Index: head/sys/powerpc/pseries/platform_chrp.c =================================================================== --- head/sys/powerpc/pseries/platform_chrp.c (revision 329257) +++ head/sys/powerpc/pseries/platform_chrp.c (revision 329258) @@ -1,501 +1,513 @@ /*- * SPDX-License-Identifier: BSD-2-Clause-FreeBSD * * Copyright (c) 2008 Marcel Moolenaar * Copyright (c) 2009 Nathan Whitehorn * All rights reserved. * * Redistribution and use in source and binary forms, with or without * modification, are permitted provided that the following conditions * are met: * * 1. Redistributions of source code must retain the above copyright * notice, this list of conditions and the following disclaimer. * 2. Redistributions in binary form must reproduce the above copyright * notice, this list of conditions and the following disclaimer in the * documentation and/or other materials provided with the distribution. * * THIS SOFTWARE IS PROVIDED BY THE AUTHOR ``AS IS'' AND ANY EXPRESS OR * IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE IMPLIED WARRANTIES * OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR PURPOSE ARE DISCLAIMED. * IN NO EVENT SHALL THE AUTHOR BE LIABLE FOR ANY DIRECT, INDIRECT, * INCIDENTAL, SPECIAL, EXEMPLARY, OR CONSEQUENTIAL DAMAGES (INCLUDING, BUT * NOT LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS OR SERVICES; LOSS OF USE, * DATA, OR PROFITS; OR BUSINESS INTERRUPTION) HOWEVER CAUSED AND ON ANY * THEORY OF LIABILITY, WHETHER IN CONTRACT, STRICT LIABILITY, OR TORT * (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY OUT OF THE USE OF * THIS SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF SUCH DAMAGE. */ #include __FBSDID("$FreeBSD$"); #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include "platform_if.h" #ifdef SMP extern void *ap_pcpu; #endif #ifdef __powerpc64__ static uint8_t splpar_vpa[MAXCPU][640] __aligned(128); /* XXX: dpcpu */ #endif static vm_offset_t realmaxaddr = VM_MAX_ADDRESS; static int chrp_probe(platform_t); static int chrp_attach(platform_t); void chrp_mem_regions(platform_t, struct mem_region *phys, int *physsz, struct mem_region *avail, int *availsz); static vm_offset_t chrp_real_maxaddr(platform_t); static u_long chrp_timebase_freq(platform_t, struct cpuref *cpuref); static int chrp_smp_first_cpu(platform_t, struct cpuref *cpuref); static int chrp_smp_next_cpu(platform_t, struct cpuref *cpuref); static int chrp_smp_get_bsp(platform_t, struct cpuref *cpuref); static void chrp_smp_ap_init(platform_t); static int chrp_cpuref_init(void); #ifdef SMP static int chrp_smp_start_cpu(platform_t, struct pcpu *cpu); static struct cpu_group *chrp_smp_topo(platform_t plat); #endif static void chrp_reset(platform_t); #ifdef __powerpc64__ #include "phyp-hvcall.h" static void phyp_cpu_idle(sbintime_t sbt); #endif static struct cpuref platform_cpuref[MAXCPU]; static int platform_cpuref_cnt; static int platform_cpuref_valid; static platform_method_t chrp_methods[] = { PLATFORMMETHOD(platform_probe, chrp_probe), PLATFORMMETHOD(platform_attach, chrp_attach), PLATFORMMETHOD(platform_mem_regions, chrp_mem_regions), PLATFORMMETHOD(platform_real_maxaddr, chrp_real_maxaddr), PLATFORMMETHOD(platform_timebase_freq, chrp_timebase_freq), PLATFORMMETHOD(platform_smp_ap_init, chrp_smp_ap_init), PLATFORMMETHOD(platform_smp_first_cpu, chrp_smp_first_cpu), PLATFORMMETHOD(platform_smp_next_cpu, chrp_smp_next_cpu), PLATFORMMETHOD(platform_smp_get_bsp, chrp_smp_get_bsp), #ifdef SMP PLATFORMMETHOD(platform_smp_start_cpu, chrp_smp_start_cpu), PLATFORMMETHOD(platform_smp_topo, chrp_smp_topo), #endif PLATFORMMETHOD(platform_reset, chrp_reset), { 0, 0 } }; static platform_def_t chrp_platform = { "chrp", chrp_methods, 0 }; PLATFORM_DEF(chrp_platform); static int chrp_probe(platform_t plat) { if (OF_finddevice("/memory") != -1 || OF_finddevice("/memory@0") != -1) return (BUS_PROBE_GENERIC); return (ENXIO); } static int chrp_attach(platform_t plat) { #ifdef __powerpc64__ int i; /* XXX: check for /rtas/ibm,hypertas-functions? */ if (!(mfmsr() & PSL_HV)) { struct mem_region *phys, *avail; int nphys, navail; mem_regions(&phys, &nphys, &avail, &navail); realmaxaddr = phys[0].mr_size; pmap_mmu_install("mmu_phyp", BUS_PROBE_SPECIFIC); cpu_idle_hook = phyp_cpu_idle; /* Set up important VPA fields */ for (i = 0; i < MAXCPU; i++) { bzero(splpar_vpa[i], sizeof(splpar_vpa)); /* First two: VPA size */ splpar_vpa[i][4] = (uint8_t)((sizeof(splpar_vpa[i]) >> 8) & 0xff); splpar_vpa[i][5] = (uint8_t)(sizeof(splpar_vpa[i]) & 0xff); splpar_vpa[i][0xba] = 1; /* Maintain FPRs */ splpar_vpa[i][0xbb] = 1; /* Maintain PMCs */ splpar_vpa[i][0xfc] = 0xff; /* Maintain full SLB */ splpar_vpa[i][0xfd] = 0xff; splpar_vpa[i][0xff] = 1; /* Maintain Altivec */ } mb(); /* Set up hypervisor CPU stuff */ chrp_smp_ap_init(plat); } #endif chrp_cpuref_init(); /* Some systems (e.g. QEMU) need Open Firmware to stand down */ ofw_quiesce(); return (0); } static int parse_drconf_memory(struct mem_region *ofmem, int *msz, struct mem_region *ofavail, int *asz) { phandle_t phandle; vm_offset_t base; int i, idx, len, lasz, lmsz, res; uint32_t flags, lmb_size[2]; uint32_t *dmem; lmsz = *msz; lasz = *asz; phandle = OF_finddevice("/ibm,dynamic-reconfiguration-memory"); if (phandle == -1) /* No drconf node, return. */ return (0); res = OF_getencprop(phandle, "ibm,lmb-size", lmb_size, sizeof(lmb_size)); if (res == -1) return (0); printf("Logical Memory Block size: %d MB\n", lmb_size[1] >> 20); /* Parse the /ibm,dynamic-memory. The first position gives the # of entries. The next two words reflect the address of the memory block. The next four words are the DRC index, reserved, list index and flags. (see PAPR C.6.6.2 ibm,dynamic-reconfiguration-memory) #el Addr DRC-idx res list-idx flags ------------------------------------------------- | 4 | 8 | 4 | 4 | 4 | 4 |.... ------------------------------------------------- */ len = OF_getproplen(phandle, "ibm,dynamic-memory"); if (len > 0) { /* We have to use a variable length array on the stack since we have very limited stack space. */ cell_t arr[len/sizeof(cell_t)]; res = OF_getencprop(phandle, "ibm,dynamic-memory", arr, sizeof(arr)); if (res == -1) return (0); /* Number of elements */ idx = arr[0]; /* First address, in arr[1], arr[2]*/ dmem = &arr[1]; for (i = 0; i < idx; i++) { base = ((uint64_t)dmem[0] << 32) + dmem[1]; dmem += 4; flags = dmem[1]; /* Use region only if available and not reserved. */ if ((flags & 0x8) && !(flags & 0x80)) { ofmem[lmsz].mr_start = base; ofmem[lmsz].mr_size = (vm_size_t)lmb_size[1]; ofavail[lasz].mr_start = base; ofavail[lasz].mr_size = (vm_size_t)lmb_size[1]; lmsz++; lasz++; } dmem += 2; } } *msz = lmsz; *asz = lasz; return (1); } void chrp_mem_regions(platform_t plat, struct mem_region *phys, int *physsz, struct mem_region *avail, int *availsz) { vm_offset_t maxphysaddr; int i; ofw_mem_regions(phys, physsz, avail, availsz); parse_drconf_memory(phys, physsz, avail, availsz); /* * On some firmwares (SLOF), some memory may be marked available that * doesn't actually exist. This manifests as an extension of the last * available segment past the end of physical memory, so truncate that * one. */ maxphysaddr = 0; for (i = 0; i < *physsz; i++) if (phys[i].mr_start + phys[i].mr_size > maxphysaddr) maxphysaddr = phys[i].mr_start + phys[i].mr_size; for (i = 0; i < *availsz; i++) if (avail[i].mr_start + avail[i].mr_size > maxphysaddr) avail[i].mr_size = maxphysaddr - avail[i].mr_start; } static vm_offset_t chrp_real_maxaddr(platform_t plat) { return (realmaxaddr); } static u_long chrp_timebase_freq(platform_t plat, struct cpuref *cpuref) { - phandle_t phandle; + phandle_t cpus, cpunode; int32_t ticks = -1; + int res; + char buf[8]; - phandle = cpuref->cr_hwref; + cpus = OF_finddevice("/cpus"); + if (cpus <= 0) + panic("CPU tree not found on Open Firmware\n"); - OF_getencprop(phandle, "timebase-frequency", &ticks, sizeof(ticks)); + for (cpunode = OF_child(cpus); cpunode != 0; cpunode = OF_peer(cpunode)) { + res = OF_getprop(cpunode, "device_type", buf, sizeof(buf)); + if (res > 0 && strcmp(buf, "cpu") == 0) + break; + } + if (cpunode <= 0) + panic("CPU node not found on Open Firmware\n"); + + OF_getencprop(cpunode, "timebase-frequency", &ticks, sizeof(ticks)); if (ticks <= 0) panic("Unable to determine timebase frequency!"); return (ticks); } static int chrp_smp_first_cpu(platform_t plat, struct cpuref *cpuref) { if (platform_cpuref_valid == 0) return (EINVAL); cpuref->cr_cpuid = 0; cpuref->cr_hwref = platform_cpuref[0].cr_hwref; return (0); } static int chrp_smp_next_cpu(platform_t plat, struct cpuref *cpuref) { int id; if (platform_cpuref_valid == 0) return (EINVAL); id = cpuref->cr_cpuid + 1; if (id >= platform_cpuref_cnt) return (ENOENT); cpuref->cr_cpuid = platform_cpuref[id].cr_cpuid; cpuref->cr_hwref = platform_cpuref[id].cr_hwref; return (0); } static int chrp_smp_get_bsp(platform_t plat, struct cpuref *cpuref) { cpuref->cr_cpuid = platform_cpuref[0].cr_cpuid; cpuref->cr_hwref = platform_cpuref[0].cr_hwref; return (0); } static int chrp_cpuref_init(void) { phandle_t cpu, dev; char buf[32]; int a, res; cell_t interrupt_servers[32]; uint64_t bsp; if (platform_cpuref_valid) return (0); dev = OF_peer(0); dev = OF_child(dev); while (dev != 0) { res = OF_getprop(dev, "name", buf, sizeof(buf)); if (res > 0 && strcmp(buf, "cpus") == 0) break; dev = OF_peer(dev); } bsp = 0; for (cpu = OF_child(dev); cpu != 0; cpu = OF_peer(cpu)) { res = OF_getprop(cpu, "device_type", buf, sizeof(buf)); if (res > 0 && strcmp(buf, "cpu") == 0) { res = OF_getproplen(cpu, "ibm,ppc-interrupt-server#s"); if (res > 0) { OF_getencprop(cpu, "ibm,ppc-interrupt-server#s", interrupt_servers, res); for (a = 0; a < res/sizeof(cell_t); a++) { platform_cpuref[platform_cpuref_cnt].cr_hwref = interrupt_servers[a]; platform_cpuref[platform_cpuref_cnt].cr_cpuid = platform_cpuref_cnt; platform_cpuref_cnt++; } } } } platform_cpuref_valid = 1; return (0); } #ifdef SMP static int chrp_smp_start_cpu(platform_t plat, struct pcpu *pc) { cell_t start_cpu; int result, err, timeout; if (!rtas_exists()) { printf("RTAS uninitialized: unable to start AP %d\n", pc->pc_cpuid); return (ENXIO); } start_cpu = rtas_token_lookup("start-cpu"); if (start_cpu == -1) { printf("RTAS unknown method: unable to start AP %d\n", pc->pc_cpuid); return (ENXIO); } ap_pcpu = pc; powerpc_sync(); result = rtas_call_method(start_cpu, 3, 1, pc->pc_hwref, EXC_RST, pc, &err); if (result < 0 || err != 0) { printf("RTAS error (%d/%d): unable to start AP %d\n", result, err, pc->pc_cpuid); return (ENXIO); } timeout = 10000; while (!pc->pc_awake && timeout--) DELAY(100); return ((pc->pc_awake) ? 0 : EBUSY); } static struct cpu_group * chrp_smp_topo(platform_t plat) { struct pcpu *pc, *last_pc; int i, ncores, ncpus; ncores = ncpus = 0; last_pc = NULL; for (i = 0; i <= mp_maxid; i++) { pc = pcpu_find(i); if (pc == NULL) continue; if (last_pc == NULL || pc->pc_hwref != last_pc->pc_hwref) ncores++; last_pc = pc; ncpus++; } if (ncpus % ncores != 0) { printf("WARNING: Irregular SMP topology. Performance may be " "suboptimal (%d CPUS, %d cores)\n", ncpus, ncores); return (smp_topo_none()); } /* Don't do anything fancier for non-threaded SMP */ if (ncpus == ncores) return (smp_topo_none()); return (smp_topo_1level(CG_SHARE_L1, ncpus / ncores, CG_FLAG_SMT)); } #endif static void chrp_reset(platform_t platform) { OF_reboot(); } #ifdef __powerpc64__ static void phyp_cpu_idle(sbintime_t sbt) { register_t msr; msr = mfmsr(); mtmsr(msr & ~PSL_EE); if (sched_runnable()) { mtmsr(msr); return; } phyp_hcall(H_CEDE); /* Re-enables interrupts internally */ mtmsr(msr); } static void chrp_smp_ap_init(platform_t platform) { if (!(mfmsr() & PSL_HV)) { /* Register VPA */ phyp_hcall(H_REGISTER_VPA, 1UL, PCPU_GET(hwref), splpar_vpa[PCPU_GET(hwref)]); /* Set interrupt priority */ phyp_hcall(H_CPPR, 0xff); } } #else static void chrp_smp_ap_init(platform_t platform) { } #endif