that denotes the starting position. */ if (nargs == 3) { int64_t pos = (int64_t)tupregs[2].dttk_value; /* * If the position argument to index() is * negative, Perl implicitly clamps it at * zero. This semantic is a little surprising * given the special meaning of negative * positions to similar Perl functions like * substr(), but it appears to reflect a * notion that index() can start from a * negative index and increment its way up to * the string. Given this notion, Perl's * rindex() is at least self-consistent in * that it implicitly clamps positions greater * than the string length to be the string * length. Where Perl completely loses * coherence, however, is when the specified * substring is the empty string (""). In * this case, even if the position is * negative, rindex() returns 0 -- and even if * the position is greater than the length, * index() returns the string length. These * semantics violate the notion that index() * should never return a value less than the * specified position and that rindex() should * never return a value greater than the * specified position. (One assumes that * these semantics are artifacts of Perl's * implementation and not the results of * deliberate design -- it beggars belief that * even Larry Wall could desire such oddness.) * While in the abstract one would wish for * consistent position semantics across * substr(), index() and rindex() -- or at the * very least self-consistent position * semantics for index() and rindex() -- we * instead opt to keep with the extant Perl * semantics, in all their broken glory. (Do * we have more desire to maintain Perl's * semantics than Perl does? Probably.) */ if (subr == DIF_SUBR_RINDEX) { if (pos < 0) { if (sublen == 0) regs[rd] = 0; break; } if (pos > len) pos = len; } else { if (pos < 0) pos = 0; if (pos >= len) { if (sublen == 0) regs[rd] = len; break; } } addr = orig + pos; } } for (regs[rd] = notfound; addr != limit; addr += inc) { if (dtrace_strncmp(addr, substr, sublen) == 0) { if (subr != DIF_SUBR_STRSTR) { /* * As D index() and rindex() are * modeled on Perl (and not on awk), * we return a zero-based (and not a * one-based) index. (For you Perl * weenies: no, we're not going to add * $[ -- and shouldn't you be at a con * or something?) */ regs[rd] = (uintptr_t)(addr - orig); break; } ASSERT(subr == DIF_SUBR_STRSTR); regs[rd] = (uintptr_t)addr; break; } } break; } case DIF_SUBR_STRTOK: { uintptr_t addr = tupregs[0].dttk_value; uintptr_t tokaddr = tupregs[1].dttk_value; uint64_t size = state->dts_options[DTRACEOPT_STRSIZE]; uintptr_t limit, toklimit = tokaddr + size; - uint8_t c, tokmap[32]; /* 256 / 8 */ + uint8_t c = 0, tokmap[32]; /* 256 / 8 */ char *dest = (char *)mstate->dtms_scratch_ptr; int i; /* * Check both the token buffer and (later) the input buffer, * since both could be non-scratch addresses. */ if (!dtrace_strcanload(tokaddr, size, mstate, vstate)) { - regs[rd] = NULL; + regs[rd] = 0; break; } if (!DTRACE_INSCRATCH(mstate, size)) { DTRACE_CPUFLAG_SET(CPU_DTRACE_NOSCRATCH); - regs[rd] = NULL; + regs[rd] = 0; break; } - if (addr == NULL) { + if (addr == 0) { /* * If the address specified is NULL, we use our saved * strtok pointer from the mstate. Note that this * means that the saved strtok pointer is _only_ * valid within multiple enablings of the same probe -- * it behaves like an implicit clause-local variable. */ addr = mstate->dtms_strtok; } else { /* * If the user-specified address is non-NULL we must * access check it. This is the only time we have * a chance to do so, since this address may reside * in the string table of this clause-- future calls * (when we fetch addr from mstate->dtms_strtok) * would fail this access check. */ if (!dtrace_strcanload(addr, size, mstate, vstate)) { - regs[rd] = NULL; + regs[rd] = 0; break; } } /* * First, zero the token map, and then process the token * string -- setting a bit in the map for every character * found in the token string. */ for (i = 0; i < sizeof (tokmap); i++) tokmap[i] = 0; for (; tokaddr < toklimit; tokaddr++) { if ((c = dtrace_load8(tokaddr)) == '\0') break; ASSERT((c >> 3) < sizeof (tokmap)); tokmap[c >> 3] |= (1 << (c & 0x7)); } for (limit = addr + size; addr < limit; addr++) { /* * We're looking for a character that is _not_ contained * in the token string. */ if ((c = dtrace_load8(addr)) == '\0') break; if (!(tokmap[c >> 3] & (1 << (c & 0x7)))) break; } if (c == '\0') { /* * We reached the end of the string without finding * any character that was not in the token string. * We return NULL in this case, and we set the saved * address to NULL as well. */ - regs[rd] = NULL; - mstate->dtms_strtok = NULL; + regs[rd] = 0; + mstate->dtms_strtok = 0; break; } /* * From here on, we're copying into the destination string. */ for (i = 0; addr < limit && i < size - 1; addr++) { if ((c = dtrace_load8(addr)) == '\0') break; if (tokmap[c >> 3] & (1 << (c & 0x7))) break; ASSERT(i < size); dest[i++] = c; } ASSERT(i < size); dest[i] = '\0'; regs[rd] = (uintptr_t)dest; mstate->dtms_scratch_ptr += size; mstate->dtms_strtok = addr; break; } case DIF_SUBR_SUBSTR: { uintptr_t s = tupregs[0].dttk_value; uint64_t size = state->dts_options[DTRACEOPT_STRSIZE]; char *d = (char *)mstate->dtms_scratch_ptr; int64_t index = (int64_t)tupregs[1].dttk_value; int64_t remaining = (int64_t)tupregs[2].dttk_value; size_t len = dtrace_strlen((char *)s, size); int64_t i = 0; if (!dtrace_canload(s, len + 1, mstate, vstate)) { - regs[rd] = NULL; + regs[rd] = 0; break; } - if (nargs <= 2) - remaining = (int64_t)size; - if (!DTRACE_INSCRATCH(mstate, size)) { DTRACE_CPUFLAG_SET(CPU_DTRACE_NOSCRATCH); - regs[rd] = NULL; + regs[rd] = 0; break; } + if (nargs <= 2) + remaining = (int64_t)size; + if (index < 0) { index += len; if (index < 0 && index + remaining > 0) { remaining += index; index = 0; } } - if (index >= len || index < 0) - index = len; + if (index >= len || index < 0) { + remaining = 0; + } else if (remaining < 0) { + remaining += len - index; + } else if (index + remaining > size) { + remaining = size - index; + } - for (d[0] = '\0'; remaining > 0; remaining--) { - if ((d[i++] = dtrace_load8(s++ + index)) == '\0') + for (i = 0; i < remaining; i++) { + if ((d[i] = dtrace_load8(s + index + i)) == '\0') break; - - if (i == size) { - d[i - 1] = '\0'; - break; - } } + d[i] = '\0'; + mstate->dtms_scratch_ptr += size; regs[rd] = (uintptr_t)d; break; } +#if defined(sun) case DIF_SUBR_GETMAJOR: #ifdef _LP64 regs[rd] = (tupregs[0].dttk_value >> NBITSMINOR64) & MAXMAJ64; #else regs[rd] = (tupregs[0].dttk_value >> NBITSMINOR) & MAXMAJ; #endif break; case DIF_SUBR_GETMINOR: #ifdef _LP64 regs[rd] = tupregs[0].dttk_value & MAXMIN64; #else regs[rd] = tupregs[0].dttk_value & MAXMIN; #endif break; case DIF_SUBR_DDI_PATHNAME: { /* * This one is a galactic mess. We are going to roughly * emulate ddi_pathname(), but it's made more complicated * by the fact that we (a) want to include the minor name and * (b) must proceed iteratively instead of recursively. */ uintptr_t dest = mstate->dtms_scratch_ptr; uint64_t size = state->dts_options[DTRACEOPT_STRSIZE]; char *start = (char *)dest, *end = start + size - 1; uintptr_t daddr = tupregs[0].dttk_value; int64_t minor = (int64_t)tupregs[1].dttk_value; char *s; int i, len, depth = 0; /* * Due to all the pointer jumping we do and context we must * rely upon, we just mandate that the user must have kernel * read privileges to use this routine. */ if ((mstate->dtms_access & DTRACE_ACCESS_KERNEL) == 0) { *flags |= CPU_DTRACE_KPRIV; *illval = daddr; - regs[rd] = NULL; + regs[rd] = 0; } if (!DTRACE_INSCRATCH(mstate, size)) { DTRACE_CPUFLAG_SET(CPU_DTRACE_NOSCRATCH); - regs[rd] = NULL; + regs[rd] = 0; break; } *end = '\0'; /* * We want to have a name for the minor. In order to do this, * we need to walk the minor list from the devinfo. We want * to be sure that we don't infinitely walk a circular list, * so we check for circularity by sending a scout pointer * ahead two elements for every element that we iterate over; * if the list is circular, these will ultimately point to the * same element. You may recognize this little trick as the * answer to a stupid interview question -- one that always * seems to be asked by those who had to have it laboriously * explained to them, and who can't even concisely describe * the conditions under which one would be forced to resort to * this technique. Needless to say, those conditions are - * found here -- and probably only here. Is this is the only - * use of this infamous trick in shipping, production code? - * If it isn't, it probably should be... + * found here -- and probably only here. Is this the only use + * of this infamous trick in shipping, production code? If it + * isn't, it probably should be... */ if (minor != -1) { uintptr_t maddr = dtrace_loadptr(daddr + offsetof(struct dev_info, devi_minor)); uintptr_t next = offsetof(struct ddi_minor_data, next); uintptr_t name = offsetof(struct ddi_minor_data, d_minor) + offsetof(struct ddi_minor, name); uintptr_t dev = offsetof(struct ddi_minor_data, d_minor) + offsetof(struct ddi_minor, dev); uintptr_t scout; if (maddr != NULL) scout = dtrace_loadptr(maddr + next); while (maddr != NULL && !(*flags & CPU_DTRACE_FAULT)) { uint64_t m; #ifdef _LP64 m = dtrace_load64(maddr + dev) & MAXMIN64; #else m = dtrace_load32(maddr + dev) & MAXMIN; #endif if (m != minor) { maddr = dtrace_loadptr(maddr + next); if (scout == NULL) continue; scout = dtrace_loadptr(scout + next); if (scout == NULL) continue; scout = dtrace_loadptr(scout + next); if (scout == NULL) continue; if (scout == maddr) { *flags |= CPU_DTRACE_ILLOP; break; } continue; } /* * We have the minor data. Now we need to * copy the minor's name into the end of the * pathname. */ s = (char *)dtrace_loadptr(maddr + name); len = dtrace_strlen(s, size); if (*flags & CPU_DTRACE_FAULT) break; if (len != 0) { if ((end -= (len + 1)) < start) break; *end = ':'; } for (i = 1; i <= len; i++) end[i] = dtrace_load8((uintptr_t)s++); break; } } while (daddr != NULL && !(*flags & CPU_DTRACE_FAULT)) { ddi_node_state_t devi_state; devi_state = dtrace_load32(daddr + offsetof(struct dev_info, devi_node_state)); if (*flags & CPU_DTRACE_FAULT) break; if (devi_state >= DS_INITIALIZED) { s = (char *)dtrace_loadptr(daddr + offsetof(struct dev_info, devi_addr)); len = dtrace_strlen(s, size); if (*flags & CPU_DTRACE_FAULT) break; if (len != 0) { if ((end -= (len + 1)) < start) break; *end = '@'; } for (i = 1; i <= len; i++) end[i] = dtrace_load8((uintptr_t)s++); } /* * Now for the node name... */ s = (char *)dtrace_loadptr(daddr + offsetof(struct dev_info, devi_node_name)); daddr = dtrace_loadptr(daddr + offsetof(struct dev_info, devi_parent)); /* * If our parent is NULL (that is, if we're the root * node), we're going to use the special path * "devices". */ - if (daddr == NULL) + if (daddr == 0) s = "devices"; len = dtrace_strlen(s, size); if (*flags & CPU_DTRACE_FAULT) break; if ((end -= (len + 1)) < start) break; for (i = 1; i <= len; i++) end[i] = dtrace_load8((uintptr_t)s++); *end = '/'; if (depth++ > dtrace_devdepth_max) { *flags |= CPU_DTRACE_ILLOP; break; } } if (end < start) DTRACE_CPUFLAG_SET(CPU_DTRACE_NOSCRATCH); - if (daddr == NULL) { + if (daddr == 0) { regs[rd] = (uintptr_t)end; mstate->dtms_scratch_ptr += size; } break; } +#endif case DIF_SUBR_STRJOIN: { char *d = (char *)mstate->dtms_scratch_ptr; uint64_t size = state->dts_options[DTRACEOPT_STRSIZE]; uintptr_t s1 = tupregs[0].dttk_value; uintptr_t s2 = tupregs[1].dttk_value; int i = 0; if (!dtrace_strcanload(s1, size, mstate, vstate) || !dtrace_strcanload(s2, size, mstate, vstate)) { - regs[rd] = NULL; + regs[rd] = 0; break; } if (!DTRACE_INSCRATCH(mstate, size)) { DTRACE_CPUFLAG_SET(CPU_DTRACE_NOSCRATCH); - regs[rd] = NULL; + regs[rd] = 0; break; } for (;;) { if (i >= size) { DTRACE_CPUFLAG_SET(CPU_DTRACE_NOSCRATCH); - regs[rd] = NULL; + regs[rd] = 0; break; } if ((d[i++] = dtrace_load8(s1++)) == '\0') { i--; break; } } for (;;) { if (i >= size) { DTRACE_CPUFLAG_SET(CPU_DTRACE_NOSCRATCH); - regs[rd] = NULL; + regs[rd] = 0; break; } if ((d[i++] = dtrace_load8(s2++)) == '\0') break; } if (i < size) { mstate->dtms_scratch_ptr += i; regs[rd] = (uintptr_t)d; } break; } case DIF_SUBR_LLTOSTR: { int64_t i = (int64_t)tupregs[0].dttk_value; int64_t val = i < 0 ? i * -1 : i; uint64_t size = 22; /* enough room for 2^64 in decimal */ char *end = (char *)mstate->dtms_scratch_ptr + size - 1; if (!DTRACE_INSCRATCH(mstate, size)) { DTRACE_CPUFLAG_SET(CPU_DTRACE_NOSCRATCH); - regs[rd] = NULL; + regs[rd] = 0; break; } for (*end-- = '\0'; val; val /= 10) *end-- = '0' + (val % 10); if (i == 0) *end-- = '0'; if (i < 0) *end-- = '-'; regs[rd] = (uintptr_t)end + 1; mstate->dtms_scratch_ptr += size; break; } case DIF_SUBR_HTONS: case DIF_SUBR_NTOHS: -#ifdef _BIG_ENDIAN +#if BYTE_ORDER == BIG_ENDIAN regs[rd] = (uint16_t)tupregs[0].dttk_value; #else regs[rd] = DT_BSWAP_16((uint16_t)tupregs[0].dttk_value); #endif break; case DIF_SUBR_HTONL: case DIF_SUBR_NTOHL: -#ifdef _BIG_ENDIAN +#if BYTE_ORDER == BIG_ENDIAN regs[rd] = (uint32_t)tupregs[0].dttk_value; #else regs[rd] = DT_BSWAP_32((uint32_t)tupregs[0].dttk_value); #endif break; case DIF_SUBR_HTONLL: case DIF_SUBR_NTOHLL: -#ifdef _BIG_ENDIAN +#if BYTE_ORDER == BIG_ENDIAN regs[rd] = (uint64_t)tupregs[0].dttk_value; #else regs[rd] = DT_BSWAP_64((uint64_t)tupregs[0].dttk_value); #endif break; case DIF_SUBR_DIRNAME: case DIF_SUBR_BASENAME: { char *dest = (char *)mstate->dtms_scratch_ptr; uint64_t size = state->dts_options[DTRACEOPT_STRSIZE]; uintptr_t src = tupregs[0].dttk_value; int i, j, len = dtrace_strlen((char *)src, size); int lastbase = -1, firstbase = -1, lastdir = -1; int start, end; if (!dtrace_canload(src, len + 1, mstate, vstate)) { - regs[rd] = NULL; + regs[rd] = 0; break; } if (!DTRACE_INSCRATCH(mstate, size)) { DTRACE_CPUFLAG_SET(CPU_DTRACE_NOSCRATCH); - regs[rd] = NULL; + regs[rd] = 0; break; } /* * The basename and dirname for a zero-length string is * defined to be "." */ if (len == 0) { len = 1; src = (uintptr_t)"."; } /* * Start from the back of the string, moving back toward the * front until we see a character that isn't a slash. That * character is the last character in the basename. */ for (i = len - 1; i >= 0; i--) { if (dtrace_load8(src + i) != '/') break; } if (i >= 0) lastbase = i; /* * Starting from the last character in the basename, move * towards the front until we find a slash. The character * that we processed immediately before that is the first * character in the basename. */ for (; i >= 0; i--) { if (dtrace_load8(src + i) == '/') break; } if (i >= 0) firstbase = i + 1; /* * Now keep going until we find a non-slash character. That * character is the last character in the dirname. */ for (; i >= 0; i--) { if (dtrace_load8(src + i) != '/') break; } if (i >= 0) lastdir = i; ASSERT(!(lastbase == -1 && firstbase != -1)); ASSERT(!(firstbase == -1 && lastdir != -1)); if (lastbase == -1) { /* * We didn't find a non-slash character. We know that * the length is non-zero, so the whole string must be * slashes. In either the dirname or the basename * case, we return '/'. */ ASSERT(firstbase == -1); firstbase = lastbase = lastdir = 0; } if (firstbase == -1) { /* * The entire string consists only of a basename * component. If we're looking for dirname, we need * to change our string to be just "."; if we're * looking for a basename, we'll just set the first * character of the basename to be 0. */ if (subr == DIF_SUBR_DIRNAME) { ASSERT(lastdir == -1); src = (uintptr_t)"."; lastdir = 0; } else { firstbase = 0; } } if (subr == DIF_SUBR_DIRNAME) { if (lastdir == -1) { /* * We know that we have a slash in the name -- * or lastdir would be set to 0, above. And * because lastdir is -1, we know that this * slash must be the first character. (That * is, the full string must be of the form * "/basename".) In this case, the last * character of the directory name is 0. */ lastdir = 0; } start = 0; end = lastdir; } else { ASSERT(subr == DIF_SUBR_BASENAME); ASSERT(firstbase != -1 && lastbase != -1); start = firstbase; end = lastbase; } for (i = start, j = 0; i <= end && j < size - 1; i++, j++) dest[j] = dtrace_load8(src + i); dest[j] = '\0'; regs[rd] = (uintptr_t)dest; mstate->dtms_scratch_ptr += size; break; } case DIF_SUBR_CLEANPATH: { char *dest = (char *)mstate->dtms_scratch_ptr, c; uint64_t size = state->dts_options[DTRACEOPT_STRSIZE]; uintptr_t src = tupregs[0].dttk_value; int i = 0, j = 0; if (!dtrace_strcanload(src, size, mstate, vstate)) { - regs[rd] = NULL; + regs[rd] = 0; break; } if (!DTRACE_INSCRATCH(mstate, size)) { DTRACE_CPUFLAG_SET(CPU_DTRACE_NOSCRATCH); - regs[rd] = NULL; + regs[rd] = 0; break; } /* * Move forward, loading each character. */ do { c = dtrace_load8(src + i++); next: if (j + 5 >= size) /* 5 = strlen("/..c\0") */ break; if (c != '/') { dest[j++] = c; continue; } c = dtrace_load8(src + i++); if (c == '/') { /* * We have two slashes -- we can just advance * to the next character. */ goto next; } if (c != '.') { /* * This is not "." and it's not ".." -- we can * just store the "/" and this character and * drive on. */ dest[j++] = '/'; dest[j++] = c; continue; } c = dtrace_load8(src + i++); if (c == '/') { /* * This is a "/./" component. We're not going * to store anything in the destination buffer; * we're just going to go to the next component. */ goto next; } if (c != '.') { /* * This is not ".." -- we can just store the * "/." and this character and continue * processing. */ dest[j++] = '/'; dest[j++] = '.'; dest[j++] = c; continue; } c = dtrace_load8(src + i++); if (c != '/' && c != '\0') { /* * This is not ".." -- it's "..[mumble]". * We'll store the "/.." and this character * and continue processing. */ dest[j++] = '/'; dest[j++] = '.'; dest[j++] = '.'; dest[j++] = c; continue; } /* * This is "/../" or "/..\0". We need to back up * our destination pointer until we find a "/". */ i--; while (j != 0 && dest[--j] != '/') continue; if (c == '\0') dest[++j] = '/'; } while (c != '\0'); dest[j] = '\0'; regs[rd] = (uintptr_t)dest; mstate->dtms_scratch_ptr += size; break; } case DIF_SUBR_INET_NTOA: case DIF_SUBR_INET_NTOA6: case DIF_SUBR_INET_NTOP: { size_t size; int af, argi, i; char *base, *end; if (subr == DIF_SUBR_INET_NTOP) { af = (int)tupregs[0].dttk_value; argi = 1; } else { af = subr == DIF_SUBR_INET_NTOA ? AF_INET: AF_INET6; argi = 0; } if (af == AF_INET) { ipaddr_t ip4; uint8_t *ptr8, val; /* * Safely load the IPv4 address. */ ip4 = dtrace_load32(tupregs[argi].dttk_value); /* * Check an IPv4 string will fit in scratch. */ size = INET_ADDRSTRLEN; if (!DTRACE_INSCRATCH(mstate, size)) { DTRACE_CPUFLAG_SET(CPU_DTRACE_NOSCRATCH); - regs[rd] = NULL; + regs[rd] = 0; break; } base = (char *)mstate->dtms_scratch_ptr; end = (char *)mstate->dtms_scratch_ptr + size - 1; /* * Stringify as a dotted decimal quad. */ *end-- = '\0'; ptr8 = (uint8_t *)&ip4; for (i = 3; i >= 0; i--) { val = ptr8[i]; if (val == 0) { *end-- = '0'; } else { for (; val; val /= 10) { *end-- = '0' + (val % 10); } } if (i > 0) *end-- = '.'; } ASSERT(end + 1 >= base); } else if (af == AF_INET6) { struct in6_addr ip6; int firstzero, tryzero, numzero, v6end; uint16_t val; const char digits[] = "0123456789abcdef"; /* * Stringify using RFC 1884 convention 2 - 16 bit * hexadecimal values with a zero-run compression. * Lower case hexadecimal digits are used. * eg, fe80::214:4fff:fe0b:76c8. * The IPv4 embedded form is returned for inet_ntop, * just the IPv4 string is returned for inet_ntoa6. */ /* * Safely load the IPv6 address. */ dtrace_bcopy( (void *)(uintptr_t)tupregs[argi].dttk_value, (void *)(uintptr_t)&ip6, sizeof (struct in6_addr)); /* * Check an IPv6 string will fit in scratch. */ size = INET6_ADDRSTRLEN; if (!DTRACE_INSCRATCH(mstate, size)) { DTRACE_CPUFLAG_SET(CPU_DTRACE_NOSCRATCH); - regs[rd] = NULL; + regs[rd] = 0; break; } base = (char *)mstate->dtms_scratch_ptr; end = (char *)mstate->dtms_scratch_ptr + size - 1; *end-- = '\0'; /* * Find the longest run of 16 bit zero values * for the single allowed zero compression - "::". */ firstzero = -1; tryzero = -1; numzero = 1; for (i = 0; i < sizeof (struct in6_addr); i++) { +#if defined(sun) if (ip6._S6_un._S6_u8[i] == 0 && +#else + if (ip6.__u6_addr.__u6_addr8[i] == 0 && +#endif tryzero == -1 && i % 2 == 0) { tryzero = i; continue; } if (tryzero != -1 && +#if defined(sun) (ip6._S6_un._S6_u8[i] != 0 || +#else + (ip6.__u6_addr.__u6_addr8[i] != 0 || +#endif i == sizeof (struct in6_addr) - 1)) { if (i - tryzero <= numzero) { tryzero = -1; continue; } firstzero = tryzero; numzero = i - i % 2 - tryzero; tryzero = -1; +#if defined(sun) if (ip6._S6_un._S6_u8[i] == 0 && +#else + if (ip6.__u6_addr.__u6_addr8[i] == 0 && +#endif i == sizeof (struct in6_addr) - 1) numzero += 2; } } ASSERT(firstzero + numzero <= sizeof (struct in6_addr)); /* * Check for an IPv4 embedded address. */ v6end = sizeof (struct in6_addr) - 2; if (IN6_IS_ADDR_V4MAPPED(&ip6) || IN6_IS_ADDR_V4COMPAT(&ip6)) { for (i = sizeof (struct in6_addr) - 1; i >= DTRACE_V4MAPPED_OFFSET; i--) { ASSERT(end >= base); +#if defined(sun) val = ip6._S6_un._S6_u8[i]; +#else + val = ip6.__u6_addr.__u6_addr8[i]; +#endif if (val == 0) { *end-- = '0'; } else { for (; val; val /= 10) { *end-- = '0' + val % 10; } } if (i > DTRACE_V4MAPPED_OFFSET) *end-- = '.'; } if (subr == DIF_SUBR_INET_NTOA6) goto inetout; /* * Set v6end to skip the IPv4 address that * we have already stringified. */ v6end = 10; } /* * Build the IPv6 string by working through the * address in reverse. */ for (i = v6end; i >= 0; i -= 2) { ASSERT(end >= base); if (i == firstzero + numzero - 2) { *end-- = ':'; *end-- = ':'; i -= numzero - 2; continue; } if (i < 14 && i != firstzero - 2) *end-- = ':'; +#if defined(sun) val = (ip6._S6_un._S6_u8[i] << 8) + ip6._S6_un._S6_u8[i + 1]; +#else + val = (ip6.__u6_addr.__u6_addr8[i] << 8) + + ip6.__u6_addr.__u6_addr8[i + 1]; +#endif if (val == 0) { *end-- = '0'; } else { for (; val; val /= 16) { *end-- = digits[val % 16]; } } } ASSERT(end + 1 >= base); } else { /* * The user didn't use AH_INET or AH_INET6. */ DTRACE_CPUFLAG_SET(CPU_DTRACE_ILLOP); - regs[rd] = NULL; + regs[rd] = 0; break; } inetout: regs[rd] = (uintptr_t)end + 1; mstate->dtms_scratch_ptr += size; break; } + case DIF_SUBR_MEMREF: { + uintptr_t size = 2 * sizeof(uintptr_t); + uintptr_t *memref = (uintptr_t *) P2ROUNDUP(mstate->dtms_scratch_ptr, sizeof(uintptr_t)); + size_t scratch_size = ((uintptr_t) memref - mstate->dtms_scratch_ptr) + size; + + /* address and length */ + memref[0] = tupregs[0].dttk_value; + memref[1] = tupregs[1].dttk_value; + + regs[rd] = (uintptr_t) memref; + mstate->dtms_scratch_ptr += scratch_size; + break; } + + case DIF_SUBR_TYPEREF: { + uintptr_t size = 4 * sizeof(uintptr_t); + uintptr_t *typeref = (uintptr_t *) P2ROUNDUP(mstate->dtms_scratch_ptr, sizeof(uintptr_t)); + size_t scratch_size = ((uintptr_t) typeref - mstate->dtms_scratch_ptr) + size; + + /* address, num_elements, type_str, type_len */ + typeref[0] = tupregs[0].dttk_value; + typeref[1] = tupregs[1].dttk_value; + typeref[2] = tupregs[2].dttk_value; + typeref[3] = tupregs[3].dttk_value; + + regs[rd] = (uintptr_t) typeref; + mstate->dtms_scratch_ptr += scratch_size; + break; + } + } } /* * Emulate the execution of DTrace IR instructions specified by the given * DIF object. This function is deliberately void of assertions as all of * the necessary checks are handled by a call to dtrace_difo_validate(). */ static uint64_t dtrace_dif_emulate(dtrace_difo_t *difo, dtrace_mstate_t *mstate, dtrace_vstate_t *vstate, dtrace_state_t *state) { const dif_instr_t *text = difo->dtdo_buf; const uint_t textlen = difo->dtdo_len; const char *strtab = difo->dtdo_strtab; const uint64_t *inttab = difo->dtdo_inttab; uint64_t rval = 0; dtrace_statvar_t *svar; dtrace_dstate_t *dstate = &vstate->dtvs_dynvars; dtrace_difv_t *v; - volatile uint16_t *flags = &cpu_core[CPU->cpu_id].cpuc_dtrace_flags; - volatile uintptr_t *illval = &cpu_core[CPU->cpu_id].cpuc_dtrace_illval; + volatile uint16_t *flags = &cpu_core[curcpu].cpuc_dtrace_flags; + volatile uintptr_t *illval = &cpu_core[curcpu].cpuc_dtrace_illval; dtrace_key_t tupregs[DIF_DTR_NREGS + 2]; /* +2 for thread and id */ uint64_t regs[DIF_DIR_NREGS]; uint64_t *tmp; uint8_t cc_n = 0, cc_z = 0, cc_v = 0, cc_c = 0; int64_t cc_r; - uint_t pc = 0, id, opc; + uint_t pc = 0, id, opc = 0; uint8_t ttop = 0; dif_instr_t instr; uint_t r1, r2, rd; /* * We stash the current DIF object into the machine state: we need it * for subsequent access checking. */ mstate->dtms_difo = difo; regs[DIF_REG_R0] = 0; /* %r0 is fixed at zero */ while (pc < textlen && !(*flags & CPU_DTRACE_FAULT)) { opc = pc; instr = text[pc++]; r1 = DIF_INSTR_R1(instr); r2 = DIF_INSTR_R2(instr); rd = DIF_INSTR_RD(instr); switch (DIF_INSTR_OP(instr)) { case DIF_OP_OR: regs[rd] = regs[r1] | regs[r2]; break; case DIF_OP_XOR: regs[rd] = regs[r1] ^ regs[r2]; break; case DIF_OP_AND: regs[rd] = regs[r1] & regs[r2]; break; case DIF_OP_SLL: regs[rd] = regs[r1] << regs[r2]; break; case DIF_OP_SRL: regs[rd] = regs[r1] >> regs[r2]; break; case DIF_OP_SUB: regs[rd] = regs[r1] - regs[r2]; break; case DIF_OP_ADD: regs[rd] = regs[r1] + regs[r2]; break; case DIF_OP_MUL: regs[rd] = regs[r1] * regs[r2]; break; case DIF_OP_SDIV: if (regs[r2] == 0) { regs[rd] = 0; *flags |= CPU_DTRACE_DIVZERO; } else { regs[rd] = (int64_t)regs[r1] / (int64_t)regs[r2]; } break; case DIF_OP_UDIV: if (regs[r2] == 0) { regs[rd] = 0; *flags |= CPU_DTRACE_DIVZERO; } else { regs[rd] = regs[r1] / regs[r2]; } break; case DIF_OP_SREM: if (regs[r2] == 0) { regs[rd] = 0; *flags |= CPU_DTRACE_DIVZERO; } else { regs[rd] = (int64_t)regs[r1] % (int64_t)regs[r2]; } break; case DIF_OP_UREM: if (regs[r2] == 0) { regs[rd] = 0; *flags |= CPU_DTRACE_DIVZERO; } else { regs[rd] = regs[r1] % regs[r2]; } break; case DIF_OP_NOT: regs[rd] = ~regs[r1]; break; case DIF_OP_MOV: regs[rd] = regs[r1]; break; case DIF_OP_CMP: cc_r = regs[r1] - regs[r2]; cc_n = cc_r < 0; cc_z = cc_r == 0; cc_v = 0; cc_c = regs[r1] < regs[r2]; break; case DIF_OP_TST: cc_n = cc_v = cc_c = 0; cc_z = regs[r1] == 0; break; case DIF_OP_BA: pc = DIF_INSTR_LABEL(instr); break; case DIF_OP_BE: if (cc_z) pc = DIF_INSTR_LABEL(instr); break; case DIF_OP_BNE: if (cc_z == 0) pc = DIF_INSTR_LABEL(instr); break; case DIF_OP_BG: if ((cc_z | (cc_n ^ cc_v)) == 0) pc = DIF_INSTR_LABEL(instr); break; case DIF_OP_BGU: if ((cc_c | cc_z) == 0) pc = DIF_INSTR_LABEL(instr); break; case DIF_OP_BGE: if ((cc_n ^ cc_v) == 0) pc = DIF_INSTR_LABEL(instr); break; case DIF_OP_BGEU: if (cc_c == 0) pc = DIF_INSTR_LABEL(instr); break; case DIF_OP_BL: if (cc_n ^ cc_v) pc = DIF_INSTR_LABEL(instr); break; case DIF_OP_BLU: if (cc_c) pc = DIF_INSTR_LABEL(instr); break; case DIF_OP_BLE: if (cc_z | (cc_n ^ cc_v)) pc = DIF_INSTR_LABEL(instr); break; case DIF_OP_BLEU: if (cc_c | cc_z) pc = DIF_INSTR_LABEL(instr); break; case DIF_OP_RLDSB: if (!dtrace_canstore(regs[r1], 1, mstate, vstate)) { *flags |= CPU_DTRACE_KPRIV; *illval = regs[r1]; break; } /*FALLTHROUGH*/ case DIF_OP_LDSB: regs[rd] = (int8_t)dtrace_load8(regs[r1]); break; case DIF_OP_RLDSH: if (!dtrace_canstore(regs[r1], 2, mstate, vstate)) { *flags |= CPU_DTRACE_KPRIV; *illval = regs[r1]; break; } /*FALLTHROUGH*/ case DIF_OP_LDSH: regs[rd] = (int16_t)dtrace_load16(regs[r1]); break; case DIF_OP_RLDSW: if (!dtrace_canstore(regs[r1], 4, mstate, vstate)) { *flags |= CPU_DTRACE_KPRIV; *illval = regs[r1]; break; } /*FALLTHROUGH*/ case DIF_OP_LDSW: regs[rd] = (int32_t)dtrace_load32(regs[r1]); break; case DIF_OP_RLDUB: if (!dtrace_canstore(regs[r1], 1, mstate, vstate)) { *flags |= CPU_DTRACE_KPRIV; *illval = regs[r1]; break; } /*FALLTHROUGH*/ case DIF_OP_LDUB: regs[rd] = dtrace_load8(regs[r1]); break; case DIF_OP_RLDUH: if (!dtrace_canstore(regs[r1], 2, mstate, vstate)) { *flags |= CPU_DTRACE_KPRIV; *illval = regs[r1]; break; } /*FALLTHROUGH*/ case DIF_OP_LDUH: regs[rd] = dtrace_load16(regs[r1]); break; case DIF_OP_RLDUW: if (!dtrace_canstore(regs[r1], 4, mstate, vstate)) { *flags |= CPU_DTRACE_KPRIV; *illval = regs[r1]; break; } /*FALLTHROUGH*/ case DIF_OP_LDUW: regs[rd] = dtrace_load32(regs[r1]); break; case DIF_OP_RLDX: if (!dtrace_canstore(regs[r1], 8, mstate, vstate)) { *flags |= CPU_DTRACE_KPRIV; *illval = regs[r1]; break; } /*FALLTHROUGH*/ case DIF_OP_LDX: regs[rd] = dtrace_load64(regs[r1]); break; case DIF_OP_ULDSB: regs[rd] = (int8_t) dtrace_fuword8((void *)(uintptr_t)regs[r1]); break; case DIF_OP_ULDSH: regs[rd] = (int16_t) dtrace_fuword16((void *)(uintptr_t)regs[r1]); break; case DIF_OP_ULDSW: regs[rd] = (int32_t) dtrace_fuword32((void *)(uintptr_t)regs[r1]); break; case DIF_OP_ULDUB: regs[rd] = dtrace_fuword8((void *)(uintptr_t)regs[r1]); break; case DIF_OP_ULDUH: regs[rd] = dtrace_fuword16((void *)(uintptr_t)regs[r1]); break; case DIF_OP_ULDUW: regs[rd] = dtrace_fuword32((void *)(uintptr_t)regs[r1]); break; case DIF_OP_ULDX: regs[rd] = dtrace_fuword64((void *)(uintptr_t)regs[r1]); break; case DIF_OP_RET: rval = regs[rd]; pc = textlen; break; case DIF_OP_NOP: break; case DIF_OP_SETX: regs[rd] = inttab[DIF_INSTR_INTEGER(instr)]; break; case DIF_OP_SETS: regs[rd] = (uint64_t)(uintptr_t) (strtab + DIF_INSTR_STRING(instr)); break; case DIF_OP_SCMP: { size_t sz = state->dts_options[DTRACEOPT_STRSIZE]; uintptr_t s1 = regs[r1]; uintptr_t s2 = regs[r2]; - if (s1 != NULL && + if (s1 != 0 && !dtrace_strcanload(s1, sz, mstate, vstate)) break; - if (s2 != NULL && + if (s2 != 0 && !dtrace_strcanload(s2, sz, mstate, vstate)) break; cc_r = dtrace_strncmp((char *)s1, (char *)s2, sz); cc_n = cc_r < 0; cc_z = cc_r == 0; cc_v = cc_c = 0; break; } case DIF_OP_LDGA: regs[rd] = dtrace_dif_variable(mstate, state, r1, regs[r2]); break; case DIF_OP_LDGS: id = DIF_INSTR_VAR(instr); if (id >= DIF_VAR_OTHER_UBASE) { uintptr_t a; id -= DIF_VAR_OTHER_UBASE; svar = vstate->dtvs_globals[id]; ASSERT(svar != NULL); v = &svar->dtsv_var; if (!(v->dtdv_type.dtdt_flags & DIF_TF_BYREF)) { regs[rd] = svar->dtsv_data; break; } a = (uintptr_t)svar->dtsv_data; if (*(uint8_t *)a == UINT8_MAX) { /* * If the 0th byte is set to UINT8_MAX * then this is to be treated as a * reference to a NULL variable. */ - regs[rd] = NULL; + regs[rd] = 0; } else { regs[rd] = a + sizeof (uint64_t); } break; } regs[rd] = dtrace_dif_variable(mstate, state, id, 0); break; case DIF_OP_STGS: id = DIF_INSTR_VAR(instr); ASSERT(id >= DIF_VAR_OTHER_UBASE); id -= DIF_VAR_OTHER_UBASE; svar = vstate->dtvs_globals[id]; ASSERT(svar != NULL); v = &svar->dtsv_var; if (v->dtdv_type.dtdt_flags & DIF_TF_BYREF) { uintptr_t a = (uintptr_t)svar->dtsv_data; - ASSERT(a != NULL); + ASSERT(a != 0); ASSERT(svar->dtsv_size != 0); - if (regs[rd] == NULL) { + if (regs[rd] == 0) { *(uint8_t *)a = UINT8_MAX; break; } else { *(uint8_t *)a = 0; a += sizeof (uint64_t); } if (!dtrace_vcanload( (void *)(uintptr_t)regs[rd], &v->dtdv_type, mstate, vstate)) break; dtrace_vcopy((void *)(uintptr_t)regs[rd], (void *)a, &v->dtdv_type); break; } svar->dtsv_data = regs[rd]; break; case DIF_OP_LDTA: /* * There are no DTrace built-in thread-local arrays at * present. This opcode is saved for future work. */ *flags |= CPU_DTRACE_ILLOP; regs[rd] = 0; break; case DIF_OP_LDLS: id = DIF_INSTR_VAR(instr); if (id < DIF_VAR_OTHER_UBASE) { /* * For now, this has no meaning. */ regs[rd] = 0; break; } id -= DIF_VAR_OTHER_UBASE; ASSERT(id < vstate->dtvs_nlocals); ASSERT(vstate->dtvs_locals != NULL); svar = vstate->dtvs_locals[id]; ASSERT(svar != NULL); v = &svar->dtsv_var; if (v->dtdv_type.dtdt_flags & DIF_TF_BYREF) { uintptr_t a = (uintptr_t)svar->dtsv_data; size_t sz = v->dtdv_type.dtdt_size; sz += sizeof (uint64_t); ASSERT(svar->dtsv_size == NCPU * sz); - a += CPU->cpu_id * sz; + a += curcpu * sz; if (*(uint8_t *)a == UINT8_MAX) { /* * If the 0th byte is set to UINT8_MAX * then this is to be treated as a * reference to a NULL variable. */ - regs[rd] = NULL; + regs[rd] = 0; } else { regs[rd] = a + sizeof (uint64_t); } break; } ASSERT(svar->dtsv_size == NCPU * sizeof (uint64_t)); tmp = (uint64_t *)(uintptr_t)svar->dtsv_data; - regs[rd] = tmp[CPU->cpu_id]; + regs[rd] = tmp[curcpu]; break; case DIF_OP_STLS: id = DIF_INSTR_VAR(instr); ASSERT(id >= DIF_VAR_OTHER_UBASE); id -= DIF_VAR_OTHER_UBASE; ASSERT(id < vstate->dtvs_nlocals); ASSERT(vstate->dtvs_locals != NULL); svar = vstate->dtvs_locals[id]; ASSERT(svar != NULL); v = &svar->dtsv_var; if (v->dtdv_type.dtdt_flags & DIF_TF_BYREF) { uintptr_t a = (uintptr_t)svar->dtsv_data; size_t sz = v->dtdv_type.dtdt_size; sz += sizeof (uint64_t); ASSERT(svar->dtsv_size == NCPU * sz); - a += CPU->cpu_id * sz; + a += curcpu * sz; - if (regs[rd] == NULL) { + if (regs[rd] == 0) { *(uint8_t *)a = UINT8_MAX; break; } else { *(uint8_t *)a = 0; a += sizeof (uint64_t); } if (!dtrace_vcanload( (void *)(uintptr_t)regs[rd], &v->dtdv_type, mstate, vstate)) break; dtrace_vcopy((void *)(uintptr_t)regs[rd], (void *)a, &v->dtdv_type); break; } ASSERT(svar->dtsv_size == NCPU * sizeof (uint64_t)); tmp = (uint64_t *)(uintptr_t)svar->dtsv_data; - tmp[CPU->cpu_id] = regs[rd]; + tmp[curcpu] = regs[rd]; break; case DIF_OP_LDTS: { dtrace_dynvar_t *dvar; dtrace_key_t *key; id = DIF_INSTR_VAR(instr); ASSERT(id >= DIF_VAR_OTHER_UBASE); id -= DIF_VAR_OTHER_UBASE; v = &vstate->dtvs_tlocals[id]; key = &tupregs[DIF_DTR_NREGS]; key[0].dttk_value = (uint64_t)id; key[0].dttk_size = 0; DTRACE_TLS_THRKEY(key[1].dttk_value); key[1].dttk_size = 0; dvar = dtrace_dynvar(dstate, 2, key, sizeof (uint64_t), DTRACE_DYNVAR_NOALLOC, mstate, vstate); if (dvar == NULL) { regs[rd] = 0; break; } if (v->dtdv_type.dtdt_flags & DIF_TF_BYREF) { regs[rd] = (uint64_t)(uintptr_t)dvar->dtdv_data; } else { regs[rd] = *((uint64_t *)dvar->dtdv_data); } break; } case DIF_OP_STTS: { dtrace_dynvar_t *dvar; dtrace_key_t *key; id = DIF_INSTR_VAR(instr); ASSERT(id >= DIF_VAR_OTHER_UBASE); id -= DIF_VAR_OTHER_UBASE; key = &tupregs[DIF_DTR_NREGS]; key[0].dttk_value = (uint64_t)id; key[0].dttk_size = 0; DTRACE_TLS_THRKEY(key[1].dttk_value); key[1].dttk_size = 0; v = &vstate->dtvs_tlocals[id]; dvar = dtrace_dynvar(dstate, 2, key, v->dtdv_type.dtdt_size > sizeof (uint64_t) ? v->dtdv_type.dtdt_size : sizeof (uint64_t), regs[rd] ? DTRACE_DYNVAR_ALLOC : DTRACE_DYNVAR_DEALLOC, mstate, vstate); /* * Given that we're storing to thread-local data, * we need to flush our predicate cache. */ - curthread->t_predcache = NULL; + curthread->t_predcache = 0; if (dvar == NULL) break; if (v->dtdv_type.dtdt_flags & DIF_TF_BYREF) { if (!dtrace_vcanload( (void *)(uintptr_t)regs[rd], &v->dtdv_type, mstate, vstate)) break; dtrace_vcopy((void *)(uintptr_t)regs[rd], dvar->dtdv_data, &v->dtdv_type); } else { *((uint64_t *)dvar->dtdv_data) = regs[rd]; } break; } case DIF_OP_SRA: regs[rd] = (int64_t)regs[r1] >> regs[r2]; break; case DIF_OP_CALL: dtrace_dif_subr(DIF_INSTR_SUBR(instr), rd, regs, tupregs, ttop, mstate, state); break; case DIF_OP_PUSHTR: if (ttop == DIF_DTR_NREGS) { *flags |= CPU_DTRACE_TUPOFLOW; break; } if (r1 == DIF_TYPE_STRING) { /* * If this is a string type and the size is 0, * we'll use the system-wide default string * size. Note that we are _not_ looking at * the value of the DTRACEOPT_STRSIZE option; * had this been set, we would expect to have * a non-zero size value in the "pushtr". */ tupregs[ttop].dttk_size = dtrace_strlen((char *)(uintptr_t)regs[rd], regs[r2] ? regs[r2] : dtrace_strsize_default) + 1; } else { tupregs[ttop].dttk_size = regs[r2]; } tupregs[ttop++].dttk_value = regs[rd]; break; case DIF_OP_PUSHTV: if (ttop == DIF_DTR_NREGS) { *flags |= CPU_DTRACE_TUPOFLOW; break; } tupregs[ttop].dttk_value = regs[rd]; tupregs[ttop++].dttk_size = 0; break; case DIF_OP_POPTS: if (ttop != 0) ttop--; break; case DIF_OP_FLUSHTS: ttop = 0; break; case DIF_OP_LDGAA: case DIF_OP_LDTAA: { dtrace_dynvar_t *dvar; dtrace_key_t *key = tupregs; uint_t nkeys = ttop; id = DIF_INSTR_VAR(instr); ASSERT(id >= DIF_VAR_OTHER_UBASE); id -= DIF_VAR_OTHER_UBASE; key[nkeys].dttk_value = (uint64_t)id; key[nkeys++].dttk_size = 0; if (DIF_INSTR_OP(instr) == DIF_OP_LDTAA) { DTRACE_TLS_THRKEY(key[nkeys].dttk_value); key[nkeys++].dttk_size = 0; v = &vstate->dtvs_tlocals[id]; } else { v = &vstate->dtvs_globals[id]->dtsv_var; } dvar = dtrace_dynvar(dstate, nkeys, key, v->dtdv_type.dtdt_size > sizeof (uint64_t) ? v->dtdv_type.dtdt_size : sizeof (uint64_t), DTRACE_DYNVAR_NOALLOC, mstate, vstate); if (dvar == NULL) { regs[rd] = 0; break; } if (v->dtdv_type.dtdt_flags & DIF_TF_BYREF) { regs[rd] = (uint64_t)(uintptr_t)dvar->dtdv_data; } else { regs[rd] = *((uint64_t *)dvar->dtdv_data); } break; } case DIF_OP_STGAA: case DIF_OP_STTAA: { dtrace_dynvar_t *dvar; dtrace_key_t *key = tupregs; uint_t nkeys = ttop; id = DIF_INSTR_VAR(instr); ASSERT(id >= DIF_VAR_OTHER_UBASE); id -= DIF_VAR_OTHER_UBASE; key[nkeys].dttk_value = (uint64_t)id; key[nkeys++].dttk_size = 0; if (DIF_INSTR_OP(instr) == DIF_OP_STTAA) { DTRACE_TLS_THRKEY(key[nkeys].dttk_value); key[nkeys++].dttk_size = 0; v = &vstate->dtvs_tlocals[id]; } else { v = &vstate->dtvs_globals[id]->dtsv_var; } dvar = dtrace_dynvar(dstate, nkeys, key, v->dtdv_type.dtdt_size > sizeof (uint64_t) ? v->dtdv_type.dtdt_size : sizeof (uint64_t), regs[rd] ? DTRACE_DYNVAR_ALLOC : DTRACE_DYNVAR_DEALLOC, mstate, vstate); if (dvar == NULL) break; if (v->dtdv_type.dtdt_flags & DIF_TF_BYREF) { if (!dtrace_vcanload( (void *)(uintptr_t)regs[rd], &v->dtdv_type, mstate, vstate)) break; dtrace_vcopy((void *)(uintptr_t)regs[rd], dvar->dtdv_data, &v->dtdv_type); } else { *((uint64_t *)dvar->dtdv_data) = regs[rd]; } break; } case DIF_OP_ALLOCS: { uintptr_t ptr = P2ROUNDUP(mstate->dtms_scratch_ptr, 8); size_t size = ptr - mstate->dtms_scratch_ptr + regs[r1]; /* * Rounding up the user allocation size could have * overflowed large, bogus allocations (like -1ULL) to * 0. */ if (size < regs[r1] || !DTRACE_INSCRATCH(mstate, size)) { DTRACE_CPUFLAG_SET(CPU_DTRACE_NOSCRATCH); - regs[rd] = NULL; + regs[rd] = 0; break; } dtrace_bzero((void *) mstate->dtms_scratch_ptr, size); mstate->dtms_scratch_ptr += size; regs[rd] = ptr; break; } case DIF_OP_COPYS: if (!dtrace_canstore(regs[rd], regs[r2], mstate, vstate)) { *flags |= CPU_DTRACE_BADADDR; *illval = regs[rd]; break; } if (!dtrace_canload(regs[r1], regs[r2], mstate, vstate)) break; dtrace_bcopy((void *)(uintptr_t)regs[r1], (void *)(uintptr_t)regs[rd], (size_t)regs[r2]); break; case DIF_OP_STB: if (!dtrace_canstore(regs[rd], 1, mstate, vstate)) { *flags |= CPU_DTRACE_BADADDR; *illval = regs[rd]; break; } *((uint8_t *)(uintptr_t)regs[rd]) = (uint8_t)regs[r1]; break; case DIF_OP_STH: if (!dtrace_canstore(regs[rd], 2, mstate, vstate)) { *flags |= CPU_DTRACE_BADADDR; *illval = regs[rd]; break; } if (regs[rd] & 1) { *flags |= CPU_DTRACE_BADALIGN; *illval = regs[rd]; break; } *((uint16_t *)(uintptr_t)regs[rd]) = (uint16_t)regs[r1]; break; case DIF_OP_STW: if (!dtrace_canstore(regs[rd], 4, mstate, vstate)) { *flags |= CPU_DTRACE_BADADDR; *illval = regs[rd]; break; } if (regs[rd] & 3) { *flags |= CPU_DTRACE_BADALIGN; *illval = regs[rd]; break; } *((uint32_t *)(uintptr_t)regs[rd]) = (uint32_t)regs[r1]; break; case DIF_OP_STX: if (!dtrace_canstore(regs[rd], 8, mstate, vstate)) { *flags |= CPU_DTRACE_BADADDR; *illval = regs[rd]; break; } if (regs[rd] & 7) { *flags |= CPU_DTRACE_BADALIGN; *illval = regs[rd]; break; } *((uint64_t *)(uintptr_t)regs[rd]) = regs[r1]; break; } } if (!(*flags & CPU_DTRACE_FAULT)) return (rval); mstate->dtms_fltoffs = opc * sizeof (dif_instr_t); mstate->dtms_present |= DTRACE_MSTATE_FLTOFFS; return (0); } static void dtrace_action_breakpoint(dtrace_ecb_t *ecb) { dtrace_probe_t *probe = ecb->dte_probe; dtrace_provider_t *prov = probe->dtpr_provider; char c[DTRACE_FULLNAMELEN + 80], *str; char *msg = "dtrace: breakpoint action at probe "; char *ecbmsg = " (ecb "; uintptr_t mask = (0xf << (sizeof (uintptr_t) * NBBY / 4)); uintptr_t val = (uintptr_t)ecb; int shift = (sizeof (uintptr_t) * NBBY) - 4, i = 0; if (dtrace_destructive_disallow) return; /* * It's impossible to be taking action on the NULL probe. */ ASSERT(probe != NULL); /* * This is a poor man's (destitute man's?) sprintf(): we want to * print the provider name, module name, function name and name of * the probe, along with the hex address of the ECB with the breakpoint * action -- all of which we must place in the character buffer by * hand. */ while (*msg != '\0') c[i++] = *msg++; for (str = prov->dtpv_name; *str != '\0'; str++) c[i++] = *str; c[i++] = ':'; for (str = probe->dtpr_mod; *str != '\0'; str++) c[i++] = *str; c[i++] = ':'; for (str = probe->dtpr_func; *str != '\0'; str++) c[i++] = *str; c[i++] = ':'; for (str = probe->dtpr_name; *str != '\0'; str++) c[i++] = *str; while (*ecbmsg != '\0') c[i++] = *ecbmsg++; while (shift >= 0) { mask = (uintptr_t)0xf << shift; if (val >= ((uintptr_t)1 << shift)) c[i++] = "0123456789abcdef"[(val & mask) >> shift]; shift -= 4; } c[i++] = ')'; c[i] = '\0'; +#if defined(sun) debug_enter(c); +#else + kdb_enter(KDB_WHY_DTRACE, "breakpoint action"); +#endif } static void dtrace_action_panic(dtrace_ecb_t *ecb) { dtrace_probe_t *probe = ecb->dte_probe; /* * It's impossible to be taking action on the NULL probe. */ ASSERT(probe != NULL); if (dtrace_destructive_disallow) return; if (dtrace_panicked != NULL) return; if (dtrace_casptr(&dtrace_panicked, NULL, curthread) != NULL) return; /* * We won the right to panic. (We want to be sure that only one * thread calls panic() from dtrace_probe(), and that panic() is * called exactly once.) */ dtrace_panic("dtrace: panic action at probe %s:%s:%s:%s (ecb %p)", probe->dtpr_provider->dtpv_name, probe->dtpr_mod, probe->dtpr_func, probe->dtpr_name, (void *)ecb); } static void dtrace_action_raise(uint64_t sig) { if (dtrace_destructive_disallow) return; if (sig >= NSIG) { DTRACE_CPUFLAG_SET(CPU_DTRACE_ILLOP); return; } +#if defined(sun) /* * raise() has a queue depth of 1 -- we ignore all subsequent * invocations of the raise() action. */ if (curthread->t_dtrace_sig == 0) curthread->t_dtrace_sig = (uint8_t)sig; curthread->t_sig_check = 1; aston(curthread); +#else + struct proc *p = curproc; + PROC_LOCK(p); + psignal(p, sig); + PROC_UNLOCK(p); +#endif } static void dtrace_action_stop(void) { if (dtrace_destructive_disallow) return; +#if defined(sun) if (!curthread->t_dtrace_stop) { curthread->t_dtrace_stop = 1; curthread->t_sig_check = 1; aston(curthread); } +#else + struct proc *p = curproc; + PROC_LOCK(p); + psignal(p, SIGSTOP); + PROC_UNLOCK(p); +#endif } static void dtrace_action_chill(dtrace_mstate_t *mstate, hrtime_t val) { hrtime_t now; volatile uint16_t *flags; +#if defined(sun) cpu_t *cpu = CPU; +#else + cpu_t *cpu = &solaris_cpu[curcpu]; +#endif if (dtrace_destructive_disallow) return; flags = (volatile uint16_t *)&cpu_core[cpu->cpu_id].cpuc_dtrace_flags; now = dtrace_gethrtime(); if (now - cpu->cpu_dtrace_chillmark > dtrace_chill_interval) { /* * We need to advance the mark to the current time. */ cpu->cpu_dtrace_chillmark = now; cpu->cpu_dtrace_chilled = 0; } /* * Now check to see if the requested chill time would take us over * the maximum amount of time allowed in the chill interval. (Or * worse, if the calculation itself induces overflow.) */ if (cpu->cpu_dtrace_chilled + val > dtrace_chill_max || cpu->cpu_dtrace_chilled + val < cpu->cpu_dtrace_chilled) { *flags |= CPU_DTRACE_ILLOP; return; } while (dtrace_gethrtime() - now < val) continue; /* * Normally, we assure that the value of the variable "timestamp" does * not change within an ECB. The presence of chill() represents an * exception to this rule, however. */ mstate->dtms_present &= ~DTRACE_MSTATE_TIMESTAMP; cpu->cpu_dtrace_chilled += val; } +#if defined(sun) static void dtrace_action_ustack(dtrace_mstate_t *mstate, dtrace_state_t *state, uint64_t *buf, uint64_t arg) { int nframes = DTRACE_USTACK_NFRAMES(arg); int strsize = DTRACE_USTACK_STRSIZE(arg); uint64_t *pcs = &buf[1], *fps; char *str = (char *)&pcs[nframes]; int size, offs = 0, i, j; uintptr_t old = mstate->dtms_scratch_ptr, saved; - uint16_t *flags = &cpu_core[CPU->cpu_id].cpuc_dtrace_flags; + uint16_t *flags = &cpu_core[curcpu].cpuc_dtrace_flags; char *sym; /* * Should be taking a faster path if string space has not been * allocated. */ ASSERT(strsize != 0); /* * We will first allocate some temporary space for the frame pointers. */ fps = (uint64_t *)P2ROUNDUP(mstate->dtms_scratch_ptr, 8); size = (uintptr_t)fps - mstate->dtms_scratch_ptr + (nframes * sizeof (uint64_t)); if (!DTRACE_INSCRATCH(mstate, size)) { /* * Not enough room for our frame pointers -- need to indicate * that we ran out of scratch space. */ DTRACE_CPUFLAG_SET(CPU_DTRACE_NOSCRATCH); return; } mstate->dtms_scratch_ptr += size; saved = mstate->dtms_scratch_ptr; /* * Now get a stack with both program counters and frame pointers. */ DTRACE_CPUFLAG_SET(CPU_DTRACE_NOFAULT); dtrace_getufpstack(buf, fps, nframes + 1); DTRACE_CPUFLAG_CLEAR(CPU_DTRACE_NOFAULT); /* * If that faulted, we're cooked. */ if (*flags & CPU_DTRACE_FAULT) goto out; /* * Now we want to walk up the stack, calling the USTACK helper. For * each iteration, we restore the scratch pointer. */ for (i = 0; i < nframes; i++) { mstate->dtms_scratch_ptr = saved; if (offs >= strsize) break; sym = (char *)(uintptr_t)dtrace_helper( DTRACE_HELPER_ACTION_USTACK, mstate, state, pcs[i], fps[i]); /* * If we faulted while running the helper, we're going to * clear the fault and null out the corresponding string. */ if (*flags & CPU_DTRACE_FAULT) { *flags &= ~CPU_DTRACE_FAULT; str[offs++] = '\0'; continue; } if (sym == NULL) { str[offs++] = '\0'; continue; } DTRACE_CPUFLAG_SET(CPU_DTRACE_NOFAULT); /* * Now copy in the string that the helper returned to us. */ for (j = 0; offs + j < strsize; j++) { if ((str[offs + j] = sym[j]) == '\0') break; } DTRACE_CPUFLAG_CLEAR(CPU_DTRACE_NOFAULT); offs += j + 1; } if (offs >= strsize) { /* * If we didn't have room for all of the strings, we don't * abort processing -- this needn't be a fatal error -- but we * still want to increment a counter (dts_stkstroverflows) to * allow this condition to be warned about. (If this is from * a jstack() action, it is easily tuned via jstackstrsize.) */ dtrace_error(&state->dts_stkstroverflows); } while (offs < strsize) str[offs++] = '\0'; out: mstate->dtms_scratch_ptr = old; } +#endif /* * If you're looking for the epicenter of DTrace, you just found it. This * is the function called by the provider to fire a probe -- from which all * subsequent probe-context DTrace activity emanates. */ void dtrace_probe(dtrace_id_t id, uintptr_t arg0, uintptr_t arg1, uintptr_t arg2, uintptr_t arg3, uintptr_t arg4) { processorid_t cpuid; dtrace_icookie_t cookie; dtrace_probe_t *probe; dtrace_mstate_t mstate; dtrace_ecb_t *ecb; dtrace_action_t *act; intptr_t offs; size_t size; int vtime, onintr; volatile uint16_t *flags; hrtime_t now; +#if defined(sun) /* * Kick out immediately if this CPU is still being born (in which case * curthread will be set to -1) or the current thread can't allow * probes in its current context. */ if (((uintptr_t)curthread & 1) || (curthread->t_flag & T_DONTDTRACE)) return; +#endif cookie = dtrace_interrupt_disable(); probe = dtrace_probes[id - 1]; - cpuid = CPU->cpu_id; + cpuid = curcpu; onintr = CPU_ON_INTR(CPU); if (!onintr && probe->dtpr_predcache != DTRACE_CACHEIDNONE && probe->dtpr_predcache == curthread->t_predcache) { /* * We have hit in the predicate cache; we know that * this predicate would evaluate to be false. */ dtrace_interrupt_enable(cookie); return; } +#if defined(sun) if (panic_quiesce) { +#else + if (panicstr != NULL) { +#endif /* * We don't trace anything if we're panicking. */ dtrace_interrupt_enable(cookie); return; } now = dtrace_gethrtime(); vtime = dtrace_vtime_references != 0; if (vtime && curthread->t_dtrace_start) curthread->t_dtrace_vtime += now - curthread->t_dtrace_start; mstate.dtms_difo = NULL; mstate.dtms_probe = probe; - mstate.dtms_strtok = NULL; + mstate.dtms_strtok = 0; mstate.dtms_arg[0] = arg0; mstate.dtms_arg[1] = arg1; mstate.dtms_arg[2] = arg2; mstate.dtms_arg[3] = arg3; mstate.dtms_arg[4] = arg4; flags = (volatile uint16_t *)&cpu_core[cpuid].cpuc_dtrace_flags; for (ecb = probe->dtpr_ecb; ecb != NULL; ecb = ecb->dte_next) { dtrace_predicate_t *pred = ecb->dte_predicate; dtrace_state_t *state = ecb->dte_state; dtrace_buffer_t *buf = &state->dts_buffer[cpuid]; dtrace_buffer_t *aggbuf = &state->dts_aggbuffer[cpuid]; dtrace_vstate_t *vstate = &state->dts_vstate; dtrace_provider_t *prov = probe->dtpr_provider; int committed = 0; caddr_t tomax; /* * A little subtlety with the following (seemingly innocuous) * declaration of the automatic 'val': by looking at the * code, you might think that it could be declared in the * action processing loop, below. (That is, it's only used in * the action processing loop.) However, it must be declared * out of that scope because in the case of DIF expression * arguments to aggregating actions, one iteration of the * action loop will use the last iteration's value. */ -#ifdef lint uint64_t val = 0; -#else - uint64_t val; -#endif mstate.dtms_present = DTRACE_MSTATE_ARGS | DTRACE_MSTATE_PROBE; *flags &= ~CPU_DTRACE_ERROR; if (prov == dtrace_provider) { /* * If dtrace itself is the provider of this probe, * we're only going to continue processing the ECB if * arg0 (the dtrace_state_t) is equal to the ECB's * creating state. (This prevents disjoint consumers * from seeing one another's metaprobes.) */ if (arg0 != (uint64_t)(uintptr_t)state) continue; } if (state->dts_activity != DTRACE_ACTIVITY_ACTIVE) { /* * We're not currently active. If our provider isn't * the dtrace pseudo provider, we're not interested. */ if (prov != dtrace_provider) continue; /* * Now we must further check if we are in the BEGIN * probe. If we are, we will only continue processing * if we're still in WARMUP -- if one BEGIN enabling * has invoked the exit() action, we don't want to * evaluate subsequent BEGIN enablings. */ if (probe->dtpr_id == dtrace_probeid_begin && state->dts_activity != DTRACE_ACTIVITY_WARMUP) { ASSERT(state->dts_activity == DTRACE_ACTIVITY_DRAINING); continue; } } if (ecb->dte_cond) { /* * If the dte_cond bits indicate that this * consumer is only allowed to see user-mode firings * of this probe, call the provider's dtps_usermode() * entry point to check that the probe was fired * while in a user context. Skip this ECB if that's * not the case. */ if ((ecb->dte_cond & DTRACE_COND_USERMODE) && prov->dtpv_pops.dtps_usermode(prov->dtpv_arg, probe->dtpr_id, probe->dtpr_arg) == 0) continue; +#if defined(sun) /* * This is more subtle than it looks. We have to be * absolutely certain that CRED() isn't going to * change out from under us so it's only legit to * examine that structure if we're in constrained * situations. Currently, the only times we'll this * check is if a non-super-user has enabled the * profile or syscall providers -- providers that * allow visibility of all processes. For the * profile case, the check above will ensure that * we're examining a user context. */ if (ecb->dte_cond & DTRACE_COND_OWNER) { cred_t *cr; cred_t *s_cr = ecb->dte_state->dts_cred.dcr_cred; proc_t *proc; ASSERT(s_cr != NULL); if ((cr = CRED()) == NULL || s_cr->cr_uid != cr->cr_uid || s_cr->cr_uid != cr->cr_ruid || s_cr->cr_uid != cr->cr_suid || s_cr->cr_gid != cr->cr_gid || s_cr->cr_gid != cr->cr_rgid || s_cr->cr_gid != cr->cr_sgid || (proc = ttoproc(curthread)) == NULL || (proc->p_flag & SNOCD)) continue; } if (ecb->dte_cond & DTRACE_COND_ZONEOWNER) { cred_t *cr; cred_t *s_cr = ecb->dte_state->dts_cred.dcr_cred; ASSERT(s_cr != NULL); if ((cr = CRED()) == NULL || s_cr->cr_zone->zone_id != cr->cr_zone->zone_id) continue; } +#endif } if (now - state->dts_alive > dtrace_deadman_timeout) { /* * We seem to be dead. Unless we (a) have kernel * destructive permissions (b) have expicitly enabled * destructive actions and (c) destructive actions have * not been disabled, we're going to transition into * the KILLED state, from which no further processing * on this state will be performed. */ if (!dtrace_priv_kernel_destructive(state) || !state->dts_cred.dcr_destructive || dtrace_destructive_disallow) { void *activity = &state->dts_activity; dtrace_activity_t current; do { current = state->dts_activity; } while (dtrace_cas32(activity, current, DTRACE_ACTIVITY_KILLED) != current); continue; } } if ((offs = dtrace_buffer_reserve(buf, ecb->dte_needed, ecb->dte_alignment, state, &mstate)) < 0) continue; tomax = buf->dtb_tomax; ASSERT(tomax != NULL); if (ecb->dte_size != 0) DTRACE_STORE(uint32_t, tomax, offs, ecb->dte_epid); mstate.dtms_epid = ecb->dte_epid; mstate.dtms_present |= DTRACE_MSTATE_EPID; if (state->dts_cred.dcr_visible & DTRACE_CRV_KERNEL) mstate.dtms_access = DTRACE_ACCESS_KERNEL; else mstate.dtms_access = 0; if (pred != NULL) { dtrace_difo_t *dp = pred->dtp_difo; int rval; rval = dtrace_dif_emulate(dp, &mstate, vstate, state); if (!(*flags & CPU_DTRACE_ERROR) && !rval) { dtrace_cacheid_t cid = probe->dtpr_predcache; if (cid != DTRACE_CACHEIDNONE && !onintr) { /* * Update the predicate cache... */ ASSERT(cid == pred->dtp_cacheid); curthread->t_predcache = cid; } continue; } } for (act = ecb->dte_action; !(*flags & CPU_DTRACE_ERROR) && act != NULL; act = act->dta_next) { size_t valoffs; dtrace_difo_t *dp; dtrace_recdesc_t *rec = &act->dta_rec; size = rec->dtrd_size; valoffs = offs + rec->dtrd_offset; if (DTRACEACT_ISAGG(act->dta_kind)) { uint64_t v = 0xbad; dtrace_aggregation_t *agg; agg = (dtrace_aggregation_t *)act; if ((dp = act->dta_difo) != NULL) v = dtrace_dif_emulate(dp, &mstate, vstate, state); if (*flags & CPU_DTRACE_ERROR) continue; /* * Note that we always pass the expression * value from the previous iteration of the * action loop. This value will only be used * if there is an expression argument to the * aggregating action, denoted by the * dtag_hasarg field. */ dtrace_aggregate(agg, buf, offs, aggbuf, v, val); continue; } switch (act->dta_kind) { case DTRACEACT_STOP: if (dtrace_priv_proc_destructive(state)) dtrace_action_stop(); continue; case DTRACEACT_BREAKPOINT: if (dtrace_priv_kernel_destructive(state)) dtrace_action_breakpoint(ecb); continue; case DTRACEACT_PANIC: if (dtrace_priv_kernel_destructive(state)) dtrace_action_panic(ecb); continue; case DTRACEACT_STACK: if (!dtrace_priv_kernel(state)) continue; dtrace_getpcstack((pc_t *)(tomax + valoffs), size / sizeof (pc_t), probe->dtpr_aframes, DTRACE_ANCHORED(probe) ? NULL : (uint32_t *)arg0); - continue; +#if defined(sun) case DTRACEACT_JSTACK: case DTRACEACT_USTACK: if (!dtrace_priv_proc(state)) continue; /* * See comment in DIF_VAR_PID. */ if (DTRACE_ANCHORED(mstate.dtms_probe) && CPU_ON_INTR(CPU)) { int depth = DTRACE_USTACK_NFRAMES( rec->dtrd_arg) + 1; dtrace_bzero((void *)(tomax + valoffs), DTRACE_USTACK_STRSIZE(rec->dtrd_arg) + depth * sizeof (uint64_t)); continue; } if (DTRACE_USTACK_STRSIZE(rec->dtrd_arg) != 0 && curproc->p_dtrace_helpers != NULL) { /* * This is the slow path -- we have * allocated string space, and we're * getting the stack of a process that * has helpers. Call into a separate * routine to perform this processing. */ dtrace_action_ustack(&mstate, state, (uint64_t *)(tomax + valoffs), rec->dtrd_arg); continue; } DTRACE_CPUFLAG_SET(CPU_DTRACE_NOFAULT); dtrace_getupcstack((uint64_t *) (tomax + valoffs), DTRACE_USTACK_NFRAMES(rec->dtrd_arg) + 1); DTRACE_CPUFLAG_CLEAR(CPU_DTRACE_NOFAULT); continue; +#endif default: break; } dp = act->dta_difo; ASSERT(dp != NULL); val = dtrace_dif_emulate(dp, &mstate, vstate, state); if (*flags & CPU_DTRACE_ERROR) continue; switch (act->dta_kind) { case DTRACEACT_SPECULATE: ASSERT(buf == &state->dts_buffer[cpuid]); buf = dtrace_speculation_buffer(state, cpuid, val); if (buf == NULL) { *flags |= CPU_DTRACE_DROP; continue; } offs = dtrace_buffer_reserve(buf, ecb->dte_needed, ecb->dte_alignment, state, NULL); if (offs < 0) { *flags |= CPU_DTRACE_DROP; continue; } tomax = buf->dtb_tomax; ASSERT(tomax != NULL); if (ecb->dte_size != 0) DTRACE_STORE(uint32_t, tomax, offs, ecb->dte_epid); continue; + case DTRACEACT_PRINTM: { + /* The DIF returns a 'memref'. */ + uintptr_t *memref = (uintptr_t *)(uintptr_t) val; + + /* Get the size from the memref. */ + size = memref[1]; + + /* + * Check if the size exceeds the allocated + * buffer size. + */ + if (size + sizeof(uintptr_t) > dp->dtdo_rtype.dtdt_size) { + /* Flag a drop! */ + *flags |= CPU_DTRACE_DROP; + continue; + } + + /* Store the size in the buffer first. */ + DTRACE_STORE(uintptr_t, tomax, + valoffs, size); + + /* + * Offset the buffer address to the start + * of the data. + */ + valoffs += sizeof(uintptr_t); + + /* + * Reset to the memory address rather than + * the memref array, then let the BYREF + * code below do the work to store the + * memory data in the buffer. + */ + val = memref[0]; + break; + } + + case DTRACEACT_PRINTT: { + /* The DIF returns a 'typeref'. */ + uintptr_t *typeref = (uintptr_t *)(uintptr_t) val; + char c = '\0' + 1; + size_t s; + + /* + * Get the type string length and round it + * up so that the data that follows is + * aligned for easy access. + */ + size_t typs = strlen((char *) typeref[2]) + 1; + typs = roundup(typs, sizeof(uintptr_t)); + + /* + *Get the size from the typeref using the + * number of elements and the type size. + */ + size = typeref[1] * typeref[3]; + + /* + * Check if the size exceeds the allocated + * buffer size. + */ + if (size + typs + 2 * sizeof(uintptr_t) > dp->dtdo_rtype.dtdt_size) { + /* Flag a drop! */ + *flags |= CPU_DTRACE_DROP; + + } + + /* Store the size in the buffer first. */ + DTRACE_STORE(uintptr_t, tomax, + valoffs, size); + valoffs += sizeof(uintptr_t); + + /* Store the type size in the buffer. */ + DTRACE_STORE(uintptr_t, tomax, + valoffs, typeref[3]); + valoffs += sizeof(uintptr_t); + + val = typeref[2]; + + for (s = 0; s < typs; s++) { + if (c != '\0') + c = dtrace_load8(val++); + + DTRACE_STORE(uint8_t, tomax, + valoffs++, c); + } + + /* + * Reset to the memory address rather than + * the typeref array, then let the BYREF + * code below do the work to store the + * memory data in the buffer. + */ + val = typeref[0]; + break; + } + case DTRACEACT_CHILL: if (dtrace_priv_kernel_destructive(state)) dtrace_action_chill(&mstate, val); continue; case DTRACEACT_RAISE: if (dtrace_priv_proc_destructive(state)) dtrace_action_raise(val); continue; case DTRACEACT_COMMIT: ASSERT(!committed); /* * We need to commit our buffer state. */ if (ecb->dte_size) buf->dtb_offset = offs + ecb->dte_size; buf = &state->dts_buffer[cpuid]; dtrace_speculation_commit(state, cpuid, val); committed = 1; continue; case DTRACEACT_DISCARD: dtrace_speculation_discard(state, cpuid, val); continue; case DTRACEACT_DIFEXPR: case DTRACEACT_LIBACT: case DTRACEACT_PRINTF: case DTRACEACT_PRINTA: case DTRACEACT_SYSTEM: case DTRACEACT_FREOPEN: break; case DTRACEACT_SYM: case DTRACEACT_MOD: if (!dtrace_priv_kernel(state)) continue; break; case DTRACEACT_USYM: case DTRACEACT_UMOD: case DTRACEACT_UADDR: { +#if defined(sun) struct pid *pid = curthread->t_procp->p_pidp; +#endif if (!dtrace_priv_proc(state)) continue; DTRACE_STORE(uint64_t, tomax, +#if defined(sun) valoffs, (uint64_t)pid->pid_id); +#else + valoffs, (uint64_t) curproc->p_pid); +#endif DTRACE_STORE(uint64_t, tomax, valoffs + sizeof (uint64_t), val); continue; } case DTRACEACT_EXIT: { /* * For the exit action, we are going to attempt * to atomically set our activity to be * draining. If this fails (either because * another CPU has beat us to the exit action, * or because our current activity is something * other than ACTIVE or WARMUP), we will * continue. This assures that the exit action * can be successfully recorded at most once * when we're in the ACTIVE state. If we're * encountering the exit() action while in * COOLDOWN, however, we want to honor the new * status code. (We know that we're the only * thread in COOLDOWN, so there is no race.) */ void *activity = &state->dts_activity; dtrace_activity_t current = state->dts_activity; if (current == DTRACE_ACTIVITY_COOLDOWN) break; if (current != DTRACE_ACTIVITY_WARMUP) current = DTRACE_ACTIVITY_ACTIVE; if (dtrace_cas32(activity, current, DTRACE_ACTIVITY_DRAINING) != current) { *flags |= CPU_DTRACE_DROP; continue; } break; } default: ASSERT(0); } if (dp->dtdo_rtype.dtdt_flags & DIF_TF_BYREF) { uintptr_t end = valoffs + size; if (!dtrace_vcanload((void *)(uintptr_t)val, &dp->dtdo_rtype, &mstate, vstate)) continue; /* * If this is a string, we're going to only * load until we find the zero byte -- after * which we'll store zero bytes. */ if (dp->dtdo_rtype.dtdt_kind == DIF_TYPE_STRING) { char c = '\0' + 1; int intuple = act->dta_intuple; size_t s; for (s = 0; s < size; s++) { if (c != '\0') c = dtrace_load8(val++); DTRACE_STORE(uint8_t, tomax, valoffs++, c); if (c == '\0' && intuple) break; } continue; } while (valoffs < end) { DTRACE_STORE(uint8_t, tomax, valoffs++, dtrace_load8(val++)); } continue; } switch (size) { case 0: break; case sizeof (uint8_t): DTRACE_STORE(uint8_t, tomax, valoffs, val); break; case sizeof (uint16_t): DTRACE_STORE(uint16_t, tomax, valoffs, val); break; case sizeof (uint32_t): DTRACE_STORE(uint32_t, tomax, valoffs, val); break; case sizeof (uint64_t): DTRACE_STORE(uint64_t, tomax, valoffs, val); break; default: /* * Any other size should have been returned by * reference, not by value. */ ASSERT(0); break; } } if (*flags & CPU_DTRACE_DROP) continue; if (*flags & CPU_DTRACE_FAULT) { int ndx; dtrace_action_t *err; buf->dtb_errors++; if (probe->dtpr_id == dtrace_probeid_error) { /* * There's nothing we can do -- we had an * error on the error probe. We bump an * error counter to at least indicate that * this condition happened. */ dtrace_error(&state->dts_dblerrors); continue; } if (vtime) { /* * Before recursing on dtrace_probe(), we * need to explicitly clear out our start * time to prevent it from being accumulated * into t_dtrace_vtime. */ curthread->t_dtrace_start = 0; } /* * Iterate over the actions to figure out which action * we were processing when we experienced the error. * Note that act points _past_ the faulting action; if * act is ecb->dte_action, the fault was in the * predicate, if it's ecb->dte_action->dta_next it's * in action #1, and so on. */ for (err = ecb->dte_action, ndx = 0; err != act; err = err->dta_next, ndx++) continue; dtrace_probe_error(state, ecb->dte_epid, ndx, (mstate.dtms_present & DTRACE_MSTATE_FLTOFFS) ? mstate.dtms_fltoffs : -1, DTRACE_FLAGS2FLT(*flags), cpu_core[cpuid].cpuc_dtrace_illval); continue; } if (!committed) buf->dtb_offset = offs + ecb->dte_size; } if (vtime) curthread->t_dtrace_start = dtrace_gethrtime(); dtrace_interrupt_enable(cookie); } /* * DTrace Probe Hashing Functions * * The functions in this section (and indeed, the functions in remaining * sections) are not _called_ from probe context. (Any exceptions to this are * marked with a "Note:".) Rather, they are called from elsewhere in the * DTrace framework to look-up probes in, add probes to and remove probes from * the DTrace probe hashes. (Each probe is hashed by each element of the * probe tuple -- allowing for fast lookups, regardless of what was * specified.) */ static uint_t -dtrace_hash_str(char *p) +dtrace_hash_str(const char *p) { unsigned int g; uint_t hval = 0; while (*p) { hval = (hval << 4) + *p++; if ((g = (hval & 0xf0000000)) != 0) hval ^= g >> 24; hval &= ~g; } return (hval); } static dtrace_hash_t * dtrace_hash_create(uintptr_t stroffs, uintptr_t nextoffs, uintptr_t prevoffs) { dtrace_hash_t *hash = kmem_zalloc(sizeof (dtrace_hash_t), KM_SLEEP); hash->dth_stroffs = stroffs; hash->dth_nextoffs = nextoffs; hash->dth_prevoffs = prevoffs; hash->dth_size = 1; hash->dth_mask = hash->dth_size - 1; hash->dth_tab = kmem_zalloc(hash->dth_size * sizeof (dtrace_hashbucket_t *), KM_SLEEP); return (hash); } static void dtrace_hash_destroy(dtrace_hash_t *hash) { #ifdef DEBUG int i; for (i = 0; i < hash->dth_size; i++) ASSERT(hash->dth_tab[i] == NULL); #endif kmem_free(hash->dth_tab, hash->dth_size * sizeof (dtrace_hashbucket_t *)); kmem_free(hash, sizeof (dtrace_hash_t)); } static void dtrace_hash_resize(dtrace_hash_t *hash) { int size = hash->dth_size, i, ndx; int new_size = hash->dth_size << 1; int new_mask = new_size - 1; dtrace_hashbucket_t **new_tab, *bucket, *next; ASSERT((new_size & new_mask) == 0); new_tab = kmem_zalloc(new_size * sizeof (void *), KM_SLEEP); for (i = 0; i < size; i++) { for (bucket = hash->dth_tab[i]; bucket != NULL; bucket = next) { dtrace_probe_t *probe = bucket->dthb_chain; ASSERT(probe != NULL); ndx = DTRACE_HASHSTR(hash, probe) & new_mask; next = bucket->dthb_next; bucket->dthb_next = new_tab[ndx]; new_tab[ndx] = bucket; } } kmem_free(hash->dth_tab, hash->dth_size * sizeof (void *)); hash->dth_tab = new_tab; hash->dth_size = new_size; hash->dth_mask = new_mask; } static void dtrace_hash_add(dtrace_hash_t *hash, dtrace_probe_t *new) { int hashval = DTRACE_HASHSTR(hash, new); int ndx = hashval & hash->dth_mask; dtrace_hashbucket_t *bucket = hash->dth_tab[ndx]; dtrace_probe_t **nextp, **prevp; for (; bucket != NULL; bucket = bucket->dthb_next) { if (DTRACE_HASHEQ(hash, bucket->dthb_chain, new)) goto add; } if ((hash->dth_nbuckets >> 1) > hash->dth_size) { dtrace_hash_resize(hash); dtrace_hash_add(hash, new); return; } bucket = kmem_zalloc(sizeof (dtrace_hashbucket_t), KM_SLEEP); bucket->dthb_next = hash->dth_tab[ndx]; hash->dth_tab[ndx] = bucket; hash->dth_nbuckets++; add: nextp = DTRACE_HASHNEXT(hash, new); ASSERT(*nextp == NULL && *(DTRACE_HASHPREV(hash, new)) == NULL); *nextp = bucket->dthb_chain; if (bucket->dthb_chain != NULL) { prevp = DTRACE_HASHPREV(hash, bucket->dthb_chain); ASSERT(*prevp == NULL); *prevp = new; } bucket->dthb_chain = new; bucket->dthb_len++; } static dtrace_probe_t * dtrace_hash_lookup(dtrace_hash_t *hash, dtrace_probe_t *template) { int hashval = DTRACE_HASHSTR(hash, template); int ndx = hashval & hash->dth_mask; dtrace_hashbucket_t *bucket = hash->dth_tab[ndx]; for (; bucket != NULL; bucket = bucket->dthb_next) { if (DTRACE_HASHEQ(hash, bucket->dthb_chain, template)) return (bucket->dthb_chain); } return (NULL); } static int dtrace_hash_collisions(dtrace_hash_t *hash, dtrace_probe_t *template) { int hashval = DTRACE_HASHSTR(hash, template); int ndx = hashval & hash->dth_mask; dtrace_hashbucket_t *bucket = hash->dth_tab[ndx]; for (; bucket != NULL; bucket = bucket->dthb_next) { if (DTRACE_HASHEQ(hash, bucket->dthb_chain, template)) return (bucket->dthb_len); } - return (NULL); + return (0); } static void dtrace_hash_remove(dtrace_hash_t *hash, dtrace_probe_t *probe) { int ndx = DTRACE_HASHSTR(hash, probe) & hash->dth_mask; dtrace_hashbucket_t *bucket = hash->dth_tab[ndx]; dtrace_probe_t **prevp = DTRACE_HASHPREV(hash, probe); dtrace_probe_t **nextp = DTRACE_HASHNEXT(hash, probe); /* * Find the bucket that we're removing this probe from. */ for (; bucket != NULL; bucket = bucket->dthb_next) { if (DTRACE_HASHEQ(hash, bucket->dthb_chain, probe)) break; } ASSERT(bucket != NULL); if (*prevp == NULL) { if (*nextp == NULL) { /* * The removed probe was the only probe on this * bucket; we need to remove the bucket. */ dtrace_hashbucket_t *b = hash->dth_tab[ndx]; ASSERT(bucket->dthb_chain == probe); ASSERT(b != NULL); if (b == bucket) { hash->dth_tab[ndx] = bucket->dthb_next; } else { while (b->dthb_next != bucket) b = b->dthb_next; b->dthb_next = bucket->dthb_next; } ASSERT(hash->dth_nbuckets > 0); hash->dth_nbuckets--; kmem_free(bucket, sizeof (dtrace_hashbucket_t)); return; } bucket->dthb_chain = *nextp; } else { *(DTRACE_HASHNEXT(hash, *prevp)) = *nextp; } if (*nextp != NULL) *(DTRACE_HASHPREV(hash, *nextp)) = *prevp; } /* * DTrace Utility Functions * * These are random utility functions that are _not_ called from probe context. */ static int dtrace_badattr(const dtrace_attribute_t *a) { return (a->dtat_name > DTRACE_STABILITY_MAX || a->dtat_data > DTRACE_STABILITY_MAX || a->dtat_class > DTRACE_CLASS_MAX); } /* * Return a duplicate copy of a string. If the specified string is NULL, * this function returns a zero-length string. */ static char * dtrace_strdup(const char *str) { char *new = kmem_zalloc((str != NULL ? strlen(str) : 0) + 1, KM_SLEEP); if (str != NULL) (void) strcpy(new, str); return (new); } #define DTRACE_ISALPHA(c) \ (((c) >= 'a' && (c) <= 'z') || ((c) >= 'A' && (c) <= 'Z')) static int dtrace_badname(const char *s) { char c; if (s == NULL || (c = *s++) == '\0') return (0); if (!DTRACE_ISALPHA(c) && c != '-' && c != '_' && c != '.') return (1); while ((c = *s++) != '\0') { if (!DTRACE_ISALPHA(c) && (c < '0' || c > '9') && c != '-' && c != '_' && c != '.' && c != '`') return (1); } return (0); } static void dtrace_cred2priv(cred_t *cr, uint32_t *privp, uid_t *uidp, zoneid_t *zoneidp) { uint32_t priv; +#if defined(sun) if (cr == NULL || PRIV_POLICY_ONLY(cr, PRIV_ALL, B_FALSE)) { /* * For DTRACE_PRIV_ALL, the uid and zoneid don't matter. */ priv = DTRACE_PRIV_ALL; } else { *uidp = crgetuid(cr); *zoneidp = crgetzoneid(cr); priv = 0; if (PRIV_POLICY_ONLY(cr, PRIV_DTRACE_KERNEL, B_FALSE)) priv |= DTRACE_PRIV_KERNEL | DTRACE_PRIV_USER; else if (PRIV_POLICY_ONLY(cr, PRIV_DTRACE_USER, B_FALSE)) priv |= DTRACE_PRIV_USER; if (PRIV_POLICY_ONLY(cr, PRIV_DTRACE_PROC, B_FALSE)) priv |= DTRACE_PRIV_PROC; if (PRIV_POLICY_ONLY(cr, PRIV_PROC_OWNER, B_FALSE)) priv |= DTRACE_PRIV_OWNER; if (PRIV_POLICY_ONLY(cr, PRIV_PROC_ZONE, B_FALSE)) priv |= DTRACE_PRIV_ZONEOWNER; } +#else + priv = DTRACE_PRIV_ALL; +#endif *privp = priv; } #ifdef DTRACE_ERRDEBUG static void dtrace_errdebug(const char *str) { - int hval = dtrace_hash_str((char *)str) % DTRACE_ERRHASHSZ; + int hval = dtrace_hash_str(str) % DTRACE_ERRHASHSZ; int occupied = 0; mutex_enter(&dtrace_errlock); dtrace_errlast = str; dtrace_errthread = curthread; while (occupied++ < DTRACE_ERRHASHSZ) { if (dtrace_errhash[hval].dter_msg == str) { dtrace_errhash[hval].dter_count++; goto out; } if (dtrace_errhash[hval].dter_msg != NULL) { hval = (hval + 1) % DTRACE_ERRHASHSZ; continue; } dtrace_errhash[hval].dter_msg = str; dtrace_errhash[hval].dter_count = 1; goto out; } panic("dtrace: undersized error hash"); out: mutex_exit(&dtrace_errlock); } #endif /* * DTrace Matching Functions * * These functions are used to match groups of probes, given some elements of * a probe tuple, or some globbed expressions for elements of a probe tuple. */ static int dtrace_match_priv(const dtrace_probe_t *prp, uint32_t priv, uid_t uid, zoneid_t zoneid) { if (priv != DTRACE_PRIV_ALL) { uint32_t ppriv = prp->dtpr_provider->dtpv_priv.dtpp_flags; uint32_t match = priv & ppriv; /* * No PRIV_DTRACE_* privileges... */ if ((priv & (DTRACE_PRIV_PROC | DTRACE_PRIV_USER | DTRACE_PRIV_KERNEL)) == 0) return (0); /* * No matching bits, but there were bits to match... */ if (match == 0 && ppriv != 0) return (0); /* * Need to have permissions to the process, but don't... */ if (((ppriv & ~match) & DTRACE_PRIV_OWNER) != 0 && uid != prp->dtpr_provider->dtpv_priv.dtpp_uid) { return (0); } /* * Need to be in the same zone unless we possess the * privilege to examine all zones. */ if (((ppriv & ~match) & DTRACE_PRIV_ZONEOWNER) != 0 && zoneid != prp->dtpr_provider->dtpv_priv.dtpp_zoneid) { return (0); } } return (1); } /* * dtrace_match_probe compares a dtrace_probe_t to a pre-compiled key, which * consists of input pattern strings and an ops-vector to evaluate them. * This function returns >0 for match, 0 for no match, and <0 for error. */ static int dtrace_match_probe(const dtrace_probe_t *prp, const dtrace_probekey_t *pkp, uint32_t priv, uid_t uid, zoneid_t zoneid) { dtrace_provider_t *pvp = prp->dtpr_provider; int rv; if (pvp->dtpv_defunct) return (0); if ((rv = pkp->dtpk_pmatch(pvp->dtpv_name, pkp->dtpk_prov, 0)) <= 0) return (rv); if ((rv = pkp->dtpk_mmatch(prp->dtpr_mod, pkp->dtpk_mod, 0)) <= 0) return (rv); if ((rv = pkp->dtpk_fmatch(prp->dtpr_func, pkp->dtpk_func, 0)) <= 0) return (rv); if ((rv = pkp->dtpk_nmatch(prp->dtpr_name, pkp->dtpk_name, 0)) <= 0) return (rv); if (dtrace_match_priv(prp, priv, uid, zoneid) == 0) return (0); return (rv); } /* * dtrace_match_glob() is a safe kernel implementation of the gmatch(3GEN) * interface for matching a glob pattern 'p' to an input string 's'. Unlike * libc's version, the kernel version only applies to 8-bit ASCII strings. * In addition, all of the recursion cases except for '*' matching have been * unwound. For '*', we still implement recursive evaluation, but a depth * counter is maintained and matching is aborted if we recurse too deep. * The function returns 0 if no match, >0 if match, and <0 if recursion error. */ static int dtrace_match_glob(const char *s, const char *p, int depth) { const char *olds; char s1, c; int gs; if (depth > DTRACE_PROBEKEY_MAXDEPTH) return (-1); if (s == NULL) s = ""; /* treat NULL as empty string */ top: olds = s; s1 = *s++; if (p == NULL) return (0); if ((c = *p++) == '\0') return (s1 == '\0'); switch (c) { case '[': { int ok = 0, notflag = 0; char lc = '\0'; if (s1 == '\0') return (0); if (*p == '!') { notflag = 1; p++; } if ((c = *p++) == '\0') return (0); do { if (c == '-' && lc != '\0' && *p != ']') { if ((c = *p++) == '\0') return (0); if (c == '\\' && (c = *p++) == '\0') return (0); if (notflag) { if (s1 < lc || s1 > c) ok++; else return (0); } else if (lc <= s1 && s1 <= c) ok++; } else if (c == '\\' && (c = *p++) == '\0') return (0); lc = c; /* save left-hand 'c' for next iteration */ if (notflag) { if (s1 != c) ok++; else return (0); } else if (s1 == c) ok++; if ((c = *p++) == '\0') return (0); } while (c != ']'); if (ok) goto top; return (0); } case '\\': if ((c = *p++) == '\0') return (0); /*FALLTHRU*/ default: if (c != s1) return (0); /*FALLTHRU*/ case '?': if (s1 != '\0') goto top; return (0); case '*': while (*p == '*') p++; /* consecutive *'s are identical to a single one */ if (*p == '\0') return (1); for (s = olds; *s != '\0'; s++) { if ((gs = dtrace_match_glob(s, p, depth + 1)) != 0) return (gs); } return (0); } } /*ARGSUSED*/ static int dtrace_match_string(const char *s, const char *p, int depth) { return (s != NULL && strcmp(s, p) == 0); } /*ARGSUSED*/ static int dtrace_match_nul(const char *s, const char *p, int depth) { return (1); /* always match the empty pattern */ } /*ARGSUSED*/ static int dtrace_match_nonzero(const char *s, const char *p, int depth) { return (s != NULL && s[0] != '\0'); } static int dtrace_match(const dtrace_probekey_t *pkp, uint32_t priv, uid_t uid, zoneid_t zoneid, int (*matched)(dtrace_probe_t *, void *), void *arg) { dtrace_probe_t template, *probe; dtrace_hash_t *hash = NULL; int len, best = INT_MAX, nmatched = 0; dtrace_id_t i; ASSERT(MUTEX_HELD(&dtrace_lock)); /* * If the probe ID is specified in the key, just lookup by ID and * invoke the match callback once if a matching probe is found. */ if (pkp->dtpk_id != DTRACE_IDNONE) { if ((probe = dtrace_probe_lookup_id(pkp->dtpk_id)) != NULL && dtrace_match_probe(probe, pkp, priv, uid, zoneid) > 0) { (void) (*matched)(probe, arg); nmatched++; } return (nmatched); } template.dtpr_mod = (char *)pkp->dtpk_mod; template.dtpr_func = (char *)pkp->dtpk_func; template.dtpr_name = (char *)pkp->dtpk_name; /* * We want to find the most distinct of the module name, function * name, and name. So for each one that is not a glob pattern or * empty string, we perform a lookup in the corresponding hash and * use the hash table with the fewest collisions to do our search. */ if (pkp->dtpk_mmatch == &dtrace_match_string && (len = dtrace_hash_collisions(dtrace_bymod, &template)) < best) { best = len; hash = dtrace_bymod; } if (pkp->dtpk_fmatch == &dtrace_match_string && (len = dtrace_hash_collisions(dtrace_byfunc, &template)) < best) { best = len; hash = dtrace_byfunc; } if (pkp->dtpk_nmatch == &dtrace_match_string && (len = dtrace_hash_collisions(dtrace_byname, &template)) < best) { best = len; hash = dtrace_byname; } /* * If we did not select a hash table, iterate over every probe and * invoke our callback for each one that matches our input probe key. */ if (hash == NULL) { for (i = 0; i < dtrace_nprobes; i++) { if ((probe = dtrace_probes[i]) == NULL || dtrace_match_probe(probe, pkp, priv, uid, zoneid) <= 0) continue; nmatched++; if ((*matched)(probe, arg) != DTRACE_MATCH_NEXT) break; } return (nmatched); } /* * If we selected a hash table, iterate over each probe of the same key * name and invoke the callback for every probe that matches the other * attributes of our input probe key. */ for (probe = dtrace_hash_lookup(hash, &template); probe != NULL; probe = *(DTRACE_HASHNEXT(hash, probe))) { if (dtrace_match_probe(probe, pkp, priv, uid, zoneid) <= 0) continue; nmatched++; if ((*matched)(probe, arg) != DTRACE_MATCH_NEXT) break; } return (nmatched); } /* * Return the function pointer dtrace_probecmp() should use to compare the * specified pattern with a string. For NULL or empty patterns, we select * dtrace_match_nul(). For glob pattern strings, we use dtrace_match_glob(). * For non-empty non-glob strings, we use dtrace_match_string(). */ static dtrace_probekey_f * dtrace_probekey_func(const char *p) { char c; if (p == NULL || *p == '\0') return (&dtrace_match_nul); while ((c = *p++) != '\0') { if (c == '[' || c == '?' || c == '*' || c == '\\') return (&dtrace_match_glob); } return (&dtrace_match_string); } /* * Build a probe comparison key for use with dtrace_match_probe() from the * given probe description. By convention, a null key only matches anchored * probes: if each field is the empty string, reset dtpk_fmatch to * dtrace_match_nonzero(). */ static void -dtrace_probekey(const dtrace_probedesc_t *pdp, dtrace_probekey_t *pkp) +dtrace_probekey(dtrace_probedesc_t *pdp, dtrace_probekey_t *pkp) { pkp->dtpk_prov = pdp->dtpd_provider; pkp->dtpk_pmatch = dtrace_probekey_func(pdp->dtpd_provider); pkp->dtpk_mod = pdp->dtpd_mod; pkp->dtpk_mmatch = dtrace_probekey_func(pdp->dtpd_mod); pkp->dtpk_func = pdp->dtpd_func; pkp->dtpk_fmatch = dtrace_probekey_func(pdp->dtpd_func); pkp->dtpk_name = pdp->dtpd_name; pkp->dtpk_nmatch = dtrace_probekey_func(pdp->dtpd_name); pkp->dtpk_id = pdp->dtpd_id; if (pkp->dtpk_id == DTRACE_IDNONE && pkp->dtpk_pmatch == &dtrace_match_nul && pkp->dtpk_mmatch == &dtrace_match_nul && pkp->dtpk_fmatch == &dtrace_match_nul && pkp->dtpk_nmatch == &dtrace_match_nul) pkp->dtpk_fmatch = &dtrace_match_nonzero; } /* * DTrace Provider-to-Framework API Functions * * These functions implement much of the Provider-to-Framework API, as * described in . The parts of the API not in this section are * the functions in the API for probe management (found below), and * dtrace_probe() itself (found above). */ /* * Register the calling provider with the DTrace framework. This should * generally be called by DTrace providers in their attach(9E) entry point. */ int dtrace_register(const char *name, const dtrace_pattr_t *pap, uint32_t priv, cred_t *cr, const dtrace_pops_t *pops, void *arg, dtrace_provider_id_t *idp) { dtrace_provider_t *provider; if (name == NULL || pap == NULL || pops == NULL || idp == NULL) { cmn_err(CE_WARN, "failed to register provider '%s': invalid " "arguments", name ? name : ""); return (EINVAL); } if (name[0] == '\0' || dtrace_badname(name)) { cmn_err(CE_WARN, "failed to register provider '%s': invalid " "provider name", name); return (EINVAL); } if ((pops->dtps_provide == NULL && pops->dtps_provide_module == NULL) || pops->dtps_enable == NULL || pops->dtps_disable == NULL || pops->dtps_destroy == NULL || ((pops->dtps_resume == NULL) != (pops->dtps_suspend == NULL))) { cmn_err(CE_WARN, "failed to register provider '%s': invalid " "provider ops", name); return (EINVAL); } if (dtrace_badattr(&pap->dtpa_provider) || dtrace_badattr(&pap->dtpa_mod) || dtrace_badattr(&pap->dtpa_func) || dtrace_badattr(&pap->dtpa_name) || dtrace_badattr(&pap->dtpa_args)) { cmn_err(CE_WARN, "failed to register provider '%s': invalid " "provider attributes", name); return (EINVAL); } if (priv & ~DTRACE_PRIV_ALL) { cmn_err(CE_WARN, "failed to register provider '%s': invalid " "privilege attributes", name); return (EINVAL); } if ((priv & DTRACE_PRIV_KERNEL) && (priv & (DTRACE_PRIV_USER | DTRACE_PRIV_OWNER)) && pops->dtps_usermode == NULL) { cmn_err(CE_WARN, "failed to register provider '%s': need " "dtps_usermode() op for given privilege attributes", name); return (EINVAL); } provider = kmem_zalloc(sizeof (dtrace_provider_t), KM_SLEEP); provider->dtpv_name = kmem_alloc(strlen(name) + 1, KM_SLEEP); (void) strcpy(provider->dtpv_name, name); provider->dtpv_attr = *pap; provider->dtpv_priv.dtpp_flags = priv; if (cr != NULL) { provider->dtpv_priv.dtpp_uid = crgetuid(cr); provider->dtpv_priv.dtpp_zoneid = crgetzoneid(cr); } provider->dtpv_pops = *pops; if (pops->dtps_provide == NULL) { ASSERT(pops->dtps_provide_module != NULL); provider->dtpv_pops.dtps_provide = - (void (*)(void *, const dtrace_probedesc_t *))dtrace_nullop; + (void (*)(void *, dtrace_probedesc_t *))dtrace_nullop; } if (pops->dtps_provide_module == NULL) { ASSERT(pops->dtps_provide != NULL); provider->dtpv_pops.dtps_provide_module = - (void (*)(void *, struct modctl *))dtrace_nullop; + (void (*)(void *, modctl_t *))dtrace_nullop; } if (pops->dtps_suspend == NULL) { ASSERT(pops->dtps_resume == NULL); provider->dtpv_pops.dtps_suspend = (void (*)(void *, dtrace_id_t, void *))dtrace_nullop; provider->dtpv_pops.dtps_resume = (void (*)(void *, dtrace_id_t, void *))dtrace_nullop; } provider->dtpv_arg = arg; *idp = (dtrace_provider_id_t)provider; if (pops == &dtrace_provider_ops) { ASSERT(MUTEX_HELD(&dtrace_provider_lock)); ASSERT(MUTEX_HELD(&dtrace_lock)); ASSERT(dtrace_anon.dta_enabling == NULL); /* * We make sure that the DTrace provider is at the head of * the provider chain. */ provider->dtpv_next = dtrace_provider; dtrace_provider = provider; return (0); } mutex_enter(&dtrace_provider_lock); mutex_enter(&dtrace_lock); /* * If there is at least one provider registered, we'll add this * provider after the first provider. */ if (dtrace_provider != NULL) { provider->dtpv_next = dtrace_provider->dtpv_next; dtrace_provider->dtpv_next = provider; } else { dtrace_provider = provider; } if (dtrace_retained != NULL) { dtrace_enabling_provide(provider); /* * Now we need to call dtrace_enabling_matchall() -- which * will acquire cpu_lock and dtrace_lock. We therefore need * to drop all of our locks before calling into it... */ mutex_exit(&dtrace_lock); mutex_exit(&dtrace_provider_lock); dtrace_enabling_matchall(); return (0); } mutex_exit(&dtrace_lock); mutex_exit(&dtrace_provider_lock); return (0); } /* * Unregister the specified provider from the DTrace framework. This should * generally be called by DTrace providers in their detach(9E) entry point. */ int dtrace_unregister(dtrace_provider_id_t id) { dtrace_provider_t *old = (dtrace_provider_t *)id; dtrace_provider_t *prev = NULL; int i, self = 0; dtrace_probe_t *probe, *first = NULL; if (old->dtpv_pops.dtps_enable == (void (*)(void *, dtrace_id_t, void *))dtrace_nullop) { /* * If DTrace itself is the provider, we're called with locks * already held. */ ASSERT(old == dtrace_provider); +#if defined(sun) ASSERT(dtrace_devi != NULL); +#endif ASSERT(MUTEX_HELD(&dtrace_provider_lock)); ASSERT(MUTEX_HELD(&dtrace_lock)); self = 1; if (dtrace_provider->dtpv_next != NULL) { /* * There's another provider here; return failure. */ return (EBUSY); } } else { mutex_enter(&dtrace_provider_lock); mutex_enter(&mod_lock); mutex_enter(&dtrace_lock); } /* * If anyone has /dev/dtrace open, or if there are anonymous enabled * probes, we refuse to let providers slither away, unless this * provider has already been explicitly invalidated. */ if (!old->dtpv_defunct && (dtrace_opens || (dtrace_anon.dta_state != NULL && dtrace_anon.dta_state->dts_necbs > 0))) { if (!self) { mutex_exit(&dtrace_lock); mutex_exit(&mod_lock); mutex_exit(&dtrace_provider_lock); } return (EBUSY); } /* * Attempt to destroy the probes associated with this provider. */ for (i = 0; i < dtrace_nprobes; i++) { if ((probe = dtrace_probes[i]) == NULL) continue; if (probe->dtpr_provider != old) continue; if (probe->dtpr_ecb == NULL) continue; /* * We have at least one ECB; we can't remove this provider. */ if (!self) { mutex_exit(&dtrace_lock); mutex_exit(&mod_lock); mutex_exit(&dtrace_provider_lock); } return (EBUSY); } /* * All of the probes for this provider are disabled; we can safely * remove all of them from their hash chains and from the probe array. */ for (i = 0; i < dtrace_nprobes; i++) { if ((probe = dtrace_probes[i]) == NULL) continue; if (probe->dtpr_provider != old) continue; dtrace_probes[i] = NULL; dtrace_hash_remove(dtrace_bymod, probe); dtrace_hash_remove(dtrace_byfunc, probe); dtrace_hash_remove(dtrace_byname, probe); if (first == NULL) { first = probe; probe->dtpr_nextmod = NULL; } else { probe->dtpr_nextmod = first; first = probe; } } /* * The provider's probes have been removed from the hash chains and * from the probe array. Now issue a dtrace_sync() to be sure that * everyone has cleared out from any probe array processing. */ dtrace_sync(); for (probe = first; probe != NULL; probe = first) { first = probe->dtpr_nextmod; old->dtpv_pops.dtps_destroy(old->dtpv_arg, probe->dtpr_id, probe->dtpr_arg); kmem_free(probe->dtpr_mod, strlen(probe->dtpr_mod) + 1); kmem_free(probe->dtpr_func, strlen(probe->dtpr_func) + 1); kmem_free(probe->dtpr_name, strlen(probe->dtpr_name) + 1); +#if defined(sun) vmem_free(dtrace_arena, (void *)(uintptr_t)(probe->dtpr_id), 1); +#else + free_unr(dtrace_arena, probe->dtpr_id); +#endif kmem_free(probe, sizeof (dtrace_probe_t)); } if ((prev = dtrace_provider) == old) { +#if defined(sun) ASSERT(self || dtrace_devi == NULL); ASSERT(old->dtpv_next == NULL || dtrace_devi == NULL); +#endif dtrace_provider = old->dtpv_next; } else { while (prev != NULL && prev->dtpv_next != old) prev = prev->dtpv_next; if (prev == NULL) { panic("attempt to unregister non-existent " "dtrace provider %p\n", (void *)id); } prev->dtpv_next = old->dtpv_next; } if (!self) { mutex_exit(&dtrace_lock); mutex_exit(&mod_lock); mutex_exit(&dtrace_provider_lock); } kmem_free(old->dtpv_name, strlen(old->dtpv_name) + 1); kmem_free(old, sizeof (dtrace_provider_t)); return (0); } /* * Invalidate the specified provider. All subsequent probe lookups for the * specified provider will fail, but its probes will not be removed. */ void dtrace_invalidate(dtrace_provider_id_t id) { dtrace_provider_t *pvp = (dtrace_provider_t *)id; ASSERT(pvp->dtpv_pops.dtps_enable != (void (*)(void *, dtrace_id_t, void *))dtrace_nullop); mutex_enter(&dtrace_provider_lock); mutex_enter(&dtrace_lock); pvp->dtpv_defunct = 1; mutex_exit(&dtrace_lock); mutex_exit(&dtrace_provider_lock); } /* * Indicate whether or not DTrace has attached. */ int dtrace_attached(void) { /* * dtrace_provider will be non-NULL iff the DTrace driver has * attached. (It's non-NULL because DTrace is always itself a * provider.) */ return (dtrace_provider != NULL); } /* * Remove all the unenabled probes for the given provider. This function is * not unlike dtrace_unregister(), except that it doesn't remove the provider * -- just as many of its associated probes as it can. */ int dtrace_condense(dtrace_provider_id_t id) { dtrace_provider_t *prov = (dtrace_provider_t *)id; int i; dtrace_probe_t *probe; /* * Make sure this isn't the dtrace provider itself. */ ASSERT(prov->dtpv_pops.dtps_enable != (void (*)(void *, dtrace_id_t, void *))dtrace_nullop); mutex_enter(&dtrace_provider_lock); mutex_enter(&dtrace_lock); /* * Attempt to destroy the probes associated with this provider. */ for (i = 0; i < dtrace_nprobes; i++) { if ((probe = dtrace_probes[i]) == NULL) continue; if (probe->dtpr_provider != prov) continue; if (probe->dtpr_ecb != NULL) continue; dtrace_probes[i] = NULL; dtrace_hash_remove(dtrace_bymod, probe); dtrace_hash_remove(dtrace_byfunc, probe); dtrace_hash_remove(dtrace_byname, probe); prov->dtpv_pops.dtps_destroy(prov->dtpv_arg, i + 1, probe->dtpr_arg); kmem_free(probe->dtpr_mod, strlen(probe->dtpr_mod) + 1); kmem_free(probe->dtpr_func, strlen(probe->dtpr_func) + 1); kmem_free(probe->dtpr_name, strlen(probe->dtpr_name) + 1); kmem_free(probe, sizeof (dtrace_probe_t)); +#if defined(sun) vmem_free(dtrace_arena, (void *)((uintptr_t)i + 1), 1); +#else + free_unr(dtrace_arena, i + 1); +#endif } mutex_exit(&dtrace_lock); mutex_exit(&dtrace_provider_lock); return (0); } /* * DTrace Probe Management Functions * * The functions in this section perform the DTrace probe management, * including functions to create probes, look-up probes, and call into the * providers to request that probes be provided. Some of these functions are * in the Provider-to-Framework API; these functions can be identified by the * fact that they are not declared "static". */ /* * Create a probe with the specified module name, function name, and name. */ dtrace_id_t dtrace_probe_create(dtrace_provider_id_t prov, const char *mod, const char *func, const char *name, int aframes, void *arg) { dtrace_probe_t *probe, **probes; dtrace_provider_t *provider = (dtrace_provider_t *)prov; dtrace_id_t id; if (provider == dtrace_provider) { ASSERT(MUTEX_HELD(&dtrace_lock)); } else { mutex_enter(&dtrace_lock); } +#if defined(sun) id = (dtrace_id_t)(uintptr_t)vmem_alloc(dtrace_arena, 1, VM_BESTFIT | VM_SLEEP); +#else + id = alloc_unr(dtrace_arena); +#endif probe = kmem_zalloc(sizeof (dtrace_probe_t), KM_SLEEP); probe->dtpr_id = id; probe->dtpr_gen = dtrace_probegen++; probe->dtpr_mod = dtrace_strdup(mod); probe->dtpr_func = dtrace_strdup(func); probe->dtpr_name = dtrace_strdup(name); probe->dtpr_arg = arg; probe->dtpr_aframes = aframes; probe->dtpr_provider = provider; dtrace_hash_add(dtrace_bymod, probe); dtrace_hash_add(dtrace_byfunc, probe); dtrace_hash_add(dtrace_byname, probe); if (id - 1 >= dtrace_nprobes) { size_t osize = dtrace_nprobes * sizeof (dtrace_probe_t *); size_t nsize = osize << 1; if (nsize == 0) { ASSERT(osize == 0); ASSERT(dtrace_probes == NULL); nsize = sizeof (dtrace_probe_t *); } probes = kmem_zalloc(nsize, KM_SLEEP); if (dtrace_probes == NULL) { ASSERT(osize == 0); dtrace_probes = probes; dtrace_nprobes = 1; } else { dtrace_probe_t **oprobes = dtrace_probes; bcopy(oprobes, probes, osize); dtrace_membar_producer(); dtrace_probes = probes; dtrace_sync(); /* * All CPUs are now seeing the new probes array; we can * safely free the old array. */ kmem_free(oprobes, osize); dtrace_nprobes <<= 1; } ASSERT(id - 1 < dtrace_nprobes); } ASSERT(dtrace_probes[id - 1] == NULL); dtrace_probes[id - 1] = probe; if (provider != dtrace_provider) mutex_exit(&dtrace_lock); return (id); } static dtrace_probe_t * dtrace_probe_lookup_id(dtrace_id_t id) { ASSERT(MUTEX_HELD(&dtrace_lock)); if (id == 0 || id > dtrace_nprobes) return (NULL); return (dtrace_probes[id - 1]); } static int dtrace_probe_lookup_match(dtrace_probe_t *probe, void *arg) { *((dtrace_id_t *)arg) = probe->dtpr_id; return (DTRACE_MATCH_DONE); } /* * Look up a probe based on provider and one or more of module name, function * name and probe name. */ dtrace_id_t -dtrace_probe_lookup(dtrace_provider_id_t prid, const char *mod, - const char *func, const char *name) +dtrace_probe_lookup(dtrace_provider_id_t prid, char *mod, + char *func, char *name) { dtrace_probekey_t pkey; dtrace_id_t id; int match; pkey.dtpk_prov = ((dtrace_provider_t *)prid)->dtpv_name; pkey.dtpk_pmatch = &dtrace_match_string; pkey.dtpk_mod = mod; pkey.dtpk_mmatch = mod ? &dtrace_match_string : &dtrace_match_nul; pkey.dtpk_func = func; pkey.dtpk_fmatch = func ? &dtrace_match_string : &dtrace_match_nul; pkey.dtpk_name = name; pkey.dtpk_nmatch = name ? &dtrace_match_string : &dtrace_match_nul; pkey.dtpk_id = DTRACE_IDNONE; mutex_enter(&dtrace_lock); match = dtrace_match(&pkey, DTRACE_PRIV_ALL, 0, 0, dtrace_probe_lookup_match, &id); mutex_exit(&dtrace_lock); ASSERT(match == 1 || match == 0); return (match ? id : 0); } /* * Returns the probe argument associated with the specified probe. */ void * dtrace_probe_arg(dtrace_provider_id_t id, dtrace_id_t pid) { dtrace_probe_t *probe; void *rval = NULL; mutex_enter(&dtrace_lock); if ((probe = dtrace_probe_lookup_id(pid)) != NULL && probe->dtpr_provider == (dtrace_provider_t *)id) rval = probe->dtpr_arg; mutex_exit(&dtrace_lock); return (rval); } /* * Copy a probe into a probe description. */ static void dtrace_probe_description(const dtrace_probe_t *prp, dtrace_probedesc_t *pdp) { bzero(pdp, sizeof (dtrace_probedesc_t)); pdp->dtpd_id = prp->dtpr_id; (void) strncpy(pdp->dtpd_provider, prp->dtpr_provider->dtpv_name, DTRACE_PROVNAMELEN - 1); (void) strncpy(pdp->dtpd_mod, prp->dtpr_mod, DTRACE_MODNAMELEN - 1); (void) strncpy(pdp->dtpd_func, prp->dtpr_func, DTRACE_FUNCNAMELEN - 1); (void) strncpy(pdp->dtpd_name, prp->dtpr_name, DTRACE_NAMELEN - 1); } +#if !defined(sun) +static int +dtrace_probe_provide_cb(linker_file_t lf, void *arg) +{ + dtrace_provider_t *prv = (dtrace_provider_t *) arg; + + prv->dtpv_pops.dtps_provide_module(prv->dtpv_arg, lf); + + return(0); +} +#endif + + /* * Called to indicate that a probe -- or probes -- should be provided by a * specfied provider. If the specified description is NULL, the provider will * be told to provide all of its probes. (This is done whenever a new * consumer comes along, or whenever a retained enabling is to be matched.) If * the specified description is non-NULL, the provider is given the * opportunity to dynamically provide the specified probe, allowing providers * to support the creation of probes on-the-fly. (So-called _autocreated_ * probes.) If the provider is NULL, the operations will be applied to all * providers; if the provider is non-NULL the operations will only be applied * to the specified provider. The dtrace_provider_lock must be held, and the * dtrace_lock must _not_ be held -- the provider's dtps_provide() operation * will need to grab the dtrace_lock when it reenters the framework through * dtrace_probe_lookup(), dtrace_probe_create(), etc. */ static void dtrace_probe_provide(dtrace_probedesc_t *desc, dtrace_provider_t *prv) { - struct modctl *ctl; +#if defined(sun) + modctl_t *ctl; +#endif int all = 0; ASSERT(MUTEX_HELD(&dtrace_provider_lock)); if (prv == NULL) { all = 1; prv = dtrace_provider; } do { /* * First, call the blanket provide operation. */ prv->dtpv_pops.dtps_provide(prv->dtpv_arg, desc); /* * Now call the per-module provide operation. We will grab * mod_lock to prevent the list from being modified. Note * that this also prevents the mod_busy bits from changing. * (mod_busy can only be changed with mod_lock held.) */ mutex_enter(&mod_lock); +#if defined(sun) ctl = &modules; do { if (ctl->mod_busy || ctl->mod_mp == NULL) continue; prv->dtpv_pops.dtps_provide_module(prv->dtpv_arg, ctl); } while ((ctl = ctl->mod_next) != &modules); +#else + (void) linker_file_foreach(dtrace_probe_provide_cb, prv); +#endif mutex_exit(&mod_lock); } while (all && (prv = prv->dtpv_next) != NULL); } +#if defined(sun) /* * Iterate over each probe, and call the Framework-to-Provider API function * denoted by offs. */ static void dtrace_probe_foreach(uintptr_t offs) { dtrace_provider_t *prov; void (*func)(void *, dtrace_id_t, void *); dtrace_probe_t *probe; dtrace_icookie_t cookie; int i; /* * We disable interrupts to walk through the probe array. This is * safe -- the dtrace_sync() in dtrace_unregister() assures that we * won't see stale data. */ cookie = dtrace_interrupt_disable(); for (i = 0; i < dtrace_nprobes; i++) { if ((probe = dtrace_probes[i]) == NULL) continue; if (probe->dtpr_ecb == NULL) { /* * This probe isn't enabled -- don't call the function. */ continue; } prov = probe->dtpr_provider; func = *((void(**)(void *, dtrace_id_t, void *)) ((uintptr_t)&prov->dtpv_pops + offs)); func(prov->dtpv_arg, i + 1, probe->dtpr_arg); } dtrace_interrupt_enable(cookie); } +#endif static int -dtrace_probe_enable(const dtrace_probedesc_t *desc, dtrace_enabling_t *enab) +dtrace_probe_enable(dtrace_probedesc_t *desc, dtrace_enabling_t *enab) { dtrace_probekey_t pkey; uint32_t priv; uid_t uid; zoneid_t zoneid; ASSERT(MUTEX_HELD(&dtrace_lock)); dtrace_ecb_create_cache = NULL; if (desc == NULL) { /* * If we're passed a NULL description, we're being asked to * create an ECB with a NULL probe. */ (void) dtrace_ecb_create_enable(NULL, enab); return (0); } dtrace_probekey(desc, &pkey); dtrace_cred2priv(enab->dten_vstate->dtvs_state->dts_cred.dcr_cred, &priv, &uid, &zoneid); return (dtrace_match(&pkey, priv, uid, zoneid, dtrace_ecb_create_enable, enab)); } /* * DTrace Helper Provider Functions */ static void dtrace_dofattr2attr(dtrace_attribute_t *attr, const dof_attr_t dofattr) { attr->dtat_name = DOF_ATTR_NAME(dofattr); attr->dtat_data = DOF_ATTR_DATA(dofattr); attr->dtat_class = DOF_ATTR_CLASS(dofattr); } static void dtrace_dofprov2hprov(dtrace_helper_provdesc_t *hprov, const dof_provider_t *dofprov, char *strtab) { hprov->dthpv_provname = strtab + dofprov->dofpv_name; dtrace_dofattr2attr(&hprov->dthpv_pattr.dtpa_provider, dofprov->dofpv_provattr); dtrace_dofattr2attr(&hprov->dthpv_pattr.dtpa_mod, dofprov->dofpv_modattr); dtrace_dofattr2attr(&hprov->dthpv_pattr.dtpa_func, dofprov->dofpv_funcattr); dtrace_dofattr2attr(&hprov->dthpv_pattr.dtpa_name, dofprov->dofpv_nameattr); dtrace_dofattr2attr(&hprov->dthpv_pattr.dtpa_args, dofprov->dofpv_argsattr); } static void dtrace_helper_provide_one(dof_helper_t *dhp, dof_sec_t *sec, pid_t pid) { uintptr_t daddr = (uintptr_t)dhp->dofhp_dof; dof_hdr_t *dof = (dof_hdr_t *)daddr; dof_sec_t *str_sec, *prb_sec, *arg_sec, *off_sec, *enoff_sec; dof_provider_t *provider; dof_probe_t *probe; uint32_t *off, *enoff; uint8_t *arg; char *strtab; uint_t i, nprobes; dtrace_helper_provdesc_t dhpv; dtrace_helper_probedesc_t dhpb; dtrace_meta_t *meta = dtrace_meta_pid; dtrace_mops_t *mops = &meta->dtm_mops; void *parg; provider = (dof_provider_t *)(uintptr_t)(daddr + sec->dofs_offset); str_sec = (dof_sec_t *)(uintptr_t)(daddr + dof->dofh_secoff + provider->dofpv_strtab * dof->dofh_secsize); prb_sec = (dof_sec_t *)(uintptr_t)(daddr + dof->dofh_secoff + provider->dofpv_probes * dof->dofh_secsize); arg_sec = (dof_sec_t *)(uintptr_t)(daddr + dof->dofh_secoff + provider->dofpv_prargs * dof->dofh_secsize); off_sec = (dof_sec_t *)(uintptr_t)(daddr + dof->dofh_secoff + provider->dofpv_proffs * dof->dofh_secsize); strtab = (char *)(uintptr_t)(daddr + str_sec->dofs_offset); off = (uint32_t *)(uintptr_t)(daddr + off_sec->dofs_offset); arg = (uint8_t *)(uintptr_t)(daddr + arg_sec->dofs_offset); enoff = NULL; /* * See dtrace_helper_provider_validate(). */ if (dof->dofh_ident[DOF_ID_VERSION] != DOF_VERSION_1 && provider->dofpv_prenoffs != DOF_SECT_NONE) { enoff_sec = (dof_sec_t *)(uintptr_t)(daddr + dof->dofh_secoff + provider->dofpv_prenoffs * dof->dofh_secsize); enoff = (uint32_t *)(uintptr_t)(daddr + enoff_sec->dofs_offset); } nprobes = prb_sec->dofs_size / prb_sec->dofs_entsize; /* * Create the provider. */ dtrace_dofprov2hprov(&dhpv, provider, strtab); if ((parg = mops->dtms_provide_pid(meta->dtm_arg, &dhpv, pid)) == NULL) return; meta->dtm_count++; /* * Create the probes. */ for (i = 0; i < nprobes; i++) { probe = (dof_probe_t *)(uintptr_t)(daddr + prb_sec->dofs_offset + i * prb_sec->dofs_entsize); dhpb.dthpb_mod = dhp->dofhp_mod; dhpb.dthpb_func = strtab + probe->dofpr_func; dhpb.dthpb_name = strtab + probe->dofpr_name; dhpb.dthpb_base = probe->dofpr_addr; dhpb.dthpb_offs = off + probe->dofpr_offidx; dhpb.dthpb_noffs = probe->dofpr_noffs; if (enoff != NULL) { dhpb.dthpb_enoffs = enoff + probe->dofpr_enoffidx; dhpb.dthpb_nenoffs = probe->dofpr_nenoffs; } else { dhpb.dthpb_enoffs = NULL; dhpb.dthpb_nenoffs = 0; } dhpb.dthpb_args = arg + probe->dofpr_argidx; dhpb.dthpb_nargc = probe->dofpr_nargc; dhpb.dthpb_xargc = probe->dofpr_xargc; dhpb.dthpb_ntypes = strtab + probe->dofpr_nargv; dhpb.dthpb_xtypes = strtab + probe->dofpr_xargv; mops->dtms_create_probe(meta->dtm_arg, parg, &dhpb); } } static void dtrace_helper_provide(dof_helper_t *dhp, pid_t pid) { uintptr_t daddr = (uintptr_t)dhp->dofhp_dof; dof_hdr_t *dof = (dof_hdr_t *)daddr; int i; ASSERT(MUTEX_HELD(&dtrace_meta_lock)); for (i = 0; i < dof->dofh_secnum; i++) { dof_sec_t *sec = (dof_sec_t *)(uintptr_t)(daddr + dof->dofh_secoff + i * dof->dofh_secsize); if (sec->dofs_type != DOF_SECT_PROVIDER) continue; dtrace_helper_provide_one(dhp, sec, pid); } /* * We may have just created probes, so we must now rematch against * any retained enablings. Note that this call will acquire both * cpu_lock and dtrace_lock; the fact that we are holding * dtrace_meta_lock now is what defines the ordering with respect to * these three locks. */ dtrace_enabling_matchall(); } +#if defined(sun) static void dtrace_helper_provider_remove_one(dof_helper_t *dhp, dof_sec_t *sec, pid_t pid) { uintptr_t daddr = (uintptr_t)dhp->dofhp_dof; dof_hdr_t *dof = (dof_hdr_t *)daddr; dof_sec_t *str_sec; dof_provider_t *provider; char *strtab; dtrace_helper_provdesc_t dhpv; dtrace_meta_t *meta = dtrace_meta_pid; dtrace_mops_t *mops = &meta->dtm_mops; provider = (dof_provider_t *)(uintptr_t)(daddr + sec->dofs_offset); str_sec = (dof_sec_t *)(uintptr_t)(daddr + dof->dofh_secoff + provider->dofpv_strtab * dof->dofh_secsize); strtab = (char *)(uintptr_t)(daddr + str_sec->dofs_offset); /* * Create the provider. */ dtrace_dofprov2hprov(&dhpv, provider, strtab); mops->dtms_remove_pid(meta->dtm_arg, &dhpv, pid); meta->dtm_count--; } static void dtrace_helper_provider_remove(dof_helper_t *dhp, pid_t pid) { uintptr_t daddr = (uintptr_t)dhp->dofhp_dof; dof_hdr_t *dof = (dof_hdr_t *)daddr; int i; ASSERT(MUTEX_HELD(&dtrace_meta_lock)); for (i = 0; i < dof->dofh_secnum; i++) { dof_sec_t *sec = (dof_sec_t *)(uintptr_t)(daddr + dof->dofh_secoff + i * dof->dofh_secsize); if (sec->dofs_type != DOF_SECT_PROVIDER) continue; dtrace_helper_provider_remove_one(dhp, sec, pid); } } +#endif /* * DTrace Meta Provider-to-Framework API Functions * * These functions implement the Meta Provider-to-Framework API, as described * in . */ int dtrace_meta_register(const char *name, const dtrace_mops_t *mops, void *arg, dtrace_meta_provider_id_t *idp) { dtrace_meta_t *meta; dtrace_helpers_t *help, *next; int i; *idp = DTRACE_METAPROVNONE; /* * We strictly don't need the name, but we hold onto it for * debuggability. All hail error queues! */ if (name == NULL) { cmn_err(CE_WARN, "failed to register meta-provider: " "invalid name"); return (EINVAL); } if (mops == NULL || mops->dtms_create_probe == NULL || mops->dtms_provide_pid == NULL || mops->dtms_remove_pid == NULL) { cmn_err(CE_WARN, "failed to register meta-register %s: " "invalid ops", name); return (EINVAL); } meta = kmem_zalloc(sizeof (dtrace_meta_t), KM_SLEEP); meta->dtm_mops = *mops; meta->dtm_name = kmem_alloc(strlen(name) + 1, KM_SLEEP); (void) strcpy(meta->dtm_name, name); meta->dtm_arg = arg; mutex_enter(&dtrace_meta_lock); mutex_enter(&dtrace_lock); if (dtrace_meta_pid != NULL) { mutex_exit(&dtrace_lock); mutex_exit(&dtrace_meta_lock); cmn_err(CE_WARN, "failed to register meta-register %s: " "user-land meta-provider exists", name); kmem_free(meta->dtm_name, strlen(meta->dtm_name) + 1); kmem_free(meta, sizeof (dtrace_meta_t)); return (EINVAL); } dtrace_meta_pid = meta; *idp = (dtrace_meta_provider_id_t)meta; /* * If there are providers and probes ready to go, pass them * off to the new meta provider now. */ help = dtrace_deferred_pid; dtrace_deferred_pid = NULL; mutex_exit(&dtrace_lock); while (help != NULL) { for (i = 0; i < help->dthps_nprovs; i++) { dtrace_helper_provide(&help->dthps_provs[i]->dthp_prov, help->dthps_pid); } next = help->dthps_next; help->dthps_next = NULL; help->dthps_prev = NULL; help->dthps_deferred = 0; help = next; } mutex_exit(&dtrace_meta_lock); return (0); } int dtrace_meta_unregister(dtrace_meta_provider_id_t id) { dtrace_meta_t **pp, *old = (dtrace_meta_t *)id; mutex_enter(&dtrace_meta_lock); mutex_enter(&dtrace_lock); if (old == dtrace_meta_pid) { pp = &dtrace_meta_pid; } else { panic("attempt to unregister non-existent " "dtrace meta-provider %p\n", (void *)old); } if (old->dtm_count != 0) { mutex_exit(&dtrace_lock); mutex_exit(&dtrace_meta_lock); return (EBUSY); } *pp = NULL; mutex_exit(&dtrace_lock); mutex_exit(&dtrace_meta_lock); kmem_free(old->dtm_name, strlen(old->dtm_name) + 1); kmem_free(old, sizeof (dtrace_meta_t)); return (0); } /* * DTrace DIF Object Functions */ static int dtrace_difo_err(uint_t pc, const char *format, ...) { if (dtrace_err_verbose) { va_list alist; (void) uprintf("dtrace DIF object error: [%u]: ", pc); va_start(alist, format); (void) vuprintf(format, alist); va_end(alist); } #ifdef DTRACE_ERRDEBUG dtrace_errdebug(format); #endif return (1); } /* * Validate a DTrace DIF object by checking the IR instructions. The following * rules are currently enforced by dtrace_difo_validate(): * * 1. Each instruction must have a valid opcode * 2. Each register, string, variable, or subroutine reference must be valid * 3. No instruction can modify register %r0 (must be zero) * 4. All instruction reserved bits must be set to zero * 5. The last instruction must be a "ret" instruction * 6. All branch targets must reference a valid instruction _after_ the branch */ static int dtrace_difo_validate(dtrace_difo_t *dp, dtrace_vstate_t *vstate, uint_t nregs, cred_t *cr) { int err = 0, i; int (*efunc)(uint_t pc, const char *, ...) = dtrace_difo_err; int kcheckload; uint_t pc; kcheckload = cr == NULL || (vstate->dtvs_state->dts_cred.dcr_visible & DTRACE_CRV_KERNEL) == 0; dp->dtdo_destructive = 0; for (pc = 0; pc < dp->dtdo_len && err == 0; pc++) { dif_instr_t instr = dp->dtdo_buf[pc]; uint_t r1 = DIF_INSTR_R1(instr); uint_t r2 = DIF_INSTR_R2(instr); uint_t rd = DIF_INSTR_RD(instr); uint_t rs = DIF_INSTR_RS(instr); uint_t label = DIF_INSTR_LABEL(instr); uint_t v = DIF_INSTR_VAR(instr); uint_t subr = DIF_INSTR_SUBR(instr); uint_t type = DIF_INSTR_TYPE(instr); uint_t op = DIF_INSTR_OP(instr); switch (op) { case DIF_OP_OR: case DIF_OP_XOR: case DIF_OP_AND: case DIF_OP_SLL: case DIF_OP_SRL: case DIF_OP_SRA: case DIF_OP_SUB: case DIF_OP_ADD: case DIF_OP_MUL: case DIF_OP_SDIV: case DIF_OP_UDIV: case DIF_OP_SREM: case DIF_OP_UREM: case DIF_OP_COPYS: if (r1 >= nregs) err += efunc(pc, "invalid register %u\n", r1); if (r2 >= nregs) err += efunc(pc, "invalid register %u\n", r2); if (rd >= nregs) err += efunc(pc, "invalid register %u\n", rd); if (rd == 0) err += efunc(pc, "cannot write to %r0\n"); break; case DIF_OP_NOT: case DIF_OP_MOV: case DIF_OP_ALLOCS: if (r1 >= nregs) err += efunc(pc, "invalid register %u\n", r1); if (r2 != 0) err += efunc(pc, "non-zero reserved bits\n"); if (rd >= nregs) err += efunc(pc, "invalid register %u\n", rd); if (rd == 0) err += efunc(pc, "cannot write to %r0\n"); break; case DIF_OP_LDSB: case DIF_OP_LDSH: case DIF_OP_LDSW: case DIF_OP_LDUB: case DIF_OP_LDUH: case DIF_OP_LDUW: case DIF_OP_LDX: if (r1 >= nregs) err += efunc(pc, "invalid register %u\n", r1); if (r2 != 0) err += efunc(pc, "non-zero reserved bits\n"); if (rd >= nregs) err += efunc(pc, "invalid register %u\n", rd); if (rd == 0) err += efunc(pc, "cannot write to %r0\n"); if (kcheckload) dp->dtdo_buf[pc] = DIF_INSTR_LOAD(op + DIF_OP_RLDSB - DIF_OP_LDSB, r1, rd); break; case DIF_OP_RLDSB: case DIF_OP_RLDSH: case DIF_OP_RLDSW: case DIF_OP_RLDUB: case DIF_OP_RLDUH: case DIF_OP_RLDUW: case DIF_OP_RLDX: if (r1 >= nregs) err += efunc(pc, "invalid register %u\n", r1); if (r2 != 0) err += efunc(pc, "non-zero reserved bits\n"); if (rd >= nregs) err += efunc(pc, "invalid register %u\n", rd); if (rd == 0) err += efunc(pc, "cannot write to %r0\n"); break; case DIF_OP_ULDSB: case DIF_OP_ULDSH: case DIF_OP_ULDSW: case DIF_OP_ULDUB: case DIF_OP_ULDUH: case DIF_OP_ULDUW: case DIF_OP_ULDX: if (r1 >= nregs) err += efunc(pc, "invalid register %u\n", r1); if (r2 != 0) err += efunc(pc, "non-zero reserved bits\n"); if (rd >= nregs) err += efunc(pc, "invalid register %u\n", rd); if (rd == 0) err += efunc(pc, "cannot write to %r0\n"); break; case DIF_OP_STB: case DIF_OP_STH: case DIF_OP_STW: case DIF_OP_STX: if (r1 >= nregs) err += efunc(pc, "invalid register %u\n", r1); if (r2 != 0) err += efunc(pc, "non-zero reserved bits\n"); if (rd >= nregs) err += efunc(pc, "invalid register %u\n", rd); if (rd == 0) err += efunc(pc, "cannot write to 0 address\n"); break; case DIF_OP_CMP: case DIF_OP_SCMP: if (r1 >= nregs) err += efunc(pc, "invalid register %u\n", r1); if (r2 >= nregs) err += efunc(pc, "invalid register %u\n", r2); if (rd != 0) err += efunc(pc, "non-zero reserved bits\n"); break; case DIF_OP_TST: if (r1 >= nregs) err += efunc(pc, "invalid register %u\n", r1); if (r2 != 0 || rd != 0) err += efunc(pc, "non-zero reserved bits\n"); break; case DIF_OP_BA: case DIF_OP_BE: case DIF_OP_BNE: case DIF_OP_BG: case DIF_OP_BGU: case DIF_OP_BGE: case DIF_OP_BGEU: case DIF_OP_BL: case DIF_OP_BLU: case DIF_OP_BLE: case DIF_OP_BLEU: if (label >= dp->dtdo_len) { err += efunc(pc, "invalid branch target %u\n", label); } if (label <= pc) { err += efunc(pc, "backward branch to %u\n", label); } break; case DIF_OP_RET: if (r1 != 0 || r2 != 0) err += efunc(pc, "non-zero reserved bits\n"); if (rd >= nregs) err += efunc(pc, "invalid register %u\n", rd); break; case DIF_OP_NOP: case DIF_OP_POPTS: case DIF_OP_FLUSHTS: if (r1 != 0 || r2 != 0 || rd != 0) err += efunc(pc, "non-zero reserved bits\n"); break; case DIF_OP_SETX: if (DIF_INSTR_INTEGER(instr) >= dp->dtdo_intlen) { err += efunc(pc, "invalid integer ref %u\n", DIF_INSTR_INTEGER(instr)); } if (rd >= nregs) err += efunc(pc, "invalid register %u\n", rd); if (rd == 0) err += efunc(pc, "cannot write to %r0\n"); break; case DIF_OP_SETS: if (DIF_INSTR_STRING(instr) >= dp->dtdo_strlen) { err += efunc(pc, "invalid string ref %u\n", DIF_INSTR_STRING(instr)); } if (rd >= nregs) err += efunc(pc, "invalid register %u\n", rd); if (rd == 0) err += efunc(pc, "cannot write to %r0\n"); break; case DIF_OP_LDGA: case DIF_OP_LDTA: if (r1 > DIF_VAR_ARRAY_MAX) err += efunc(pc, "invalid array %u\n", r1); if (r2 >= nregs) err += efunc(pc, "invalid register %u\n", r2); if (rd >= nregs) err += efunc(pc, "invalid register %u\n", rd); if (rd == 0) err += efunc(pc, "cannot write to %r0\n"); break; case DIF_OP_LDGS: case DIF_OP_LDTS: case DIF_OP_LDLS: case DIF_OP_LDGAA: case DIF_OP_LDTAA: if (v < DIF_VAR_OTHER_MIN || v > DIF_VAR_OTHER_MAX) err += efunc(pc, "invalid variable %u\n", v); if (rd >= nregs) err += efunc(pc, "invalid register %u\n", rd); if (rd == 0) err += efunc(pc, "cannot write to %r0\n"); break; case DIF_OP_STGS: case DIF_OP_STTS: case DIF_OP_STLS: case DIF_OP_STGAA: case DIF_OP_STTAA: if (v < DIF_VAR_OTHER_UBASE || v > DIF_VAR_OTHER_MAX) err += efunc(pc, "invalid variable %u\n", v); if (rs >= nregs) err += efunc(pc, "invalid register %u\n", rd); break; case DIF_OP_CALL: if (subr > DIF_SUBR_MAX) err += efunc(pc, "invalid subr %u\n", subr); if (rd >= nregs) err += efunc(pc, "invalid register %u\n", rd); if (rd == 0) err += efunc(pc, "cannot write to %r0\n"); if (subr == DIF_SUBR_COPYOUT || subr == DIF_SUBR_COPYOUTSTR) { dp->dtdo_destructive = 1; } break; case DIF_OP_PUSHTR: if (type != DIF_TYPE_STRING && type != DIF_TYPE_CTF) err += efunc(pc, "invalid ref type %u\n", type); if (r2 >= nregs) err += efunc(pc, "invalid register %u\n", r2); if (rs >= nregs) err += efunc(pc, "invalid register %u\n", rs); break; case DIF_OP_PUSHTV: if (type != DIF_TYPE_CTF) err += efunc(pc, "invalid val type %u\n", type); if (r2 >= nregs) err += efunc(pc, "invalid register %u\n", r2); if (rs >= nregs) err += efunc(pc, "invalid register %u\n", rs); break; default: err += efunc(pc, "invalid opcode %u\n", DIF_INSTR_OP(instr)); } } if (dp->dtdo_len != 0 && DIF_INSTR_OP(dp->dtdo_buf[dp->dtdo_len - 1]) != DIF_OP_RET) { err += efunc(dp->dtdo_len - 1, "expected 'ret' as last DIF instruction\n"); } if (!(dp->dtdo_rtype.dtdt_flags & DIF_TF_BYREF)) { /* * If we're not returning by reference, the size must be either * 0 or the size of one of the base types. */ switch (dp->dtdo_rtype.dtdt_size) { case 0: case sizeof (uint8_t): case sizeof (uint16_t): case sizeof (uint32_t): case sizeof (uint64_t): break; default: err += efunc(dp->dtdo_len - 1, "bad return size"); } } for (i = 0; i < dp->dtdo_varlen && err == 0; i++) { dtrace_difv_t *v = &dp->dtdo_vartab[i], *existing = NULL; dtrace_diftype_t *vt, *et; uint_t id, ndx; if (v->dtdv_scope != DIFV_SCOPE_GLOBAL && v->dtdv_scope != DIFV_SCOPE_THREAD && v->dtdv_scope != DIFV_SCOPE_LOCAL) { err += efunc(i, "unrecognized variable scope %d\n", v->dtdv_scope); break; } if (v->dtdv_kind != DIFV_KIND_ARRAY && v->dtdv_kind != DIFV_KIND_SCALAR) { err += efunc(i, "unrecognized variable type %d\n", v->dtdv_kind); break; } if ((id = v->dtdv_id) > DIF_VARIABLE_MAX) { err += efunc(i, "%d exceeds variable id limit\n", id); break; } if (id < DIF_VAR_OTHER_UBASE) continue; /* * For user-defined variables, we need to check that this * definition is identical to any previous definition that we * encountered. */ ndx = id - DIF_VAR_OTHER_UBASE; switch (v->dtdv_scope) { case DIFV_SCOPE_GLOBAL: if (ndx < vstate->dtvs_nglobals) { dtrace_statvar_t *svar; if ((svar = vstate->dtvs_globals[ndx]) != NULL) existing = &svar->dtsv_var; } break; case DIFV_SCOPE_THREAD: if (ndx < vstate->dtvs_ntlocals) existing = &vstate->dtvs_tlocals[ndx]; break; case DIFV_SCOPE_LOCAL: if (ndx < vstate->dtvs_nlocals) { dtrace_statvar_t *svar; if ((svar = vstate->dtvs_locals[ndx]) != NULL) existing = &svar->dtsv_var; } break; } vt = &v->dtdv_type; if (vt->dtdt_flags & DIF_TF_BYREF) { if (vt->dtdt_size == 0) { err += efunc(i, "zero-sized variable\n"); break; } if (v->dtdv_scope == DIFV_SCOPE_GLOBAL && vt->dtdt_size > dtrace_global_maxsize) { err += efunc(i, "oversized by-ref global\n"); break; } } if (existing == NULL || existing->dtdv_id == 0) continue; ASSERT(existing->dtdv_id == v->dtdv_id); ASSERT(existing->dtdv_scope == v->dtdv_scope); if (existing->dtdv_kind != v->dtdv_kind) err += efunc(i, "%d changed variable kind\n", id); et = &existing->dtdv_type; if (vt->dtdt_flags != et->dtdt_flags) { err += efunc(i, "%d changed variable type flags\n", id); break; } if (vt->dtdt_size != 0 && vt->dtdt_size != et->dtdt_size) { err += efunc(i, "%d changed variable type size\n", id); break; } } return (err); } +#if defined(sun) /* * Validate a DTrace DIF object that it is to be used as a helper. Helpers * are much more constrained than normal DIFOs. Specifically, they may * not: * * 1. Make calls to subroutines other than copyin(), copyinstr() or * miscellaneous string routines * 2. Access DTrace variables other than the args[] array, and the * curthread, pid, ppid, tid, execname, zonename, uid and gid variables. * 3. Have thread-local variables. * 4. Have dynamic variables. */ static int dtrace_difo_validate_helper(dtrace_difo_t *dp) { int (*efunc)(uint_t pc, const char *, ...) = dtrace_difo_err; int err = 0; uint_t pc; for (pc = 0; pc < dp->dtdo_len; pc++) { dif_instr_t instr = dp->dtdo_buf[pc]; uint_t v = DIF_INSTR_VAR(instr); uint_t subr = DIF_INSTR_SUBR(instr); uint_t op = DIF_INSTR_OP(instr); switch (op) { case DIF_OP_OR: case DIF_OP_XOR: case DIF_OP_AND: case DIF_OP_SLL: case DIF_OP_SRL: case DIF_OP_SRA: case DIF_OP_SUB: case DIF_OP_ADD: case DIF_OP_MUL: case DIF_OP_SDIV: case DIF_OP_UDIV: case DIF_OP_SREM: case DIF_OP_UREM: case DIF_OP_COPYS: case DIF_OP_NOT: case DIF_OP_MOV: case DIF_OP_RLDSB: case DIF_OP_RLDSH: case DIF_OP_RLDSW: case DIF_OP_RLDUB: case DIF_OP_RLDUH: case DIF_OP_RLDUW: case DIF_OP_RLDX: case DIF_OP_ULDSB: case DIF_OP_ULDSH: case DIF_OP_ULDSW: case DIF_OP_ULDUB: case DIF_OP_ULDUH: case DIF_OP_ULDUW: case DIF_OP_ULDX: case DIF_OP_STB: case DIF_OP_STH: case DIF_OP_STW: case DIF_OP_STX: case DIF_OP_ALLOCS: case DIF_OP_CMP: case DIF_OP_SCMP: case DIF_OP_TST: case DIF_OP_BA: case DIF_OP_BE: case DIF_OP_BNE: case DIF_OP_BG: case DIF_OP_BGU: case DIF_OP_BGE: case DIF_OP_BGEU: case DIF_OP_BL: case DIF_OP_BLU: case DIF_OP_BLE: case DIF_OP_BLEU: case DIF_OP_RET: case DIF_OP_NOP: case DIF_OP_POPTS: case DIF_OP_FLUSHTS: case DIF_OP_SETX: case DIF_OP_SETS: case DIF_OP_LDGA: case DIF_OP_LDLS: case DIF_OP_STGS: case DIF_OP_STLS: case DIF_OP_PUSHTR: case DIF_OP_PUSHTV: break; case DIF_OP_LDGS: if (v >= DIF_VAR_OTHER_UBASE) break; if (v >= DIF_VAR_ARG0 && v <= DIF_VAR_ARG9) break; if (v == DIF_VAR_CURTHREAD || v == DIF_VAR_PID || v == DIF_VAR_PPID || v == DIF_VAR_TID || + v == DIF_VAR_EXECARGS || v == DIF_VAR_EXECNAME || v == DIF_VAR_ZONENAME || v == DIF_VAR_UID || v == DIF_VAR_GID) break; err += efunc(pc, "illegal variable %u\n", v); break; case DIF_OP_LDTA: case DIF_OP_LDTS: case DIF_OP_LDGAA: case DIF_OP_LDTAA: err += efunc(pc, "illegal dynamic variable load\n"); break; case DIF_OP_STTS: case DIF_OP_STGAA: case DIF_OP_STTAA: err += efunc(pc, "illegal dynamic variable store\n"); break; case DIF_OP_CALL: if (subr == DIF_SUBR_ALLOCA || subr == DIF_SUBR_BCOPY || subr == DIF_SUBR_COPYIN || subr == DIF_SUBR_COPYINTO || subr == DIF_SUBR_COPYINSTR || subr == DIF_SUBR_INDEX || subr == DIF_SUBR_INET_NTOA || subr == DIF_SUBR_INET_NTOA6 || subr == DIF_SUBR_INET_NTOP || subr == DIF_SUBR_LLTOSTR || subr == DIF_SUBR_RINDEX || subr == DIF_SUBR_STRCHR || subr == DIF_SUBR_STRJOIN || subr == DIF_SUBR_STRRCHR || subr == DIF_SUBR_STRSTR || subr == DIF_SUBR_HTONS || subr == DIF_SUBR_HTONL || subr == DIF_SUBR_HTONLL || subr == DIF_SUBR_NTOHS || subr == DIF_SUBR_NTOHL || - subr == DIF_SUBR_NTOHLL) + subr == DIF_SUBR_NTOHLL || + subr == DIF_SUBR_MEMREF || + subr == DIF_SUBR_TYPEREF) break; err += efunc(pc, "invalid subr %u\n", subr); break; default: err += efunc(pc, "invalid opcode %u\n", DIF_INSTR_OP(instr)); } } return (err); } +#endif /* * Returns 1 if the expression in the DIF object can be cached on a per-thread * basis; 0 if not. */ static int dtrace_difo_cacheable(dtrace_difo_t *dp) { int i; if (dp == NULL) return (0); for (i = 0; i < dp->dtdo_varlen; i++) { dtrace_difv_t *v = &dp->dtdo_vartab[i]; if (v->dtdv_scope != DIFV_SCOPE_GLOBAL) continue; switch (v->dtdv_id) { case DIF_VAR_CURTHREAD: case DIF_VAR_PID: case DIF_VAR_TID: + case DIF_VAR_EXECARGS: case DIF_VAR_EXECNAME: case DIF_VAR_ZONENAME: break; default: return (0); } } /* * This DIF object may be cacheable. Now we need to look for any * array loading instructions, any memory loading instructions, or * any stores to thread-local variables. */ for (i = 0; i < dp->dtdo_len; i++) { uint_t op = DIF_INSTR_OP(dp->dtdo_buf[i]); if ((op >= DIF_OP_LDSB && op <= DIF_OP_LDX) || (op >= DIF_OP_ULDSB && op <= DIF_OP_ULDX) || (op >= DIF_OP_RLDSB && op <= DIF_OP_RLDX) || op == DIF_OP_LDGA || op == DIF_OP_STTS) return (0); } return (1); } static void dtrace_difo_hold(dtrace_difo_t *dp) { int i; ASSERT(MUTEX_HELD(&dtrace_lock)); dp->dtdo_refcnt++; ASSERT(dp->dtdo_refcnt != 0); /* * We need to check this DIF object for references to the variable * DIF_VAR_VTIMESTAMP. */ for (i = 0; i < dp->dtdo_varlen; i++) { dtrace_difv_t *v = &dp->dtdo_vartab[i]; if (v->dtdv_id != DIF_VAR_VTIMESTAMP) continue; if (dtrace_vtime_references++ == 0) dtrace_vtime_enable(); } } /* * This routine calculates the dynamic variable chunksize for a given DIF * object. The calculation is not fool-proof, and can probably be tricked by * malicious DIF -- but it works for all compiler-generated DIF. Because this * calculation is likely imperfect, dtrace_dynvar() is able to gracefully fail * if a dynamic variable size exceeds the chunksize. */ static void dtrace_difo_chunksize(dtrace_difo_t *dp, dtrace_vstate_t *vstate) { - uint64_t sval; + uint64_t sval = 0; dtrace_key_t tupregs[DIF_DTR_NREGS + 2]; /* +2 for thread and id */ const dif_instr_t *text = dp->dtdo_buf; uint_t pc, srd = 0; uint_t ttop = 0; size_t size, ksize; uint_t id, i; for (pc = 0; pc < dp->dtdo_len; pc++) { dif_instr_t instr = text[pc]; uint_t op = DIF_INSTR_OP(instr); uint_t rd = DIF_INSTR_RD(instr); uint_t r1 = DIF_INSTR_R1(instr); uint_t nkeys = 0; - uchar_t scope; + uchar_t scope = 0; dtrace_key_t *key = tupregs; switch (op) { case DIF_OP_SETX: sval = dp->dtdo_inttab[DIF_INSTR_INTEGER(instr)]; srd = rd; continue; case DIF_OP_STTS: key = &tupregs[DIF_DTR_NREGS]; key[0].dttk_size = 0; key[1].dttk_size = 0; nkeys = 2; scope = DIFV_SCOPE_THREAD; break; case DIF_OP_STGAA: case DIF_OP_STTAA: nkeys = ttop; if (DIF_INSTR_OP(instr) == DIF_OP_STTAA) key[nkeys++].dttk_size = 0; key[nkeys++].dttk_size = 0; if (op == DIF_OP_STTAA) { scope = DIFV_SCOPE_THREAD; } else { scope = DIFV_SCOPE_GLOBAL; } break; case DIF_OP_PUSHTR: if (ttop == DIF_DTR_NREGS) return; if ((srd == 0 || sval == 0) && r1 == DIF_TYPE_STRING) { /* * If the register for the size of the "pushtr" * is %r0 (or the value is 0) and the type is * a string, we'll use the system-wide default * string size. */ tupregs[ttop++].dttk_size = dtrace_strsize_default; } else { if (srd == 0) return; tupregs[ttop++].dttk_size = sval; } break; case DIF_OP_PUSHTV: if (ttop == DIF_DTR_NREGS) return; tupregs[ttop++].dttk_size = 0; break; case DIF_OP_FLUSHTS: ttop = 0; break; case DIF_OP_POPTS: if (ttop != 0) ttop--; break; } sval = 0; srd = 0; if (nkeys == 0) continue; /* * We have a dynamic variable allocation; calculate its size. */ for (ksize = 0, i = 0; i < nkeys; i++) ksize += P2ROUNDUP(key[i].dttk_size, sizeof (uint64_t)); size = sizeof (dtrace_dynvar_t); size += sizeof (dtrace_key_t) * (nkeys - 1); size += ksize; /* * Now we need to determine the size of the stored data. */ id = DIF_INSTR_VAR(instr); for (i = 0; i < dp->dtdo_varlen; i++) { dtrace_difv_t *v = &dp->dtdo_vartab[i]; if (v->dtdv_id == id && v->dtdv_scope == scope) { size += v->dtdv_type.dtdt_size; break; } } if (i == dp->dtdo_varlen) return; /* * We have the size. If this is larger than the chunk size * for our dynamic variable state, reset the chunk size. */ size = P2ROUNDUP(size, sizeof (uint64_t)); if (size > vstate->dtvs_dynvars.dtds_chunksize) vstate->dtvs_dynvars.dtds_chunksize = size; } } static void dtrace_difo_init(dtrace_difo_t *dp, dtrace_vstate_t *vstate) { int i, oldsvars, osz, nsz, otlocals, ntlocals; uint_t id; ASSERT(MUTEX_HELD(&dtrace_lock)); ASSERT(dp->dtdo_buf != NULL && dp->dtdo_len != 0); for (i = 0; i < dp->dtdo_varlen; i++) { dtrace_difv_t *v = &dp->dtdo_vartab[i]; - dtrace_statvar_t *svar, ***svarp; + dtrace_statvar_t *svar, ***svarp = NULL; size_t dsize = 0; uint8_t scope = v->dtdv_scope; - int *np; + int *np = NULL; if ((id = v->dtdv_id) < DIF_VAR_OTHER_UBASE) continue; id -= DIF_VAR_OTHER_UBASE; switch (scope) { case DIFV_SCOPE_THREAD: while (id >= (otlocals = vstate->dtvs_ntlocals)) { dtrace_difv_t *tlocals; if ((ntlocals = (otlocals << 1)) == 0) ntlocals = 1; osz = otlocals * sizeof (dtrace_difv_t); nsz = ntlocals * sizeof (dtrace_difv_t); tlocals = kmem_zalloc(nsz, KM_SLEEP); if (osz != 0) { bcopy(vstate->dtvs_tlocals, tlocals, osz); kmem_free(vstate->dtvs_tlocals, osz); } vstate->dtvs_tlocals = tlocals; vstate->dtvs_ntlocals = ntlocals; } vstate->dtvs_tlocals[id] = *v; continue; case DIFV_SCOPE_LOCAL: np = &vstate->dtvs_nlocals; svarp = &vstate->dtvs_locals; if (v->dtdv_type.dtdt_flags & DIF_TF_BYREF) dsize = NCPU * (v->dtdv_type.dtdt_size + sizeof (uint64_t)); else dsize = NCPU * sizeof (uint64_t); break; case DIFV_SCOPE_GLOBAL: np = &vstate->dtvs_nglobals; svarp = &vstate->dtvs_globals; if (v->dtdv_type.dtdt_flags & DIF_TF_BYREF) dsize = v->dtdv_type.dtdt_size + sizeof (uint64_t); break; default: ASSERT(0); } while (id >= (oldsvars = *np)) { dtrace_statvar_t **statics; int newsvars, oldsize, newsize; if ((newsvars = (oldsvars << 1)) == 0) newsvars = 1; oldsize = oldsvars * sizeof (dtrace_statvar_t *); newsize = newsvars * sizeof (dtrace_statvar_t *); statics = kmem_zalloc(newsize, KM_SLEEP); if (oldsize != 0) { bcopy(*svarp, statics, oldsize); kmem_free(*svarp, oldsize); } *svarp = statics; *np = newsvars; } if ((svar = (*svarp)[id]) == NULL) { svar = kmem_zalloc(sizeof (dtrace_statvar_t), KM_SLEEP); svar->dtsv_var = *v; if ((svar->dtsv_size = dsize) != 0) { svar->dtsv_data = (uint64_t)(uintptr_t) kmem_zalloc(dsize, KM_SLEEP); } (*svarp)[id] = svar; } svar->dtsv_refcnt++; } dtrace_difo_chunksize(dp, vstate); dtrace_difo_hold(dp); } +#if defined(sun) static dtrace_difo_t * dtrace_difo_duplicate(dtrace_difo_t *dp, dtrace_vstate_t *vstate) { dtrace_difo_t *new; size_t sz; ASSERT(dp->dtdo_buf != NULL); ASSERT(dp->dtdo_refcnt != 0); new = kmem_zalloc(sizeof (dtrace_difo_t), KM_SLEEP); ASSERT(dp->dtdo_buf != NULL); sz = dp->dtdo_len * sizeof (dif_instr_t); new->dtdo_buf = kmem_alloc(sz, KM_SLEEP); bcopy(dp->dtdo_buf, new->dtdo_buf, sz); new->dtdo_len = dp->dtdo_len; if (dp->dtdo_strtab != NULL) { ASSERT(dp->dtdo_strlen != 0); new->dtdo_strtab = kmem_alloc(dp->dtdo_strlen, KM_SLEEP); bcopy(dp->dtdo_strtab, new->dtdo_strtab, dp->dtdo_strlen); new->dtdo_strlen = dp->dtdo_strlen; } if (dp->dtdo_inttab != NULL) { ASSERT(dp->dtdo_intlen != 0); sz = dp->dtdo_intlen * sizeof (uint64_t); new->dtdo_inttab = kmem_alloc(sz, KM_SLEEP); bcopy(dp->dtdo_inttab, new->dtdo_inttab, sz); new->dtdo_intlen = dp->dtdo_intlen; } if (dp->dtdo_vartab != NULL) { ASSERT(dp->dtdo_varlen != 0); sz = dp->dtdo_varlen * sizeof (dtrace_difv_t); new->dtdo_vartab = kmem_alloc(sz, KM_SLEEP); bcopy(dp->dtdo_vartab, new->dtdo_vartab, sz); new->dtdo_varlen = dp->dtdo_varlen; } dtrace_difo_init(new, vstate); return (new); } +#endif static void dtrace_difo_destroy(dtrace_difo_t *dp, dtrace_vstate_t *vstate) { int i; ASSERT(dp->dtdo_refcnt == 0); for (i = 0; i < dp->dtdo_varlen; i++) { dtrace_difv_t *v = &dp->dtdo_vartab[i]; - dtrace_statvar_t *svar, **svarp; + dtrace_statvar_t *svar, **svarp = NULL; uint_t id; uint8_t scope = v->dtdv_scope; - int *np; + int *np = NULL; switch (scope) { case DIFV_SCOPE_THREAD: continue; case DIFV_SCOPE_LOCAL: np = &vstate->dtvs_nlocals; svarp = vstate->dtvs_locals; break; case DIFV_SCOPE_GLOBAL: np = &vstate->dtvs_nglobals; svarp = vstate->dtvs_globals; break; default: ASSERT(0); } if ((id = v->dtdv_id) < DIF_VAR_OTHER_UBASE) continue; id -= DIF_VAR_OTHER_UBASE; ASSERT(id < *np); svar = svarp[id]; ASSERT(svar != NULL); ASSERT(svar->dtsv_refcnt > 0); if (--svar->dtsv_refcnt > 0) continue; if (svar->dtsv_size != 0) { - ASSERT(svar->dtsv_data != NULL); + ASSERT(svar->dtsv_data != 0); kmem_free((void *)(uintptr_t)svar->dtsv_data, svar->dtsv_size); } kmem_free(svar, sizeof (dtrace_statvar_t)); svarp[id] = NULL; } - kmem_free(dp->dtdo_buf, dp->dtdo_len * sizeof (dif_instr_t)); - kmem_free(dp->dtdo_inttab, dp->dtdo_intlen * sizeof (uint64_t)); - kmem_free(dp->dtdo_strtab, dp->dtdo_strlen); - kmem_free(dp->dtdo_vartab, dp->dtdo_varlen * sizeof (dtrace_difv_t)); + if (dp->dtdo_buf != NULL) + kmem_free(dp->dtdo_buf, dp->dtdo_len * sizeof (dif_instr_t)); + if (dp->dtdo_inttab != NULL) + kmem_free(dp->dtdo_inttab, dp->dtdo_intlen * sizeof (uint64_t)); + if (dp->dtdo_strtab != NULL) + kmem_free(dp->dtdo_strtab, dp->dtdo_strlen); + if (dp->dtdo_vartab != NULL) + kmem_free(dp->dtdo_vartab, dp->dtdo_varlen * sizeof (dtrace_difv_t)); kmem_free(dp, sizeof (dtrace_difo_t)); } static void dtrace_difo_release(dtrace_difo_t *dp, dtrace_vstate_t *vstate) { int i; ASSERT(MUTEX_HELD(&dtrace_lock)); ASSERT(dp->dtdo_refcnt != 0); for (i = 0; i < dp->dtdo_varlen; i++) { dtrace_difv_t *v = &dp->dtdo_vartab[i]; if (v->dtdv_id != DIF_VAR_VTIMESTAMP) continue; ASSERT(dtrace_vtime_references > 0); if (--dtrace_vtime_references == 0) dtrace_vtime_disable(); } if (--dp->dtdo_refcnt == 0) dtrace_difo_destroy(dp, vstate); } /* * DTrace Format Functions */ static uint16_t dtrace_format_add(dtrace_state_t *state, char *str) { char *fmt, **new; uint16_t ndx, len = strlen(str) + 1; fmt = kmem_zalloc(len, KM_SLEEP); bcopy(str, fmt, len); for (ndx = 0; ndx < state->dts_nformats; ndx++) { if (state->dts_formats[ndx] == NULL) { state->dts_formats[ndx] = fmt; return (ndx + 1); } } if (state->dts_nformats == USHRT_MAX) { /* * This is only likely if a denial-of-service attack is being * attempted. As such, it's okay to fail silently here. */ kmem_free(fmt, len); return (0); } /* * For simplicity, we always resize the formats array to be exactly the * number of formats. */ ndx = state->dts_nformats++; new = kmem_alloc((ndx + 1) * sizeof (char *), KM_SLEEP); if (state->dts_formats != NULL) { ASSERT(ndx != 0); bcopy(state->dts_formats, new, ndx * sizeof (char *)); kmem_free(state->dts_formats, ndx * sizeof (char *)); } state->dts_formats = new; state->dts_formats[ndx] = fmt; return (ndx + 1); } static void dtrace_format_remove(dtrace_state_t *state, uint16_t format) { char *fmt; ASSERT(state->dts_formats != NULL); ASSERT(format <= state->dts_nformats); ASSERT(state->dts_formats[format - 1] != NULL); fmt = state->dts_formats[format - 1]; kmem_free(fmt, strlen(fmt) + 1); state->dts_formats[format - 1] = NULL; } static void dtrace_format_destroy(dtrace_state_t *state) { int i; if (state->dts_nformats == 0) { ASSERT(state->dts_formats == NULL); return; } ASSERT(state->dts_formats != NULL); for (i = 0; i < state->dts_nformats; i++) { char *fmt = state->dts_formats[i]; if (fmt == NULL) continue; kmem_free(fmt, strlen(fmt) + 1); } kmem_free(state->dts_formats, state->dts_nformats * sizeof (char *)); state->dts_nformats = 0; state->dts_formats = NULL; } /* * DTrace Predicate Functions */ static dtrace_predicate_t * dtrace_predicate_create(dtrace_difo_t *dp) { dtrace_predicate_t *pred; ASSERT(MUTEX_HELD(&dtrace_lock)); ASSERT(dp->dtdo_refcnt != 0); pred = kmem_zalloc(sizeof (dtrace_predicate_t), KM_SLEEP); pred->dtp_difo = dp; pred->dtp_refcnt = 1; if (!dtrace_difo_cacheable(dp)) return (pred); if (dtrace_predcache_id == DTRACE_CACHEIDNONE) { /* * This is only theoretically possible -- we have had 2^32 * cacheable predicates on this machine. We cannot allow any * more predicates to become cacheable: as unlikely as it is, * there may be a thread caching a (now stale) predicate cache * ID. (N.B.: the temptation is being successfully resisted to * have this cmn_err() "Holy shit -- we executed this code!") */ return (pred); } pred->dtp_cacheid = dtrace_predcache_id++; return (pred); } static void dtrace_predicate_hold(dtrace_predicate_t *pred) { ASSERT(MUTEX_HELD(&dtrace_lock)); ASSERT(pred->dtp_difo != NULL && pred->dtp_difo->dtdo_refcnt != 0); ASSERT(pred->dtp_refcnt > 0); pred->dtp_refcnt++; } static void dtrace_predicate_release(dtrace_predicate_t *pred, dtrace_vstate_t *vstate) { dtrace_difo_t *dp = pred->dtp_difo; ASSERT(MUTEX_HELD(&dtrace_lock)); ASSERT(dp != NULL && dp->dtdo_refcnt != 0); ASSERT(pred->dtp_refcnt > 0); if (--pred->dtp_refcnt == 0) { dtrace_difo_release(pred->dtp_difo, vstate); kmem_free(pred, sizeof (dtrace_predicate_t)); } } /* * DTrace Action Description Functions */ static dtrace_actdesc_t * dtrace_actdesc_create(dtrace_actkind_t kind, uint32_t ntuple, uint64_t uarg, uint64_t arg) { dtrace_actdesc_t *act; +#if defined(sun) ASSERT(!DTRACEACT_ISPRINTFLIKE(kind) || (arg != NULL && arg >= KERNELBASE) || (arg == NULL && kind == DTRACEACT_PRINTA)); +#endif act = kmem_zalloc(sizeof (dtrace_actdesc_t), KM_SLEEP); act->dtad_kind = kind; act->dtad_ntuple = ntuple; act->dtad_uarg = uarg; act->dtad_arg = arg; act->dtad_refcnt = 1; return (act); } static void dtrace_actdesc_hold(dtrace_actdesc_t *act) { ASSERT(act->dtad_refcnt >= 1); act->dtad_refcnt++; } static void dtrace_actdesc_release(dtrace_actdesc_t *act, dtrace_vstate_t *vstate) { dtrace_actkind_t kind = act->dtad_kind; dtrace_difo_t *dp; ASSERT(act->dtad_refcnt >= 1); if (--act->dtad_refcnt != 0) return; if ((dp = act->dtad_difo) != NULL) dtrace_difo_release(dp, vstate); if (DTRACEACT_ISPRINTFLIKE(kind)) { char *str = (char *)(uintptr_t)act->dtad_arg; +#if defined(sun) ASSERT((str != NULL && (uintptr_t)str >= KERNELBASE) || (str == NULL && act->dtad_kind == DTRACEACT_PRINTA)); +#endif if (str != NULL) kmem_free(str, strlen(str) + 1); } kmem_free(act, sizeof (dtrace_actdesc_t)); } /* * DTrace ECB Functions */ static dtrace_ecb_t * dtrace_ecb_add(dtrace_state_t *state, dtrace_probe_t *probe) { dtrace_ecb_t *ecb; dtrace_epid_t epid; ASSERT(MUTEX_HELD(&dtrace_lock)); ecb = kmem_zalloc(sizeof (dtrace_ecb_t), KM_SLEEP); ecb->dte_predicate = NULL; ecb->dte_probe = probe; /* * The default size is the size of the default action: recording * the epid. */ ecb->dte_size = ecb->dte_needed = sizeof (dtrace_epid_t); ecb->dte_alignment = sizeof (dtrace_epid_t); epid = state->dts_epid++; if (epid - 1 >= state->dts_necbs) { dtrace_ecb_t **oecbs = state->dts_ecbs, **ecbs; int necbs = state->dts_necbs << 1; ASSERT(epid == state->dts_necbs + 1); if (necbs == 0) { ASSERT(oecbs == NULL); necbs = 1; } ecbs = kmem_zalloc(necbs * sizeof (*ecbs), KM_SLEEP); if (oecbs != NULL) bcopy(oecbs, ecbs, state->dts_necbs * sizeof (*ecbs)); dtrace_membar_producer(); state->dts_ecbs = ecbs; if (oecbs != NULL) { /* * If this state is active, we must dtrace_sync() * before we can free the old dts_ecbs array: we're * coming in hot, and there may be active ring * buffer processing (which indexes into the dts_ecbs * array) on another CPU. */ if (state->dts_activity != DTRACE_ACTIVITY_INACTIVE) dtrace_sync(); kmem_free(oecbs, state->dts_necbs * sizeof (*ecbs)); } dtrace_membar_producer(); state->dts_necbs = necbs; } ecb->dte_state = state; ASSERT(state->dts_ecbs[epid - 1] == NULL); dtrace_membar_producer(); state->dts_ecbs[(ecb->dte_epid = epid) - 1] = ecb; return (ecb); } static void dtrace_ecb_enable(dtrace_ecb_t *ecb) { dtrace_probe_t *probe = ecb->dte_probe; ASSERT(MUTEX_HELD(&cpu_lock)); ASSERT(MUTEX_HELD(&dtrace_lock)); ASSERT(ecb->dte_next == NULL); if (probe == NULL) { /* * This is the NULL probe -- there's nothing to do. */ return; } if (probe->dtpr_ecb == NULL) { dtrace_provider_t *prov = probe->dtpr_provider; /* * We're the first ECB on this probe. */ probe->dtpr_ecb = probe->dtpr_ecb_last = ecb; if (ecb->dte_predicate != NULL) probe->dtpr_predcache = ecb->dte_predicate->dtp_cacheid; prov->dtpv_pops.dtps_enable(prov->dtpv_arg, probe->dtpr_id, probe->dtpr_arg); } else { /* * This probe is already active. Swing the last pointer to * point to the new ECB, and issue a dtrace_sync() to assure * that all CPUs have seen the change. */ ASSERT(probe->dtpr_ecb_last != NULL); probe->dtpr_ecb_last->dte_next = ecb; probe->dtpr_ecb_last = ecb; probe->dtpr_predcache = 0; dtrace_sync(); } } static void dtrace_ecb_resize(dtrace_ecb_t *ecb) { uint32_t maxalign = sizeof (dtrace_epid_t); uint32_t align = sizeof (uint8_t), offs, diff; dtrace_action_t *act; int wastuple = 0; uint32_t aggbase = UINT32_MAX; dtrace_state_t *state = ecb->dte_state; /* * If we record anything, we always record the epid. (And we always * record it first.) */ offs = sizeof (dtrace_epid_t); ecb->dte_size = ecb->dte_needed = sizeof (dtrace_epid_t); for (act = ecb->dte_action; act != NULL; act = act->dta_next) { dtrace_recdesc_t *rec = &act->dta_rec; if ((align = rec->dtrd_alignment) > maxalign) maxalign = align; if (!wastuple && act->dta_intuple) { /* * This is the first record in a tuple. Align the * offset to be at offset 4 in an 8-byte aligned * block. */ diff = offs + sizeof (dtrace_aggid_t); - if (diff = (diff & (sizeof (uint64_t) - 1))) + if ((diff = (diff & (sizeof (uint64_t) - 1)))) offs += sizeof (uint64_t) - diff; aggbase = offs - sizeof (dtrace_aggid_t); ASSERT(!(aggbase & (sizeof (uint64_t) - 1))); } /*LINTED*/ if (rec->dtrd_size != 0 && (diff = (offs & (align - 1)))) { /* * The current offset is not properly aligned; align it. */ offs += align - diff; } rec->dtrd_offset = offs; if (offs + rec->dtrd_size > ecb->dte_needed) { ecb->dte_needed = offs + rec->dtrd_size; if (ecb->dte_needed > state->dts_needed) state->dts_needed = ecb->dte_needed; } if (DTRACEACT_ISAGG(act->dta_kind)) { dtrace_aggregation_t *agg = (dtrace_aggregation_t *)act; dtrace_action_t *first = agg->dtag_first, *prev; ASSERT(rec->dtrd_size != 0 && first != NULL); ASSERT(wastuple); ASSERT(aggbase != UINT32_MAX); agg->dtag_base = aggbase; while ((prev = first->dta_prev) != NULL && DTRACEACT_ISAGG(prev->dta_kind)) { agg = (dtrace_aggregation_t *)prev; first = agg->dtag_first; } if (prev != NULL) { offs = prev->dta_rec.dtrd_offset + prev->dta_rec.dtrd_size; } else { offs = sizeof (dtrace_epid_t); } wastuple = 0; } else { if (!act->dta_intuple) ecb->dte_size = offs + rec->dtrd_size; offs += rec->dtrd_size; } wastuple = act->dta_intuple; } if ((act = ecb->dte_action) != NULL && !(act->dta_kind == DTRACEACT_SPECULATE && act->dta_next == NULL) && ecb->dte_size == sizeof (dtrace_epid_t)) { /* * If the size is still sizeof (dtrace_epid_t), then all * actions store no data; set the size to 0. */ ecb->dte_alignment = maxalign; ecb->dte_size = 0; /* * If the needed space is still sizeof (dtrace_epid_t), then * all actions need no additional space; set the needed * size to 0. */ if (ecb->dte_needed == sizeof (dtrace_epid_t)) ecb->dte_needed = 0; return; } /* * Set our alignment, and make sure that the dte_size and dte_needed * are aligned to the size of an EPID. */ ecb->dte_alignment = maxalign; ecb->dte_size = (ecb->dte_size + (sizeof (dtrace_epid_t) - 1)) & ~(sizeof (dtrace_epid_t) - 1); ecb->dte_needed = (ecb->dte_needed + (sizeof (dtrace_epid_t) - 1)) & ~(sizeof (dtrace_epid_t) - 1); ASSERT(ecb->dte_size <= ecb->dte_needed); } static dtrace_action_t * dtrace_ecb_aggregation_create(dtrace_ecb_t *ecb, dtrace_actdesc_t *desc) { dtrace_aggregation_t *agg; size_t size = sizeof (uint64_t); int ntuple = desc->dtad_ntuple; dtrace_action_t *act; dtrace_recdesc_t *frec; dtrace_aggid_t aggid; dtrace_state_t *state = ecb->dte_state; agg = kmem_zalloc(sizeof (dtrace_aggregation_t), KM_SLEEP); agg->dtag_ecb = ecb; ASSERT(DTRACEACT_ISAGG(desc->dtad_kind)); switch (desc->dtad_kind) { case DTRACEAGG_MIN: agg->dtag_initial = INT64_MAX; agg->dtag_aggregate = dtrace_aggregate_min; break; case DTRACEAGG_MAX: agg->dtag_initial = INT64_MIN; agg->dtag_aggregate = dtrace_aggregate_max; break; case DTRACEAGG_COUNT: agg->dtag_aggregate = dtrace_aggregate_count; break; case DTRACEAGG_QUANTIZE: agg->dtag_aggregate = dtrace_aggregate_quantize; size = (((sizeof (uint64_t) * NBBY) - 1) * 2 + 1) * sizeof (uint64_t); break; case DTRACEAGG_LQUANTIZE: { uint16_t step = DTRACE_LQUANTIZE_STEP(desc->dtad_arg); uint16_t levels = DTRACE_LQUANTIZE_LEVELS(desc->dtad_arg); agg->dtag_initial = desc->dtad_arg; agg->dtag_aggregate = dtrace_aggregate_lquantize; if (step == 0 || levels == 0) goto err; size = levels * sizeof (uint64_t) + 3 * sizeof (uint64_t); break; } case DTRACEAGG_AVG: agg->dtag_aggregate = dtrace_aggregate_avg; size = sizeof (uint64_t) * 2; break; case DTRACEAGG_STDDEV: agg->dtag_aggregate = dtrace_aggregate_stddev; size = sizeof (uint64_t) * 4; break; case DTRACEAGG_SUM: agg->dtag_aggregate = dtrace_aggregate_sum; break; default: goto err; } agg->dtag_action.dta_rec.dtrd_size = size; if (ntuple == 0) goto err; /* * We must make sure that we have enough actions for the n-tuple. */ for (act = ecb->dte_action_last; act != NULL; act = act->dta_prev) { if (DTRACEACT_ISAGG(act->dta_kind)) break; if (--ntuple == 0) { /* * This is the action with which our n-tuple begins. */ agg->dtag_first = act; goto success; } } /* * This n-tuple is short by ntuple elements. Return failure. */ ASSERT(ntuple != 0); err: kmem_free(agg, sizeof (dtrace_aggregation_t)); return (NULL); success: /* * If the last action in the tuple has a size of zero, it's actually * an expression argument for the aggregating action. */ ASSERT(ecb->dte_action_last != NULL); act = ecb->dte_action_last; if (act->dta_kind == DTRACEACT_DIFEXPR) { ASSERT(act->dta_difo != NULL); if (act->dta_difo->dtdo_rtype.dtdt_size == 0) agg->dtag_hasarg = 1; } /* * We need to allocate an id for this aggregation. */ +#if defined(sun) aggid = (dtrace_aggid_t)(uintptr_t)vmem_alloc(state->dts_aggid_arena, 1, VM_BESTFIT | VM_SLEEP); +#else + aggid = alloc_unr(state->dts_aggid_arena); +#endif if (aggid - 1 >= state->dts_naggregations) { dtrace_aggregation_t **oaggs = state->dts_aggregations; dtrace_aggregation_t **aggs; int naggs = state->dts_naggregations << 1; int onaggs = state->dts_naggregations; ASSERT(aggid == state->dts_naggregations + 1); if (naggs == 0) { ASSERT(oaggs == NULL); naggs = 1; } aggs = kmem_zalloc(naggs * sizeof (*aggs), KM_SLEEP); if (oaggs != NULL) { bcopy(oaggs, aggs, onaggs * sizeof (*aggs)); kmem_free(oaggs, onaggs * sizeof (*aggs)); } state->dts_aggregations = aggs; state->dts_naggregations = naggs; } ASSERT(state->dts_aggregations[aggid - 1] == NULL); state->dts_aggregations[(agg->dtag_id = aggid) - 1] = agg; frec = &agg->dtag_first->dta_rec; if (frec->dtrd_alignment < sizeof (dtrace_aggid_t)) frec->dtrd_alignment = sizeof (dtrace_aggid_t); for (act = agg->dtag_first; act != NULL; act = act->dta_next) { ASSERT(!act->dta_intuple); act->dta_intuple = 1; } return (&agg->dtag_action); } static void dtrace_ecb_aggregation_destroy(dtrace_ecb_t *ecb, dtrace_action_t *act) { dtrace_aggregation_t *agg = (dtrace_aggregation_t *)act; dtrace_state_t *state = ecb->dte_state; dtrace_aggid_t aggid = agg->dtag_id; ASSERT(DTRACEACT_ISAGG(act->dta_kind)); +#if defined(sun) vmem_free(state->dts_aggid_arena, (void *)(uintptr_t)aggid, 1); +#else + free_unr(state->dts_aggid_arena, aggid); +#endif ASSERT(state->dts_aggregations[aggid - 1] == agg); state->dts_aggregations[aggid - 1] = NULL; kmem_free(agg, sizeof (dtrace_aggregation_t)); } static int dtrace_ecb_action_add(dtrace_ecb_t *ecb, dtrace_actdesc_t *desc) { dtrace_action_t *action, *last; dtrace_difo_t *dp = desc->dtad_difo; uint32_t size = 0, align = sizeof (uint8_t), mask; uint16_t format = 0; dtrace_recdesc_t *rec; dtrace_state_t *state = ecb->dte_state; - dtrace_optval_t *opt = state->dts_options, nframes, strsize; + dtrace_optval_t *opt = state->dts_options, nframes = 0, strsize; uint64_t arg = desc->dtad_arg; ASSERT(MUTEX_HELD(&dtrace_lock)); ASSERT(ecb->dte_action == NULL || ecb->dte_action->dta_refcnt == 1); if (DTRACEACT_ISAGG(desc->dtad_kind)) { /* * If this is an aggregating action, there must be neither * a speculate nor a commit on the action chain. */ dtrace_action_t *act; for (act = ecb->dte_action; act != NULL; act = act->dta_next) { if (act->dta_kind == DTRACEACT_COMMIT) return (EINVAL); if (act->dta_kind == DTRACEACT_SPECULATE) return (EINVAL); } action = dtrace_ecb_aggregation_create(ecb, desc); if (action == NULL) return (EINVAL); } else { if (DTRACEACT_ISDESTRUCTIVE(desc->dtad_kind) || (desc->dtad_kind == DTRACEACT_DIFEXPR && dp != NULL && dp->dtdo_destructive)) { state->dts_destructive = 1; } switch (desc->dtad_kind) { case DTRACEACT_PRINTF: case DTRACEACT_PRINTA: case DTRACEACT_SYSTEM: case DTRACEACT_FREOPEN: /* * We know that our arg is a string -- turn it into a * format. */ - if (arg == NULL) { + if (arg == 0) { ASSERT(desc->dtad_kind == DTRACEACT_PRINTA); format = 0; } else { - ASSERT(arg != NULL); + ASSERT(arg != 0); +#if defined(sun) ASSERT(arg > KERNELBASE); +#endif format = dtrace_format_add(state, (char *)(uintptr_t)arg); } /*FALLTHROUGH*/ case DTRACEACT_LIBACT: case DTRACEACT_DIFEXPR: if (dp == NULL) return (EINVAL); if ((size = dp->dtdo_rtype.dtdt_size) != 0) break; if (dp->dtdo_rtype.dtdt_kind == DIF_TYPE_STRING) { if (!(dp->dtdo_rtype.dtdt_flags & DIF_TF_BYREF)) return (EINVAL); size = opt[DTRACEOPT_STRSIZE]; } break; case DTRACEACT_STACK: if ((nframes = arg) == 0) { nframes = opt[DTRACEOPT_STACKFRAMES]; ASSERT(nframes > 0); arg = nframes; } size = nframes * sizeof (pc_t); break; case DTRACEACT_JSTACK: if ((strsize = DTRACE_USTACK_STRSIZE(arg)) == 0) strsize = opt[DTRACEOPT_JSTACKSTRSIZE]; if ((nframes = DTRACE_USTACK_NFRAMES(arg)) == 0) nframes = opt[DTRACEOPT_JSTACKFRAMES]; arg = DTRACE_USTACK_ARG(nframes, strsize); /*FALLTHROUGH*/ case DTRACEACT_USTACK: if (desc->dtad_kind != DTRACEACT_JSTACK && (nframes = DTRACE_USTACK_NFRAMES(arg)) == 0) { strsize = DTRACE_USTACK_STRSIZE(arg); nframes = opt[DTRACEOPT_USTACKFRAMES]; ASSERT(nframes > 0); arg = DTRACE_USTACK_ARG(nframes, strsize); } /* * Save a slot for the pid. */ size = (nframes + 1) * sizeof (uint64_t); size += DTRACE_USTACK_STRSIZE(arg); size = P2ROUNDUP(size, (uint32_t)(sizeof (uintptr_t))); break; case DTRACEACT_SYM: case DTRACEACT_MOD: if (dp == NULL || ((size = dp->dtdo_rtype.dtdt_size) != sizeof (uint64_t)) || (dp->dtdo_rtype.dtdt_flags & DIF_TF_BYREF)) return (EINVAL); break; case DTRACEACT_USYM: case DTRACEACT_UMOD: case DTRACEACT_UADDR: if (dp == NULL || (dp->dtdo_rtype.dtdt_size != sizeof (uint64_t)) || (dp->dtdo_rtype.dtdt_flags & DIF_TF_BYREF)) return (EINVAL); /* * We have a slot for the pid, plus a slot for the * argument. To keep things simple (aligned with * bitness-neutral sizing), we store each as a 64-bit * quantity. */ size = 2 * sizeof (uint64_t); break; case DTRACEACT_STOP: case DTRACEACT_BREAKPOINT: case DTRACEACT_PANIC: break; case DTRACEACT_CHILL: case DTRACEACT_DISCARD: case DTRACEACT_RAISE: if (dp == NULL) return (EINVAL); break; case DTRACEACT_EXIT: if (dp == NULL || (size = dp->dtdo_rtype.dtdt_size) != sizeof (int) || (dp->dtdo_rtype.dtdt_flags & DIF_TF_BYREF)) return (EINVAL); break; case DTRACEACT_SPECULATE: if (ecb->dte_size > sizeof (dtrace_epid_t)) return (EINVAL); if (dp == NULL) return (EINVAL); state->dts_speculates = 1; break; + case DTRACEACT_PRINTM: + size = dp->dtdo_rtype.dtdt_size; + break; + + case DTRACEACT_PRINTT: + size = dp->dtdo_rtype.dtdt_size; + break; + case DTRACEACT_COMMIT: { dtrace_action_t *act = ecb->dte_action; for (; act != NULL; act = act->dta_next) { if (act->dta_kind == DTRACEACT_COMMIT) return (EINVAL); } if (dp == NULL) return (EINVAL); break; } default: return (EINVAL); } if (size != 0 || desc->dtad_kind == DTRACEACT_SPECULATE) { /* * If this is a data-storing action or a speculate, * we must be sure that there isn't a commit on the * action chain. */ dtrace_action_t *act = ecb->dte_action; for (; act != NULL; act = act->dta_next) { if (act->dta_kind == DTRACEACT_COMMIT) return (EINVAL); } } action = kmem_zalloc(sizeof (dtrace_action_t), KM_SLEEP); action->dta_rec.dtrd_size = size; } action->dta_refcnt = 1; rec = &action->dta_rec; size = rec->dtrd_size; for (mask = sizeof (uint64_t) - 1; size != 0 && mask > 0; mask >>= 1) { if (!(size & mask)) { align = mask + 1; break; } } action->dta_kind = desc->dtad_kind; if ((action->dta_difo = dp) != NULL) dtrace_difo_hold(dp); rec->dtrd_action = action->dta_kind; rec->dtrd_arg = arg; rec->dtrd_uarg = desc->dtad_uarg; rec->dtrd_alignment = (uint16_t)align; rec->dtrd_format = format; if ((last = ecb->dte_action_last) != NULL) { ASSERT(ecb->dte_action != NULL); action->dta_prev = last; last->dta_next = action; } else { ASSERT(ecb->dte_action == NULL); ecb->dte_action = action; } ecb->dte_action_last = action; return (0); } static void dtrace_ecb_action_remove(dtrace_ecb_t *ecb) { dtrace_action_t *act = ecb->dte_action, *next; dtrace_vstate_t *vstate = &ecb->dte_state->dts_vstate; dtrace_difo_t *dp; uint16_t format; if (act != NULL && act->dta_refcnt > 1) { ASSERT(act->dta_next == NULL || act->dta_next->dta_refcnt == 1); act->dta_refcnt--; } else { for (; act != NULL; act = next) { next = act->dta_next; ASSERT(next != NULL || act == ecb->dte_action_last); ASSERT(act->dta_refcnt == 1); if ((format = act->dta_rec.dtrd_format) != 0) dtrace_format_remove(ecb->dte_state, format); if ((dp = act->dta_difo) != NULL) dtrace_difo_release(dp, vstate); if (DTRACEACT_ISAGG(act->dta_kind)) { dtrace_ecb_aggregation_destroy(ecb, act); } else { kmem_free(act, sizeof (dtrace_action_t)); } } } ecb->dte_action = NULL; ecb->dte_action_last = NULL; ecb->dte_size = sizeof (dtrace_epid_t); } static void dtrace_ecb_disable(dtrace_ecb_t *ecb) { /* * We disable the ECB by removing it from its probe. */ dtrace_ecb_t *pecb, *prev = NULL; dtrace_probe_t *probe = ecb->dte_probe; ASSERT(MUTEX_HELD(&dtrace_lock)); if (probe == NULL) { /* * This is the NULL probe; there is nothing to disable. */ return; } for (pecb = probe->dtpr_ecb; pecb != NULL; pecb = pecb->dte_next) { if (pecb == ecb) break; prev = pecb; } ASSERT(pecb != NULL); if (prev == NULL) { probe->dtpr_ecb = ecb->dte_next; } else { prev->dte_next = ecb->dte_next; } if (ecb == probe->dtpr_ecb_last) { ASSERT(ecb->dte_next == NULL); probe->dtpr_ecb_last = prev; } /* * The ECB has been disconnected from the probe; now sync to assure * that all CPUs have seen the change before returning. */ dtrace_sync(); if (probe->dtpr_ecb == NULL) { /* * That was the last ECB on the probe; clear the predicate * cache ID for the probe, disable it and sync one more time * to assure that we'll never hit it again. */ dtrace_provider_t *prov = probe->dtpr_provider; ASSERT(ecb->dte_next == NULL); ASSERT(probe->dtpr_ecb_last == NULL); probe->dtpr_predcache = DTRACE_CACHEIDNONE; prov->dtpv_pops.dtps_disable(prov->dtpv_arg, probe->dtpr_id, probe->dtpr_arg); dtrace_sync(); } else { /* * There is at least one ECB remaining on the probe. If there * is _exactly_ one, set the probe's predicate cache ID to be * the predicate cache ID of the remaining ECB. */ ASSERT(probe->dtpr_ecb_last != NULL); ASSERT(probe->dtpr_predcache == DTRACE_CACHEIDNONE); if (probe->dtpr_ecb == probe->dtpr_ecb_last) { dtrace_predicate_t *p = probe->dtpr_ecb->dte_predicate; ASSERT(probe->dtpr_ecb->dte_next == NULL); if (p != NULL) probe->dtpr_predcache = p->dtp_cacheid; } ecb->dte_next = NULL; } } static void dtrace_ecb_destroy(dtrace_ecb_t *ecb) { dtrace_state_t *state = ecb->dte_state; dtrace_vstate_t *vstate = &state->dts_vstate; dtrace_predicate_t *pred; dtrace_epid_t epid = ecb->dte_epid; ASSERT(MUTEX_HELD(&dtrace_lock)); ASSERT(ecb->dte_next == NULL); ASSERT(ecb->dte_probe == NULL || ecb->dte_probe->dtpr_ecb != ecb); if ((pred = ecb->dte_predicate) != NULL) dtrace_predicate_release(pred, vstate); dtrace_ecb_action_remove(ecb); ASSERT(state->dts_ecbs[epid - 1] == ecb); state->dts_ecbs[epid - 1] = NULL; kmem_free(ecb, sizeof (dtrace_ecb_t)); } static dtrace_ecb_t * dtrace_ecb_create(dtrace_state_t *state, dtrace_probe_t *probe, dtrace_enabling_t *enab) { dtrace_ecb_t *ecb; dtrace_predicate_t *pred; dtrace_actdesc_t *act; dtrace_provider_t *prov; dtrace_ecbdesc_t *desc = enab->dten_current; ASSERT(MUTEX_HELD(&dtrace_lock)); ASSERT(state != NULL); ecb = dtrace_ecb_add(state, probe); ecb->dte_uarg = desc->dted_uarg; if ((pred = desc->dted_pred.dtpdd_predicate) != NULL) { dtrace_predicate_hold(pred); ecb->dte_predicate = pred; } if (probe != NULL) { /* * If the provider shows more leg than the consumer is old * enough to see, we need to enable the appropriate implicit * predicate bits to prevent the ecb from activating at * revealing times. * * Providers specifying DTRACE_PRIV_USER at register time * are stating that they need the /proc-style privilege * model to be enforced, and this is what DTRACE_COND_OWNER * and DTRACE_COND_ZONEOWNER will then do at probe time. */ prov = probe->dtpr_provider; if (!(state->dts_cred.dcr_visible & DTRACE_CRV_ALLPROC) && (prov->dtpv_priv.dtpp_flags & DTRACE_PRIV_USER)) ecb->dte_cond |= DTRACE_COND_OWNER; if (!(state->dts_cred.dcr_visible & DTRACE_CRV_ALLZONE) && (prov->dtpv_priv.dtpp_flags & DTRACE_PRIV_USER)) ecb->dte_cond |= DTRACE_COND_ZONEOWNER; /* * If the provider shows us kernel innards and the user * is lacking sufficient privilege, enable the * DTRACE_COND_USERMODE implicit predicate. */ if (!(state->dts_cred.dcr_visible & DTRACE_CRV_KERNEL) && (prov->dtpv_priv.dtpp_flags & DTRACE_PRIV_KERNEL)) ecb->dte_cond |= DTRACE_COND_USERMODE; } if (dtrace_ecb_create_cache != NULL) { /* * If we have a cached ecb, we'll use its action list instead * of creating our own (saving both time and space). */ dtrace_ecb_t *cached = dtrace_ecb_create_cache; dtrace_action_t *act = cached->dte_action; if (act != NULL) { ASSERT(act->dta_refcnt > 0); act->dta_refcnt++; ecb->dte_action = act; ecb->dte_action_last = cached->dte_action_last; ecb->dte_needed = cached->dte_needed; ecb->dte_size = cached->dte_size; ecb->dte_alignment = cached->dte_alignment; } return (ecb); } for (act = desc->dted_action; act != NULL; act = act->dtad_next) { if ((enab->dten_error = dtrace_ecb_action_add(ecb, act)) != 0) { dtrace_ecb_destroy(ecb); return (NULL); } } dtrace_ecb_resize(ecb); return (dtrace_ecb_create_cache = ecb); } static int dtrace_ecb_create_enable(dtrace_probe_t *probe, void *arg) { dtrace_ecb_t *ecb; dtrace_enabling_t *enab = arg; dtrace_state_t *state = enab->dten_vstate->dtvs_state; ASSERT(state != NULL); if (probe != NULL && probe->dtpr_gen < enab->dten_probegen) { /* * This probe was created in a generation for which this * enabling has previously created ECBs; we don't want to * enable it again, so just kick out. */ return (DTRACE_MATCH_NEXT); } if ((ecb = dtrace_ecb_create(state, probe, enab)) == NULL) return (DTRACE_MATCH_DONE); dtrace_ecb_enable(ecb); return (DTRACE_MATCH_NEXT); } static dtrace_ecb_t * dtrace_epid2ecb(dtrace_state_t *state, dtrace_epid_t id) { dtrace_ecb_t *ecb; ASSERT(MUTEX_HELD(&dtrace_lock)); if (id == 0 || id > state->dts_necbs) return (NULL); ASSERT(state->dts_necbs > 0 && state->dts_ecbs != NULL); ASSERT((ecb = state->dts_ecbs[id - 1]) == NULL || ecb->dte_epid == id); return (state->dts_ecbs[id - 1]); } static dtrace_aggregation_t * dtrace_aggid2agg(dtrace_state_t *state, dtrace_aggid_t id) { dtrace_aggregation_t *agg; ASSERT(MUTEX_HELD(&dtrace_lock)); if (id == 0 || id > state->dts_naggregations) return (NULL); ASSERT(state->dts_naggregations > 0 && state->dts_aggregations != NULL); ASSERT((agg = state->dts_aggregations[id - 1]) == NULL || agg->dtag_id == id); return (state->dts_aggregations[id - 1]); } /* * DTrace Buffer Functions * * The following functions manipulate DTrace buffers. Most of these functions * are called in the context of establishing or processing consumer state; * exceptions are explicitly noted. */ /* * Note: called from cross call context. This function switches the two * buffers on a given CPU. The atomicity of this operation is assured by * disabling interrupts while the actual switch takes place; the disabling of * interrupts serializes the execution with any execution of dtrace_probe() on * the same CPU. */ static void dtrace_buffer_switch(dtrace_buffer_t *buf) { caddr_t tomax = buf->dtb_tomax; caddr_t xamot = buf->dtb_xamot; dtrace_icookie_t cookie; ASSERT(!(buf->dtb_flags & DTRACEBUF_NOSWITCH)); ASSERT(!(buf->dtb_flags & DTRACEBUF_RING)); cookie = dtrace_interrupt_disable(); buf->dtb_tomax = xamot; buf->dtb_xamot = tomax; buf->dtb_xamot_drops = buf->dtb_drops; buf->dtb_xamot_offset = buf->dtb_offset; buf->dtb_xamot_errors = buf->dtb_errors; buf->dtb_xamot_flags = buf->dtb_flags; buf->dtb_offset = 0; buf->dtb_drops = 0; buf->dtb_errors = 0; buf->dtb_flags &= ~(DTRACEBUF_ERROR | DTRACEBUF_DROPPED); dtrace_interrupt_enable(cookie); } /* * Note: called from cross call context. This function activates a buffer * on a CPU. As with dtrace_buffer_switch(), the atomicity of the operation * is guaranteed by the disabling of interrupts. */ static void dtrace_buffer_activate(dtrace_state_t *state) { dtrace_buffer_t *buf; dtrace_icookie_t cookie = dtrace_interrupt_disable(); - buf = &state->dts_buffer[CPU->cpu_id]; + buf = &state->dts_buffer[curcpu]; if (buf->dtb_tomax != NULL) { /* * We might like to assert that the buffer is marked inactive, * but this isn't necessarily true: the buffer for the CPU * that processes the BEGIN probe has its buffer activated * manually. In this case, we take the (harmless) action * re-clearing the bit INACTIVE bit. */ buf->dtb_flags &= ~DTRACEBUF_INACTIVE; } dtrace_interrupt_enable(cookie); } static int dtrace_buffer_alloc(dtrace_buffer_t *bufs, size_t size, int flags, processorid_t cpu) { +#if defined(sun) cpu_t *cp; +#else + struct pcpu *cp; +#endif dtrace_buffer_t *buf; +#if defined(sun) ASSERT(MUTEX_HELD(&cpu_lock)); ASSERT(MUTEX_HELD(&dtrace_lock)); if (size > dtrace_nonroot_maxsize && !PRIV_POLICY_CHOICE(CRED(), PRIV_ALL, B_FALSE)) return (EFBIG); cp = cpu_list; do { if (cpu != DTRACE_CPUALL && cpu != cp->cpu_id) continue; buf = &bufs[cp->cpu_id]; /* * If there is already a buffer allocated for this CPU, it * is only possible that this is a DR event. In this case, * the buffer size must match our specified size. */ if (buf->dtb_tomax != NULL) { ASSERT(buf->dtb_size == size); continue; } ASSERT(buf->dtb_xamot == NULL); if ((buf->dtb_tomax = kmem_zalloc(size, KM_NOSLEEP)) == NULL) goto err; buf->dtb_size = size; buf->dtb_flags = flags; buf->dtb_offset = 0; buf->dtb_drops = 0; if (flags & DTRACEBUF_NOSWITCH) continue; if ((buf->dtb_xamot = kmem_zalloc(size, KM_NOSLEEP)) == NULL) goto err; } while ((cp = cp->cpu_next) != cpu_list); return (0); err: cp = cpu_list; do { if (cpu != DTRACE_CPUALL && cpu != cp->cpu_id) continue; buf = &bufs[cp->cpu_id]; if (buf->dtb_xamot != NULL) { ASSERT(buf->dtb_tomax != NULL); ASSERT(buf->dtb_size == size); kmem_free(buf->dtb_xamot, size); } if (buf->dtb_tomax != NULL) { ASSERT(buf->dtb_size == size); kmem_free(buf->dtb_tomax, size); } buf->dtb_tomax = NULL; buf->dtb_xamot = NULL; buf->dtb_size = 0; } while ((cp = cp->cpu_next) != cpu_list); return (ENOMEM); +#else + int i; + +#if defined(__amd64__) + /* + * FreeBSD isn't good at limiting the amount of memory we + * ask to malloc, so let's place a limit here before trying + * to do something that might well end in tears at bedtime. + */ + if (size > physmem * PAGE_SIZE / (128 * (mp_maxid + 1))) + return(ENOMEM); +#endif + + ASSERT(MUTEX_HELD(&dtrace_lock)); + for (i = 0; i <= mp_maxid; i++) { + if ((cp = pcpu_find(i)) == NULL) + continue; + + if (cpu != DTRACE_CPUALL && cpu != i) + continue; + + buf = &bufs[i]; + + /* + * If there is already a buffer allocated for this CPU, it + * is only possible that this is a DR event. In this case, + * the buffer size must match our specified size. + */ + if (buf->dtb_tomax != NULL) { + ASSERT(buf->dtb_size == size); + continue; + } + + ASSERT(buf->dtb_xamot == NULL); + + if ((buf->dtb_tomax = kmem_zalloc(size, KM_NOSLEEP)) == NULL) + goto err; + + buf->dtb_size = size; + buf->dtb_flags = flags; + buf->dtb_offset = 0; + buf->dtb_drops = 0; + + if (flags & DTRACEBUF_NOSWITCH) + continue; + + if ((buf->dtb_xamot = kmem_zalloc(size, KM_NOSLEEP)) == NULL) + goto err; + } + + return (0); + +err: + /* + * Error allocating memory, so free the buffers that were + * allocated before the failed allocation. + */ + for (i = 0; i <= mp_maxid; i++) { + if ((cp = pcpu_find(i)) == NULL) + continue; + + if (cpu != DTRACE_CPUALL && cpu != i) + continue; + + buf = &bufs[i]; + + if (buf->dtb_xamot != NULL) { + ASSERT(buf->dtb_tomax != NULL); + ASSERT(buf->dtb_size == size); + kmem_free(buf->dtb_xamot, size); + } + + if (buf->dtb_tomax != NULL) { + ASSERT(buf->dtb_size == size); + kmem_free(buf->dtb_tomax, size); + } + + buf->dtb_tomax = NULL; + buf->dtb_xamot = NULL; + buf->dtb_size = 0; + + } + + return (ENOMEM); +#endif } /* * Note: called from probe context. This function just increments the drop * count on a buffer. It has been made a function to allow for the * possibility of understanding the source of mysterious drop counts. (A * problem for which one may be particularly disappointed that DTrace cannot * be used to understand DTrace.) */ static void dtrace_buffer_drop(dtrace_buffer_t *buf) { buf->dtb_drops++; } /* * Note: called from probe context. This function is called to reserve space * in a buffer. If mstate is non-NULL, sets the scratch base and size in the * mstate. Returns the new offset in the buffer, or a negative value if an * error has occurred. */ static intptr_t dtrace_buffer_reserve(dtrace_buffer_t *buf, size_t needed, size_t align, dtrace_state_t *state, dtrace_mstate_t *mstate) { intptr_t offs = buf->dtb_offset, soffs; intptr_t woffs; caddr_t tomax; size_t total; if (buf->dtb_flags & DTRACEBUF_INACTIVE) return (-1); if ((tomax = buf->dtb_tomax) == NULL) { dtrace_buffer_drop(buf); return (-1); } if (!(buf->dtb_flags & (DTRACEBUF_RING | DTRACEBUF_FILL))) { while (offs & (align - 1)) { /* * Assert that our alignment is off by a number which * is itself sizeof (uint32_t) aligned. */ ASSERT(!((align - (offs & (align - 1))) & (sizeof (uint32_t) - 1))); DTRACE_STORE(uint32_t, tomax, offs, DTRACE_EPIDNONE); offs += sizeof (uint32_t); } if ((soffs = offs + needed) > buf->dtb_size) { dtrace_buffer_drop(buf); return (-1); } if (mstate == NULL) return (offs); mstate->dtms_scratch_base = (uintptr_t)tomax + soffs; mstate->dtms_scratch_size = buf->dtb_size - soffs; mstate->dtms_scratch_ptr = mstate->dtms_scratch_base; return (offs); } if (buf->dtb_flags & DTRACEBUF_FILL) { if (state->dts_activity != DTRACE_ACTIVITY_COOLDOWN && (buf->dtb_flags & DTRACEBUF_FULL)) return (-1); goto out; } total = needed + (offs & (align - 1)); /* * For a ring buffer, life is quite a bit more complicated. Before * we can store any padding, we need to adjust our wrapping offset. * (If we've never before wrapped or we're not about to, no adjustment * is required.) */ if ((buf->dtb_flags & DTRACEBUF_WRAPPED) || offs + total > buf->dtb_size) { woffs = buf->dtb_xamot_offset; if (offs + total > buf->dtb_size) { /* * We can't fit in the end of the buffer. First, a * sanity check that we can fit in the buffer at all. */ if (total > buf->dtb_size) { dtrace_buffer_drop(buf); return (-1); } /* * We're going to be storing at the top of the buffer, * so now we need to deal with the wrapped offset. We * only reset our wrapped offset to 0 if it is * currently greater than the current offset. If it * is less than the current offset, it is because a * previous allocation induced a wrap -- but the * allocation didn't subsequently take the space due * to an error or false predicate evaluation. In this * case, we'll just leave the wrapped offset alone: if * the wrapped offset hasn't been advanced far enough * for this allocation, it will be adjusted in the * lower loop. */ if (buf->dtb_flags & DTRACEBUF_WRAPPED) { if (woffs >= offs) woffs = 0; } else { woffs = 0; } /* * Now we know that we're going to be storing to the * top of the buffer and that there is room for us * there. We need to clear the buffer from the current * offset to the end (there may be old gunk there). */ while (offs < buf->dtb_size) tomax[offs++] = 0; /* * We need to set our offset to zero. And because we * are wrapping, we need to set the bit indicating as * much. We can also adjust our needed space back * down to the space required by the ECB -- we know * that the top of the buffer is aligned. */ offs = 0; total = needed; buf->dtb_flags |= DTRACEBUF_WRAPPED; } else { /* * There is room for us in the buffer, so we simply * need to check the wrapped offset. */ if (woffs < offs) { /* * The wrapped offset is less than the offset. * This can happen if we allocated buffer space * that induced a wrap, but then we didn't * subsequently take the space due to an error * or false predicate evaluation. This is * okay; we know that _this_ allocation isn't * going to induce a wrap. We still can't * reset the wrapped offset to be zero, * however: the space may have been trashed in * the previous failed probe attempt. But at * least the wrapped offset doesn't need to * be adjusted at all... */ goto out; } } while (offs + total > woffs) { dtrace_epid_t epid = *(uint32_t *)(tomax + woffs); size_t size; if (epid == DTRACE_EPIDNONE) { size = sizeof (uint32_t); } else { ASSERT(epid <= state->dts_necbs); ASSERT(state->dts_ecbs[epid - 1] != NULL); size = state->dts_ecbs[epid - 1]->dte_size; } ASSERT(woffs + size <= buf->dtb_size); ASSERT(size != 0); if (woffs + size == buf->dtb_size) { /* * We've reached the end of the buffer; we want * to set the wrapped offset to 0 and break * out. However, if the offs is 0, then we're * in a strange edge-condition: the amount of * space that we want to reserve plus the size * of the record that we're overwriting is * greater than the size of the buffer. This * is problematic because if we reserve the * space but subsequently don't consume it (due * to a failed predicate or error) the wrapped * offset will be 0 -- yet the EPID at offset 0 * will not be committed. This situation is * relatively easy to deal with: if we're in * this case, the buffer is indistinguishable * from one that hasn't wrapped; we need only * finish the job by clearing the wrapped bit, * explicitly setting the offset to be 0, and * zero'ing out the old data in the buffer. */ if (offs == 0) { buf->dtb_flags &= ~DTRACEBUF_WRAPPED; buf->dtb_offset = 0; woffs = total; while (woffs < buf->dtb_size) tomax[woffs++] = 0; } woffs = 0; break; } woffs += size; } /* * We have a wrapped offset. It may be that the wrapped offset * has become zero -- that's okay. */ buf->dtb_xamot_offset = woffs; } out: /* * Now we can plow the buffer with any necessary padding. */ while (offs & (align - 1)) { /* * Assert that our alignment is off by a number which * is itself sizeof (uint32_t) aligned. */ ASSERT(!((align - (offs & (align - 1))) & (sizeof (uint32_t) - 1))); DTRACE_STORE(uint32_t, tomax, offs, DTRACE_EPIDNONE); offs += sizeof (uint32_t); } if (buf->dtb_flags & DTRACEBUF_FILL) { if (offs + needed > buf->dtb_size - state->dts_reserve) { buf->dtb_flags |= DTRACEBUF_FULL; return (-1); } } if (mstate == NULL) return (offs); /* * For ring buffers and fill buffers, the scratch space is always * the inactive buffer. */ mstate->dtms_scratch_base = (uintptr_t)buf->dtb_xamot; mstate->dtms_scratch_size = buf->dtb_size; mstate->dtms_scratch_ptr = mstate->dtms_scratch_base; return (offs); } static void dtrace_buffer_polish(dtrace_buffer_t *buf) { ASSERT(buf->dtb_flags & DTRACEBUF_RING); ASSERT(MUTEX_HELD(&dtrace_lock)); if (!(buf->dtb_flags & DTRACEBUF_WRAPPED)) return; /* * We need to polish the ring buffer. There are three cases: * * - The first (and presumably most common) is that there is no gap * between the buffer offset and the wrapped offset. In this case, * there is nothing in the buffer that isn't valid data; we can * mark the buffer as polished and return. * * - The second (less common than the first but still more common * than the third) is that there is a gap between the buffer offset * and the wrapped offset, and the wrapped offset is larger than the * buffer offset. This can happen because of an alignment issue, or * can happen because of a call to dtrace_buffer_reserve() that * didn't subsequently consume the buffer space. In this case, * we need to zero the data from the buffer offset to the wrapped * offset. * * - The third (and least common) is that there is a gap between the * buffer offset and the wrapped offset, but the wrapped offset is * _less_ than the buffer offset. This can only happen because a * call to dtrace_buffer_reserve() induced a wrap, but the space * was not subsequently consumed. In this case, we need to zero the * space from the offset to the end of the buffer _and_ from the * top of the buffer to the wrapped offset. */ if (buf->dtb_offset < buf->dtb_xamot_offset) { bzero(buf->dtb_tomax + buf->dtb_offset, buf->dtb_xamot_offset - buf->dtb_offset); } if (buf->dtb_offset > buf->dtb_xamot_offset) { bzero(buf->dtb_tomax + buf->dtb_offset, buf->dtb_size - buf->dtb_offset); bzero(buf->dtb_tomax, buf->dtb_xamot_offset); } } static void dtrace_buffer_free(dtrace_buffer_t *bufs) { int i; for (i = 0; i < NCPU; i++) { dtrace_buffer_t *buf = &bufs[i]; if (buf->dtb_tomax == NULL) { ASSERT(buf->dtb_xamot == NULL); ASSERT(buf->dtb_size == 0); continue; } if (buf->dtb_xamot != NULL) { ASSERT(!(buf->dtb_flags & DTRACEBUF_NOSWITCH)); kmem_free(buf->dtb_xamot, buf->dtb_size); } kmem_free(buf->dtb_tomax, buf->dtb_size); buf->dtb_size = 0; buf->dtb_tomax = NULL; buf->dtb_xamot = NULL; } } /* * DTrace Enabling Functions */ static dtrace_enabling_t * dtrace_enabling_create(dtrace_vstate_t *vstate) { dtrace_enabling_t *enab; enab = kmem_zalloc(sizeof (dtrace_enabling_t), KM_SLEEP); enab->dten_vstate = vstate; return (enab); } static void dtrace_enabling_add(dtrace_enabling_t *enab, dtrace_ecbdesc_t *ecb) { dtrace_ecbdesc_t **ndesc; size_t osize, nsize; /* * We can't add to enablings after we've enabled them, or after we've * retained them. */ ASSERT(enab->dten_probegen == 0); ASSERT(enab->dten_next == NULL && enab->dten_prev == NULL); if (enab->dten_ndesc < enab->dten_maxdesc) { enab->dten_desc[enab->dten_ndesc++] = ecb; return; } osize = enab->dten_maxdesc * sizeof (dtrace_enabling_t *); if (enab->dten_maxdesc == 0) { enab->dten_maxdesc = 1; } else { enab->dten_maxdesc <<= 1; } ASSERT(enab->dten_ndesc < enab->dten_maxdesc); nsize = enab->dten_maxdesc * sizeof (dtrace_enabling_t *); ndesc = kmem_zalloc(nsize, KM_SLEEP); bcopy(enab->dten_desc, ndesc, osize); - kmem_free(enab->dten_desc, osize); + if (enab->dten_desc != NULL) + kmem_free(enab->dten_desc, osize); enab->dten_desc = ndesc; enab->dten_desc[enab->dten_ndesc++] = ecb; } static void dtrace_enabling_addlike(dtrace_enabling_t *enab, dtrace_ecbdesc_t *ecb, dtrace_probedesc_t *pd) { dtrace_ecbdesc_t *new; dtrace_predicate_t *pred; dtrace_actdesc_t *act; /* * We're going to create a new ECB description that matches the * specified ECB in every way, but has the specified probe description. */ new = kmem_zalloc(sizeof (dtrace_ecbdesc_t), KM_SLEEP); if ((pred = ecb->dted_pred.dtpdd_predicate) != NULL) dtrace_predicate_hold(pred); for (act = ecb->dted_action; act != NULL; act = act->dtad_next) dtrace_actdesc_hold(act); new->dted_action = ecb->dted_action; new->dted_pred = ecb->dted_pred; new->dted_probe = *pd; new->dted_uarg = ecb->dted_uarg; dtrace_enabling_add(enab, new); } static void dtrace_enabling_dump(dtrace_enabling_t *enab) { int i; for (i = 0; i < enab->dten_ndesc; i++) { dtrace_probedesc_t *desc = &enab->dten_desc[i]->dted_probe; cmn_err(CE_NOTE, "enabling probe %d (%s:%s:%s:%s)", i, desc->dtpd_provider, desc->dtpd_mod, desc->dtpd_func, desc->dtpd_name); } } static void dtrace_enabling_destroy(dtrace_enabling_t *enab) { int i; dtrace_ecbdesc_t *ep; dtrace_vstate_t *vstate = enab->dten_vstate; ASSERT(MUTEX_HELD(&dtrace_lock)); for (i = 0; i < enab->dten_ndesc; i++) { dtrace_actdesc_t *act, *next; dtrace_predicate_t *pred; ep = enab->dten_desc[i]; if ((pred = ep->dted_pred.dtpdd_predicate) != NULL) dtrace_predicate_release(pred, vstate); for (act = ep->dted_action; act != NULL; act = next) { next = act->dtad_next; dtrace_actdesc_release(act, vstate); } kmem_free(ep, sizeof (dtrace_ecbdesc_t)); } - kmem_free(enab->dten_desc, - enab->dten_maxdesc * sizeof (dtrace_enabling_t *)); + if (enab->dten_desc != NULL) + kmem_free(enab->dten_desc, + enab->dten_maxdesc * sizeof (dtrace_enabling_t *)); /* * If this was a retained enabling, decrement the dts_nretained count * and take it off of the dtrace_retained list. */ if (enab->dten_prev != NULL || enab->dten_next != NULL || dtrace_retained == enab) { ASSERT(enab->dten_vstate->dtvs_state != NULL); ASSERT(enab->dten_vstate->dtvs_state->dts_nretained > 0); enab->dten_vstate->dtvs_state->dts_nretained--; } if (enab->dten_prev == NULL) { if (dtrace_retained == enab) { dtrace_retained = enab->dten_next; if (dtrace_retained != NULL) dtrace_retained->dten_prev = NULL; } } else { ASSERT(enab != dtrace_retained); ASSERT(dtrace_retained != NULL); enab->dten_prev->dten_next = enab->dten_next; } if (enab->dten_next != NULL) { ASSERT(dtrace_retained != NULL); enab->dten_next->dten_prev = enab->dten_prev; } kmem_free(enab, sizeof (dtrace_enabling_t)); } static int dtrace_enabling_retain(dtrace_enabling_t *enab) { dtrace_state_t *state; ASSERT(MUTEX_HELD(&dtrace_lock)); ASSERT(enab->dten_next == NULL && enab->dten_prev == NULL); ASSERT(enab->dten_vstate != NULL); state = enab->dten_vstate->dtvs_state; ASSERT(state != NULL); /* * We only allow each state to retain dtrace_retain_max enablings. */ if (state->dts_nretained >= dtrace_retain_max) return (ENOSPC); state->dts_nretained++; if (dtrace_retained == NULL) { dtrace_retained = enab; return (0); } enab->dten_next = dtrace_retained; dtrace_retained->dten_prev = enab; dtrace_retained = enab; return (0); } static int dtrace_enabling_replicate(dtrace_state_t *state, dtrace_probedesc_t *match, dtrace_probedesc_t *create) { dtrace_enabling_t *new, *enab; int found = 0, err = ENOENT; ASSERT(MUTEX_HELD(&dtrace_lock)); ASSERT(strlen(match->dtpd_provider) < DTRACE_PROVNAMELEN); ASSERT(strlen(match->dtpd_mod) < DTRACE_MODNAMELEN); ASSERT(strlen(match->dtpd_func) < DTRACE_FUNCNAMELEN); ASSERT(strlen(match->dtpd_name) < DTRACE_NAMELEN); new = dtrace_enabling_create(&state->dts_vstate); /* * Iterate over all retained enablings, looking for enablings that * match the specified state. */ for (enab = dtrace_retained; enab != NULL; enab = enab->dten_next) { int i; /* * dtvs_state can only be NULL for helper enablings -- and * helper enablings can't be retained. */ ASSERT(enab->dten_vstate->dtvs_state != NULL); if (enab->dten_vstate->dtvs_state != state) continue; /* * Now iterate over each probe description; we're looking for * an exact match to the specified probe description. */ for (i = 0; i < enab->dten_ndesc; i++) { dtrace_ecbdesc_t *ep = enab->dten_desc[i]; dtrace_probedesc_t *pd = &ep->dted_probe; if (strcmp(pd->dtpd_provider, match->dtpd_provider)) continue; if (strcmp(pd->dtpd_mod, match->dtpd_mod)) continue; if (strcmp(pd->dtpd_func, match->dtpd_func)) continue; if (strcmp(pd->dtpd_name, match->dtpd_name)) continue; /* * We have a winning probe! Add it to our growing * enabling. */ found = 1; dtrace_enabling_addlike(new, ep, create); } } if (!found || (err = dtrace_enabling_retain(new)) != 0) { dtrace_enabling_destroy(new); return (err); } return (0); } static void dtrace_enabling_retract(dtrace_state_t *state) { dtrace_enabling_t *enab, *next; ASSERT(MUTEX_HELD(&dtrace_lock)); /* * Iterate over all retained enablings, destroy the enablings retained * for the specified state. */ for (enab = dtrace_retained; enab != NULL; enab = next) { next = enab->dten_next; /* * dtvs_state can only be NULL for helper enablings -- and * helper enablings can't be retained. */ ASSERT(enab->dten_vstate->dtvs_state != NULL); if (enab->dten_vstate->dtvs_state == state) { ASSERT(state->dts_nretained > 0); dtrace_enabling_destroy(enab); } } ASSERT(state->dts_nretained == 0); } static int dtrace_enabling_match(dtrace_enabling_t *enab, int *nmatched) { int i = 0; int matched = 0; ASSERT(MUTEX_HELD(&cpu_lock)); ASSERT(MUTEX_HELD(&dtrace_lock)); for (i = 0; i < enab->dten_ndesc; i++) { dtrace_ecbdesc_t *ep = enab->dten_desc[i]; enab->dten_current = ep; enab->dten_error = 0; matched += dtrace_probe_enable(&ep->dted_probe, enab); if (enab->dten_error != 0) { /* * If we get an error half-way through enabling the * probes, we kick out -- perhaps with some number of * them enabled. Leaving enabled probes enabled may * be slightly confusing for user-level, but we expect * that no one will attempt to actually drive on in * the face of such errors. If this is an anonymous * enabling (indicated with a NULL nmatched pointer), * we cmn_err() a message. We aren't expecting to * get such an error -- such as it can exist at all, * it would be a result of corrupted DOF in the driver * properties. */ if (nmatched == NULL) { cmn_err(CE_WARN, "dtrace_enabling_match() " "error on %p: %d", (void *)ep, enab->dten_error); } return (enab->dten_error); } } enab->dten_probegen = dtrace_probegen; if (nmatched != NULL) *nmatched = matched; return (0); } static void dtrace_enabling_matchall(void) { dtrace_enabling_t *enab; mutex_enter(&cpu_lock); mutex_enter(&dtrace_lock); /* * Because we can be called after dtrace_detach() has been called, we * cannot assert that there are retained enablings. We can safely * load from dtrace_retained, however: the taskq_destroy() at the * end of dtrace_detach() will block pending our completion. */ for (enab = dtrace_retained; enab != NULL; enab = enab->dten_next) (void) dtrace_enabling_match(enab, NULL); mutex_exit(&dtrace_lock); mutex_exit(&cpu_lock); } -static int -dtrace_enabling_matchstate(dtrace_state_t *state, int *nmatched) -{ - dtrace_enabling_t *enab; - int matched, total = 0, err; - - ASSERT(MUTEX_HELD(&cpu_lock)); - ASSERT(MUTEX_HELD(&dtrace_lock)); - - for (enab = dtrace_retained; enab != NULL; enab = enab->dten_next) { - ASSERT(enab->dten_vstate->dtvs_state != NULL); - - if (enab->dten_vstate->dtvs_state != state) - continue; - - if ((err = dtrace_enabling_match(enab, &matched)) != 0) - return (err); - - total += matched; - } - - if (nmatched != NULL) - *nmatched = total; - - return (0); -} - /* * If an enabling is to be enabled without having matched probes (that is, if * dtrace_state_go() is to be called on the underlying dtrace_state_t), the * enabling must be _primed_ by creating an ECB for every ECB description. * This must be done to assure that we know the number of speculations, the * number of aggregations, the minimum buffer size needed, etc. before we * transition out of DTRACE_ACTIVITY_INACTIVE. To do this without actually * enabling any probes, we create ECBs for every ECB decription, but with a * NULL probe -- which is exactly what this function does. */ static void dtrace_enabling_prime(dtrace_state_t *state) { dtrace_enabling_t *enab; int i; for (enab = dtrace_retained; enab != NULL; enab = enab->dten_next) { ASSERT(enab->dten_vstate->dtvs_state != NULL); if (enab->dten_vstate->dtvs_state != state) continue; /* * We don't want to prime an enabling more than once, lest * we allow a malicious user to induce resource exhaustion. * (The ECBs that result from priming an enabling aren't * leaked -- but they also aren't deallocated until the * consumer state is destroyed.) */ if (enab->dten_primed) continue; for (i = 0; i < enab->dten_ndesc; i++) { enab->dten_current = enab->dten_desc[i]; (void) dtrace_probe_enable(NULL, enab); } enab->dten_primed = 1; } } /* * Called to indicate that probes should be provided due to retained * enablings. This is implemented in terms of dtrace_probe_provide(), but it * must take an initial lap through the enabling calling the dtps_provide() * entry point explicitly to allow for autocreated probes. */ static void dtrace_enabling_provide(dtrace_provider_t *prv) { int i, all = 0; dtrace_probedesc_t desc; ASSERT(MUTEX_HELD(&dtrace_lock)); ASSERT(MUTEX_HELD(&dtrace_provider_lock)); if (prv == NULL) { all = 1; prv = dtrace_provider; } do { dtrace_enabling_t *enab = dtrace_retained; void *parg = prv->dtpv_arg; for (; enab != NULL; enab = enab->dten_next) { for (i = 0; i < enab->dten_ndesc; i++) { desc = enab->dten_desc[i]->dted_probe; mutex_exit(&dtrace_lock); prv->dtpv_pops.dtps_provide(parg, &desc); mutex_enter(&dtrace_lock); } } } while (all && (prv = prv->dtpv_next) != NULL); mutex_exit(&dtrace_lock); dtrace_probe_provide(NULL, all ? NULL : prv); mutex_enter(&dtrace_lock); } /* * DTrace DOF Functions */ /*ARGSUSED*/ static void dtrace_dof_error(dof_hdr_t *dof, const char *str) { if (dtrace_err_verbose) cmn_err(CE_WARN, "failed to process DOF: %s", str); #ifdef DTRACE_ERRDEBUG dtrace_errdebug(str); #endif } /* * Create DOF out of a currently enabled state. Right now, we only create * DOF containing the run-time options -- but this could be expanded to create * complete DOF representing the enabled state. */ static dof_hdr_t * dtrace_dof_create(dtrace_state_t *state) { dof_hdr_t *dof; dof_sec_t *sec; dof_optdesc_t *opt; int i, len = sizeof (dof_hdr_t) + roundup(sizeof (dof_sec_t), sizeof (uint64_t)) + sizeof (dof_optdesc_t) * DTRACEOPT_MAX; ASSERT(MUTEX_HELD(&dtrace_lock)); dof = kmem_zalloc(len, KM_SLEEP); dof->dofh_ident[DOF_ID_MAG0] = DOF_MAG_MAG0; dof->dofh_ident[DOF_ID_MAG1] = DOF_MAG_MAG1; dof->dofh_ident[DOF_ID_MAG2] = DOF_MAG_MAG2; dof->dofh_ident[DOF_ID_MAG3] = DOF_MAG_MAG3; dof->dofh_ident[DOF_ID_MODEL] = DOF_MODEL_NATIVE; dof->dofh_ident[DOF_ID_ENCODING] = DOF_ENCODE_NATIVE; dof->dofh_ident[DOF_ID_VERSION] = DOF_VERSION; dof->dofh_ident[DOF_ID_DIFVERS] = DIF_VERSION; dof->dofh_ident[DOF_ID_DIFIREG] = DIF_DIR_NREGS; dof->dofh_ident[DOF_ID_DIFTREG] = DIF_DTR_NREGS; dof->dofh_flags = 0; dof->dofh_hdrsize = sizeof (dof_hdr_t); dof->dofh_secsize = sizeof (dof_sec_t); dof->dofh_secnum = 1; /* only DOF_SECT_OPTDESC */ dof->dofh_secoff = sizeof (dof_hdr_t); dof->dofh_loadsz = len; dof->dofh_filesz = len; dof->dofh_pad = 0; /* * Fill in the option section header... */ sec = (dof_sec_t *)((uintptr_t)dof + sizeof (dof_hdr_t)); sec->dofs_type = DOF_SECT_OPTDESC; sec->dofs_align = sizeof (uint64_t); sec->dofs_flags = DOF_SECF_LOAD; sec->dofs_entsize = sizeof (dof_optdesc_t); opt = (dof_optdesc_t *)((uintptr_t)sec + roundup(sizeof (dof_sec_t), sizeof (uint64_t))); sec->dofs_offset = (uintptr_t)opt - (uintptr_t)dof; sec->dofs_size = sizeof (dof_optdesc_t) * DTRACEOPT_MAX; for (i = 0; i < DTRACEOPT_MAX; i++) { opt[i].dofo_option = i; opt[i].dofo_strtab = DOF_SECIDX_NONE; opt[i].dofo_value = state->dts_options[i]; } return (dof); } static dof_hdr_t * dtrace_dof_copyin(uintptr_t uarg, int *errp) { dof_hdr_t hdr, *dof; ASSERT(!MUTEX_HELD(&dtrace_lock)); /* * First, we're going to copyin() the sizeof (dof_hdr_t). */ if (copyin((void *)uarg, &hdr, sizeof (hdr)) != 0) { dtrace_dof_error(NULL, "failed to copyin DOF header"); *errp = EFAULT; return (NULL); } /* * Now we'll allocate the entire DOF and copy it in -- provided * that the length isn't outrageous. */ if (hdr.dofh_loadsz >= dtrace_dof_maxsize) { dtrace_dof_error(&hdr, "load size exceeds maximum"); *errp = E2BIG; return (NULL); } if (hdr.dofh_loadsz < sizeof (hdr)) { dtrace_dof_error(&hdr, "invalid load size"); *errp = EINVAL; return (NULL); } dof = kmem_alloc(hdr.dofh_loadsz, KM_SLEEP); if (copyin((void *)uarg, dof, hdr.dofh_loadsz) != 0) { kmem_free(dof, hdr.dofh_loadsz); *errp = EFAULT; return (NULL); } return (dof); } +#if !defined(sun) +static __inline uchar_t +dtrace_dof_char(char c) { + switch (c) { + case '0': + case '1': + case '2': + case '3': + case '4': + case '5': + case '6': + case '7': + case '8': + case '9': + return (c - '0'); + case 'A': + case 'B': + case 'C': + case 'D': + case 'E': + case 'F': + return (c - 'A' + 10); + case 'a': + case 'b': + case 'c': + case 'd': + case 'e': + case 'f': + return (c - 'a' + 10); + } + /* Should not reach here. */ + return (0); +} +#endif + static dof_hdr_t * dtrace_dof_property(const char *name) { uchar_t *buf; uint64_t loadsz; unsigned int len, i; dof_hdr_t *dof; +#if defined(sun) /* * Unfortunately, array of values in .conf files are always (and * only) interpreted to be integer arrays. We must read our DOF * as an integer array, and then squeeze it into a byte array. */ if (ddi_prop_lookup_int_array(DDI_DEV_T_ANY, dtrace_devi, 0, (char *)name, (int **)&buf, &len) != DDI_PROP_SUCCESS) return (NULL); for (i = 0; i < len; i++) buf[i] = (uchar_t)(((int *)buf)[i]); if (len < sizeof (dof_hdr_t)) { ddi_prop_free(buf); dtrace_dof_error(NULL, "truncated header"); return (NULL); } if (len < (loadsz = ((dof_hdr_t *)buf)->dofh_loadsz)) { ddi_prop_free(buf); dtrace_dof_error(NULL, "truncated DOF"); return (NULL); } if (loadsz >= dtrace_dof_maxsize) { ddi_prop_free(buf); dtrace_dof_error(NULL, "oversized DOF"); return (NULL); } dof = kmem_alloc(loadsz, KM_SLEEP); bcopy(buf, dof, loadsz); ddi_prop_free(buf); +#else + char *p; + char *p_env; + if ((p_env = getenv(name)) == NULL) + return (NULL); + + len = strlen(p_env) / 2; + + buf = kmem_alloc(len, KM_SLEEP); + + dof = (dof_hdr_t *) buf; + + p = p_env; + + for (i = 0; i < len; i++) { + buf[i] = (dtrace_dof_char(p[0]) << 4) | + dtrace_dof_char(p[1]); + p += 2; + } + + freeenv(p_env); + + if (len < sizeof (dof_hdr_t)) { + kmem_free(buf, 0); + dtrace_dof_error(NULL, "truncated header"); + return (NULL); + } + + if (len < (loadsz = dof->dofh_loadsz)) { + kmem_free(buf, 0); + dtrace_dof_error(NULL, "truncated DOF"); + return (NULL); + } + + if (loadsz >= dtrace_dof_maxsize) { + kmem_free(buf, 0); + dtrace_dof_error(NULL, "oversized DOF"); + return (NULL); + } +#endif + return (dof); } static void dtrace_dof_destroy(dof_hdr_t *dof) { kmem_free(dof, dof->dofh_loadsz); } /* * Return the dof_sec_t pointer corresponding to a given section index. If the * index is not valid, dtrace_dof_error() is called and NULL is returned. If * a type other than DOF_SECT_NONE is specified, the header is checked against * this type and NULL is returned if the types do not match. */ static dof_sec_t * dtrace_dof_sect(dof_hdr_t *dof, uint32_t type, dof_secidx_t i) { dof_sec_t *sec = (dof_sec_t *)(uintptr_t) ((uintptr_t)dof + dof->dofh_secoff + i * dof->dofh_secsize); if (i >= dof->dofh_secnum) { dtrace_dof_error(dof, "referenced section index is invalid"); return (NULL); } if (!(sec->dofs_flags & DOF_SECF_LOAD)) { dtrace_dof_error(dof, "referenced section is not loadable"); return (NULL); } if (type != DOF_SECT_NONE && type != sec->dofs_type) { dtrace_dof_error(dof, "referenced section is the wrong type"); return (NULL); } return (sec); } static dtrace_probedesc_t * dtrace_dof_probedesc(dof_hdr_t *dof, dof_sec_t *sec, dtrace_probedesc_t *desc) { dof_probedesc_t *probe; dof_sec_t *strtab; uintptr_t daddr = (uintptr_t)dof; uintptr_t str; size_t size; if (sec->dofs_type != DOF_SECT_PROBEDESC) { dtrace_dof_error(dof, "invalid probe section"); return (NULL); } if (sec->dofs_align != sizeof (dof_secidx_t)) { dtrace_dof_error(dof, "bad alignment in probe description"); return (NULL); } if (sec->dofs_offset + sizeof (dof_probedesc_t) > dof->dofh_loadsz) { dtrace_dof_error(dof, "truncated probe description"); return (NULL); } probe = (dof_probedesc_t *)(uintptr_t)(daddr + sec->dofs_offset); strtab = dtrace_dof_sect(dof, DOF_SECT_STRTAB, probe->dofp_strtab); if (strtab == NULL) return (NULL); str = daddr + strtab->dofs_offset; size = strtab->dofs_size; if (probe->dofp_provider >= strtab->dofs_size) { dtrace_dof_error(dof, "corrupt probe provider"); return (NULL); } (void) strncpy(desc->dtpd_provider, (char *)(str + probe->dofp_provider), MIN(DTRACE_PROVNAMELEN - 1, size - probe->dofp_provider)); if (probe->dofp_mod >= strtab->dofs_size) { dtrace_dof_error(dof, "corrupt probe module"); return (NULL); } (void) strncpy(desc->dtpd_mod, (char *)(str + probe->dofp_mod), MIN(DTRACE_MODNAMELEN - 1, size - probe->dofp_mod)); if (probe->dofp_func >= strtab->dofs_size) { dtrace_dof_error(dof, "corrupt probe function"); return (NULL); } (void) strncpy(desc->dtpd_func, (char *)(str + probe->dofp_func), MIN(DTRACE_FUNCNAMELEN - 1, size - probe->dofp_func)); if (probe->dofp_name >= strtab->dofs_size) { dtrace_dof_error(dof, "corrupt probe name"); return (NULL); } (void) strncpy(desc->dtpd_name, (char *)(str + probe->dofp_name), MIN(DTRACE_NAMELEN - 1, size - probe->dofp_name)); return (desc); } static dtrace_difo_t * dtrace_dof_difo(dof_hdr_t *dof, dof_sec_t *sec, dtrace_vstate_t *vstate, cred_t *cr) { dtrace_difo_t *dp; size_t ttl = 0; dof_difohdr_t *dofd; uintptr_t daddr = (uintptr_t)dof; size_t max = dtrace_difo_maxsize; int i, l, n; static const struct { int section; int bufoffs; int lenoffs; int entsize; int align; const char *msg; } difo[] = { { DOF_SECT_DIF, offsetof(dtrace_difo_t, dtdo_buf), offsetof(dtrace_difo_t, dtdo_len), sizeof (dif_instr_t), sizeof (dif_instr_t), "multiple DIF sections" }, { DOF_SECT_INTTAB, offsetof(dtrace_difo_t, dtdo_inttab), offsetof(dtrace_difo_t, dtdo_intlen), sizeof (uint64_t), sizeof (uint64_t), "multiple integer tables" }, { DOF_SECT_STRTAB, offsetof(dtrace_difo_t, dtdo_strtab), offsetof(dtrace_difo_t, dtdo_strlen), 0, sizeof (char), "multiple string tables" }, { DOF_SECT_VARTAB, offsetof(dtrace_difo_t, dtdo_vartab), offsetof(dtrace_difo_t, dtdo_varlen), sizeof (dtrace_difv_t), sizeof (uint_t), "multiple variable tables" }, - { DOF_SECT_NONE, 0, 0, 0, NULL } + { DOF_SECT_NONE, 0, 0, 0, 0, NULL } }; if (sec->dofs_type != DOF_SECT_DIFOHDR) { dtrace_dof_error(dof, "invalid DIFO header section"); return (NULL); } if (sec->dofs_align != sizeof (dof_secidx_t)) { dtrace_dof_error(dof, "bad alignment in DIFO header"); return (NULL); } if (sec->dofs_size < sizeof (dof_difohdr_t) || sec->dofs_size % sizeof (dof_secidx_t)) { dtrace_dof_error(dof, "bad size in DIFO header"); return (NULL); } dofd = (dof_difohdr_t *)(uintptr_t)(daddr + sec->dofs_offset); n = (sec->dofs_size - sizeof (*dofd)) / sizeof (dof_secidx_t) + 1; dp = kmem_zalloc(sizeof (dtrace_difo_t), KM_SLEEP); dp->dtdo_rtype = dofd->dofd_rtype; for (l = 0; l < n; l++) { dof_sec_t *subsec; void **bufp; uint32_t *lenp; if ((subsec = dtrace_dof_sect(dof, DOF_SECT_NONE, dofd->dofd_links[l])) == NULL) goto err; /* invalid section link */ if (ttl + subsec->dofs_size > max) { dtrace_dof_error(dof, "exceeds maximum size"); goto err; } ttl += subsec->dofs_size; for (i = 0; difo[i].section != DOF_SECT_NONE; i++) { if (subsec->dofs_type != difo[i].section) continue; if (!(subsec->dofs_flags & DOF_SECF_LOAD)) { dtrace_dof_error(dof, "section not loaded"); goto err; } if (subsec->dofs_align != difo[i].align) { dtrace_dof_error(dof, "bad alignment"); goto err; } bufp = (void **)((uintptr_t)dp + difo[i].bufoffs); lenp = (uint32_t *)((uintptr_t)dp + difo[i].lenoffs); if (*bufp != NULL) { dtrace_dof_error(dof, difo[i].msg); goto err; } if (difo[i].entsize != subsec->dofs_entsize) { dtrace_dof_error(dof, "entry size mismatch"); goto err; } if (subsec->dofs_entsize != 0 && (subsec->dofs_size % subsec->dofs_entsize) != 0) { dtrace_dof_error(dof, "corrupt entry size"); goto err; } *lenp = subsec->dofs_size; *bufp = kmem_alloc(subsec->dofs_size, KM_SLEEP); bcopy((char *)(uintptr_t)(daddr + subsec->dofs_offset), *bufp, subsec->dofs_size); if (subsec->dofs_entsize != 0) *lenp /= subsec->dofs_entsize; break; } /* * If we encounter a loadable DIFO sub-section that is not * known to us, assume this is a broken program and fail. */ if (difo[i].section == DOF_SECT_NONE && (subsec->dofs_flags & DOF_SECF_LOAD)) { dtrace_dof_error(dof, "unrecognized DIFO subsection"); goto err; } } if (dp->dtdo_buf == NULL) { /* * We can't have a DIF object without DIF text. */ dtrace_dof_error(dof, "missing DIF text"); goto err; } /* * Before we validate the DIF object, run through the variable table * looking for the strings -- if any of their size are under, we'll set * their size to be the system-wide default string size. Note that * this should _not_ happen if the "strsize" option has been set -- * in this case, the compiler should have set the size to reflect the * setting of the option. */ for (i = 0; i < dp->dtdo_varlen; i++) { dtrace_difv_t *v = &dp->dtdo_vartab[i]; dtrace_diftype_t *t = &v->dtdv_type; if (v->dtdv_id < DIF_VAR_OTHER_UBASE) continue; if (t->dtdt_kind == DIF_TYPE_STRING && t->dtdt_size == 0) t->dtdt_size = dtrace_strsize_default; } if (dtrace_difo_validate(dp, vstate, DIF_DIR_NREGS, cr) != 0) goto err; dtrace_difo_init(dp, vstate); return (dp); err: kmem_free(dp->dtdo_buf, dp->dtdo_len * sizeof (dif_instr_t)); kmem_free(dp->dtdo_inttab, dp->dtdo_intlen * sizeof (uint64_t)); kmem_free(dp->dtdo_strtab, dp->dtdo_strlen); kmem_free(dp->dtdo_vartab, dp->dtdo_varlen * sizeof (dtrace_difv_t)); kmem_free(dp, sizeof (dtrace_difo_t)); return (NULL); } static dtrace_predicate_t * dtrace_dof_predicate(dof_hdr_t *dof, dof_sec_t *sec, dtrace_vstate_t *vstate, cred_t *cr) { dtrace_difo_t *dp; if ((dp = dtrace_dof_difo(dof, sec, vstate, cr)) == NULL) return (NULL); return (dtrace_predicate_create(dp)); } static dtrace_actdesc_t * dtrace_dof_actdesc(dof_hdr_t *dof, dof_sec_t *sec, dtrace_vstate_t *vstate, cred_t *cr) { dtrace_actdesc_t *act, *first = NULL, *last = NULL, *next; dof_actdesc_t *desc; dof_sec_t *difosec; size_t offs; uintptr_t daddr = (uintptr_t)dof; uint64_t arg; dtrace_actkind_t kind; if (sec->dofs_type != DOF_SECT_ACTDESC) { dtrace_dof_error(dof, "invalid action section"); return (NULL); } if (sec->dofs_offset + sizeof (dof_actdesc_t) > dof->dofh_loadsz) { dtrace_dof_error(dof, "truncated action description"); return (NULL); } if (sec->dofs_align != sizeof (uint64_t)) { dtrace_dof_error(dof, "bad alignment in action description"); return (NULL); } if (sec->dofs_size < sec->dofs_entsize) { dtrace_dof_error(dof, "section entry size exceeds total size"); return (NULL); } if (sec->dofs_entsize != sizeof (dof_actdesc_t)) { dtrace_dof_error(dof, "bad entry size in action description"); return (NULL); } if (sec->dofs_size / sec->dofs_entsize > dtrace_actions_max) { dtrace_dof_error(dof, "actions exceed dtrace_actions_max"); return (NULL); } for (offs = 0; offs < sec->dofs_size; offs += sec->dofs_entsize) { desc = (dof_actdesc_t *)(daddr + (uintptr_t)sec->dofs_offset + offs); kind = (dtrace_actkind_t)desc->dofa_kind; if (DTRACEACT_ISPRINTFLIKE(kind) && (kind != DTRACEACT_PRINTA || desc->dofa_strtab != DOF_SECIDX_NONE)) { dof_sec_t *strtab; char *str, *fmt; uint64_t i; /* * printf()-like actions must have a format string. */ if ((strtab = dtrace_dof_sect(dof, DOF_SECT_STRTAB, desc->dofa_strtab)) == NULL) goto err; str = (char *)((uintptr_t)dof + (uintptr_t)strtab->dofs_offset); for (i = desc->dofa_arg; i < strtab->dofs_size; i++) { if (str[i] == '\0') break; } if (i >= strtab->dofs_size) { dtrace_dof_error(dof, "bogus format string"); goto err; } if (i == desc->dofa_arg) { dtrace_dof_error(dof, "empty format string"); goto err; } i -= desc->dofa_arg; fmt = kmem_alloc(i + 1, KM_SLEEP); bcopy(&str[desc->dofa_arg], fmt, i + 1); arg = (uint64_t)(uintptr_t)fmt; } else { if (kind == DTRACEACT_PRINTA) { ASSERT(desc->dofa_strtab == DOF_SECIDX_NONE); arg = 0; } else { arg = desc->dofa_arg; } } act = dtrace_actdesc_create(kind, desc->dofa_ntuple, desc->dofa_uarg, arg); if (last != NULL) { last->dtad_next = act; } else { first = act; } last = act; if (desc->dofa_difo == DOF_SECIDX_NONE) continue; if ((difosec = dtrace_dof_sect(dof, DOF_SECT_DIFOHDR, desc->dofa_difo)) == NULL) goto err; act->dtad_difo = dtrace_dof_difo(dof, difosec, vstate, cr); if (act->dtad_difo == NULL) goto err; } ASSERT(first != NULL); return (first); err: for (act = first; act != NULL; act = next) { next = act->dtad_next; dtrace_actdesc_release(act, vstate); } return (NULL); } static dtrace_ecbdesc_t * dtrace_dof_ecbdesc(dof_hdr_t *dof, dof_sec_t *sec, dtrace_vstate_t *vstate, cred_t *cr) { dtrace_ecbdesc_t *ep; dof_ecbdesc_t *ecb; dtrace_probedesc_t *desc; dtrace_predicate_t *pred = NULL; if (sec->dofs_size < sizeof (dof_ecbdesc_t)) { dtrace_dof_error(dof, "truncated ECB description"); return (NULL); } if (sec->dofs_align != sizeof (uint64_t)) { dtrace_dof_error(dof, "bad alignment in ECB description"); return (NULL); } ecb = (dof_ecbdesc_t *)((uintptr_t)dof + (uintptr_t)sec->dofs_offset); sec = dtrace_dof_sect(dof, DOF_SECT_PROBEDESC, ecb->dofe_probes); if (sec == NULL) return (NULL); ep = kmem_zalloc(sizeof (dtrace_ecbdesc_t), KM_SLEEP); ep->dted_uarg = ecb->dofe_uarg; desc = &ep->dted_probe; if (dtrace_dof_probedesc(dof, sec, desc) == NULL) goto err; if (ecb->dofe_pred != DOF_SECIDX_NONE) { if ((sec = dtrace_dof_sect(dof, DOF_SECT_DIFOHDR, ecb->dofe_pred)) == NULL) goto err; if ((pred = dtrace_dof_predicate(dof, sec, vstate, cr)) == NULL) goto err; ep->dted_pred.dtpdd_predicate = pred; } if (ecb->dofe_actions != DOF_SECIDX_NONE) { if ((sec = dtrace_dof_sect(dof, DOF_SECT_ACTDESC, ecb->dofe_actions)) == NULL) goto err; ep->dted_action = dtrace_dof_actdesc(dof, sec, vstate, cr); if (ep->dted_action == NULL) goto err; } return (ep); err: if (pred != NULL) dtrace_predicate_release(pred, vstate); kmem_free(ep, sizeof (dtrace_ecbdesc_t)); return (NULL); } /* * Apply the relocations from the specified 'sec' (a DOF_SECT_URELHDR) to the * specified DOF. At present, this amounts to simply adding 'ubase' to the * site of any user SETX relocations to account for load object base address. * In the future, if we need other relocations, this function can be extended. */ static int dtrace_dof_relocate(dof_hdr_t *dof, dof_sec_t *sec, uint64_t ubase) { uintptr_t daddr = (uintptr_t)dof; dof_relohdr_t *dofr = (dof_relohdr_t *)(uintptr_t)(daddr + sec->dofs_offset); dof_sec_t *ss, *rs, *ts; dof_relodesc_t *r; uint_t i, n; if (sec->dofs_size < sizeof (dof_relohdr_t) || sec->dofs_align != sizeof (dof_secidx_t)) { dtrace_dof_error(dof, "invalid relocation header"); return (-1); } ss = dtrace_dof_sect(dof, DOF_SECT_STRTAB, dofr->dofr_strtab); rs = dtrace_dof_sect(dof, DOF_SECT_RELTAB, dofr->dofr_relsec); ts = dtrace_dof_sect(dof, DOF_SECT_NONE, dofr->dofr_tgtsec); if (ss == NULL || rs == NULL || ts == NULL) return (-1); /* dtrace_dof_error() has been called already */ if (rs->dofs_entsize < sizeof (dof_relodesc_t) || rs->dofs_align != sizeof (uint64_t)) { dtrace_dof_error(dof, "invalid relocation section"); return (-1); } r = (dof_relodesc_t *)(uintptr_t)(daddr + rs->dofs_offset); n = rs->dofs_size / rs->dofs_entsize; for (i = 0; i < n; i++) { uintptr_t taddr = daddr + ts->dofs_offset + r->dofr_offset; switch (r->dofr_type) { case DOF_RELO_NONE: break; case DOF_RELO_SETX: if (r->dofr_offset >= ts->dofs_size || r->dofr_offset + sizeof (uint64_t) > ts->dofs_size) { dtrace_dof_error(dof, "bad relocation offset"); return (-1); } if (!IS_P2ALIGNED(taddr, sizeof (uint64_t))) { dtrace_dof_error(dof, "misaligned setx relo"); return (-1); } *(uint64_t *)taddr += ubase; break; default: dtrace_dof_error(dof, "invalid relocation type"); return (-1); } r = (dof_relodesc_t *)((uintptr_t)r + rs->dofs_entsize); } return (0); } /* * The dof_hdr_t passed to dtrace_dof_slurp() should be a partially validated * header: it should be at the front of a memory region that is at least * sizeof (dof_hdr_t) in size -- and then at least dof_hdr.dofh_loadsz in * size. It need not be validated in any other way. */ static int dtrace_dof_slurp(dof_hdr_t *dof, dtrace_vstate_t *vstate, cred_t *cr, dtrace_enabling_t **enabp, uint64_t ubase, int noprobes) { uint64_t len = dof->dofh_loadsz, seclen; uintptr_t daddr = (uintptr_t)dof; dtrace_ecbdesc_t *ep; dtrace_enabling_t *enab; uint_t i; ASSERT(MUTEX_HELD(&dtrace_lock)); ASSERT(dof->dofh_loadsz >= sizeof (dof_hdr_t)); /* * Check the DOF header identification bytes. In addition to checking * valid settings, we also verify that unused bits/bytes are zeroed so * we can use them later without fear of regressing existing binaries. */ if (bcmp(&dof->dofh_ident[DOF_ID_MAG0], DOF_MAG_STRING, DOF_MAG_STRLEN) != 0) { dtrace_dof_error(dof, "DOF magic string mismatch"); return (-1); } if (dof->dofh_ident[DOF_ID_MODEL] != DOF_MODEL_ILP32 && dof->dofh_ident[DOF_ID_MODEL] != DOF_MODEL_LP64) { dtrace_dof_error(dof, "DOF has invalid data model"); return (-1); } if (dof->dofh_ident[DOF_ID_ENCODING] != DOF_ENCODE_NATIVE) { dtrace_dof_error(dof, "DOF encoding mismatch"); return (-1); } if (dof->dofh_ident[DOF_ID_VERSION] != DOF_VERSION_1 && dof->dofh_ident[DOF_ID_VERSION] != DOF_VERSION_2) { dtrace_dof_error(dof, "DOF version mismatch"); return (-1); } if (dof->dofh_ident[DOF_ID_DIFVERS] != DIF_VERSION_2) { dtrace_dof_error(dof, "DOF uses unsupported instruction set"); return (-1); } if (dof->dofh_ident[DOF_ID_DIFIREG] > DIF_DIR_NREGS) { dtrace_dof_error(dof, "DOF uses too many integer registers"); return (-1); } if (dof->dofh_ident[DOF_ID_DIFTREG] > DIF_DTR_NREGS) { dtrace_dof_error(dof, "DOF uses too many tuple registers"); return (-1); } for (i = DOF_ID_PAD; i < DOF_ID_SIZE; i++) { if (dof->dofh_ident[i] != 0) { dtrace_dof_error(dof, "DOF has invalid ident byte set"); return (-1); } } if (dof->dofh_flags & ~DOF_FL_VALID) { dtrace_dof_error(dof, "DOF has invalid flag bits set"); return (-1); } if (dof->dofh_secsize == 0) { dtrace_dof_error(dof, "zero section header size"); return (-1); } /* * Check that the section headers don't exceed the amount of DOF * data. Note that we cast the section size and number of sections * to uint64_t's to prevent possible overflow in the multiplication. */ seclen = (uint64_t)dof->dofh_secnum * (uint64_t)dof->dofh_secsize; if (dof->dofh_secoff > len || seclen > len || dof->dofh_secoff + seclen > len) { dtrace_dof_error(dof, "truncated section headers"); return (-1); } if (!IS_P2ALIGNED(dof->dofh_secoff, sizeof (uint64_t))) { dtrace_dof_error(dof, "misaligned section headers"); return (-1); } if (!IS_P2ALIGNED(dof->dofh_secsize, sizeof (uint64_t))) { dtrace_dof_error(dof, "misaligned section size"); return (-1); } /* * Take an initial pass through the section headers to be sure that * the headers don't have stray offsets. If the 'noprobes' flag is * set, do not permit sections relating to providers, probes, or args. */ for (i = 0; i < dof->dofh_secnum; i++) { dof_sec_t *sec = (dof_sec_t *)(daddr + (uintptr_t)dof->dofh_secoff + i * dof->dofh_secsize); if (noprobes) { switch (sec->dofs_type) { case DOF_SECT_PROVIDER: case DOF_SECT_PROBES: case DOF_SECT_PRARGS: case DOF_SECT_PROFFS: dtrace_dof_error(dof, "illegal sections " "for enabling"); return (-1); } } if (!(sec->dofs_flags & DOF_SECF_LOAD)) continue; /* just ignore non-loadable sections */ if (sec->dofs_align & (sec->dofs_align - 1)) { dtrace_dof_error(dof, "bad section alignment"); return (-1); } if (sec->dofs_offset & (sec->dofs_align - 1)) { dtrace_dof_error(dof, "misaligned section"); return (-1); } if (sec->dofs_offset > len || sec->dofs_size > len || sec->dofs_offset + sec->dofs_size > len) { dtrace_dof_error(dof, "corrupt section header"); return (-1); } if (sec->dofs_type == DOF_SECT_STRTAB && *((char *)daddr + sec->dofs_offset + sec->dofs_size - 1) != '\0') { dtrace_dof_error(dof, "non-terminating string table"); return (-1); } } /* * Take a second pass through the sections and locate and perform any * relocations that are present. We do this after the first pass to * be sure that all sections have had their headers validated. */ for (i = 0; i < dof->dofh_secnum; i++) { dof_sec_t *sec = (dof_sec_t *)(daddr + (uintptr_t)dof->dofh_secoff + i * dof->dofh_secsize); if (!(sec->dofs_flags & DOF_SECF_LOAD)) continue; /* skip sections that are not loadable */ switch (sec->dofs_type) { case DOF_SECT_URELHDR: if (dtrace_dof_relocate(dof, sec, ubase) != 0) return (-1); break; } } if ((enab = *enabp) == NULL) enab = *enabp = dtrace_enabling_create(vstate); for (i = 0; i < dof->dofh_secnum; i++) { dof_sec_t *sec = (dof_sec_t *)(daddr + (uintptr_t)dof->dofh_secoff + i * dof->dofh_secsize); if (sec->dofs_type != DOF_SECT_ECBDESC) continue; if ((ep = dtrace_dof_ecbdesc(dof, sec, vstate, cr)) == NULL) { dtrace_enabling_destroy(enab); *enabp = NULL; return (-1); } dtrace_enabling_add(enab, ep); } return (0); } /* * Process DOF for any options. This routine assumes that the DOF has been * at least processed by dtrace_dof_slurp(). */ static int dtrace_dof_options(dof_hdr_t *dof, dtrace_state_t *state) { int i, rval; uint32_t entsize; size_t offs; dof_optdesc_t *desc; for (i = 0; i < dof->dofh_secnum; i++) { dof_sec_t *sec = (dof_sec_t *)((uintptr_t)dof + (uintptr_t)dof->dofh_secoff + i * dof->dofh_secsize); if (sec->dofs_type != DOF_SECT_OPTDESC) continue; if (sec->dofs_align != sizeof (uint64_t)) { dtrace_dof_error(dof, "bad alignment in " "option description"); return (EINVAL); } if ((entsize = sec->dofs_entsize) == 0) { dtrace_dof_error(dof, "zeroed option entry size"); return (EINVAL); } if (entsize < sizeof (dof_optdesc_t)) { dtrace_dof_error(dof, "bad option entry size"); return (EINVAL); } for (offs = 0; offs < sec->dofs_size; offs += entsize) { desc = (dof_optdesc_t *)((uintptr_t)dof + (uintptr_t)sec->dofs_offset + offs); if (desc->dofo_strtab != DOF_SECIDX_NONE) { dtrace_dof_error(dof, "non-zero option string"); return (EINVAL); } if (desc->dofo_value == DTRACEOPT_UNSET) { dtrace_dof_error(dof, "unset option"); return (EINVAL); } if ((rval = dtrace_state_option(state, desc->dofo_option, desc->dofo_value)) != 0) { dtrace_dof_error(dof, "rejected option"); return (rval); } } } return (0); } /* * DTrace Consumer State Functions */ -int +static int dtrace_dstate_init(dtrace_dstate_t *dstate, size_t size) { size_t hashsize, maxper, min, chunksize = dstate->dtds_chunksize; void *base; uintptr_t limit; dtrace_dynvar_t *dvar, *next, *start; int i; ASSERT(MUTEX_HELD(&dtrace_lock)); ASSERT(dstate->dtds_base == NULL && dstate->dtds_percpu == NULL); bzero(dstate, sizeof (dtrace_dstate_t)); if ((dstate->dtds_chunksize = chunksize) == 0) dstate->dtds_chunksize = DTRACE_DYNVAR_CHUNKSIZE; if (size < (min = dstate->dtds_chunksize + sizeof (dtrace_dynhash_t))) size = min; if ((base = kmem_zalloc(size, KM_NOSLEEP)) == NULL) return (ENOMEM); dstate->dtds_size = size; dstate->dtds_base = base; dstate->dtds_percpu = kmem_cache_alloc(dtrace_state_cache, KM_SLEEP); bzero(dstate->dtds_percpu, NCPU * sizeof (dtrace_dstate_percpu_t)); hashsize = size / (dstate->dtds_chunksize + sizeof (dtrace_dynhash_t)); if (hashsize != 1 && (hashsize & 1)) hashsize--; dstate->dtds_hashsize = hashsize; dstate->dtds_hash = dstate->dtds_base; /* * Set all of our hash buckets to point to the single sink, and (if * it hasn't already been set), set the sink's hash value to be the * sink sentinel value. The sink is needed for dynamic variable * lookups to know that they have iterated over an entire, valid hash * chain. */ for (i = 0; i < hashsize; i++) dstate->dtds_hash[i].dtdh_chain = &dtrace_dynhash_sink; if (dtrace_dynhash_sink.dtdv_hashval != DTRACE_DYNHASH_SINK) dtrace_dynhash_sink.dtdv_hashval = DTRACE_DYNHASH_SINK; /* * Determine number of active CPUs. Divide free list evenly among * active CPUs. */ start = (dtrace_dynvar_t *) ((uintptr_t)base + hashsize * sizeof (dtrace_dynhash_t)); limit = (uintptr_t)base + size; maxper = (limit - (uintptr_t)start) / NCPU; maxper = (maxper / dstate->dtds_chunksize) * dstate->dtds_chunksize; for (i = 0; i < NCPU; i++) { +#if !defined(sun) + if (CPU_ABSENT(i)) + continue; +#endif dstate->dtds_percpu[i].dtdsc_free = dvar = start; /* * If we don't even have enough chunks to make it once through * NCPUs, we're just going to allocate everything to the first * CPU. And if we're on the last CPU, we're going to allocate * whatever is left over. In either case, we set the limit to * be the limit of the dynamic variable space. */ if (maxper == 0 || i == NCPU - 1) { limit = (uintptr_t)base + size; start = NULL; } else { limit = (uintptr_t)start + maxper; start = (dtrace_dynvar_t *)limit; } ASSERT(limit <= (uintptr_t)base + size); for (;;) { next = (dtrace_dynvar_t *)((uintptr_t)dvar + dstate->dtds_chunksize); if ((uintptr_t)next + dstate->dtds_chunksize >= limit) break; dvar->dtdv_next = next; dvar = next; } if (maxper == 0) break; } return (0); } -void +static void dtrace_dstate_fini(dtrace_dstate_t *dstate) { ASSERT(MUTEX_HELD(&cpu_lock)); if (dstate->dtds_base == NULL) return; kmem_free(dstate->dtds_base, dstate->dtds_size); kmem_cache_free(dtrace_state_cache, dstate->dtds_percpu); } static void dtrace_vstate_fini(dtrace_vstate_t *vstate) { /* * Logical XOR, where are you? */ ASSERT((vstate->dtvs_nglobals == 0) ^ (vstate->dtvs_globals != NULL)); if (vstate->dtvs_nglobals > 0) { kmem_free(vstate->dtvs_globals, vstate->dtvs_nglobals * sizeof (dtrace_statvar_t *)); } if (vstate->dtvs_ntlocals > 0) { kmem_free(vstate->dtvs_tlocals, vstate->dtvs_ntlocals * sizeof (dtrace_difv_t)); } ASSERT((vstate->dtvs_nlocals == 0) ^ (vstate->dtvs_locals != NULL)); if (vstate->dtvs_nlocals > 0) { kmem_free(vstate->dtvs_locals, vstate->dtvs_nlocals * sizeof (dtrace_statvar_t *)); } } static void dtrace_state_clean(dtrace_state_t *state) { if (state->dts_activity == DTRACE_ACTIVITY_INACTIVE) return; dtrace_dynvar_clean(&state->dts_vstate.dtvs_dynvars); dtrace_speculation_clean(state); } static void dtrace_state_deadman(dtrace_state_t *state) { hrtime_t now; dtrace_sync(); +#if !defined(sun) + dtrace_debug_output(); +#endif + now = dtrace_gethrtime(); if (state != dtrace_anon.dta_state && now - state->dts_laststatus >= dtrace_deadman_user) return; /* * We must be sure that dts_alive never appears to be less than the * value upon entry to dtrace_state_deadman(), and because we lack a * dtrace_cas64(), we cannot store to it atomically. We thus instead * store INT64_MAX to it, followed by a memory barrier, followed by * the new value. This assures that dts_alive never appears to be * less than its true value, regardless of the order in which the * stores to the underlying storage are issued. */ state->dts_alive = INT64_MAX; dtrace_membar_producer(); state->dts_alive = now; } -dtrace_state_t * +static dtrace_state_t * +#if defined(sun) dtrace_state_create(dev_t *devp, cred_t *cr) +#else +dtrace_state_create(struct cdev *dev) +#endif { +#if defined(sun) minor_t minor; major_t major; +#else + cred_t *cr = NULL; + int m = 0; +#endif char c[30]; dtrace_state_t *state; dtrace_optval_t *opt; int bufsize = NCPU * sizeof (dtrace_buffer_t), i; ASSERT(MUTEX_HELD(&dtrace_lock)); ASSERT(MUTEX_HELD(&cpu_lock)); +#if defined(sun) minor = (minor_t)(uintptr_t)vmem_alloc(dtrace_minor, 1, VM_BESTFIT | VM_SLEEP); if (ddi_soft_state_zalloc(dtrace_softstate, minor) != DDI_SUCCESS) { vmem_free(dtrace_minor, (void *)(uintptr_t)minor, 1); return (NULL); } state = ddi_get_soft_state(dtrace_softstate, minor); +#else + if (dev != NULL) { + cr = dev->si_cred; + m = minor(dev); + } + + /* Allocate memory for the state. */ + state = kmem_zalloc(sizeof(dtrace_state_t), KM_SLEEP); +#endif + state->dts_epid = DTRACE_EPIDNONE + 1; - (void) snprintf(c, sizeof (c), "dtrace_aggid_%d", minor); + (void) snprintf(c, sizeof (c), "dtrace_aggid_%d", m); +#if defined(sun) state->dts_aggid_arena = vmem_create(c, (void *)1, UINT32_MAX, 1, NULL, NULL, NULL, 0, VM_SLEEP | VMC_IDENTIFIER); if (devp != NULL) { major = getemajor(*devp); } else { major = ddi_driver_major(dtrace_devi); } state->dts_dev = makedevice(major, minor); if (devp != NULL) *devp = state->dts_dev; +#else + state->dts_aggid_arena = new_unrhdr(1, INT_MAX, &dtrace_unr_mtx); + state->dts_dev = dev; +#endif /* * We allocate NCPU buffers. On the one hand, this can be quite * a bit of memory per instance (nearly 36K on a Starcat). On the * other hand, it saves an additional memory reference in the probe * path. */ state->dts_buffer = kmem_zalloc(bufsize, KM_SLEEP); state->dts_aggbuffer = kmem_zalloc(bufsize, KM_SLEEP); state->dts_cleaner = CYCLIC_NONE; state->dts_deadman = CYCLIC_NONE; state->dts_vstate.dtvs_state = state; for (i = 0; i < DTRACEOPT_MAX; i++) state->dts_options[i] = DTRACEOPT_UNSET; /* * Set the default options. */ opt = state->dts_options; opt[DTRACEOPT_BUFPOLICY] = DTRACEOPT_BUFPOLICY_SWITCH; opt[DTRACEOPT_BUFRESIZE] = DTRACEOPT_BUFRESIZE_AUTO; opt[DTRACEOPT_NSPEC] = dtrace_nspec_default; opt[DTRACEOPT_SPECSIZE] = dtrace_specsize_default; opt[DTRACEOPT_CPU] = (dtrace_optval_t)DTRACE_CPUALL; opt[DTRACEOPT_STRSIZE] = dtrace_strsize_default; opt[DTRACEOPT_STACKFRAMES] = dtrace_stackframes_default; opt[DTRACEOPT_USTACKFRAMES] = dtrace_ustackframes_default; opt[DTRACEOPT_CLEANRATE] = dtrace_cleanrate_default; opt[DTRACEOPT_AGGRATE] = dtrace_aggrate_default; opt[DTRACEOPT_SWITCHRATE] = dtrace_switchrate_default; opt[DTRACEOPT_STATUSRATE] = dtrace_statusrate_default; opt[DTRACEOPT_JSTACKFRAMES] = dtrace_jstackframes_default; opt[DTRACEOPT_JSTACKSTRSIZE] = dtrace_jstackstrsize_default; state->dts_activity = DTRACE_ACTIVITY_INACTIVE; /* * Depending on the user credentials, we set flag bits which alter probe * visibility or the amount of destructiveness allowed. In the case of * actual anonymous tracing, or the possession of all privileges, all of * the normal checks are bypassed. */ if (cr == NULL || PRIV_POLICY_ONLY(cr, PRIV_ALL, B_FALSE)) { state->dts_cred.dcr_visible = DTRACE_CRV_ALL; state->dts_cred.dcr_action = DTRACE_CRA_ALL; } else { /* * Set up the credentials for this instantiation. We take a * hold on the credential to prevent it from disappearing on * us; this in turn prevents the zone_t referenced by this * credential from disappearing. This means that we can * examine the credential and the zone from probe context. */ crhold(cr); state->dts_cred.dcr_cred = cr; /* * CRA_PROC means "we have *some* privilege for dtrace" and * unlocks the use of variables like pid, zonename, etc. */ if (PRIV_POLICY_ONLY(cr, PRIV_DTRACE_USER, B_FALSE) || PRIV_POLICY_ONLY(cr, PRIV_DTRACE_PROC, B_FALSE)) { state->dts_cred.dcr_action |= DTRACE_CRA_PROC; } /* * dtrace_user allows use of syscall and profile providers. * If the user also has proc_owner and/or proc_zone, we * extend the scope to include additional visibility and * destructive power. */ if (PRIV_POLICY_ONLY(cr, PRIV_DTRACE_USER, B_FALSE)) { if (PRIV_POLICY_ONLY(cr, PRIV_PROC_OWNER, B_FALSE)) { state->dts_cred.dcr_visible |= DTRACE_CRV_ALLPROC; state->dts_cred.dcr_action |= DTRACE_CRA_PROC_DESTRUCTIVE_ALLUSER; } if (PRIV_POLICY_ONLY(cr, PRIV_PROC_ZONE, B_FALSE)) { state->dts_cred.dcr_visible |= DTRACE_CRV_ALLZONE; state->dts_cred.dcr_action |= DTRACE_CRA_PROC_DESTRUCTIVE_ALLZONE; } /* * If we have all privs in whatever zone this is, * we can do destructive things to processes which * have altered credentials. */ +#if defined(sun) if (priv_isequalset(priv_getset(cr, PRIV_EFFECTIVE), cr->cr_zone->zone_privset)) { state->dts_cred.dcr_action |= DTRACE_CRA_PROC_DESTRUCTIVE_CREDCHG; } +#endif } /* * Holding the dtrace_kernel privilege also implies that * the user has the dtrace_user privilege from a visibility * perspective. But without further privileges, some * destructive actions are not available. */ if (PRIV_POLICY_ONLY(cr, PRIV_DTRACE_KERNEL, B_FALSE)) { /* * Make all probes in all zones visible. However, * this doesn't mean that all actions become available * to all zones. */ state->dts_cred.dcr_visible |= DTRACE_CRV_KERNEL | DTRACE_CRV_ALLPROC | DTRACE_CRV_ALLZONE; state->dts_cred.dcr_action |= DTRACE_CRA_KERNEL | DTRACE_CRA_PROC; /* * Holding proc_owner means that destructive actions * for *this* zone are allowed. */ if (PRIV_POLICY_ONLY(cr, PRIV_PROC_OWNER, B_FALSE)) state->dts_cred.dcr_action |= DTRACE_CRA_PROC_DESTRUCTIVE_ALLUSER; /* * Holding proc_zone means that destructive actions * for this user/group ID in all zones is allowed. */ if (PRIV_POLICY_ONLY(cr, PRIV_PROC_ZONE, B_FALSE)) state->dts_cred.dcr_action |= DTRACE_CRA_PROC_DESTRUCTIVE_ALLZONE; +#if defined(sun) /* * If we have all privs in whatever zone this is, * we can do destructive things to processes which * have altered credentials. */ if (priv_isequalset(priv_getset(cr, PRIV_EFFECTIVE), cr->cr_zone->zone_privset)) { state->dts_cred.dcr_action |= DTRACE_CRA_PROC_DESTRUCTIVE_CREDCHG; } +#endif } /* * Holding the dtrace_proc privilege gives control over fasttrap * and pid providers. We need to grant wider destructive * privileges in the event that the user has proc_owner and/or * proc_zone. */ if (PRIV_POLICY_ONLY(cr, PRIV_DTRACE_PROC, B_FALSE)) { if (PRIV_POLICY_ONLY(cr, PRIV_PROC_OWNER, B_FALSE)) state->dts_cred.dcr_action |= DTRACE_CRA_PROC_DESTRUCTIVE_ALLUSER; if (PRIV_POLICY_ONLY(cr, PRIV_PROC_ZONE, B_FALSE)) state->dts_cred.dcr_action |= DTRACE_CRA_PROC_DESTRUCTIVE_ALLZONE; } } return (state); } static int dtrace_state_buffer(dtrace_state_t *state, dtrace_buffer_t *buf, int which) { dtrace_optval_t *opt = state->dts_options, size; - processorid_t cpu; + processorid_t cpu = 0;; int flags = 0, rval; ASSERT(MUTEX_HELD(&dtrace_lock)); ASSERT(MUTEX_HELD(&cpu_lock)); ASSERT(which < DTRACEOPT_MAX); ASSERT(state->dts_activity == DTRACE_ACTIVITY_INACTIVE || (state == dtrace_anon.dta_state && state->dts_activity == DTRACE_ACTIVITY_ACTIVE)); if (opt[which] == DTRACEOPT_UNSET || opt[which] == 0) return (0); if (opt[DTRACEOPT_CPU] != DTRACEOPT_UNSET) cpu = opt[DTRACEOPT_CPU]; if (which == DTRACEOPT_SPECSIZE) flags |= DTRACEBUF_NOSWITCH; if (which == DTRACEOPT_BUFSIZE) { if (opt[DTRACEOPT_BUFPOLICY] == DTRACEOPT_BUFPOLICY_RING) flags |= DTRACEBUF_RING; if (opt[DTRACEOPT_BUFPOLICY] == DTRACEOPT_BUFPOLICY_FILL) flags |= DTRACEBUF_FILL; if (state != dtrace_anon.dta_state || state->dts_activity != DTRACE_ACTIVITY_ACTIVE) flags |= DTRACEBUF_INACTIVE; } for (size = opt[which]; size >= sizeof (uint64_t); size >>= 1) { /* * The size must be 8-byte aligned. If the size is not 8-byte * aligned, drop it down by the difference. */ if (size & (sizeof (uint64_t) - 1)) size -= size & (sizeof (uint64_t) - 1); if (size < state->dts_reserve) { /* * Buffers always must be large enough to accommodate * their prereserved space. We return E2BIG instead * of ENOMEM in this case to allow for user-level * software to differentiate the cases. */ return (E2BIG); } rval = dtrace_buffer_alloc(buf, size, flags, cpu); if (rval != ENOMEM) { opt[which] = size; return (rval); } if (opt[DTRACEOPT_BUFRESIZE] == DTRACEOPT_BUFRESIZE_MANUAL) return (rval); } return (ENOMEM); } static int dtrace_state_buffers(dtrace_state_t *state) { dtrace_speculation_t *spec = state->dts_speculations; int rval, i; if ((rval = dtrace_state_buffer(state, state->dts_buffer, DTRACEOPT_BUFSIZE)) != 0) return (rval); if ((rval = dtrace_state_buffer(state, state->dts_aggbuffer, DTRACEOPT_AGGSIZE)) != 0) return (rval); for (i = 0; i < state->dts_nspeculations; i++) { if ((rval = dtrace_state_buffer(state, spec[i].dtsp_buffer, DTRACEOPT_SPECSIZE)) != 0) return (rval); } return (0); } static void dtrace_state_prereserve(dtrace_state_t *state) { dtrace_ecb_t *ecb; dtrace_probe_t *probe; state->dts_reserve = 0; if (state->dts_options[DTRACEOPT_BUFPOLICY] != DTRACEOPT_BUFPOLICY_FILL) return; /* * If our buffer policy is a "fill" buffer policy, we need to set the * prereserved space to be the space required by the END probes. */ probe = dtrace_probes[dtrace_probeid_end - 1]; ASSERT(probe != NULL); for (ecb = probe->dtpr_ecb; ecb != NULL; ecb = ecb->dte_next) { if (ecb->dte_state != state) continue; state->dts_reserve += ecb->dte_needed + ecb->dte_alignment; } } static int dtrace_state_go(dtrace_state_t *state, processorid_t *cpu) { dtrace_optval_t *opt = state->dts_options, sz, nspec; dtrace_speculation_t *spec; dtrace_buffer_t *buf; cyc_handler_t hdlr; cyc_time_t when; int rval = 0, i, bufsize = NCPU * sizeof (dtrace_buffer_t); dtrace_icookie_t cookie; mutex_enter(&cpu_lock); mutex_enter(&dtrace_lock); if (state->dts_activity != DTRACE_ACTIVITY_INACTIVE) { rval = EBUSY; goto out; } /* * Before we can perform any checks, we must prime all of the * retained enablings that correspond to this state. */ dtrace_enabling_prime(state); if (state->dts_destructive && !state->dts_cred.dcr_destructive) { rval = EACCES; goto out; } dtrace_state_prereserve(state); /* * Now we want to do is try to allocate our speculations. * We do not automatically resize the number of speculations; if * this fails, we will fail the operation. */ nspec = opt[DTRACEOPT_NSPEC]; ASSERT(nspec != DTRACEOPT_UNSET); if (nspec > INT_MAX) { rval = ENOMEM; goto out; } spec = kmem_zalloc(nspec * sizeof (dtrace_speculation_t), KM_NOSLEEP); if (spec == NULL) { rval = ENOMEM; goto out; } state->dts_speculations = spec; state->dts_nspeculations = (int)nspec; for (i = 0; i < nspec; i++) { if ((buf = kmem_zalloc(bufsize, KM_NOSLEEP)) == NULL) { rval = ENOMEM; goto err; } spec[i].dtsp_buffer = buf; } if (opt[DTRACEOPT_GRABANON] != DTRACEOPT_UNSET) { if (dtrace_anon.dta_state == NULL) { rval = ENOENT; goto out; } if (state->dts_necbs != 0) { rval = EALREADY; goto out; } state->dts_anon = dtrace_anon_grab(); ASSERT(state->dts_anon != NULL); state = state->dts_anon; /* * We want "grabanon" to be set in the grabbed state, so we'll * copy that option value from the grabbing state into the * grabbed state. */ state->dts_options[DTRACEOPT_GRABANON] = opt[DTRACEOPT_GRABANON]; *cpu = dtrace_anon.dta_beganon; /* * If the anonymous state is active (as it almost certainly * is if the anonymous enabling ultimately matched anything), * we don't allow any further option processing -- but we * don't return failure. */ if (state->dts_activity != DTRACE_ACTIVITY_INACTIVE) goto out; } if (opt[DTRACEOPT_AGGSIZE] != DTRACEOPT_UNSET && opt[DTRACEOPT_AGGSIZE] != 0) { if (state->dts_aggregations == NULL) { /* * We're not going to create an aggregation buffer * because we don't have any ECBs that contain * aggregations -- set this option to 0. */ opt[DTRACEOPT_AGGSIZE] = 0; } else { /* * If we have an aggregation buffer, we must also have * a buffer to use as scratch. */ if (opt[DTRACEOPT_BUFSIZE] == DTRACEOPT_UNSET || opt[DTRACEOPT_BUFSIZE] < state->dts_needed) { opt[DTRACEOPT_BUFSIZE] = state->dts_needed; } } } if (opt[DTRACEOPT_SPECSIZE] != DTRACEOPT_UNSET && opt[DTRACEOPT_SPECSIZE] != 0) { if (!state->dts_speculates) { /* * We're not going to create speculation buffers * because we don't have any ECBs that actually * speculate -- set the speculation size to 0. */ opt[DTRACEOPT_SPECSIZE] = 0; } } /* * The bare minimum size for any buffer that we're actually going to * do anything to is sizeof (uint64_t). */ sz = sizeof (uint64_t); if ((state->dts_needed != 0 && opt[DTRACEOPT_BUFSIZE] < sz) || (state->dts_speculates && opt[DTRACEOPT_SPECSIZE] < sz) || (state->dts_aggregations != NULL && opt[DTRACEOPT_AGGSIZE] < sz)) { /* * A buffer size has been explicitly set to 0 (or to a size * that will be adjusted to 0) and we need the space -- we * need to return failure. We return ENOSPC to differentiate * it from failing to allocate a buffer due to failure to meet * the reserve (for which we return E2BIG). */ rval = ENOSPC; goto out; } if ((rval = dtrace_state_buffers(state)) != 0) goto err; if ((sz = opt[DTRACEOPT_DYNVARSIZE]) == DTRACEOPT_UNSET) sz = dtrace_dstate_defsize; do { rval = dtrace_dstate_init(&state->dts_vstate.dtvs_dynvars, sz); if (rval == 0) break; if (opt[DTRACEOPT_BUFRESIZE] == DTRACEOPT_BUFRESIZE_MANUAL) goto err; } while (sz >>= 1); opt[DTRACEOPT_DYNVARSIZE] = sz; if (rval != 0) goto err; if (opt[DTRACEOPT_STATUSRATE] > dtrace_statusrate_max) opt[DTRACEOPT_STATUSRATE] = dtrace_statusrate_max; if (opt[DTRACEOPT_CLEANRATE] == 0) opt[DTRACEOPT_CLEANRATE] = dtrace_cleanrate_max; if (opt[DTRACEOPT_CLEANRATE] < dtrace_cleanrate_min) opt[DTRACEOPT_CLEANRATE] = dtrace_cleanrate_min; if (opt[DTRACEOPT_CLEANRATE] > dtrace_cleanrate_max) opt[DTRACEOPT_CLEANRATE] = dtrace_cleanrate_max; hdlr.cyh_func = (cyc_func_t)dtrace_state_clean; hdlr.cyh_arg = state; +#if defined(sun) hdlr.cyh_level = CY_LOW_LEVEL; +#endif when.cyt_when = 0; when.cyt_interval = opt[DTRACEOPT_CLEANRATE]; state->dts_cleaner = cyclic_add(&hdlr, &when); hdlr.cyh_func = (cyc_func_t)dtrace_state_deadman; hdlr.cyh_arg = state; +#if defined(sun) hdlr.cyh_level = CY_LOW_LEVEL; +#endif when.cyt_when = 0; when.cyt_interval = dtrace_deadman_interval; state->dts_alive = state->dts_laststatus = dtrace_gethrtime(); state->dts_deadman = cyclic_add(&hdlr, &when); state->dts_activity = DTRACE_ACTIVITY_WARMUP; /* * Now it's time to actually fire the BEGIN probe. We need to disable * interrupts here both to record the CPU on which we fired the BEGIN * probe (the data from this CPU will be processed first at user * level) and to manually activate the buffer for this CPU. */ cookie = dtrace_interrupt_disable(); - *cpu = CPU->cpu_id; + *cpu = curcpu; ASSERT(state->dts_buffer[*cpu].dtb_flags & DTRACEBUF_INACTIVE); state->dts_buffer[*cpu].dtb_flags &= ~DTRACEBUF_INACTIVE; dtrace_probe(dtrace_probeid_begin, (uint64_t)(uintptr_t)state, 0, 0, 0, 0); dtrace_interrupt_enable(cookie); /* * We may have had an exit action from a BEGIN probe; only change our * state to ACTIVE if we're still in WARMUP. */ ASSERT(state->dts_activity == DTRACE_ACTIVITY_WARMUP || state->dts_activity == DTRACE_ACTIVITY_DRAINING); if (state->dts_activity == DTRACE_ACTIVITY_WARMUP) state->dts_activity = DTRACE_ACTIVITY_ACTIVE; /* * Regardless of whether or not now we're in ACTIVE or DRAINING, we * want each CPU to transition its principal buffer out of the * INACTIVE state. Doing this assures that no CPU will suddenly begin * processing an ECB halfway down a probe's ECB chain; all CPUs will * atomically transition from processing none of a state's ECBs to * processing all of them. */ dtrace_xcall(DTRACE_CPUALL, (dtrace_xcall_t)dtrace_buffer_activate, state); goto out; err: dtrace_buffer_free(state->dts_buffer); dtrace_buffer_free(state->dts_aggbuffer); if ((nspec = state->dts_nspeculations) == 0) { ASSERT(state->dts_speculations == NULL); goto out; } spec = state->dts_speculations; ASSERT(spec != NULL); for (i = 0; i < state->dts_nspeculations; i++) { if ((buf = spec[i].dtsp_buffer) == NULL) break; dtrace_buffer_free(buf); kmem_free(buf, bufsize); } kmem_free(spec, nspec * sizeof (dtrace_speculation_t)); state->dts_nspeculations = 0; state->dts_speculations = NULL; out: mutex_exit(&dtrace_lock); mutex_exit(&cpu_lock); return (rval); } static int dtrace_state_stop(dtrace_state_t *state, processorid_t *cpu) { dtrace_icookie_t cookie; ASSERT(MUTEX_HELD(&dtrace_lock)); if (state->dts_activity != DTRACE_ACTIVITY_ACTIVE && state->dts_activity != DTRACE_ACTIVITY_DRAINING) return (EINVAL); /* * We'll set the activity to DTRACE_ACTIVITY_DRAINING, and issue a sync * to be sure that every CPU has seen it. See below for the details * on why this is done. */ state->dts_activity = DTRACE_ACTIVITY_DRAINING; dtrace_sync(); /* * By this point, it is impossible for any CPU to be still processing * with DTRACE_ACTIVITY_ACTIVE. We can thus set our activity to * DTRACE_ACTIVITY_COOLDOWN and know that we're not racing with any * other CPU in dtrace_buffer_reserve(). This allows dtrace_probe() * and callees to know that the activity is DTRACE_ACTIVITY_COOLDOWN * iff we're in the END probe. */ state->dts_activity = DTRACE_ACTIVITY_COOLDOWN; dtrace_sync(); ASSERT(state->dts_activity == DTRACE_ACTIVITY_COOLDOWN); /* * Finally, we can release the reserve and call the END probe. We * disable interrupts across calling the END probe to allow us to * return the CPU on which we actually called the END probe. This * allows user-land to be sure that this CPU's principal buffer is * processed last. */ state->dts_reserve = 0; cookie = dtrace_interrupt_disable(); - *cpu = CPU->cpu_id; + *cpu = curcpu; dtrace_probe(dtrace_probeid_end, (uint64_t)(uintptr_t)state, 0, 0, 0, 0); dtrace_interrupt_enable(cookie); state->dts_activity = DTRACE_ACTIVITY_STOPPED; dtrace_sync(); return (0); } static int dtrace_state_option(dtrace_state_t *state, dtrace_optid_t option, dtrace_optval_t val) { ASSERT(MUTEX_HELD(&dtrace_lock)); if (state->dts_activity != DTRACE_ACTIVITY_INACTIVE) return (EBUSY); if (option >= DTRACEOPT_MAX) return (EINVAL); if (option != DTRACEOPT_CPU && val < 0) return (EINVAL); switch (option) { case DTRACEOPT_DESTRUCTIVE: if (dtrace_destructive_disallow) return (EACCES); state->dts_cred.dcr_destructive = 1; break; case DTRACEOPT_BUFSIZE: case DTRACEOPT_DYNVARSIZE: case DTRACEOPT_AGGSIZE: case DTRACEOPT_SPECSIZE: case DTRACEOPT_STRSIZE: if (val < 0) return (EINVAL); if (val >= LONG_MAX) { /* * If this is an otherwise negative value, set it to * the highest multiple of 128m less than LONG_MAX. * Technically, we're adjusting the size without * regard to the buffer resizing policy, but in fact, * this has no effect -- if we set the buffer size to * ~LONG_MAX and the buffer policy is ultimately set to * be "manual", the buffer allocation is guaranteed to * fail, if only because the allocation requires two * buffers. (We set the the size to the highest * multiple of 128m because it ensures that the size * will remain a multiple of a megabyte when * repeatedly halved -- all the way down to 15m.) */ val = LONG_MAX - (1 << 27) + 1; } } state->dts_options[option] = val; return (0); } static void dtrace_state_destroy(dtrace_state_t *state) { dtrace_ecb_t *ecb; dtrace_vstate_t *vstate = &state->dts_vstate; +#if defined(sun) minor_t minor = getminor(state->dts_dev); +#endif int i, bufsize = NCPU * sizeof (dtrace_buffer_t); dtrace_speculation_t *spec = state->dts_speculations; int nspec = state->dts_nspeculations; uint32_t match; ASSERT(MUTEX_HELD(&dtrace_lock)); ASSERT(MUTEX_HELD(&cpu_lock)); /* * First, retract any retained enablings for this state. */ dtrace_enabling_retract(state); ASSERT(state->dts_nretained == 0); if (state->dts_activity == DTRACE_ACTIVITY_ACTIVE || state->dts_activity == DTRACE_ACTIVITY_DRAINING) { /* * We have managed to come into dtrace_state_destroy() on a * hot enabling -- almost certainly because of a disorderly * shutdown of a consumer. (That is, a consumer that is * exiting without having called dtrace_stop().) In this case, * we're going to set our activity to be KILLED, and then * issue a sync to be sure that everyone is out of probe * context before we start blowing away ECBs. */ state->dts_activity = DTRACE_ACTIVITY_KILLED; dtrace_sync(); } /* * Release the credential hold we took in dtrace_state_create(). */ if (state->dts_cred.dcr_cred != NULL) crfree(state->dts_cred.dcr_cred); /* * Now we can safely disable and destroy any enabled probes. Because * any DTRACE_PRIV_KERNEL probes may actually be slowing our progress * (especially if they're all enabled), we take two passes through the * ECBs: in the first, we disable just DTRACE_PRIV_KERNEL probes, and * in the second we disable whatever is left over. */ for (match = DTRACE_PRIV_KERNEL; ; match = 0) { for (i = 0; i < state->dts_necbs; i++) { if ((ecb = state->dts_ecbs[i]) == NULL) continue; if (match && ecb->dte_probe != NULL) { dtrace_probe_t *probe = ecb->dte_probe; dtrace_provider_t *prov = probe->dtpr_provider; if (!(prov->dtpv_priv.dtpp_flags & match)) continue; } dtrace_ecb_disable(ecb); dtrace_ecb_destroy(ecb); } if (!match) break; } /* * Before we free the buffers, perform one more sync to assure that * every CPU is out of probe context. */ dtrace_sync(); dtrace_buffer_free(state->dts_buffer); dtrace_buffer_free(state->dts_aggbuffer); for (i = 0; i < nspec; i++) dtrace_buffer_free(spec[i].dtsp_buffer); if (state->dts_cleaner != CYCLIC_NONE) cyclic_remove(state->dts_cleaner); if (state->dts_deadman != CYCLIC_NONE) cyclic_remove(state->dts_deadman); dtrace_dstate_fini(&vstate->dtvs_dynvars); dtrace_vstate_fini(vstate); - kmem_free(state->dts_ecbs, state->dts_necbs * sizeof (dtrace_ecb_t *)); + if (state->dts_ecbs != NULL) + kmem_free(state->dts_ecbs, state->dts_necbs * sizeof (dtrace_ecb_t *)); if (state->dts_aggregations != NULL) { #ifdef DEBUG for (i = 0; i < state->dts_naggregations; i++) ASSERT(state->dts_aggregations[i] == NULL); #endif ASSERT(state->dts_naggregations > 0); kmem_free(state->dts_aggregations, state->dts_naggregations * sizeof (dtrace_aggregation_t *)); } kmem_free(state->dts_buffer, bufsize); kmem_free(state->dts_aggbuffer, bufsize); for (i = 0; i < nspec; i++) kmem_free(spec[i].dtsp_buffer, bufsize); - kmem_free(spec, nspec * sizeof (dtrace_speculation_t)); + if (spec != NULL) + kmem_free(spec, nspec * sizeof (dtrace_speculation_t)); dtrace_format_destroy(state); - vmem_destroy(state->dts_aggid_arena); + if (state->dts_aggid_arena != NULL) { +#if defined(sun) + vmem_destroy(state->dts_aggid_arena); +#else + delete_unrhdr(state->dts_aggid_arena); +#endif + state->dts_aggid_arena = NULL; + } +#if defined(sun) ddi_soft_state_free(dtrace_softstate, minor); vmem_free(dtrace_minor, (void *)(uintptr_t)minor, 1); +#endif } /* * DTrace Anonymous Enabling Functions */ static dtrace_state_t * dtrace_anon_grab(void) { dtrace_state_t *state; ASSERT(MUTEX_HELD(&dtrace_lock)); if ((state = dtrace_anon.dta_state) == NULL) { ASSERT(dtrace_anon.dta_enabling == NULL); return (NULL); } ASSERT(dtrace_anon.dta_enabling != NULL); ASSERT(dtrace_retained != NULL); dtrace_enabling_destroy(dtrace_anon.dta_enabling); dtrace_anon.dta_enabling = NULL; dtrace_anon.dta_state = NULL; return (state); } static void dtrace_anon_property(void) { int i, rv; dtrace_state_t *state; dof_hdr_t *dof; char c[32]; /* enough for "dof-data-" + digits */ ASSERT(MUTEX_HELD(&dtrace_lock)); ASSERT(MUTEX_HELD(&cpu_lock)); for (i = 0; ; i++) { (void) snprintf(c, sizeof (c), "dof-data-%d", i); dtrace_err_verbose = 1; if ((dof = dtrace_dof_property(c)) == NULL) { dtrace_err_verbose = 0; break; } +#if defined(sun) /* * We want to create anonymous state, so we need to transition * the kernel debugger to indicate that DTrace is active. If * this fails (e.g. because the debugger has modified text in * some way), we won't continue with the processing. */ if (kdi_dtrace_set(KDI_DTSET_DTRACE_ACTIVATE) != 0) { cmn_err(CE_NOTE, "kernel debugger active; anonymous " "enabling ignored."); dtrace_dof_destroy(dof); break; } +#endif /* * If we haven't allocated an anonymous state, we'll do so now. */ if ((state = dtrace_anon.dta_state) == NULL) { +#if defined(sun) state = dtrace_state_create(NULL, NULL); +#else + state = dtrace_state_create(NULL); +#endif dtrace_anon.dta_state = state; if (state == NULL) { /* * This basically shouldn't happen: the only * failure mode from dtrace_state_create() is a * failure of ddi_soft_state_zalloc() that * itself should never happen. Still, the * interface allows for a failure mode, and * we want to fail as gracefully as possible: * we'll emit an error message and cease * processing anonymous state in this case. */ cmn_err(CE_WARN, "failed to create " "anonymous state"); dtrace_dof_destroy(dof); break; } } rv = dtrace_dof_slurp(dof, &state->dts_vstate, CRED(), &dtrace_anon.dta_enabling, 0, B_TRUE); if (rv == 0) rv = dtrace_dof_options(dof, state); dtrace_err_verbose = 0; dtrace_dof_destroy(dof); if (rv != 0) { /* * This is malformed DOF; chuck any anonymous state * that we created. */ ASSERT(dtrace_anon.dta_enabling == NULL); dtrace_state_destroy(state); dtrace_anon.dta_state = NULL; break; } ASSERT(dtrace_anon.dta_enabling != NULL); } if (dtrace_anon.dta_enabling != NULL) { int rval; /* * dtrace_enabling_retain() can only fail because we are * trying to retain more enablings than are allowed -- but * we only have one anonymous enabling, and we are guaranteed * to be allowed at least one retained enabling; we assert * that dtrace_enabling_retain() returns success. */ rval = dtrace_enabling_retain(dtrace_anon.dta_enabling); ASSERT(rval == 0); dtrace_enabling_dump(dtrace_anon.dta_enabling); } } +#if defined(sun) /* * DTrace Helper Functions */ static void dtrace_helper_trace(dtrace_helper_action_t *helper, dtrace_mstate_t *mstate, dtrace_vstate_t *vstate, int where) { uint32_t size, next, nnext, i; dtrace_helptrace_t *ent; - uint16_t flags = cpu_core[CPU->cpu_id].cpuc_dtrace_flags; + uint16_t flags = cpu_core[curcpu].cpuc_dtrace_flags; if (!dtrace_helptrace_enabled) return; ASSERT(vstate->dtvs_nlocals <= dtrace_helptrace_nlocals); /* * What would a tracing framework be without its own tracing * framework? (Well, a hell of a lot simpler, for starters...) */ size = sizeof (dtrace_helptrace_t) + dtrace_helptrace_nlocals * sizeof (uint64_t) - sizeof (uint64_t); /* * Iterate until we can allocate a slot in the trace buffer. */ do { next = dtrace_helptrace_next; if (next + size < dtrace_helptrace_bufsize) { nnext = next + size; } else { nnext = size; } } while (dtrace_cas32(&dtrace_helptrace_next, next, nnext) != next); /* * We have our slot; fill it in. */ if (nnext == size) next = 0; ent = (dtrace_helptrace_t *)&dtrace_helptrace_buffer[next]; ent->dtht_helper = helper; ent->dtht_where = where; ent->dtht_nlocals = vstate->dtvs_nlocals; ent->dtht_fltoffs = (mstate->dtms_present & DTRACE_MSTATE_FLTOFFS) ? mstate->dtms_fltoffs : -1; ent->dtht_fault = DTRACE_FLAGS2FLT(flags); - ent->dtht_illval = cpu_core[CPU->cpu_id].cpuc_dtrace_illval; + ent->dtht_illval = cpu_core[curcpu].cpuc_dtrace_illval; for (i = 0; i < vstate->dtvs_nlocals; i++) { dtrace_statvar_t *svar; if ((svar = vstate->dtvs_locals[i]) == NULL) continue; ASSERT(svar->dtsv_size >= NCPU * sizeof (uint64_t)); ent->dtht_locals[i] = - ((uint64_t *)(uintptr_t)svar->dtsv_data)[CPU->cpu_id]; + ((uint64_t *)(uintptr_t)svar->dtsv_data)[curcpu]; } } +#endif +#if defined(sun) static uint64_t dtrace_helper(int which, dtrace_mstate_t *mstate, dtrace_state_t *state, uint64_t arg0, uint64_t arg1) { - uint16_t *flags = &cpu_core[CPU->cpu_id].cpuc_dtrace_flags; + uint16_t *flags = &cpu_core[curcpu].cpuc_dtrace_flags; uint64_t sarg0 = mstate->dtms_arg[0]; uint64_t sarg1 = mstate->dtms_arg[1]; uint64_t rval; dtrace_helpers_t *helpers = curproc->p_dtrace_helpers; dtrace_helper_action_t *helper; dtrace_vstate_t *vstate; dtrace_difo_t *pred; int i, trace = dtrace_helptrace_enabled; ASSERT(which >= 0 && which < DTRACE_NHELPER_ACTIONS); if (helpers == NULL) return (0); if ((helper = helpers->dthps_actions[which]) == NULL) return (0); vstate = &helpers->dthps_vstate; mstate->dtms_arg[0] = arg0; mstate->dtms_arg[1] = arg1; /* * Now iterate over each helper. If its predicate evaluates to 'true', * we'll call the corresponding actions. Note that the below calls * to dtrace_dif_emulate() may set faults in machine state. This is * okay: our caller (the outer dtrace_dif_emulate()) will simply plow * the stored DIF offset with its own (which is the desired behavior). * Also, note the calls to dtrace_dif_emulate() may allocate scratch * from machine state; this is okay, too. */ for (; helper != NULL; helper = helper->dtha_next) { if ((pred = helper->dtha_predicate) != NULL) { if (trace) dtrace_helper_trace(helper, mstate, vstate, 0); if (!dtrace_dif_emulate(pred, mstate, vstate, state)) goto next; if (*flags & CPU_DTRACE_FAULT) goto err; } for (i = 0; i < helper->dtha_nactions; i++) { if (trace) dtrace_helper_trace(helper, mstate, vstate, i + 1); rval = dtrace_dif_emulate(helper->dtha_actions[i], mstate, vstate, state); if (*flags & CPU_DTRACE_FAULT) goto err; } next: if (trace) dtrace_helper_trace(helper, mstate, vstate, DTRACE_HELPTRACE_NEXT); } if (trace) dtrace_helper_trace(helper, mstate, vstate, DTRACE_HELPTRACE_DONE); /* * Restore the arg0 that we saved upon entry. */ mstate->dtms_arg[0] = sarg0; mstate->dtms_arg[1] = sarg1; return (rval); err: if (trace) dtrace_helper_trace(helper, mstate, vstate, DTRACE_HELPTRACE_ERR); /* * Restore the arg0 that we saved upon entry. */ mstate->dtms_arg[0] = sarg0; mstate->dtms_arg[1] = sarg1; - return (NULL); + return (0); } static void dtrace_helper_action_destroy(dtrace_helper_action_t *helper, dtrace_vstate_t *vstate) { int i; if (helper->dtha_predicate != NULL) dtrace_difo_release(helper->dtha_predicate, vstate); for (i = 0; i < helper->dtha_nactions; i++) { ASSERT(helper->dtha_actions[i] != NULL); dtrace_difo_release(helper->dtha_actions[i], vstate); } kmem_free(helper->dtha_actions, helper->dtha_nactions * sizeof (dtrace_difo_t *)); kmem_free(helper, sizeof (dtrace_helper_action_t)); } static int dtrace_helper_destroygen(int gen) { proc_t *p = curproc; dtrace_helpers_t *help = p->p_dtrace_helpers; dtrace_vstate_t *vstate; int i; ASSERT(MUTEX_HELD(&dtrace_lock)); if (help == NULL || gen > help->dthps_generation) return (EINVAL); vstate = &help->dthps_vstate; for (i = 0; i < DTRACE_NHELPER_ACTIONS; i++) { dtrace_helper_action_t *last = NULL, *h, *next; for (h = help->dthps_actions[i]; h != NULL; h = next) { next = h->dtha_next; if (h->dtha_generation == gen) { if (last != NULL) { last->dtha_next = next; } else { help->dthps_actions[i] = next; } dtrace_helper_action_destroy(h, vstate); } else { last = h; } } } /* * Interate until we've cleared out all helper providers with the * given generation number. */ for (;;) { dtrace_helper_provider_t *prov; /* * Look for a helper provider with the right generation. We * have to start back at the beginning of the list each time * because we drop dtrace_lock. It's unlikely that we'll make * more than two passes. */ for (i = 0; i < help->dthps_nprovs; i++) { prov = help->dthps_provs[i]; if (prov->dthp_generation == gen) break; } /* * If there were no matches, we're done. */ if (i == help->dthps_nprovs) break; /* * Move the last helper provider into this slot. */ help->dthps_nprovs--; help->dthps_provs[i] = help->dthps_provs[help->dthps_nprovs]; help->dthps_provs[help->dthps_nprovs] = NULL; mutex_exit(&dtrace_lock); /* * If we have a meta provider, remove this helper provider. */ mutex_enter(&dtrace_meta_lock); if (dtrace_meta_pid != NULL) { ASSERT(dtrace_deferred_pid == NULL); dtrace_helper_provider_remove(&prov->dthp_prov, p->p_pid); } mutex_exit(&dtrace_meta_lock); dtrace_helper_provider_destroy(prov); mutex_enter(&dtrace_lock); } return (0); } +#endif +#if defined(sun) static int dtrace_helper_validate(dtrace_helper_action_t *helper) { int err = 0, i; dtrace_difo_t *dp; if ((dp = helper->dtha_predicate) != NULL) err += dtrace_difo_validate_helper(dp); for (i = 0; i < helper->dtha_nactions; i++) err += dtrace_difo_validate_helper(helper->dtha_actions[i]); return (err == 0); } +#endif +#if defined(sun) static int dtrace_helper_action_add(int which, dtrace_ecbdesc_t *ep) { dtrace_helpers_t *help; dtrace_helper_action_t *helper, *last; dtrace_actdesc_t *act; dtrace_vstate_t *vstate; dtrace_predicate_t *pred; int count = 0, nactions = 0, i; if (which < 0 || which >= DTRACE_NHELPER_ACTIONS) return (EINVAL); help = curproc->p_dtrace_helpers; last = help->dthps_actions[which]; vstate = &help->dthps_vstate; for (count = 0; last != NULL; last = last->dtha_next) { count++; if (last->dtha_next == NULL) break; } /* * If we already have dtrace_helper_actions_max helper actions for this * helper action type, we'll refuse to add a new one. */ if (count >= dtrace_helper_actions_max) return (ENOSPC); helper = kmem_zalloc(sizeof (dtrace_helper_action_t), KM_SLEEP); helper->dtha_generation = help->dthps_generation; if ((pred = ep->dted_pred.dtpdd_predicate) != NULL) { ASSERT(pred->dtp_difo != NULL); dtrace_difo_hold(pred->dtp_difo); helper->dtha_predicate = pred->dtp_difo; } for (act = ep->dted_action; act != NULL; act = act->dtad_next) { if (act->dtad_kind != DTRACEACT_DIFEXPR) goto err; if (act->dtad_difo == NULL) goto err; nactions++; } helper->dtha_actions = kmem_zalloc(sizeof (dtrace_difo_t *) * (helper->dtha_nactions = nactions), KM_SLEEP); for (act = ep->dted_action, i = 0; act != NULL; act = act->dtad_next) { dtrace_difo_hold(act->dtad_difo); helper->dtha_actions[i++] = act->dtad_difo; } if (!dtrace_helper_validate(helper)) goto err; if (last == NULL) { help->dthps_actions[which] = helper; } else { last->dtha_next = helper; } if (vstate->dtvs_nlocals > dtrace_helptrace_nlocals) { dtrace_helptrace_nlocals = vstate->dtvs_nlocals; dtrace_helptrace_next = 0; } return (0); err: dtrace_helper_action_destroy(helper, vstate); return (EINVAL); } static void dtrace_helper_provider_register(proc_t *p, dtrace_helpers_t *help, dof_helper_t *dofhp) { ASSERT(MUTEX_NOT_HELD(&dtrace_lock)); mutex_enter(&dtrace_meta_lock); mutex_enter(&dtrace_lock); if (!dtrace_attached() || dtrace_meta_pid == NULL) { /* * If the dtrace module is loaded but not attached, or if * there aren't isn't a meta provider registered to deal with * these provider descriptions, we need to postpone creating * the actual providers until later. */ if (help->dthps_next == NULL && help->dthps_prev == NULL && dtrace_deferred_pid != help) { help->dthps_deferred = 1; help->dthps_pid = p->p_pid; help->dthps_next = dtrace_deferred_pid; help->dthps_prev = NULL; if (dtrace_deferred_pid != NULL) dtrace_deferred_pid->dthps_prev = help; dtrace_deferred_pid = help; } mutex_exit(&dtrace_lock); } else if (dofhp != NULL) { /* * If the dtrace module is loaded and we have a particular * helper provider description, pass that off to the * meta provider. */ mutex_exit(&dtrace_lock); dtrace_helper_provide(dofhp, p->p_pid); } else { /* * Otherwise, just pass all the helper provider descriptions * off to the meta provider. */ int i; mutex_exit(&dtrace_lock); for (i = 0; i < help->dthps_nprovs; i++) { dtrace_helper_provide(&help->dthps_provs[i]->dthp_prov, p->p_pid); } } mutex_exit(&dtrace_meta_lock); } static int dtrace_helper_provider_add(dof_helper_t *dofhp, int gen) { dtrace_helpers_t *help; dtrace_helper_provider_t *hprov, **tmp_provs; uint_t tmp_maxprovs, i; ASSERT(MUTEX_HELD(&dtrace_lock)); help = curproc->p_dtrace_helpers; ASSERT(help != NULL); /* * If we already have dtrace_helper_providers_max helper providers, * we're refuse to add a new one. */ if (help->dthps_nprovs >= dtrace_helper_providers_max) return (ENOSPC); /* * Check to make sure this isn't a duplicate. */ for (i = 0; i < help->dthps_nprovs; i++) { if (dofhp->dofhp_addr == help->dthps_provs[i]->dthp_prov.dofhp_addr) return (EALREADY); } hprov = kmem_zalloc(sizeof (dtrace_helper_provider_t), KM_SLEEP); hprov->dthp_prov = *dofhp; hprov->dthp_ref = 1; hprov->dthp_generation = gen; /* * Allocate a bigger table for helper providers if it's already full. */ if (help->dthps_maxprovs == help->dthps_nprovs) { tmp_maxprovs = help->dthps_maxprovs; tmp_provs = help->dthps_provs; if (help->dthps_maxprovs == 0) help->dthps_maxprovs = 2; else help->dthps_maxprovs *= 2; if (help->dthps_maxprovs > dtrace_helper_providers_max) help->dthps_maxprovs = dtrace_helper_providers_max; ASSERT(tmp_maxprovs < help->dthps_maxprovs); help->dthps_provs = kmem_zalloc(help->dthps_maxprovs * sizeof (dtrace_helper_provider_t *), KM_SLEEP); if (tmp_provs != NULL) { bcopy(tmp_provs, help->dthps_provs, tmp_maxprovs * sizeof (dtrace_helper_provider_t *)); kmem_free(tmp_provs, tmp_maxprovs * sizeof (dtrace_helper_provider_t *)); } } help->dthps_provs[help->dthps_nprovs] = hprov; help->dthps_nprovs++; return (0); } static void dtrace_helper_provider_destroy(dtrace_helper_provider_t *hprov) { mutex_enter(&dtrace_lock); if (--hprov->dthp_ref == 0) { dof_hdr_t *dof; mutex_exit(&dtrace_lock); dof = (dof_hdr_t *)(uintptr_t)hprov->dthp_prov.dofhp_dof; dtrace_dof_destroy(dof); kmem_free(hprov, sizeof (dtrace_helper_provider_t)); } else { mutex_exit(&dtrace_lock); } } static int dtrace_helper_provider_validate(dof_hdr_t *dof, dof_sec_t *sec) { uintptr_t daddr = (uintptr_t)dof; dof_sec_t *str_sec, *prb_sec, *arg_sec, *off_sec, *enoff_sec; dof_provider_t *provider; dof_probe_t *probe; uint8_t *arg; char *strtab, *typestr; dof_stridx_t typeidx; size_t typesz; uint_t nprobes, j, k; ASSERT(sec->dofs_type == DOF_SECT_PROVIDER); if (sec->dofs_offset & (sizeof (uint_t) - 1)) { dtrace_dof_error(dof, "misaligned section offset"); return (-1); } /* * The section needs to be large enough to contain the DOF provider * structure appropriate for the given version. */ if (sec->dofs_size < ((dof->dofh_ident[DOF_ID_VERSION] == DOF_VERSION_1) ? offsetof(dof_provider_t, dofpv_prenoffs) : sizeof (dof_provider_t))) { dtrace_dof_error(dof, "provider section too small"); return (-1); } provider = (dof_provider_t *)(uintptr_t)(daddr + sec->dofs_offset); str_sec = dtrace_dof_sect(dof, DOF_SECT_STRTAB, provider->dofpv_strtab); prb_sec = dtrace_dof_sect(dof, DOF_SECT_PROBES, provider->dofpv_probes); arg_sec = dtrace_dof_sect(dof, DOF_SECT_PRARGS, provider->dofpv_prargs); off_sec = dtrace_dof_sect(dof, DOF_SECT_PROFFS, provider->dofpv_proffs); if (str_sec == NULL || prb_sec == NULL || arg_sec == NULL || off_sec == NULL) return (-1); enoff_sec = NULL; if (dof->dofh_ident[DOF_ID_VERSION] != DOF_VERSION_1 && provider->dofpv_prenoffs != DOF_SECT_NONE && (enoff_sec = dtrace_dof_sect(dof, DOF_SECT_PRENOFFS, provider->dofpv_prenoffs)) == NULL) return (-1); strtab = (char *)(uintptr_t)(daddr + str_sec->dofs_offset); if (provider->dofpv_name >= str_sec->dofs_size || strlen(strtab + provider->dofpv_name) >= DTRACE_PROVNAMELEN) { dtrace_dof_error(dof, "invalid provider name"); return (-1); } if (prb_sec->dofs_entsize == 0 || prb_sec->dofs_entsize > prb_sec->dofs_size) { dtrace_dof_error(dof, "invalid entry size"); return (-1); } if (prb_sec->dofs_entsize & (sizeof (uintptr_t) - 1)) { dtrace_dof_error(dof, "misaligned entry size"); return (-1); } if (off_sec->dofs_entsize != sizeof (uint32_t)) { dtrace_dof_error(dof, "invalid entry size"); return (-1); } if (off_sec->dofs_offset & (sizeof (uint32_t) - 1)) { dtrace_dof_error(dof, "misaligned section offset"); return (-1); } if (arg_sec->dofs_entsize != sizeof (uint8_t)) { dtrace_dof_error(dof, "invalid entry size"); return (-1); } arg = (uint8_t *)(uintptr_t)(daddr + arg_sec->dofs_offset); nprobes = prb_sec->dofs_size / prb_sec->dofs_entsize; /* * Take a pass through the probes to check for errors. */ for (j = 0; j < nprobes; j++) { probe = (dof_probe_t *)(uintptr_t)(daddr + prb_sec->dofs_offset + j * prb_sec->dofs_entsize); if (probe->dofpr_func >= str_sec->dofs_size) { dtrace_dof_error(dof, "invalid function name"); return (-1); } if (strlen(strtab + probe->dofpr_func) >= DTRACE_FUNCNAMELEN) { dtrace_dof_error(dof, "function name too long"); return (-1); } if (probe->dofpr_name >= str_sec->dofs_size || strlen(strtab + probe->dofpr_name) >= DTRACE_NAMELEN) { dtrace_dof_error(dof, "invalid probe name"); return (-1); } /* * The offset count must not wrap the index, and the offsets * must also not overflow the section's data. */ if (probe->dofpr_offidx + probe->dofpr_noffs < probe->dofpr_offidx || (probe->dofpr_offidx + probe->dofpr_noffs) * off_sec->dofs_entsize > off_sec->dofs_size) { dtrace_dof_error(dof, "invalid probe offset"); return (-1); } if (dof->dofh_ident[DOF_ID_VERSION] != DOF_VERSION_1) { /* * If there's no is-enabled offset section, make sure * there aren't any is-enabled offsets. Otherwise * perform the same checks as for probe offsets * (immediately above). */ if (enoff_sec == NULL) { if (probe->dofpr_enoffidx != 0 || probe->dofpr_nenoffs != 0) { dtrace_dof_error(dof, "is-enabled " "offsets with null section"); return (-1); } } else if (probe->dofpr_enoffidx + probe->dofpr_nenoffs < probe->dofpr_enoffidx || (probe->dofpr_enoffidx + probe->dofpr_nenoffs) * enoff_sec->dofs_entsize > enoff_sec->dofs_size) { dtrace_dof_error(dof, "invalid is-enabled " "offset"); return (-1); } if (probe->dofpr_noffs + probe->dofpr_nenoffs == 0) { dtrace_dof_error(dof, "zero probe and " "is-enabled offsets"); return (-1); } } else if (probe->dofpr_noffs == 0) { dtrace_dof_error(dof, "zero probe offsets"); return (-1); } if (probe->dofpr_argidx + probe->dofpr_xargc < probe->dofpr_argidx || (probe->dofpr_argidx + probe->dofpr_xargc) * arg_sec->dofs_entsize > arg_sec->dofs_size) { dtrace_dof_error(dof, "invalid args"); return (-1); } typeidx = probe->dofpr_nargv; typestr = strtab + probe->dofpr_nargv; for (k = 0; k < probe->dofpr_nargc; k++) { if (typeidx >= str_sec->dofs_size) { dtrace_dof_error(dof, "bad " "native argument type"); return (-1); } typesz = strlen(typestr) + 1; if (typesz > DTRACE_ARGTYPELEN) { dtrace_dof_error(dof, "native " "argument type too long"); return (-1); } typeidx += typesz; typestr += typesz; } typeidx = probe->dofpr_xargv; typestr = strtab + probe->dofpr_xargv; for (k = 0; k < probe->dofpr_xargc; k++) { if (arg[probe->dofpr_argidx + k] > probe->dofpr_nargc) { dtrace_dof_error(dof, "bad " "native argument index"); return (-1); } if (typeidx >= str_sec->dofs_size) { dtrace_dof_error(dof, "bad " "translated argument type"); return (-1); } typesz = strlen(typestr) + 1; if (typesz > DTRACE_ARGTYPELEN) { dtrace_dof_error(dof, "translated argument " "type too long"); return (-1); } typeidx += typesz; typestr += typesz; } } return (0); } static int dtrace_helper_slurp(dof_hdr_t *dof, dof_helper_t *dhp) { dtrace_helpers_t *help; dtrace_vstate_t *vstate; dtrace_enabling_t *enab = NULL; int i, gen, rv, nhelpers = 0, nprovs = 0, destroy = 1; uintptr_t daddr = (uintptr_t)dof; ASSERT(MUTEX_HELD(&dtrace_lock)); if ((help = curproc->p_dtrace_helpers) == NULL) help = dtrace_helpers_create(curproc); vstate = &help->dthps_vstate; if ((rv = dtrace_dof_slurp(dof, vstate, NULL, &enab, dhp != NULL ? dhp->dofhp_addr : 0, B_FALSE)) != 0) { dtrace_dof_destroy(dof); return (rv); } /* * Look for helper providers and validate their descriptions. */ if (dhp != NULL) { for (i = 0; i < dof->dofh_secnum; i++) { dof_sec_t *sec = (dof_sec_t *)(uintptr_t)(daddr + dof->dofh_secoff + i * dof->dofh_secsize); if (sec->dofs_type != DOF_SECT_PROVIDER) continue; if (dtrace_helper_provider_validate(dof, sec) != 0) { dtrace_enabling_destroy(enab); dtrace_dof_destroy(dof); return (-1); } nprovs++; } } /* * Now we need to walk through the ECB descriptions in the enabling. */ for (i = 0; i < enab->dten_ndesc; i++) { dtrace_ecbdesc_t *ep = enab->dten_desc[i]; dtrace_probedesc_t *desc = &ep->dted_probe; if (strcmp(desc->dtpd_provider, "dtrace") != 0) continue; if (strcmp(desc->dtpd_mod, "helper") != 0) continue; if (strcmp(desc->dtpd_func, "ustack") != 0) continue; if ((rv = dtrace_helper_action_add(DTRACE_HELPER_ACTION_USTACK, ep)) != 0) { /* * Adding this helper action failed -- we are now going * to rip out the entire generation and return failure. */ (void) dtrace_helper_destroygen(help->dthps_generation); dtrace_enabling_destroy(enab); dtrace_dof_destroy(dof); return (-1); } nhelpers++; } if (nhelpers < enab->dten_ndesc) dtrace_dof_error(dof, "unmatched helpers"); gen = help->dthps_generation++; dtrace_enabling_destroy(enab); if (dhp != NULL && nprovs > 0) { dhp->dofhp_dof = (uint64_t)(uintptr_t)dof; if (dtrace_helper_provider_add(dhp, gen) == 0) { mutex_exit(&dtrace_lock); dtrace_helper_provider_register(curproc, help, dhp); mutex_enter(&dtrace_lock); destroy = 0; } } if (destroy) dtrace_dof_destroy(dof); return (gen); } static dtrace_helpers_t * dtrace_helpers_create(proc_t *p) { dtrace_helpers_t *help; ASSERT(MUTEX_HELD(&dtrace_lock)); ASSERT(p->p_dtrace_helpers == NULL); help = kmem_zalloc(sizeof (dtrace_helpers_t), KM_SLEEP); help->dthps_actions = kmem_zalloc(sizeof (dtrace_helper_action_t *) * DTRACE_NHELPER_ACTIONS, KM_SLEEP); p->p_dtrace_helpers = help; dtrace_helpers++; return (help); } static void dtrace_helpers_destroy(void) { dtrace_helpers_t *help; dtrace_vstate_t *vstate; proc_t *p = curproc; int i; mutex_enter(&dtrace_lock); ASSERT(p->p_dtrace_helpers != NULL); ASSERT(dtrace_helpers > 0); help = p->p_dtrace_helpers; vstate = &help->dthps_vstate; /* * We're now going to lose the help from this process. */ p->p_dtrace_helpers = NULL; dtrace_sync(); /* * Destory the helper actions. */ for (i = 0; i < DTRACE_NHELPER_ACTIONS; i++) { dtrace_helper_action_t *h, *next; for (h = help->dthps_actions[i]; h != NULL; h = next) { next = h->dtha_next; dtrace_helper_action_destroy(h, vstate); h = next; } } mutex_exit(&dtrace_lock); /* * Destroy the helper providers. */ if (help->dthps_maxprovs > 0) { mutex_enter(&dtrace_meta_lock); if (dtrace_meta_pid != NULL) { ASSERT(dtrace_deferred_pid == NULL); for (i = 0; i < help->dthps_nprovs; i++) { dtrace_helper_provider_remove( &help->dthps_provs[i]->dthp_prov, p->p_pid); } } else { mutex_enter(&dtrace_lock); ASSERT(help->dthps_deferred == 0 || help->dthps_next != NULL || help->dthps_prev != NULL || help == dtrace_deferred_pid); /* * Remove the helper from the deferred list. */ if (help->dthps_next != NULL) help->dthps_next->dthps_prev = help->dthps_prev; if (help->dthps_prev != NULL) help->dthps_prev->dthps_next = help->dthps_next; if (dtrace_deferred_pid == help) { dtrace_deferred_pid = help->dthps_next; ASSERT(help->dthps_prev == NULL); } mutex_exit(&dtrace_lock); } mutex_exit(&dtrace_meta_lock); for (i = 0; i < help->dthps_nprovs; i++) { dtrace_helper_provider_destroy(help->dthps_provs[i]); } kmem_free(help->dthps_provs, help->dthps_maxprovs * sizeof (dtrace_helper_provider_t *)); } mutex_enter(&dtrace_lock); dtrace_vstate_fini(&help->dthps_vstate); kmem_free(help->dthps_actions, sizeof (dtrace_helper_action_t *) * DTRACE_NHELPER_ACTIONS); kmem_free(help, sizeof (dtrace_helpers_t)); --dtrace_helpers; mutex_exit(&dtrace_lock); } static void dtrace_helpers_duplicate(proc_t *from, proc_t *to) { dtrace_helpers_t *help, *newhelp; dtrace_helper_action_t *helper, *new, *last; dtrace_difo_t *dp; dtrace_vstate_t *vstate; int i, j, sz, hasprovs = 0; mutex_enter(&dtrace_lock); ASSERT(from->p_dtrace_helpers != NULL); ASSERT(dtrace_helpers > 0); help = from->p_dtrace_helpers; newhelp = dtrace_helpers_create(to); ASSERT(to->p_dtrace_helpers != NULL); newhelp->dthps_generation = help->dthps_generation; vstate = &newhelp->dthps_vstate; /* * Duplicate the helper actions. */ for (i = 0; i < DTRACE_NHELPER_ACTIONS; i++) { if ((helper = help->dthps_actions[i]) == NULL) continue; for (last = NULL; helper != NULL; helper = helper->dtha_next) { new = kmem_zalloc(sizeof (dtrace_helper_action_t), KM_SLEEP); new->dtha_generation = helper->dtha_generation; if ((dp = helper->dtha_predicate) != NULL) { dp = dtrace_difo_duplicate(dp, vstate); new->dtha_predicate = dp; } new->dtha_nactions = helper->dtha_nactions; sz = sizeof (dtrace_difo_t *) * new->dtha_nactions; new->dtha_actions = kmem_alloc(sz, KM_SLEEP); for (j = 0; j < new->dtha_nactions; j++) { dtrace_difo_t *dp = helper->dtha_actions[j]; ASSERT(dp != NULL); dp = dtrace_difo_duplicate(dp, vstate); new->dtha_actions[j] = dp; } if (last != NULL) { last->dtha_next = new; } else { newhelp->dthps_actions[i] = new; } last = new; } } /* * Duplicate the helper providers and register them with the * DTrace framework. */ if (help->dthps_nprovs > 0) { newhelp->dthps_nprovs = help->dthps_nprovs; newhelp->dthps_maxprovs = help->dthps_nprovs; newhelp->dthps_provs = kmem_alloc(newhelp->dthps_nprovs * sizeof (dtrace_helper_provider_t *), KM_SLEEP); for (i = 0; i < newhelp->dthps_nprovs; i++) { newhelp->dthps_provs[i] = help->dthps_provs[i]; newhelp->dthps_provs[i]->dthp_ref++; } hasprovs = 1; } mutex_exit(&dtrace_lock); if (hasprovs) dtrace_helper_provider_register(to, newhelp, NULL); } +#endif +#if defined(sun) /* * DTrace Hook Functions */ static void -dtrace_module_loaded(struct modctl *ctl) +dtrace_module_loaded(modctl_t *ctl) { dtrace_provider_t *prv; mutex_enter(&dtrace_provider_lock); mutex_enter(&mod_lock); ASSERT(ctl->mod_busy); /* * We're going to call each providers per-module provide operation * specifying only this module. */ for (prv = dtrace_provider; prv != NULL; prv = prv->dtpv_next) prv->dtpv_pops.dtps_provide_module(prv->dtpv_arg, ctl); mutex_exit(&mod_lock); mutex_exit(&dtrace_provider_lock); /* * If we have any retained enablings, we need to match against them. * Enabling probes requires that cpu_lock be held, and we cannot hold * cpu_lock here -- it is legal for cpu_lock to be held when loading a * module. (In particular, this happens when loading scheduling * classes.) So if we have any retained enablings, we need to dispatch * our task queue to do the match for us. */ mutex_enter(&dtrace_lock); if (dtrace_retained == NULL) { mutex_exit(&dtrace_lock); return; } (void) taskq_dispatch(dtrace_taskq, (task_func_t *)dtrace_enabling_matchall, NULL, TQ_SLEEP); mutex_exit(&dtrace_lock); /* * And now, for a little heuristic sleaze: in general, we want to * match modules as soon as they load. However, we cannot guarantee * this, because it would lead us to the lock ordering violation * outlined above. The common case, of course, is that cpu_lock is * _not_ held -- so we delay here for a clock tick, hoping that that's * long enough for the task queue to do its work. If it's not, it's * not a serious problem -- it just means that the module that we * just loaded may not be immediately instrumentable. */ delay(1); } static void -dtrace_module_unloaded(struct modctl *ctl) +dtrace_module_unloaded(modctl_t *ctl) { dtrace_probe_t template, *probe, *first, *next; dtrace_provider_t *prov; template.dtpr_mod = ctl->mod_modname; mutex_enter(&dtrace_provider_lock); mutex_enter(&mod_lock); mutex_enter(&dtrace_lock); if (dtrace_bymod == NULL) { /* * The DTrace module is loaded (obviously) but not attached; * we don't have any work to do. */ mutex_exit(&dtrace_provider_lock); mutex_exit(&mod_lock); mutex_exit(&dtrace_lock); return; } for (probe = first = dtrace_hash_lookup(dtrace_bymod, &template); probe != NULL; probe = probe->dtpr_nextmod) { if (probe->dtpr_ecb != NULL) { mutex_exit(&dtrace_provider_lock); mutex_exit(&mod_lock); mutex_exit(&dtrace_lock); /* * This shouldn't _actually_ be possible -- we're * unloading a module that has an enabled probe in it. * (It's normally up to the provider to make sure that * this can't happen.) However, because dtps_enable() * doesn't have a failure mode, there can be an * enable/unload race. Upshot: we don't want to * assert, but we're not going to disable the * probe, either. */ if (dtrace_err_verbose) { cmn_err(CE_WARN, "unloaded module '%s' had " "enabled probes", ctl->mod_modname); } return; } } probe = first; for (first = NULL; probe != NULL; probe = next) { ASSERT(dtrace_probes[probe->dtpr_id - 1] == probe); dtrace_probes[probe->dtpr_id - 1] = NULL; next = probe->dtpr_nextmod; dtrace_hash_remove(dtrace_bymod, probe); dtrace_hash_remove(dtrace_byfunc, probe); dtrace_hash_remove(dtrace_byname, probe); if (first == NULL) { first = probe; probe->dtpr_nextmod = NULL; } else { probe->dtpr_nextmod = first; first = probe; } } /* * We've removed all of the module's probes from the hash chains and * from the probe array. Now issue a dtrace_sync() to be sure that * everyone has cleared out from any probe array processing. */ dtrace_sync(); for (probe = first; probe != NULL; probe = first) { first = probe->dtpr_nextmod; prov = probe->dtpr_provider; prov->dtpv_pops.dtps_destroy(prov->dtpv_arg, probe->dtpr_id, probe->dtpr_arg); kmem_free(probe->dtpr_mod, strlen(probe->dtpr_mod) + 1); kmem_free(probe->dtpr_func, strlen(probe->dtpr_func) + 1); kmem_free(probe->dtpr_name, strlen(probe->dtpr_name) + 1); vmem_free(dtrace_arena, (void *)(uintptr_t)probe->dtpr_id, 1); kmem_free(probe, sizeof (dtrace_probe_t)); } mutex_exit(&dtrace_lock); mutex_exit(&mod_lock); mutex_exit(&dtrace_provider_lock); } -void +static void dtrace_suspend(void) { dtrace_probe_foreach(offsetof(dtrace_pops_t, dtps_suspend)); } -void +static void dtrace_resume(void) { dtrace_probe_foreach(offsetof(dtrace_pops_t, dtps_resume)); } +#endif static int dtrace_cpu_setup(cpu_setup_t what, processorid_t cpu) { ASSERT(MUTEX_HELD(&cpu_lock)); mutex_enter(&dtrace_lock); switch (what) { case CPU_CONFIG: { dtrace_state_t *state; dtrace_optval_t *opt, rs, c; /* * For now, we only allocate a new buffer for anonymous state. */ if ((state = dtrace_anon.dta_state) == NULL) break; if (state->dts_activity != DTRACE_ACTIVITY_ACTIVE) break; opt = state->dts_options; c = opt[DTRACEOPT_CPU]; if (c != DTRACE_CPUALL && c != DTRACEOPT_UNSET && c != cpu) break; /* * Regardless of what the actual policy is, we're going to * temporarily set our resize policy to be manual. We're * also going to temporarily set our CPU option to denote * the newly configured CPU. */ rs = opt[DTRACEOPT_BUFRESIZE]; opt[DTRACEOPT_BUFRESIZE] = DTRACEOPT_BUFRESIZE_MANUAL; opt[DTRACEOPT_CPU] = (dtrace_optval_t)cpu; (void) dtrace_state_buffers(state); opt[DTRACEOPT_BUFRESIZE] = rs; opt[DTRACEOPT_CPU] = c; break; } case CPU_UNCONFIG: /* * We don't free the buffer in the CPU_UNCONFIG case. (The * buffer will be freed when the consumer exits.) */ break; default: break; } mutex_exit(&dtrace_lock); return (0); } +#if defined(sun) static void dtrace_cpu_setup_initial(processorid_t cpu) { (void) dtrace_cpu_setup(CPU_CONFIG, cpu); } +#endif static void dtrace_toxrange_add(uintptr_t base, uintptr_t limit) { if (dtrace_toxranges >= dtrace_toxranges_max) { int osize, nsize; dtrace_toxrange_t *range; osize = dtrace_toxranges_max * sizeof (dtrace_toxrange_t); if (osize == 0) { ASSERT(dtrace_toxrange == NULL); ASSERT(dtrace_toxranges_max == 0); dtrace_toxranges_max = 1; } else { dtrace_toxranges_max <<= 1; } nsize = dtrace_toxranges_max * sizeof (dtrace_toxrange_t); range = kmem_zalloc(nsize, KM_SLEEP); if (dtrace_toxrange != NULL) { ASSERT(osize != 0); bcopy(dtrace_toxrange, range, osize); kmem_free(dtrace_toxrange, osize); } dtrace_toxrange = range; } - ASSERT(dtrace_toxrange[dtrace_toxranges].dtt_base == NULL); - ASSERT(dtrace_toxrange[dtrace_toxranges].dtt_limit == NULL); + ASSERT(dtrace_toxrange[dtrace_toxranges].dtt_base == 0); + ASSERT(dtrace_toxrange[dtrace_toxranges].dtt_limit == 0); dtrace_toxrange[dtrace_toxranges].dtt_base = base; dtrace_toxrange[dtrace_toxranges].dtt_limit = limit; dtrace_toxranges++; } /* * DTrace Driver Cookbook Functions */ +#if defined(sun) /*ARGSUSED*/ static int dtrace_attach(dev_info_t *devi, ddi_attach_cmd_t cmd) { dtrace_provider_id_t id; dtrace_state_t *state = NULL; dtrace_enabling_t *enab; mutex_enter(&cpu_lock); mutex_enter(&dtrace_provider_lock); mutex_enter(&dtrace_lock); if (ddi_soft_state_init(&dtrace_softstate, sizeof (dtrace_state_t), 0) != 0) { cmn_err(CE_NOTE, "/dev/dtrace failed to initialize soft state"); mutex_exit(&cpu_lock); mutex_exit(&dtrace_provider_lock); mutex_exit(&dtrace_lock); return (DDI_FAILURE); } if (ddi_create_minor_node(devi, DTRACEMNR_DTRACE, S_IFCHR, DTRACEMNRN_DTRACE, DDI_PSEUDO, NULL) == DDI_FAILURE || ddi_create_minor_node(devi, DTRACEMNR_HELPER, S_IFCHR, DTRACEMNRN_HELPER, DDI_PSEUDO, NULL) == DDI_FAILURE) { cmn_err(CE_NOTE, "/dev/dtrace couldn't create minor nodes"); ddi_remove_minor_node(devi, NULL); ddi_soft_state_fini(&dtrace_softstate); mutex_exit(&cpu_lock); mutex_exit(&dtrace_provider_lock); mutex_exit(&dtrace_lock); return (DDI_FAILURE); } ddi_report_dev(devi); dtrace_devi = devi; dtrace_modload = dtrace_module_loaded; dtrace_modunload = dtrace_module_unloaded; dtrace_cpu_init = dtrace_cpu_setup_initial; dtrace_helpers_cleanup = dtrace_helpers_destroy; dtrace_helpers_fork = dtrace_helpers_duplicate; dtrace_cpustart_init = dtrace_suspend; dtrace_cpustart_fini = dtrace_resume; dtrace_debugger_init = dtrace_suspend; dtrace_debugger_fini = dtrace_resume; register_cpu_setup_func((cpu_setup_func_t *)dtrace_cpu_setup, NULL); ASSERT(MUTEX_HELD(&cpu_lock)); dtrace_arena = vmem_create("dtrace", (void *)1, UINT32_MAX, 1, NULL, NULL, NULL, 0, VM_SLEEP | VMC_IDENTIFIER); dtrace_minor = vmem_create("dtrace_minor", (void *)DTRACEMNRN_CLONE, UINT32_MAX - DTRACEMNRN_CLONE, 1, NULL, NULL, NULL, 0, VM_SLEEP | VMC_IDENTIFIER); dtrace_taskq = taskq_create("dtrace_taskq", 1, maxclsyspri, 1, INT_MAX, 0); dtrace_state_cache = kmem_cache_create("dtrace_state_cache", sizeof (dtrace_dstate_percpu_t) * NCPU, DTRACE_STATE_ALIGN, NULL, NULL, NULL, NULL, NULL, 0); ASSERT(MUTEX_HELD(&cpu_lock)); dtrace_bymod = dtrace_hash_create(offsetof(dtrace_probe_t, dtpr_mod), offsetof(dtrace_probe_t, dtpr_nextmod), offsetof(dtrace_probe_t, dtpr_prevmod)); dtrace_byfunc = dtrace_hash_create(offsetof(dtrace_probe_t, dtpr_func), offsetof(dtrace_probe_t, dtpr_nextfunc), offsetof(dtrace_probe_t, dtpr_prevfunc)); dtrace_byname = dtrace_hash_create(offsetof(dtrace_probe_t, dtpr_name), offsetof(dtrace_probe_t, dtpr_nextname), offsetof(dtrace_probe_t, dtpr_prevname)); if (dtrace_retain_max < 1) { cmn_err(CE_WARN, "illegal value (%lu) for dtrace_retain_max; " "setting to 1", dtrace_retain_max); dtrace_retain_max = 1; } /* * Now discover our toxic ranges. */ dtrace_toxic_ranges(dtrace_toxrange_add); /* * Before we register ourselves as a provider to our own framework, * we would like to assert that dtrace_provider is NULL -- but that's * not true if we were loaded as a dependency of a DTrace provider. * Once we've registered, we can assert that dtrace_provider is our * pseudo provider. */ (void) dtrace_register("dtrace", &dtrace_provider_attr, DTRACE_PRIV_NONE, 0, &dtrace_provider_ops, NULL, &id); ASSERT(dtrace_provider != NULL); ASSERT((dtrace_provider_id_t)dtrace_provider == id); dtrace_probeid_begin = dtrace_probe_create((dtrace_provider_id_t) dtrace_provider, NULL, NULL, "BEGIN", 0, NULL); dtrace_probeid_end = dtrace_probe_create((dtrace_provider_id_t) dtrace_provider, NULL, NULL, "END", 0, NULL); dtrace_probeid_error = dtrace_probe_create((dtrace_provider_id_t) dtrace_provider, NULL, NULL, "ERROR", 1, NULL); dtrace_anon_property(); mutex_exit(&cpu_lock); /* * If DTrace helper tracing is enabled, we need to allocate the * trace buffer and initialize the values. */ if (dtrace_helptrace_enabled) { ASSERT(dtrace_helptrace_buffer == NULL); dtrace_helptrace_buffer = kmem_zalloc(dtrace_helptrace_bufsize, KM_SLEEP); dtrace_helptrace_next = 0; } /* * If there are already providers, we must ask them to provide their * probes, and then match any anonymous enabling against them. Note * that there should be no other retained enablings at this time: * the only retained enablings at this time should be the anonymous * enabling. */ if (dtrace_anon.dta_enabling != NULL) { ASSERT(dtrace_retained == dtrace_anon.dta_enabling); dtrace_enabling_provide(NULL); state = dtrace_anon.dta_state; /* * We couldn't hold cpu_lock across the above call to * dtrace_enabling_provide(), but we must hold it to actually * enable the probes. We have to drop all of our locks, pick * up cpu_lock, and regain our locks before matching the * retained anonymous enabling. */ mutex_exit(&dtrace_lock); mutex_exit(&dtrace_provider_lock); mutex_enter(&cpu_lock); mutex_enter(&dtrace_provider_lock); mutex_enter(&dtrace_lock); if ((enab = dtrace_anon.dta_enabling) != NULL) (void) dtrace_enabling_match(enab, NULL); mutex_exit(&cpu_lock); } mutex_exit(&dtrace_lock); mutex_exit(&dtrace_provider_lock); if (state != NULL) { /* * If we created any anonymous state, set it going now. */ (void) dtrace_state_go(state, &dtrace_anon.dta_beganon); } return (DDI_SUCCESS); } +#endif /*ARGSUSED*/ static int +#if defined(sun) dtrace_open(dev_t *devp, int flag, int otyp, cred_t *cred_p) +#else +dtrace_open(struct cdev *dev, int oflags, int devtype, struct thread *td) +#endif { dtrace_state_t *state; uint32_t priv; uid_t uid; zoneid_t zoneid; +#if defined(sun) if (getminor(*devp) == DTRACEMNRN_HELPER) return (0); /* * If this wasn't an open with the "helper" minor, then it must be * the "dtrace" minor. */ ASSERT(getminor(*devp) == DTRACEMNRN_DTRACE); +#else + cred_t *cred_p = NULL; /* + * The first minor device is the one that is cloned so there is + * nothing more to do here. + */ + if (minor(dev) == 0) + return 0; + + /* + * Devices are cloned, so if the DTrace state has already + * been allocated, that means this device belongs to a + * different client. Each client should open '/dev/dtrace' + * to get a cloned device. + */ + if (dev->si_drv1 != NULL) + return (EBUSY); + + cred_p = dev->si_cred; +#endif + + /* * If no DTRACE_PRIV_* bits are set in the credential, then the * caller lacks sufficient permission to do anything with DTrace. */ dtrace_cred2priv(cred_p, &priv, &uid, &zoneid); - if (priv == DTRACE_PRIV_NONE) + if (priv == DTRACE_PRIV_NONE) { +#if !defined(sun) + /* Destroy the cloned device. */ + destroy_dev(dev); +#endif + return (EACCES); + } /* * Ask all providers to provide all their probes. */ mutex_enter(&dtrace_provider_lock); dtrace_probe_provide(NULL, NULL); mutex_exit(&dtrace_provider_lock); mutex_enter(&cpu_lock); mutex_enter(&dtrace_lock); dtrace_opens++; dtrace_membar_producer(); +#if defined(sun) /* * If the kernel debugger is active (that is, if the kernel debugger * modified text in some way), we won't allow the open. */ if (kdi_dtrace_set(KDI_DTSET_DTRACE_ACTIVATE) != 0) { dtrace_opens--; mutex_exit(&cpu_lock); mutex_exit(&dtrace_lock); return (EBUSY); } state = dtrace_state_create(devp, cred_p); +#else + state = dtrace_state_create(dev); + dev->si_drv1 = state; +#endif + mutex_exit(&cpu_lock); if (state == NULL) { +#if defined(sun) if (--dtrace_opens == 0) (void) kdi_dtrace_set(KDI_DTSET_DTRACE_DEACTIVATE); +#else + --dtrace_opens; +#endif mutex_exit(&dtrace_lock); +#if !defined(sun) + /* Destroy the cloned device. */ + destroy_dev(dev); +#endif return (EAGAIN); } mutex_exit(&dtrace_lock); return (0); } /*ARGSUSED*/ static int +#if defined(sun) dtrace_close(dev_t dev, int flag, int otyp, cred_t *cred_p) +#else +dtrace_close(struct cdev *dev, int flags, int fmt __unused, struct thread *td) +#endif { +#if defined(sun) minor_t minor = getminor(dev); dtrace_state_t *state; if (minor == DTRACEMNRN_HELPER) return (0); state = ddi_get_soft_state(dtrace_softstate, minor); +#else + dtrace_state_t *state = dev->si_drv1; + /* Check if this is not a cloned device. */ + if (minor(dev) == 0) + return (0); + +#endif + mutex_enter(&cpu_lock); mutex_enter(&dtrace_lock); - if (state->dts_anon) { - /* - * There is anonymous state. Destroy that first. - */ - ASSERT(dtrace_anon.dta_state == NULL); - dtrace_state_destroy(state->dts_anon); + if (state != NULL) { + if (state->dts_anon) { + /* + * There is anonymous state. Destroy that first. + */ + ASSERT(dtrace_anon.dta_state == NULL); + dtrace_state_destroy(state->dts_anon); + } + + dtrace_state_destroy(state); + +#if !defined(sun) + kmem_free(state, 0); + dev->si_drv1 = NULL; +#endif } - dtrace_state_destroy(state); ASSERT(dtrace_opens > 0); +#if defined(sun) if (--dtrace_opens == 0) (void) kdi_dtrace_set(KDI_DTSET_DTRACE_DEACTIVATE); +#else + --dtrace_opens; +#endif mutex_exit(&dtrace_lock); mutex_exit(&cpu_lock); + /* Schedule this cloned device to be destroyed. */ + destroy_dev_sched(dev); + return (0); } +#if defined(sun) /*ARGSUSED*/ static int dtrace_ioctl_helper(int cmd, intptr_t arg, int *rv) { int rval; dof_helper_t help, *dhp = NULL; switch (cmd) { case DTRACEHIOC_ADDDOF: if (copyin((void *)arg, &help, sizeof (help)) != 0) { dtrace_dof_error(NULL, "failed to copyin DOF helper"); return (EFAULT); } dhp = &help; arg = (intptr_t)help.dofhp_dof; /*FALLTHROUGH*/ case DTRACEHIOC_ADD: { dof_hdr_t *dof = dtrace_dof_copyin(arg, &rval); if (dof == NULL) return (rval); mutex_enter(&dtrace_lock); /* * dtrace_helper_slurp() takes responsibility for the dof -- * it may free it now or it may save it and free it later. */ if ((rval = dtrace_helper_slurp(dof, dhp)) != -1) { *rv = rval; rval = 0; } else { rval = EINVAL; } mutex_exit(&dtrace_lock); return (rval); } case DTRACEHIOC_REMOVE: { mutex_enter(&dtrace_lock); rval = dtrace_helper_destroygen(arg); mutex_exit(&dtrace_lock); return (rval); } default: break; } return (ENOTTY); } /*ARGSUSED*/ static int dtrace_ioctl(dev_t dev, int cmd, intptr_t arg, int md, cred_t *cr, int *rv) { minor_t minor = getminor(dev); dtrace_state_t *state; int rval; if (minor == DTRACEMNRN_HELPER) return (dtrace_ioctl_helper(cmd, arg, rv)); state = ddi_get_soft_state(dtrace_softstate, minor); if (state->dts_anon) { ASSERT(dtrace_anon.dta_state == NULL); state = state->dts_anon; } switch (cmd) { case DTRACEIOC_PROVIDER: { dtrace_providerdesc_t pvd; dtrace_provider_t *pvp; if (copyin((void *)arg, &pvd, sizeof (pvd)) != 0) return (EFAULT); pvd.dtvd_name[DTRACE_PROVNAMELEN - 1] = '\0'; mutex_enter(&dtrace_provider_lock); for (pvp = dtrace_provider; pvp != NULL; pvp = pvp->dtpv_next) { if (strcmp(pvp->dtpv_name, pvd.dtvd_name) == 0) break; } mutex_exit(&dtrace_provider_lock); if (pvp == NULL) return (ESRCH); bcopy(&pvp->dtpv_priv, &pvd.dtvd_priv, sizeof (dtrace_ppriv_t)); bcopy(&pvp->dtpv_attr, &pvd.dtvd_attr, sizeof (dtrace_pattr_t)); + if (copyout(&pvd, (void *)arg, sizeof (pvd)) != 0) return (EFAULT); return (0); } case DTRACEIOC_EPROBE: { dtrace_eprobedesc_t epdesc; dtrace_ecb_t *ecb; dtrace_action_t *act; void *buf; size_t size; uintptr_t dest; int nrecs; if (copyin((void *)arg, &epdesc, sizeof (epdesc)) != 0) return (EFAULT); mutex_enter(&dtrace_lock); if ((ecb = dtrace_epid2ecb(state, epdesc.dtepd_epid)) == NULL) { mutex_exit(&dtrace_lock); return (EINVAL); } if (ecb->dte_probe == NULL) { mutex_exit(&dtrace_lock); return (EINVAL); } epdesc.dtepd_probeid = ecb->dte_probe->dtpr_id; epdesc.dtepd_uarg = ecb->dte_uarg; epdesc.dtepd_size = ecb->dte_size; nrecs = epdesc.dtepd_nrecs; epdesc.dtepd_nrecs = 0; for (act = ecb->dte_action; act != NULL; act = act->dta_next) { if (DTRACEACT_ISAGG(act->dta_kind) || act->dta_intuple) continue; epdesc.dtepd_nrecs++; } /* * Now that we have the size, we need to allocate a temporary * buffer in which to store the complete description. We need * the temporary buffer to be able to drop dtrace_lock() * across the copyout(), below. */ size = sizeof (dtrace_eprobedesc_t) + (epdesc.dtepd_nrecs * sizeof (dtrace_recdesc_t)); buf = kmem_alloc(size, KM_SLEEP); dest = (uintptr_t)buf; bcopy(&epdesc, (void *)dest, sizeof (epdesc)); dest += offsetof(dtrace_eprobedesc_t, dtepd_rec[0]); for (act = ecb->dte_action; act != NULL; act = act->dta_next) { if (DTRACEACT_ISAGG(act->dta_kind) || act->dta_intuple) continue; if (nrecs-- == 0) break; bcopy(&act->dta_rec, (void *)dest, sizeof (dtrace_recdesc_t)); dest += sizeof (dtrace_recdesc_t); } mutex_exit(&dtrace_lock); if (copyout(buf, (void *)arg, dest - (uintptr_t)buf) != 0) { kmem_free(buf, size); return (EFAULT); } kmem_free(buf, size); return (0); } case DTRACEIOC_AGGDESC: { dtrace_aggdesc_t aggdesc; dtrace_action_t *act; dtrace_aggregation_t *agg; int nrecs; uint32_t offs; dtrace_recdesc_t *lrec; void *buf; size_t size; uintptr_t dest; if (copyin((void *)arg, &aggdesc, sizeof (aggdesc)) != 0) return (EFAULT); mutex_enter(&dtrace_lock); if ((agg = dtrace_aggid2agg(state, aggdesc.dtagd_id)) == NULL) { mutex_exit(&dtrace_lock); return (EINVAL); } aggdesc.dtagd_epid = agg->dtag_ecb->dte_epid; nrecs = aggdesc.dtagd_nrecs; aggdesc.dtagd_nrecs = 0; offs = agg->dtag_base; lrec = &agg->dtag_action.dta_rec; aggdesc.dtagd_size = lrec->dtrd_offset + lrec->dtrd_size - offs; for (act = agg->dtag_first; ; act = act->dta_next) { ASSERT(act->dta_intuple || DTRACEACT_ISAGG(act->dta_kind)); /* * If this action has a record size of zero, it * denotes an argument to the aggregating action. * Because the presence of this record doesn't (or * shouldn't) affect the way the data is interpreted, * we don't copy it out to save user-level the * confusion of dealing with a zero-length record. */ if (act->dta_rec.dtrd_size == 0) { ASSERT(agg->dtag_hasarg); continue; } aggdesc.dtagd_nrecs++; if (act == &agg->dtag_action) break; } /* * Now that we have the size, we need to allocate a temporary * buffer in which to store the complete description. We need * the temporary buffer to be able to drop dtrace_lock() * across the copyout(), below. */ size = sizeof (dtrace_aggdesc_t) + (aggdesc.dtagd_nrecs * sizeof (dtrace_recdesc_t)); buf = kmem_alloc(size, KM_SLEEP); dest = (uintptr_t)buf; bcopy(&aggdesc, (void *)dest, sizeof (aggdesc)); dest += offsetof(dtrace_aggdesc_t, dtagd_rec[0]); for (act = agg->dtag_first; ; act = act->dta_next) { dtrace_recdesc_t rec = act->dta_rec; /* * See the comment in the above loop for why we pass * over zero-length records. */ if (rec.dtrd_size == 0) { ASSERT(agg->dtag_hasarg); continue; } if (nrecs-- == 0) break; rec.dtrd_offset -= offs; bcopy(&rec, (void *)dest, sizeof (rec)); dest += sizeof (dtrace_recdesc_t); if (act == &agg->dtag_action) break; } mutex_exit(&dtrace_lock); if (copyout(buf, (void *)arg, dest - (uintptr_t)buf) != 0) { kmem_free(buf, size); return (EFAULT); } kmem_free(buf, size); return (0); } case DTRACEIOC_ENABLE: { dof_hdr_t *dof; dtrace_enabling_t *enab = NULL; dtrace_vstate_t *vstate; int err = 0; *rv = 0; /* * If a NULL argument has been passed, we take this as our * cue to reevaluate our enablings. */ if (arg == NULL) { - mutex_enter(&cpu_lock); - mutex_enter(&dtrace_lock); - err = dtrace_enabling_matchstate(state, rv); - mutex_exit(&dtrace_lock); - mutex_exit(&cpu_lock); + dtrace_enabling_matchall(); - return (err); + return (0); } if ((dof = dtrace_dof_copyin(arg, &rval)) == NULL) return (rval); mutex_enter(&cpu_lock); mutex_enter(&dtrace_lock); vstate = &state->dts_vstate; if (state->dts_activity != DTRACE_ACTIVITY_INACTIVE) { mutex_exit(&dtrace_lock); mutex_exit(&cpu_lock); dtrace_dof_destroy(dof); return (EBUSY); } if (dtrace_dof_slurp(dof, vstate, cr, &enab, 0, B_TRUE) != 0) { mutex_exit(&dtrace_lock); mutex_exit(&cpu_lock); dtrace_dof_destroy(dof); return (EINVAL); } if ((rval = dtrace_dof_options(dof, state)) != 0) { dtrace_enabling_destroy(enab); mutex_exit(&dtrace_lock); mutex_exit(&cpu_lock); dtrace_dof_destroy(dof); return (rval); } if ((err = dtrace_enabling_match(enab, rv)) == 0) { err = dtrace_enabling_retain(enab); } else { dtrace_enabling_destroy(enab); } mutex_exit(&cpu_lock); mutex_exit(&dtrace_lock); dtrace_dof_destroy(dof); return (err); } case DTRACEIOC_REPLICATE: { dtrace_repldesc_t desc; dtrace_probedesc_t *match = &desc.dtrpd_match; dtrace_probedesc_t *create = &desc.dtrpd_create; int err; if (copyin((void *)arg, &desc, sizeof (desc)) != 0) return (EFAULT); match->dtpd_provider[DTRACE_PROVNAMELEN - 1] = '\0'; match->dtpd_mod[DTRACE_MODNAMELEN - 1] = '\0'; match->dtpd_func[DTRACE_FUNCNAMELEN - 1] = '\0'; match->dtpd_name[DTRACE_NAMELEN - 1] = '\0'; create->dtpd_provider[DTRACE_PROVNAMELEN - 1] = '\0'; create->dtpd_mod[DTRACE_MODNAMELEN - 1] = '\0'; create->dtpd_func[DTRACE_FUNCNAMELEN - 1] = '\0'; create->dtpd_name[DTRACE_NAMELEN - 1] = '\0'; mutex_enter(&dtrace_lock); err = dtrace_enabling_replicate(state, match, create); mutex_exit(&dtrace_lock); return (err); } case DTRACEIOC_PROBEMATCH: case DTRACEIOC_PROBES: { dtrace_probe_t *probe = NULL; dtrace_probedesc_t desc; dtrace_probekey_t pkey; dtrace_id_t i; int m = 0; uint32_t priv; uid_t uid; zoneid_t zoneid; if (copyin((void *)arg, &desc, sizeof (desc)) != 0) return (EFAULT); desc.dtpd_provider[DTRACE_PROVNAMELEN - 1] = '\0'; desc.dtpd_mod[DTRACE_MODNAMELEN - 1] = '\0'; desc.dtpd_func[DTRACE_FUNCNAMELEN - 1] = '\0'; desc.dtpd_name[DTRACE_NAMELEN - 1] = '\0'; /* * Before we attempt to match this probe, we want to give * all providers the opportunity to provide it. */ if (desc.dtpd_id == DTRACE_IDNONE) { mutex_enter(&dtrace_provider_lock); dtrace_probe_provide(&desc, NULL); mutex_exit(&dtrace_provider_lock); desc.dtpd_id++; } if (cmd == DTRACEIOC_PROBEMATCH) { dtrace_probekey(&desc, &pkey); pkey.dtpk_id = DTRACE_IDNONE; } dtrace_cred2priv(cr, &priv, &uid, &zoneid); mutex_enter(&dtrace_lock); if (cmd == DTRACEIOC_PROBEMATCH) { for (i = desc.dtpd_id; i <= dtrace_nprobes; i++) { if ((probe = dtrace_probes[i - 1]) != NULL && (m = dtrace_match_probe(probe, &pkey, priv, uid, zoneid)) != 0) break; } if (m < 0) { mutex_exit(&dtrace_lock); return (EINVAL); } } else { for (i = desc.dtpd_id; i <= dtrace_nprobes; i++) { if ((probe = dtrace_probes[i - 1]) != NULL && dtrace_match_priv(probe, priv, uid, zoneid)) break; } } if (probe == NULL) { mutex_exit(&dtrace_lock); return (ESRCH); } dtrace_probe_description(probe, &desc); mutex_exit(&dtrace_lock); if (copyout(&desc, (void *)arg, sizeof (desc)) != 0) return (EFAULT); return (0); } case DTRACEIOC_PROBEARG: { dtrace_argdesc_t desc; dtrace_probe_t *probe; dtrace_provider_t *prov; if (copyin((void *)arg, &desc, sizeof (desc)) != 0) return (EFAULT); if (desc.dtargd_id == DTRACE_IDNONE) return (EINVAL); if (desc.dtargd_ndx == DTRACE_ARGNONE) return (EINVAL); mutex_enter(&dtrace_provider_lock); mutex_enter(&mod_lock); mutex_enter(&dtrace_lock); if (desc.dtargd_id > dtrace_nprobes) { mutex_exit(&dtrace_lock); mutex_exit(&mod_lock); mutex_exit(&dtrace_provider_lock); return (EINVAL); } if ((probe = dtrace_probes[desc.dtargd_id - 1]) == NULL) { mutex_exit(&dtrace_lock); mutex_exit(&mod_lock); mutex_exit(&dtrace_provider_lock); return (EINVAL); } mutex_exit(&dtrace_lock); prov = probe->dtpr_provider; if (prov->dtpv_pops.dtps_getargdesc == NULL) { /* * There isn't any typed information for this probe. * Set the argument number to DTRACE_ARGNONE. */ desc.dtargd_ndx = DTRACE_ARGNONE; } else { desc.dtargd_native[0] = '\0'; desc.dtargd_xlate[0] = '\0'; desc.dtargd_mapping = desc.dtargd_ndx; prov->dtpv_pops.dtps_getargdesc(prov->dtpv_arg, probe->dtpr_id, probe->dtpr_arg, &desc); } mutex_exit(&mod_lock); mutex_exit(&dtrace_provider_lock); if (copyout(&desc, (void *)arg, sizeof (desc)) != 0) return (EFAULT); return (0); } case DTRACEIOC_GO: { processorid_t cpuid; rval = dtrace_state_go(state, &cpuid); if (rval != 0) return (rval); if (copyout(&cpuid, (void *)arg, sizeof (cpuid)) != 0) return (EFAULT); return (0); } case DTRACEIOC_STOP: { processorid_t cpuid; mutex_enter(&dtrace_lock); rval = dtrace_state_stop(state, &cpuid); mutex_exit(&dtrace_lock); if (rval != 0) return (rval); if (copyout(&cpuid, (void *)arg, sizeof (cpuid)) != 0) return (EFAULT); return (0); } case DTRACEIOC_DOFGET: { dof_hdr_t hdr, *dof; uint64_t len; if (copyin((void *)arg, &hdr, sizeof (hdr)) != 0) return (EFAULT); mutex_enter(&dtrace_lock); dof = dtrace_dof_create(state); mutex_exit(&dtrace_lock); len = MIN(hdr.dofh_loadsz, dof->dofh_loadsz); rval = copyout(dof, (void *)arg, len); dtrace_dof_destroy(dof); return (rval == 0 ? 0 : EFAULT); } case DTRACEIOC_AGGSNAP: case DTRACEIOC_BUFSNAP: { dtrace_bufdesc_t desc; caddr_t cached; dtrace_buffer_t *buf; if (copyin((void *)arg, &desc, sizeof (desc)) != 0) return (EFAULT); if (desc.dtbd_cpu < 0 || desc.dtbd_cpu >= NCPU) return (EINVAL); mutex_enter(&dtrace_lock); if (cmd == DTRACEIOC_BUFSNAP) { buf = &state->dts_buffer[desc.dtbd_cpu]; } else { buf = &state->dts_aggbuffer[desc.dtbd_cpu]; } if (buf->dtb_flags & (DTRACEBUF_RING | DTRACEBUF_FILL)) { size_t sz = buf->dtb_offset; if (state->dts_activity != DTRACE_ACTIVITY_STOPPED) { mutex_exit(&dtrace_lock); return (EBUSY); } /* * If this buffer has already been consumed, we're * going to indicate that there's nothing left here * to consume. */ if (buf->dtb_flags & DTRACEBUF_CONSUMED) { mutex_exit(&dtrace_lock); desc.dtbd_size = 0; desc.dtbd_drops = 0; desc.dtbd_errors = 0; desc.dtbd_oldest = 0; sz = sizeof (desc); if (copyout(&desc, (void *)arg, sz) != 0) return (EFAULT); return (0); } /* * If this is a ring buffer that has wrapped, we want * to copy the whole thing out. */ if (buf->dtb_flags & DTRACEBUF_WRAPPED) { dtrace_buffer_polish(buf); sz = buf->dtb_size; } if (copyout(buf->dtb_tomax, desc.dtbd_data, sz) != 0) { mutex_exit(&dtrace_lock); return (EFAULT); } desc.dtbd_size = sz; desc.dtbd_drops = buf->dtb_drops; desc.dtbd_errors = buf->dtb_errors; desc.dtbd_oldest = buf->dtb_xamot_offset; mutex_exit(&dtrace_lock); if (copyout(&desc, (void *)arg, sizeof (desc)) != 0) return (EFAULT); buf->dtb_flags |= DTRACEBUF_CONSUMED; return (0); } if (buf->dtb_tomax == NULL) { ASSERT(buf->dtb_xamot == NULL); mutex_exit(&dtrace_lock); return (ENOENT); } cached = buf->dtb_tomax; ASSERT(!(buf->dtb_flags & DTRACEBUF_NOSWITCH)); dtrace_xcall(desc.dtbd_cpu, (dtrace_xcall_t)dtrace_buffer_switch, buf); state->dts_errors += buf->dtb_xamot_errors; /* * If the buffers did not actually switch, then the cross call * did not take place -- presumably because the given CPU is * not in the ready set. If this is the case, we'll return * ENOENT. */ if (buf->dtb_tomax == cached) { ASSERT(buf->dtb_xamot != cached); mutex_exit(&dtrace_lock); return (ENOENT); } ASSERT(cached == buf->dtb_xamot); /* * We have our snapshot; now copy it out. */ if (copyout(buf->dtb_xamot, desc.dtbd_data, buf->dtb_xamot_offset) != 0) { mutex_exit(&dtrace_lock); return (EFAULT); } desc.dtbd_size = buf->dtb_xamot_offset; desc.dtbd_drops = buf->dtb_xamot_drops; desc.dtbd_errors = buf->dtb_xamot_errors; desc.dtbd_oldest = 0; mutex_exit(&dtrace_lock); /* * Finally, copy out the buffer description. */ if (copyout(&desc, (void *)arg, sizeof (desc)) != 0) return (EFAULT); return (0); } case DTRACEIOC_CONF: { dtrace_conf_t conf; bzero(&conf, sizeof (conf)); conf.dtc_difversion = DIF_VERSION; conf.dtc_difintregs = DIF_DIR_NREGS; conf.dtc_diftupregs = DIF_DTR_NREGS; conf.dtc_ctfmodel = CTF_MODEL_NATIVE; if (copyout(&conf, (void *)arg, sizeof (conf)) != 0) return (EFAULT); return (0); } case DTRACEIOC_STATUS: { dtrace_status_t stat; dtrace_dstate_t *dstate; int i, j; uint64_t nerrs; /* * See the comment in dtrace_state_deadman() for the reason * for setting dts_laststatus to INT64_MAX before setting * it to the correct value. */ state->dts_laststatus = INT64_MAX; dtrace_membar_producer(); state->dts_laststatus = dtrace_gethrtime(); bzero(&stat, sizeof (stat)); mutex_enter(&dtrace_lock); if (state->dts_activity == DTRACE_ACTIVITY_INACTIVE) { mutex_exit(&dtrace_lock); return (ENOENT); } if (state->dts_activity == DTRACE_ACTIVITY_DRAINING) stat.dtst_exiting = 1; nerrs = state->dts_errors; dstate = &state->dts_vstate.dtvs_dynvars; for (i = 0; i < NCPU; i++) { dtrace_dstate_percpu_t *dcpu = &dstate->dtds_percpu[i]; stat.dtst_dyndrops += dcpu->dtdsc_drops; stat.dtst_dyndrops_dirty += dcpu->dtdsc_dirty_drops; stat.dtst_dyndrops_rinsing += dcpu->dtdsc_rinsing_drops; if (state->dts_buffer[i].dtb_flags & DTRACEBUF_FULL) stat.dtst_filled++; nerrs += state->dts_buffer[i].dtb_errors; for (j = 0; j < state->dts_nspeculations; j++) { dtrace_speculation_t *spec; dtrace_buffer_t *buf; spec = &state->dts_speculations[j]; buf = &spec->dtsp_buffer[i]; stat.dtst_specdrops += buf->dtb_xamot_drops; } } stat.dtst_specdrops_busy = state->dts_speculations_busy; stat.dtst_specdrops_unavail = state->dts_speculations_unavail; stat.dtst_stkstroverflows = state->dts_stkstroverflows; stat.dtst_dblerrors = state->dts_dblerrors; stat.dtst_killed = (state->dts_activity == DTRACE_ACTIVITY_KILLED); stat.dtst_errors = nerrs; mutex_exit(&dtrace_lock); if (copyout(&stat, (void *)arg, sizeof (stat)) != 0) return (EFAULT); return (0); } case DTRACEIOC_FORMAT: { dtrace_fmtdesc_t fmt; char *str; int len; if (copyin((void *)arg, &fmt, sizeof (fmt)) != 0) return (EFAULT); mutex_enter(&dtrace_lock); if (fmt.dtfd_format == 0 || fmt.dtfd_format > state->dts_nformats) { mutex_exit(&dtrace_lock); return (EINVAL); } /* * Format strings are allocated contiguously and they are * never freed; if a format index is less than the number * of formats, we can assert that the format map is non-NULL * and that the format for the specified index is non-NULL. */ ASSERT(state->dts_formats != NULL); str = state->dts_formats[fmt.dtfd_format - 1]; ASSERT(str != NULL); len = strlen(str) + 1; if (len > fmt.dtfd_length) { fmt.dtfd_length = len; if (copyout(&fmt, (void *)arg, sizeof (fmt)) != 0) { mutex_exit(&dtrace_lock); return (EINVAL); } } else { if (copyout(str, fmt.dtfd_string, len) != 0) { mutex_exit(&dtrace_lock); return (EINVAL); } } mutex_exit(&dtrace_lock); return (0); } default: break; } return (ENOTTY); } /*ARGSUSED*/ static int dtrace_detach(dev_info_t *dip, ddi_detach_cmd_t cmd) { dtrace_state_t *state; switch (cmd) { case DDI_DETACH: break; case DDI_SUSPEND: return (DDI_SUCCESS); default: return (DDI_FAILURE); } mutex_enter(&cpu_lock); mutex_enter(&dtrace_provider_lock); mutex_enter(&dtrace_lock); ASSERT(dtrace_opens == 0); if (dtrace_helpers > 0) { mutex_exit(&dtrace_provider_lock); mutex_exit(&dtrace_lock); mutex_exit(&cpu_lock); return (DDI_FAILURE); } if (dtrace_unregister((dtrace_provider_id_t)dtrace_provider) != 0) { mutex_exit(&dtrace_provider_lock); mutex_exit(&dtrace_lock); mutex_exit(&cpu_lock); return (DDI_FAILURE); } dtrace_provider = NULL; if ((state = dtrace_anon_grab()) != NULL) { /* * If there were ECBs on this state, the provider should * have not been allowed to detach; assert that there is * none. */ ASSERT(state->dts_necbs == 0); dtrace_state_destroy(state); /* * If we're being detached with anonymous state, we need to * indicate to the kernel debugger that DTrace is now inactive. */ (void) kdi_dtrace_set(KDI_DTSET_DTRACE_DEACTIVATE); } bzero(&dtrace_anon, sizeof (dtrace_anon_t)); unregister_cpu_setup_func((cpu_setup_func_t *)dtrace_cpu_setup, NULL); dtrace_cpu_init = NULL; dtrace_helpers_cleanup = NULL; dtrace_helpers_fork = NULL; dtrace_cpustart_init = NULL; dtrace_cpustart_fini = NULL; dtrace_debugger_init = NULL; dtrace_debugger_fini = NULL; dtrace_modload = NULL; dtrace_modunload = NULL; mutex_exit(&cpu_lock); if (dtrace_helptrace_enabled) { kmem_free(dtrace_helptrace_buffer, dtrace_helptrace_bufsize); dtrace_helptrace_buffer = NULL; } kmem_free(dtrace_probes, dtrace_nprobes * sizeof (dtrace_probe_t *)); dtrace_probes = NULL; dtrace_nprobes = 0; dtrace_hash_destroy(dtrace_bymod); dtrace_hash_destroy(dtrace_byfunc); dtrace_hash_destroy(dtrace_byname); dtrace_bymod = NULL; dtrace_byfunc = NULL; dtrace_byname = NULL; kmem_cache_destroy(dtrace_state_cache); vmem_destroy(dtrace_minor); vmem_destroy(dtrace_arena); if (dtrace_toxrange != NULL) { kmem_free(dtrace_toxrange, dtrace_toxranges_max * sizeof (dtrace_toxrange_t)); dtrace_toxrange = NULL; dtrace_toxranges = 0; dtrace_toxranges_max = 0; } ddi_remove_minor_node(dtrace_devi, NULL); dtrace_devi = NULL; ddi_soft_state_fini(&dtrace_softstate); ASSERT(dtrace_vtime_references == 0); ASSERT(dtrace_opens == 0); ASSERT(dtrace_retained == NULL); mutex_exit(&dtrace_lock); mutex_exit(&dtrace_provider_lock); /* * We don't destroy the task queue until after we have dropped our * locks (taskq_destroy() may block on running tasks). To prevent * attempting to do work after we have effectively detached but before * the task queue has been destroyed, all tasks dispatched via the * task queue must check that DTrace is still attached before * performing any operation. */ taskq_destroy(dtrace_taskq); dtrace_taskq = NULL; return (DDI_SUCCESS); } +#endif +#if defined(sun) /*ARGSUSED*/ static int dtrace_info(dev_info_t *dip, ddi_info_cmd_t infocmd, void *arg, void **result) { int error; switch (infocmd) { case DDI_INFO_DEVT2DEVINFO: *result = (void *)dtrace_devi; error = DDI_SUCCESS; break; case DDI_INFO_DEVT2INSTANCE: *result = (void *)0; error = DDI_SUCCESS; break; default: error = DDI_FAILURE; } return (error); } +#endif +#if defined(sun) static struct cb_ops dtrace_cb_ops = { dtrace_open, /* open */ dtrace_close, /* close */ nulldev, /* strategy */ nulldev, /* print */ nodev, /* dump */ nodev, /* read */ nodev, /* write */ dtrace_ioctl, /* ioctl */ nodev, /* devmap */ nodev, /* mmap */ nodev, /* segmap */ nochpoll, /* poll */ ddi_prop_op, /* cb_prop_op */ 0, /* streamtab */ D_NEW | D_MP /* Driver compatibility flag */ }; static struct dev_ops dtrace_ops = { DEVO_REV, /* devo_rev */ 0, /* refcnt */ dtrace_info, /* get_dev_info */ nulldev, /* identify */ nulldev, /* probe */ dtrace_attach, /* attach */ dtrace_detach, /* detach */ nodev, /* reset */ &dtrace_cb_ops, /* driver operations */ NULL, /* bus operations */ nodev /* dev power */ }; static struct modldrv modldrv = { &mod_driverops, /* module type (this is a pseudo driver) */ "Dynamic Tracing", /* name of module */ &dtrace_ops, /* driver ops */ }; static struct modlinkage modlinkage = { MODREV_1, (void *)&modldrv, NULL }; int _init(void) { return (mod_install(&modlinkage)); } int _info(struct modinfo *modinfop) { return (mod_info(&modlinkage, modinfop)); } int _fini(void) { return (mod_remove(&modlinkage)); } +#else + +static d_ioctl_t dtrace_ioctl; +static void dtrace_load(void *); +static int dtrace_unload(void); +static void dtrace_clone(void *, struct ucred *, char *, int , struct cdev **); +static struct clonedevs *dtrace_clones; /* Ptr to the array of cloned devices. */ +static eventhandler_tag eh_tag; /* Event handler tag. */ + +void dtrace_invop_init(void); +void dtrace_invop_uninit(void); + +static struct cdevsw dtrace_cdevsw = { + .d_version = D_VERSION, + .d_close = dtrace_close, + .d_ioctl = dtrace_ioctl, + .d_open = dtrace_open, + .d_name = "dtrace", +}; + +#include +#include +#include +#include +#include +#include +#include +#include +#include +#include + +SYSINIT(dtrace_load, SI_SUB_DTRACE, SI_ORDER_FIRST, dtrace_load, NULL); +SYSUNINIT(dtrace_unload, SI_SUB_DTRACE, SI_ORDER_FIRST, dtrace_unload, NULL); +SYSINIT(dtrace_anon_init, SI_SUB_DTRACE_ANON, SI_ORDER_FIRST, dtrace_anon_init, NULL); + +DEV_MODULE(dtrace, dtrace_modevent, NULL); +MODULE_VERSION(dtrace, 1); +MODULE_DEPEND(dtrace, cyclic, 1, 1, 1); +MODULE_DEPEND(dtrace, opensolaris, 1, 1, 1); +#endif Index: head/sys/cddl/contrib/opensolaris/uts/common/dtrace/fasttrap.c =================================================================== --- head/sys/cddl/contrib/opensolaris/uts/common/dtrace/fasttrap.c (revision 179197) +++ head/sys/cddl/contrib/opensolaris/uts/common/dtrace/fasttrap.c (revision 179198) @@ -1,2346 +1,2383 @@ /* * CDDL HEADER START * * The contents of this file are subject to the terms of the * Common Development and Distribution License (the "License"). * You may not use this file except in compliance with the License. * * You can obtain a copy of the license at usr/src/OPENSOLARIS.LICENSE * or http://www.opensolaris.org/os/licensing. * See the License for the specific language governing permissions * and limitations under the License. * * When distributing Covered Code, include this CDDL HEADER in each * file and include the License file at usr/src/OPENSOLARIS.LICENSE. * If applicable, add the following below this CDDL HEADER, with the * fields enclosed by brackets "[]" replaced with your own identifying * information: Portions Copyright [yyyy] [name of copyright owner] * * CDDL HEADER END */ /* - * Copyright 2007 Sun Microsystems, Inc. All rights reserved. + * Copyright 2008 Sun Microsystems, Inc. All rights reserved. * Use is subject to license terms. */ #pragma ident "%Z%%M% %I% %E% SMI" #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include /* * User-Land Trap-Based Tracing * ---------------------------- * * The fasttrap provider allows DTrace consumers to instrument any user-level * instruction to gather data; this includes probes with semantic * signifigance like entry and return as well as simple offsets into the * function. While the specific techniques used are very ISA specific, the * methodology is generalizable to any architecture. * * * The General Methodology * ----------------------- * * With the primary goal of tracing every user-land instruction and the * limitation that we can't trust user space so don't want to rely on much * information there, we begin by replacing the instructions we want to trace * with trap instructions. Each instruction we overwrite is saved into a hash * table keyed by process ID and pc address. When we enter the kernel due to * this trap instruction, we need the effects of the replaced instruction to * appear to have occurred before we proceed with the user thread's * execution. * * Each user level thread is represented by a ulwp_t structure which is * always easily accessible through a register. The most basic way to produce * the effects of the instruction we replaced is to copy that instruction out * to a bit of scratch space reserved in the user thread's ulwp_t structure * (a sort of kernel-private thread local storage), set the PC to that * scratch space and single step. When we reenter the kernel after single * stepping the instruction we must then adjust the PC to point to what would * normally be the next instruction. Of course, special care must be taken * for branches and jumps, but these represent such a small fraction of any * instruction set that writing the code to emulate these in the kernel is * not too difficult. * * Return probes may require several tracepoints to trace every return site, * and, conversely, each tracepoint may activate several probes (the entry * and offset 0 probes, for example). To solve this muliplexing problem, * tracepoints contain lists of probes to activate and probes contain lists * of tracepoints to enable. If a probe is activated, it adds its ID to * existing tracepoints or creates new ones as necessary. * * Most probes are activated _before_ the instruction is executed, but return * probes are activated _after_ the effects of the last instruction of the * function are visible. Return probes must be fired _after_ we have * single-stepped the instruction whereas all other probes are fired * beforehand. * * * Lock Ordering * ------------- * * The lock ordering below -- both internally and with respect to the DTrace * framework -- is a little tricky and bears some explanation. Each provider * has a lock (ftp_mtx) that protects its members including reference counts * for enabled probes (ftp_rcount), consumers actively creating probes * (ftp_ccount) and USDT consumers (ftp_mcount); all three prevent a provider * from being freed. A provider is looked up by taking the bucket lock for the * provider hash table, and is returned with its lock held. The provider lock * may be taken in functions invoked by the DTrace framework, but may not be * held while calling functions in the DTrace framework. * * To ensure consistency over multiple calls to the DTrace framework, the * creation lock (ftp_cmtx) should be held. Naturally, the creation lock may * not be taken when holding the provider lock as that would create a cyclic * lock ordering. In situations where one would naturally take the provider * lock and then the creation lock, we instead up a reference count to prevent * the provider from disappearing, drop the provider lock, and acquire the * creation lock. * * Briefly: * bucket lock before provider lock * DTrace before provider lock * creation lock before DTrace * never hold the provider lock and creation lock simultaneously */ static dev_info_t *fasttrap_devi; static dtrace_meta_provider_id_t fasttrap_meta_id; static timeout_id_t fasttrap_timeout; static kmutex_t fasttrap_cleanup_mtx; static uint_t fasttrap_cleanup_work; /* * Generation count on modifications to the global tracepoint lookup table. */ static volatile uint64_t fasttrap_mod_gen; /* * When the fasttrap provider is loaded, fasttrap_max is set to either * FASTTRAP_MAX_DEFAULT or the value for fasttrap-max-probes in the * fasttrap.conf file. Each time a probe is created, fasttrap_total is * incremented by the number of tracepoints that may be associated with that * probe; fasttrap_total is capped at fasttrap_max. */ #define FASTTRAP_MAX_DEFAULT 250000 static uint32_t fasttrap_max; static uint32_t fasttrap_total; #define FASTTRAP_TPOINTS_DEFAULT_SIZE 0x4000 #define FASTTRAP_PROVIDERS_DEFAULT_SIZE 0x100 #define FASTTRAP_PROCS_DEFAULT_SIZE 0x100 #define FASTTRAP_PID_NAME "pid" fasttrap_hash_t fasttrap_tpoints; static fasttrap_hash_t fasttrap_provs; static fasttrap_hash_t fasttrap_procs; static uint64_t fasttrap_pid_count; /* pid ref count */ static kmutex_t fasttrap_count_mtx; /* lock on ref count */ #define FASTTRAP_ENABLE_FAIL 1 #define FASTTRAP_ENABLE_PARTIAL 2 static int fasttrap_tracepoint_enable(proc_t *, fasttrap_probe_t *, uint_t); static void fasttrap_tracepoint_disable(proc_t *, fasttrap_probe_t *, uint_t); static fasttrap_provider_t *fasttrap_provider_lookup(pid_t, const char *, const dtrace_pattr_t *); static void fasttrap_provider_retire(pid_t, const char *, int); static void fasttrap_provider_free(fasttrap_provider_t *); static fasttrap_proc_t *fasttrap_proc_lookup(pid_t); static void fasttrap_proc_release(fasttrap_proc_t *); #define FASTTRAP_PROVS_INDEX(pid, name) \ ((fasttrap_hash_str(name) + (pid)) & fasttrap_provs.fth_mask) #define FASTTRAP_PROCS_INDEX(pid) ((pid) & fasttrap_procs.fth_mask) static int fasttrap_highbit(ulong_t i) { int h = 1; if (i == 0) return (0); #ifdef _LP64 if (i & 0xffffffff00000000ul) { h += 32; i >>= 32; } #endif if (i & 0xffff0000) { h += 16; i >>= 16; } if (i & 0xff00) { h += 8; i >>= 8; } if (i & 0xf0) { h += 4; i >>= 4; } if (i & 0xc) { h += 2; i >>= 2; } if (i & 0x2) { h += 1; } return (h); } static uint_t fasttrap_hash_str(const char *p) { unsigned int g; uint_t hval = 0; while (*p) { hval = (hval << 4) + *p++; if ((g = (hval & 0xf0000000)) != 0) hval ^= g >> 24; hval &= ~g; } return (hval); } void fasttrap_sigtrap(proc_t *p, kthread_t *t, uintptr_t pc) { sigqueue_t *sqp = kmem_zalloc(sizeof (sigqueue_t), KM_SLEEP); sqp->sq_info.si_signo = SIGTRAP; sqp->sq_info.si_code = TRAP_DTRACE; sqp->sq_info.si_addr = (caddr_t)pc; mutex_enter(&p->p_lock); sigaddqa(p, t, sqp); mutex_exit(&p->p_lock); if (t != NULL) aston(t); } /* * This function ensures that no threads are actively using the memory * associated with probes that were formerly live. */ static void fasttrap_mod_barrier(uint64_t gen) { int i; if (gen < fasttrap_mod_gen) return; fasttrap_mod_gen++; for (i = 0; i < NCPU; i++) { mutex_enter(&cpu_core[i].cpuc_pid_lock); mutex_exit(&cpu_core[i].cpuc_pid_lock); } } /* * This is the timeout's callback for cleaning up the providers and their * probes. */ /*ARGSUSED*/ static void fasttrap_pid_cleanup_cb(void *data) { fasttrap_provider_t **fpp, *fp; fasttrap_bucket_t *bucket; dtrace_provider_id_t provid; int i, later; static volatile int in = 0; ASSERT(in == 0); in = 1; mutex_enter(&fasttrap_cleanup_mtx); while (fasttrap_cleanup_work) { fasttrap_cleanup_work = 0; mutex_exit(&fasttrap_cleanup_mtx); later = 0; /* * Iterate over all the providers trying to remove the marked * ones. If a provider is marked but not retired, we just * have to take a crack at removing it -- it's no big deal if * we can't. */ for (i = 0; i < fasttrap_provs.fth_nent; i++) { bucket = &fasttrap_provs.fth_table[i]; mutex_enter(&bucket->ftb_mtx); fpp = (fasttrap_provider_t **)&bucket->ftb_data; while ((fp = *fpp) != NULL) { if (!fp->ftp_marked) { fpp = &fp->ftp_next; continue; } mutex_enter(&fp->ftp_mtx); /* * If this provider has consumers actively * creating probes (ftp_ccount) or is a USDT * provider (ftp_mcount), we can't unregister * or even condense. */ if (fp->ftp_ccount != 0 || fp->ftp_mcount != 0) { mutex_exit(&fp->ftp_mtx); fp->ftp_marked = 0; continue; } if (!fp->ftp_retired || fp->ftp_rcount != 0) fp->ftp_marked = 0; mutex_exit(&fp->ftp_mtx); /* * If we successfully unregister this * provider we can remove it from the hash * chain and free the memory. If our attempt * to unregister fails and this is a retired * provider, increment our flag to try again * pretty soon. If we've consumed more than * half of our total permitted number of * probes call dtrace_condense() to try to * clean out the unenabled probes. */ provid = fp->ftp_provid; if (dtrace_unregister(provid) != 0) { if (fasttrap_total > fasttrap_max / 2) (void) dtrace_condense(provid); later += fp->ftp_marked; fpp = &fp->ftp_next; } else { *fpp = fp->ftp_next; fasttrap_provider_free(fp); } } mutex_exit(&bucket->ftb_mtx); } mutex_enter(&fasttrap_cleanup_mtx); } ASSERT(fasttrap_timeout != 0); /* * If we were unable to remove a retired provider, try again after * a second. This situation can occur in certain circumstances where * providers cannot be unregistered even though they have no probes * enabled because of an execution of dtrace -l or something similar. * If the timeout has been disabled (set to 1 because we're trying * to detach), we set fasttrap_cleanup_work to ensure that we'll * get a chance to do that work if and when the timeout is reenabled * (if detach fails). */ if (later > 0 && fasttrap_timeout != (timeout_id_t)1) fasttrap_timeout = timeout(&fasttrap_pid_cleanup_cb, NULL, hz); else if (later > 0) fasttrap_cleanup_work = 1; else fasttrap_timeout = 0; mutex_exit(&fasttrap_cleanup_mtx); in = 0; } /* * Activates the asynchronous cleanup mechanism. */ static void fasttrap_pid_cleanup(void) { mutex_enter(&fasttrap_cleanup_mtx); fasttrap_cleanup_work = 1; if (fasttrap_timeout == 0) fasttrap_timeout = timeout(&fasttrap_pid_cleanup_cb, NULL, 1); mutex_exit(&fasttrap_cleanup_mtx); } /* * This is called from cfork() via dtrace_fasttrap_fork(). The child - * process's address space is a (roughly) a copy of the parent process's so + * process's address space is (roughly) a copy of the parent process's so * we have to remove all the instrumentation we had previously enabled in the * parent. */ static void fasttrap_fork(proc_t *p, proc_t *cp) { pid_t ppid = p->p_pid; int i; ASSERT(curproc == p); ASSERT(p->p_proc_flag & P_PR_LOCK); ASSERT(p->p_dtrace_count > 0); ASSERT(cp->p_dtrace_count == 0); /* * This would be simpler and faster if we maintained per-process * hash tables of enabled tracepoints. It could, however, potentially * slow down execution of a tracepoint since we'd need to go * through two levels of indirection. In the future, we should * consider either maintaining per-process ancillary lists of * enabled tracepoints or hanging a pointer to a per-process hash * table of enabled tracepoints off the proc structure. */ /* * We don't have to worry about the child process disappearing * because we're in fork(). */ mutex_enter(&cp->p_lock); sprlock_proc(cp); mutex_exit(&cp->p_lock); /* * Iterate over every tracepoint looking for ones that belong to the * parent process, and remove each from the child process. */ for (i = 0; i < fasttrap_tpoints.fth_nent; i++) { fasttrap_tracepoint_t *tp; fasttrap_bucket_t *bucket = &fasttrap_tpoints.fth_table[i]; mutex_enter(&bucket->ftb_mtx); for (tp = bucket->ftb_data; tp != NULL; tp = tp->ftt_next) { if (tp->ftt_pid == ppid && tp->ftt_proc->ftpc_acount != 0) { int ret = fasttrap_tracepoint_remove(cp, tp); ASSERT(ret == 0); + + /* + * The count of active providers can only be + * decremented (i.e. to zero) during exec, + * exit, and removal of a meta provider so it + * should be impossible to drop the count + * mid-fork. + */ + ASSERT(tp->ftt_proc->ftpc_acount != 0); } } mutex_exit(&bucket->ftb_mtx); } mutex_enter(&cp->p_lock); sprunlock(cp); } /* * This is called from proc_exit() or from exec_common() if p_dtrace_probes * is set on the proc structure to indicate that there is a pid provider * associated with this process. */ static void fasttrap_exec_exit(proc_t *p) { ASSERT(p == curproc); ASSERT(MUTEX_HELD(&p->p_lock)); mutex_exit(&p->p_lock); /* * We clean up the pid provider for this process here; user-land * static probes are handled by the meta-provider remove entry point. */ fasttrap_provider_retire(p->p_pid, FASTTRAP_PID_NAME, 0); mutex_enter(&p->p_lock); } /*ARGSUSED*/ static void fasttrap_pid_provide(void *arg, const dtrace_probedesc_t *desc) { /* * There are no "default" pid probes. */ } static int fasttrap_tracepoint_enable(proc_t *p, fasttrap_probe_t *probe, uint_t index) { fasttrap_tracepoint_t *tp, *new_tp = NULL; fasttrap_bucket_t *bucket; fasttrap_id_t *id; pid_t pid; uintptr_t pc; ASSERT(index < probe->ftp_ntps); pid = probe->ftp_pid; pc = probe->ftp_tps[index].fit_tp->ftt_pc; id = &probe->ftp_tps[index].fit_id; ASSERT(probe->ftp_tps[index].fit_tp->ftt_pid == pid); ASSERT(!(p->p_flag & SVFORK)); /* * Before we make any modifications, make sure we've imposed a barrier * on the generation in which this probe was last modified. */ fasttrap_mod_barrier(probe->ftp_gen); bucket = &fasttrap_tpoints.fth_table[FASTTRAP_TPOINTS_INDEX(pid, pc)]; /* * If the tracepoint has already been enabled, just add our id to the * list of interested probes. This may be our second time through * this path in which case we'll have constructed the tracepoint we'd * like to install. If we can't find a match, and have an allocated * tracepoint ready to go, enable that one now. * * A tracepoint whose process is defunct is also considered defunct. */ again: mutex_enter(&bucket->ftb_mtx); for (tp = bucket->ftb_data; tp != NULL; tp = tp->ftt_next) { + /* + * Note that it's safe to access the active count on the + * associated proc structure because we know that at least one + * provider (this one) will still be around throughout this + * operation. + */ if (tp->ftt_pid != pid || tp->ftt_pc != pc || tp->ftt_proc->ftpc_acount == 0) continue; /* * Now that we've found a matching tracepoint, it would be * a decent idea to confirm that the tracepoint is still * enabled and the trap instruction hasn't been overwritten. * Since this is a little hairy, we'll punt for now. */ /* * This can't be the first interested probe. We don't have * to worry about another thread being in the midst of * deleting this tracepoint (which would be the only valid * reason for a tracepoint to have no interested probes) * since we're holding P_PR_LOCK for this process. */ ASSERT(tp->ftt_ids != NULL || tp->ftt_retids != NULL); switch (id->fti_ptype) { case DTFTP_ENTRY: case DTFTP_OFFSETS: case DTFTP_IS_ENABLED: id->fti_next = tp->ftt_ids; membar_producer(); tp->ftt_ids = id; membar_producer(); break; case DTFTP_RETURN: case DTFTP_POST_OFFSETS: id->fti_next = tp->ftt_retids; membar_producer(); tp->ftt_retids = id; membar_producer(); break; default: ASSERT(0); } mutex_exit(&bucket->ftb_mtx); if (new_tp != NULL) { new_tp->ftt_ids = NULL; new_tp->ftt_retids = NULL; } return (0); } /* * If we have a good tracepoint ready to go, install it now while * we have the lock held and no one can screw with us. */ if (new_tp != NULL) { int rc = 0; new_tp->ftt_next = bucket->ftb_data; membar_producer(); bucket->ftb_data = new_tp; membar_producer(); mutex_exit(&bucket->ftb_mtx); /* * Activate the tracepoint in the ISA-specific manner. * If this fails, we need to report the failure, but * indicate that this tracepoint must still be disabled * by calling fasttrap_tracepoint_disable(). */ if (fasttrap_tracepoint_install(p, new_tp) != 0) rc = FASTTRAP_ENABLE_PARTIAL; /* * Increment the count of the number of tracepoints active in * the victim process. */ ASSERT(p->p_proc_flag & P_PR_LOCK); p->p_dtrace_count++; return (rc); } mutex_exit(&bucket->ftb_mtx); /* * Initialize the tracepoint that's been preallocated with the probe. */ new_tp = probe->ftp_tps[index].fit_tp; ASSERT(new_tp->ftt_pid == pid); ASSERT(new_tp->ftt_pc == pc); ASSERT(new_tp->ftt_proc == probe->ftp_prov->ftp_proc); ASSERT(new_tp->ftt_ids == NULL); ASSERT(new_tp->ftt_retids == NULL); switch (id->fti_ptype) { case DTFTP_ENTRY: case DTFTP_OFFSETS: case DTFTP_IS_ENABLED: id->fti_next = NULL; new_tp->ftt_ids = id; break; case DTFTP_RETURN: case DTFTP_POST_OFFSETS: id->fti_next = NULL; new_tp->ftt_retids = id; break; default: ASSERT(0); } /* * If the ISA-dependent initialization goes to plan, go back to the * beginning and try to install this freshly made tracepoint. */ if (fasttrap_tracepoint_init(p, new_tp, pc, id->fti_ptype) == 0) goto again; new_tp->ftt_ids = NULL; new_tp->ftt_retids = NULL; return (FASTTRAP_ENABLE_FAIL); } static void fasttrap_tracepoint_disable(proc_t *p, fasttrap_probe_t *probe, uint_t index) { fasttrap_bucket_t *bucket; fasttrap_provider_t *provider = probe->ftp_prov; fasttrap_tracepoint_t **pp, *tp; fasttrap_id_t *id, **idp; pid_t pid; uintptr_t pc; ASSERT(index < probe->ftp_ntps); pid = probe->ftp_pid; pc = probe->ftp_tps[index].fit_tp->ftt_pc; id = &probe->ftp_tps[index].fit_id; ASSERT(probe->ftp_tps[index].fit_tp->ftt_pid == pid); /* * Find the tracepoint and make sure that our id is one of the * ones registered with it. */ bucket = &fasttrap_tpoints.fth_table[FASTTRAP_TPOINTS_INDEX(pid, pc)]; mutex_enter(&bucket->ftb_mtx); for (tp = bucket->ftb_data; tp != NULL; tp = tp->ftt_next) { if (tp->ftt_pid == pid && tp->ftt_pc == pc && tp->ftt_proc == provider->ftp_proc) break; } /* * If we somehow lost this tracepoint, we're in a world of hurt. */ ASSERT(tp != NULL); switch (id->fti_ptype) { case DTFTP_ENTRY: case DTFTP_OFFSETS: case DTFTP_IS_ENABLED: ASSERT(tp->ftt_ids != NULL); idp = &tp->ftt_ids; break; case DTFTP_RETURN: case DTFTP_POST_OFFSETS: ASSERT(tp->ftt_retids != NULL); idp = &tp->ftt_retids; break; default: ASSERT(0); } while ((*idp)->fti_probe != probe) { idp = &(*idp)->fti_next; ASSERT(*idp != NULL); } id = *idp; *idp = id->fti_next; membar_producer(); ASSERT(id->fti_probe == probe); /* * If there are other registered enablings of this tracepoint, we're * all done, but if this was the last probe assocated with this * this tracepoint, we need to remove and free it. */ if (tp->ftt_ids != NULL || tp->ftt_retids != NULL) { /* * If the current probe's tracepoint is in use, swap it * for an unused tracepoint. */ if (tp == probe->ftp_tps[index].fit_tp) { fasttrap_probe_t *tmp_probe; fasttrap_tracepoint_t **tmp_tp; uint_t tmp_index; if (tp->ftt_ids != NULL) { tmp_probe = tp->ftt_ids->fti_probe; /* LINTED - alignment */ tmp_index = FASTTRAP_ID_INDEX(tp->ftt_ids); tmp_tp = &tmp_probe->ftp_tps[tmp_index].fit_tp; } else { tmp_probe = tp->ftt_retids->fti_probe; /* LINTED - alignment */ tmp_index = FASTTRAP_ID_INDEX(tp->ftt_retids); tmp_tp = &tmp_probe->ftp_tps[tmp_index].fit_tp; } ASSERT(*tmp_tp != NULL); ASSERT(*tmp_tp != probe->ftp_tps[index].fit_tp); ASSERT((*tmp_tp)->ftt_ids == NULL); ASSERT((*tmp_tp)->ftt_retids == NULL); probe->ftp_tps[index].fit_tp = *tmp_tp; *tmp_tp = tp; } mutex_exit(&bucket->ftb_mtx); /* * Tag the modified probe with the generation in which it was * changed. */ probe->ftp_gen = fasttrap_mod_gen; return; } mutex_exit(&bucket->ftb_mtx); /* * We can't safely remove the tracepoint from the set of active * tracepoints until we've actually removed the fasttrap instruction * from the process's text. We can, however, operate on this * tracepoint secure in the knowledge that no other thread is going to * be looking at it since we hold P_PR_LOCK on the process if it's * live or we hold the provider lock on the process if it's dead and * gone. */ /* * We only need to remove the actual instruction if we're looking * at an existing process */ if (p != NULL) { /* * If we fail to restore the instruction we need to kill * this process since it's in a completely unrecoverable * state. */ if (fasttrap_tracepoint_remove(p, tp) != 0) fasttrap_sigtrap(p, NULL, pc); /* * Decrement the count of the number of tracepoints active * in the victim process. */ ASSERT(p->p_proc_flag & P_PR_LOCK); p->p_dtrace_count--; } /* * Remove the probe from the hash table of active tracepoints. */ mutex_enter(&bucket->ftb_mtx); pp = (fasttrap_tracepoint_t **)&bucket->ftb_data; ASSERT(*pp != NULL); while (*pp != tp) { pp = &(*pp)->ftt_next; ASSERT(*pp != NULL); } *pp = tp->ftt_next; membar_producer(); mutex_exit(&bucket->ftb_mtx); /* * Tag the modified probe with the generation in which it was changed. */ probe->ftp_gen = fasttrap_mod_gen; } static void fasttrap_enable_callbacks(void) { /* * We don't have to play the rw lock game here because we're * providing something rather than taking something away -- * we can be sure that no threads have tried to follow this * function pointer yet. */ mutex_enter(&fasttrap_count_mtx); if (fasttrap_pid_count == 0) { ASSERT(dtrace_pid_probe_ptr == NULL); ASSERT(dtrace_return_probe_ptr == NULL); dtrace_pid_probe_ptr = &fasttrap_pid_probe; dtrace_return_probe_ptr = &fasttrap_return_probe; } ASSERT(dtrace_pid_probe_ptr == &fasttrap_pid_probe); ASSERT(dtrace_return_probe_ptr == &fasttrap_return_probe); fasttrap_pid_count++; mutex_exit(&fasttrap_count_mtx); } static void fasttrap_disable_callbacks(void) { ASSERT(MUTEX_HELD(&cpu_lock)); mutex_enter(&fasttrap_count_mtx); ASSERT(fasttrap_pid_count > 0); fasttrap_pid_count--; if (fasttrap_pid_count == 0) { cpu_t *cur, *cpu = CPU; for (cur = cpu->cpu_next_onln; cur != cpu; cur = cur->cpu_next_onln) { rw_enter(&cur->cpu_ft_lock, RW_WRITER); } dtrace_pid_probe_ptr = NULL; dtrace_return_probe_ptr = NULL; for (cur = cpu->cpu_next_onln; cur != cpu; cur = cur->cpu_next_onln) { rw_exit(&cur->cpu_ft_lock); } } mutex_exit(&fasttrap_count_mtx); } /*ARGSUSED*/ static void fasttrap_pid_enable(void *arg, dtrace_id_t id, void *parg) { fasttrap_probe_t *probe = parg; proc_t *p; int i, rc; ASSERT(probe != NULL); ASSERT(!probe->ftp_enabled); ASSERT(id == probe->ftp_id); ASSERT(MUTEX_HELD(&cpu_lock)); /* * Increment the count of enabled probes on this probe's provider; * the provider can't go away while the probe still exists. We * must increment this even if we aren't able to properly enable * this probe. */ mutex_enter(&probe->ftp_prov->ftp_mtx); probe->ftp_prov->ftp_rcount++; mutex_exit(&probe->ftp_prov->ftp_mtx); /* * If this probe's provider is retired (meaning it was valid in a * previously exec'ed incarnation of this address space), bail out. The * provider can't go away while we're in this code path. */ if (probe->ftp_prov->ftp_retired) return; /* * If we can't find the process, it may be that we're in the context of * a fork in which the traced process is being born and we're copying * USDT probes. Otherwise, the process is gone so bail. */ if ((p = sprlock(probe->ftp_pid)) == NULL) { if ((curproc->p_flag & SFORKING) == 0) return; mutex_enter(&pidlock); p = prfind(probe->ftp_pid); /* * Confirm that curproc is indeed forking the process in which * we're trying to enable probes. */ ASSERT(p != NULL); ASSERT(p->p_parent == curproc); ASSERT(p->p_stat == SIDL); mutex_enter(&p->p_lock); mutex_exit(&pidlock); sprlock_proc(p); } ASSERT(!(p->p_flag & SVFORK)); mutex_exit(&p->p_lock); /* * We have to enable the trap entry point before any user threads have * the chance to execute the trap instruction we're about to place * in their process's text. */ fasttrap_enable_callbacks(); /* * Enable all the tracepoints and add this probe's id to each * tracepoint's list of active probes. */ for (i = 0; i < probe->ftp_ntps; i++) { if ((rc = fasttrap_tracepoint_enable(p, probe, i)) != 0) { /* * If enabling the tracepoint failed completely, * we don't have to disable it; if the failure * was only partial we must disable it. */ if (rc == FASTTRAP_ENABLE_FAIL) i--; else ASSERT(rc == FASTTRAP_ENABLE_PARTIAL); /* * Back up and pull out all the tracepoints we've * created so far for this probe. */ while (i >= 0) { fasttrap_tracepoint_disable(p, probe, i); i--; } mutex_enter(&p->p_lock); sprunlock(p); /* * Since we're not actually enabling this probe, * drop our reference on the trap table entry. */ fasttrap_disable_callbacks(); return; } } mutex_enter(&p->p_lock); sprunlock(p); probe->ftp_enabled = 1; } /*ARGSUSED*/ static void fasttrap_pid_disable(void *arg, dtrace_id_t id, void *parg) { fasttrap_probe_t *probe = parg; fasttrap_provider_t *provider = probe->ftp_prov; proc_t *p; int i, whack = 0; ASSERT(id == probe->ftp_id); /* * We won't be able to acquire a /proc-esque lock on the process * iff the process is dead and gone. In this case, we rely on the * provider lock as a point of mutual exclusion to prevent other * DTrace consumers from disabling this probe. */ if ((p = sprlock(probe->ftp_pid)) != NULL) { ASSERT(!(p->p_flag & SVFORK)); mutex_exit(&p->p_lock); } mutex_enter(&provider->ftp_mtx); /* * Disable all the associated tracepoints (for fully enabled probes). */ if (probe->ftp_enabled) { for (i = 0; i < probe->ftp_ntps; i++) { fasttrap_tracepoint_disable(p, probe, i); } } ASSERT(provider->ftp_rcount > 0); provider->ftp_rcount--; if (p != NULL) { /* * Even though we may not be able to remove it entirely, we * mark this retired provider to get a chance to remove some * of the associated probes. */ if (provider->ftp_retired && !provider->ftp_marked) whack = provider->ftp_marked = 1; mutex_exit(&provider->ftp_mtx); mutex_enter(&p->p_lock); sprunlock(p); } else { /* * If the process is dead, we're just waiting for the * last probe to be disabled to be able to free it. */ if (provider->ftp_rcount == 0 && !provider->ftp_marked) whack = provider->ftp_marked = 1; mutex_exit(&provider->ftp_mtx); } if (whack) fasttrap_pid_cleanup(); if (!probe->ftp_enabled) return; probe->ftp_enabled = 0; ASSERT(MUTEX_HELD(&cpu_lock)); fasttrap_disable_callbacks(); } /*ARGSUSED*/ static void fasttrap_pid_getargdesc(void *arg, dtrace_id_t id, void *parg, dtrace_argdesc_t *desc) { fasttrap_probe_t *probe = parg; char *str; int i, ndx; desc->dtargd_native[0] = '\0'; desc->dtargd_xlate[0] = '\0'; if (probe->ftp_prov->ftp_retired != 0 || desc->dtargd_ndx >= probe->ftp_nargs) { desc->dtargd_ndx = DTRACE_ARGNONE; return; } ndx = (probe->ftp_argmap != NULL) ? probe->ftp_argmap[desc->dtargd_ndx] : desc->dtargd_ndx; str = probe->ftp_ntypes; for (i = 0; i < ndx; i++) { str += strlen(str) + 1; } ASSERT(strlen(str + 1) < sizeof (desc->dtargd_native)); (void) strcpy(desc->dtargd_native, str); if (probe->ftp_xtypes == NULL) return; str = probe->ftp_xtypes; for (i = 0; i < desc->dtargd_ndx; i++) { str += strlen(str) + 1; } ASSERT(strlen(str + 1) < sizeof (desc->dtargd_xlate)); (void) strcpy(desc->dtargd_xlate, str); } /*ARGSUSED*/ static void fasttrap_pid_destroy(void *arg, dtrace_id_t id, void *parg) { fasttrap_probe_t *probe = parg; int i; size_t size; ASSERT(probe != NULL); ASSERT(!probe->ftp_enabled); ASSERT(fasttrap_total >= probe->ftp_ntps); atomic_add_32(&fasttrap_total, -probe->ftp_ntps); size = offsetof(fasttrap_probe_t, ftp_tps[probe->ftp_ntps]); if (probe->ftp_gen + 1 >= fasttrap_mod_gen) fasttrap_mod_barrier(probe->ftp_gen); for (i = 0; i < probe->ftp_ntps; i++) { kmem_free(probe->ftp_tps[i].fit_tp, sizeof (fasttrap_tracepoint_t)); } kmem_free(probe, size); } static const dtrace_pattr_t pid_attr = { { DTRACE_STABILITY_EVOLVING, DTRACE_STABILITY_EVOLVING, DTRACE_CLASS_ISA }, { DTRACE_STABILITY_PRIVATE, DTRACE_STABILITY_PRIVATE, DTRACE_CLASS_UNKNOWN }, { DTRACE_STABILITY_PRIVATE, DTRACE_STABILITY_PRIVATE, DTRACE_CLASS_UNKNOWN }, { DTRACE_STABILITY_EVOLVING, DTRACE_STABILITY_EVOLVING, DTRACE_CLASS_ISA }, { DTRACE_STABILITY_PRIVATE, DTRACE_STABILITY_PRIVATE, DTRACE_CLASS_UNKNOWN }, }; static dtrace_pops_t pid_pops = { fasttrap_pid_provide, NULL, fasttrap_pid_enable, fasttrap_pid_disable, NULL, NULL, fasttrap_pid_getargdesc, fasttrap_pid_getarg, NULL, fasttrap_pid_destroy }; static dtrace_pops_t usdt_pops = { fasttrap_pid_provide, NULL, fasttrap_pid_enable, fasttrap_pid_disable, NULL, NULL, fasttrap_pid_getargdesc, fasttrap_usdt_getarg, NULL, fasttrap_pid_destroy }; static fasttrap_proc_t * fasttrap_proc_lookup(pid_t pid) { fasttrap_bucket_t *bucket; fasttrap_proc_t *fprc, *new_fprc; bucket = &fasttrap_procs.fth_table[FASTTRAP_PROCS_INDEX(pid)]; mutex_enter(&bucket->ftb_mtx); for (fprc = bucket->ftb_data; fprc != NULL; fprc = fprc->ftpc_next) { if (fprc->ftpc_pid == pid && fprc->ftpc_acount != 0) { mutex_enter(&fprc->ftpc_mtx); mutex_exit(&bucket->ftb_mtx); fprc->ftpc_rcount++; atomic_add_64(&fprc->ftpc_acount, 1); + ASSERT(fprc->ftpc_acount <= fprc->ftpc_rcount); mutex_exit(&fprc->ftpc_mtx); return (fprc); } } /* * Drop the bucket lock so we don't try to perform a sleeping * allocation under it. */ mutex_exit(&bucket->ftb_mtx); new_fprc = kmem_zalloc(sizeof (fasttrap_proc_t), KM_SLEEP); new_fprc->ftpc_pid = pid; new_fprc->ftpc_rcount = 1; new_fprc->ftpc_acount = 1; mutex_enter(&bucket->ftb_mtx); /* * Take another lap through the list to make sure a proc hasn't * been created for this pid while we weren't under the bucket lock. */ for (fprc = bucket->ftb_data; fprc != NULL; fprc = fprc->ftpc_next) { if (fprc->ftpc_pid == pid && fprc->ftpc_acount != 0) { mutex_enter(&fprc->ftpc_mtx); mutex_exit(&bucket->ftb_mtx); fprc->ftpc_rcount++; atomic_add_64(&fprc->ftpc_acount, 1); + ASSERT(fprc->ftpc_acount <= fprc->ftpc_rcount); mutex_exit(&fprc->ftpc_mtx); kmem_free(new_fprc, sizeof (fasttrap_proc_t)); return (fprc); } } new_fprc->ftpc_next = bucket->ftb_data; bucket->ftb_data = new_fprc; mutex_exit(&bucket->ftb_mtx); return (new_fprc); } static void fasttrap_proc_release(fasttrap_proc_t *proc) { fasttrap_bucket_t *bucket; fasttrap_proc_t *fprc, **fprcp; pid_t pid = proc->ftpc_pid; mutex_enter(&proc->ftpc_mtx); ASSERT(proc->ftpc_rcount != 0); + ASSERT(proc->ftpc_acount <= proc->ftpc_rcount); if (--proc->ftpc_rcount != 0) { mutex_exit(&proc->ftpc_mtx); return; } mutex_exit(&proc->ftpc_mtx); /* * There should definitely be no live providers associated with this * process at this point. */ ASSERT(proc->ftpc_acount == 0); bucket = &fasttrap_procs.fth_table[FASTTRAP_PROCS_INDEX(pid)]; mutex_enter(&bucket->ftb_mtx); fprcp = (fasttrap_proc_t **)&bucket->ftb_data; while ((fprc = *fprcp) != NULL) { if (fprc == proc) break; fprcp = &fprc->ftpc_next; } /* * Something strange has happened if we can't find the proc. */ ASSERT(fprc != NULL); *fprcp = fprc->ftpc_next; mutex_exit(&bucket->ftb_mtx); kmem_free(fprc, sizeof (fasttrap_proc_t)); } /* * Lookup a fasttrap-managed provider based on its name and associated pid. * If the pattr argument is non-NULL, this function instantiates the provider * if it doesn't exist otherwise it returns NULL. The provider is returned * with its lock held. */ static fasttrap_provider_t * fasttrap_provider_lookup(pid_t pid, const char *name, const dtrace_pattr_t *pattr) { fasttrap_provider_t *fp, *new_fp = NULL; fasttrap_bucket_t *bucket; char provname[DTRACE_PROVNAMELEN]; proc_t *p; cred_t *cred; ASSERT(strlen(name) < sizeof (fp->ftp_name)); ASSERT(pattr != NULL); bucket = &fasttrap_provs.fth_table[FASTTRAP_PROVS_INDEX(pid, name)]; mutex_enter(&bucket->ftb_mtx); /* * Take a lap through the list and return the match if we find it. */ for (fp = bucket->ftb_data; fp != NULL; fp = fp->ftp_next) { if (fp->ftp_pid == pid && strcmp(fp->ftp_name, name) == 0 && !fp->ftp_retired) { mutex_enter(&fp->ftp_mtx); mutex_exit(&bucket->ftb_mtx); return (fp); } } /* * Drop the bucket lock so we don't try to perform a sleeping * allocation under it. */ mutex_exit(&bucket->ftb_mtx); /* * Make sure the process exists, isn't a child created as the result * of a vfork(2), and isn't a zombie (but may be in fork). */ mutex_enter(&pidlock); if ((p = prfind(pid)) == NULL) { mutex_exit(&pidlock); return (NULL); } mutex_enter(&p->p_lock); mutex_exit(&pidlock); if (p->p_flag & (SVFORK | SEXITING)) { mutex_exit(&p->p_lock); return (NULL); } /* * Increment p_dtrace_probes so that the process knows to inform us * when it exits or execs. fasttrap_provider_free() decrements this * when we're done with this provider. */ p->p_dtrace_probes++; /* * Grab the credentials for this process so we have * something to pass to dtrace_register(). */ mutex_enter(&p->p_crlock); crhold(p->p_cred); cred = p->p_cred; mutex_exit(&p->p_crlock); mutex_exit(&p->p_lock); new_fp = kmem_zalloc(sizeof (fasttrap_provider_t), KM_SLEEP); new_fp->ftp_pid = pid; new_fp->ftp_proc = fasttrap_proc_lookup(pid); ASSERT(new_fp->ftp_proc != NULL); mutex_enter(&bucket->ftb_mtx); /* * Take another lap through the list to make sure a provider hasn't * been created for this pid while we weren't under the bucket lock. */ for (fp = bucket->ftb_data; fp != NULL; fp = fp->ftp_next) { if (fp->ftp_pid == pid && strcmp(fp->ftp_name, name) == 0 && !fp->ftp_retired) { mutex_enter(&fp->ftp_mtx); mutex_exit(&bucket->ftb_mtx); fasttrap_provider_free(new_fp); crfree(cred); return (fp); } } (void) strcpy(new_fp->ftp_name, name); /* * Fail and return NULL if either the provider name is too long * or we fail to register this new provider with the DTrace * framework. Note that this is the only place we ever construct * the full provider name -- we keep it in pieces in the provider * structure. */ if (snprintf(provname, sizeof (provname), "%s%u", name, (uint_t)pid) >= sizeof (provname) || dtrace_register(provname, pattr, DTRACE_PRIV_PROC | DTRACE_PRIV_OWNER | DTRACE_PRIV_ZONEOWNER, cred, pattr == &pid_attr ? &pid_pops : &usdt_pops, new_fp, &new_fp->ftp_provid) != 0) { mutex_exit(&bucket->ftb_mtx); fasttrap_provider_free(new_fp); crfree(cred); return (NULL); } new_fp->ftp_next = bucket->ftb_data; bucket->ftb_data = new_fp; mutex_enter(&new_fp->ftp_mtx); mutex_exit(&bucket->ftb_mtx); crfree(cred); return (new_fp); } static void fasttrap_provider_free(fasttrap_provider_t *provider) { pid_t pid = provider->ftp_pid; proc_t *p; /* * There need to be no associated enabled probes, no consumers * creating probes, and no meta providers referencing this provider. */ ASSERT(provider->ftp_rcount == 0); ASSERT(provider->ftp_ccount == 0); ASSERT(provider->ftp_mcount == 0); + /* + * If this provider hasn't been retired, we need to explicitly drop the + * count of active providers on the associated process structure. + */ + if (!provider->ftp_retired) { + atomic_add_64(&provider->ftp_proc->ftpc_acount, -1); + ASSERT(provider->ftp_proc->ftpc_acount < + provider->ftp_proc->ftpc_rcount); + } + fasttrap_proc_release(provider->ftp_proc); kmem_free(provider, sizeof (fasttrap_provider_t)); /* * Decrement p_dtrace_probes on the process whose provider we're * freeing. We don't have to worry about clobbering somone else's * modifications to it because we have locked the bucket that * corresponds to this process's hash chain in the provider hash * table. Don't sweat it if we can't find the process. */ mutex_enter(&pidlock); if ((p = prfind(pid)) == NULL) { mutex_exit(&pidlock); return; } mutex_enter(&p->p_lock); mutex_exit(&pidlock); p->p_dtrace_probes--; mutex_exit(&p->p_lock); } static void fasttrap_provider_retire(pid_t pid, const char *name, int mprov) { fasttrap_provider_t *fp; fasttrap_bucket_t *bucket; dtrace_provider_id_t provid; ASSERT(strlen(name) < sizeof (fp->ftp_name)); bucket = &fasttrap_provs.fth_table[FASTTRAP_PROVS_INDEX(pid, name)]; mutex_enter(&bucket->ftb_mtx); for (fp = bucket->ftb_data; fp != NULL; fp = fp->ftp_next) { if (fp->ftp_pid == pid && strcmp(fp->ftp_name, name) == 0 && !fp->ftp_retired) break; } if (fp == NULL) { mutex_exit(&bucket->ftb_mtx); return; } mutex_enter(&fp->ftp_mtx); ASSERT(!mprov || fp->ftp_mcount > 0); if (mprov && --fp->ftp_mcount != 0) { mutex_exit(&fp->ftp_mtx); mutex_exit(&bucket->ftb_mtx); return; } /* * Mark the provider to be removed in our post-processing step, mark it * retired, and drop the active count on its proc. Marking it indicates * that we should try to remove it; setting the retired flag indicates * that we're done with this provider; dropping the active the proc * releases our hold, and when this reaches zero (as it will during * exit or exec) the proc and associated providers become defunct. * * We obviously need to take the bucket lock before the provider lock * to perform the lookup, but we need to drop the provider lock * before calling into the DTrace framework since we acquire the * provider lock in callbacks invoked from the DTrace framework. The * bucket lock therefore protects the integrity of the provider hash * table. */ atomic_add_64(&fp->ftp_proc->ftpc_acount, -1); + ASSERT(fp->ftp_proc->ftpc_acount < fp->ftp_proc->ftpc_rcount); + fp->ftp_retired = 1; fp->ftp_marked = 1; provid = fp->ftp_provid; mutex_exit(&fp->ftp_mtx); /* * We don't have to worry about invalidating the same provider twice * since fasttrap_provider_lookup() will ignore provider that have * been marked as retired. */ dtrace_invalidate(provid); mutex_exit(&bucket->ftb_mtx); fasttrap_pid_cleanup(); } static int fasttrap_uint32_cmp(const void *ap, const void *bp) { return (*(const uint32_t *)ap - *(const uint32_t *)bp); } static int fasttrap_uint64_cmp(const void *ap, const void *bp) { return (*(const uint64_t *)ap - *(const uint64_t *)bp); } static int fasttrap_add_probe(fasttrap_probe_spec_t *pdata) { fasttrap_provider_t *provider; fasttrap_probe_t *pp; fasttrap_tracepoint_t *tp; char *name; int i, aframes, whack; /* * There needs to be at least one desired trace point. */ if (pdata->ftps_noffs == 0) return (EINVAL); switch (pdata->ftps_type) { case DTFTP_ENTRY: name = "entry"; aframes = FASTTRAP_ENTRY_AFRAMES; break; case DTFTP_RETURN: name = "return"; aframes = FASTTRAP_RETURN_AFRAMES; break; case DTFTP_OFFSETS: name = NULL; break; default: return (EINVAL); } if ((provider = fasttrap_provider_lookup(pdata->ftps_pid, FASTTRAP_PID_NAME, &pid_attr)) == NULL) return (ESRCH); /* * Increment this reference count to indicate that a consumer is * actively adding a new probe associated with this provider. This * prevents the provider from being deleted -- we'll need to check * for pending deletions when we drop this reference count. */ provider->ftp_ccount++; mutex_exit(&provider->ftp_mtx); /* * Grab the creation lock to ensure consistency between calls to * dtrace_probe_lookup() and dtrace_probe_create() in the face of * other threads creating probes. We must drop the provider lock * before taking this lock to avoid a three-way deadlock with the * DTrace framework. */ mutex_enter(&provider->ftp_cmtx); if (name == NULL) { for (i = 0; i < pdata->ftps_noffs; i++) { char name_str[17]; (void) sprintf(name_str, "%llx", (unsigned long long)pdata->ftps_offs[i]); if (dtrace_probe_lookup(provider->ftp_provid, pdata->ftps_mod, pdata->ftps_func, name_str) != 0) continue; atomic_add_32(&fasttrap_total, 1); if (fasttrap_total > fasttrap_max) { atomic_add_32(&fasttrap_total, -1); goto no_mem; } pp = kmem_zalloc(sizeof (fasttrap_probe_t), KM_SLEEP); pp->ftp_prov = provider; pp->ftp_faddr = pdata->ftps_pc; pp->ftp_fsize = pdata->ftps_size; pp->ftp_pid = pdata->ftps_pid; pp->ftp_ntps = 1; tp = kmem_zalloc(sizeof (fasttrap_tracepoint_t), KM_SLEEP); tp->ftt_proc = provider->ftp_proc; tp->ftt_pc = pdata->ftps_offs[i] + pdata->ftps_pc; tp->ftt_pid = pdata->ftps_pid; pp->ftp_tps[0].fit_tp = tp; pp->ftp_tps[0].fit_id.fti_probe = pp; pp->ftp_tps[0].fit_id.fti_ptype = pdata->ftps_type; pp->ftp_id = dtrace_probe_create(provider->ftp_provid, pdata->ftps_mod, pdata->ftps_func, name_str, FASTTRAP_OFFSET_AFRAMES, pp); } } else if (dtrace_probe_lookup(provider->ftp_provid, pdata->ftps_mod, pdata->ftps_func, name) == 0) { atomic_add_32(&fasttrap_total, pdata->ftps_noffs); if (fasttrap_total > fasttrap_max) { atomic_add_32(&fasttrap_total, -pdata->ftps_noffs); goto no_mem; } /* * Make sure all tracepoint program counter values are unique. * We later assume that each probe has exactly one tracepoint * for a given pc. */ qsort(pdata->ftps_offs, pdata->ftps_noffs, sizeof (uint64_t), fasttrap_uint64_cmp); for (i = 1; i < pdata->ftps_noffs; i++) { if (pdata->ftps_offs[i] > pdata->ftps_offs[i - 1]) continue; atomic_add_32(&fasttrap_total, -pdata->ftps_noffs); goto no_mem; } ASSERT(pdata->ftps_noffs > 0); pp = kmem_zalloc(offsetof(fasttrap_probe_t, ftp_tps[pdata->ftps_noffs]), KM_SLEEP); pp->ftp_prov = provider; pp->ftp_faddr = pdata->ftps_pc; pp->ftp_fsize = pdata->ftps_size; pp->ftp_pid = pdata->ftps_pid; pp->ftp_ntps = pdata->ftps_noffs; for (i = 0; i < pdata->ftps_noffs; i++) { tp = kmem_zalloc(sizeof (fasttrap_tracepoint_t), KM_SLEEP); tp->ftt_proc = provider->ftp_proc; tp->ftt_pc = pdata->ftps_offs[i] + pdata->ftps_pc; tp->ftt_pid = pdata->ftps_pid; pp->ftp_tps[i].fit_tp = tp; pp->ftp_tps[i].fit_id.fti_probe = pp; pp->ftp_tps[i].fit_id.fti_ptype = pdata->ftps_type; } pp->ftp_id = dtrace_probe_create(provider->ftp_provid, pdata->ftps_mod, pdata->ftps_func, name, aframes, pp); } mutex_exit(&provider->ftp_cmtx); /* * We know that the provider is still valid since we incremented the * creation reference count. If someone tried to clean up this provider * while we were using it (e.g. because the process called exec(2) or * exit(2)), take note of that and try to clean it up now. */ mutex_enter(&provider->ftp_mtx); provider->ftp_ccount--; whack = provider->ftp_retired; mutex_exit(&provider->ftp_mtx); if (whack) fasttrap_pid_cleanup(); return (0); no_mem: /* * If we've exhausted the allowable resources, we'll try to remove * this provider to free some up. This is to cover the case where * the user has accidentally created many more probes than was * intended (e.g. pid123:::). */ mutex_exit(&provider->ftp_cmtx); mutex_enter(&provider->ftp_mtx); provider->ftp_ccount--; provider->ftp_marked = 1; mutex_exit(&provider->ftp_mtx); fasttrap_pid_cleanup(); return (ENOMEM); } /*ARGSUSED*/ static void * fasttrap_meta_provide(void *arg, dtrace_helper_provdesc_t *dhpv, pid_t pid) { fasttrap_provider_t *provider; /* * A 32-bit unsigned integer (like a pid for example) can be * expressed in 10 or fewer decimal digits. Make sure that we'll * have enough space for the provider name. */ if (strlen(dhpv->dthpv_provname) + 10 >= sizeof (provider->ftp_name)) { cmn_err(CE_WARN, "failed to instantiate provider %s: " "name too long to accomodate pid", dhpv->dthpv_provname); return (NULL); } /* * Don't let folks spoof the true pid provider. */ if (strcmp(dhpv->dthpv_provname, FASTTRAP_PID_NAME) == 0) { cmn_err(CE_WARN, "failed to instantiate provider %s: " "%s is an invalid name", dhpv->dthpv_provname, FASTTRAP_PID_NAME); return (NULL); } /* * The highest stability class that fasttrap supports is ISA; cap * the stability of the new provider accordingly. */ if (dhpv->dthpv_pattr.dtpa_provider.dtat_class > DTRACE_CLASS_ISA) dhpv->dthpv_pattr.dtpa_provider.dtat_class = DTRACE_CLASS_ISA; if (dhpv->dthpv_pattr.dtpa_mod.dtat_class > DTRACE_CLASS_ISA) dhpv->dthpv_pattr.dtpa_mod.dtat_class = DTRACE_CLASS_ISA; if (dhpv->dthpv_pattr.dtpa_func.dtat_class > DTRACE_CLASS_ISA) dhpv->dthpv_pattr.dtpa_func.dtat_class = DTRACE_CLASS_ISA; if (dhpv->dthpv_pattr.dtpa_name.dtat_class > DTRACE_CLASS_ISA) dhpv->dthpv_pattr.dtpa_name.dtat_class = DTRACE_CLASS_ISA; if (dhpv->dthpv_pattr.dtpa_args.dtat_class > DTRACE_CLASS_ISA) dhpv->dthpv_pattr.dtpa_args.dtat_class = DTRACE_CLASS_ISA; if ((provider = fasttrap_provider_lookup(pid, dhpv->dthpv_provname, &dhpv->dthpv_pattr)) == NULL) { cmn_err(CE_WARN, "failed to instantiate provider %s for " "process %u", dhpv->dthpv_provname, (uint_t)pid); return (NULL); } /* * Up the meta provider count so this provider isn't removed until * the meta provider has been told to remove it. */ provider->ftp_mcount++; mutex_exit(&provider->ftp_mtx); return (provider); } /*ARGSUSED*/ static void fasttrap_meta_create_probe(void *arg, void *parg, dtrace_helper_probedesc_t *dhpb) { fasttrap_provider_t *provider = parg; fasttrap_probe_t *pp; fasttrap_tracepoint_t *tp; int i, j; uint32_t ntps; /* * Since the meta provider count is non-zero we don't have to worry * about this provider disappearing. */ ASSERT(provider->ftp_mcount > 0); /* * The offsets must be unique. */ qsort(dhpb->dthpb_offs, dhpb->dthpb_noffs, sizeof (uint32_t), fasttrap_uint32_cmp); for (i = 1; i < dhpb->dthpb_noffs; i++) { if (dhpb->dthpb_base + dhpb->dthpb_offs[i] <= dhpb->dthpb_base + dhpb->dthpb_offs[i - 1]) return; } qsort(dhpb->dthpb_enoffs, dhpb->dthpb_nenoffs, sizeof (uint32_t), fasttrap_uint32_cmp); for (i = 1; i < dhpb->dthpb_nenoffs; i++) { if (dhpb->dthpb_base + dhpb->dthpb_enoffs[i] <= dhpb->dthpb_base + dhpb->dthpb_enoffs[i - 1]) return; } /* * Grab the creation lock to ensure consistency between calls to * dtrace_probe_lookup() and dtrace_probe_create() in the face of * other threads creating probes. */ mutex_enter(&provider->ftp_cmtx); if (dtrace_probe_lookup(provider->ftp_provid, dhpb->dthpb_mod, dhpb->dthpb_func, dhpb->dthpb_name) != 0) { mutex_exit(&provider->ftp_cmtx); return; } ntps = dhpb->dthpb_noffs + dhpb->dthpb_nenoffs; ASSERT(ntps > 0); atomic_add_32(&fasttrap_total, ntps); if (fasttrap_total > fasttrap_max) { atomic_add_32(&fasttrap_total, -ntps); mutex_exit(&provider->ftp_cmtx); return; } pp = kmem_zalloc(offsetof(fasttrap_probe_t, ftp_tps[ntps]), KM_SLEEP); pp->ftp_prov = provider; pp->ftp_pid = provider->ftp_pid; pp->ftp_ntps = ntps; pp->ftp_nargs = dhpb->dthpb_xargc; pp->ftp_xtypes = dhpb->dthpb_xtypes; pp->ftp_ntypes = dhpb->dthpb_ntypes; /* * First create a tracepoint for each actual point of interest. */ for (i = 0; i < dhpb->dthpb_noffs; i++) { tp = kmem_zalloc(sizeof (fasttrap_tracepoint_t), KM_SLEEP); tp->ftt_proc = provider->ftp_proc; tp->ftt_pc = dhpb->dthpb_base + dhpb->dthpb_offs[i]; tp->ftt_pid = provider->ftp_pid; pp->ftp_tps[i].fit_tp = tp; pp->ftp_tps[i].fit_id.fti_probe = pp; #ifdef __sparc pp->ftp_tps[i].fit_id.fti_ptype = DTFTP_POST_OFFSETS; #else pp->ftp_tps[i].fit_id.fti_ptype = DTFTP_OFFSETS; #endif } /* * Then create a tracepoint for each is-enabled point. */ for (j = 0; i < ntps; i++, j++) { tp = kmem_zalloc(sizeof (fasttrap_tracepoint_t), KM_SLEEP); tp->ftt_proc = provider->ftp_proc; tp->ftt_pc = dhpb->dthpb_base + dhpb->dthpb_enoffs[j]; tp->ftt_pid = provider->ftp_pid; pp->ftp_tps[i].fit_tp = tp; pp->ftp_tps[i].fit_id.fti_probe = pp; pp->ftp_tps[i].fit_id.fti_ptype = DTFTP_IS_ENABLED; } /* * If the arguments are shuffled around we set the argument remapping * table. Later, when the probe fires, we only remap the arguments * if the table is non-NULL. */ for (i = 0; i < dhpb->dthpb_xargc; i++) { if (dhpb->dthpb_args[i] != i) { pp->ftp_argmap = dhpb->dthpb_args; break; } } /* * The probe is fully constructed -- register it with DTrace. */ pp->ftp_id = dtrace_probe_create(provider->ftp_provid, dhpb->dthpb_mod, dhpb->dthpb_func, dhpb->dthpb_name, FASTTRAP_OFFSET_AFRAMES, pp); mutex_exit(&provider->ftp_cmtx); } /*ARGSUSED*/ static void fasttrap_meta_remove(void *arg, dtrace_helper_provdesc_t *dhpv, pid_t pid) { /* * Clean up the USDT provider. There may be active consumers of the * provider busy adding probes, no damage will actually befall the * provider until that count has dropped to zero. This just puts * the provider on death row. */ fasttrap_provider_retire(pid, dhpv->dthpv_provname, 1); } static dtrace_mops_t fasttrap_mops = { fasttrap_meta_create_probe, fasttrap_meta_provide, fasttrap_meta_remove }; /*ARGSUSED*/ static int fasttrap_open(dev_t *devp, int flag, int otyp, cred_t *cred_p) { return (0); } /*ARGSUSED*/ static int fasttrap_ioctl(dev_t dev, int cmd, intptr_t arg, int md, cred_t *cr, int *rv) { if (!dtrace_attached()) return (EAGAIN); if (cmd == FASTTRAPIOC_MAKEPROBE) { fasttrap_probe_spec_t *uprobe = (void *)arg; fasttrap_probe_spec_t *probe; uint64_t noffs; size_t size; int ret; char *c; if (copyin(&uprobe->ftps_noffs, &noffs, sizeof (uprobe->ftps_noffs))) return (EFAULT); /* * Probes must have at least one tracepoint. */ if (noffs == 0) return (EINVAL); size = sizeof (fasttrap_probe_spec_t) + sizeof (probe->ftps_offs[0]) * (noffs - 1); if (size > 1024 * 1024) return (ENOMEM); probe = kmem_alloc(size, KM_SLEEP); if (copyin(uprobe, probe, size) != 0) { kmem_free(probe, size); return (EFAULT); } /* * Verify that the function and module strings contain no * funny characters. */ for (c = &probe->ftps_func[0]; *c != '\0'; c++) { if (*c < 0x20 || 0x7f <= *c) { ret = EINVAL; goto err; } } for (c = &probe->ftps_mod[0]; *c != '\0'; c++) { if (*c < 0x20 || 0x7f <= *c) { ret = EINVAL; goto err; } } if (!PRIV_POLICY_CHOICE(cr, PRIV_ALL, B_FALSE)) { proc_t *p; pid_t pid = probe->ftps_pid; mutex_enter(&pidlock); /* * Report an error if the process doesn't exist * or is actively being birthed. */ if ((p = prfind(pid)) == NULL || p->p_stat == SIDL) { mutex_exit(&pidlock); return (ESRCH); } mutex_enter(&p->p_lock); mutex_exit(&pidlock); if ((ret = priv_proc_cred_perm(cr, p, NULL, VREAD | VWRITE)) != 0) { mutex_exit(&p->p_lock); return (ret); } mutex_exit(&p->p_lock); } ret = fasttrap_add_probe(probe); err: kmem_free(probe, size); return (ret); } else if (cmd == FASTTRAPIOC_GETINSTR) { fasttrap_instr_query_t instr; fasttrap_tracepoint_t *tp; uint_t index; int ret; if (copyin((void *)arg, &instr, sizeof (instr)) != 0) return (EFAULT); if (!PRIV_POLICY_CHOICE(cr, PRIV_ALL, B_FALSE)) { proc_t *p; pid_t pid = instr.ftiq_pid; mutex_enter(&pidlock); /* * Report an error if the process doesn't exist * or is actively being birthed. */ if ((p = prfind(pid)) == NULL || p->p_stat == SIDL) { mutex_exit(&pidlock); return (ESRCH); } mutex_enter(&p->p_lock); mutex_exit(&pidlock); if ((ret = priv_proc_cred_perm(cr, p, NULL, VREAD)) != 0) { mutex_exit(&p->p_lock); return (ret); } mutex_exit(&p->p_lock); } index = FASTTRAP_TPOINTS_INDEX(instr.ftiq_pid, instr.ftiq_pc); mutex_enter(&fasttrap_tpoints.fth_table[index].ftb_mtx); tp = fasttrap_tpoints.fth_table[index].ftb_data; while (tp != NULL) { if (instr.ftiq_pid == tp->ftt_pid && instr.ftiq_pc == tp->ftt_pc && tp->ftt_proc->ftpc_acount != 0) break; + /* + * The count of active providers can only be + * decremented (i.e. to zero) during exec, exit, and + * removal of a meta provider so it should be + * impossible to drop the count during this operation(). + */ + ASSERT(tp->ftt_proc->ftpc_acount != 0); tp = tp->ftt_next; } if (tp == NULL) { mutex_exit(&fasttrap_tpoints.fth_table[index].ftb_mtx); return (ENOENT); } bcopy(&tp->ftt_instr, &instr.ftiq_instr, sizeof (instr.ftiq_instr)); mutex_exit(&fasttrap_tpoints.fth_table[index].ftb_mtx); if (copyout(&instr, (void *)arg, sizeof (instr)) != 0) return (EFAULT); return (0); } return (EINVAL); } static struct cb_ops fasttrap_cb_ops = { fasttrap_open, /* open */ nodev, /* close */ nulldev, /* strategy */ nulldev, /* print */ nodev, /* dump */ nodev, /* read */ nodev, /* write */ fasttrap_ioctl, /* ioctl */ nodev, /* devmap */ nodev, /* mmap */ nodev, /* segmap */ nochpoll, /* poll */ ddi_prop_op, /* cb_prop_op */ 0, /* streamtab */ D_NEW | D_MP /* Driver compatibility flag */ }; /*ARGSUSED*/ static int fasttrap_info(dev_info_t *dip, ddi_info_cmd_t infocmd, void *arg, void **result) { int error; switch (infocmd) { case DDI_INFO_DEVT2DEVINFO: *result = (void *)fasttrap_devi; error = DDI_SUCCESS; break; case DDI_INFO_DEVT2INSTANCE: *result = (void *)0; error = DDI_SUCCESS; break; default: error = DDI_FAILURE; } return (error); } static int fasttrap_attach(dev_info_t *devi, ddi_attach_cmd_t cmd) { ulong_t nent; switch (cmd) { case DDI_ATTACH: break; case DDI_RESUME: return (DDI_SUCCESS); default: return (DDI_FAILURE); } if (ddi_create_minor_node(devi, "fasttrap", S_IFCHR, 0, DDI_PSEUDO, NULL) == DDI_FAILURE) { ddi_remove_minor_node(devi, NULL); return (DDI_FAILURE); } ddi_report_dev(devi); fasttrap_devi = devi; /* * Install our hooks into fork(2), exec(2), and exit(2). */ dtrace_fasttrap_fork_ptr = &fasttrap_fork; dtrace_fasttrap_exit_ptr = &fasttrap_exec_exit; dtrace_fasttrap_exec_ptr = &fasttrap_exec_exit; fasttrap_max = ddi_getprop(DDI_DEV_T_ANY, devi, DDI_PROP_DONTPASS, "fasttrap-max-probes", FASTTRAP_MAX_DEFAULT); fasttrap_total = 0; /* * Conjure up the tracepoints hashtable... */ nent = ddi_getprop(DDI_DEV_T_ANY, devi, DDI_PROP_DONTPASS, "fasttrap-hash-size", FASTTRAP_TPOINTS_DEFAULT_SIZE); if (nent == 0 || nent > 0x1000000) nent = FASTTRAP_TPOINTS_DEFAULT_SIZE; if ((nent & (nent - 1)) == 0) fasttrap_tpoints.fth_nent = nent; else fasttrap_tpoints.fth_nent = 1 << fasttrap_highbit(nent); ASSERT(fasttrap_tpoints.fth_nent > 0); fasttrap_tpoints.fth_mask = fasttrap_tpoints.fth_nent - 1; fasttrap_tpoints.fth_table = kmem_zalloc(fasttrap_tpoints.fth_nent * sizeof (fasttrap_bucket_t), KM_SLEEP); /* * ... and the providers hash table... */ nent = FASTTRAP_PROVIDERS_DEFAULT_SIZE; if ((nent & (nent - 1)) == 0) fasttrap_provs.fth_nent = nent; else fasttrap_provs.fth_nent = 1 << fasttrap_highbit(nent); ASSERT(fasttrap_provs.fth_nent > 0); fasttrap_provs.fth_mask = fasttrap_provs.fth_nent - 1; fasttrap_provs.fth_table = kmem_zalloc(fasttrap_provs.fth_nent * sizeof (fasttrap_bucket_t), KM_SLEEP); /* * ... and the procs hash table. */ nent = FASTTRAP_PROCS_DEFAULT_SIZE; if ((nent & (nent - 1)) == 0) fasttrap_procs.fth_nent = nent; else fasttrap_procs.fth_nent = 1 << fasttrap_highbit(nent); ASSERT(fasttrap_procs.fth_nent > 0); fasttrap_procs.fth_mask = fasttrap_procs.fth_nent - 1; fasttrap_procs.fth_table = kmem_zalloc(fasttrap_procs.fth_nent * sizeof (fasttrap_bucket_t), KM_SLEEP); (void) dtrace_meta_register("fasttrap", &fasttrap_mops, NULL, &fasttrap_meta_id); return (DDI_SUCCESS); } static int fasttrap_detach(dev_info_t *devi, ddi_detach_cmd_t cmd) { int i, fail = 0; timeout_id_t tmp; switch (cmd) { case DDI_DETACH: break; case DDI_SUSPEND: return (DDI_SUCCESS); default: return (DDI_FAILURE); } /* * Unregister the meta-provider to make sure no new fasttrap- * managed providers come along while we're trying to close up * shop. If we fail to detach, we'll need to re-register as a * meta-provider. We can fail to unregister as a meta-provider * if providers we manage still exist. */ if (fasttrap_meta_id != DTRACE_METAPROVNONE && dtrace_meta_unregister(fasttrap_meta_id) != 0) return (DDI_FAILURE); /* * Prevent any new timeouts from running by setting fasttrap_timeout * to a non-zero value, and wait for the current timeout to complete. */ mutex_enter(&fasttrap_cleanup_mtx); fasttrap_cleanup_work = 0; while (fasttrap_timeout != (timeout_id_t)1) { tmp = fasttrap_timeout; fasttrap_timeout = (timeout_id_t)1; if (tmp != 0) { mutex_exit(&fasttrap_cleanup_mtx); (void) untimeout(tmp); mutex_enter(&fasttrap_cleanup_mtx); } } fasttrap_cleanup_work = 0; mutex_exit(&fasttrap_cleanup_mtx); /* * Iterate over all of our providers. If there's still a process * that corresponds to that pid, fail to detach. */ for (i = 0; i < fasttrap_provs.fth_nent; i++) { fasttrap_provider_t **fpp, *fp; fasttrap_bucket_t *bucket = &fasttrap_provs.fth_table[i]; mutex_enter(&bucket->ftb_mtx); fpp = (fasttrap_provider_t **)&bucket->ftb_data; while ((fp = *fpp) != NULL) { /* * Acquire and release the lock as a simple way of * waiting for any other consumer to finish with * this provider. A thread must first acquire the * bucket lock so there's no chance of another thread * blocking on the provider's lock. */ mutex_enter(&fp->ftp_mtx); mutex_exit(&fp->ftp_mtx); if (dtrace_unregister(fp->ftp_provid) != 0) { fail = 1; fpp = &fp->ftp_next; } else { *fpp = fp->ftp_next; fasttrap_provider_free(fp); } } mutex_exit(&bucket->ftb_mtx); } if (fail) { uint_t work; /* * If we're failing to detach, we need to unblock timeouts * and start a new timeout if any work has accumulated while * we've been unsuccessfully trying to detach. */ mutex_enter(&fasttrap_cleanup_mtx); fasttrap_timeout = 0; work = fasttrap_cleanup_work; mutex_exit(&fasttrap_cleanup_mtx); if (work) fasttrap_pid_cleanup(); (void) dtrace_meta_register("fasttrap", &fasttrap_mops, NULL, &fasttrap_meta_id); return (DDI_FAILURE); } #ifdef DEBUG mutex_enter(&fasttrap_count_mtx); ASSERT(fasttrap_pid_count == 0); mutex_exit(&fasttrap_count_mtx); #endif kmem_free(fasttrap_tpoints.fth_table, fasttrap_tpoints.fth_nent * sizeof (fasttrap_bucket_t)); fasttrap_tpoints.fth_nent = 0; kmem_free(fasttrap_provs.fth_table, fasttrap_provs.fth_nent * sizeof (fasttrap_bucket_t)); fasttrap_provs.fth_nent = 0; kmem_free(fasttrap_procs.fth_table, fasttrap_procs.fth_nent * sizeof (fasttrap_bucket_t)); fasttrap_procs.fth_nent = 0; /* * We know there are no tracepoints in any process anywhere in * the system so there is no process which has its p_dtrace_count * greater than zero, therefore we know that no thread can actively * be executing code in fasttrap_fork(). Similarly for p_dtrace_probes * and fasttrap_exec() and fasttrap_exit(). */ ASSERT(dtrace_fasttrap_fork_ptr == &fasttrap_fork); dtrace_fasttrap_fork_ptr = NULL; ASSERT(dtrace_fasttrap_exec_ptr == &fasttrap_exec_exit); dtrace_fasttrap_exec_ptr = NULL; ASSERT(dtrace_fasttrap_exit_ptr == &fasttrap_exec_exit); dtrace_fasttrap_exit_ptr = NULL; ddi_remove_minor_node(devi, NULL); return (DDI_SUCCESS); } static struct dev_ops fasttrap_ops = { DEVO_REV, /* devo_rev */ 0, /* refcnt */ fasttrap_info, /* get_dev_info */ nulldev, /* identify */ nulldev, /* probe */ fasttrap_attach, /* attach */ fasttrap_detach, /* detach */ nodev, /* reset */ &fasttrap_cb_ops, /* driver operations */ NULL, /* bus operations */ nodev /* dev power */ }; /* * Module linkage information for the kernel. */ static struct modldrv modldrv = { &mod_driverops, /* module type (this is a pseudo driver) */ "Fasttrap Tracing", /* name of module */ &fasttrap_ops, /* driver ops */ }; static struct modlinkage modlinkage = { MODREV_1, (void *)&modldrv, NULL }; int _init(void) { return (mod_install(&modlinkage)); } int _info(struct modinfo *modinfop) { return (mod_info(&modlinkage, modinfop)); } int _fini(void) { return (mod_remove(&modlinkage)); } Index: head/sys/cddl/contrib/opensolaris/uts/common/sys/cpuvar.h =================================================================== --- head/sys/cddl/contrib/opensolaris/uts/common/sys/cpuvar.h (revision 179197) +++ head/sys/cddl/contrib/opensolaris/uts/common/sys/cpuvar.h (revision 179198) @@ -1,737 +1,737 @@ /* * CDDL HEADER START * * The contents of this file are subject to the terms of the * Common Development and Distribution License (the "License"). * You may not use this file except in compliance with the License. * * You can obtain a copy of the license at usr/src/OPENSOLARIS.LICENSE * or http://www.opensolaris.org/os/licensing. * See the License for the specific language governing permissions * and limitations under the License. * * When distributing Covered Code, include this CDDL HEADER in each * file and include the License file at usr/src/OPENSOLARIS.LICENSE. * If applicable, add the following below this CDDL HEADER, with the * fields enclosed by brackets "[]" replaced with your own identifying * information: Portions Copyright [yyyy] [name of copyright owner] * * CDDL HEADER END */ /* * Copyright 2008 Sun Microsystems, Inc. All rights reserved. * Use is subject to license terms. */ #ifndef _SYS_CPUVAR_H #define _SYS_CPUVAR_H #pragma ident "%Z%%M% %I% %E% SMI" #include #include /* has cpu_stat_t definition */ #include #include #if (defined(_KERNEL) || defined(_KMEMUSER)) && defined(_MACHDEP) #include #endif #include #include #include #include #include #if defined(__GNUC__) && defined(_ASM_INLINES) && defined(_KERNEL) && \ (defined(__i386) || defined(__amd64)) #include #endif #ifdef __cplusplus extern "C" { #endif struct squeue_set_s; #define CPU_CACHE_COHERENCE_SIZE 64 #define S_LOADAVG_SZ 11 #define S_MOVAVG_SZ 10 struct loadavg_s { int lg_cur; /* current loadavg entry */ unsigned int lg_len; /* number entries recorded */ hrtime_t lg_total; /* used to temporarily hold load totals */ hrtime_t lg_loads[S_LOADAVG_SZ]; /* table of recorded entries */ }; /* * For fast event tracing. */ struct ftrace_record; typedef struct ftrace_data { int ftd_state; /* ftrace flags */ kmutex_t ftd_unused; /* ftrace buffer lock, unused */ struct ftrace_record *ftd_cur; /* current record */ struct ftrace_record *ftd_first; /* first record */ struct ftrace_record *ftd_last; /* last record */ } ftrace_data_t; struct cyc_cpu; struct nvlist; /* * Per-CPU data. * * Be careful adding new members: if they are not the same in all modules (e.g. * change size depending on a #define), CTF uniquification can fail to work * properly. Furthermore, this is transitive in that it applies recursively to * all types pointed to by cpu_t. */ typedef struct cpu { processorid_t cpu_id; /* CPU number */ processorid_t cpu_seqid; /* sequential CPU id (0..ncpus-1) */ volatile cpu_flag_t cpu_flags; /* flags indicating CPU state */ struct cpu *cpu_self; /* pointer to itself */ kthread_t *cpu_thread; /* current thread */ kthread_t *cpu_idle_thread; /* idle thread for this CPU */ kthread_t *cpu_pause_thread; /* pause thread for this CPU */ klwp_id_t cpu_lwp; /* current lwp (if any) */ klwp_id_t cpu_fpowner; /* currently loaded fpu owner */ struct cpupart *cpu_part; /* partition with this CPU */ struct lgrp_ld *cpu_lpl; /* pointer to this cpu's load */ int cpu_cache_offset; /* see kmem.c for details */ /* * Links to other CPUs. It is safe to walk these lists if * one of the following is true: * - cpu_lock held * - preemption disabled via kpreempt_disable * - PIL >= DISP_LEVEL * - acting thread is an interrupt thread * - all other CPUs are paused */ struct cpu *cpu_next; /* next existing CPU */ struct cpu *cpu_prev; /* prev existing CPU */ struct cpu *cpu_next_onln; /* next online (enabled) CPU */ struct cpu *cpu_prev_onln; /* prev online (enabled) CPU */ struct cpu *cpu_next_part; /* next CPU in partition */ struct cpu *cpu_prev_part; /* prev CPU in partition */ struct cpu *cpu_next_lgrp; /* next CPU in latency group */ struct cpu *cpu_prev_lgrp; /* prev CPU in latency group */ struct cpu *cpu_next_lpl; /* next CPU in lgrp partition */ struct cpu *cpu_prev_lpl; struct cpu_pg *cpu_pg; /* cpu's processor groups */ void *cpu_reserved[4]; /* reserved for future use */ /* * Scheduling variables. */ disp_t *cpu_disp; /* dispatch queue data */ /* * Note that cpu_disp is set before the CPU is added to the system * and is never modified. Hence, no additional locking is needed * beyond what's necessary to access the cpu_t structure. */ char cpu_runrun; /* scheduling flag - set to preempt */ char cpu_kprunrun; /* force kernel preemption */ pri_t cpu_chosen_level; /* priority at which cpu */ /* was chosen for scheduling */ kthread_t *cpu_dispthread; /* thread selected for dispatch */ disp_lock_t cpu_thread_lock; /* dispatcher lock on current thread */ uint8_t cpu_disp_flags; /* flags used by dispatcher */ /* * The following field is updated when ever the cpu_dispthread * changes. Also in places, where the current thread(cpu_dispthread) * priority changes. This is used in disp_lowpri_cpu() */ pri_t cpu_dispatch_pri; /* priority of cpu_dispthread */ clock_t cpu_last_swtch; /* last time switched to new thread */ /* * Interrupt data. */ caddr_t cpu_intr_stack; /* interrupt stack */ kthread_t *cpu_intr_thread; /* interrupt thread list */ uint_t cpu_intr_actv; /* interrupt levels active (bitmask) */ int cpu_base_spl; /* priority for highest rupt active */ /* * Statistics. */ cpu_stats_t cpu_stats; /* per-CPU statistics */ struct kstat *cpu_info_kstat; /* kstat for cpu info */ uintptr_t cpu_profile_pc; /* kernel PC in profile interrupt */ uintptr_t cpu_profile_upc; /* user PC in profile interrupt */ uintptr_t cpu_profile_pil; /* PIL when profile interrupted */ ftrace_data_t cpu_ftrace; /* per cpu ftrace data */ clock_t cpu_deadman_lbolt; /* used by deadman() */ uint_t cpu_deadman_countdown; /* used by deadman() */ kmutex_t cpu_cpc_ctxlock; /* protects context for idle thread */ kcpc_ctx_t *cpu_cpc_ctx; /* performance counter context */ /* * Configuration information for the processor_info system call. */ processor_info_t cpu_type_info; /* config info */ time_t cpu_state_begin; /* when CPU entered current state */ char cpu_cpr_flags; /* CPR related info */ struct cyc_cpu *cpu_cyclic; /* per cpu cyclic subsystem data */ struct squeue_set_s *cpu_squeue_set; /* per cpu squeue set */ struct nvlist *cpu_props; /* pool-related properties */ krwlock_t cpu_ft_lock; /* DTrace: fasttrap lock */ uintptr_t cpu_dtrace_caller; /* DTrace: caller, if any */ hrtime_t cpu_dtrace_chillmark; /* DTrace: chill mark time */ hrtime_t cpu_dtrace_chilled; /* DTrace: total chill time */ volatile uint16_t cpu_mstate; /* cpu microstate */ volatile uint16_t cpu_mstate_gen; /* generation counter */ volatile hrtime_t cpu_mstate_start; /* cpu microstate start time */ volatile hrtime_t cpu_acct[NCMSTATES]; /* cpu microstate data */ hrtime_t cpu_intracct[NCMSTATES]; /* interrupt mstate data */ hrtime_t cpu_waitrq; /* cpu run-queue wait time */ struct loadavg_s cpu_loadavg; /* loadavg info for this cpu */ char *cpu_idstr; /* for printing and debugging */ char *cpu_brandstr; /* for printing */ /* * Sum of all device interrupt weights that are currently directed at * this cpu. Cleared at start of interrupt redistribution. */ int32_t cpu_intr_weight; void *cpu_vm_data; struct cpu_physid *cpu_physid; /* physical associations */ uint64_t cpu_curr_clock; /* current clock freq in Hz */ char *cpu_supp_freqs; /* supported freqs in Hz */ /* * Interrupt load factor used by dispatcher & softcall */ hrtime_t cpu_intrlast; /* total interrupt time (nsec) */ int cpu_intrload; /* interrupt load factor (0-99%) */ /* * New members must be added /before/ this member, as the CTF tools * rely on this being the last field before cpu_m, so they can * correctly calculate the offset when synthetically adding the cpu_m * member in objects that do not have it. This fixup is required for * uniquification to work correctly. */ uintptr_t cpu_m_pad; #if (defined(_KERNEL) || defined(_KMEMUSER)) && defined(_MACHDEP) struct machcpu cpu_m; /* per architecture info */ #endif } cpu_t; /* * The cpu_core structure consists of per-CPU state available in any context. * On some architectures, this may mean that the page(s) containing the * NCPU-sized array of cpu_core structures must be locked in the TLB -- it * is up to the platform to assure that this is performed properly. Note that * the structure is sized to avoid false sharing. */ #define CPUC_SIZE (sizeof (uint16_t) + sizeof (uintptr_t) + \ sizeof (kmutex_t)) #define CPUC_PADSIZE CPU_CACHE_COHERENCE_SIZE - CPUC_SIZE typedef struct cpu_core { uint16_t cpuc_dtrace_flags; /* DTrace flags */ uint8_t cpuc_pad[CPUC_PADSIZE]; /* padding */ uintptr_t cpuc_dtrace_illval; /* DTrace illegal value */ kmutex_t cpuc_pid_lock; /* DTrace pid provider lock */ } cpu_core_t; #ifdef _KERNEL extern cpu_core_t cpu_core[]; #endif /* _KERNEL */ /* * CPU_ON_INTR() macro. Returns non-zero if currently on interrupt stack. * Note that this isn't a test for a high PIL. For example, cpu_intr_actv * does not get updated when we go through sys_trap from TL>0 at high PIL. * getpil() should be used instead to check for PIL levels. */ #define CPU_ON_INTR(cpup) ((cpup)->cpu_intr_actv >> (LOCK_LEVEL + 1)) #if defined(_KERNEL) || defined(_KMEMUSER) #define INTR_STACK_SIZE MAX(DEFAULTSTKSZ, PAGESIZE) /* MEMBERS PROTECTED BY "atomicity": cpu_flags */ /* * Flags in the CPU structure. * * These are protected by cpu_lock (except during creation). * * Offlined-CPUs have three stages of being offline: * * CPU_ENABLE indicates that the CPU is participating in I/O interrupts * that can be directed at a number of different CPUs. If CPU_ENABLE * is off, the CPU will not be given interrupts that can be sent elsewhere, * but will still get interrupts from devices associated with that CPU only, * and from other CPUs. * * CPU_OFFLINE indicates that the dispatcher should not allow any threads * other than interrupt threads to run on that CPU. A CPU will not have * CPU_OFFLINE set if there are any bound threads (besides interrupts). * * CPU_QUIESCED is set if p_offline was able to completely turn idle the * CPU and it will not have to run interrupt threads. In this case it'll * stay in the idle loop until CPU_QUIESCED is turned off. * * CPU_FROZEN is used only by CPR to mark CPUs that have been successfully * suspended (in the suspend path), or have yet to be resumed (in the resume * case). * * On some platforms CPUs can be individually powered off. * The following flags are set for powered off CPUs: CPU_QUIESCED, * CPU_OFFLINE, and CPU_POWEROFF. The following flags are cleared: * CPU_RUNNING, CPU_READY, CPU_EXISTS, and CPU_ENABLE. */ #define CPU_RUNNING 0x001 /* CPU running */ #define CPU_READY 0x002 /* CPU ready for cross-calls */ #define CPU_QUIESCED 0x004 /* CPU will stay in idle */ #define CPU_EXISTS 0x008 /* CPU is configured */ #define CPU_ENABLE 0x010 /* CPU enabled for interrupts */ #define CPU_OFFLINE 0x020 /* CPU offline via p_online */ #define CPU_POWEROFF 0x040 /* CPU is powered off */ #define CPU_FROZEN 0x080 /* CPU is frozen via CPR suspend */ #define CPU_SPARE 0x100 /* CPU offline available for use */ #define CPU_FAULTED 0x200 /* CPU offline diagnosed faulty */ #define FMT_CPU_FLAGS \ "\20\12fault\11spare\10frozen" \ "\7poweroff\6offline\5enable\4exist\3quiesced\2ready\1run" #define CPU_ACTIVE(cpu) (((cpu)->cpu_flags & CPU_OFFLINE) == 0) /* * Flags for cpu_offline(), cpu_faulted(), and cpu_spare(). */ #define CPU_FORCED 0x0001 /* Force CPU offline */ /* * DTrace flags. */ #define CPU_DTRACE_NOFAULT 0x0001 /* Don't fault */ #define CPU_DTRACE_DROP 0x0002 /* Drop this ECB */ #define CPU_DTRACE_BADADDR 0x0004 /* DTrace fault: bad address */ #define CPU_DTRACE_BADALIGN 0x0008 /* DTrace fault: bad alignment */ #define CPU_DTRACE_DIVZERO 0x0010 /* DTrace fault: divide by zero */ #define CPU_DTRACE_ILLOP 0x0020 /* DTrace fault: illegal operation */ #define CPU_DTRACE_NOSCRATCH 0x0040 /* DTrace fault: out of scratch */ #define CPU_DTRACE_KPRIV 0x0080 /* DTrace fault: bad kernel access */ #define CPU_DTRACE_UPRIV 0x0100 /* DTrace fault: bad user access */ #define CPU_DTRACE_TUPOFLOW 0x0200 /* DTrace fault: tuple stack overflow */ #if defined(__sparc) #define CPU_DTRACE_FAKERESTORE 0x0400 /* pid provider hint to getreg */ #endif #define CPU_DTRACE_ENTRY 0x0800 /* pid provider hint to ustack() */ #define CPU_DTRACE_BADSTACK 0x1000 /* DTrace fault: bad stack */ #define CPU_DTRACE_FAULT (CPU_DTRACE_BADADDR | CPU_DTRACE_BADALIGN | \ CPU_DTRACE_DIVZERO | CPU_DTRACE_ILLOP | \ CPU_DTRACE_NOSCRATCH | CPU_DTRACE_KPRIV | \ CPU_DTRACE_UPRIV | CPU_DTRACE_TUPOFLOW | \ CPU_DTRACE_BADSTACK) #define CPU_DTRACE_ERROR (CPU_DTRACE_FAULT | CPU_DTRACE_DROP) /* * Dispatcher flags * These flags must be changed only by the current CPU. */ #define CPU_DISP_DONTSTEAL 0x01 /* CPU undergoing context swtch */ #define CPU_DISP_HALTED 0x02 /* CPU halted waiting for interrupt */ #endif /* _KERNEL || _KMEMUSER */ #if (defined(_KERNEL) || defined(_KMEMUSER)) && defined(_MACHDEP) /* * Macros for manipulating sets of CPUs as a bitmap. Note that this * bitmap may vary in size depending on the maximum CPU id a specific * platform supports. This may be different than the number of CPUs * the platform supports, since CPU ids can be sparse. We define two * sets of macros; one for platforms where the maximum CPU id is less * than the number of bits in a single word (32 in a 32-bit kernel, * 64 in a 64-bit kernel), and one for platforms that require bitmaps * of more than one word. */ #define CPUSET_WORDS BT_BITOUL(NCPU) #define CPUSET_NOTINSET ((uint_t)-1) #if CPUSET_WORDS > 1 typedef struct cpuset { ulong_t cpub[CPUSET_WORDS]; } cpuset_t; /* * Private functions for manipulating cpusets that do not fit in a * single word. These should not be used directly; instead the * CPUSET_* macros should be used so the code will be portable * across different definitions of NCPU. */ extern void cpuset_all(cpuset_t *); extern void cpuset_all_but(cpuset_t *, uint_t); extern int cpuset_isnull(cpuset_t *); extern int cpuset_cmp(cpuset_t *, cpuset_t *); extern void cpuset_only(cpuset_t *, uint_t); extern uint_t cpuset_find(cpuset_t *); extern void cpuset_bounds(cpuset_t *, uint_t *, uint_t *); #define CPUSET_ALL(set) cpuset_all(&(set)) #define CPUSET_ALL_BUT(set, cpu) cpuset_all_but(&(set), cpu) #define CPUSET_ONLY(set, cpu) cpuset_only(&(set), cpu) #define CPU_IN_SET(set, cpu) BT_TEST((set).cpub, cpu) #define CPUSET_ADD(set, cpu) BT_SET((set).cpub, cpu) #define CPUSET_DEL(set, cpu) BT_CLEAR((set).cpub, cpu) #define CPUSET_ISNULL(set) cpuset_isnull(&(set)) #define CPUSET_ISEQUAL(set1, set2) cpuset_cmp(&(set1), &(set2)) /* * Find one CPU in the cpuset. * Sets "cpu" to the id of the found CPU, or CPUSET_NOTINSET if no cpu * could be found. (i.e. empty set) */ #define CPUSET_FIND(set, cpu) { \ cpu = cpuset_find(&(set)); \ } /* * Determine the smallest and largest CPU id in the set. Returns * CPUSET_NOTINSET in smallest and largest when set is empty. */ #define CPUSET_BOUNDS(set, smallest, largest) { \ cpuset_bounds(&(set), &(smallest), &(largest)); \ } /* * Atomic cpuset operations * These are safe to use for concurrent cpuset manipulations. * "xdel" and "xadd" are exclusive operations, that set "result" to "0" * if the add or del was successful, or "-1" if not successful. * (e.g. attempting to add a cpu to a cpuset that's already there, or * deleting a cpu that's not in the cpuset) */ #define CPUSET_ATOMIC_DEL(set, cpu) BT_ATOMIC_CLEAR((set).cpub, (cpu)) #define CPUSET_ATOMIC_ADD(set, cpu) BT_ATOMIC_SET((set).cpub, (cpu)) #define CPUSET_ATOMIC_XADD(set, cpu, result) \ BT_ATOMIC_SET_EXCL((set).cpub, cpu, result) #define CPUSET_ATOMIC_XDEL(set, cpu, result) \ BT_ATOMIC_CLEAR_EXCL((set).cpub, cpu, result) #define CPUSET_OR(set1, set2) { \ int _i; \ for (_i = 0; _i < CPUSET_WORDS; _i++) \ (set1).cpub[_i] |= (set2).cpub[_i]; \ } #define CPUSET_XOR(set1, set2) { \ int _i; \ for (_i = 0; _i < CPUSET_WORDS; _i++) \ (set1).cpub[_i] ^= (set2).cpub[_i]; \ } #define CPUSET_AND(set1, set2) { \ int _i; \ for (_i = 0; _i < CPUSET_WORDS; _i++) \ (set1).cpub[_i] &= (set2).cpub[_i]; \ } #define CPUSET_ZERO(set) { \ int _i; \ for (_i = 0; _i < CPUSET_WORDS; _i++) \ (set).cpub[_i] = 0; \ } #elif CPUSET_WORDS == 1 typedef ulong_t cpuset_t; /* a set of CPUs */ #define CPUSET(cpu) (1UL << (cpu)) #define CPUSET_ALL(set) ((void)((set) = ~0UL)) #define CPUSET_ALL_BUT(set, cpu) ((void)((set) = ~CPUSET(cpu))) #define CPUSET_ONLY(set, cpu) ((void)((set) = CPUSET(cpu))) #define CPU_IN_SET(set, cpu) ((set) & CPUSET(cpu)) #define CPUSET_ADD(set, cpu) ((void)((set) |= CPUSET(cpu))) #define CPUSET_DEL(set, cpu) ((void)((set) &= ~CPUSET(cpu))) #define CPUSET_ISNULL(set) ((set) == 0) #define CPUSET_ISEQUAL(set1, set2) ((set1) == (set2)) #define CPUSET_OR(set1, set2) ((void)((set1) |= (set2))) #define CPUSET_XOR(set1, set2) ((void)((set1) ^= (set2))) #define CPUSET_AND(set1, set2) ((void)((set1) &= (set2))) #define CPUSET_ZERO(set) ((void)((set) = 0)) #define CPUSET_FIND(set, cpu) { \ cpu = (uint_t)(lowbit(set) - 1); \ } #define CPUSET_BOUNDS(set, smallest, largest) { \ smallest = (uint_t)(lowbit(set) - 1); \ largest = (uint_t)(highbit(set) - 1); \ } #define CPUSET_ATOMIC_DEL(set, cpu) atomic_and_long(&(set), ~CPUSET(cpu)) #define CPUSET_ATOMIC_ADD(set, cpu) atomic_or_long(&(set), CPUSET(cpu)) #define CPUSET_ATOMIC_XADD(set, cpu, result) \ { result = atomic_set_long_excl(&(set), (cpu)); } #define CPUSET_ATOMIC_XDEL(set, cpu, result) \ { result = atomic_clear_long_excl(&(set), (cpu)); } #else /* CPUSET_WORDS <= 0 */ #error NCPU is undefined or invalid #endif /* CPUSET_WORDS */ extern cpuset_t cpu_seqid_inuse; #endif /* (_KERNEL || _KMEMUSER) && _MACHDEP */ #define CPU_CPR_OFFLINE 0x0 #define CPU_CPR_ONLINE 0x1 #define CPU_CPR_IS_OFFLINE(cpu) (((cpu)->cpu_cpr_flags & CPU_CPR_ONLINE) == 0) #define CPU_CPR_IS_ONLINE(cpu) ((cpu)->cpu_cpr_flags & CPU_CPR_ONLINE) #define CPU_SET_CPR_FLAGS(cpu, flag) ((cpu)->cpu_cpr_flags |= flag) #if defined(_KERNEL) || defined(_KMEMUSER) extern struct cpu *cpu[]; /* indexed by CPU number */ extern cpu_t *cpu_list; /* list of CPUs */ extern cpu_t *cpu_active; /* list of active CPUs */ extern int ncpus; /* number of CPUs present */ extern int ncpus_online; /* number of CPUs not quiesced */ extern int max_ncpus; /* max present before ncpus is known */ extern int boot_max_ncpus; /* like max_ncpus but for real */ extern processorid_t max_cpuid; /* maximum CPU number */ extern struct cpu *cpu_inmotion; /* offline or partition move target */ extern cpu_t *clock_cpu_list; #if defined(__i386) || defined(__amd64) extern struct cpu *curcpup(void); #define CPU (curcpup()) /* Pointer to current CPU */ #else #define CPU (curthread->t_cpu) /* Pointer to current CPU */ #endif /* * CPU_CURRENT indicates to thread_affinity_set to use CPU->cpu_id * as the target and to grab cpu_lock instead of requiring the caller * to grab it. */ #define CPU_CURRENT -3 /* * Per-CPU statistics * * cpu_stats_t contains numerous system and VM-related statistics, in the form * of gauges or monotonically-increasing event occurrence counts. */ #define CPU_STATS_ENTER_K() kpreempt_disable() #define CPU_STATS_EXIT_K() kpreempt_enable() #define CPU_STATS_ADD_K(class, stat, amount) \ { kpreempt_disable(); /* keep from switching CPUs */\ CPU_STATS_ADDQ(CPU, class, stat, amount); \ kpreempt_enable(); \ } #define CPU_STATS_ADDQ(cp, class, stat, amount) { \ extern void __dtrace_probe___cpu_##class##info_##stat(uint_t, \ uint64_t *, cpu_t *); \ uint64_t *stataddr = &((cp)->cpu_stats.class.stat); \ __dtrace_probe___cpu_##class##info_##stat((amount), \ stataddr, cp); \ *(stataddr) += (amount); \ } #define CPU_STATS(cp, stat) \ ((cp)->cpu_stats.stat) #endif /* _KERNEL || _KMEMUSER */ /* * CPU support routines. */ #if defined(_KERNEL) && defined(__STDC__) /* not for genassym.c */ struct zone; void cpu_list_init(cpu_t *); void cpu_add_unit(cpu_t *); void cpu_del_unit(int cpuid); void cpu_add_active(cpu_t *); void cpu_kstat_init(cpu_t *); void cpu_visibility_add(cpu_t *, struct zone *); void cpu_visibility_remove(cpu_t *, struct zone *); void cpu_visibility_configure(cpu_t *, struct zone *); void cpu_visibility_unconfigure(cpu_t *, struct zone *); void cpu_visibility_online(cpu_t *, struct zone *); void cpu_visibility_offline(cpu_t *, struct zone *); void cpu_create_intrstat(cpu_t *); void cpu_delete_intrstat(cpu_t *); int cpu_kstat_intrstat_update(kstat_t *, int); void cpu_intr_swtch_enter(kthread_t *); void cpu_intr_swtch_exit(kthread_t *); void mbox_lock_init(void); /* initialize cross-call locks */ void mbox_init(int cpun); /* initialize cross-calls */ void poke_cpu(int cpun); /* interrupt another CPU (to preempt) */ /* * values for safe_list. Pause state that CPUs are in. */ #define PAUSE_IDLE 0 /* normal state */ #define PAUSE_READY 1 /* paused thread ready to spl */ #define PAUSE_WAIT 2 /* paused thread is spl-ed high */ #define PAUSE_DIE 3 /* tell pause thread to leave */ #define PAUSE_DEAD 4 /* pause thread has left */ void mach_cpu_pause(volatile char *); void pause_cpus(cpu_t *off_cp); void start_cpus(void); int cpus_paused(void); void cpu_pause_init(void); cpu_t *cpu_get(processorid_t cpun); /* get the CPU struct associated */ int cpu_online(cpu_t *cp); /* take cpu online */ int cpu_offline(cpu_t *cp, int flags); /* take cpu offline */ int cpu_spare(cpu_t *cp, int flags); /* take cpu to spare */ int cpu_faulted(cpu_t *cp, int flags); /* take cpu to faulted */ int cpu_poweron(cpu_t *cp); /* take powered-off cpu to offline */ int cpu_poweroff(cpu_t *cp); /* take offline cpu to powered-off */ cpu_t *cpu_intr_next(cpu_t *cp); /* get next online CPU taking intrs */ int cpu_intr_count(cpu_t *cp); /* count # of CPUs handling intrs */ int cpu_intr_on(cpu_t *cp); /* CPU taking I/O interrupts? */ void cpu_intr_enable(cpu_t *cp); /* enable I/O interrupts */ int cpu_intr_disable(cpu_t *cp); /* disable I/O interrupts */ void cpu_intr_alloc(cpu_t *cp, int n); /* allocate interrupt threads */ /* * Routines for checking CPU states. */ int cpu_is_online(cpu_t *); /* check if CPU is online */ int cpu_is_nointr(cpu_t *); /* check if CPU can service intrs */ int cpu_is_active(cpu_t *); /* check if CPU can run threads */ int cpu_is_offline(cpu_t *); /* check if CPU is offline */ int cpu_is_poweredoff(cpu_t *); /* check if CPU is powered off */ int cpu_flagged_online(cpu_flag_t); /* flags show CPU is online */ int cpu_flagged_nointr(cpu_flag_t); /* flags show CPU not handling intrs */ int cpu_flagged_active(cpu_flag_t); /* flags show CPU scheduling threads */ int cpu_flagged_offline(cpu_flag_t); /* flags show CPU is offline */ int cpu_flagged_poweredoff(cpu_flag_t); /* flags show CPU is powered off */ /* * The processor_info(2) state of a CPU is a simplified representation suitable * for use by an application program. Kernel subsystems should utilize the * internal per-CPU state as given by the cpu_flags member of the cpu structure, * as this information may include platform- or architecture-specific state * critical to a subsystem's disposition of a particular CPU. */ void cpu_set_state(cpu_t *); /* record/timestamp current state */ int cpu_get_state(cpu_t *); /* get current cpu state */ const char *cpu_get_state_str(cpu_t *); /* get current cpu state as string */ void cpu_set_supp_freqs(cpu_t *, const char *); /* set the CPU supported */ /* frequencies */ int cpu_configure(int); int cpu_unconfigure(int); void cpu_destroy_bound_threads(cpu_t *cp); extern int cpu_bind_thread(kthread_t *tp, processorid_t bind, processorid_t *obind, int *error); -extern int cpu_unbind(processorid_t cpu_id); +extern int cpu_unbind(processorid_t cpu_id, boolean_t force); extern void thread_affinity_set(kthread_t *t, int cpu_id); extern void thread_affinity_clear(kthread_t *t); extern void affinity_set(int cpu_id); extern void affinity_clear(void); extern void init_cpu_mstate(struct cpu *, int); extern void term_cpu_mstate(struct cpu *); extern void new_cpu_mstate(int, hrtime_t); extern void get_cpu_mstate(struct cpu *, hrtime_t *); extern void thread_nomigrate(void); extern void thread_allowmigrate(void); extern void weakbinding_stop(void); extern void weakbinding_start(void); /* * The following routines affect the CPUs participation in interrupt processing, * if that is applicable on the architecture. This only affects interrupts * which aren't directed at the processor (not cross calls). * * cpu_disable_intr returns non-zero if interrupts were previously enabled. */ int cpu_disable_intr(struct cpu *cp); /* stop issuing interrupts to cpu */ void cpu_enable_intr(struct cpu *cp); /* start issuing interrupts to cpu */ /* * The mutex cpu_lock protects cpu_flags for all CPUs, as well as the ncpus * and ncpus_online counts. */ extern kmutex_t cpu_lock; /* lock protecting CPU data */ typedef enum { CPU_INIT, CPU_CONFIG, CPU_UNCONFIG, CPU_ON, CPU_OFF, CPU_CPUPART_IN, CPU_CPUPART_OUT } cpu_setup_t; typedef int cpu_setup_func_t(cpu_setup_t, int, void *); /* * Routines used to register interest in cpu's being added to or removed * from the system. */ extern void register_cpu_setup_func(cpu_setup_func_t *, void *); extern void unregister_cpu_setup_func(cpu_setup_func_t *, void *); extern void cpu_state_change_notify(int, cpu_setup_t); /* * Create various strings that describe the given CPU for the * processor_info system call and configuration-related kstats. */ #define CPU_IDSTRLEN 100 extern void init_cpu_info(struct cpu *); extern void cpu_vm_data_init(struct cpu *); extern void cpu_vm_data_destroy(struct cpu *); #endif /* _KERNEL */ #ifdef __cplusplus } #endif #endif /* _SYS_CPUVAR_H */ Index: head/sys/cddl/contrib/opensolaris/uts/common/sys/ctf.h =================================================================== --- head/sys/cddl/contrib/opensolaris/uts/common/sys/ctf.h (revision 179197) +++ head/sys/cddl/contrib/opensolaris/uts/common/sys/ctf.h (revision 179198) @@ -1,358 +1,360 @@ /* * CDDL HEADER START * * The contents of this file are subject to the terms of the * Common Development and Distribution License, Version 1.0 only * (the "License"). You may not use this file except in compliance * with the License. * * You can obtain a copy of the license at usr/src/OPENSOLARIS.LICENSE * or http://www.opensolaris.org/os/licensing. * See the License for the specific language governing permissions * and limitations under the License. * * When distributing Covered Code, include this CDDL HEADER in each * file and include the License file at usr/src/OPENSOLARIS.LICENSE. * If applicable, add the following below this CDDL HEADER, with the * fields enclosed by brackets "[]" replaced with your own identifying * information: Portions Copyright [yyyy] [name of copyright owner] * * CDDL HEADER END */ /* * Copyright 2004 Sun Microsystems, Inc. All rights reserved. * Use is subject to license terms. */ #ifndef _CTF_H #define _CTF_H +#if defined(sun) #pragma ident "%Z%%M% %I% %E% SMI" +#endif #include #ifdef __cplusplus extern "C" { #endif /* * CTF - Compact ANSI-C Type Format * * This file format can be used to compactly represent the information needed * by a debugger to interpret the ANSI-C types used by a given program. * Traditionally, this kind of information is generated by the compiler when * invoked with the -g flag and is stored in "stabs" strings or in the more * modern DWARF format. CTF provides a representation of only the information * that is relevant to debugging a complex, optimized C program such as the * operating system kernel in a form that is significantly more compact than * the equivalent stabs or DWARF representation. The format is data-model * independent, so consumers do not need different code depending on whether * they are 32-bit or 64-bit programs. CTF assumes that a standard ELF symbol * table is available for use in the debugger, and uses the structure and data * of the symbol table to avoid storing redundant information. The CTF data * may be compressed on disk or in memory, indicated by a bit in the header. * CTF may be interpreted in a raw disk file, or it may be stored in an ELF * section, typically named .SUNW_ctf. Data structures are aligned so that * a raw CTF file or CTF ELF section may be manipulated using mmap(2). * * The CTF file or section itself has the following structure: * * +--------+--------+---------+----------+-------+--------+ * | file | type | data | function | data | string | * | header | labels | objects | info | types | table | * +--------+--------+---------+----------+-------+--------+ * * The file header stores a magic number and version information, encoding * flags, and the byte offset of each of the sections relative to the end of the * header itself. If the CTF data has been uniquified against another set of * CTF data, a reference to that data also appears in the the header. This * reference is the name of the label corresponding to the types uniquified * against. * * Following the header is a list of labels, used to group the types included in * the data types section. Each label is accompanied by a type ID i. A given * label refers to the group of types whose IDs are in the range [0, i]. * * Data object and function records are stored in the same order as they appear * in the corresponding symbol table, except that symbols marked SHN_UNDEF are * not stored and symbols that have no type data are padded out with zeroes. * For each data object, the type ID (a small integer) is recorded. For each * function, the type ID of the return type and argument types is recorded. * * The data types section is a list of variable size records that represent each * type, in order by their ID. The types themselves form a directed graph, * where each node may contain one or more outgoing edges to other type nodes, * denoted by their ID. * * Strings are recorded as a string table ID (0 or 1) and a byte offset into the * string table. String table 0 is the internal CTF string table. String table * 1 is the external string table, which is the string table associated with the * ELF symbol table for this object. CTF does not record any strings that are * already in the symbol table, and the CTF string table does not contain any * duplicated strings. * * If the CTF data has been merged with another parent CTF object, some outgoing * edges may refer to type nodes that exist in another CTF object. The debugger * and libctf library are responsible for connecting the appropriate objects * together so that the full set of types can be explored and manipulated. */ #define CTF_MAX_TYPE 0xffff /* max type identifier value */ #define CTF_MAX_NAME 0x7fffffff /* max offset into a string table */ #define CTF_MAX_VLEN 0x3ff /* max struct, union, enum members or args */ #define CTF_MAX_INTOFF 0xff /* max offset of intrinsic value in bits */ #define CTF_MAX_INTBITS 0xffff /* max size of an intrinsic in bits */ /* See ctf_type_t */ #define CTF_MAX_SIZE 0xfffe /* max size of a type in bytes */ #define CTF_LSIZE_SENT 0xffff /* sentinel for ctt_size */ #define CTF_MAX_LSIZE UINT64_MAX typedef struct ctf_preamble { ushort_t ctp_magic; /* magic number (CTF_MAGIC) */ uchar_t ctp_version; /* data format version number (CTF_VERSION) */ uchar_t ctp_flags; /* flags (see below) */ } ctf_preamble_t; typedef struct ctf_header { ctf_preamble_t cth_preamble; uint_t cth_parlabel; /* ref to name of parent lbl uniq'd against */ uint_t cth_parname; /* ref to basename of parent */ uint_t cth_lbloff; /* offset of label section */ uint_t cth_objtoff; /* offset of object section */ uint_t cth_funcoff; /* offset of function section */ uint_t cth_typeoff; /* offset of type section */ uint_t cth_stroff; /* offset of string section */ uint_t cth_strlen; /* length of string section in bytes */ } ctf_header_t; #define cth_magic cth_preamble.ctp_magic #define cth_version cth_preamble.ctp_version #define cth_flags cth_preamble.ctp_flags #ifdef CTF_OLD_VERSIONS typedef struct ctf_header_v1 { ctf_preamble_t cth_preamble; uint_t cth_objtoff; uint_t cth_funcoff; uint_t cth_typeoff; uint_t cth_stroff; uint_t cth_strlen; } ctf_header_v1_t; #endif /* CTF_OLD_VERSIONS */ #define CTF_MAGIC 0xcff1 /* magic number identifying header */ /* data format version number */ #define CTF_VERSION_1 1 #define CTF_VERSION_2 2 #define CTF_VERSION CTF_VERSION_2 /* current version */ #define CTF_F_COMPRESS 0x1 /* data buffer is compressed */ typedef struct ctf_lblent { uint_t ctl_label; /* ref to name of label */ uint_t ctl_typeidx; /* last type associated with this label */ } ctf_lblent_t; typedef struct ctf_stype { uint_t ctt_name; /* reference to name in string table */ ushort_t ctt_info; /* encoded kind, variant length (see below) */ union { ushort_t _size; /* size of entire type in bytes */ ushort_t _type; /* reference to another type */ } _u; } ctf_stype_t; /* * type sizes, measured in bytes, come in two flavors. 99% of them fit within * (USHRT_MAX - 1), and thus can be stored in the ctt_size member of a * ctf_stype_t. The maximum value for these sizes is CTF_MAX_SIZE. The sizes * larger than CTF_MAX_SIZE must be stored in the ctt_lsize member of a * ctf_type_t. Use of this member is indicated by the presence of * CTF_LSIZE_SENT in ctt_size. */ typedef struct ctf_type { uint_t ctt_name; /* reference to name in string table */ ushort_t ctt_info; /* encoded kind, variant length (see below) */ union { ushort_t _size; /* always CTF_LSIZE_SENT */ ushort_t _type; /* do not use */ } _u; uint_t ctt_lsizehi; /* high 32 bits of type size in bytes */ uint_t ctt_lsizelo; /* low 32 bits of type size in bytes */ } ctf_type_t; #define ctt_size _u._size /* for fundamental types that have a size */ #define ctt_type _u._type /* for types that reference another type */ /* * The following macros compose and decompose values for ctt_info and * ctt_name, as well as other structures that contain name references. * * ------------------------ * ctt_info: | kind | isroot | vlen | * ------------------------ * 15 11 10 9 0 * * kind = CTF_INFO_KIND(c.ctt_info); <-- CTF_K_* value (see below) * vlen = CTF_INFO_VLEN(c.ctt_info); <-- length of variable data list * * stid = CTF_NAME_STID(c.ctt_name); <-- string table id number (0 or 1) * offset = CTF_NAME_OFFSET(c.ctt_name); <-- string table byte offset * * c.ctt_info = CTF_TYPE_INFO(kind, vlen); * c.ctt_name = CTF_TYPE_NAME(stid, offset); */ #define CTF_INFO_KIND(info) (((info) & 0xf800) >> 11) #define CTF_INFO_ISROOT(info) (((info) & 0x0400) >> 10) #define CTF_INFO_VLEN(info) (((info) & CTF_MAX_VLEN)) #define CTF_NAME_STID(name) ((name) >> 31) #define CTF_NAME_OFFSET(name) ((name) & 0x7fffffff) #define CTF_TYPE_INFO(kind, isroot, vlen) \ (((kind) << 11) | (((isroot) ? 1 : 0) << 10) | ((vlen) & CTF_MAX_VLEN)) #define CTF_TYPE_NAME(stid, offset) \ (((stid) << 31) | ((offset) & 0x7fffffff)) #define CTF_TYPE_ISPARENT(id) ((id) < 0x8000) #define CTF_TYPE_ISCHILD(id) ((id) > 0x7fff) #define CTF_TYPE_TO_INDEX(id) ((id) & 0x7fff) #define CTF_INDEX_TO_TYPE(id, child) ((child) ? ((id) | 0x8000) : (id)) #define CTF_PARENT_SHIFT 15 #define CTF_STRTAB_0 0 /* symbolic define for string table id 0 */ #define CTF_STRTAB_1 1 /* symbolic define for string table id 1 */ #define CTF_TYPE_LSIZE(cttp) \ (((uint64_t)(cttp)->ctt_lsizehi) << 32 | (cttp)->ctt_lsizelo) #define CTF_SIZE_TO_LSIZE_HI(size) ((uint32_t)((uint64_t)(size) >> 32)) #define CTF_SIZE_TO_LSIZE_LO(size) ((uint32_t)(size)) #ifdef CTF_OLD_VERSIONS #define CTF_INFO_KIND_V1(info) (((info) & 0xf000) >> 12) #define CTF_INFO_ISROOT_V1(info) (((info) & 0x0800) >> 11) #define CTF_INFO_VLEN_V1(info) (((info) & 0x07ff)) #define CTF_TYPE_INFO_V1(kind, isroot, vlen) \ (((kind) << 12) | (((isroot) ? 1 : 0) << 11) | ((vlen) & 0x07ff)) #endif /* CTF_OLD_VERSIONS */ /* * Values for CTF_TYPE_KIND(). If the kind has an associated data list, * CTF_INFO_VLEN() will extract the number of elements in the list, and * the type of each element is shown in the comments below. */ #define CTF_K_UNKNOWN 0 /* unknown type (used for padding) */ #define CTF_K_INTEGER 1 /* variant data is CTF_INT_DATA() (see below) */ #define CTF_K_FLOAT 2 /* variant data is CTF_FP_DATA() (see below) */ #define CTF_K_POINTER 3 /* ctt_type is referenced type */ #define CTF_K_ARRAY 4 /* variant data is single ctf_array_t */ #define CTF_K_FUNCTION 5 /* ctt_type is return type, variant data is */ /* list of argument types (ushort_t's) */ #define CTF_K_STRUCT 6 /* variant data is list of ctf_member_t's */ #define CTF_K_UNION 7 /* variant data is list of ctf_member_t's */ #define CTF_K_ENUM 8 /* variant data is list of ctf_enum_t's */ #define CTF_K_FORWARD 9 /* no additional data; ctt_name is tag */ #define CTF_K_TYPEDEF 10 /* ctt_type is referenced type */ #define CTF_K_VOLATILE 11 /* ctt_type is base type */ #define CTF_K_CONST 12 /* ctt_type is base type */ #define CTF_K_RESTRICT 13 /* ctt_type is base type */ #define CTF_K_MAX 31 /* Maximum possible CTF_K_* value */ /* * Values for ctt_type when kind is CTF_K_INTEGER. The flags, offset in bits, * and size in bits are encoded as a single word using the following macros. */ #define CTF_INT_ENCODING(data) (((data) & 0xff000000) >> 24) #define CTF_INT_OFFSET(data) (((data) & 0x00ff0000) >> 16) #define CTF_INT_BITS(data) (((data) & 0x0000ffff)) #define CTF_INT_DATA(encoding, offset, bits) \ (((encoding) << 24) | ((offset) << 16) | (bits)) #define CTF_INT_SIGNED 0x01 /* integer is signed (otherwise unsigned) */ #define CTF_INT_CHAR 0x02 /* character display format */ #define CTF_INT_BOOL 0x04 /* boolean display format */ #define CTF_INT_VARARGS 0x08 /* varargs display format */ /* * Values for ctt_type when kind is CTF_K_FLOAT. The encoding, offset in bits, * and size in bits are encoded as a single word using the following macros. */ #define CTF_FP_ENCODING(data) (((data) & 0xff000000) >> 24) #define CTF_FP_OFFSET(data) (((data) & 0x00ff0000) >> 16) #define CTF_FP_BITS(data) (((data) & 0x0000ffff)) #define CTF_FP_DATA(encoding, offset, bits) \ (((encoding) << 24) | ((offset) << 16) | (bits)) #define CTF_FP_SINGLE 1 /* IEEE 32-bit float encoding */ #define CTF_FP_DOUBLE 2 /* IEEE 64-bit float encoding */ #define CTF_FP_CPLX 3 /* Complex encoding */ #define CTF_FP_DCPLX 4 /* Double complex encoding */ #define CTF_FP_LDCPLX 5 /* Long double complex encoding */ #define CTF_FP_LDOUBLE 6 /* Long double encoding */ #define CTF_FP_INTRVL 7 /* Interval (2x32-bit) encoding */ #define CTF_FP_DINTRVL 8 /* Double interval (2x64-bit) encoding */ #define CTF_FP_LDINTRVL 9 /* Long double interval (2x128-bit) encoding */ #define CTF_FP_IMAGRY 10 /* Imaginary (32-bit) encoding */ #define CTF_FP_DIMAGRY 11 /* Long imaginary (64-bit) encoding */ #define CTF_FP_LDIMAGRY 12 /* Long double imaginary (128-bit) encoding */ #define CTF_FP_MAX 12 /* Maximum possible CTF_FP_* value */ typedef struct ctf_array { ushort_t cta_contents; /* reference to type of array contents */ ushort_t cta_index; /* reference to type of array index */ uint_t cta_nelems; /* number of elements */ } ctf_array_t; /* * Most structure members have bit offsets that can be expressed using a * short. Some don't. ctf_member_t is used for structs which cannot * contain any of these large offsets, whereas ctf_lmember_t is used in the * latter case. If ctt_size for a given struct is >= 8192 bytes, all members * will be stored as type ctf_lmember_t. */ #define CTF_LSTRUCT_THRESH 8192 typedef struct ctf_member { uint_t ctm_name; /* reference to name in string table */ ushort_t ctm_type; /* reference to type of member */ ushort_t ctm_offset; /* offset of this member in bits */ } ctf_member_t; typedef struct ctf_lmember { uint_t ctlm_name; /* reference to name in string table */ ushort_t ctlm_type; /* reference to type of member */ ushort_t ctlm_pad; /* padding */ uint_t ctlm_offsethi; /* high 32 bits of member offset in bits */ uint_t ctlm_offsetlo; /* low 32 bits of member offset in bits */ } ctf_lmember_t; #define CTF_LMEM_OFFSET(ctlmp) \ (((uint64_t)(ctlmp)->ctlm_offsethi) << 32 | (ctlmp)->ctlm_offsetlo) #define CTF_OFFSET_TO_LMEMHI(offset) ((uint32_t)((uint64_t)(offset) >> 32)) #define CTF_OFFSET_TO_LMEMLO(offset) ((uint32_t)(offset)) typedef struct ctf_enum { uint_t cte_name; /* reference to name in string table */ int cte_value; /* value associated with this name */ } ctf_enum_t; #ifdef __cplusplus } #endif #endif /* _CTF_H */ Index: head/sys/cddl/contrib/opensolaris/uts/common/sys/ctf_api.h =================================================================== --- head/sys/cddl/contrib/opensolaris/uts/common/sys/ctf_api.h (revision 179197) +++ head/sys/cddl/contrib/opensolaris/uts/common/sys/ctf_api.h (revision 179198) @@ -1,241 +1,245 @@ /* * CDDL HEADER START * * The contents of this file are subject to the terms of the * Common Development and Distribution License, Version 1.0 only * (the "License"). You may not use this file except in compliance * with the License. * * You can obtain a copy of the license at usr/src/OPENSOLARIS.LICENSE * or http://www.opensolaris.org/os/licensing. * See the License for the specific language governing permissions * and limitations under the License. * * When distributing Covered Code, include this CDDL HEADER in each * file and include the License file at usr/src/OPENSOLARIS.LICENSE. * If applicable, add the following below this CDDL HEADER, with the * fields enclosed by brackets "[]" replaced with your own identifying * information: Portions Copyright [yyyy] [name of copyright owner] * * CDDL HEADER END */ /* * Copyright 2005 Sun Microsystems, Inc. All rights reserved. * Use is subject to license terms. */ /* * This header file defines the interfaces available from the CTF debugger * library, libctf, and an equivalent kernel module. This API can be used by * a debugger to operate on data in the Compact ANSI-C Type Format (CTF). * This is NOT a public interface, although it may eventually become one in * the fullness of time after we gain more experience with the interfaces. * * In the meantime, be aware that any program linked with this API in this * release of Solaris is almost guaranteed to break in the next release. * * In short, do not user this header file or the CTF routines for any purpose. */ #ifndef _CTF_API_H #define _CTF_API_H #pragma ident "%Z%%M% %I% %E% SMI" #include #include #include #include #ifdef __cplusplus extern "C" { #endif /* * Clients can open one or more CTF containers and obtain a pointer to an * opaque ctf_file_t. Types are identified by an opaque ctf_id_t token. * These opaque definitions allow libctf to evolve without breaking clients. */ typedef struct ctf_file ctf_file_t; typedef long ctf_id_t; /* * If the debugger needs to provide the CTF library with a set of raw buffers * for use as the CTF data, symbol table, and string table, it can do so by * filling in ctf_sect_t structures and passing them to ctf_bufopen(): */ typedef struct ctf_sect { - const char *cts_name; /* section name (if any) */ + char *cts_name; /* section name (if any) */ ulong_t cts_type; /* section type (ELF SHT_... value) */ ulong_t cts_flags; /* section flags (ELF SHF_... value) */ +#if defined(sun) const void *cts_data; /* pointer to section data */ +#else + void *cts_data; /* pointer to section data */ +#endif size_t cts_size; /* size of data in bytes */ size_t cts_entsize; /* size of each section entry (symtab only) */ off64_t cts_offset; /* file offset of this section (if any) */ } ctf_sect_t; /* * Encoding information for integers, floating-point values, and certain other * intrinsics can be obtained by calling ctf_type_encoding(), below. The flags * field will contain values appropriate for the type defined in . */ typedef struct ctf_encoding { uint_t cte_format; /* data format (CTF_INT_* or CTF_FP_* flags) */ uint_t cte_offset; /* offset of value in bits */ uint_t cte_bits; /* size of storage in bits */ } ctf_encoding_t; typedef struct ctf_membinfo { ctf_id_t ctm_type; /* type of struct or union member */ ulong_t ctm_offset; /* offset of member in bits */ } ctf_membinfo_t; typedef struct ctf_arinfo { ctf_id_t ctr_contents; /* type of array contents */ ctf_id_t ctr_index; /* type of array index */ uint_t ctr_nelems; /* number of elements */ } ctf_arinfo_t; typedef struct ctf_funcinfo { ctf_id_t ctc_return; /* function return type */ uint_t ctc_argc; /* number of typed arguments to function */ uint_t ctc_flags; /* function attributes (see below) */ } ctf_funcinfo_t; typedef struct ctf_lblinfo { ctf_id_t ctb_typeidx; /* last type associated with the label */ } ctf_lblinfo_t; #define CTF_FUNC_VARARG 0x1 /* function arguments end with varargs */ /* * Functions that return integer status or a ctf_id_t use the following value * to indicate failure. ctf_errno() can be used to obtain an error code. */ #define CTF_ERR (-1L) /* * The CTF data model is inferred to be the caller's data model or the data * model of the given object, unless ctf_setmodel() is explicitly called. */ #define CTF_MODEL_ILP32 1 /* object data model is ILP32 */ #define CTF_MODEL_LP64 2 /* object data model is LP64 */ #ifdef _LP64 #define CTF_MODEL_NATIVE CTF_MODEL_LP64 #else #define CTF_MODEL_NATIVE CTF_MODEL_ILP32 #endif /* * Dynamic CTF containers can be created using ctf_create(). The ctf_add_* * routines can be used to add new definitions to the dynamic container. * New types are labeled as root or non-root to determine whether they are * visible at the top-level program scope when subsequently doing a lookup. */ #define CTF_ADD_NONROOT 0 /* type only visible in nested scope */ #define CTF_ADD_ROOT 1 /* type visible at top-level scope */ /* * These typedefs are used to define the signature for callback functions * that can be used with the iteration and visit functions below: */ typedef int ctf_visit_f(const char *, ctf_id_t, ulong_t, int, void *); typedef int ctf_member_f(const char *, ctf_id_t, ulong_t, void *); typedef int ctf_enum_f(const char *, int, void *); typedef int ctf_type_f(ctf_id_t, void *); typedef int ctf_label_f(const char *, const ctf_lblinfo_t *, void *); extern ctf_file_t *ctf_bufopen(const ctf_sect_t *, const ctf_sect_t *, const ctf_sect_t *, int *); extern ctf_file_t *ctf_fdopen(int, int *); extern ctf_file_t *ctf_open(const char *, int *); extern ctf_file_t *ctf_create(int *); extern void ctf_close(ctf_file_t *); extern ctf_file_t *ctf_parent_file(ctf_file_t *); extern const char *ctf_parent_name(ctf_file_t *); extern int ctf_import(ctf_file_t *, ctf_file_t *); extern int ctf_setmodel(ctf_file_t *, int); extern int ctf_getmodel(ctf_file_t *); extern void ctf_setspecific(ctf_file_t *, void *); extern void *ctf_getspecific(ctf_file_t *); extern int ctf_errno(ctf_file_t *); extern const char *ctf_errmsg(int); extern int ctf_version(int); extern int ctf_func_info(ctf_file_t *, ulong_t, ctf_funcinfo_t *); extern int ctf_func_args(ctf_file_t *, ulong_t, uint_t, ctf_id_t *); extern ctf_id_t ctf_lookup_by_name(ctf_file_t *, const char *); extern ctf_id_t ctf_lookup_by_symbol(ctf_file_t *, ulong_t); extern ctf_id_t ctf_type_resolve(ctf_file_t *, ctf_id_t); extern ssize_t ctf_type_lname(ctf_file_t *, ctf_id_t, char *, size_t); extern char *ctf_type_name(ctf_file_t *, ctf_id_t, char *, size_t); extern ssize_t ctf_type_size(ctf_file_t *, ctf_id_t); extern ssize_t ctf_type_align(ctf_file_t *, ctf_id_t); extern int ctf_type_kind(ctf_file_t *, ctf_id_t); extern ctf_id_t ctf_type_reference(ctf_file_t *, ctf_id_t); extern ctf_id_t ctf_type_pointer(ctf_file_t *, ctf_id_t); extern int ctf_type_encoding(ctf_file_t *, ctf_id_t, ctf_encoding_t *); extern int ctf_type_visit(ctf_file_t *, ctf_id_t, ctf_visit_f *, void *); extern int ctf_type_cmp(ctf_file_t *, ctf_id_t, ctf_file_t *, ctf_id_t); extern int ctf_type_compat(ctf_file_t *, ctf_id_t, ctf_file_t *, ctf_id_t); extern int ctf_member_info(ctf_file_t *, ctf_id_t, const char *, ctf_membinfo_t *); extern int ctf_array_info(ctf_file_t *, ctf_id_t, ctf_arinfo_t *); extern const char *ctf_enum_name(ctf_file_t *, ctf_id_t, int); extern int ctf_enum_value(ctf_file_t *, ctf_id_t, const char *, int *); extern const char *ctf_label_topmost(ctf_file_t *); extern int ctf_label_info(ctf_file_t *, const char *, ctf_lblinfo_t *); extern int ctf_member_iter(ctf_file_t *, ctf_id_t, ctf_member_f *, void *); extern int ctf_enum_iter(ctf_file_t *, ctf_id_t, ctf_enum_f *, void *); extern int ctf_type_iter(ctf_file_t *, ctf_type_f *, void *); extern int ctf_label_iter(ctf_file_t *, ctf_label_f *, void *); extern ctf_id_t ctf_add_array(ctf_file_t *, uint_t, const ctf_arinfo_t *); extern ctf_id_t ctf_add_const(ctf_file_t *, uint_t, ctf_id_t); extern ctf_id_t ctf_add_enum(ctf_file_t *, uint_t, const char *); extern ctf_id_t ctf_add_float(ctf_file_t *, uint_t, const char *, const ctf_encoding_t *); extern ctf_id_t ctf_add_forward(ctf_file_t *, uint_t, const char *, uint_t); extern ctf_id_t ctf_add_function(ctf_file_t *, uint_t, const ctf_funcinfo_t *, const ctf_id_t *); extern ctf_id_t ctf_add_integer(ctf_file_t *, uint_t, const char *, const ctf_encoding_t *); extern ctf_id_t ctf_add_pointer(ctf_file_t *, uint_t, ctf_id_t); extern ctf_id_t ctf_add_type(ctf_file_t *, ctf_file_t *, ctf_id_t); extern ctf_id_t ctf_add_typedef(ctf_file_t *, uint_t, const char *, ctf_id_t); extern ctf_id_t ctf_add_restrict(ctf_file_t *, uint_t, ctf_id_t); extern ctf_id_t ctf_add_struct(ctf_file_t *, uint_t, const char *); extern ctf_id_t ctf_add_union(ctf_file_t *, uint_t, const char *); extern ctf_id_t ctf_add_volatile(ctf_file_t *, uint_t, ctf_id_t); extern int ctf_add_enumerator(ctf_file_t *, ctf_id_t, const char *, int); extern int ctf_add_member(ctf_file_t *, ctf_id_t, const char *, ctf_id_t); extern int ctf_set_array(ctf_file_t *, ctf_id_t, const ctf_arinfo_t *); extern int ctf_update(ctf_file_t *); extern int ctf_discard(ctf_file_t *); extern int ctf_write(ctf_file_t *, int); #ifdef _KERNEL struct module; extern ctf_file_t *ctf_modopen(struct module *, int *); #endif #ifdef __cplusplus } #endif #endif /* _CTF_API_H */ Index: head/sys/cddl/contrib/opensolaris/uts/common/sys/debug.h =================================================================== --- head/sys/cddl/contrib/opensolaris/uts/common/sys/debug.h (revision 179197) +++ head/sys/cddl/contrib/opensolaris/uts/common/sys/debug.h (revision 179198) @@ -1,129 +1,129 @@ /* * CDDL HEADER START * * The contents of this file are subject to the terms of the * Common Development and Distribution License, Version 1.0 only * (the "License"). You may not use this file except in compliance * with the License. * * You can obtain a copy of the license at usr/src/OPENSOLARIS.LICENSE * or http://www.opensolaris.org/os/licensing. * See the License for the specific language governing permissions * and limitations under the License. * * When distributing Covered Code, include this CDDL HEADER in each * file and include the License file at usr/src/OPENSOLARIS.LICENSE. * If applicable, add the following below this CDDL HEADER, with the * fields enclosed by brackets "[]" replaced with your own identifying * information: Portions Copyright [yyyy] [name of copyright owner] * * CDDL HEADER END */ /* * Copyright 2005 Sun Microsystems, Inc. All rights reserved. * Use is subject to license terms. */ /* Copyright (c) 1984, 1986, 1987, 1988, 1989 AT&T */ /* All Rights Reserved */ #ifndef _SYS_DEBUG_H #define _SYS_DEBUG_H #pragma ident "%Z%%M% %I% %E% SMI" #include #ifdef __cplusplus extern "C" { #endif /* * ASSERT(ex) causes a panic or debugger entry if expression ex is not * true. ASSERT() is included only for debugging, and is a no-op in * production kernels. VERIFY(ex), on the other hand, behaves like * ASSERT and is evaluated on both debug and non-debug kernels. */ #if defined(__STDC__) extern int assfail(const char *, const char *, int); #define VERIFY(EX) ((void)((EX) || assfail(#EX, __FILE__, __LINE__))) -#if DEBUG +#ifdef DEBUG #define ASSERT(EX) VERIFY(EX) #else #define ASSERT(x) ((void)0) #endif #else /* defined(__STDC__) */ extern int assfail(); #define VERIFY(EX) ((void)((EX) || assfail("EX", __FILE__, __LINE__))) -#if DEBUG +#ifdef DEBUG #define ASSERT(EX) VERIFY(EX) #else #define ASSERT(x) ((void)0) #endif #endif /* defined(__STDC__) */ /* * Assertion variants sensitive to the compilation data model */ #if defined(_LP64) #define ASSERT64(x) ASSERT(x) #define ASSERT32(x) #else #define ASSERT64(x) #define ASSERT32(x) ASSERT(x) #endif /* * ASSERT3() behaves like ASSERT() except that it is an explicit conditional, * and prints out the values of the left and right hand expressions as part of * the panic message to ease debugging. The three variants imply the type * of their arguments. ASSERT3S() is for signed data types, ASSERT3U() is * for unsigned, and ASSERT3P() is for pointers. The VERIFY3*() macros * have the same relationship as above. */ extern void assfail3(const char *, uintmax_t, const char *, uintmax_t, const char *, int); #define VERIFY3_IMPL(LEFT, OP, RIGHT, TYPE) do { \ const TYPE __left = (TYPE)(LEFT); \ const TYPE __right = (TYPE)(RIGHT); \ if (!(__left OP __right)) \ assfail3(#LEFT " " #OP " " #RIGHT, \ (uintmax_t)__left, #OP, (uintmax_t)__right, \ __FILE__, __LINE__); \ _NOTE(CONSTCOND) } while (0) #define VERIFY3S(x, y, z) VERIFY3_IMPL(x, y, z, int64_t) #define VERIFY3U(x, y, z) VERIFY3_IMPL(x, y, z, uint64_t) #define VERIFY3P(x, y, z) VERIFY3_IMPL(x, y, z, uintptr_t) -#if DEBUG +#ifdef DEBUG #define ASSERT3S(x, y, z) VERIFY3S(x, y, z) #define ASSERT3U(x, y, z) VERIFY3U(x, y, z) #define ASSERT3P(x, y, z) VERIFY3P(x, y, z) #else #define ASSERT3S(x, y, z) ((void)0) #define ASSERT3U(x, y, z) ((void)0) #define ASSERT3P(x, y, z) ((void)0) #endif #ifdef _KERNEL extern void abort_sequence_enter(char *); extern void debug_enter(char *); #endif /* _KERNEL */ #if defined(DEBUG) && !defined(__sun) /* CSTYLED */ #define STATIC #else /* CSTYLED */ #define STATIC static #endif #ifdef __cplusplus } #endif #endif /* _SYS_DEBUG_H */ Index: head/sys/cddl/contrib/opensolaris/uts/common/sys/dtrace.h =================================================================== --- head/sys/cddl/contrib/opensolaris/uts/common/sys/dtrace.h (revision 179197) +++ head/sys/cddl/contrib/opensolaris/uts/common/sys/dtrace.h (revision 179198) @@ -1,2242 +1,2309 @@ /* * CDDL HEADER START * * The contents of this file are subject to the terms of the * Common Development and Distribution License (the "License"). * You may not use this file except in compliance with the License. * * You can obtain a copy of the license at usr/src/OPENSOLARIS.LICENSE * or http://www.opensolaris.org/os/licensing. * See the License for the specific language governing permissions * and limitations under the License. * * When distributing Covered Code, include this CDDL HEADER in each * file and include the License file at usr/src/OPENSOLARIS.LICENSE. * If applicable, add the following below this CDDL HEADER, with the * fields enclosed by brackets "[]" replaced with your own identifying * information: Portions Copyright [yyyy] [name of copyright owner] * * CDDL HEADER END */ /* * Copyright 2007 Sun Microsystems, Inc. All rights reserved. * Use is subject to license terms. */ #ifndef _SYS_DTRACE_H #define _SYS_DTRACE_H #pragma ident "%Z%%M% %I% %E% SMI" #ifdef __cplusplus extern "C" { #endif /* * DTrace Dynamic Tracing Software: Kernel Interfaces * * Note: The contents of this file are private to the implementation of the * Solaris system and DTrace subsystem and are subject to change at any time * without notice. Applications and drivers using these interfaces will fail * to run on future releases. These interfaces should not be used for any * purpose except those expressly outlined in dtrace(7D) and libdtrace(3LIB). * Please refer to the "Solaris Dynamic Tracing Guide" for more information. */ #ifndef _ASM #include #include #include +#if defined(sun) #include +#else +#include +#include +#include +#include +typedef int model_t; +#endif #include #include +#if defined(sun) #include +#else +#include +#endif /* * DTrace Universal Constants and Typedefs */ #define DTRACE_CPUALL -1 /* all CPUs */ #define DTRACE_IDNONE 0 /* invalid probe identifier */ #define DTRACE_EPIDNONE 0 /* invalid enabled probe identifier */ #define DTRACE_AGGIDNONE 0 /* invalid aggregation identifier */ #define DTRACE_AGGVARIDNONE 0 /* invalid aggregation variable ID */ #define DTRACE_CACHEIDNONE 0 /* invalid predicate cache */ #define DTRACE_PROVNONE 0 /* invalid provider identifier */ #define DTRACE_METAPROVNONE 0 /* invalid meta-provider identifier */ #define DTRACE_ARGNONE -1 /* invalid argument index */ #define DTRACE_PROVNAMELEN 64 #define DTRACE_MODNAMELEN 64 #define DTRACE_FUNCNAMELEN 128 #define DTRACE_NAMELEN 64 #define DTRACE_FULLNAMELEN (DTRACE_PROVNAMELEN + DTRACE_MODNAMELEN + \ DTRACE_FUNCNAMELEN + DTRACE_NAMELEN + 4) #define DTRACE_ARGTYPELEN 128 typedef uint32_t dtrace_id_t; /* probe identifier */ typedef uint32_t dtrace_epid_t; /* enabled probe identifier */ typedef uint32_t dtrace_aggid_t; /* aggregation identifier */ typedef int64_t dtrace_aggvarid_t; /* aggregation variable identifier */ typedef uint16_t dtrace_actkind_t; /* action kind */ typedef int64_t dtrace_optval_t; /* option value */ typedef uint32_t dtrace_cacheid_t; /* predicate cache identifier */ typedef enum dtrace_probespec { DTRACE_PROBESPEC_NONE = -1, DTRACE_PROBESPEC_PROVIDER = 0, DTRACE_PROBESPEC_MOD, DTRACE_PROBESPEC_FUNC, DTRACE_PROBESPEC_NAME } dtrace_probespec_t; /* * DTrace Intermediate Format (DIF) * * The following definitions describe the DTrace Intermediate Format (DIF), a * a RISC-like instruction set and program encoding used to represent * predicates and actions that can be bound to DTrace probes. The constants * below defining the number of available registers are suggested minimums; the * compiler should use DTRACEIOC_CONF to dynamically obtain the number of * registers provided by the current DTrace implementation. */ #define DIF_VERSION_1 1 /* DIF version 1: Solaris 10 Beta */ #define DIF_VERSION_2 2 /* DIF version 2: Solaris 10 FCS */ #define DIF_VERSION DIF_VERSION_2 /* latest DIF instruction set version */ #define DIF_DIR_NREGS 8 /* number of DIF integer registers */ #define DIF_DTR_NREGS 8 /* number of DIF tuple registers */ #define DIF_OP_OR 1 /* or r1, r2, rd */ #define DIF_OP_XOR 2 /* xor r1, r2, rd */ #define DIF_OP_AND 3 /* and r1, r2, rd */ #define DIF_OP_SLL 4 /* sll r1, r2, rd */ #define DIF_OP_SRL 5 /* srl r1, r2, rd */ #define DIF_OP_SUB 6 /* sub r1, r2, rd */ #define DIF_OP_ADD 7 /* add r1, r2, rd */ #define DIF_OP_MUL 8 /* mul r1, r2, rd */ #define DIF_OP_SDIV 9 /* sdiv r1, r2, rd */ #define DIF_OP_UDIV 10 /* udiv r1, r2, rd */ #define DIF_OP_SREM 11 /* srem r1, r2, rd */ #define DIF_OP_UREM 12 /* urem r1, r2, rd */ #define DIF_OP_NOT 13 /* not r1, rd */ #define DIF_OP_MOV 14 /* mov r1, rd */ #define DIF_OP_CMP 15 /* cmp r1, r2 */ #define DIF_OP_TST 16 /* tst r1 */ #define DIF_OP_BA 17 /* ba label */ #define DIF_OP_BE 18 /* be label */ #define DIF_OP_BNE 19 /* bne label */ #define DIF_OP_BG 20 /* bg label */ #define DIF_OP_BGU 21 /* bgu label */ #define DIF_OP_BGE 22 /* bge label */ #define DIF_OP_BGEU 23 /* bgeu label */ #define DIF_OP_BL 24 /* bl label */ #define DIF_OP_BLU 25 /* blu label */ #define DIF_OP_BLE 26 /* ble label */ #define DIF_OP_BLEU 27 /* bleu label */ #define DIF_OP_LDSB 28 /* ldsb [r1], rd */ #define DIF_OP_LDSH 29 /* ldsh [r1], rd */ #define DIF_OP_LDSW 30 /* ldsw [r1], rd */ #define DIF_OP_LDUB 31 /* ldub [r1], rd */ #define DIF_OP_LDUH 32 /* lduh [r1], rd */ #define DIF_OP_LDUW 33 /* lduw [r1], rd */ #define DIF_OP_LDX 34 /* ldx [r1], rd */ #define DIF_OP_RET 35 /* ret rd */ #define DIF_OP_NOP 36 /* nop */ #define DIF_OP_SETX 37 /* setx intindex, rd */ #define DIF_OP_SETS 38 /* sets strindex, rd */ #define DIF_OP_SCMP 39 /* scmp r1, r2 */ #define DIF_OP_LDGA 40 /* ldga var, ri, rd */ #define DIF_OP_LDGS 41 /* ldgs var, rd */ #define DIF_OP_STGS 42 /* stgs var, rs */ #define DIF_OP_LDTA 43 /* ldta var, ri, rd */ #define DIF_OP_LDTS 44 /* ldts var, rd */ #define DIF_OP_STTS 45 /* stts var, rs */ #define DIF_OP_SRA 46 /* sra r1, r2, rd */ #define DIF_OP_CALL 47 /* call subr, rd */ #define DIF_OP_PUSHTR 48 /* pushtr type, rs, rr */ #define DIF_OP_PUSHTV 49 /* pushtv type, rs, rv */ #define DIF_OP_POPTS 50 /* popts */ #define DIF_OP_FLUSHTS 51 /* flushts */ #define DIF_OP_LDGAA 52 /* ldgaa var, rd */ #define DIF_OP_LDTAA 53 /* ldtaa var, rd */ #define DIF_OP_STGAA 54 /* stgaa var, rs */ #define DIF_OP_STTAA 55 /* sttaa var, rs */ #define DIF_OP_LDLS 56 /* ldls var, rd */ #define DIF_OP_STLS 57 /* stls var, rs */ #define DIF_OP_ALLOCS 58 /* allocs r1, rd */ #define DIF_OP_COPYS 59 /* copys r1, r2, rd */ #define DIF_OP_STB 60 /* stb r1, [rd] */ #define DIF_OP_STH 61 /* sth r1, [rd] */ #define DIF_OP_STW 62 /* stw r1, [rd] */ #define DIF_OP_STX 63 /* stx r1, [rd] */ #define DIF_OP_ULDSB 64 /* uldsb [r1], rd */ #define DIF_OP_ULDSH 65 /* uldsh [r1], rd */ #define DIF_OP_ULDSW 66 /* uldsw [r1], rd */ #define DIF_OP_ULDUB 67 /* uldub [r1], rd */ #define DIF_OP_ULDUH 68 /* ulduh [r1], rd */ #define DIF_OP_ULDUW 69 /* ulduw [r1], rd */ #define DIF_OP_ULDX 70 /* uldx [r1], rd */ #define DIF_OP_RLDSB 71 /* rldsb [r1], rd */ #define DIF_OP_RLDSH 72 /* rldsh [r1], rd */ #define DIF_OP_RLDSW 73 /* rldsw [r1], rd */ #define DIF_OP_RLDUB 74 /* rldub [r1], rd */ #define DIF_OP_RLDUH 75 /* rlduh [r1], rd */ #define DIF_OP_RLDUW 76 /* rlduw [r1], rd */ #define DIF_OP_RLDX 77 /* rldx [r1], rd */ #define DIF_OP_XLATE 78 /* xlate xlrindex, rd */ #define DIF_OP_XLARG 79 /* xlarg xlrindex, rd */ #define DIF_INTOFF_MAX 0xffff /* highest integer table offset */ #define DIF_STROFF_MAX 0xffff /* highest string table offset */ #define DIF_REGISTER_MAX 0xff /* highest register number */ #define DIF_VARIABLE_MAX 0xffff /* highest variable identifier */ #define DIF_SUBROUTINE_MAX 0xffff /* highest subroutine code */ #define DIF_VAR_ARRAY_MIN 0x0000 /* lowest numbered array variable */ #define DIF_VAR_ARRAY_UBASE 0x0080 /* lowest user-defined array */ #define DIF_VAR_ARRAY_MAX 0x00ff /* highest numbered array variable */ #define DIF_VAR_OTHER_MIN 0x0100 /* lowest numbered scalar or assc */ #define DIF_VAR_OTHER_UBASE 0x0500 /* lowest user-defined scalar or assc */ #define DIF_VAR_OTHER_MAX 0xffff /* highest numbered scalar or assc */ #define DIF_VAR_ARGS 0x0000 /* arguments array */ #define DIF_VAR_REGS 0x0001 /* registers array */ #define DIF_VAR_UREGS 0x0002 /* user registers array */ #define DIF_VAR_CURTHREAD 0x0100 /* thread pointer */ #define DIF_VAR_TIMESTAMP 0x0101 /* timestamp */ #define DIF_VAR_VTIMESTAMP 0x0102 /* virtual timestamp */ #define DIF_VAR_IPL 0x0103 /* interrupt priority level */ #define DIF_VAR_EPID 0x0104 /* enabled probe ID */ #define DIF_VAR_ID 0x0105 /* probe ID */ #define DIF_VAR_ARG0 0x0106 /* first argument */ #define DIF_VAR_ARG1 0x0107 /* second argument */ #define DIF_VAR_ARG2 0x0108 /* third argument */ #define DIF_VAR_ARG3 0x0109 /* fourth argument */ #define DIF_VAR_ARG4 0x010a /* fifth argument */ #define DIF_VAR_ARG5 0x010b /* sixth argument */ #define DIF_VAR_ARG6 0x010c /* seventh argument */ #define DIF_VAR_ARG7 0x010d /* eighth argument */ #define DIF_VAR_ARG8 0x010e /* ninth argument */ #define DIF_VAR_ARG9 0x010f /* tenth argument */ #define DIF_VAR_STACKDEPTH 0x0110 /* stack depth */ #define DIF_VAR_CALLER 0x0111 /* caller */ #define DIF_VAR_PROBEPROV 0x0112 /* probe provider */ #define DIF_VAR_PROBEMOD 0x0113 /* probe module */ #define DIF_VAR_PROBEFUNC 0x0114 /* probe function */ #define DIF_VAR_PROBENAME 0x0115 /* probe name */ #define DIF_VAR_PID 0x0116 /* process ID */ #define DIF_VAR_TID 0x0117 /* (per-process) thread ID */ #define DIF_VAR_EXECNAME 0x0118 /* name of executable */ #define DIF_VAR_ZONENAME 0x0119 /* zone name associated with process */ #define DIF_VAR_WALLTIMESTAMP 0x011a /* wall-clock timestamp */ #define DIF_VAR_USTACKDEPTH 0x011b /* user-land stack depth */ #define DIF_VAR_UCALLER 0x011c /* user-level caller */ #define DIF_VAR_PPID 0x011d /* parent process ID */ #define DIF_VAR_UID 0x011e /* process user ID */ #define DIF_VAR_GID 0x011f /* process group ID */ #define DIF_VAR_ERRNO 0x0120 /* thread errno */ +#define DIF_VAR_EXECARGS 0x0121 /* process arguments */ #define DIF_SUBR_RAND 0 #define DIF_SUBR_MUTEX_OWNED 1 #define DIF_SUBR_MUTEX_OWNER 2 #define DIF_SUBR_MUTEX_TYPE_ADAPTIVE 3 #define DIF_SUBR_MUTEX_TYPE_SPIN 4 #define DIF_SUBR_RW_READ_HELD 5 #define DIF_SUBR_RW_WRITE_HELD 6 #define DIF_SUBR_RW_ISWRITER 7 #define DIF_SUBR_COPYIN 8 #define DIF_SUBR_COPYINSTR 9 #define DIF_SUBR_SPECULATION 10 #define DIF_SUBR_PROGENYOF 11 #define DIF_SUBR_STRLEN 12 #define DIF_SUBR_COPYOUT 13 #define DIF_SUBR_COPYOUTSTR 14 #define DIF_SUBR_ALLOCA 15 #define DIF_SUBR_BCOPY 16 #define DIF_SUBR_COPYINTO 17 #define DIF_SUBR_MSGDSIZE 18 #define DIF_SUBR_MSGSIZE 19 #define DIF_SUBR_GETMAJOR 20 #define DIF_SUBR_GETMINOR 21 #define DIF_SUBR_DDI_PATHNAME 22 #define DIF_SUBR_STRJOIN 23 #define DIF_SUBR_LLTOSTR 24 #define DIF_SUBR_BASENAME 25 #define DIF_SUBR_DIRNAME 26 #define DIF_SUBR_CLEANPATH 27 #define DIF_SUBR_STRCHR 28 #define DIF_SUBR_STRRCHR 29 #define DIF_SUBR_STRSTR 30 #define DIF_SUBR_STRTOK 31 #define DIF_SUBR_SUBSTR 32 #define DIF_SUBR_INDEX 33 #define DIF_SUBR_RINDEX 34 #define DIF_SUBR_HTONS 35 #define DIF_SUBR_HTONL 36 #define DIF_SUBR_HTONLL 37 #define DIF_SUBR_NTOHS 38 #define DIF_SUBR_NTOHL 39 #define DIF_SUBR_NTOHLL 40 #define DIF_SUBR_INET_NTOP 41 #define DIF_SUBR_INET_NTOA 42 #define DIF_SUBR_INET_NTOA6 43 +#define DIF_SUBR_MEMREF 44 +#define DIF_SUBR_TYPEREF 45 +#define DIF_SUBR_SX_SHARED_HELD 46 +#define DIF_SUBR_SX_EXCLUSIVE_HELD 47 +#define DIF_SUBR_SX_ISEXCLUSIVE 48 -#define DIF_SUBR_MAX 43 /* max subroutine value */ +#define DIF_SUBR_MAX 48 /* max subroutine value */ typedef uint32_t dif_instr_t; #define DIF_INSTR_OP(i) (((i) >> 24) & 0xff) #define DIF_INSTR_R1(i) (((i) >> 16) & 0xff) #define DIF_INSTR_R2(i) (((i) >> 8) & 0xff) #define DIF_INSTR_RD(i) ((i) & 0xff) #define DIF_INSTR_RS(i) ((i) & 0xff) #define DIF_INSTR_LABEL(i) ((i) & 0xffffff) #define DIF_INSTR_VAR(i) (((i) >> 8) & 0xffff) #define DIF_INSTR_INTEGER(i) (((i) >> 8) & 0xffff) #define DIF_INSTR_STRING(i) (((i) >> 8) & 0xffff) #define DIF_INSTR_SUBR(i) (((i) >> 8) & 0xffff) #define DIF_INSTR_TYPE(i) (((i) >> 16) & 0xff) #define DIF_INSTR_XLREF(i) (((i) >> 8) & 0xffff) #define DIF_INSTR_FMT(op, r1, r2, d) \ (((op) << 24) | ((r1) << 16) | ((r2) << 8) | (d)) #define DIF_INSTR_NOT(r1, d) (DIF_INSTR_FMT(DIF_OP_NOT, r1, 0, d)) #define DIF_INSTR_MOV(r1, d) (DIF_INSTR_FMT(DIF_OP_MOV, r1, 0, d)) #define DIF_INSTR_CMP(op, r1, r2) (DIF_INSTR_FMT(op, r1, r2, 0)) #define DIF_INSTR_TST(r1) (DIF_INSTR_FMT(DIF_OP_TST, r1, 0, 0)) #define DIF_INSTR_BRANCH(op, label) (((op) << 24) | (label)) #define DIF_INSTR_LOAD(op, r1, d) (DIF_INSTR_FMT(op, r1, 0, d)) #define DIF_INSTR_STORE(op, r1, d) (DIF_INSTR_FMT(op, r1, 0, d)) #define DIF_INSTR_SETX(i, d) ((DIF_OP_SETX << 24) | ((i) << 8) | (d)) #define DIF_INSTR_SETS(s, d) ((DIF_OP_SETS << 24) | ((s) << 8) | (d)) #define DIF_INSTR_RET(d) (DIF_INSTR_FMT(DIF_OP_RET, 0, 0, d)) #define DIF_INSTR_NOP (DIF_OP_NOP << 24) #define DIF_INSTR_LDA(op, v, r, d) (DIF_INSTR_FMT(op, v, r, d)) #define DIF_INSTR_LDV(op, v, d) (((op) << 24) | ((v) << 8) | (d)) #define DIF_INSTR_STV(op, v, rs) (((op) << 24) | ((v) << 8) | (rs)) #define DIF_INSTR_CALL(s, d) ((DIF_OP_CALL << 24) | ((s) << 8) | (d)) #define DIF_INSTR_PUSHTS(op, t, r2, rs) (DIF_INSTR_FMT(op, t, r2, rs)) #define DIF_INSTR_POPTS (DIF_OP_POPTS << 24) #define DIF_INSTR_FLUSHTS (DIF_OP_FLUSHTS << 24) #define DIF_INSTR_ALLOCS(r1, d) (DIF_INSTR_FMT(DIF_OP_ALLOCS, r1, 0, d)) #define DIF_INSTR_COPYS(r1, r2, d) (DIF_INSTR_FMT(DIF_OP_COPYS, r1, r2, d)) #define DIF_INSTR_XLATE(op, r, d) (((op) << 24) | ((r) << 8) | (d)) #define DIF_REG_R0 0 /* %r0 is always set to zero */ /* * A DTrace Intermediate Format Type (DIF Type) is used to represent the types * of variables, function and associative array arguments, and the return type * for each DIF object (shown below). It contains a description of the type, * its size in bytes, and a module identifier. */ typedef struct dtrace_diftype { uint8_t dtdt_kind; /* type kind (see below) */ uint8_t dtdt_ckind; /* type kind in CTF */ uint8_t dtdt_flags; /* type flags (see below) */ uint8_t dtdt_pad; /* reserved for future use */ uint32_t dtdt_size; /* type size in bytes (unless string) */ } dtrace_diftype_t; #define DIF_TYPE_CTF 0 /* type is a CTF type */ #define DIF_TYPE_STRING 1 /* type is a D string */ #define DIF_TF_BYREF 0x1 /* type is passed by reference */ /* * A DTrace Intermediate Format variable record is used to describe each of the * variables referenced by a given DIF object. It contains an integer variable * identifier along with variable scope and properties, as shown below. The * size of this structure must be sizeof (int) aligned. */ typedef struct dtrace_difv { uint32_t dtdv_name; /* variable name index in dtdo_strtab */ uint32_t dtdv_id; /* variable reference identifier */ uint8_t dtdv_kind; /* variable kind (see below) */ uint8_t dtdv_scope; /* variable scope (see below) */ uint16_t dtdv_flags; /* variable flags (see below) */ dtrace_diftype_t dtdv_type; /* variable type (see above) */ } dtrace_difv_t; #define DIFV_KIND_ARRAY 0 /* variable is an array of quantities */ #define DIFV_KIND_SCALAR 1 /* variable is a scalar quantity */ #define DIFV_SCOPE_GLOBAL 0 /* variable has global scope */ #define DIFV_SCOPE_THREAD 1 /* variable has thread scope */ #define DIFV_SCOPE_LOCAL 2 /* variable has local scope */ #define DIFV_F_REF 0x1 /* variable is referenced by DIFO */ #define DIFV_F_MOD 0x2 /* variable is written by DIFO */ /* * DTrace Actions * * The upper byte determines the class of the action; the low bytes determines * the specific action within that class. The classes of actions are as * follows: * * [ no class ] <= May record process- or kernel-related data * DTRACEACT_PROC <= Only records process-related data * DTRACEACT_PROC_DESTRUCTIVE <= Potentially destructive to processes * DTRACEACT_KERNEL <= Only records kernel-related data * DTRACEACT_KERNEL_DESTRUCTIVE <= Potentially destructive to the kernel * DTRACEACT_SPECULATIVE <= Speculation-related action * DTRACEACT_AGGREGATION <= Aggregating action */ #define DTRACEACT_NONE 0 /* no action */ #define DTRACEACT_DIFEXPR 1 /* action is DIF expression */ #define DTRACEACT_EXIT 2 /* exit() action */ #define DTRACEACT_PRINTF 3 /* printf() action */ #define DTRACEACT_PRINTA 4 /* printa() action */ #define DTRACEACT_LIBACT 5 /* library-controlled action */ +#define DTRACEACT_PRINTM 6 /* printm() action */ +#define DTRACEACT_PRINTT 7 /* printt() action */ #define DTRACEACT_PROC 0x0100 #define DTRACEACT_USTACK (DTRACEACT_PROC + 1) #define DTRACEACT_JSTACK (DTRACEACT_PROC + 2) #define DTRACEACT_USYM (DTRACEACT_PROC + 3) #define DTRACEACT_UMOD (DTRACEACT_PROC + 4) #define DTRACEACT_UADDR (DTRACEACT_PROC + 5) #define DTRACEACT_PROC_DESTRUCTIVE 0x0200 #define DTRACEACT_STOP (DTRACEACT_PROC_DESTRUCTIVE + 1) #define DTRACEACT_RAISE (DTRACEACT_PROC_DESTRUCTIVE + 2) #define DTRACEACT_SYSTEM (DTRACEACT_PROC_DESTRUCTIVE + 3) #define DTRACEACT_FREOPEN (DTRACEACT_PROC_DESTRUCTIVE + 4) #define DTRACEACT_PROC_CONTROL 0x0300 #define DTRACEACT_KERNEL 0x0400 #define DTRACEACT_STACK (DTRACEACT_KERNEL + 1) #define DTRACEACT_SYM (DTRACEACT_KERNEL + 2) #define DTRACEACT_MOD (DTRACEACT_KERNEL + 3) #define DTRACEACT_KERNEL_DESTRUCTIVE 0x0500 #define DTRACEACT_BREAKPOINT (DTRACEACT_KERNEL_DESTRUCTIVE + 1) #define DTRACEACT_PANIC (DTRACEACT_KERNEL_DESTRUCTIVE + 2) #define DTRACEACT_CHILL (DTRACEACT_KERNEL_DESTRUCTIVE + 3) #define DTRACEACT_SPECULATIVE 0x0600 #define DTRACEACT_SPECULATE (DTRACEACT_SPECULATIVE + 1) #define DTRACEACT_COMMIT (DTRACEACT_SPECULATIVE + 2) #define DTRACEACT_DISCARD (DTRACEACT_SPECULATIVE + 3) #define DTRACEACT_CLASS(x) ((x) & 0xff00) #define DTRACEACT_ISDESTRUCTIVE(x) \ (DTRACEACT_CLASS(x) == DTRACEACT_PROC_DESTRUCTIVE || \ DTRACEACT_CLASS(x) == DTRACEACT_KERNEL_DESTRUCTIVE) #define DTRACEACT_ISSPECULATIVE(x) \ (DTRACEACT_CLASS(x) == DTRACEACT_SPECULATIVE) #define DTRACEACT_ISPRINTFLIKE(x) \ ((x) == DTRACEACT_PRINTF || (x) == DTRACEACT_PRINTA || \ (x) == DTRACEACT_SYSTEM || (x) == DTRACEACT_FREOPEN) /* * DTrace Aggregating Actions * * These are functions f(x) for which the following is true: * * f(f(x_0) U f(x_1) U ... U f(x_n)) = f(x_0 U x_1 U ... U x_n) * * where x_n is a set of arbitrary data. Aggregating actions are in their own * DTrace action class, DTTRACEACT_AGGREGATION. The macros provided here allow * for easier processing of the aggregation argument and data payload for a few * aggregating actions (notably: quantize(), lquantize(), and ustack()). */ #define DTRACEACT_AGGREGATION 0x0700 #define DTRACEAGG_COUNT (DTRACEACT_AGGREGATION + 1) #define DTRACEAGG_MIN (DTRACEACT_AGGREGATION + 2) #define DTRACEAGG_MAX (DTRACEACT_AGGREGATION + 3) #define DTRACEAGG_AVG (DTRACEACT_AGGREGATION + 4) #define DTRACEAGG_SUM (DTRACEACT_AGGREGATION + 5) #define DTRACEAGG_STDDEV (DTRACEACT_AGGREGATION + 6) #define DTRACEAGG_QUANTIZE (DTRACEACT_AGGREGATION + 7) #define DTRACEAGG_LQUANTIZE (DTRACEACT_AGGREGATION + 8) #define DTRACEACT_ISAGG(x) \ (DTRACEACT_CLASS(x) == DTRACEACT_AGGREGATION) #define DTRACE_QUANTIZE_NBUCKETS \ (((sizeof (uint64_t) * NBBY) - 1) * 2 + 1) #define DTRACE_QUANTIZE_ZEROBUCKET ((sizeof (uint64_t) * NBBY) - 1) #define DTRACE_QUANTIZE_BUCKETVAL(buck) \ (int64_t)((buck) < DTRACE_QUANTIZE_ZEROBUCKET ? \ -(1LL << (DTRACE_QUANTIZE_ZEROBUCKET - 1 - (buck))) : \ (buck) == DTRACE_QUANTIZE_ZEROBUCKET ? 0 : \ 1LL << ((buck) - DTRACE_QUANTIZE_ZEROBUCKET - 1)) #define DTRACE_LQUANTIZE_STEPSHIFT 48 #define DTRACE_LQUANTIZE_STEPMASK ((uint64_t)UINT16_MAX << 48) #define DTRACE_LQUANTIZE_LEVELSHIFT 32 #define DTRACE_LQUANTIZE_LEVELMASK ((uint64_t)UINT16_MAX << 32) #define DTRACE_LQUANTIZE_BASESHIFT 0 #define DTRACE_LQUANTIZE_BASEMASK UINT32_MAX #define DTRACE_LQUANTIZE_STEP(x) \ (uint16_t)(((x) & DTRACE_LQUANTIZE_STEPMASK) >> \ DTRACE_LQUANTIZE_STEPSHIFT) #define DTRACE_LQUANTIZE_LEVELS(x) \ (uint16_t)(((x) & DTRACE_LQUANTIZE_LEVELMASK) >> \ DTRACE_LQUANTIZE_LEVELSHIFT) #define DTRACE_LQUANTIZE_BASE(x) \ (int32_t)(((x) & DTRACE_LQUANTIZE_BASEMASK) >> \ DTRACE_LQUANTIZE_BASESHIFT) #define DTRACE_USTACK_NFRAMES(x) (uint32_t)((x) & UINT32_MAX) #define DTRACE_USTACK_STRSIZE(x) (uint32_t)((x) >> 32) #define DTRACE_USTACK_ARG(x, y) \ ((((uint64_t)(y)) << 32) | ((x) & UINT32_MAX)) #ifndef _LP64 -#ifndef _LITTLE_ENDIAN +#if BYTE_ORDER == _BIG_ENDIAN #define DTRACE_PTR(type, name) uint32_t name##pad; type *name #else #define DTRACE_PTR(type, name) type *name; uint32_t name##pad #endif #else #define DTRACE_PTR(type, name) type *name #endif /* * DTrace Object Format (DOF) * * DTrace programs can be persistently encoded in the DOF format so that they * may be embedded in other programs (for example, in an ELF file) or in the * dtrace driver configuration file for use in anonymous tracing. The DOF * format is versioned and extensible so that it can be revised and so that * internal data structures can be modified or extended compatibly. All DOF * structures use fixed-size types, so the 32-bit and 64-bit representations * are identical and consumers can use either data model transparently. * * The file layout is structured as follows: * * +---------------+-------------------+----- ... ----+---- ... ------+ * | dof_hdr_t | dof_sec_t[ ... ] | loadable | non-loadable | * | (file header) | (section headers) | section data | section data | * +---------------+-------------------+----- ... ----+---- ... ------+ * |<------------ dof_hdr.dofh_loadsz --------------->| | * |<------------ dof_hdr.dofh_filesz ------------------------------->| * * The file header stores meta-data including a magic number, data model for * the instrumentation, data encoding, and properties of the DIF code within. * The header describes its own size and the size of the section headers. By * convention, an array of section headers follows the file header, and then * the data for all loadable sections and unloadable sections. This permits * consumer code to easily download the headers and all loadable data into the * DTrace driver in one contiguous chunk, omitting other extraneous sections. * * The section headers describe the size, offset, alignment, and section type * for each section. Sections are described using a set of #defines that tell * the consumer what kind of data is expected. Sections can contain links to * other sections by storing a dof_secidx_t, an index into the section header * array, inside of the section data structures. The section header includes * an entry size so that sections with data arrays can grow their structures. * * The DOF data itself can contain many snippets of DIF (i.e. >1 DIFOs), which * are represented themselves as a collection of related DOF sections. This * permits us to change the set of sections associated with a DIFO over time, * and also permits us to encode DIFOs that contain different sets of sections. * When a DOF section wants to refer to a DIFO, it stores the dof_secidx_t of a * section of type DOF_SECT_DIFOHDR. This section's data is then an array of * dof_secidx_t's which in turn denote the sections associated with this DIFO. * * This loose coupling of the file structure (header and sections) to the * structure of the DTrace program itself (ECB descriptions, action * descriptions, and DIFOs) permits activities such as relocation processing * to occur in a single pass without having to understand D program structure. * * Finally, strings are always stored in ELF-style string tables along with a * string table section index and string table offset. Therefore strings in * DOF are always arbitrary-length and not bound to the current implementation. */ #define DOF_ID_SIZE 16 /* total size of dofh_ident[] in bytes */ typedef struct dof_hdr { uint8_t dofh_ident[DOF_ID_SIZE]; /* identification bytes (see below) */ uint32_t dofh_flags; /* file attribute flags (if any) */ uint32_t dofh_hdrsize; /* size of file header in bytes */ uint32_t dofh_secsize; /* size of section header in bytes */ uint32_t dofh_secnum; /* number of section headers */ uint64_t dofh_secoff; /* file offset of section headers */ uint64_t dofh_loadsz; /* file size of loadable portion */ uint64_t dofh_filesz; /* file size of entire DOF file */ uint64_t dofh_pad; /* reserved for future use */ } dof_hdr_t; #define DOF_ID_MAG0 0 /* first byte of magic number */ #define DOF_ID_MAG1 1 /* second byte of magic number */ #define DOF_ID_MAG2 2 /* third byte of magic number */ #define DOF_ID_MAG3 3 /* fourth byte of magic number */ #define DOF_ID_MODEL 4 /* DOF data model (see below) */ #define DOF_ID_ENCODING 5 /* DOF data encoding (see below) */ #define DOF_ID_VERSION 6 /* DOF file format major version (see below) */ #define DOF_ID_DIFVERS 7 /* DIF instruction set version */ #define DOF_ID_DIFIREG 8 /* DIF integer registers used by compiler */ #define DOF_ID_DIFTREG 9 /* DIF tuple registers used by compiler */ #define DOF_ID_PAD 10 /* start of padding bytes (all zeroes) */ #define DOF_MAG_MAG0 0x7F /* DOF_ID_MAG[0-3] */ #define DOF_MAG_MAG1 'D' #define DOF_MAG_MAG2 'O' #define DOF_MAG_MAG3 'F' #define DOF_MAG_STRING "\177DOF" #define DOF_MAG_STRLEN 4 #define DOF_MODEL_NONE 0 /* DOF_ID_MODEL */ #define DOF_MODEL_ILP32 1 #define DOF_MODEL_LP64 2 #ifdef _LP64 #define DOF_MODEL_NATIVE DOF_MODEL_LP64 #else #define DOF_MODEL_NATIVE DOF_MODEL_ILP32 #endif #define DOF_ENCODE_NONE 0 /* DOF_ID_ENCODING */ #define DOF_ENCODE_LSB 1 #define DOF_ENCODE_MSB 2 -#ifdef _BIG_ENDIAN +#if BYTE_ORDER == _BIG_ENDIAN #define DOF_ENCODE_NATIVE DOF_ENCODE_MSB #else #define DOF_ENCODE_NATIVE DOF_ENCODE_LSB #endif #define DOF_VERSION_1 1 /* DOF version 1: Solaris 10 FCS */ #define DOF_VERSION_2 2 /* DOF version 2: Solaris Express 6/06 */ #define DOF_VERSION DOF_VERSION_2 /* Latest DOF version */ #define DOF_FL_VALID 0 /* mask of all valid dofh_flags bits */ typedef uint32_t dof_secidx_t; /* section header table index type */ typedef uint32_t dof_stridx_t; /* string table index type */ #define DOF_SECIDX_NONE (-1U) /* null value for section indices */ #define DOF_STRIDX_NONE (-1U) /* null value for string indices */ typedef struct dof_sec { uint32_t dofs_type; /* section type (see below) */ uint32_t dofs_align; /* section data memory alignment */ uint32_t dofs_flags; /* section flags (if any) */ uint32_t dofs_entsize; /* size of section entry (if table) */ uint64_t dofs_offset; /* offset of section data within file */ uint64_t dofs_size; /* size of section data in bytes */ } dof_sec_t; #define DOF_SECT_NONE 0 /* null section */ #define DOF_SECT_COMMENTS 1 /* compiler comments */ #define DOF_SECT_SOURCE 2 /* D program source code */ #define DOF_SECT_ECBDESC 3 /* dof_ecbdesc_t */ #define DOF_SECT_PROBEDESC 4 /* dof_probedesc_t */ #define DOF_SECT_ACTDESC 5 /* dof_actdesc_t array */ #define DOF_SECT_DIFOHDR 6 /* dof_difohdr_t (variable length) */ #define DOF_SECT_DIF 7 /* uint32_t array of byte code */ #define DOF_SECT_STRTAB 8 /* string table */ #define DOF_SECT_VARTAB 9 /* dtrace_difv_t array */ #define DOF_SECT_RELTAB 10 /* dof_relodesc_t array */ #define DOF_SECT_TYPTAB 11 /* dtrace_diftype_t array */ #define DOF_SECT_URELHDR 12 /* dof_relohdr_t (user relocations) */ #define DOF_SECT_KRELHDR 13 /* dof_relohdr_t (kernel relocations) */ #define DOF_SECT_OPTDESC 14 /* dof_optdesc_t array */ #define DOF_SECT_PROVIDER 15 /* dof_provider_t */ #define DOF_SECT_PROBES 16 /* dof_probe_t array */ #define DOF_SECT_PRARGS 17 /* uint8_t array (probe arg mappings) */ #define DOF_SECT_PROFFS 18 /* uint32_t array (probe arg offsets) */ #define DOF_SECT_INTTAB 19 /* uint64_t array */ #define DOF_SECT_UTSNAME 20 /* struct utsname */ #define DOF_SECT_XLTAB 21 /* dof_xlref_t array */ #define DOF_SECT_XLMEMBERS 22 /* dof_xlmember_t array */ #define DOF_SECT_XLIMPORT 23 /* dof_xlator_t */ #define DOF_SECT_XLEXPORT 24 /* dof_xlator_t */ #define DOF_SECT_PREXPORT 25 /* dof_secidx_t array (exported objs) */ #define DOF_SECT_PRENOFFS 26 /* uint32_t array (enabled offsets) */ #define DOF_SECF_LOAD 1 /* section should be loaded */ typedef struct dof_ecbdesc { dof_secidx_t dofe_probes; /* link to DOF_SECT_PROBEDESC */ dof_secidx_t dofe_pred; /* link to DOF_SECT_DIFOHDR */ dof_secidx_t dofe_actions; /* link to DOF_SECT_ACTDESC */ uint32_t dofe_pad; /* reserved for future use */ uint64_t dofe_uarg; /* user-supplied library argument */ } dof_ecbdesc_t; typedef struct dof_probedesc { dof_secidx_t dofp_strtab; /* link to DOF_SECT_STRTAB section */ dof_stridx_t dofp_provider; /* provider string */ dof_stridx_t dofp_mod; /* module string */ dof_stridx_t dofp_func; /* function string */ dof_stridx_t dofp_name; /* name string */ uint32_t dofp_id; /* probe identifier (or zero) */ } dof_probedesc_t; typedef struct dof_actdesc { dof_secidx_t dofa_difo; /* link to DOF_SECT_DIFOHDR */ dof_secidx_t dofa_strtab; /* link to DOF_SECT_STRTAB section */ uint32_t dofa_kind; /* action kind (DTRACEACT_* constant) */ uint32_t dofa_ntuple; /* number of subsequent tuple actions */ uint64_t dofa_arg; /* kind-specific argument */ uint64_t dofa_uarg; /* user-supplied argument */ } dof_actdesc_t; typedef struct dof_difohdr { dtrace_diftype_t dofd_rtype; /* return type for this fragment */ dof_secidx_t dofd_links[1]; /* variable length array of indices */ } dof_difohdr_t; typedef struct dof_relohdr { dof_secidx_t dofr_strtab; /* link to DOF_SECT_STRTAB for names */ dof_secidx_t dofr_relsec; /* link to DOF_SECT_RELTAB for relos */ dof_secidx_t dofr_tgtsec; /* link to section we are relocating */ } dof_relohdr_t; typedef struct dof_relodesc { dof_stridx_t dofr_name; /* string name of relocation symbol */ uint32_t dofr_type; /* relo type (DOF_RELO_* constant) */ uint64_t dofr_offset; /* byte offset for relocation */ uint64_t dofr_data; /* additional type-specific data */ } dof_relodesc_t; #define DOF_RELO_NONE 0 /* empty relocation entry */ #define DOF_RELO_SETX 1 /* relocate setx value */ typedef struct dof_optdesc { uint32_t dofo_option; /* option identifier */ dof_secidx_t dofo_strtab; /* string table, if string option */ uint64_t dofo_value; /* option value or string index */ } dof_optdesc_t; typedef uint32_t dof_attr_t; /* encoded stability attributes */ #define DOF_ATTR(n, d, c) (((n) << 24) | ((d) << 16) | ((c) << 8)) #define DOF_ATTR_NAME(a) (((a) >> 24) & 0xff) #define DOF_ATTR_DATA(a) (((a) >> 16) & 0xff) #define DOF_ATTR_CLASS(a) (((a) >> 8) & 0xff) typedef struct dof_provider { dof_secidx_t dofpv_strtab; /* link to DOF_SECT_STRTAB section */ dof_secidx_t dofpv_probes; /* link to DOF_SECT_PROBES section */ dof_secidx_t dofpv_prargs; /* link to DOF_SECT_PRARGS section */ dof_secidx_t dofpv_proffs; /* link to DOF_SECT_PROFFS section */ dof_stridx_t dofpv_name; /* provider name string */ dof_attr_t dofpv_provattr; /* provider attributes */ dof_attr_t dofpv_modattr; /* module attributes */ dof_attr_t dofpv_funcattr; /* function attributes */ dof_attr_t dofpv_nameattr; /* name attributes */ dof_attr_t dofpv_argsattr; /* args attributes */ dof_secidx_t dofpv_prenoffs; /* link to DOF_SECT_PRENOFFS section */ } dof_provider_t; typedef struct dof_probe { uint64_t dofpr_addr; /* probe base address or offset */ dof_stridx_t dofpr_func; /* probe function string */ dof_stridx_t dofpr_name; /* probe name string */ dof_stridx_t dofpr_nargv; /* native argument type strings */ dof_stridx_t dofpr_xargv; /* translated argument type strings */ uint32_t dofpr_argidx; /* index of first argument mapping */ uint32_t dofpr_offidx; /* index of first offset entry */ uint8_t dofpr_nargc; /* native argument count */ uint8_t dofpr_xargc; /* translated argument count */ uint16_t dofpr_noffs; /* number of offset entries for probe */ uint32_t dofpr_enoffidx; /* index of first is-enabled offset */ uint16_t dofpr_nenoffs; /* number of is-enabled offsets */ uint16_t dofpr_pad1; /* reserved for future use */ uint32_t dofpr_pad2; /* reserved for future use */ } dof_probe_t; typedef struct dof_xlator { dof_secidx_t dofxl_members; /* link to DOF_SECT_XLMEMBERS section */ dof_secidx_t dofxl_strtab; /* link to DOF_SECT_STRTAB section */ dof_stridx_t dofxl_argv; /* input parameter type strings */ uint32_t dofxl_argc; /* input parameter list length */ dof_stridx_t dofxl_type; /* output type string name */ dof_attr_t dofxl_attr; /* output stability attributes */ } dof_xlator_t; typedef struct dof_xlmember { dof_secidx_t dofxm_difo; /* member link to DOF_SECT_DIFOHDR */ dof_stridx_t dofxm_name; /* member name */ dtrace_diftype_t dofxm_type; /* member type */ } dof_xlmember_t; typedef struct dof_xlref { dof_secidx_t dofxr_xlator; /* link to DOF_SECT_XLATORS section */ uint32_t dofxr_member; /* index of referenced dof_xlmember */ uint32_t dofxr_argn; /* index of argument for DIF_OP_XLARG */ } dof_xlref_t; /* * DTrace Intermediate Format Object (DIFO) * * A DIFO is used to store the compiled DIF for a D expression, its return * type, and its string and variable tables. The string table is a single * buffer of character data into which sets instructions and variable * references can reference strings using a byte offset. The variable table * is an array of dtrace_difv_t structures that describe the name and type of * each variable and the id used in the DIF code. This structure is described * above in the DIF section of this header file. The DIFO is used at both * user-level (in the library) and in the kernel, but the structure is never * passed between the two: the DOF structures form the only interface. As a * result, the definition can change depending on the presence of _KERNEL. */ typedef struct dtrace_difo { dif_instr_t *dtdo_buf; /* instruction buffer */ uint64_t *dtdo_inttab; /* integer table (optional) */ char *dtdo_strtab; /* string table (optional) */ dtrace_difv_t *dtdo_vartab; /* variable table (optional) */ uint_t dtdo_len; /* length of instruction buffer */ uint_t dtdo_intlen; /* length of integer table */ uint_t dtdo_strlen; /* length of string table */ uint_t dtdo_varlen; /* length of variable table */ dtrace_diftype_t dtdo_rtype; /* return type */ uint_t dtdo_refcnt; /* owner reference count */ uint_t dtdo_destructive; /* invokes destructive subroutines */ #ifndef _KERNEL dof_relodesc_t *dtdo_kreltab; /* kernel relocations */ dof_relodesc_t *dtdo_ureltab; /* user relocations */ struct dt_node **dtdo_xlmtab; /* translator references */ uint_t dtdo_krelen; /* length of krelo table */ uint_t dtdo_urelen; /* length of urelo table */ uint_t dtdo_xlmlen; /* length of translator table */ #endif } dtrace_difo_t; /* * DTrace Enabling Description Structures * * When DTrace is tracking the description of a DTrace enabling entity (probe, * predicate, action, ECB, record, etc.), it does so in a description * structure. These structures all end in "desc", and are used at both * user-level and in the kernel -- but (with the exception of * dtrace_probedesc_t) they are never passed between them. Typically, * user-level will use the description structures when assembling an enabling. * It will then distill those description structures into a DOF object (see * above), and send it into the kernel. The kernel will again use the * description structures to create a description of the enabling as it reads * the DOF. When the description is complete, the enabling will be actually * created -- turning it into the structures that represent the enabling * instead of merely describing it. Not surprisingly, the description * structures bear a strong resemblance to the DOF structures that act as their * conduit. */ struct dtrace_predicate; typedef struct dtrace_probedesc { dtrace_id_t dtpd_id; /* probe identifier */ char dtpd_provider[DTRACE_PROVNAMELEN]; /* probe provider name */ char dtpd_mod[DTRACE_MODNAMELEN]; /* probe module name */ char dtpd_func[DTRACE_FUNCNAMELEN]; /* probe function name */ char dtpd_name[DTRACE_NAMELEN]; /* probe name */ } dtrace_probedesc_t; typedef struct dtrace_repldesc { dtrace_probedesc_t dtrpd_match; /* probe descr. to match */ dtrace_probedesc_t dtrpd_create; /* probe descr. to create */ } dtrace_repldesc_t; typedef struct dtrace_preddesc { dtrace_difo_t *dtpdd_difo; /* pointer to DIF object */ struct dtrace_predicate *dtpdd_predicate; /* pointer to predicate */ } dtrace_preddesc_t; typedef struct dtrace_actdesc { dtrace_difo_t *dtad_difo; /* pointer to DIF object */ struct dtrace_actdesc *dtad_next; /* next action */ dtrace_actkind_t dtad_kind; /* kind of action */ uint32_t dtad_ntuple; /* number in tuple */ uint64_t dtad_arg; /* action argument */ uint64_t dtad_uarg; /* user argument */ int dtad_refcnt; /* reference count */ } dtrace_actdesc_t; typedef struct dtrace_ecbdesc { dtrace_actdesc_t *dted_action; /* action description(s) */ dtrace_preddesc_t dted_pred; /* predicate description */ dtrace_probedesc_t dted_probe; /* probe description */ uint64_t dted_uarg; /* library argument */ int dted_refcnt; /* reference count */ } dtrace_ecbdesc_t; /* * DTrace Metadata Description Structures * * DTrace separates the trace data stream from the metadata stream. The only * metadata tokens placed in the data stream are enabled probe identifiers * (EPIDs) or (in the case of aggregations) aggregation identifiers. In order * to determine the structure of the data, DTrace consumers pass the token to * the kernel, and receive in return a corresponding description of the enabled * probe (via the dtrace_eprobedesc structure) or the aggregation (via the * dtrace_aggdesc structure). Both of these structures are expressed in terms * of record descriptions (via the dtrace_recdesc structure) that describe the * exact structure of the data. Some record descriptions may also contain a * format identifier; this additional bit of metadata can be retrieved from the * kernel, for which a format description is returned via the dtrace_fmtdesc * structure. Note that all four of these structures must be bitness-neutral * to allow for a 32-bit DTrace consumer on a 64-bit kernel. */ typedef struct dtrace_recdesc { dtrace_actkind_t dtrd_action; /* kind of action */ uint32_t dtrd_size; /* size of record */ uint32_t dtrd_offset; /* offset in ECB's data */ uint16_t dtrd_alignment; /* required alignment */ uint16_t dtrd_format; /* format, if any */ uint64_t dtrd_arg; /* action argument */ uint64_t dtrd_uarg; /* user argument */ } dtrace_recdesc_t; typedef struct dtrace_eprobedesc { dtrace_epid_t dtepd_epid; /* enabled probe ID */ dtrace_id_t dtepd_probeid; /* probe ID */ uint64_t dtepd_uarg; /* library argument */ uint32_t dtepd_size; /* total size */ int dtepd_nrecs; /* number of records */ dtrace_recdesc_t dtepd_rec[1]; /* records themselves */ } dtrace_eprobedesc_t; typedef struct dtrace_aggdesc { DTRACE_PTR(char, dtagd_name); /* not filled in by kernel */ dtrace_aggvarid_t dtagd_varid; /* not filled in by kernel */ int dtagd_flags; /* not filled in by kernel */ dtrace_aggid_t dtagd_id; /* aggregation ID */ dtrace_epid_t dtagd_epid; /* enabled probe ID */ uint32_t dtagd_size; /* size in bytes */ int dtagd_nrecs; /* number of records */ uint32_t dtagd_pad; /* explicit padding */ dtrace_recdesc_t dtagd_rec[1]; /* record descriptions */ } dtrace_aggdesc_t; typedef struct dtrace_fmtdesc { DTRACE_PTR(char, dtfd_string); /* format string */ int dtfd_length; /* length of format string */ uint16_t dtfd_format; /* format identifier */ } dtrace_fmtdesc_t; #define DTRACE_SIZEOF_EPROBEDESC(desc) \ (sizeof (dtrace_eprobedesc_t) + ((desc)->dtepd_nrecs ? \ (((desc)->dtepd_nrecs - 1) * sizeof (dtrace_recdesc_t)) : 0)) #define DTRACE_SIZEOF_AGGDESC(desc) \ (sizeof (dtrace_aggdesc_t) + ((desc)->dtagd_nrecs ? \ (((desc)->dtagd_nrecs - 1) * sizeof (dtrace_recdesc_t)) : 0)) /* * DTrace Option Interface * * Run-time DTrace options are set and retrieved via DOF_SECT_OPTDESC sections * in a DOF image. The dof_optdesc structure contains an option identifier and * an option value. The valid option identifiers are found below; the mapping * between option identifiers and option identifying strings is maintained at * user-level. Note that the value of DTRACEOPT_UNSET is such that all of the * following are potentially valid option values: all positive integers, zero * and negative one. Some options (notably "bufpolicy" and "bufresize") take * predefined tokens as their values; these are defined with * DTRACEOPT_{option}_{token}. */ #define DTRACEOPT_BUFSIZE 0 /* buffer size */ #define DTRACEOPT_BUFPOLICY 1 /* buffer policy */ #define DTRACEOPT_DYNVARSIZE 2 /* dynamic variable size */ #define DTRACEOPT_AGGSIZE 3 /* aggregation size */ #define DTRACEOPT_SPECSIZE 4 /* speculation size */ #define DTRACEOPT_NSPEC 5 /* number of speculations */ #define DTRACEOPT_STRSIZE 6 /* string size */ #define DTRACEOPT_CLEANRATE 7 /* dynvar cleaning rate */ #define DTRACEOPT_CPU 8 /* CPU to trace */ #define DTRACEOPT_BUFRESIZE 9 /* buffer resizing policy */ #define DTRACEOPT_GRABANON 10 /* grab anonymous state, if any */ #define DTRACEOPT_FLOWINDENT 11 /* indent function entry/return */ #define DTRACEOPT_QUIET 12 /* only output explicitly traced data */ #define DTRACEOPT_STACKFRAMES 13 /* number of stack frames */ #define DTRACEOPT_USTACKFRAMES 14 /* number of user stack frames */ #define DTRACEOPT_AGGRATE 15 /* aggregation snapshot rate */ #define DTRACEOPT_SWITCHRATE 16 /* buffer switching rate */ #define DTRACEOPT_STATUSRATE 17 /* status rate */ #define DTRACEOPT_DESTRUCTIVE 18 /* destructive actions allowed */ #define DTRACEOPT_STACKINDENT 19 /* output indent for stack traces */ #define DTRACEOPT_RAWBYTES 20 /* always print bytes in raw form */ #define DTRACEOPT_JSTACKFRAMES 21 /* number of jstack() frames */ #define DTRACEOPT_JSTACKSTRSIZE 22 /* size of jstack() string table */ #define DTRACEOPT_AGGSORTKEY 23 /* sort aggregations by key */ #define DTRACEOPT_AGGSORTREV 24 /* reverse-sort aggregations */ #define DTRACEOPT_AGGSORTPOS 25 /* agg. position to sort on */ #define DTRACEOPT_AGGSORTKEYPOS 26 /* agg. key position to sort on */ #define DTRACEOPT_MAX 27 /* number of options */ #define DTRACEOPT_UNSET (dtrace_optval_t)-2 /* unset option */ #define DTRACEOPT_BUFPOLICY_RING 0 /* ring buffer */ #define DTRACEOPT_BUFPOLICY_FILL 1 /* fill buffer, then stop */ #define DTRACEOPT_BUFPOLICY_SWITCH 2 /* switch buffers */ #define DTRACEOPT_BUFRESIZE_AUTO 0 /* automatic resizing */ #define DTRACEOPT_BUFRESIZE_MANUAL 1 /* manual resizing */ /* * DTrace Buffer Interface * * In order to get a snapshot of the principal or aggregation buffer, * user-level passes a buffer description to the kernel with the dtrace_bufdesc * structure. This describes which CPU user-level is interested in, and * where user-level wishes the kernel to snapshot the buffer to (the * dtbd_data field). The kernel uses the same structure to pass back some * information regarding the buffer: the size of data actually copied out, the * number of drops, the number of errors, and the offset of the oldest record. * If the buffer policy is a "switch" policy, taking a snapshot of the * principal buffer has the additional effect of switching the active and * inactive buffers. Taking a snapshot of the aggregation buffer _always_ has * the additional effect of switching the active and inactive buffers. */ typedef struct dtrace_bufdesc { uint64_t dtbd_size; /* size of buffer */ uint32_t dtbd_cpu; /* CPU or DTRACE_CPUALL */ uint32_t dtbd_errors; /* number of errors */ uint64_t dtbd_drops; /* number of drops */ DTRACE_PTR(char, dtbd_data); /* data */ uint64_t dtbd_oldest; /* offset of oldest record */ } dtrace_bufdesc_t; /* * DTrace Status * * The status of DTrace is relayed via the dtrace_status structure. This * structure contains members to count drops other than the capacity drops * available via the buffer interface (see above). This consists of dynamic * drops (including capacity dynamic drops, rinsing drops and dirty drops), and * speculative drops (including capacity speculative drops, drops due to busy * speculative buffers and drops due to unavailable speculative buffers). * Additionally, the status structure contains a field to indicate the number * of "fill"-policy buffers have been filled and a boolean field to indicate * that exit() has been called. If the dtst_exiting field is non-zero, no * further data will be generated until tracing is stopped (at which time any * enablings of the END action will be processed); if user-level sees that * this field is non-zero, tracing should be stopped as soon as possible. */ typedef struct dtrace_status { uint64_t dtst_dyndrops; /* dynamic drops */ uint64_t dtst_dyndrops_rinsing; /* dyn drops due to rinsing */ uint64_t dtst_dyndrops_dirty; /* dyn drops due to dirty */ uint64_t dtst_specdrops; /* speculative drops */ uint64_t dtst_specdrops_busy; /* spec drops due to busy */ uint64_t dtst_specdrops_unavail; /* spec drops due to unavail */ uint64_t dtst_errors; /* total errors */ uint64_t dtst_filled; /* number of filled bufs */ uint64_t dtst_stkstroverflows; /* stack string tab overflows */ uint64_t dtst_dblerrors; /* errors in ERROR probes */ char dtst_killed; /* non-zero if killed */ char dtst_exiting; /* non-zero if exit() called */ char dtst_pad[6]; /* pad out to 64-bit align */ } dtrace_status_t; /* * DTrace Configuration * * User-level may need to understand some elements of the kernel DTrace * configuration in order to generate correct DIF. This information is * conveyed via the dtrace_conf structure. */ typedef struct dtrace_conf { uint_t dtc_difversion; /* supported DIF version */ uint_t dtc_difintregs; /* # of DIF integer registers */ uint_t dtc_diftupregs; /* # of DIF tuple registers */ uint_t dtc_ctfmodel; /* CTF data model */ uint_t dtc_pad[8]; /* reserved for future use */ } dtrace_conf_t; /* * DTrace Faults * * The constants below DTRACEFLT_LIBRARY indicate probe processing faults; * constants at or above DTRACEFLT_LIBRARY indicate faults in probe * postprocessing at user-level. Probe processing faults induce an ERROR * probe and are replicated in unistd.d to allow users' ERROR probes to decode * the error condition using thse symbolic labels. */ #define DTRACEFLT_UNKNOWN 0 /* Unknown fault */ #define DTRACEFLT_BADADDR 1 /* Bad address */ #define DTRACEFLT_BADALIGN 2 /* Bad alignment */ #define DTRACEFLT_ILLOP 3 /* Illegal operation */ #define DTRACEFLT_DIVZERO 4 /* Divide-by-zero */ #define DTRACEFLT_NOSCRATCH 5 /* Out of scratch space */ #define DTRACEFLT_KPRIV 6 /* Illegal kernel access */ #define DTRACEFLT_UPRIV 7 /* Illegal user access */ #define DTRACEFLT_TUPOFLOW 8 /* Tuple stack overflow */ #define DTRACEFLT_BADSTACK 9 /* Bad stack */ #define DTRACEFLT_LIBRARY 1000 /* Library-level fault */ /* * DTrace Argument Types * * Because it would waste both space and time, argument types do not reside * with the probe. In order to determine argument types for args[X] * variables, the D compiler queries for argument types on a probe-by-probe * basis. (This optimizes for the common case that arguments are either not * used or used in an untyped fashion.) Typed arguments are specified with a * string of the type name in the dtragd_native member of the argument * description structure. Typed arguments may be further translated to types * of greater stability; the provider indicates such a translated argument by * filling in the dtargd_xlate member with the string of the translated type. * Finally, the provider may indicate which argument value a given argument * maps to by setting the dtargd_mapping member -- allowing a single argument * to map to multiple args[X] variables. */ typedef struct dtrace_argdesc { dtrace_id_t dtargd_id; /* probe identifier */ int dtargd_ndx; /* arg number (-1 iff none) */ int dtargd_mapping; /* value mapping */ char dtargd_native[DTRACE_ARGTYPELEN]; /* native type name */ char dtargd_xlate[DTRACE_ARGTYPELEN]; /* translated type name */ } dtrace_argdesc_t; /* * DTrace Stability Attributes * * Each DTrace provider advertises the name and data stability of each of its * probe description components, as well as its architectural dependencies. * The D compiler can query the provider attributes (dtrace_pattr_t below) in * order to compute the properties of an input program and report them. */ typedef uint8_t dtrace_stability_t; /* stability code (see attributes(5)) */ typedef uint8_t dtrace_class_t; /* architectural dependency class */ #define DTRACE_STABILITY_INTERNAL 0 /* private to DTrace itself */ #define DTRACE_STABILITY_PRIVATE 1 /* private to Sun (see docs) */ #define DTRACE_STABILITY_OBSOLETE 2 /* scheduled for removal */ #define DTRACE_STABILITY_EXTERNAL 3 /* not controlled by Sun */ #define DTRACE_STABILITY_UNSTABLE 4 /* new or rapidly changing */ #define DTRACE_STABILITY_EVOLVING 5 /* less rapidly changing */ #define DTRACE_STABILITY_STABLE 6 /* mature interface from Sun */ #define DTRACE_STABILITY_STANDARD 7 /* industry standard */ #define DTRACE_STABILITY_MAX 7 /* maximum valid stability */ #define DTRACE_CLASS_UNKNOWN 0 /* unknown architectural dependency */ #define DTRACE_CLASS_CPU 1 /* CPU-module-specific */ #define DTRACE_CLASS_PLATFORM 2 /* platform-specific (uname -i) */ #define DTRACE_CLASS_GROUP 3 /* hardware-group-specific (uname -m) */ #define DTRACE_CLASS_ISA 4 /* ISA-specific (uname -p) */ #define DTRACE_CLASS_COMMON 5 /* common to all systems */ #define DTRACE_CLASS_MAX 5 /* maximum valid class */ #define DTRACE_PRIV_NONE 0x0000 #define DTRACE_PRIV_KERNEL 0x0001 #define DTRACE_PRIV_USER 0x0002 #define DTRACE_PRIV_PROC 0x0004 #define DTRACE_PRIV_OWNER 0x0008 #define DTRACE_PRIV_ZONEOWNER 0x0010 #define DTRACE_PRIV_ALL \ (DTRACE_PRIV_KERNEL | DTRACE_PRIV_USER | \ DTRACE_PRIV_PROC | DTRACE_PRIV_OWNER | DTRACE_PRIV_ZONEOWNER) typedef struct dtrace_ppriv { uint32_t dtpp_flags; /* privilege flags */ uid_t dtpp_uid; /* user ID */ zoneid_t dtpp_zoneid; /* zone ID */ } dtrace_ppriv_t; typedef struct dtrace_attribute { dtrace_stability_t dtat_name; /* entity name stability */ dtrace_stability_t dtat_data; /* entity data stability */ dtrace_class_t dtat_class; /* entity data dependency */ } dtrace_attribute_t; typedef struct dtrace_pattr { dtrace_attribute_t dtpa_provider; /* provider attributes */ dtrace_attribute_t dtpa_mod; /* module attributes */ dtrace_attribute_t dtpa_func; /* function attributes */ dtrace_attribute_t dtpa_name; /* name attributes */ dtrace_attribute_t dtpa_args; /* args[] attributes */ } dtrace_pattr_t; typedef struct dtrace_providerdesc { char dtvd_name[DTRACE_PROVNAMELEN]; /* provider name */ dtrace_pattr_t dtvd_attr; /* stability attributes */ dtrace_ppriv_t dtvd_priv; /* privileges required */ } dtrace_providerdesc_t; /* * DTrace Pseudodevice Interface * * DTrace is controlled through ioctl(2)'s to the in-kernel dtrace:dtrace * pseudodevice driver. These ioctls comprise the user-kernel interface to * DTrace. */ +#if defined(sun) #define DTRACEIOC (('d' << 24) | ('t' << 16) | ('r' << 8)) #define DTRACEIOC_PROVIDER (DTRACEIOC | 1) /* provider query */ #define DTRACEIOC_PROBES (DTRACEIOC | 2) /* probe query */ #define DTRACEIOC_BUFSNAP (DTRACEIOC | 4) /* snapshot buffer */ #define DTRACEIOC_PROBEMATCH (DTRACEIOC | 5) /* match probes */ #define DTRACEIOC_ENABLE (DTRACEIOC | 6) /* enable probes */ #define DTRACEIOC_AGGSNAP (DTRACEIOC | 7) /* snapshot agg. */ #define DTRACEIOC_EPROBE (DTRACEIOC | 8) /* get eprobe desc. */ #define DTRACEIOC_PROBEARG (DTRACEIOC | 9) /* get probe arg */ #define DTRACEIOC_CONF (DTRACEIOC | 10) /* get config. */ #define DTRACEIOC_STATUS (DTRACEIOC | 11) /* get status */ #define DTRACEIOC_GO (DTRACEIOC | 12) /* start tracing */ #define DTRACEIOC_STOP (DTRACEIOC | 13) /* stop tracing */ #define DTRACEIOC_AGGDESC (DTRACEIOC | 15) /* get agg. desc. */ #define DTRACEIOC_FORMAT (DTRACEIOC | 16) /* get format str */ #define DTRACEIOC_DOFGET (DTRACEIOC | 17) /* get DOF */ #define DTRACEIOC_REPLICATE (DTRACEIOC | 18) /* replicate enab */ +#else +#define DTRACEIOC_PROVIDER _IOWR('x',1,dtrace_providerdesc_t) + /* provider query */ +#define DTRACEIOC_PROBES _IOWR('x',2,dtrace_probedesc_t) + /* probe query */ +#define DTRACEIOC_BUFSNAP _IOW('x',4,dtrace_bufdesc_t *) + /* snapshot buffer */ +#define DTRACEIOC_PROBEMATCH _IOWR('x',5,dtrace_probedesc_t) + /* match probes */ +typedef struct { + void *dof; /* DOF userland address written to driver. */ + int n_matched; /* # matches returned by driver. */ +} dtrace_enable_io_t; +#define DTRACEIOC_ENABLE _IOWR('x',6,dtrace_enable_io_t) + /* enable probes */ +#define DTRACEIOC_AGGSNAP _IOW('x',7,dtrace_bufdesc_t *) + /* snapshot agg. */ +#define DTRACEIOC_EPROBE _IOW('x',8,dtrace_eprobedesc_t) + /* get eprobe desc. */ +#define DTRACEIOC_PROBEARG _IOWR('x',9,dtrace_argdesc_t) + /* get probe arg */ +#define DTRACEIOC_CONF _IOR('x',10,dtrace_conf_t) + /* get config. */ +#define DTRACEIOC_STATUS _IOR('x',11,dtrace_status_t) + /* get status */ +#define DTRACEIOC_GO _IOR('x',12,processorid_t) + /* start tracing */ +#define DTRACEIOC_STOP _IOWR('x',13,processorid_t) + /* stop tracing */ +#define DTRACEIOC_AGGDESC _IOW('x',15,dtrace_aggdesc_t *) + /* get agg. desc. */ +#define DTRACEIOC_FORMAT _IOWR('x',16,dtrace_fmtdesc_t) + /* get format str */ +#define DTRACEIOC_DOFGET _IOW('x',17,dof_hdr_t *) + /* get DOF */ +#define DTRACEIOC_REPLICATE _IOW('x',18,dtrace_repldesc_t) + /* replicate enab */ +#endif /* * DTrace Helpers * * In general, DTrace establishes probes in processes and takes actions on * processes without knowing their specific user-level structures. Instead of * existing in the framework, process-specific knowledge is contained by the * enabling D program -- which can apply process-specific knowledge by making * appropriate use of DTrace primitives like copyin() and copyinstr() to * operate on user-level data. However, there may exist some specific probes * of particular semantic relevance that the application developer may wish to * explicitly export. For example, an application may wish to export a probe * at the point that it begins and ends certain well-defined transactions. In * addition to providing probes, programs may wish to offer assistance for * certain actions. For example, in highly dynamic environments (e.g., Java), * it may be difficult to obtain a stack trace in terms of meaningful symbol * names (the translation from instruction addresses to corresponding symbol * names may only be possible in situ); these environments may wish to define * a series of actions to be applied in situ to obtain a meaningful stack * trace. * * These two mechanisms -- user-level statically defined tracing and assisting * DTrace actions -- are provided via DTrace _helpers_. Helpers are specified * via DOF, but unlike enabling DOF, helper DOF may contain definitions of * providers, probes and their arguments. If a helper wishes to provide * action assistance, probe descriptions and corresponding DIF actions may be * specified in the helper DOF. For such helper actions, however, the probe * description describes the specific helper: all DTrace helpers have the * provider name "dtrace" and the module name "helper", and the name of the * helper is contained in the function name (for example, the ustack() helper * is named "ustack"). Any helper-specific name may be contained in the name * (for example, if a helper were to have a constructor, it might be named * "dtrace:helper::init"). Helper actions are only called when the * action that they are helping is taken. Helper actions may only return DIF * expressions, and may only call the following subroutines: * * alloca() <= Allocates memory out of the consumer's scratch space * bcopy() <= Copies memory to scratch space * copyin() <= Copies memory from user-level into consumer's scratch * copyinto() <= Copies memory into a specific location in scratch * copyinstr() <= Copies a string into a specific location in scratch * * Helper actions may only access the following built-in variables: * * curthread <= Current kthread_t pointer * tid <= Current thread identifier * pid <= Current process identifier * ppid <= Parent process identifier * uid <= Current user ID * gid <= Current group ID * execname <= Current executable name * zonename <= Current zone name * * Helper actions may not manipulate or allocate dynamic variables, but they * may have clause-local and statically-allocated global variables. The * helper action variable state is specific to the helper action -- variables * used by the helper action may not be accessed outside of the helper * action, and the helper action may not access variables that like outside * of it. Helper actions may not load from kernel memory at-large; they are * restricting to loading current user state (via copyin() and variants) and * scratch space. As with probe enablings, helper actions are executed in * program order. The result of the helper action is the result of the last * executing helper expression. * * Helpers -- composed of either providers/probes or probes/actions (or both) * -- are added by opening the "helper" minor node, and issuing an ioctl(2) * (DTRACEHIOC_ADDDOF) that specifies the dof_helper_t structure. This * encapsulates the name and base address of the user-level library or * executable publishing the helpers and probes as well as the DOF that * contains the definitions of those helpers and probes. * * The DTRACEHIOC_ADD and DTRACEHIOC_REMOVE are left in place for legacy * helpers and should no longer be used. No other ioctls are valid on the * helper minor node. */ #define DTRACEHIOC (('d' << 24) | ('t' << 16) | ('h' << 8)) #define DTRACEHIOC_ADD (DTRACEHIOC | 1) /* add helper */ #define DTRACEHIOC_REMOVE (DTRACEHIOC | 2) /* remove helper */ #define DTRACEHIOC_ADDDOF (DTRACEHIOC | 3) /* add helper DOF */ typedef struct dof_helper { char dofhp_mod[DTRACE_MODNAMELEN]; /* executable or library name */ uint64_t dofhp_addr; /* base address of object */ uint64_t dofhp_dof; /* address of helper DOF */ } dof_helper_t; #define DTRACEMNR_DTRACE "dtrace" /* node for DTrace ops */ #define DTRACEMNR_HELPER "helper" /* node for helpers */ #define DTRACEMNRN_DTRACE 0 /* minor for DTrace ops */ #define DTRACEMNRN_HELPER 1 /* minor for helpers */ #define DTRACEMNRN_CLONE 2 /* first clone minor */ #ifdef _KERNEL /* * DTrace Provider API * * The following functions are implemented by the DTrace framework and are * used to implement separate in-kernel DTrace providers. Common functions * are provided in uts/common/os/dtrace.c. ISA-dependent subroutines are * defined in uts//dtrace/dtrace_asm.s or uts//dtrace/dtrace_isa.c. * * The provider API has two halves: the API that the providers consume from * DTrace, and the API that providers make available to DTrace. * * 1 Framework-to-Provider API * * 1.1 Overview * * The Framework-to-Provider API is represented by the dtrace_pops structure * that the provider passes to the framework when registering itself. This * structure consists of the following members: * * dtps_provide() <-- Provide all probes, all modules * dtps_provide_module() <-- Provide all probes in specified module * dtps_enable() <-- Enable specified probe * dtps_disable() <-- Disable specified probe * dtps_suspend() <-- Suspend specified probe * dtps_resume() <-- Resume specified probe * dtps_getargdesc() <-- Get the argument description for args[X] * dtps_getargval() <-- Get the value for an argX or args[X] variable * dtps_usermode() <-- Find out if the probe was fired in user mode * dtps_destroy() <-- Destroy all state associated with this probe * * 1.2 void dtps_provide(void *arg, const dtrace_probedesc_t *spec) * * 1.2.1 Overview * * Called to indicate that the provider should provide all probes. If the * specified description is non-NULL, dtps_provide() is being called because * no probe matched a specified probe -- if the provider has the ability to * create custom probes, it may wish to create a probe that matches the * specified description. * * 1.2.2 Arguments and notes * * The first argument is the cookie as passed to dtrace_register(). The * second argument is a pointer to a probe description that the provider may * wish to consider when creating custom probes. The provider is expected to * call back into the DTrace framework via dtrace_probe_create() to create * any necessary probes. dtps_provide() may be called even if the provider * has made available all probes; the provider should check the return value * of dtrace_probe_create() to handle this case. Note that the provider need * not implement both dtps_provide() and dtps_provide_module(); see * "Arguments and Notes" for dtrace_register(), below. * * 1.2.3 Return value * * None. * * 1.2.4 Caller's context * * dtps_provide() is typically called from open() or ioctl() context, but may * be called from other contexts as well. The DTrace framework is locked in * such a way that providers may not register or unregister. This means that * the provider may not call any DTrace API that affects its registration with * the framework, including dtrace_register(), dtrace_unregister(), * dtrace_invalidate(), and dtrace_condense(). However, the context is such * that the provider may (and indeed, is expected to) call probe-related * DTrace routines, including dtrace_probe_create(), dtrace_probe_lookup(), * and dtrace_probe_arg(). * - * 1.3 void dtps_provide_module(void *arg, struct modctl *mp) + * 1.3 void dtps_provide_module(void *arg, modctl_t *mp) * * 1.3.1 Overview * * Called to indicate that the provider should provide all probes in the * specified module. * * 1.3.2 Arguments and notes * * The first argument is the cookie as passed to dtrace_register(). The * second argument is a pointer to a modctl structure that indicates the * module for which probes should be created. * * 1.3.3 Return value * * None. * * 1.3.4 Caller's context * * dtps_provide_module() may be called from open() or ioctl() context, but * may also be called from a module loading context. mod_lock is held, and * the DTrace framework is locked in such a way that providers may not * register or unregister. This means that the provider may not call any * DTrace API that affects its registration with the framework, including * dtrace_register(), dtrace_unregister(), dtrace_invalidate(), and * dtrace_condense(). However, the context is such that the provider may (and * indeed, is expected to) call probe-related DTrace routines, including * dtrace_probe_create(), dtrace_probe_lookup(), and dtrace_probe_arg(). Note * that the provider need not implement both dtps_provide() and * dtps_provide_module(); see "Arguments and Notes" for dtrace_register(), * below. * * 1.4 void dtps_enable(void *arg, dtrace_id_t id, void *parg) * * 1.4.1 Overview * * Called to enable the specified probe. * * 1.4.2 Arguments and notes * * The first argument is the cookie as passed to dtrace_register(). The * second argument is the identifier of the probe to be enabled. The third * argument is the probe argument as passed to dtrace_probe_create(). * dtps_enable() will be called when a probe transitions from not being * enabled at all to having one or more ECB. The number of ECBs associated * with the probe may change without subsequent calls into the provider. * When the number of ECBs drops to zero, the provider will be explicitly * told to disable the probe via dtps_disable(). dtrace_probe() should never * be called for a probe identifier that hasn't been explicitly enabled via * dtps_enable(). * * 1.4.3 Return value * * None. * * 1.4.4 Caller's context * * The DTrace framework is locked in such a way that it may not be called * back into at all. cpu_lock is held. mod_lock is not held and may not * be acquired. * * 1.5 void dtps_disable(void *arg, dtrace_id_t id, void *parg) * * 1.5.1 Overview * * Called to disable the specified probe. * * 1.5.2 Arguments and notes * * The first argument is the cookie as passed to dtrace_register(). The * second argument is the identifier of the probe to be disabled. The third * argument is the probe argument as passed to dtrace_probe_create(). * dtps_disable() will be called when a probe transitions from being enabled * to having zero ECBs. dtrace_probe() should never be called for a probe * identifier that has been explicitly enabled via dtps_disable(). * * 1.5.3 Return value * * None. * * 1.5.4 Caller's context * * The DTrace framework is locked in such a way that it may not be called * back into at all. cpu_lock is held. mod_lock is not held and may not * be acquired. * * 1.6 void dtps_suspend(void *arg, dtrace_id_t id, void *parg) * * 1.6.1 Overview * * Called to suspend the specified enabled probe. This entry point is for * providers that may need to suspend some or all of their probes when CPUs * are being powered on or when the boot monitor is being entered for a * prolonged period of time. * * 1.6.2 Arguments and notes * * The first argument is the cookie as passed to dtrace_register(). The * second argument is the identifier of the probe to be suspended. The * third argument is the probe argument as passed to dtrace_probe_create(). * dtps_suspend will only be called on an enabled probe. Providers that * provide a dtps_suspend entry point will want to take roughly the action * that it takes for dtps_disable. * * 1.6.3 Return value * * None. * * 1.6.4 Caller's context * * Interrupts are disabled. The DTrace framework is in a state such that the * specified probe cannot be disabled or destroyed for the duration of * dtps_suspend(). As interrupts are disabled, the provider is afforded * little latitude; the provider is expected to do no more than a store to * memory. * * 1.7 void dtps_resume(void *arg, dtrace_id_t id, void *parg) * * 1.7.1 Overview * * Called to resume the specified enabled probe. This entry point is for * providers that may need to resume some or all of their probes after the * completion of an event that induced a call to dtps_suspend(). * * 1.7.2 Arguments and notes * * The first argument is the cookie as passed to dtrace_register(). The * second argument is the identifier of the probe to be resumed. The * third argument is the probe argument as passed to dtrace_probe_create(). * dtps_resume will only be called on an enabled probe. Providers that * provide a dtps_resume entry point will want to take roughly the action * that it takes for dtps_enable. * * 1.7.3 Return value * * None. * * 1.7.4 Caller's context * * Interrupts are disabled. The DTrace framework is in a state such that the * specified probe cannot be disabled or destroyed for the duration of * dtps_resume(). As interrupts are disabled, the provider is afforded * little latitude; the provider is expected to do no more than a store to * memory. * * 1.8 void dtps_getargdesc(void *arg, dtrace_id_t id, void *parg, * dtrace_argdesc_t *desc) * * 1.8.1 Overview * * Called to retrieve the argument description for an args[X] variable. * * 1.8.2 Arguments and notes * * The first argument is the cookie as passed to dtrace_register(). The * second argument is the identifier of the current probe. The third * argument is the probe argument as passed to dtrace_probe_create(). The * fourth argument is a pointer to the argument description. This * description is both an input and output parameter: it contains the * index of the desired argument in the dtargd_ndx field, and expects * the other fields to be filled in upon return. If there is no argument * corresponding to the specified index, the dtargd_ndx field should be set * to DTRACE_ARGNONE. * * 1.8.3 Return value * * None. The dtargd_ndx, dtargd_native, dtargd_xlate and dtargd_mapping * members of the dtrace_argdesc_t structure are all output values. * * 1.8.4 Caller's context * * dtps_getargdesc() is called from ioctl() context. mod_lock is held, and * the DTrace framework is locked in such a way that providers may not * register or unregister. This means that the provider may not call any * DTrace API that affects its registration with the framework, including * dtrace_register(), dtrace_unregister(), dtrace_invalidate(), and * dtrace_condense(). * * 1.9 uint64_t dtps_getargval(void *arg, dtrace_id_t id, void *parg, * int argno, int aframes) * * 1.9.1 Overview * * Called to retrieve a value for an argX or args[X] variable. * * 1.9.2 Arguments and notes * * The first argument is the cookie as passed to dtrace_register(). The * second argument is the identifier of the current probe. The third * argument is the probe argument as passed to dtrace_probe_create(). The * fourth argument is the number of the argument (the X in the example in * 1.9.1). The fifth argument is the number of stack frames that were used * to get from the actual place in the code that fired the probe to * dtrace_probe() itself, the so-called artificial frames. This argument may * be used to descend an appropriate number of frames to find the correct * values. If this entry point is left NULL, the dtrace_getarg() built-in * function is used. * * 1.9.3 Return value * * The value of the argument. * * 1.9.4 Caller's context * * This is called from within dtrace_probe() meaning that interrupts * are disabled. No locks should be taken within this entry point. * * 1.10 int dtps_usermode(void *arg, dtrace_id_t id, void *parg) * * 1.10.1 Overview * * Called to determine if the probe was fired in a user context. * * 1.10.2 Arguments and notes * * The first argument is the cookie as passed to dtrace_register(). The * second argument is the identifier of the current probe. The third * argument is the probe argument as passed to dtrace_probe_create(). This * entry point must not be left NULL for providers whose probes allow for * mixed mode tracing, that is to say those probes that can fire during * kernel- _or_ user-mode execution * * 1.10.3 Return value * * A boolean value. * * 1.10.4 Caller's context * * This is called from within dtrace_probe() meaning that interrupts * are disabled. No locks should be taken within this entry point. * * 1.11 void dtps_destroy(void *arg, dtrace_id_t id, void *parg) * * 1.11.1 Overview * * Called to destroy the specified probe. * * 1.11.2 Arguments and notes * * The first argument is the cookie as passed to dtrace_register(). The * second argument is the identifier of the probe to be destroyed. The third * argument is the probe argument as passed to dtrace_probe_create(). The * provider should free all state associated with the probe. The framework * guarantees that dtps_destroy() is only called for probes that have either * been disabled via dtps_disable() or were never enabled via dtps_enable(). * Once dtps_disable() has been called for a probe, no further call will be * made specifying the probe. * * 1.11.3 Return value * * None. * * 1.11.4 Caller's context * * The DTrace framework is locked in such a way that it may not be called * back into at all. mod_lock is held. cpu_lock is not held, and may not be * acquired. * * * 2 Provider-to-Framework API * * 2.1 Overview * * The Provider-to-Framework API provides the mechanism for the provider to * register itself with the DTrace framework, to create probes, to lookup * probes and (most importantly) to fire probes. The Provider-to-Framework * consists of: * * dtrace_register() <-- Register a provider with the DTrace framework * dtrace_unregister() <-- Remove a provider's DTrace registration * dtrace_invalidate() <-- Invalidate the specified provider * dtrace_condense() <-- Remove a provider's unenabled probes * dtrace_attached() <-- Indicates whether or not DTrace has attached * dtrace_probe_create() <-- Create a DTrace probe * dtrace_probe_lookup() <-- Lookup a DTrace probe based on its name * dtrace_probe_arg() <-- Return the probe argument for a specific probe * dtrace_probe() <-- Fire the specified probe * * 2.2 int dtrace_register(const char *name, const dtrace_pattr_t *pap, * uint32_t priv, cred_t *cr, const dtrace_pops_t *pops, void *arg, * dtrace_provider_id_t *idp) * * 2.2.1 Overview * * dtrace_register() registers the calling provider with the DTrace * framework. It should generally be called by DTrace providers in their * attach(9E) entry point. * * 2.2.2 Arguments and Notes * * The first argument is the name of the provider. The second argument is a * pointer to the stability attributes for the provider. The third argument * is the privilege flags for the provider, and must be some combination of: * * DTRACE_PRIV_NONE <= All users may enable probes from this provider * * DTRACE_PRIV_PROC <= Any user with privilege of PRIV_DTRACE_PROC may * enable probes from this provider * * DTRACE_PRIV_USER <= Any user with privilege of PRIV_DTRACE_USER may * enable probes from this provider * * DTRACE_PRIV_KERNEL <= Any user with privilege of PRIV_DTRACE_KERNEL * may enable probes from this provider * * DTRACE_PRIV_OWNER <= This flag places an additional constraint on * the privilege requirements above. These probes * require either (a) a user ID matching the user * ID of the cred passed in the fourth argument * or (b) the PRIV_PROC_OWNER privilege. * * DTRACE_PRIV_ZONEOWNER<= This flag places an additional constraint on * the privilege requirements above. These probes * require either (a) a zone ID matching the zone * ID of the cred passed in the fourth argument * or (b) the PRIV_PROC_ZONE privilege. * * Note that these flags designate the _visibility_ of the probes, not * the conditions under which they may or may not fire. * * The fourth argument is the credential that is associated with the * provider. This argument should be NULL if the privilege flags don't * include DTRACE_PRIV_OWNER or DTRACE_PRIV_ZONEOWNER. If non-NULL, the * framework stashes the uid and zoneid represented by this credential * for use at probe-time, in implicit predicates. These limit visibility * of the probes to users and/or zones which have sufficient privilege to * access them. * * The fifth argument is a DTrace provider operations vector, which provides * the implementation for the Framework-to-Provider API. (See Section 1, * above.) This must be non-NULL, and each member must be non-NULL. The * exceptions to this are (1) the dtps_provide() and dtps_provide_module() * members (if the provider so desires, _one_ of these members may be left * NULL -- denoting that the provider only implements the other) and (2) * the dtps_suspend() and dtps_resume() members, which must either both be * NULL or both be non-NULL. * * The sixth argument is a cookie to be specified as the first argument for * each function in the Framework-to-Provider API. This argument may have * any value. * * The final argument is a pointer to dtrace_provider_id_t. If * dtrace_register() successfully completes, the provider identifier will be * stored in the memory pointed to be this argument. This argument must be * non-NULL. * * 2.2.3 Return value * * On success, dtrace_register() returns 0 and stores the new provider's * identifier into the memory pointed to by the idp argument. On failure, * dtrace_register() returns an errno: * * EINVAL The arguments passed to dtrace_register() were somehow invalid. * This may because a parameter that must be non-NULL was NULL, * because the name was invalid (either empty or an illegal * provider name) or because the attributes were invalid. * * No other failure code is returned. * * 2.2.4 Caller's context * * dtrace_register() may induce calls to dtrace_provide(); the provider must * hold no locks across dtrace_register() that may also be acquired by * dtrace_provide(). cpu_lock and mod_lock must not be held. * * 2.3 int dtrace_unregister(dtrace_provider_t id) * * 2.3.1 Overview * * Unregisters the specified provider from the DTrace framework. It should * generally be called by DTrace providers in their detach(9E) entry point. * * 2.3.2 Arguments and Notes * * The only argument is the provider identifier, as returned from a * successful call to dtrace_register(). As a result of calling * dtrace_unregister(), the DTrace framework will call back into the provider * via the dtps_destroy() entry point. Once dtrace_unregister() successfully * completes, however, the DTrace framework will no longer make calls through * the Framework-to-Provider API. * * 2.3.3 Return value * * On success, dtrace_unregister returns 0. On failure, dtrace_unregister() * returns an errno: * * EBUSY There are currently processes that have the DTrace pseudodevice * open, or there exists an anonymous enabling that hasn't yet * been claimed. * * No other failure code is returned. * * 2.3.4 Caller's context * * Because a call to dtrace_unregister() may induce calls through the * Framework-to-Provider API, the caller may not hold any lock across * dtrace_register() that is also acquired in any of the Framework-to- * Provider API functions. Additionally, mod_lock may not be held. * * 2.4 void dtrace_invalidate(dtrace_provider_id_t id) * * 2.4.1 Overview * * Invalidates the specified provider. All subsequent probe lookups for the * specified provider will fail, but its probes will not be removed. * * 2.4.2 Arguments and note * * The only argument is the provider identifier, as returned from a * successful call to dtrace_register(). In general, a provider's probes * always remain valid; dtrace_invalidate() is a mechanism for invalidating * an entire provider, regardless of whether or not probes are enabled or * not. Note that dtrace_invalidate() will _not_ prevent already enabled * probes from firing -- it will merely prevent any new enablings of the * provider's probes. * * 2.5 int dtrace_condense(dtrace_provider_id_t id) * * 2.5.1 Overview * * Removes all the unenabled probes for the given provider. This function is * not unlike dtrace_unregister(), except that it doesn't remove the * provider just as many of its associated probes as it can. * * 2.5.2 Arguments and Notes * * As with dtrace_unregister(), the sole argument is the provider identifier * as returned from a successful call to dtrace_register(). As a result of * calling dtrace_condense(), the DTrace framework will call back into the * given provider's dtps_destroy() entry point for each of the provider's * unenabled probes. * * 2.5.3 Return value * * Currently, dtrace_condense() always returns 0. However, consumers of this * function should check the return value as appropriate; its behavior may * change in the future. * * 2.5.4 Caller's context * * As with dtrace_unregister(), the caller may not hold any lock across * dtrace_condense() that is also acquired in the provider's entry points. * Also, mod_lock may not be held. * * 2.6 int dtrace_attached() * * 2.6.1 Overview * * Indicates whether or not DTrace has attached. * * 2.6.2 Arguments and Notes * * For most providers, DTrace makes initial contact beyond registration. * That is, once a provider has registered with DTrace, it waits to hear * from DTrace to create probes. However, some providers may wish to * proactively create probes without first being told by DTrace to do so. * If providers wish to do this, they must first call dtrace_attached() to * determine if DTrace itself has attached. If dtrace_attached() returns 0, * the provider must not make any other Provider-to-Framework API call. * * 2.6.3 Return value * * dtrace_attached() returns 1 if DTrace has attached, 0 otherwise. * * 2.7 int dtrace_probe_create(dtrace_provider_t id, const char *mod, * const char *func, const char *name, int aframes, void *arg) * * 2.7.1 Overview * * Creates a probe with specified module name, function name, and name. * * 2.7.2 Arguments and Notes * * The first argument is the provider identifier, as returned from a * successful call to dtrace_register(). The second, third, and fourth * arguments are the module name, function name, and probe name, * respectively. Of these, module name and function name may both be NULL * (in which case the probe is considered to be unanchored), or they may both * be non-NULL. The name must be non-NULL, and must point to a non-empty * string. * * The fifth argument is the number of artificial stack frames that will be * found on the stack when dtrace_probe() is called for the new probe. These * artificial frames will be automatically be pruned should the stack() or * stackdepth() functions be called as part of one of the probe's ECBs. If * the parameter doesn't add an artificial frame, this parameter should be * zero. * * The final argument is a probe argument that will be passed back to the * provider when a probe-specific operation is called. (e.g., via * dtps_enable(), dtps_disable(), etc.) * * Note that it is up to the provider to be sure that the probe that it * creates does not already exist -- if the provider is unsure of the probe's * existence, it should assure its absence with dtrace_probe_lookup() before * calling dtrace_probe_create(). * * 2.7.3 Return value * * dtrace_probe_create() always succeeds, and always returns the identifier * of the newly-created probe. * * 2.7.4 Caller's context * * While dtrace_probe_create() is generally expected to be called from * dtps_provide() and/or dtps_provide_module(), it may be called from other * non-DTrace contexts. Neither cpu_lock nor mod_lock may be held. * * 2.8 dtrace_id_t dtrace_probe_lookup(dtrace_provider_t id, const char *mod, * const char *func, const char *name) * * 2.8.1 Overview * * Looks up a probe based on provdider and one or more of module name, * function name and probe name. * * 2.8.2 Arguments and Notes * * The first argument is the provider identifier, as returned from a * successful call to dtrace_register(). The second, third, and fourth * arguments are the module name, function name, and probe name, * respectively. Any of these may be NULL; dtrace_probe_lookup() will return * the identifier of the first probe that is provided by the specified * provider and matches all of the non-NULL matching criteria. * dtrace_probe_lookup() is generally used by a provider to be check the * existence of a probe before creating it with dtrace_probe_create(). * * 2.8.3 Return value * * If the probe exists, returns its identifier. If the probe does not exist, * return DTRACE_IDNONE. * * 2.8.4 Caller's context * * While dtrace_probe_lookup() is generally expected to be called from * dtps_provide() and/or dtps_provide_module(), it may also be called from * other non-DTrace contexts. Neither cpu_lock nor mod_lock may be held. * * 2.9 void *dtrace_probe_arg(dtrace_provider_t id, dtrace_id_t probe) * * 2.9.1 Overview * * Returns the probe argument associated with the specified probe. * * 2.9.2 Arguments and Notes * * The first argument is the provider identifier, as returned from a * successful call to dtrace_register(). The second argument is a probe * identifier, as returned from dtrace_probe_lookup() or * dtrace_probe_create(). This is useful if a probe has multiple * provider-specific components to it: the provider can create the probe * once with provider-specific state, and then add to the state by looking * up the probe based on probe identifier. * * 2.9.3 Return value * * Returns the argument associated with the specified probe. If the * specified probe does not exist, or if the specified probe is not provided * by the specified provider, NULL is returned. * * 2.9.4 Caller's context * * While dtrace_probe_arg() is generally expected to be called from * dtps_provide() and/or dtps_provide_module(), it may also be called from * other non-DTrace contexts. Neither cpu_lock nor mod_lock may be held. * * 2.10 void dtrace_probe(dtrace_id_t probe, uintptr_t arg0, uintptr_t arg1, * uintptr_t arg2, uintptr_t arg3, uintptr_t arg4) * * 2.10.1 Overview * * The epicenter of DTrace: fires the specified probes with the specified * arguments. * * 2.10.2 Arguments and Notes * * The first argument is a probe identifier as returned by * dtrace_probe_create() or dtrace_probe_lookup(). The second through sixth * arguments are the values to which the D variables "arg0" through "arg4" * will be mapped. * * dtrace_probe() should be called whenever the specified probe has fired -- * however the provider defines it. * * 2.10.3 Return value * * None. * * 2.10.4 Caller's context * * dtrace_probe() may be called in virtually any context: kernel, user, * interrupt, high-level interrupt, with arbitrary adaptive locks held, with * dispatcher locks held, with interrupts disabled, etc. The only latitude * that must be afforded to DTrace is the ability to make calls within * itself (and to its in-kernel subroutines) and the ability to access * arbitrary (but mapped) memory. On some platforms, this constrains * context. For example, on UltraSPARC, dtrace_probe() cannot be called * from any context in which TL is greater than zero. dtrace_probe() may * also not be called from any routine which may be called by dtrace_probe() * -- which includes functions in the DTrace framework and some in-kernel * DTrace subroutines. All such functions "dtrace_"; providers that * instrument the kernel arbitrarily should be sure to not instrument these * routines. */ typedef struct dtrace_pops { - void (*dtps_provide)(void *arg, const dtrace_probedesc_t *spec); - void (*dtps_provide_module)(void *arg, struct modctl *mp); + void (*dtps_provide)(void *arg, dtrace_probedesc_t *spec); + void (*dtps_provide_module)(void *arg, modctl_t *mp); void (*dtps_enable)(void *arg, dtrace_id_t id, void *parg); void (*dtps_disable)(void *arg, dtrace_id_t id, void *parg); void (*dtps_suspend)(void *arg, dtrace_id_t id, void *parg); void (*dtps_resume)(void *arg, dtrace_id_t id, void *parg); void (*dtps_getargdesc)(void *arg, dtrace_id_t id, void *parg, dtrace_argdesc_t *desc); uint64_t (*dtps_getargval)(void *arg, dtrace_id_t id, void *parg, int argno, int aframes); int (*dtps_usermode)(void *arg, dtrace_id_t id, void *parg); void (*dtps_destroy)(void *arg, dtrace_id_t id, void *parg); } dtrace_pops_t; typedef uintptr_t dtrace_provider_id_t; extern int dtrace_register(const char *, const dtrace_pattr_t *, uint32_t, cred_t *, const dtrace_pops_t *, void *, dtrace_provider_id_t *); extern int dtrace_unregister(dtrace_provider_id_t); extern int dtrace_condense(dtrace_provider_id_t); extern void dtrace_invalidate(dtrace_provider_id_t); -extern dtrace_id_t dtrace_probe_lookup(dtrace_provider_id_t, const char *, - const char *, const char *); +extern dtrace_id_t dtrace_probe_lookup(dtrace_provider_id_t, char *, + char *, char *); extern dtrace_id_t dtrace_probe_create(dtrace_provider_id_t, const char *, const char *, const char *, int, void *); extern void *dtrace_probe_arg(dtrace_provider_id_t, dtrace_id_t); extern void dtrace_probe(dtrace_id_t, uintptr_t arg0, uintptr_t arg1, uintptr_t arg2, uintptr_t arg3, uintptr_t arg4); /* * DTrace Meta Provider API * * The following functions are implemented by the DTrace framework and are * used to implement meta providers. Meta providers plug into the DTrace * framework and are used to instantiate new providers on the fly. At * present, there is only one type of meta provider and only one meta * provider may be registered with the DTrace framework at a time. The * sole meta provider type provides user-land static tracing facilities * by taking meta probe descriptions and adding a corresponding provider * into the DTrace framework. * * 1 Framework-to-Provider * * 1.1 Overview * * The Framework-to-Provider API is represented by the dtrace_mops structure * that the meta provider passes to the framework when registering itself as * a meta provider. This structure consists of the following members: * * dtms_create_probe() <-- Add a new probe to a created provider * dtms_provide_pid() <-- Create a new provider for a given process * dtms_remove_pid() <-- Remove a previously created provider * * 1.2 void dtms_create_probe(void *arg, void *parg, * dtrace_helper_probedesc_t *probedesc); * * 1.2.1 Overview * * Called by the DTrace framework to create a new probe in a provider * created by this meta provider. * * 1.2.2 Arguments and notes * * The first argument is the cookie as passed to dtrace_meta_register(). * The second argument is the provider cookie for the associated provider; * this is obtained from the return value of dtms_provide_pid(). The third * argument is the helper probe description. * * 1.2.3 Return value * * None * * 1.2.4 Caller's context * * dtms_create_probe() is called from either ioctl() or module load context. * The DTrace framework is locked in such a way that meta providers may not * register or unregister. This means that the meta provider cannot call * dtrace_meta_register() or dtrace_meta_unregister(). However, the context is * such that the provider may (and is expected to) call provider-related * DTrace provider APIs including dtrace_probe_create(). * * 1.3 void *dtms_provide_pid(void *arg, dtrace_meta_provider_t *mprov, * pid_t pid) * * 1.3.1 Overview * * Called by the DTrace framework to instantiate a new provider given the * description of the provider and probes in the mprov argument. The * meta provider should call dtrace_register() to insert the new provider * into the DTrace framework. * * 1.3.2 Arguments and notes * * The first argument is the cookie as passed to dtrace_meta_register(). * The second argument is a pointer to a structure describing the new * helper provider. The third argument is the process identifier for * process associated with this new provider. Note that the name of the * provider as passed to dtrace_register() should be the contatenation of * the dtmpb_provname member of the mprov argument and the processs * identifier as a string. * * 1.3.3 Return value * * The cookie for the provider that the meta provider creates. This is * the same value that it passed to dtrace_register(). * * 1.3.4 Caller's context * * dtms_provide_pid() is called from either ioctl() or module load context. * The DTrace framework is locked in such a way that meta providers may not * register or unregister. This means that the meta provider cannot call * dtrace_meta_register() or dtrace_meta_unregister(). However, the context * is such that the provider may -- and is expected to -- call * provider-related DTrace provider APIs including dtrace_register(). * * 1.4 void dtms_remove_pid(void *arg, dtrace_meta_provider_t *mprov, * pid_t pid) * * 1.4.1 Overview * * Called by the DTrace framework to remove a provider that had previously * been instantiated via the dtms_provide_pid() entry point. The meta * provider need not remove the provider immediately, but this entry * point indicates that the provider should be removed as soon as possible * using the dtrace_unregister() API. * * 1.4.2 Arguments and notes * * The first argument is the cookie as passed to dtrace_meta_register(). * The second argument is a pointer to a structure describing the helper * provider. The third argument is the process identifier for process * associated with this new provider. * * 1.4.3 Return value * * None * * 1.4.4 Caller's context * * dtms_remove_pid() is called from either ioctl() or exit() context. * The DTrace framework is locked in such a way that meta providers may not * register or unregister. This means that the meta provider cannot call * dtrace_meta_register() or dtrace_meta_unregister(). However, the context * is such that the provider may -- and is expected to -- call * provider-related DTrace provider APIs including dtrace_unregister(). */ typedef struct dtrace_helper_probedesc { char *dthpb_mod; /* probe module */ char *dthpb_func; /* probe function */ char *dthpb_name; /* probe name */ uint64_t dthpb_base; /* base address */ uint32_t *dthpb_offs; /* offsets array */ uint32_t *dthpb_enoffs; /* is-enabled offsets array */ uint32_t dthpb_noffs; /* offsets count */ uint32_t dthpb_nenoffs; /* is-enabled offsets count */ uint8_t *dthpb_args; /* argument mapping array */ uint8_t dthpb_xargc; /* translated argument count */ uint8_t dthpb_nargc; /* native argument count */ char *dthpb_xtypes; /* translated types strings */ char *dthpb_ntypes; /* native types strings */ } dtrace_helper_probedesc_t; typedef struct dtrace_helper_provdesc { char *dthpv_provname; /* provider name */ dtrace_pattr_t dthpv_pattr; /* stability attributes */ } dtrace_helper_provdesc_t; typedef struct dtrace_mops { void (*dtms_create_probe)(void *, void *, dtrace_helper_probedesc_t *); void *(*dtms_provide_pid)(void *, dtrace_helper_provdesc_t *, pid_t); void (*dtms_remove_pid)(void *, dtrace_helper_provdesc_t *, pid_t); } dtrace_mops_t; typedef uintptr_t dtrace_meta_provider_id_t; extern int dtrace_meta_register(const char *, const dtrace_mops_t *, void *, dtrace_meta_provider_id_t *); extern int dtrace_meta_unregister(dtrace_meta_provider_id_t); /* * DTrace Kernel Hooks * * The following functions are implemented by the base kernel and form a set of * hooks used by the DTrace framework. DTrace hooks are implemented in either * uts/common/os/dtrace_subr.c, an ISA-specific assembly file, or in a * uts//os/dtrace_subr.c corresponding to each hardware platform. */ typedef enum dtrace_vtime_state { DTRACE_VTIME_INACTIVE = 0, /* No DTrace, no TNF */ DTRACE_VTIME_ACTIVE, /* DTrace virtual time, no TNF */ DTRACE_VTIME_INACTIVE_TNF, /* No DTrace, TNF active */ DTRACE_VTIME_ACTIVE_TNF /* DTrace virtual time _and_ TNF */ } dtrace_vtime_state_t; +#if defined(sun) extern dtrace_vtime_state_t dtrace_vtime_active; +#endif extern void dtrace_vtime_switch(kthread_t *next); extern void dtrace_vtime_enable_tnf(void); extern void dtrace_vtime_disable_tnf(void); extern void dtrace_vtime_enable(void); extern void dtrace_vtime_disable(void); struct regs; +#if defined(sun) extern int (*dtrace_pid_probe_ptr)(struct regs *); extern int (*dtrace_return_probe_ptr)(struct regs *); extern void (*dtrace_fasttrap_fork_ptr)(proc_t *, proc_t *); extern void (*dtrace_fasttrap_exec_ptr)(proc_t *); extern void (*dtrace_fasttrap_exit_ptr)(proc_t *); extern void dtrace_fasttrap_fork(proc_t *, proc_t *); +#endif typedef uintptr_t dtrace_icookie_t; typedef void (*dtrace_xcall_t)(void *); extern dtrace_icookie_t dtrace_interrupt_disable(void); extern void dtrace_interrupt_enable(dtrace_icookie_t); extern void dtrace_membar_producer(void); extern void dtrace_membar_consumer(void); extern void (*dtrace_cpu_init)(processorid_t); -extern void (*dtrace_modload)(struct modctl *); -extern void (*dtrace_modunload)(struct modctl *); -extern void (*dtrace_helpers_cleanup)(); +extern void (*dtrace_modload)(modctl_t *); +extern void (*dtrace_modunload)(modctl_t *); +extern void (*dtrace_helpers_cleanup)(void); extern void (*dtrace_helpers_fork)(proc_t *parent, proc_t *child); -extern void (*dtrace_cpustart_init)(); -extern void (*dtrace_cpustart_fini)(); +extern void (*dtrace_cpustart_init)(void); +extern void (*dtrace_cpustart_fini)(void); -extern void (*dtrace_debugger_init)(); -extern void (*dtrace_debugger_fini)(); +extern void (*dtrace_debugger_init)(void); +extern void (*dtrace_debugger_fini)(void); extern dtrace_cacheid_t dtrace_predcache_id; +#if defined(sun) extern hrtime_t dtrace_gethrtime(void); +#else +void dtrace_debug_printf(const char *, ...) __printflike(1, 2); +#endif extern void dtrace_sync(void); extern void dtrace_toxic_ranges(void (*)(uintptr_t, uintptr_t)); extern void dtrace_xcall(processorid_t, dtrace_xcall_t, void *); extern void dtrace_vpanic(const char *, __va_list); extern void dtrace_panic(const char *, ...); extern int dtrace_safe_defer_signal(void); extern void dtrace_safe_synchronous_signal(void); extern int dtrace_mach_aframes(void); #if defined(__i386) || defined(__amd64) extern int dtrace_instr_size(uchar_t *instr); extern int dtrace_instr_size_isa(uchar_t *, model_t, int *); extern void dtrace_invop_add(int (*)(uintptr_t, uintptr_t *, uintptr_t)); extern void dtrace_invop_remove(int (*)(uintptr_t, uintptr_t *, uintptr_t)); extern void dtrace_invop_callsite(void); #endif #ifdef __sparc extern int dtrace_blksuword32(uintptr_t, uint32_t *, int); extern void dtrace_getfsr(uint64_t *); #endif #define DTRACE_CPUFLAG_ISSET(flag) \ - (cpu_core[CPU->cpu_id].cpuc_dtrace_flags & (flag)) + (cpu_core[curcpu].cpuc_dtrace_flags & (flag)) #define DTRACE_CPUFLAG_SET(flag) \ - (cpu_core[CPU->cpu_id].cpuc_dtrace_flags |= (flag)) + (cpu_core[curcpu].cpuc_dtrace_flags |= (flag)) #define DTRACE_CPUFLAG_CLEAR(flag) \ - (cpu_core[CPU->cpu_id].cpuc_dtrace_flags &= ~(flag)) + (cpu_core[curcpu].cpuc_dtrace_flags &= ~(flag)) #endif /* _KERNEL */ #endif /* _ASM */ #if defined(__i386) || defined(__amd64) #define DTRACE_INVOP_PUSHL_EBP 1 #define DTRACE_INVOP_POPL_EBP 2 #define DTRACE_INVOP_LEAVE 3 #define DTRACE_INVOP_NOP 4 #define DTRACE_INVOP_RET 5 #endif #ifdef __cplusplus } #endif #endif /* _SYS_DTRACE_H */ Index: head/sys/cddl/contrib/opensolaris/uts/common/sys/dtrace_impl.h =================================================================== --- head/sys/cddl/contrib/opensolaris/uts/common/sys/dtrace_impl.h (revision 179197) +++ head/sys/cddl/contrib/opensolaris/uts/common/sys/dtrace_impl.h (revision 179198) @@ -1,1298 +1,1316 @@ /* * CDDL HEADER START * * The contents of this file are subject to the terms of the * Common Development and Distribution License (the "License"). * You may not use this file except in compliance with the License. * * You can obtain a copy of the license at usr/src/OPENSOLARIS.LICENSE * or http://www.opensolaris.org/os/licensing. * See the License for the specific language governing permissions * and limitations under the License. * * When distributing Covered Code, include this CDDL HEADER in each * file and include the License file at usr/src/OPENSOLARIS.LICENSE. * If applicable, add the following below this CDDL HEADER, with the * fields enclosed by brackets "[]" replaced with your own identifying * information: Portions Copyright [yyyy] [name of copyright owner] * * CDDL HEADER END */ /* * Copyright 2007 Sun Microsystems, Inc. All rights reserved. * Use is subject to license terms. */ #ifndef _SYS_DTRACE_IMPL_H #define _SYS_DTRACE_IMPL_H #pragma ident "%Z%%M% %I% %E% SMI" #ifdef __cplusplus extern "C" { #endif /* * DTrace Dynamic Tracing Software: Kernel Implementation Interfaces * * Note: The contents of this file are private to the implementation of the * Solaris system and DTrace subsystem and are subject to change at any time * without notice. Applications and drivers using these interfaces will fail * to run on future releases. These interfaces should not be used for any * purpose except those expressly outlined in dtrace(7D) and libdtrace(3LIB). * Please refer to the "Solaris Dynamic Tracing Guide" for more information. */ #include +#if !defined(sun) +#ifdef __sparcv9 +typedef uint32_t pc_t; +#else +typedef uintptr_t pc_t; +#endif +typedef u_long greg_t; +#endif /* * DTrace Implementation Constants and Typedefs */ #define DTRACE_MAXPROPLEN 128 #define DTRACE_DYNVAR_CHUNKSIZE 256 struct dtrace_probe; struct dtrace_ecb; struct dtrace_predicate; struct dtrace_action; struct dtrace_provider; struct dtrace_state; typedef struct dtrace_probe dtrace_probe_t; typedef struct dtrace_ecb dtrace_ecb_t; typedef struct dtrace_predicate dtrace_predicate_t; typedef struct dtrace_action dtrace_action_t; typedef struct dtrace_provider dtrace_provider_t; typedef struct dtrace_meta dtrace_meta_t; typedef struct dtrace_state dtrace_state_t; typedef uint32_t dtrace_optid_t; typedef uint32_t dtrace_specid_t; typedef uint64_t dtrace_genid_t; /* * DTrace Probes * * The probe is the fundamental unit of the DTrace architecture. Probes are * created by DTrace providers, and managed by the DTrace framework. A probe * is identified by a unique tuple, and has * a unique probe identifier assigned to it. (Some probes are not associated * with a specific point in text; these are called _unanchored probes_ and have * no module or function associated with them.) Probes are represented as a * dtrace_probe structure. To allow quick lookups based on each element of the * probe tuple, probes are hashed by each of provider, module, function and * name. (If a lookup is performed based on a regular expression, a * dtrace_probekey is prepared, and a linear search is performed.) Each probe * is additionally pointed to by a linear array indexed by its identifier. The * identifier is the provider's mechanism for indicating to the DTrace * framework that a probe has fired: the identifier is passed as the first * argument to dtrace_probe(), where it is then mapped into the corresponding * dtrace_probe structure. From the dtrace_probe structure, dtrace_probe() can * iterate over the probe's list of enabling control blocks; see "DTrace * Enabling Control Blocks", below.) */ struct dtrace_probe { dtrace_id_t dtpr_id; /* probe identifier */ dtrace_ecb_t *dtpr_ecb; /* ECB list; see below */ dtrace_ecb_t *dtpr_ecb_last; /* last ECB in list */ void *dtpr_arg; /* provider argument */ dtrace_cacheid_t dtpr_predcache; /* predicate cache ID */ int dtpr_aframes; /* artificial frames */ dtrace_provider_t *dtpr_provider; /* pointer to provider */ char *dtpr_mod; /* probe's module name */ char *dtpr_func; /* probe's function name */ char *dtpr_name; /* probe's name */ dtrace_probe_t *dtpr_nextmod; /* next in module hash */ dtrace_probe_t *dtpr_prevmod; /* previous in module hash */ dtrace_probe_t *dtpr_nextfunc; /* next in function hash */ dtrace_probe_t *dtpr_prevfunc; /* previous in function hash */ dtrace_probe_t *dtpr_nextname; /* next in name hash */ dtrace_probe_t *dtpr_prevname; /* previous in name hash */ dtrace_genid_t dtpr_gen; /* probe generation ID */ }; typedef int dtrace_probekey_f(const char *, const char *, int); typedef struct dtrace_probekey { - const char *dtpk_prov; /* provider name to match */ + char *dtpk_prov; /* provider name to match */ dtrace_probekey_f *dtpk_pmatch; /* provider matching function */ - const char *dtpk_mod; /* module name to match */ + char *dtpk_mod; /* module name to match */ dtrace_probekey_f *dtpk_mmatch; /* module matching function */ - const char *dtpk_func; /* func name to match */ + char *dtpk_func; /* func name to match */ dtrace_probekey_f *dtpk_fmatch; /* func matching function */ - const char *dtpk_name; /* name to match */ + char *dtpk_name; /* name to match */ dtrace_probekey_f *dtpk_nmatch; /* name matching function */ dtrace_id_t dtpk_id; /* identifier to match */ } dtrace_probekey_t; typedef struct dtrace_hashbucket { struct dtrace_hashbucket *dthb_next; /* next on hash chain */ dtrace_probe_t *dthb_chain; /* chain of probes */ int dthb_len; /* number of probes here */ } dtrace_hashbucket_t; typedef struct dtrace_hash { dtrace_hashbucket_t **dth_tab; /* hash table */ int dth_size; /* size of hash table */ int dth_mask; /* mask to index into table */ int dth_nbuckets; /* total number of buckets */ uintptr_t dth_nextoffs; /* offset of next in probe */ uintptr_t dth_prevoffs; /* offset of prev in probe */ uintptr_t dth_stroffs; /* offset of str in probe */ } dtrace_hash_t; /* * DTrace Enabling Control Blocks * * When a provider wishes to fire a probe, it calls into dtrace_probe(), * passing the probe identifier as the first argument. As described above, * dtrace_probe() maps the identifier into a pointer to a dtrace_probe_t * structure. This structure contains information about the probe, and a * pointer to the list of Enabling Control Blocks (ECBs). Each ECB points to * DTrace consumer state, and contains an optional predicate, and a list of * actions. (Shown schematically below.) The ECB abstraction allows a single * probe to be multiplexed across disjoint consumers, or across disjoint * enablings of a single probe within one consumer. * * Enabling Control Block * dtrace_ecb_t * +------------------------+ * | dtrace_epid_t ---------+--------------> Enabled Probe ID (EPID) * | dtrace_state_t * ------+--------------> State associated with this ECB * | dtrace_predicate_t * --+---------+ * | dtrace_action_t * -----+----+ | * | dtrace_ecb_t * ---+ | | | Predicate (if any) * +-------------------+----+ | | dtrace_predicate_t * | | +---> +--------------------+ * | | | dtrace_difo_t * ---+----> DIFO * | | +--------------------+ * | | * Next ECB | | Action * (if any) | | dtrace_action_t * : +--> +-------------------+ * : | dtrace_actkind_t -+------> kind * v | dtrace_difo_t * --+------> DIFO (if any) * | dtrace_recdesc_t -+------> record descr. * | dtrace_action_t * +------+ * +-------------------+ | * | Next action * +-------------------------------+ (if any) * | * | Action * | dtrace_action_t * +--> +-------------------+ * | dtrace_actkind_t -+------> kind * | dtrace_difo_t * --+------> DIFO (if any) * | dtrace_action_t * +------+ * +-------------------+ | * | Next action * +-------------------------------+ (if any) * | * : * v * * * dtrace_probe() iterates over the ECB list. If the ECB needs less space * than is available in the principal buffer, the ECB is processed: if the * predicate is non-NULL, the DIF object is executed. If the result is * non-zero, the action list is processed, with each action being executed * accordingly. When the action list has been completely executed, processing * advances to the next ECB. processing advances to the next ECB. If the * result is non-zero; For each ECB, it first determines the The ECB * abstraction allows disjoint consumers to multiplex on single probes. */ struct dtrace_ecb { dtrace_epid_t dte_epid; /* enabled probe ID */ uint32_t dte_alignment; /* required alignment */ size_t dte_needed; /* bytes needed */ size_t dte_size; /* total size of payload */ dtrace_predicate_t *dte_predicate; /* predicate, if any */ dtrace_action_t *dte_action; /* actions, if any */ dtrace_ecb_t *dte_next; /* next ECB on probe */ dtrace_state_t *dte_state; /* pointer to state */ uint32_t dte_cond; /* security condition */ dtrace_probe_t *dte_probe; /* pointer to probe */ dtrace_action_t *dte_action_last; /* last action on ECB */ uint64_t dte_uarg; /* library argument */ }; struct dtrace_predicate { dtrace_difo_t *dtp_difo; /* DIF object */ dtrace_cacheid_t dtp_cacheid; /* cache identifier */ int dtp_refcnt; /* reference count */ }; struct dtrace_action { dtrace_actkind_t dta_kind; /* kind of action */ uint16_t dta_intuple; /* boolean: in aggregation */ uint32_t dta_refcnt; /* reference count */ dtrace_difo_t *dta_difo; /* pointer to DIFO */ dtrace_recdesc_t dta_rec; /* record description */ dtrace_action_t *dta_prev; /* previous action */ dtrace_action_t *dta_next; /* next action */ }; typedef struct dtrace_aggregation { dtrace_action_t dtag_action; /* action; must be first */ dtrace_aggid_t dtag_id; /* identifier */ dtrace_ecb_t *dtag_ecb; /* corresponding ECB */ dtrace_action_t *dtag_first; /* first action in tuple */ uint32_t dtag_base; /* base of aggregation */ uint8_t dtag_hasarg; /* boolean: has argument */ uint64_t dtag_initial; /* initial value */ void (*dtag_aggregate)(uint64_t *, uint64_t, uint64_t); } dtrace_aggregation_t; /* * DTrace Buffers * * Principal buffers, aggregation buffers, and speculative buffers are all * managed with the dtrace_buffer structure. By default, this structure * includes twin data buffers -- dtb_tomax and dtb_xamot -- that serve as the * active and passive buffers, respectively. For speculative buffers, * dtb_xamot will be NULL; for "ring" and "fill" buffers, dtb_xamot will point * to a scratch buffer. For all buffer types, the dtrace_buffer structure is * always allocated on a per-CPU basis; a single dtrace_buffer structure is * never shared among CPUs. (That is, there is never true sharing of the * dtrace_buffer structure; to prevent false sharing of the structure, it must * always be aligned to the coherence granularity -- generally 64 bytes.) * * One of the critical design decisions of DTrace is that a given ECB always * stores the same quantity and type of data. This is done to assure that the * only metadata required for an ECB's traced data is the EPID. That is, from * the EPID, the consumer can determine the data layout. (The data buffer * layout is shown schematically below.) By assuring that one can determine * data layout from the EPID, the metadata stream can be separated from the * data stream -- simplifying the data stream enormously. * * base of data buffer ---> +------+--------------------+------+ * | EPID | data | EPID | * +------+--------+------+----+------+ * | data | EPID | data | * +---------------+------+-----------+ * | data, cont. | * +------+--------------------+------+ * | EPID | data | | * +------+--------------------+ | * | || | * | || | * | \/ | * : : * . . * . . * . . * : : * | | * limit of data buffer ---> +----------------------------------+ * * When evaluating an ECB, dtrace_probe() determines if the ECB's needs of the * principal buffer (both scratch and payload) exceed the available space. If * the ECB's needs exceed available space (and if the principal buffer policy * is the default "switch" policy), the ECB is dropped, the buffer's drop count * is incremented, and processing advances to the next ECB. If the ECB's needs * can be met with the available space, the ECB is processed, but the offset in * the principal buffer is only advanced if the ECB completes processing * without error. * * When a buffer is to be switched (either because the buffer is the principal * buffer with a "switch" policy or because it is an aggregation buffer), a * cross call is issued to the CPU associated with the buffer. In the cross * call context, interrupts are disabled, and the active and the inactive * buffers are atomically switched. This involves switching the data pointers, * copying the various state fields (offset, drops, errors, etc.) into their * inactive equivalents, and clearing the state fields. Because interrupts are * disabled during this procedure, the switch is guaranteed to appear atomic to * dtrace_probe(). * * DTrace Ring Buffering * * To process a ring buffer correctly, one must know the oldest valid record. * Processing starts at the oldest record in the buffer and continues until * the end of the buffer is reached. Processing then resumes starting with * the record stored at offset 0 in the buffer, and continues until the * youngest record is processed. If trace records are of a fixed-length, * determining the oldest record is trivial: * * - If the ring buffer has not wrapped, the oldest record is the record * stored at offset 0. * * - If the ring buffer has wrapped, the oldest record is the record stored * at the current offset. * * With variable length records, however, just knowing the current offset * doesn't suffice for determining the oldest valid record: assuming that one * allows for arbitrary data, one has no way of searching forward from the * current offset to find the oldest valid record. (That is, one has no way * of separating data from metadata.) It would be possible to simply refuse to * process any data in the ring buffer between the current offset and the * limit, but this leaves (potentially) an enormous amount of otherwise valid * data unprocessed. * * To effect ring buffering, we track two offsets in the buffer: the current * offset and the _wrapped_ offset. If a request is made to reserve some * amount of data, and the buffer has wrapped, the wrapped offset is * incremented until the wrapped offset minus the current offset is greater * than or equal to the reserve request. This is done by repeatedly looking * up the ECB corresponding to the EPID at the current wrapped offset, and * incrementing the wrapped offset by the size of the data payload * corresponding to that ECB. If this offset is greater than or equal to the * limit of the data buffer, the wrapped offset is set to 0. Thus, the * current offset effectively "chases" the wrapped offset around the buffer. * Schematically: * * base of data buffer ---> +------+--------------------+------+ * | EPID | data | EPID | * +------+--------+------+----+------+ * | data | EPID | data | * +---------------+------+-----------+ * | data, cont. | * +------+---------------------------+ * | EPID | data | * current offset ---> +------+---------------------------+ * | invalid data | * wrapped offset ---> +------+--------------------+------+ * | EPID | data | EPID | * +------+--------+------+----+------+ * | data | EPID | data | * +---------------+------+-----------+ * : : * . . * . ... valid data ... . * . . * : : * +------+-------------+------+------+ * | EPID | data | EPID | data | * +------+------------++------+------+ * | data, cont. | leftover | * limit of data buffer ---> +-------------------+--------------+ * * If the amount of requested buffer space exceeds the amount of space * available between the current offset and the end of the buffer: * * (1) all words in the data buffer between the current offset and the limit * of the data buffer (marked "leftover", above) are set to * DTRACE_EPIDNONE * * (2) the wrapped offset is set to zero * * (3) the iteration process described above occurs until the wrapped offset * is greater than the amount of desired space. * * The wrapped offset is implemented by (re-)using the inactive offset. * In a "switch" buffer policy, the inactive offset stores the offset in * the inactive buffer; in a "ring" buffer policy, it stores the wrapped * offset. * * DTrace Scratch Buffering * * Some ECBs may wish to allocate dynamically-sized temporary scratch memory. * To accommodate such requests easily, scratch memory may be allocated in * the buffer beyond the current offset plus the needed memory of the current * ECB. If there isn't sufficient room in the buffer for the requested amount * of scratch space, the allocation fails and an error is generated. Scratch * memory is tracked in the dtrace_mstate_t and is automatically freed when * the ECB ceases processing. Note that ring buffers cannot allocate their * scratch from the principal buffer -- lest they needlessly overwrite older, * valid data. Ring buffers therefore have their own dedicated scratch buffer * from which scratch is allocated. */ #define DTRACEBUF_RING 0x0001 /* bufpolicy set to "ring" */ #define DTRACEBUF_FILL 0x0002 /* bufpolicy set to "fill" */ #define DTRACEBUF_NOSWITCH 0x0004 /* do not switch buffer */ #define DTRACEBUF_WRAPPED 0x0008 /* ring buffer has wrapped */ #define DTRACEBUF_DROPPED 0x0010 /* drops occurred */ #define DTRACEBUF_ERROR 0x0020 /* errors occurred */ #define DTRACEBUF_FULL 0x0040 /* "fill" buffer is full */ #define DTRACEBUF_CONSUMED 0x0080 /* buffer has been consumed */ #define DTRACEBUF_INACTIVE 0x0100 /* buffer is not yet active */ typedef struct dtrace_buffer { uint64_t dtb_offset; /* current offset in buffer */ uint64_t dtb_size; /* size of buffer */ uint32_t dtb_flags; /* flags */ uint32_t dtb_drops; /* number of drops */ caddr_t dtb_tomax; /* active buffer */ caddr_t dtb_xamot; /* inactive buffer */ uint32_t dtb_xamot_flags; /* inactive flags */ uint32_t dtb_xamot_drops; /* drops in inactive buffer */ uint64_t dtb_xamot_offset; /* offset in inactive buffer */ uint32_t dtb_errors; /* number of errors */ uint32_t dtb_xamot_errors; /* errors in inactive buffer */ #ifndef _LP64 uint64_t dtb_pad1; #endif } dtrace_buffer_t; /* * DTrace Aggregation Buffers * * Aggregation buffers use much of the same mechanism as described above * ("DTrace Buffers"). However, because an aggregation is fundamentally a * hash, there exists dynamic metadata associated with an aggregation buffer * that is not associated with other kinds of buffers. This aggregation * metadata is _only_ relevant for the in-kernel implementation of * aggregations; it is not actually relevant to user-level consumers. To do * this, we allocate dynamic aggregation data (hash keys and hash buckets) * starting below the _limit_ of the buffer, and we allocate data from the * _base_ of the buffer. When the aggregation buffer is copied out, _only_ the * data is copied out; the metadata is simply discarded. Schematically, * aggregation buffers look like: * * base of data buffer ---> +-------+------+-----------+-------+ * | aggid | key | value | aggid | * +-------+------+-----------+-------+ * | key | * +-------+-------+-----+------------+ * | value | aggid | key | value | * +-------+------++-----+------+-----+ * | aggid | key | value | | * +-------+------+-------------+ | * | || | * | || | * | \/ | * : : * . . * . . * . . * : : * | /\ | * | || +------------+ * | || | | * +---------------------+ | * | hash keys | * | (dtrace_aggkey structures) | * | | * +----------------------------------+ * | hash buckets | * | (dtrace_aggbuffer structure) | * | | * limit of data buffer ---> +----------------------------------+ * * * As implied above, just as we assure that ECBs always store a constant * amount of data, we assure that a given aggregation -- identified by its * aggregation ID -- always stores data of a constant quantity and type. * As with EPIDs, this allows the aggregation ID to serve as the metadata for a * given record. * * Note that the size of the dtrace_aggkey structure must be sizeof (uintptr_t) * aligned. (If this the structure changes such that this becomes false, an * assertion will fail in dtrace_aggregate().) */ typedef struct dtrace_aggkey { uint32_t dtak_hashval; /* hash value */ uint32_t dtak_action:4; /* action -- 4 bits */ uint32_t dtak_size:28; /* size -- 28 bits */ caddr_t dtak_data; /* data pointer */ struct dtrace_aggkey *dtak_next; /* next in hash chain */ } dtrace_aggkey_t; typedef struct dtrace_aggbuffer { uintptr_t dtagb_hashsize; /* number of buckets */ uintptr_t dtagb_free; /* free list of keys */ dtrace_aggkey_t **dtagb_hash; /* hash table */ } dtrace_aggbuffer_t; /* * DTrace Speculations * * Speculations have a per-CPU buffer and a global state. Once a speculation * buffer has been comitted or discarded, it cannot be reused until all CPUs * have taken the same action (commit or discard) on their respective * speculative buffer. However, because DTrace probes may execute in arbitrary * context, other CPUs cannot simply be cross-called at probe firing time to * perform the necessary commit or discard. The speculation states thus * optimize for the case that a speculative buffer is only active on one CPU at * the time of a commit() or discard() -- for if this is the case, other CPUs * need not take action, and the speculation is immediately available for * reuse. If the speculation is active on multiple CPUs, it must be * asynchronously cleaned -- potentially leading to a higher rate of dirty * speculative drops. The speculation states are as follows: * * DTRACESPEC_INACTIVE <= Initial state; inactive speculation * DTRACESPEC_ACTIVE <= Allocated, but not yet speculatively traced to * DTRACESPEC_ACTIVEONE <= Speculatively traced to on one CPU * DTRACESPEC_ACTIVEMANY <= Speculatively traced to on more than one CPU * DTRACESPEC_COMMITTING <= Currently being commited on one CPU * DTRACESPEC_COMMITTINGMANY <= Currently being commited on many CPUs * DTRACESPEC_DISCARDING <= Currently being discarded on many CPUs * * The state transition diagram is as follows: * * +----------------------------------------------------------+ * | | * | +------------+ | * | +-------------------| COMMITTING |<-----------------+ | * | | +------------+ | | * | | copied spec. ^ commit() on | | discard() on * | | into principal | active CPU | | active CPU * | | | commit() | | * V V | | | * +----------+ +--------+ +-----------+ * | INACTIVE |---------------->| ACTIVE |--------------->| ACTIVEONE | * +----------+ speculation() +--------+ speculate() +-----------+ * ^ ^ | | | * | | | discard() | | * | | asynchronously | discard() on | | speculate() * | | cleaned V inactive CPU | | on inactive * | | +------------+ | | CPU * | +-------------------| DISCARDING |<-----------------+ | * | +------------+ | * | asynchronously ^ | * | copied spec. | discard() | * | into principal +------------------------+ | * | | V * +----------------+ commit() +------------+ * | COMMITTINGMANY |<----------------------------------| ACTIVEMANY | * +----------------+ +------------+ */ typedef enum dtrace_speculation_state { DTRACESPEC_INACTIVE = 0, DTRACESPEC_ACTIVE, DTRACESPEC_ACTIVEONE, DTRACESPEC_ACTIVEMANY, DTRACESPEC_COMMITTING, DTRACESPEC_COMMITTINGMANY, DTRACESPEC_DISCARDING } dtrace_speculation_state_t; typedef struct dtrace_speculation { dtrace_speculation_state_t dtsp_state; /* current speculation state */ int dtsp_cleaning; /* non-zero if being cleaned */ dtrace_buffer_t *dtsp_buffer; /* speculative buffer */ } dtrace_speculation_t; /* * DTrace Dynamic Variables * * The dynamic variable problem is obviously decomposed into two subproblems: * allocating new dynamic storage, and freeing old dynamic storage. The * presence of the second problem makes the first much more complicated -- or * rather, the absence of the second renders the first trivial. This is the * case with aggregations, for which there is effectively no deallocation of * dynamic storage. (Or more accurately, all dynamic storage is deallocated * when a snapshot is taken of the aggregation.) As DTrace dynamic variables * allow for both dynamic allocation and dynamic deallocation, the * implementation of dynamic variables is quite a bit more complicated than * that of their aggregation kin. * * We observe that allocating new dynamic storage is tricky only because the * size can vary -- the allocation problem is much easier if allocation sizes * are uniform. We further observe that in D, the size of dynamic variables is * actually _not_ dynamic -- dynamic variable sizes may be determined by static * analysis of DIF text. (This is true even of putatively dynamically-sized * objects like strings and stacks, the sizes of which are dictated by the * "stringsize" and "stackframes" variables, respectively.) We exploit this by * performing this analysis on all DIF before enabling any probes. For each * dynamic load or store, we calculate the dynamically-allocated size plus the * size of the dtrace_dynvar structure plus the storage required to key the * data. For all DIF, we take the largest value and dub it the _chunksize_. * We then divide dynamic memory into two parts: a hash table that is wide * enough to have every chunk in its own bucket, and a larger region of equal * chunksize units. Whenever we wish to dynamically allocate a variable, we * always allocate a single chunk of memory. Depending on the uniformity of * allocation, this will waste some amount of memory -- but it eliminates the * non-determinism inherent in traditional heap fragmentation. * * Dynamic objects are allocated by storing a non-zero value to them; they are * deallocated by storing a zero value to them. Dynamic variables are * complicated enormously by being shared between CPUs. In particular, * consider the following scenario: * * CPU A CPU B * +---------------------------------+ +---------------------------------+ * | | | | * | allocates dynamic object a[123] | | | * | by storing the value 345 to it | | | * | ---------> | * | | | wishing to load from object | * | | | a[123], performs lookup in | * | | | dynamic variable space | * | <--------- | * | deallocates object a[123] by | | | * | storing 0 to it | | | * | | | | * | allocates dynamic object b[567] | | performs load from a[123] | * | by storing the value 789 to it | | | * : : : : * . . . . * * This is obviously a race in the D program, but there are nonetheless only * two valid values for CPU B's load from a[123]: 345 or 0. Most importantly, * CPU B may _not_ see the value 789 for a[123]. * * There are essentially two ways to deal with this: * * (1) Explicitly spin-lock variables. That is, if CPU B wishes to load * from a[123], it needs to lock a[123] and hold the lock for the * duration that it wishes to manipulate it. * * (2) Avoid reusing freed chunks until it is known that no CPU is referring * to them. * * The implementation of (1) is rife with complexity, because it requires the * user of a dynamic variable to explicitly decree when they are done using it. * Were all variables by value, this perhaps wouldn't be debilitating -- but * dynamic variables of non-scalar types are tracked by reference. That is, if * a dynamic variable is, say, a string, and that variable is to be traced to, * say, the principal buffer, the DIF emulation code returns to the main * dtrace_probe() loop a pointer to the underlying storage, not the contents of * the storage. Further, code calling on DIF emulation would have to be aware * that the DIF emulation has returned a reference to a dynamic variable that * has been potentially locked. The variable would have to be unlocked after * the main dtrace_probe() loop is finished with the variable, and the main * dtrace_probe() loop would have to be careful to not call any further DIF * emulation while the variable is locked to avoid deadlock. More generally, * if one were to implement (1), DIF emulation code dealing with dynamic * variables could only deal with one dynamic variable at a time (lest deadlock * result). To sum, (1) exports too much subtlety to the users of dynamic * variables -- increasing maintenance burden and imposing serious constraints * on future DTrace development. * * The implementation of (2) is also complex, but the complexity is more * manageable. We need to be sure that when a variable is deallocated, it is * not placed on a traditional free list, but rather on a _dirty_ list. Once a * variable is on a dirty list, it cannot be found by CPUs performing a * subsequent lookup of the variable -- but it may still be in use by other * CPUs. To assure that all CPUs that may be seeing the old variable have * cleared out of probe context, a dtrace_sync() can be issued. Once the * dtrace_sync() has completed, it can be known that all CPUs are done * manipulating the dynamic variable -- the dirty list can be atomically * appended to the free list. Unfortunately, there's a slight hiccup in this * mechanism: dtrace_sync() may not be issued from probe context. The * dtrace_sync() must be therefore issued asynchronously from non-probe * context. For this we rely on the DTrace cleaner, a cyclic that runs at the * "cleanrate" frequency. To ease this implementation, we define several chunk * lists: * * - Dirty. Deallocated chunks, not yet cleaned. Not available. * * - Rinsing. Formerly dirty chunks that are currently being asynchronously * cleaned. Not available, but will be shortly. Dynamic variable * allocation may not spin or block for availability, however. * * - Clean. Clean chunks, ready for allocation -- but not on the free list. * * - Free. Available for allocation. * * Moreover, to avoid absurd contention, _each_ of these lists is implemented * on a per-CPU basis. This is only for performance, not correctness; chunks * may be allocated from another CPU's free list. The algorithm for allocation * then is this: * * (1) Attempt to atomically allocate from current CPU's free list. If list * is non-empty and allocation is successful, allocation is complete. * * (2) If the clean list is non-empty, atomically move it to the free list, * and reattempt (1). * * (3) If the dynamic variable space is in the CLEAN state, look for free * and clean lists on other CPUs by setting the current CPU to the next * CPU, and reattempting (1). If the next CPU is the current CPU (that * is, if all CPUs have been checked), atomically switch the state of * the dynamic variable space based on the following: * * - If no free chunks were found and no dirty chunks were found, * atomically set the state to EMPTY. * * - If dirty chunks were found, atomically set the state to DIRTY. * * - If rinsing chunks were found, atomically set the state to RINSING. * * (4) Based on state of dynamic variable space state, increment appropriate * counter to indicate dynamic drops (if in EMPTY state) vs. dynamic * dirty drops (if in DIRTY state) vs. dynamic rinsing drops (if in * RINSING state). Fail the allocation. * * The cleaning cyclic operates with the following algorithm: for all CPUs * with a non-empty dirty list, atomically move the dirty list to the rinsing * list. Perform a dtrace_sync(). For all CPUs with a non-empty rinsing list, * atomically move the rinsing list to the clean list. Perform another * dtrace_sync(). By this point, all CPUs have seen the new clean list; the * state of the dynamic variable space can be restored to CLEAN. * * There exist two final races that merit explanation. The first is a simple * allocation race: * * CPU A CPU B * +---------------------------------+ +---------------------------------+ * | | | | * | allocates dynamic object a[123] | | allocates dynamic object a[123] | * | by storing the value 345 to it | | by storing the value 567 to it | * | | | | * : : : : * . . . . * * Again, this is a race in the D program. It can be resolved by having a[123] * hold the value 345 or a[123] hold the value 567 -- but it must be true that * a[123] have only _one_ of these values. (That is, the racing CPUs may not * put the same element twice on the same hash chain.) This is resolved * simply: before the allocation is undertaken, the start of the new chunk's * hash chain is noted. Later, after the allocation is complete, the hash * chain is atomically switched to point to the new element. If this fails * (because of either concurrent allocations or an allocation concurrent with a * deletion), the newly allocated chunk is deallocated to the dirty list, and * the whole process of looking up (and potentially allocating) the dynamic * variable is reattempted. * * The final race is a simple deallocation race: * * CPU A CPU B * +---------------------------------+ +---------------------------------+ * | | | | * | deallocates dynamic object | | deallocates dynamic object | * | a[123] by storing the value 0 | | a[123] by storing the value 0 | * | to it | | to it | * | | | | * : : : : * . . . . * * Once again, this is a race in the D program, but it is one that we must * handle without corrupting the underlying data structures. Because * deallocations require the deletion of a chunk from the middle of a hash * chain, we cannot use a single-word atomic operation to remove it. For this, * we add a spin lock to the hash buckets that is _only_ used for deallocations * (allocation races are handled as above). Further, this spin lock is _only_ * held for the duration of the delete; before control is returned to the DIF * emulation code, the hash bucket is unlocked. */ typedef struct dtrace_key { uint64_t dttk_value; /* data value or data pointer */ uint64_t dttk_size; /* 0 if by-val, >0 if by-ref */ } dtrace_key_t; typedef struct dtrace_tuple { uint32_t dtt_nkeys; /* number of keys in tuple */ uint32_t dtt_pad; /* padding */ dtrace_key_t dtt_key[1]; /* array of tuple keys */ } dtrace_tuple_t; typedef struct dtrace_dynvar { uint64_t dtdv_hashval; /* hash value -- 0 if free */ struct dtrace_dynvar *dtdv_next; /* next on list or hash chain */ void *dtdv_data; /* pointer to data */ dtrace_tuple_t dtdv_tuple; /* tuple key */ } dtrace_dynvar_t; typedef enum dtrace_dynvar_op { DTRACE_DYNVAR_ALLOC, DTRACE_DYNVAR_NOALLOC, DTRACE_DYNVAR_DEALLOC } dtrace_dynvar_op_t; typedef struct dtrace_dynhash { dtrace_dynvar_t *dtdh_chain; /* hash chain for this bucket */ uintptr_t dtdh_lock; /* deallocation lock */ #ifdef _LP64 uintptr_t dtdh_pad[6]; /* pad to avoid false sharing */ #else uintptr_t dtdh_pad[14]; /* pad to avoid false sharing */ #endif } dtrace_dynhash_t; typedef struct dtrace_dstate_percpu { dtrace_dynvar_t *dtdsc_free; /* free list for this CPU */ dtrace_dynvar_t *dtdsc_dirty; /* dirty list for this CPU */ dtrace_dynvar_t *dtdsc_rinsing; /* rinsing list for this CPU */ dtrace_dynvar_t *dtdsc_clean; /* clean list for this CPU */ uint64_t dtdsc_drops; /* number of capacity drops */ uint64_t dtdsc_dirty_drops; /* number of dirty drops */ uint64_t dtdsc_rinsing_drops; /* number of rinsing drops */ #ifdef _LP64 uint64_t dtdsc_pad; /* pad to avoid false sharing */ #else uint64_t dtdsc_pad[2]; /* pad to avoid false sharing */ #endif } dtrace_dstate_percpu_t; typedef enum dtrace_dstate_state { DTRACE_DSTATE_CLEAN = 0, DTRACE_DSTATE_EMPTY, DTRACE_DSTATE_DIRTY, DTRACE_DSTATE_RINSING } dtrace_dstate_state_t; typedef struct dtrace_dstate { void *dtds_base; /* base of dynamic var. space */ size_t dtds_size; /* size of dynamic var. space */ size_t dtds_hashsize; /* number of buckets in hash */ size_t dtds_chunksize; /* size of each chunk */ dtrace_dynhash_t *dtds_hash; /* pointer to hash table */ dtrace_dstate_state_t dtds_state; /* current dynamic var. state */ dtrace_dstate_percpu_t *dtds_percpu; /* per-CPU dyn. var. state */ } dtrace_dstate_t; /* * DTrace Variable State * * The DTrace variable state tracks user-defined variables in its dtrace_vstate * structure. Each DTrace consumer has exactly one dtrace_vstate structure, * but some dtrace_vstate structures may exist without a corresponding DTrace * consumer (see "DTrace Helpers", below). As described in , * user-defined variables can have one of three scopes: * * DIFV_SCOPE_GLOBAL => global scope * DIFV_SCOPE_THREAD => thread-local scope (i.e. "self->" variables) * DIFV_SCOPE_LOCAL => clause-local scope (i.e. "this->" variables) * * The variable state tracks variables by both their scope and their allocation * type: * * - The dtvs_globals and dtvs_locals members each point to an array of * dtrace_statvar structures. These structures contain both the variable * metadata (dtrace_difv structures) and the underlying storage for all * statically allocated variables, including statically allocated * DIFV_SCOPE_GLOBAL variables and all DIFV_SCOPE_LOCAL variables. * * - The dtvs_tlocals member points to an array of dtrace_difv structures for * DIFV_SCOPE_THREAD variables. As such, this array tracks _only_ the * variable metadata for DIFV_SCOPE_THREAD variables; the underlying storage * is allocated out of the dynamic variable space. * * - The dtvs_dynvars member is the dynamic variable state associated with the * variable state. The dynamic variable state (described in "DTrace Dynamic * Variables", above) tracks all DIFV_SCOPE_THREAD variables and all * dynamically-allocated DIFV_SCOPE_GLOBAL variables. */ typedef struct dtrace_statvar { uint64_t dtsv_data; /* data or pointer to it */ size_t dtsv_size; /* size of pointed-to data */ int dtsv_refcnt; /* reference count */ dtrace_difv_t dtsv_var; /* variable metadata */ } dtrace_statvar_t; typedef struct dtrace_vstate { dtrace_state_t *dtvs_state; /* back pointer to state */ dtrace_statvar_t **dtvs_globals; /* statically-allocated glbls */ int dtvs_nglobals; /* number of globals */ dtrace_difv_t *dtvs_tlocals; /* thread-local metadata */ int dtvs_ntlocals; /* number of thread-locals */ dtrace_statvar_t **dtvs_locals; /* clause-local data */ int dtvs_nlocals; /* number of clause-locals */ dtrace_dstate_t dtvs_dynvars; /* dynamic variable state */ } dtrace_vstate_t; /* * DTrace Machine State * * In the process of processing a fired probe, DTrace needs to track and/or * cache some per-CPU state associated with that particular firing. This is * state that is always discarded after the probe firing has completed, and * much of it is not specific to any DTrace consumer, remaining valid across * all ECBs. This state is tracked in the dtrace_mstate structure. */ #define DTRACE_MSTATE_ARGS 0x00000001 #define DTRACE_MSTATE_PROBE 0x00000002 #define DTRACE_MSTATE_EPID 0x00000004 #define DTRACE_MSTATE_TIMESTAMP 0x00000008 #define DTRACE_MSTATE_STACKDEPTH 0x00000010 #define DTRACE_MSTATE_CALLER 0x00000020 #define DTRACE_MSTATE_IPL 0x00000040 #define DTRACE_MSTATE_FLTOFFS 0x00000080 #define DTRACE_MSTATE_WALLTIMESTAMP 0x00000100 #define DTRACE_MSTATE_USTACKDEPTH 0x00000200 #define DTRACE_MSTATE_UCALLER 0x00000400 typedef struct dtrace_mstate { uintptr_t dtms_scratch_base; /* base of scratch space */ uintptr_t dtms_scratch_ptr; /* current scratch pointer */ size_t dtms_scratch_size; /* scratch size */ uint32_t dtms_present; /* variables that are present */ uint64_t dtms_arg[5]; /* cached arguments */ dtrace_epid_t dtms_epid; /* current EPID */ uint64_t dtms_timestamp; /* cached timestamp */ hrtime_t dtms_walltimestamp; /* cached wall timestamp */ int dtms_stackdepth; /* cached stackdepth */ int dtms_ustackdepth; /* cached ustackdepth */ struct dtrace_probe *dtms_probe; /* current probe */ uintptr_t dtms_caller; /* cached caller */ uint64_t dtms_ucaller; /* cached user-level caller */ int dtms_ipl; /* cached interrupt pri lev */ int dtms_fltoffs; /* faulting DIFO offset */ uintptr_t dtms_strtok; /* saved strtok() pointer */ uint32_t dtms_access; /* memory access rights */ dtrace_difo_t *dtms_difo; /* current dif object */ } dtrace_mstate_t; #define DTRACE_COND_OWNER 0x1 #define DTRACE_COND_USERMODE 0x2 #define DTRACE_COND_ZONEOWNER 0x4 #define DTRACE_PROBEKEY_MAXDEPTH 8 /* max glob recursion depth */ /* * Access flag used by dtrace_mstate.dtms_access. */ #define DTRACE_ACCESS_KERNEL 0x1 /* the priv to read kmem */ /* * DTrace Activity * * Each DTrace consumer is in one of several states, which (for purposes of * avoiding yet-another overloading of the noun "state") we call the current * _activity_. The activity transitions on dtrace_go() (from DTRACIOCGO), on * dtrace_stop() (from DTRACIOCSTOP) and on the exit() action. Activities may * only transition in one direction; the activity transition diagram is a * directed acyclic graph. The activity transition diagram is as follows: * * * +----------+ +--------+ +--------+ * | INACTIVE |------------------>| WARMUP |------------------>| ACTIVE | * +----------+ dtrace_go(), +--------+ dtrace_go(), +--------+ * before BEGIN | after BEGIN | | | * | | | | * exit() action | | | | * from BEGIN ECB | | | | * | | | | * v | | | * +----------+ exit() action | | | * +-----------------------------| DRAINING |<-------------------+ | | * | +----------+ | | * | | | | * | dtrace_stop(), | | | * | before END | | | * | | | | * | v | | * | +---------+ +----------+ | | * | | STOPPED |<----------------| COOLDOWN |<----------------------+ | * | +---------+ dtrace_stop(), +----------+ dtrace_stop(), | * | after END before END | * | | * | +--------+ | * +----------------------------->| KILLED |<--------------------------+ * deadman timeout or +--------+ deadman timeout or * killed consumer killed consumer * * Note that once a DTrace consumer has stopped tracing, there is no way to * restart it; if a DTrace consumer wishes to restart tracing, it must reopen * the DTrace pseudodevice. */ typedef enum dtrace_activity { DTRACE_ACTIVITY_INACTIVE = 0, /* not yet running */ DTRACE_ACTIVITY_WARMUP, /* while starting */ DTRACE_ACTIVITY_ACTIVE, /* running */ DTRACE_ACTIVITY_DRAINING, /* before stopping */ DTRACE_ACTIVITY_COOLDOWN, /* while stopping */ DTRACE_ACTIVITY_STOPPED, /* after stopping */ DTRACE_ACTIVITY_KILLED /* killed */ } dtrace_activity_t; /* * DTrace Helper Implementation * * A description of the helper architecture may be found in . * Each process contains a pointer to its helpers in its p_dtrace_helpers * member. This is a pointer to a dtrace_helpers structure, which contains an * array of pointers to dtrace_helper structures, helper variable state (shared * among a process's helpers) and a generation count. (The generation count is * used to provide an identifier when a helper is added so that it may be * subsequently removed.) The dtrace_helper structure is self-explanatory, * containing pointers to the objects needed to execute the helper. Note that * helpers are _duplicated_ across fork(2), and destroyed on exec(2). No more * than dtrace_helpers_max are allowed per-process. */ #define DTRACE_HELPER_ACTION_USTACK 0 #define DTRACE_NHELPER_ACTIONS 1 typedef struct dtrace_helper_action { int dtha_generation; /* helper action generation */ int dtha_nactions; /* number of actions */ dtrace_difo_t *dtha_predicate; /* helper action predicate */ dtrace_difo_t **dtha_actions; /* array of actions */ struct dtrace_helper_action *dtha_next; /* next helper action */ } dtrace_helper_action_t; typedef struct dtrace_helper_provider { int dthp_generation; /* helper provider generation */ uint32_t dthp_ref; /* reference count */ dof_helper_t dthp_prov; /* DOF w/ provider and probes */ } dtrace_helper_provider_t; typedef struct dtrace_helpers { dtrace_helper_action_t **dthps_actions; /* array of helper actions */ dtrace_vstate_t dthps_vstate; /* helper action var. state */ dtrace_helper_provider_t **dthps_provs; /* array of providers */ uint_t dthps_nprovs; /* count of providers */ uint_t dthps_maxprovs; /* provider array size */ int dthps_generation; /* current generation */ pid_t dthps_pid; /* pid of associated proc */ int dthps_deferred; /* helper in deferred list */ struct dtrace_helpers *dthps_next; /* next pointer */ struct dtrace_helpers *dthps_prev; /* prev pointer */ } dtrace_helpers_t; /* * DTrace Helper Action Tracing * * Debugging helper actions can be arduous. To ease the development and * debugging of helpers, DTrace contains a tracing-framework-within-a-tracing- * framework: helper tracing. If dtrace_helptrace_enabled is non-zero (which * it is by default on DEBUG kernels), all helper activity will be traced to a * global, in-kernel ring buffer. Each entry includes a pointer to the specific * helper, the location within the helper, and a trace of all local variables. * The ring buffer may be displayed in a human-readable format with the * ::dtrace_helptrace mdb(1) dcmd. */ #define DTRACE_HELPTRACE_NEXT (-1) #define DTRACE_HELPTRACE_DONE (-2) #define DTRACE_HELPTRACE_ERR (-3) typedef struct dtrace_helptrace { dtrace_helper_action_t *dtht_helper; /* helper action */ int dtht_where; /* where in helper action */ int dtht_nlocals; /* number of locals */ int dtht_fault; /* type of fault (if any) */ int dtht_fltoffs; /* DIF offset */ uint64_t dtht_illval; /* faulting value */ uint64_t dtht_locals[1]; /* local variables */ } dtrace_helptrace_t; /* * DTrace Credentials * * In probe context, we have limited flexibility to examine the credentials * of the DTrace consumer that created a particular enabling. We use * the Least Privilege interfaces to cache the consumer's cred pointer and * some facts about that credential in a dtrace_cred_t structure. These * can limit the consumer's breadth of visibility and what actions the * consumer may take. */ #define DTRACE_CRV_ALLPROC 0x01 #define DTRACE_CRV_KERNEL 0x02 #define DTRACE_CRV_ALLZONE 0x04 #define DTRACE_CRV_ALL (DTRACE_CRV_ALLPROC | DTRACE_CRV_KERNEL | \ DTRACE_CRV_ALLZONE) #define DTRACE_CRA_PROC 0x0001 #define DTRACE_CRA_PROC_CONTROL 0x0002 #define DTRACE_CRA_PROC_DESTRUCTIVE_ALLUSER 0x0004 #define DTRACE_CRA_PROC_DESTRUCTIVE_ALLZONE 0x0008 #define DTRACE_CRA_PROC_DESTRUCTIVE_CREDCHG 0x0010 #define DTRACE_CRA_KERNEL 0x0020 #define DTRACE_CRA_KERNEL_DESTRUCTIVE 0x0040 #define DTRACE_CRA_ALL (DTRACE_CRA_PROC | \ DTRACE_CRA_PROC_CONTROL | \ DTRACE_CRA_PROC_DESTRUCTIVE_ALLUSER | \ DTRACE_CRA_PROC_DESTRUCTIVE_ALLZONE | \ DTRACE_CRA_PROC_DESTRUCTIVE_CREDCHG | \ DTRACE_CRA_KERNEL | \ DTRACE_CRA_KERNEL_DESTRUCTIVE) typedef struct dtrace_cred { cred_t *dcr_cred; uint8_t dcr_destructive; uint8_t dcr_visible; uint16_t dcr_action; } dtrace_cred_t; /* * DTrace Consumer State * * Each DTrace consumer has an associated dtrace_state structure that contains * its in-kernel DTrace state -- including options, credentials, statistics and * pointers to ECBs, buffers, speculations and formats. A dtrace_state * structure is also allocated for anonymous enablings. When anonymous state * is grabbed, the grabbing consumers dts_anon pointer is set to the grabbed * dtrace_state structure. */ struct dtrace_state { +#if defined(sun) dev_t dts_dev; /* device */ +#else + struct cdev *dts_dev; /* device */ +#endif int dts_necbs; /* total number of ECBs */ dtrace_ecb_t **dts_ecbs; /* array of ECBs */ dtrace_epid_t dts_epid; /* next EPID to allocate */ size_t dts_needed; /* greatest needed space */ struct dtrace_state *dts_anon; /* anon. state, if grabbed */ dtrace_activity_t dts_activity; /* current activity */ dtrace_vstate_t dts_vstate; /* variable state */ dtrace_buffer_t *dts_buffer; /* principal buffer */ dtrace_buffer_t *dts_aggbuffer; /* aggregation buffer */ dtrace_speculation_t *dts_speculations; /* speculation array */ int dts_nspeculations; /* number of speculations */ int dts_naggregations; /* number of aggregations */ dtrace_aggregation_t **dts_aggregations; /* aggregation array */ +#if defined(sun) vmem_t *dts_aggid_arena; /* arena for aggregation IDs */ +#else + struct unrhdr *dts_aggid_arena; /* arena for aggregation IDs */ +#endif uint64_t dts_errors; /* total number of errors */ uint32_t dts_speculations_busy; /* number of spec. busy */ uint32_t dts_speculations_unavail; /* number of spec unavail */ uint32_t dts_stkstroverflows; /* stack string tab overflows */ uint32_t dts_dblerrors; /* errors in ERROR probes */ uint32_t dts_reserve; /* space reserved for END */ hrtime_t dts_laststatus; /* time of last status */ cyclic_id_t dts_cleaner; /* cleaning cyclic */ cyclic_id_t dts_deadman; /* deadman cyclic */ hrtime_t dts_alive; /* time last alive */ char dts_speculates; /* boolean: has speculations */ char dts_destructive; /* boolean: has dest. actions */ int dts_nformats; /* number of formats */ char **dts_formats; /* format string array */ dtrace_optval_t dts_options[DTRACEOPT_MAX]; /* options */ dtrace_cred_t dts_cred; /* credentials */ size_t dts_nretained; /* number of retained enabs */ }; struct dtrace_provider { dtrace_pattr_t dtpv_attr; /* provider attributes */ dtrace_ppriv_t dtpv_priv; /* provider privileges */ dtrace_pops_t dtpv_pops; /* provider operations */ char *dtpv_name; /* provider name */ void *dtpv_arg; /* provider argument */ uint_t dtpv_defunct; /* boolean: defunct provider */ struct dtrace_provider *dtpv_next; /* next provider */ }; struct dtrace_meta { dtrace_mops_t dtm_mops; /* meta provider operations */ char *dtm_name; /* meta provider name */ void *dtm_arg; /* meta provider user arg */ uint64_t dtm_count; /* no. of associated provs. */ }; /* * DTrace Enablings * * A dtrace_enabling structure is used to track a collection of ECB * descriptions -- before they have been turned into actual ECBs. This is * created as a result of DOF processing, and is generally used to generate * ECBs immediately thereafter. However, enablings are also generally * retained should the probes they describe be created at a later time; as * each new module or provider registers with the framework, the retained * enablings are reevaluated, with any new match resulting in new ECBs. To * prevent probes from being matched more than once, the enabling tracks the * last probe generation matched, and only matches probes from subsequent * generations. */ typedef struct dtrace_enabling { dtrace_ecbdesc_t **dten_desc; /* all ECB descriptions */ int dten_ndesc; /* number of ECB descriptions */ int dten_maxdesc; /* size of ECB array */ dtrace_vstate_t *dten_vstate; /* associated variable state */ dtrace_genid_t dten_probegen; /* matched probe generation */ dtrace_ecbdesc_t *dten_current; /* current ECB description */ int dten_error; /* current error value */ int dten_primed; /* boolean: set if primed */ struct dtrace_enabling *dten_prev; /* previous enabling */ struct dtrace_enabling *dten_next; /* next enabling */ } dtrace_enabling_t; /* * DTrace Anonymous Enablings * * Anonymous enablings are DTrace enablings that are not associated with a * controlling process, but rather derive their enabling from DOF stored as * properties in the dtrace.conf file. If there is an anonymous enabling, a * DTrace consumer state and enabling are created on attach. The state may be * subsequently grabbed by the first consumer specifying the "grabanon" * option. As long as an anonymous DTrace enabling exists, dtrace(7D) will * refuse to unload. */ typedef struct dtrace_anon { dtrace_state_t *dta_state; /* DTrace consumer state */ dtrace_enabling_t *dta_enabling; /* pointer to enabling */ processorid_t dta_beganon; /* which CPU BEGIN ran on */ } dtrace_anon_t; /* * DTrace Error Debugging */ #ifdef DEBUG #define DTRACE_ERRDEBUG #endif #ifdef DTRACE_ERRDEBUG typedef struct dtrace_errhash { const char *dter_msg; /* error message */ int dter_count; /* number of times seen */ } dtrace_errhash_t; #define DTRACE_ERRHASHSZ 256 /* must be > number of err msgs */ #endif /* DTRACE_ERRDEBUG */ /* * DTrace Toxic Ranges * * DTrace supports safe loads from probe context; if the address turns out to * be invalid, a bit will be set by the kernel indicating that DTrace * encountered a memory error, and DTrace will propagate the error to the user * accordingly. However, there may exist some regions of memory in which an * arbitrary load can change system state, and from which it is impossible to * recover from such a load after it has been attempted. Examples of this may * include memory in which programmable I/O registers are mapped (for which a * read may have some implications for the device) or (in the specific case of * UltraSPARC-I and -II) the virtual address hole. The platform is required * to make DTrace aware of these toxic ranges; DTrace will then check that * target addresses are not in a toxic range before attempting to issue a * safe load. */ typedef struct dtrace_toxrange { uintptr_t dtt_base; /* base of toxic range */ uintptr_t dtt_limit; /* limit of toxic range */ } dtrace_toxrange_t; extern uint64_t dtrace_getarg(int, int); extern greg_t dtrace_getfp(void); extern int dtrace_getipl(void); extern uintptr_t dtrace_caller(int); extern uint32_t dtrace_cas32(uint32_t *, uint32_t, uint32_t); -extern void *dtrace_casptr(void *, void *, void *); +extern void *dtrace_casptr(volatile void *, volatile void *, volatile void *); extern void dtrace_copyin(uintptr_t, uintptr_t, size_t, volatile uint16_t *); extern void dtrace_copyinstr(uintptr_t, uintptr_t, size_t, volatile uint16_t *); extern void dtrace_copyout(uintptr_t, uintptr_t, size_t, volatile uint16_t *); extern void dtrace_copyoutstr(uintptr_t, uintptr_t, size_t, volatile uint16_t *); extern void dtrace_getpcstack(pc_t *, int, int, uint32_t *); extern ulong_t dtrace_getreg(struct regs *, uint_t); extern int dtrace_getstackdepth(int); extern void dtrace_getupcstack(uint64_t *, int); extern void dtrace_getufpstack(uint64_t *, uint64_t *, int); extern int dtrace_getustackdepth(void); extern uintptr_t dtrace_fulword(void *); extern uint8_t dtrace_fuword8(void *); extern uint16_t dtrace_fuword16(void *); extern uint32_t dtrace_fuword32(void *); extern uint64_t dtrace_fuword64(void *); extern void dtrace_probe_error(dtrace_state_t *, dtrace_epid_t, int, int, int, uintptr_t); extern int dtrace_assfail(const char *, const char *, int); extern int dtrace_attached(void); -extern hrtime_t dtrace_gethrestime(); +#if defined(sun) +extern hrtime_t dtrace_gethrestime(void); +#endif #ifdef __sparc extern void dtrace_flush_windows(void); extern void dtrace_flush_user_windows(void); extern uint_t dtrace_getotherwin(void); extern uint_t dtrace_getfprs(void); #else extern void dtrace_copy(uintptr_t, uintptr_t, size_t); extern void dtrace_copystr(uintptr_t, uintptr_t, size_t, volatile uint16_t *); #endif /* * DTrace Assertions * * DTrace calls ASSERT from probe context. To assure that a failed ASSERT * does not induce a markedly more catastrophic failure (e.g., one from which * a dump cannot be gleaned), DTrace must define its own ASSERT to be one that * may safely be called from probe context. This header file must thus be * included by any DTrace component that calls ASSERT from probe context, and * _only_ by those components. (The only exception to this is kernel * debugging infrastructure at user-level that doesn't depend on calling * ASSERT.) */ #undef ASSERT #ifdef DEBUG #define ASSERT(EX) ((void)((EX) || \ dtrace_assfail(#EX, __FILE__, __LINE__))) #else #define ASSERT(X) ((void)0) #endif #ifdef __cplusplus } #endif #endif /* _SYS_DTRACE_IMPL_H */ Index: head/sys/cddl/contrib/opensolaris/uts/common/sys/isa_defs.h =================================================================== --- head/sys/cddl/contrib/opensolaris/uts/common/sys/isa_defs.h (revision 179197) +++ head/sys/cddl/contrib/opensolaris/uts/common/sys/isa_defs.h (revision 179198) @@ -1,485 +1,533 @@ /* * CDDL HEADER START * * The contents of this file are subject to the terms of the * Common Development and Distribution License (the "License"). * You may not use this file except in compliance with the License. * * You can obtain a copy of the license at usr/src/OPENSOLARIS.LICENSE * or http://www.opensolaris.org/os/licensing. * See the License for the specific language governing permissions * and limitations under the License. * * When distributing Covered Code, include this CDDL HEADER in each * file and include the License file at usr/src/OPENSOLARIS.LICENSE. * If applicable, add the following below this CDDL HEADER, with the * fields enclosed by brackets "[]" replaced with your own identifying * information: Portions Copyright [yyyy] [name of copyright owner] * * CDDL HEADER END */ /* * Copyright 2007 Sun Microsystems, Inc. All rights reserved. * Use is subject to license terms. */ #ifndef _SYS_ISA_DEFS_H #define _SYS_ISA_DEFS_H #pragma ident "%Z%%M% %I% %E% SMI" /* * This header file serves to group a set of well known defines and to * set these for each instruction set architecture. These defines may * be divided into two groups; characteristics of the processor and * implementation choices for Solaris on a processor. * * Processor Characteristics: * * _LITTLE_ENDIAN / _BIG_ENDIAN: * The natural byte order of the processor. A pointer to an int points * to the least/most significant byte of that int. * * _STACK_GROWS_UPWARD / _STACK_GROWS_DOWNWARD: * The processor specific direction of stack growth. A push onto the * stack increases/decreases the stack pointer, so it stores data at * successively higher/lower addresses. (Stackless machines ignored * without regrets). * * _LONG_LONG_HTOL / _LONG_LONG_LTOH: * A pointer to a long long points to the most/least significant long * within that long long. * * _BIT_FIELDS_HTOL / _BIT_FIELDS_LTOH: * The C compiler assigns bit fields from the high/low to the low/high end * of an int (most to least significant vs. least to most significant). * * _IEEE_754: * The processor (or supported implementations of the processor) * supports the ieee-754 floating point standard. No other floating * point standards are supported (or significant). Any other supported * floating point formats are expected to be cased on the ISA processor * symbol. * * _CHAR_IS_UNSIGNED / _CHAR_IS_SIGNED: * The C Compiler implements objects of type `char' as `unsigned' or * `signed' respectively. This is really an implementation choice of * the compiler writer, but it is specified in the ABI and tends to * be uniform across compilers for an instruction set architecture. * Hence, it has the properties of a processor characteristic. * * _CHAR_ALIGNMENT / _SHORT_ALIGNMENT / _INT_ALIGNMENT / _LONG_ALIGNMENT / * _LONG_LONG_ALIGNMENT / _DOUBLE_ALIGNMENT / _LONG_DOUBLE_ALIGNMENT / * _POINTER_ALIGNMENT / _FLOAT_ALIGNMENT: * The ABI defines alignment requirements of each of the primitive * object types. Some, if not all, may be hardware requirements as * well. The values are expressed in "byte-alignment" units. * * _MAX_ALIGNMENT: * The most stringent alignment requirement as specified by the ABI. * Equal to the maximum of all the above _XXX_ALIGNMENT values. * * _ALIGNMENT_REQUIRED: * True or false (1 or 0) whether or not the hardware requires the ABI * alignment. * * _LONG_LONG_ALIGNMENT_32 * The 32-bit ABI supported by a 64-bit kernel may have different * alignment requirements for primitive object types. The value of this * identifier is expressed in "byte-alignment" units. * * _HAVE_CPUID_INSN * This indicates that the architecture supports the 'cpuid' * instruction as defined by Intel. (Intel allows other vendors * to extend the instruction for their own purposes.) * * * Implementation Choices: * * _ILP32 / _LP64: * This specifies the compiler data type implementation as specified in * the relevant ABI. The choice between these is strongly influenced * by the underlying hardware, but is not absolutely tied to it. * Currently only two data type models are supported: * * _ILP32: * Int/Long/Pointer are 32 bits. This is the historical UNIX * and Solaris implementation. Due to its historical standing, * this is the default case. * * _LP64: * Long/Pointer are 64 bits, Int is 32 bits. This is the chosen * implementation for 64-bit ABIs such as SPARC V9. * * _I32LPx: * A compilation environment where 'int' is 32-bit, and * longs and pointers are simply the same size. * * In all cases, Char is 8 bits and Short is 16 bits. * * _SUNOS_VTOC_8 / _SUNOS_VTOC_16 / _SVR4_VTOC_16: * This specifies the form of the disk VTOC (or label): * * _SUNOS_VTOC_8: * This is a VTOC form which is upwardly compatible with the * SunOS 4.x disk label and allows 8 partitions per disk. * * _SUNOS_VTOC_16: * In this format the incore vtoc image matches the ondisk * version. It allows 16 slices per disk, and is not * compatible with the SunOS 4.x disk label. * * Note that these are not the only two VTOC forms possible and * additional forms may be added. One possible form would be the * SVr4 VTOC form. The symbol for that is reserved now, although * it is not implemented. * * _SVR4_VTOC_16: * This VTOC form is compatible with the System V Release 4 * VTOC (as implemented on the SVr4 Intel and 3b ports) with * 16 partitions per disk. * * * _DMA_USES_PHYSADDR / _DMA_USES_VIRTADDR * This describes the type of addresses used by system DMA: * * _DMA_USES_PHYSADDR: * This type of DMA, used in the x86 implementation, * requires physical addresses for DMA buffers. The 24-bit * addresses used by some legacy boards is the source of the * "low-memory" (<16MB) requirement for some devices using DMA. * * _DMA_USES_VIRTADDR: * This method of DMA allows the use of virtual addresses for * DMA transfers. * * _FIRMWARE_NEEDS_FDISK / _NO_FDISK_PRESENT * This indicates the presence/absence of an fdisk table. * * _FIRMWARE_NEEDS_FDISK * The fdisk table is required by system firmware. If present, * it allows a disk to be subdivided into multiple fdisk * partitions, each of which is equivalent to a separate, * virtual disk. This enables the co-existence of multiple * operating systems on a shared hard disk. * * _NO_FDISK_PRESENT * If the fdisk table is absent, it is assumed that the entire * media is allocated for a single operating system. * * _HAVE_TEM_FIRMWARE * Defined if this architecture has the (fallback) option of * using prom_* calls for doing I/O if a suitable kernel driver * is not available to do it. * * _DONT_USE_1275_GENERIC_NAMES * Controls whether or not device tree node names should * comply with the IEEE 1275 "Generic Names" Recommended * Practice. With _DONT_USE_GENERIC_NAMES, device-specific * names identifying the particular device will be used. * * __i386_COMPAT * This indicates whether the i386 ABI is supported as a *non-native* * mode for the platform. When this symbol is defined: * - 32-bit xstat-style system calls are enabled * - 32-bit xmknod-style system calls are enabled * - 32-bit system calls use i386 sizes -and- alignments * * Note that this is NOT defined for the i386 native environment! * * __x86 * This is ONLY a synonym for defined(__i386) || defined(__amd64) * which is useful only insofar as these two architectures share * common attributes. Analogous to __sparc. * * _PSM_MODULES * This indicates whether or not the implementation uses PSM * modules for processor support, reading /etc/mach from inside * the kernel to extract a list. * * _RTC_CONFIG * This indicates whether or not the implementation uses /etc/rtc_config * to configure the real-time clock in the kernel. * * _UNIX_KRTLD * This indicates that the implementation uses a dynamically * linked unix + krtld to form the core kernel image at boot * time, or (in the absence of this symbol) a prelinked kernel image. + * + * _OBP + * This indicates the firmware interface is OBP. */ #ifdef __cplusplus extern "C" { #endif /* * The following set of definitions characterize Solaris on AMD's * 64-bit systems. */ -#if defined(__x86_64) || defined(__amd64) +#if defined(__x86_64) || defined(__amd64) || defined(__ia64__) #if !defined(__amd64) #define __amd64 /* preferred guard */ #endif #if !defined(__x86) #define __x86 #endif /* * Define the appropriate "processor characteristics" */ #if defined(sun) #define _LITTLE_ENDIAN #endif #define _STACK_GROWS_DOWNWARD #define _LONG_LONG_LTOH #define _BIT_FIELDS_LTOH #define _IEEE_754 #define _CHAR_IS_SIGNED #define _BOOL_ALIGNMENT 1 #define _CHAR_ALIGNMENT 1 #define _SHORT_ALIGNMENT 2 #define _INT_ALIGNMENT 4 #define _FLOAT_ALIGNMENT 4 #define _FLOAT_COMPLEX_ALIGNMENT 4 #define _LONG_ALIGNMENT 8 #define _LONG_LONG_ALIGNMENT 8 #define _DOUBLE_ALIGNMENT 8 #define _DOUBLE_COMPLEX_ALIGNMENT 8 #define _LONG_DOUBLE_ALIGNMENT 16 #define _LONG_DOUBLE_COMPLEX_ALIGNMENT 16 #define _POINTER_ALIGNMENT 8 #define _MAX_ALIGNMENT 16 #define _ALIGNMENT_REQUIRED 1 /* * Different alignment constraints for the i386 ABI in compatibility mode */ #define _LONG_LONG_ALIGNMENT_32 4 /* * Define the appropriate "implementation choices". */ #if !defined(_LP64) #define _LP64 #endif #if !defined(_I32LPx) && defined(_KERNEL) #define _I32LPx #endif #define _MULTI_DATAMODEL #define _SUNOS_VTOC_16 #define _DMA_USES_PHYSADDR #define _FIRMWARE_NEEDS_FDISK #define __i386_COMPAT #define _PSM_MODULES #define _RTC_CONFIG #define _DONT_USE_1275_GENERIC_NAMES #define _HAVE_CPUID_INSN /* * The feature test macro __i386 is generic for all processors implementing * the Intel 386 instruction set or a superset of it. Specifically, this * includes all members of the 386, 486, and Pentium family of processors. */ #elif defined(__i386) || defined(__i386__) #if !defined(__i386) #define __i386 #endif #if !defined(__x86) #define __x86 #endif /* * Define the appropriate "processor characteristics" */ #if defined(sun) #define _LITTLE_ENDIAN #endif #define _STACK_GROWS_DOWNWARD #define _LONG_LONG_LTOH #define _BIT_FIELDS_LTOH #define _IEEE_754 #define _CHAR_IS_SIGNED #define _BOOL_ALIGNMENT 1 #define _CHAR_ALIGNMENT 1 #define _SHORT_ALIGNMENT 2 #define _INT_ALIGNMENT 4 #define _FLOAT_ALIGNMENT 4 #define _FLOAT_COMPLEX_ALIGNMENT 4 #define _LONG_ALIGNMENT 4 #define _LONG_LONG_ALIGNMENT 4 #define _DOUBLE_ALIGNMENT 4 #define _DOUBLE_COMPLEX_ALIGNMENT 4 #define _LONG_DOUBLE_ALIGNMENT 4 #define _LONG_DOUBLE_COMPLEX_ALIGNMENT 4 #define _POINTER_ALIGNMENT 4 #define _MAX_ALIGNMENT 4 #define _ALIGNMENT_REQUIRED 0 #define _LONG_LONG_ALIGNMENT_32 _LONG_LONG_ALIGNMENT /* * Define the appropriate "implementation choices". */ #define _ILP32 #if !defined(_I32LPx) && defined(_KERNEL) #define _I32LPx #endif #define _SUNOS_VTOC_16 #define _DMA_USES_PHYSADDR #define _FIRMWARE_NEEDS_FDISK #define _PSM_MODULES #define _RTC_CONFIG #define _DONT_USE_1275_GENERIC_NAMES #define _HAVE_CPUID_INSN +#elif defined(__arm__) + /* + * Define the appropriate "processor characteristics" + */ +#define _STACK_GROWS_DOWNWARD +#define _LONG_LONG_LTOH +#define _BIT_FIELDS_LTOH +#define _IEEE_754 +#define _CHAR_IS_SIGNED +#define _BOOL_ALIGNMENT 1 +#define _CHAR_ALIGNMENT 1 +#define _SHORT_ALIGNMENT 2 +#define _INT_ALIGNMENT 4 +#define _FLOAT_ALIGNMENT 4 +#define _FLOAT_COMPLEX_ALIGNMENT 4 +#define _LONG_ALIGNMENT 4 +#define _LONG_LONG_ALIGNMENT 4 +#define _DOUBLE_ALIGNMENT 4 +#define _DOUBLE_COMPLEX_ALIGNMENT 4 +#define _LONG_DOUBLE_ALIGNMENT 4 +#define _LONG_DOUBLE_COMPLEX_ALIGNMENT 4 +#define _POINTER_ALIGNMENT 4 +#define _MAX_ALIGNMENT 4 +#define _ALIGNMENT_REQUIRED 0 + +#define _LONG_LONG_ALIGNMENT_32 _LONG_LONG_ALIGNMENT + +/* + * Define the appropriate "implementation choices". + */ +#define _ILP32 +#if !defined(_I32LPx) && defined(_KERNEL) +#define _I32LPx +#endif +#define _SUNOS_VTOC_16 +#define _DMA_USES_PHYSADDR +#define _FIRMWARE_NEEDS_FDISK +#define _PSM_MODULES +#define _RTC_CONFIG +#define _DONT_USE_1275_GENERIC_NAMES +#define _HAVE_CPUID_INSN + +#elif defined(__powerpc__) + +/* * The following set of definitions characterize the Solaris on SPARC systems. * * The symbol __sparc indicates any of the SPARC family of processor * architectures. This includes SPARC V7, SPARC V8 and SPARC V9. * * The symbol __sparcv8 indicates the 32-bit SPARC V8 architecture as defined * by Version 8 of the SPARC Architecture Manual. (SPARC V7 is close enough * to SPARC V8 for the former to be subsumed into the latter definition.) * * The symbol __sparcv9 indicates the 64-bit SPARC V9 architecture as defined * by Version 9 of the SPARC Architecture Manual. * * The symbols __sparcv8 and __sparcv9 are mutually exclusive, and are only * relevant when the symbol __sparc is defined. */ /* * XXX Due to the existence of 5110166, "defined(__sparcv9)" needs to be added * to support backwards builds. This workaround should be removed in s10_71. */ #elif defined(__sparc) || defined(__sparcv9) || defined(__sparc__) #if !defined(__sparc) #define __sparc #endif /* * You can be 32-bit or 64-bit, but not both at the same time. */ #if defined(__sparcv8) && defined(__sparcv9) #error "SPARC Versions 8 and 9 are mutually exclusive choices" #endif /* * Existing compilers do not set __sparcv8. Years will transpire before * the compilers can be depended on to set the feature test macro. In * the interim, we'll set it here on the basis of historical behaviour; * if you haven't asked for SPARC V9, then you must've meant SPARC V8. */ #if !defined(__sparcv9) && !defined(__sparcv8) #define __sparcv8 #endif /* * Define the appropriate "processor characteristics" shared between * all Solaris on SPARC systems. */ #if defined(sun) #define _BIG_ENDIAN #endif #define _STACK_GROWS_DOWNWARD #define _LONG_LONG_HTOL #define _BIT_FIELDS_HTOL #define _IEEE_754 #define _CHAR_IS_SIGNED #define _BOOL_ALIGNMENT 1 #define _CHAR_ALIGNMENT 1 #define _SHORT_ALIGNMENT 2 #define _INT_ALIGNMENT 4 #define _FLOAT_ALIGNMENT 4 #define _FLOAT_COMPLEX_ALIGNMENT 4 #define _LONG_LONG_ALIGNMENT 8 #define _DOUBLE_ALIGNMENT 8 #define _DOUBLE_COMPLEX_ALIGNMENT 8 #define _ALIGNMENT_REQUIRED 1 /* * Define the appropriate "implementation choices" shared between versions. */ #define _SUNOS_VTOC_8 #define _DMA_USES_VIRTADDR #define _NO_FDISK_PRESENT #define _HAVE_TEM_FIRMWARE -#define _UNIX_KRTLD +#define _OBP /* * The following set of definitions characterize the implementation of * 32-bit Solaris on SPARC V8 systems. */ #if defined(__sparcv8) /* * Define the appropriate "processor characteristics" */ #define _LONG_ALIGNMENT 4 #define _LONG_DOUBLE_ALIGNMENT 8 #define _LONG_DOUBLE_COMPLEX_ALIGNMENT 8 #define _POINTER_ALIGNMENT 4 #define _MAX_ALIGNMENT 8 #define _LONG_LONG_ALIGNMENT_32 _LONG_LONG_ALIGNMENT /* * Define the appropriate "implementation choices" */ #define _ILP32 #if !defined(_I32LPx) && defined(_KERNEL) #define _I32LPx #endif /* * The following set of definitions characterize the implementation of * 64-bit Solaris on SPARC V9 systems. */ #elif defined(__sparcv9) /* * Define the appropriate "processor characteristics" */ #define _LONG_ALIGNMENT 8 #define _LONG_DOUBLE_ALIGNMENT 16 #define _LONG_DOUBLE_COMPLEX_ALIGNMENT 16 #define _POINTER_ALIGNMENT 8 #define _MAX_ALIGNMENT 16 #define _LONG_LONG_ALIGNMENT_32 _LONG_LONG_ALIGMENT /* * Define the appropriate "implementation choices" */ #if !defined(_LP64) #define _LP64 #endif #if !defined(_I32LPx) #define _I32LPx #endif #define _MULTI_DATAMODEL #else #error "unknown SPARC version" #endif /* * #error is strictly ansi-C, but works as well as anything for K&R systems. */ #else #error "ISA not supported" #endif #if defined(_ILP32) && defined(_LP64) #error "Both _ILP32 and _LP64 are defined" #endif #ifdef __cplusplus } #endif #endif /* _SYS_ISA_DEFS_H */