Index: head/sys/dev/isp/isp.c =================================================================== --- head/sys/dev/isp/isp.c (revision 345007) +++ head/sys/dev/isp/isp.c (revision 345008) @@ -1,8192 +1,8197 @@ /*- * SPDX-License-Identifier: BSD-2-Clause-FreeBSD * * Copyright (c) 2009-2018 Alexander Motin * Copyright (c) 1997-2009 by Matthew Jacob * 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 AUTHOR AND CONTRIBUTORS ``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 AUTHOR OR CONTRIBUTORS 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. * */ /* * Machine and OS Independent (well, as best as possible) * code for the Qlogic ISP SCSI and FC-SCSI adapters. */ /* * Inspiration and ideas about this driver are from Erik Moe's Linux driver * (qlogicisp.c) and Dave Miller's SBus version of same (qlogicisp.c). Some * ideas dredged from the Solaris driver. */ /* * Include header file appropriate for platform we're building on. */ #ifdef __NetBSD__ #include __KERNEL_RCSID(0, "$NetBSD$"); #include #endif #ifdef __FreeBSD__ #include __FBSDID("$FreeBSD$"); #include #endif #ifdef __OpenBSD__ #include #endif #ifdef __linux__ #include "isp_linux.h" #endif #ifdef __svr4__ #include "isp_solaris.h" #endif /* * General defines */ #define MBOX_DELAY_COUNT 1000000 / 100 /* * Local static data */ static const char notresp[] = "Unknown IOCB in RESPONSE Queue (type 0x%x) @ idx %d (next %d)"; static const char bun[] = "bad underrun (count %d, resid %d, status %s)"; static const char lipd[] = "Chan %d LIP destroyed %d active commands"; static const char sacq[] = "unable to acquire scratch area"; static const uint8_t alpa_map[] = { 0xef, 0xe8, 0xe4, 0xe2, 0xe1, 0xe0, 0xdc, 0xda, 0xd9, 0xd6, 0xd5, 0xd4, 0xd3, 0xd2, 0xd1, 0xce, 0xcd, 0xcc, 0xcb, 0xca, 0xc9, 0xc7, 0xc6, 0xc5, 0xc3, 0xbc, 0xba, 0xb9, 0xb6, 0xb5, 0xb4, 0xb3, 0xb2, 0xb1, 0xae, 0xad, 0xac, 0xab, 0xaa, 0xa9, 0xa7, 0xa6, 0xa5, 0xa3, 0x9f, 0x9e, 0x9d, 0x9b, 0x98, 0x97, 0x90, 0x8f, 0x88, 0x84, 0x82, 0x81, 0x80, 0x7c, 0x7a, 0x79, 0x76, 0x75, 0x74, 0x73, 0x72, 0x71, 0x6e, 0x6d, 0x6c, 0x6b, 0x6a, 0x69, 0x67, 0x66, 0x65, 0x63, 0x5c, 0x5a, 0x59, 0x56, 0x55, 0x54, 0x53, 0x52, 0x51, 0x4e, 0x4d, 0x4c, 0x4b, 0x4a, 0x49, 0x47, 0x46, 0x45, 0x43, 0x3c, 0x3a, 0x39, 0x36, 0x35, 0x34, 0x33, 0x32, 0x31, 0x2e, 0x2d, 0x2c, 0x2b, 0x2a, 0x29, 0x27, 0x26, 0x25, 0x23, 0x1f, 0x1e, 0x1d, 0x1b, 0x18, 0x17, 0x10, 0x0f, 0x08, 0x04, 0x02, 0x01, 0x00 }; /* * Local function prototypes. */ static void isp_parse_async(ispsoftc_t *, uint16_t); static void isp_parse_async_fc(ispsoftc_t *, uint16_t); static int isp_handle_other_response(ispsoftc_t *, int, isphdr_t *, uint32_t *); static void isp_parse_status(ispsoftc_t *, ispstatusreq_t *, XS_T *, uint32_t *); static void isp_parse_status_24xx(ispsoftc_t *, isp24xx_statusreq_t *, XS_T *, uint32_t *); static void isp_fastpost_complete(ispsoftc_t *, uint32_t); static void isp_scsi_init(ispsoftc_t *); static void isp_scsi_channel_init(ispsoftc_t *, int); static void isp_fibre_init(ispsoftc_t *); static void isp_fibre_init_2400(ispsoftc_t *); static void isp_clear_portdb(ispsoftc_t *, int); static void isp_mark_portdb(ispsoftc_t *, int); static int isp_plogx(ispsoftc_t *, int, uint16_t, uint32_t, int); static int isp_port_login(ispsoftc_t *, uint16_t, uint32_t); static int isp_port_logout(ispsoftc_t *, uint16_t, uint32_t); static int isp_getpdb(ispsoftc_t *, int, uint16_t, isp_pdb_t *); static int isp_gethandles(ispsoftc_t *, int, uint16_t *, int *, int); static void isp_dump_chip_portdb(ispsoftc_t *, int); static uint64_t isp_get_wwn(ispsoftc_t *, int, int, int); static int isp_fclink_test(ispsoftc_t *, int, int); static int isp_pdb_sync(ispsoftc_t *, int); static int isp_scan_loop(ispsoftc_t *, int); static int isp_gid_pt(ispsoftc_t *, int); static int isp_scan_fabric(ispsoftc_t *, int); static int isp_login_device(ispsoftc_t *, int, uint32_t, isp_pdb_t *, uint16_t *); static int isp_send_change_request(ispsoftc_t *, int); static int isp_register_fc4_type(ispsoftc_t *, int); static int isp_register_fc4_features_24xx(ispsoftc_t *, int); static int isp_register_port_name_24xx(ispsoftc_t *, int); static int isp_register_node_name_24xx(ispsoftc_t *, int); static uint16_t isp_next_handle(ispsoftc_t *, uint16_t *); static int isp_fw_state(ispsoftc_t *, int); static void isp_mboxcmd(ispsoftc_t *, mbreg_t *); static void isp_spi_update(ispsoftc_t *, int); static void isp_setdfltsdparm(ispsoftc_t *); static void isp_setdfltfcparm(ispsoftc_t *, int); static int isp_read_nvram(ispsoftc_t *, int); static int isp_read_nvram_2400(ispsoftc_t *, uint8_t *); static void isp_rdnvram_word(ispsoftc_t *, int, uint16_t *); static void isp_rd_2400_nvram(ispsoftc_t *, uint32_t, uint32_t *); static void isp_parse_nvram_1020(ispsoftc_t *, uint8_t *); static void isp_parse_nvram_1080(ispsoftc_t *, int, uint8_t *); static void isp_parse_nvram_12160(ispsoftc_t *, int, uint8_t *); static void isp_parse_nvram_2100(ispsoftc_t *, uint8_t *); static void isp_parse_nvram_2400(ispsoftc_t *, uint8_t *); static void isp_change_fw_state(ispsoftc_t *isp, int chan, int state) { fcparam *fcp = FCPARAM(isp, chan); if (fcp->isp_fwstate == state) return; isp_prt(isp, ISP_LOGCONFIG|ISP_LOG_SANCFG, "Chan %d Firmware state <%s->%s>", chan, isp_fc_fw_statename(fcp->isp_fwstate), isp_fc_fw_statename(state)); fcp->isp_fwstate = state; } /* * Reset Hardware. * * Hit the chip over the head, download new f/w if available and set it running. * * Locking done elsewhere. */ void isp_reset(ispsoftc_t *isp, int do_load_defaults) { mbreg_t mbs; char *buf; uint64_t fwt; uint32_t code_org, val; int loops, i, dodnld = 1; const char *btype = "????"; static const char dcrc[] = "Downloaded RISC Code Checksum Failure"; /* * Basic types (SCSI, FibreChannel and PCI or SBus) * have been set in the MD code. We figure out more * here. Possibly more refined types based upon PCI * identification. Chip revision has been gathered. * * After we've fired this chip up, zero out the conf1 register * for SCSI adapters and do other settings for the 2100. */ isp->isp_state = ISP_NILSTATE; ISP_DISABLE_INTS(isp); /* * Put the board into PAUSE mode (so we can read the SXP registers * or write FPM/FBM registers). */ if (IS_24XX(isp)) { ISP_WRITE(isp, BIU2400_HCCR, HCCR_2400_CMD_CLEAR_HOST_INT); ISP_WRITE(isp, BIU2400_HCCR, HCCR_2400_CMD_CLEAR_RISC_INT); ISP_WRITE(isp, BIU2400_HCCR, HCCR_2400_CMD_PAUSE); } else { ISP_WRITE(isp, HCCR, HCCR_CMD_PAUSE); } if (IS_FC(isp)) { switch (isp->isp_type) { case ISP_HA_FC_2100: btype = "2100"; break; case ISP_HA_FC_2200: btype = "2200"; break; case ISP_HA_FC_2300: btype = "2300"; break; case ISP_HA_FC_2312: btype = "2312"; break; case ISP_HA_FC_2322: btype = "2322"; break; case ISP_HA_FC_2400: btype = "2422"; break; case ISP_HA_FC_2500: btype = "2532"; break; case ISP_HA_FC_2600: btype = "2600"; break; case ISP_HA_FC_2700: btype = "2700"; break; default: break; } if (!IS_24XX(isp)) { /* * While we're paused, reset the FPM module and FBM * fifos. */ ISP_WRITE(isp, BIU2100_CSR, BIU2100_FPM0_REGS); ISP_WRITE(isp, FPM_DIAG_CONFIG, FPM_SOFT_RESET); ISP_WRITE(isp, BIU2100_CSR, BIU2100_FB_REGS); ISP_WRITE(isp, FBM_CMD, FBMCMD_FIFO_RESET_ALL); ISP_WRITE(isp, BIU2100_CSR, BIU2100_RISC_REGS); } } else if (IS_1240(isp)) { sdparam *sdp; btype = "1240"; isp->isp_clock = 60; sdp = SDPARAM(isp, 0); sdp->isp_ultramode = 1; sdp = SDPARAM(isp, 1); sdp->isp_ultramode = 1; /* * XXX: Should probably do some bus sensing. */ } else if (IS_ULTRA3(isp)) { sdparam *sdp = isp->isp_param; isp->isp_clock = 100; if (IS_10160(isp)) btype = "10160"; else if (IS_12160(isp)) btype = "12160"; else btype = ""; sdp->isp_lvdmode = 1; if (IS_DUALBUS(isp)) { sdp++; sdp->isp_lvdmode = 1; } } else if (IS_ULTRA2(isp)) { static const char m[] = "bus %d is in %s Mode"; uint16_t l; sdparam *sdp = SDPARAM(isp, 0); isp->isp_clock = 100; if (IS_1280(isp)) btype = "1280"; else if (IS_1080(isp)) btype = "1080"; else btype = ""; l = ISP_READ(isp, SXP_PINS_DIFF) & ISP1080_MODE_MASK; switch (l) { case ISP1080_LVD_MODE: sdp->isp_lvdmode = 1; isp_prt(isp, ISP_LOGCONFIG, m, 0, "LVD"); break; case ISP1080_HVD_MODE: sdp->isp_diffmode = 1; isp_prt(isp, ISP_LOGCONFIG, m, 0, "Differential"); break; case ISP1080_SE_MODE: sdp->isp_ultramode = 1; isp_prt(isp, ISP_LOGCONFIG, m, 0, "Single-Ended"); break; default: isp_prt(isp, ISP_LOGERR, "unknown mode on bus %d (0x%x)", 0, l); break; } if (IS_DUALBUS(isp)) { sdp = SDPARAM(isp, 1); l = ISP_READ(isp, SXP_PINS_DIFF|SXP_BANK1_SELECT); l &= ISP1080_MODE_MASK; switch (l) { case ISP1080_LVD_MODE: sdp->isp_lvdmode = 1; isp_prt(isp, ISP_LOGCONFIG, m, 1, "LVD"); break; case ISP1080_HVD_MODE: sdp->isp_diffmode = 1; isp_prt(isp, ISP_LOGCONFIG, m, 1, "Differential"); break; case ISP1080_SE_MODE: sdp->isp_ultramode = 1; isp_prt(isp, ISP_LOGCONFIG, m, 1, "Single-Ended"); break; default: isp_prt(isp, ISP_LOGERR, "unknown mode on bus %d (0x%x)", 1, l); break; } } } else { sdparam *sdp = SDPARAM(isp, 0); i = ISP_READ(isp, BIU_CONF0) & BIU_CONF0_HW_MASK; switch (i) { default: isp_prt(isp, ISP_LOGALL, "Unknown Chip Type 0x%x", i); /* FALLTHROUGH */ case 1: btype = "1020"; isp->isp_type = ISP_HA_SCSI_1020; isp->isp_clock = 40; break; case 2: /* * Some 1020A chips are Ultra Capable, but don't * run the clock rate up for that unless told to * do so by the Ultra Capable bits being set. */ btype = "1020A"; isp->isp_type = ISP_HA_SCSI_1020A; isp->isp_clock = 40; break; case 3: btype = "1040"; isp->isp_type = ISP_HA_SCSI_1040; isp->isp_clock = 60; break; case 4: btype = "1040A"; isp->isp_type = ISP_HA_SCSI_1040A; isp->isp_clock = 60; break; case 5: btype = "1040B"; isp->isp_type = ISP_HA_SCSI_1040B; isp->isp_clock = 60; break; case 6: btype = "1040C"; isp->isp_type = ISP_HA_SCSI_1040C; isp->isp_clock = 60; break; } /* * Now, while we're at it, gather info about ultra * and/or differential mode. */ if (ISP_READ(isp, SXP_PINS_DIFF) & SXP_PINS_DIFF_MODE) { isp_prt(isp, ISP_LOGCONFIG, "Differential Mode"); sdp->isp_diffmode = 1; } else { sdp->isp_diffmode = 0; } i = ISP_READ(isp, RISC_PSR); if (isp->isp_bustype == ISP_BT_SBUS) { i &= RISC_PSR_SBUS_ULTRA; } else { i &= RISC_PSR_PCI_ULTRA; } if (i != 0) { isp_prt(isp, ISP_LOGCONFIG, "Ultra Mode Capable"); sdp->isp_ultramode = 1; /* * If we're in Ultra Mode, we have to be 60MHz clock- * even for the SBus version. */ isp->isp_clock = 60; } else { sdp->isp_ultramode = 0; /* * Clock is known. Gronk. */ } /* * Machine dependent clock (if set) overrides * our generic determinations. */ if (isp->isp_mdvec->dv_clock) { if (isp->isp_mdvec->dv_clock < isp->isp_clock) { isp->isp_clock = isp->isp_mdvec->dv_clock; } } } /* * Hit the chip over the head with hammer, * and give it a chance to recover. */ if (IS_SCSI(isp)) { ISP_WRITE(isp, BIU_ICR, BIU_ICR_SOFT_RESET); /* * A slight delay... */ ISP_DELAY(100); /* * Clear data && control DMA engines. */ ISP_WRITE(isp, CDMA_CONTROL, DMA_CNTRL_CLEAR_CHAN | DMA_CNTRL_RESET_INT); ISP_WRITE(isp, DDMA_CONTROL, DMA_CNTRL_CLEAR_CHAN | DMA_CNTRL_RESET_INT); } else if (IS_24XX(isp)) { /* * Stop DMA and wait for it to stop. */ ISP_WRITE(isp, BIU2400_CSR, BIU2400_DMA_STOP|(3 << 4)); for (val = loops = 0; loops < 30000; loops++) { ISP_DELAY(10); val = ISP_READ(isp, BIU2400_CSR); if ((val & BIU2400_DMA_ACTIVE) == 0) { break; } } if (val & BIU2400_DMA_ACTIVE) { isp_prt(isp, ISP_LOGERR, "DMA Failed to Stop on Reset"); return; } /* * Hold it in SOFT_RESET and STOP state for 100us. */ ISP_WRITE(isp, BIU2400_CSR, BIU2400_SOFT_RESET|BIU2400_DMA_STOP|(3 << 4)); ISP_DELAY(100); for (loops = 0; loops < 10000; loops++) { ISP_DELAY(5); val = ISP_READ(isp, OUTMAILBOX0); } for (val = loops = 0; loops < 500000; loops ++) { val = ISP_READ(isp, BIU2400_CSR); if ((val & BIU2400_SOFT_RESET) == 0) { break; } } if (val & BIU2400_SOFT_RESET) { isp_prt(isp, ISP_LOGERR, "Failed to come out of reset"); return; } } else { ISP_WRITE(isp, BIU2100_CSR, BIU2100_SOFT_RESET); /* * A slight delay... */ ISP_DELAY(100); /* * Clear data && control DMA engines. */ ISP_WRITE(isp, CDMA2100_CONTROL, DMA_CNTRL2100_CLEAR_CHAN | DMA_CNTRL2100_RESET_INT); ISP_WRITE(isp, TDMA2100_CONTROL, DMA_CNTRL2100_CLEAR_CHAN | DMA_CNTRL2100_RESET_INT); ISP_WRITE(isp, RDMA2100_CONTROL, DMA_CNTRL2100_CLEAR_CHAN | DMA_CNTRL2100_RESET_INT); } /* * Wait for ISP to be ready to go... */ loops = MBOX_DELAY_COUNT; for (;;) { if (IS_SCSI(isp)) { if (!(ISP_READ(isp, BIU_ICR) & BIU_ICR_SOFT_RESET)) { break; } } else if (IS_24XX(isp)) { if (ISP_READ(isp, OUTMAILBOX0) == 0) { break; } } else { if (!(ISP_READ(isp, BIU2100_CSR) & BIU2100_SOFT_RESET)) break; } ISP_DELAY(100); if (--loops < 0) { ISP_DUMPREGS(isp, "chip reset timed out"); return; } } /* * After we've fired this chip up, zero out the conf1 register * for SCSI adapters and other settings for the 2100. */ if (IS_SCSI(isp)) { ISP_WRITE(isp, BIU_CONF1, 0); } else if (!IS_24XX(isp)) { ISP_WRITE(isp, BIU2100_CSR, 0); } /* * Reset RISC Processor */ if (IS_24XX(isp)) { ISP_WRITE(isp, BIU2400_HCCR, HCCR_2400_CMD_RESET); ISP_WRITE(isp, BIU2400_HCCR, HCCR_2400_CMD_RELEASE); ISP_WRITE(isp, BIU2400_HCCR, HCCR_2400_CMD_CLEAR_RESET); } else { ISP_WRITE(isp, HCCR, HCCR_CMD_RESET); ISP_DELAY(100); ISP_WRITE(isp, BIU_SEMA, 0); } /* * Post-RISC Reset stuff. */ if (IS_24XX(isp)) { for (val = loops = 0; loops < 5000000; loops++) { ISP_DELAY(5); val = ISP_READ(isp, OUTMAILBOX0); if (val == 0) { break; } } if (val != 0) { isp_prt(isp, ISP_LOGERR, "reset didn't clear"); return; } } else if (IS_SCSI(isp)) { uint16_t tmp = isp->isp_mdvec->dv_conf1; /* * Busted FIFO. Turn off all but burst enables. */ if (isp->isp_type == ISP_HA_SCSI_1040A) { tmp &= BIU_BURST_ENABLE; } ISP_SETBITS(isp, BIU_CONF1, tmp); if (tmp & BIU_BURST_ENABLE) { ISP_SETBITS(isp, CDMA_CONF, DMA_ENABLE_BURST); ISP_SETBITS(isp, DDMA_CONF, DMA_ENABLE_BURST); } if (SDPARAM(isp, 0)->isp_ptisp) { if (SDPARAM(isp, 0)->isp_ultramode) { while (ISP_READ(isp, RISC_MTR) != 0x1313) { ISP_WRITE(isp, RISC_MTR, 0x1313); ISP_WRITE(isp, HCCR, HCCR_CMD_STEP); } } else { ISP_WRITE(isp, RISC_MTR, 0x1212); } /* * PTI specific register */ ISP_WRITE(isp, RISC_EMB, DUAL_BANK); } else { ISP_WRITE(isp, RISC_MTR, 0x1212); } ISP_WRITE(isp, HCCR, HCCR_CMD_RELEASE); } else { ISP_WRITE(isp, RISC_MTR2100, 0x1212); if (IS_2200(isp) || IS_23XX(isp)) { ISP_WRITE(isp, HCCR, HCCR_2X00_DISABLE_PARITY_PAUSE); } ISP_WRITE(isp, HCCR, HCCR_CMD_RELEASE); } /* * Set up default request/response queue in-pointer/out-pointer * register indices. */ if (IS_24XX(isp)) { isp->isp_rqstinrp = BIU2400_REQINP; isp->isp_rqstoutrp = BIU2400_REQOUTP; isp->isp_respinrp = BIU2400_RSPINP; isp->isp_respoutrp = BIU2400_RSPOUTP; } else if (IS_23XX(isp)) { isp->isp_rqstinrp = BIU_REQINP; isp->isp_rqstoutrp = BIU_REQOUTP; isp->isp_respinrp = BIU_RSPINP; isp->isp_respoutrp = BIU_RSPOUTP; } else { isp->isp_rqstinrp = INMAILBOX4; isp->isp_rqstoutrp = OUTMAILBOX4; isp->isp_respinrp = OUTMAILBOX5; isp->isp_respoutrp = INMAILBOX5; } ISP_WRITE(isp, isp->isp_rqstinrp, 0); ISP_WRITE(isp, isp->isp_rqstoutrp, 0); ISP_WRITE(isp, isp->isp_respinrp, 0); ISP_WRITE(isp, isp->isp_respoutrp, 0); if (IS_24XX(isp)) { if (!IS_26XX(isp)) { ISP_WRITE(isp, BIU2400_PRI_REQINP, 0); ISP_WRITE(isp, BIU2400_PRI_REQOUTP, 0); } ISP_WRITE(isp, BIU2400_ATIO_RSPINP, 0); ISP_WRITE(isp, BIU2400_ATIO_RSPOUTP, 0); } if (!IS_24XX(isp) && isp->isp_bustype == ISP_BT_PCI) { /* Make sure the BIOS is disabled */ ISP_WRITE(isp, HCCR, PCI_HCCR_CMD_BIOS); } /* * Wait for everything to finish firing up. * * Avoid doing this on early 2312s because you can generate a PCI * parity error (chip breakage). */ if (IS_2312(isp) && isp->isp_revision < 2) { ISP_DELAY(100); } else { loops = MBOX_DELAY_COUNT; while (ISP_READ(isp, OUTMAILBOX0) == MBOX_BUSY) { ISP_DELAY(100); if (--loops < 0) { isp_prt(isp, ISP_LOGERR, "MBOX_BUSY never cleared on reset"); return; } } } /* * Up until this point we've done everything by just reading or * setting registers. From this point on we rely on at least *some* * kind of firmware running in the card. */ /* * Do some sanity checking by running a NOP command. * If it succeeds, the ROM firmware is now running. */ MBSINIT(&mbs, MBOX_NO_OP, MBLOGALL, 0); isp_mboxcmd(isp, &mbs); if (mbs.param[0] != MBOX_COMMAND_COMPLETE) { isp_prt(isp, ISP_LOGERR, "NOP command failed (%x)", mbs.param[0]); return; } /* * Do some operational tests */ if (IS_SCSI(isp) || IS_24XX(isp)) { static const uint16_t patterns[MAX_MAILBOX] = { 0x0000, 0xdead, 0xbeef, 0xffff, 0xa5a5, 0x5a5a, 0x7f7f, 0x7ff7, 0x3421, 0xabcd, 0xdcba, 0xfeef, 0xbead, 0xdebe, 0x2222, 0x3333, 0x5555, 0x6666, 0x7777, 0xaaaa, 0xffff, 0xdddd, 0x9999, 0x1fbc, 0x6666, 0x6677, 0x1122, 0x33ff, 0x0000, 0x0001, 0x1000, 0x1010, }; int nmbox = ISP_NMBOX(isp); if (IS_SCSI(isp)) nmbox = 6; MBSINIT(&mbs, MBOX_MAILBOX_REG_TEST, MBLOGALL, 0); for (i = 1; i < nmbox; i++) { mbs.param[i] = patterns[i]; } isp_mboxcmd(isp, &mbs); if (mbs.param[0] != MBOX_COMMAND_COMPLETE) { return; } for (i = 1; i < nmbox; i++) { if (mbs.param[i] != patterns[i]) { isp_prt(isp, ISP_LOGERR, "Register Test Failed at Register %d: should have 0x%04x but got 0x%04x", i, patterns[i], mbs.param[i]); return; } } } /* * Download new Firmware, unless requested not to do so. * This is made slightly trickier in some cases where the * firmware of the ROM revision is newer than the revision * compiled into the driver. So, where we used to compare * versions of our f/w and the ROM f/w, now we just see * whether we have f/w at all and whether a config flag * has disabled our download. */ if ((isp->isp_mdvec->dv_ispfw == NULL) || (isp->isp_confopts & ISP_CFG_NORELOAD)) { dodnld = 0; } else { /* * Set up DMA for the request and response queues. * We do this now so we can use the request queue * for dma to load firmware from. */ if (ISP_MBOXDMASETUP(isp) != 0) { isp_prt(isp, ISP_LOGERR, "Cannot setup DMA"); return; } } if (IS_24XX(isp)) { code_org = ISP_CODE_ORG_2400; } else if (IS_23XX(isp)) { code_org = ISP_CODE_ORG_2300; } else { code_org = ISP_CODE_ORG; } isp->isp_loaded_fw = 0; if (dodnld && IS_24XX(isp)) { const uint32_t *ptr = isp->isp_mdvec->dv_ispfw; uint32_t la, wi, wl; /* * Keep loading until we run out of f/w. */ code_org = ptr[2]; /* 1st load address is our start addr */ for (;;) { isp_prt(isp, ISP_LOGDEBUG0, "load 0x%x words of code at load address 0x%x", ptr[3], ptr[2]); wi = 0; la = ptr[2]; wl = ptr[3]; while (wi < ptr[3]) { uint32_t *cp; uint32_t nw; nw = min(wl, ISP_QUEUE_SIZE(RQUEST_QUEUE_LEN(isp)) / 4); cp = isp->isp_rquest; for (i = 0; i < nw; i++) ISP_IOXPUT_32(isp, ptr[wi + i], &cp[i]); MEMORYBARRIER(isp, SYNC_REQUEST, 0, ISP_QUEUE_SIZE(RQUEST_QUEUE_LEN(isp)), -1); MBSINIT(&mbs, MBOX_LOAD_RISC_RAM, MBLOGALL, 0); mbs.param[1] = la; mbs.param[2] = DMA_WD1(isp->isp_rquest_dma); mbs.param[3] = DMA_WD0(isp->isp_rquest_dma); mbs.param[4] = nw >> 16; mbs.param[5] = nw; mbs.param[6] = DMA_WD3(isp->isp_rquest_dma); mbs.param[7] = DMA_WD2(isp->isp_rquest_dma); mbs.param[8] = la >> 16; isp_prt(isp, ISP_LOGDEBUG0, "LOAD RISC RAM %u words at load address 0x%x", nw, la); isp_mboxcmd(isp, &mbs); if (mbs.param[0] != MBOX_COMMAND_COMPLETE) { isp_prt(isp, ISP_LOGERR, "F/W download failed"); return; } la += nw; wi += nw; wl -= nw; } if (ptr[1] == 0) { break; } ptr += ptr[3]; } isp->isp_loaded_fw = 1; } else if (dodnld && IS_23XX(isp)) { const uint16_t *ptr = isp->isp_mdvec->dv_ispfw; uint16_t wi, wl, segno; uint32_t la; la = code_org; segno = 0; for (;;) { uint32_t nxtaddr; isp_prt(isp, ISP_LOGDEBUG0, "load 0x%x words of code at load address 0x%x", ptr[3], la); wi = 0; wl = ptr[3]; while (wi < ptr[3]) { uint16_t *cp; uint16_t nw; nw = min(wl, min((1 << 15), ISP_QUEUE_SIZE(RQUEST_QUEUE_LEN(isp)) / 2)); cp = isp->isp_rquest; for (i = 0; i < nw; i++) ISP_IOXPUT_16(isp, ptr[wi + i], &cp[i]); MEMORYBARRIER(isp, SYNC_REQUEST, 0, ISP_QUEUE_SIZE(RQUEST_QUEUE_LEN(isp)), -1); MBSINIT(&mbs, 0, MBLOGALL, 0); if (la < 0x10000) { mbs.param[0] = MBOX_LOAD_RISC_RAM_2100; mbs.param[1] = la; mbs.param[2] = DMA_WD1(isp->isp_rquest_dma); mbs.param[3] = DMA_WD0(isp->isp_rquest_dma); mbs.param[4] = nw; mbs.param[6] = DMA_WD3(isp->isp_rquest_dma); mbs.param[7] = DMA_WD2(isp->isp_rquest_dma); isp_prt(isp, ISP_LOGDEBUG1, "LOAD RISC RAM 2100 %u words at load address 0x%x\n", nw, la); } else { mbs.param[0] = MBOX_LOAD_RISC_RAM; mbs.param[1] = la; mbs.param[2] = DMA_WD1(isp->isp_rquest_dma); mbs.param[3] = DMA_WD0(isp->isp_rquest_dma); mbs.param[4] = nw; mbs.param[6] = DMA_WD3(isp->isp_rquest_dma); mbs.param[7] = DMA_WD2(isp->isp_rquest_dma); mbs.param[8] = la >> 16; isp_prt(isp, ISP_LOGDEBUG1, "LOAD RISC RAM %u words at load address 0x%x\n", nw, la); } isp_mboxcmd(isp, &mbs); if (mbs.param[0] != MBOX_COMMAND_COMPLETE) { isp_prt(isp, ISP_LOGERR, "F/W download failed"); return; } la += nw; wi += nw; wl -= nw; } if (!IS_2322(isp)) { break; } if (++segno == 3) { break; } /* * If we're a 2322, the firmware actually comes in * three chunks. We loaded the first at the code_org * address. The other two chunks, which follow right * after each other in memory here, get loaded at * addresses specfied at offset 0x9..0xB. */ nxtaddr = ptr[3]; ptr = &ptr[nxtaddr]; la = ptr[5] | ((ptr[4] & 0x3f) << 16); } isp->isp_loaded_fw = 1; } else if (dodnld) { const uint16_t *ptr = isp->isp_mdvec->dv_ispfw; u_int i, wl; wl = ptr[3]; isp_prt(isp, ISP_LOGDEBUG1, "WRITE RAM %u words at load address 0x%x", wl, code_org); for (i = 0; i < wl; i++) { MBSINIT(&mbs, MBOX_WRITE_RAM_WORD, MBLOGNONE, 0); mbs.param[1] = code_org + i; mbs.param[2] = ptr[i]; isp_mboxcmd(isp, &mbs); if (mbs.param[0] != MBOX_COMMAND_COMPLETE) { isp_prt(isp, ISP_LOGERR, "F/W download failed at word %d", i); return; } } } else if (IS_26XX(isp)) { isp_prt(isp, ISP_LOGDEBUG1, "loading firmware from flash"); MBSINIT(&mbs, MBOX_LOAD_FLASH_FIRMWARE, MBLOGALL, 5000000); mbs.ibitm = 0x01; mbs.obitm = 0x07; isp_mboxcmd(isp, &mbs); if (mbs.param[0] != MBOX_COMMAND_COMPLETE) { isp_prt(isp, ISP_LOGERR, "Flash F/W load failed"); return; } } else { isp_prt(isp, ISP_LOGDEBUG2, "skipping f/w download"); } /* * If we loaded firmware, verify its checksum */ if (isp->isp_loaded_fw) { MBSINIT(&mbs, MBOX_VERIFY_CHECKSUM, MBLOGNONE, 0); if (IS_24XX(isp)) { mbs.param[1] = code_org >> 16; mbs.param[2] = code_org; } else { mbs.param[1] = code_org; } isp_mboxcmd(isp, &mbs); if (mbs.param[0] != MBOX_COMMAND_COMPLETE) { isp_prt(isp, ISP_LOGERR, dcrc); return; } } /* * Now start it rolling. * * If we didn't actually download f/w, * we still need to (re)start it. */ MBSINIT(&mbs, MBOX_EXEC_FIRMWARE, MBLOGALL, 5000000); if (IS_26XX(isp)) { mbs.param[1] = code_org >> 16; mbs.param[2] = code_org; } else if (IS_24XX(isp)) { mbs.param[1] = code_org >> 16; mbs.param[2] = code_org; if (isp->isp_loaded_fw) { mbs.param[3] = 0; } else { mbs.param[3] = 1; } } else if (IS_2322(isp)) { mbs.param[1] = code_org; if (isp->isp_loaded_fw) { mbs.param[2] = 0; } else { mbs.param[2] = 1; } } else { mbs.param[1] = code_org; } isp_mboxcmd(isp, &mbs); if (IS_2322(isp) || IS_24XX(isp)) { if (mbs.param[0] != MBOX_COMMAND_COMPLETE) { return; } } if (IS_SCSI(isp)) { /* * Set CLOCK RATE, but only if asked to. */ if (isp->isp_clock) { MBSINIT(&mbs, MBOX_SET_CLOCK_RATE, MBLOGALL, 0); mbs.param[1] = isp->isp_clock; isp_mboxcmd(isp, &mbs); /* we will try not to care if this fails */ } } /* * Ask the chip for the current firmware version. * This should prove that the new firmware is working. */ MBSINIT(&mbs, MBOX_ABOUT_FIRMWARE, MBLOGALL, 5000000); isp_mboxcmd(isp, &mbs); if (mbs.param[0] != MBOX_COMMAND_COMPLETE) { return; } /* * The SBus firmware that we are using apparently does not return * major, minor, micro revisions in the mailbox registers, which * is really, really, annoying. */ if (ISP_SBUS_SUPPORTED && isp->isp_bustype == ISP_BT_SBUS) { if (dodnld) { #ifdef ISP_TARGET_MODE isp->isp_fwrev[0] = 7; isp->isp_fwrev[1] = 55; #else isp->isp_fwrev[0] = 1; isp->isp_fwrev[1] = 37; #endif isp->isp_fwrev[2] = 0; } } else { isp->isp_fwrev[0] = mbs.param[1]; isp->isp_fwrev[1] = mbs.param[2]; isp->isp_fwrev[2] = mbs.param[3]; } if (IS_FC(isp)) { /* * We do not believe firmware attributes for 2100 code less * than 1.17.0, unless it's the firmware we specifically * are loading. * * Note that all 22XX and later f/w is greater than 1.X.0. */ if ((ISP_FW_OLDER_THAN(isp, 1, 17, 1))) { #ifdef USE_SMALLER_2100_FIRMWARE isp->isp_fwattr = ISP_FW_ATTR_SCCLUN; #else isp->isp_fwattr = 0; #endif } else { isp->isp_fwattr = mbs.param[6]; } if (IS_24XX(isp)) { isp->isp_fwattr |= ((uint64_t) mbs.param[15]) << 16; if (isp->isp_fwattr & ISP2400_FW_ATTR_EXTNDED) { isp->isp_fwattr |= (((uint64_t) mbs.param[16]) << 32) | (((uint64_t) mbs.param[17]) << 48); } } } else { isp->isp_fwattr = 0; } isp_prt(isp, ISP_LOGCONFIG, "Board Type %s, Chip Revision 0x%x, %s F/W Revision %d.%d.%d", btype, isp->isp_revision, dodnld? "loaded" : "resident", isp->isp_fwrev[0], isp->isp_fwrev[1], isp->isp_fwrev[2]); fwt = isp->isp_fwattr; if (IS_24XX(isp)) { buf = FCPARAM(isp, 0)->isp_scanscratch; ISP_SNPRINTF(buf, ISP_FC_SCRLEN, "Attributes:"); if (fwt & ISP2400_FW_ATTR_CLASS2) { fwt ^=ISP2400_FW_ATTR_CLASS2; ISP_SNPRINTF(buf, ISP_FC_SCRLEN - strlen(buf), "%s Class2", buf); } if (fwt & ISP2400_FW_ATTR_IP) { fwt ^=ISP2400_FW_ATTR_IP; ISP_SNPRINTF(buf, ISP_FC_SCRLEN - strlen(buf), "%s IP", buf); } if (fwt & ISP2400_FW_ATTR_MULTIID) { fwt ^=ISP2400_FW_ATTR_MULTIID; ISP_SNPRINTF(buf, ISP_FC_SCRLEN - strlen(buf), "%s MultiID", buf); } if (fwt & ISP2400_FW_ATTR_SB2) { fwt ^=ISP2400_FW_ATTR_SB2; ISP_SNPRINTF(buf, ISP_FC_SCRLEN - strlen(buf), "%s SB2", buf); } if (fwt & ISP2400_FW_ATTR_T10CRC) { fwt ^=ISP2400_FW_ATTR_T10CRC; ISP_SNPRINTF(buf, ISP_FC_SCRLEN - strlen(buf), "%s T10CRC", buf); } if (fwt & ISP2400_FW_ATTR_VI) { fwt ^=ISP2400_FW_ATTR_VI; ISP_SNPRINTF(buf, ISP_FC_SCRLEN - strlen(buf), "%s VI", buf); } if (fwt & ISP2400_FW_ATTR_MQ) { fwt ^=ISP2400_FW_ATTR_MQ; ISP_SNPRINTF(buf, ISP_FC_SCRLEN - strlen(buf), "%s MQ", buf); } if (fwt & ISP2400_FW_ATTR_MSIX) { fwt ^=ISP2400_FW_ATTR_MSIX; ISP_SNPRINTF(buf, ISP_FC_SCRLEN - strlen(buf), "%s MSIX", buf); } if (fwt & ISP2400_FW_ATTR_FCOE) { fwt ^=ISP2400_FW_ATTR_FCOE; ISP_SNPRINTF(buf, ISP_FC_SCRLEN - strlen(buf), "%s FCOE", buf); } if (fwt & ISP2400_FW_ATTR_VP0) { fwt ^= ISP2400_FW_ATTR_VP0; ISP_SNPRINTF(buf, ISP_FC_SCRLEN - strlen(buf), "%s VP0_Decoupling", buf); } if (fwt & ISP2400_FW_ATTR_EXPFW) { fwt ^= ISP2400_FW_ATTR_EXPFW; ISP_SNPRINTF(buf, ISP_FC_SCRLEN - strlen(buf), "%s (Experimental)", buf); } if (fwt & ISP2400_FW_ATTR_HOTFW) { fwt ^= ISP2400_FW_ATTR_HOTFW; ISP_SNPRINTF(buf, ISP_FC_SCRLEN - strlen(buf), "%s HotFW", buf); } fwt &= ~ISP2400_FW_ATTR_EXTNDED; if (fwt & ISP2400_FW_ATTR_EXTVP) { fwt ^= ISP2400_FW_ATTR_EXTVP; ISP_SNPRINTF(buf, ISP_FC_SCRLEN - strlen(buf), "%s ExtVP", buf); } if (fwt & ISP2400_FW_ATTR_VN2VN) { fwt ^= ISP2400_FW_ATTR_VN2VN; ISP_SNPRINTF(buf, ISP_FC_SCRLEN - strlen(buf), "%s VN2VN", buf); } if (fwt & ISP2400_FW_ATTR_EXMOFF) { fwt ^= ISP2400_FW_ATTR_EXMOFF; ISP_SNPRINTF(buf, ISP_FC_SCRLEN - strlen(buf), "%s EXMOFF", buf); } if (fwt & ISP2400_FW_ATTR_NPMOFF) { fwt ^= ISP2400_FW_ATTR_NPMOFF; ISP_SNPRINTF(buf, ISP_FC_SCRLEN - strlen(buf), "%s NPMOFF", buf); } if (fwt & ISP2400_FW_ATTR_DIFCHOP) { fwt ^= ISP2400_FW_ATTR_DIFCHOP; ISP_SNPRINTF(buf, ISP_FC_SCRLEN - strlen(buf), "%s DIFCHOP", buf); } if (fwt & ISP2400_FW_ATTR_SRIOV) { fwt ^= ISP2400_FW_ATTR_SRIOV; ISP_SNPRINTF(buf, ISP_FC_SCRLEN - strlen(buf), "%s SRIOV", buf); } if (fwt & ISP2400_FW_ATTR_ASICTMP) { fwt ^= ISP2400_FW_ATTR_ASICTMP; ISP_SNPRINTF(buf, ISP_FC_SCRLEN - strlen(buf), "%s ASICTMP", buf); } if (fwt & ISP2400_FW_ATTR_ATIOMQ) { fwt ^= ISP2400_FW_ATTR_ATIOMQ; ISP_SNPRINTF(buf, ISP_FC_SCRLEN - strlen(buf), "%s ATIOMQ", buf); } if (fwt) { ISP_SNPRINTF(buf, ISP_FC_SCRLEN - strlen(buf), "%s (unknown 0x%08x%08x)", buf, (uint32_t) (fwt >> 32), (uint32_t) fwt); } isp_prt(isp, ISP_LOGCONFIG, "%s", buf); } else if (IS_FC(isp)) { buf = FCPARAM(isp, 0)->isp_scanscratch; ISP_SNPRINTF(buf, ISP_FC_SCRLEN, "Attributes:"); if (fwt & ISP_FW_ATTR_TMODE) { fwt ^=ISP_FW_ATTR_TMODE; ISP_SNPRINTF(buf, ISP_FC_SCRLEN - strlen(buf), "%s TargetMode", buf); } if (fwt & ISP_FW_ATTR_SCCLUN) { fwt ^=ISP_FW_ATTR_SCCLUN; ISP_SNPRINTF(buf, ISP_FC_SCRLEN - strlen(buf), "%s SCC-Lun", buf); } if (fwt & ISP_FW_ATTR_FABRIC) { fwt ^=ISP_FW_ATTR_FABRIC; ISP_SNPRINTF(buf, ISP_FC_SCRLEN - strlen(buf), "%s Fabric", buf); } if (fwt & ISP_FW_ATTR_CLASS2) { fwt ^=ISP_FW_ATTR_CLASS2; ISP_SNPRINTF(buf, ISP_FC_SCRLEN - strlen(buf), "%s Class2", buf); } if (fwt & ISP_FW_ATTR_FCTAPE) { fwt ^=ISP_FW_ATTR_FCTAPE; ISP_SNPRINTF(buf, ISP_FC_SCRLEN - strlen(buf), "%s FC-Tape", buf); } if (fwt & ISP_FW_ATTR_IP) { fwt ^=ISP_FW_ATTR_IP; ISP_SNPRINTF(buf, ISP_FC_SCRLEN - strlen(buf), "%s IP", buf); } if (fwt & ISP_FW_ATTR_VI) { fwt ^=ISP_FW_ATTR_VI; ISP_SNPRINTF(buf, ISP_FC_SCRLEN - strlen(buf), "%s VI", buf); } if (fwt & ISP_FW_ATTR_VI_SOLARIS) { fwt ^=ISP_FW_ATTR_VI_SOLARIS; ISP_SNPRINTF(buf, ISP_FC_SCRLEN - strlen(buf), "%s VI_SOLARIS", buf); } if (fwt & ISP_FW_ATTR_2KLOGINS) { fwt ^=ISP_FW_ATTR_2KLOGINS; ISP_SNPRINTF(buf, ISP_FC_SCRLEN - strlen(buf), "%s 2K-Login", buf); } if (fwt != 0) { ISP_SNPRINTF(buf, ISP_FC_SCRLEN - strlen(buf), "%s (unknown 0x%08x%08x)", buf, (uint32_t) (fwt >> 32), (uint32_t) fwt); } isp_prt(isp, ISP_LOGCONFIG, "%s", buf); } if (IS_24XX(isp)) { MBSINIT(&mbs, MBOX_GET_RESOURCE_COUNT, MBLOGALL, 0); isp_mboxcmd(isp, &mbs); if (mbs.param[0] != MBOX_COMMAND_COMPLETE) { return; } isp->isp_maxcmds = mbs.param[3]; } else { MBSINIT(&mbs, MBOX_GET_FIRMWARE_STATUS, MBLOGALL, 0); isp_mboxcmd(isp, &mbs); if (mbs.param[0] != MBOX_COMMAND_COMPLETE) { return; } isp->isp_maxcmds = mbs.param[2]; } isp_prt(isp, ISP_LOGCONFIG, "%d max I/O command limit set", isp->isp_maxcmds); /* * If we don't have Multi-ID f/w loaded, we need to restrict channels to one. * Only make this check for non-SCSI cards (I'm not sure firmware attributes * work for them). */ if (IS_FC(isp) && isp->isp_nchan > 1) { if (!ISP_CAP_MULTI_ID(isp)) { isp_prt(isp, ISP_LOGWARN, "non-MULTIID f/w loaded, " "only can enable 1 of %d channels", isp->isp_nchan); isp->isp_nchan = 1; } else if (!ISP_CAP_VP0(isp)) { isp_prt(isp, ISP_LOGWARN, "We can not use MULTIID " "feature properly without VP0_Decoupling"); isp->isp_nchan = 1; } } /* * Final DMA setup after we got isp_maxcmds. */ if (ISP_MBOXDMASETUP(isp) != 0) { isp_prt(isp, ISP_LOGERR, "Cannot setup DMA"); return; } /* * Setup interrupts. */ if (ISP_IRQSETUP(isp) != 0) { isp_prt(isp, ISP_LOGERR, "Cannot setup IRQ"); return; } ISP_ENABLE_INTS(isp); if (IS_FC(isp)) { for (i = 0; i < isp->isp_nchan; i++) isp_change_fw_state(isp, i, FW_CONFIG_WAIT); } isp->isp_state = ISP_RESETSTATE; /* * Okay- now that we have new firmware running, we now (re)set our * notion of how many luns we support. This is somewhat tricky because * if we haven't loaded firmware, we sometimes do not have an easy way * of knowing how many luns we support. * * Expanded lun firmware gives you 32 luns for SCSI cards and * unlimited luns for Fibre Channel cards. * * It turns out that even for QLogic 2100s with ROM 1.10 and above * we do get a firmware attributes word returned in mailbox register 6. * * Because the lun is in a different position in the Request Queue * Entry structure for Fibre Channel with expanded lun firmware, we * can only support one lun (lun zero) when we don't know what kind * of firmware we're running. */ if (IS_SCSI(isp)) { if (dodnld) { if (IS_ULTRA2(isp) || IS_ULTRA3(isp)) { isp->isp_maxluns = 32; } else { isp->isp_maxluns = 8; } } else { isp->isp_maxluns = 8; } } else { if (ISP_CAP_SCCFW(isp)) { isp->isp_maxluns = 0; /* No limit -- 2/8 bytes */ } else { isp->isp_maxluns = 16; } } /* * We get some default values established. As a side * effect, NVRAM is read here (unless overriden by * a configuration flag). */ if (do_load_defaults) { if (IS_SCSI(isp)) { isp_setdfltsdparm(isp); } else { for (i = 0; i < isp->isp_nchan; i++) { isp_setdfltfcparm(isp, i); } } } } /* * Clean firmware shutdown. */ static int isp_stop(ispsoftc_t *isp) { mbreg_t mbs; isp->isp_state = ISP_NILSTATE; MBSINIT(&mbs, MBOX_STOP_FIRMWARE, MBLOGALL, 500000); mbs.param[1] = 0; mbs.param[2] = 0; mbs.param[3] = 0; mbs.param[4] = 0; mbs.param[5] = 0; mbs.param[6] = 0; mbs.param[7] = 0; mbs.param[8] = 0; isp_mboxcmd(isp, &mbs); return (mbs.param[0] == MBOX_COMMAND_COMPLETE ? 0 : mbs.param[0]); } /* * Hardware shutdown. */ void isp_shutdown(ispsoftc_t *isp) { if (isp->isp_state >= ISP_RESETSTATE) isp_stop(isp); ISP_DISABLE_INTS(isp); if (IS_FC(isp)) { if (IS_24XX(isp)) { ISP_WRITE(isp, BIU2400_ICR, 0); ISP_WRITE(isp, BIU2400_HCCR, HCCR_2400_CMD_PAUSE); } else { ISP_WRITE(isp, BIU_ICR, 0); ISP_WRITE(isp, HCCR, HCCR_CMD_PAUSE); ISP_WRITE(isp, BIU2100_CSR, BIU2100_FPM0_REGS); ISP_WRITE(isp, FPM_DIAG_CONFIG, FPM_SOFT_RESET); ISP_WRITE(isp, BIU2100_CSR, BIU2100_FB_REGS); ISP_WRITE(isp, FBM_CMD, FBMCMD_FIFO_RESET_ALL); ISP_WRITE(isp, BIU2100_CSR, BIU2100_RISC_REGS); } } else { ISP_WRITE(isp, BIU_ICR, 0); ISP_WRITE(isp, HCCR, HCCR_CMD_PAUSE); } } /* * Initialize Parameters of Hardware to a known state. * * Locks are held before coming here. */ void isp_init(ispsoftc_t *isp) { if (IS_FC(isp)) { if (IS_24XX(isp)) { isp_fibre_init_2400(isp); } else { isp_fibre_init(isp); } } else { isp_scsi_init(isp); } } static void isp_scsi_init(ispsoftc_t *isp) { sdparam *sdp_chan0, *sdp_chan1; mbreg_t mbs; isp->isp_state = ISP_INITSTATE; sdp_chan0 = SDPARAM(isp, 0); sdp_chan1 = sdp_chan0; if (IS_DUALBUS(isp)) { sdp_chan1 = SDPARAM(isp, 1); } /* First do overall per-card settings. */ /* * If we have fast memory timing enabled, turn it on. */ if (sdp_chan0->isp_fast_mttr) { ISP_WRITE(isp, RISC_MTR, 0x1313); } /* * Set Retry Delay and Count. * You set both channels at the same time. */ MBSINIT(&mbs, MBOX_SET_RETRY_COUNT, MBLOGALL, 0); mbs.param[1] = sdp_chan0->isp_retry_count; mbs.param[2] = sdp_chan0->isp_retry_delay; mbs.param[6] = sdp_chan1->isp_retry_count; mbs.param[7] = sdp_chan1->isp_retry_delay; isp_mboxcmd(isp, &mbs); if (mbs.param[0] != MBOX_COMMAND_COMPLETE) { return; } /* * Set ASYNC DATA SETUP time. This is very important. */ MBSINIT(&mbs, MBOX_SET_ASYNC_DATA_SETUP_TIME, MBLOGALL, 0); mbs.param[1] = sdp_chan0->isp_async_data_setup; mbs.param[2] = sdp_chan1->isp_async_data_setup; isp_mboxcmd(isp, &mbs); if (mbs.param[0] != MBOX_COMMAND_COMPLETE) { return; } /* * Set ACTIVE Negation State. */ MBSINIT(&mbs, MBOX_SET_ACT_NEG_STATE, MBLOGNONE, 0); mbs.param[1] = (sdp_chan0->isp_req_ack_active_neg << 4) | (sdp_chan0->isp_data_line_active_neg << 5); mbs.param[2] = (sdp_chan1->isp_req_ack_active_neg << 4) | (sdp_chan1->isp_data_line_active_neg << 5); isp_mboxcmd(isp, &mbs); if (mbs.param[0] != MBOX_COMMAND_COMPLETE) { isp_prt(isp, ISP_LOGERR, "failed to set active negation state (%d,%d), (%d,%d)", sdp_chan0->isp_req_ack_active_neg, sdp_chan0->isp_data_line_active_neg, sdp_chan1->isp_req_ack_active_neg, sdp_chan1->isp_data_line_active_neg); /* * But don't return. */ } /* * Set the Tag Aging limit */ MBSINIT(&mbs, MBOX_SET_TAG_AGE_LIMIT, MBLOGALL, 0); mbs.param[1] = sdp_chan0->isp_tag_aging; mbs.param[2] = sdp_chan1->isp_tag_aging; isp_mboxcmd(isp, &mbs); if (mbs.param[0] != MBOX_COMMAND_COMPLETE) { isp_prt(isp, ISP_LOGERR, "failed to set tag age limit (%d,%d)", sdp_chan0->isp_tag_aging, sdp_chan1->isp_tag_aging); return; } /* * Set selection timeout. */ MBSINIT(&mbs, MBOX_SET_SELECT_TIMEOUT, MBLOGALL, 0); mbs.param[1] = sdp_chan0->isp_selection_timeout; mbs.param[2] = sdp_chan1->isp_selection_timeout; isp_mboxcmd(isp, &mbs); if (mbs.param[0] != MBOX_COMMAND_COMPLETE) { return; } /* now do per-channel settings */ isp_scsi_channel_init(isp, 0); if (IS_DUALBUS(isp)) isp_scsi_channel_init(isp, 1); /* * Now enable request/response queues */ if (IS_ULTRA2(isp) || IS_1240(isp)) { MBSINIT(&mbs, MBOX_INIT_RES_QUEUE_A64, MBLOGALL, 0); mbs.param[1] = RESULT_QUEUE_LEN(isp); mbs.param[2] = DMA_WD1(isp->isp_result_dma); mbs.param[3] = DMA_WD0(isp->isp_result_dma); mbs.param[4] = 0; mbs.param[6] = DMA_WD3(isp->isp_result_dma); mbs.param[7] = DMA_WD2(isp->isp_result_dma); isp_mboxcmd(isp, &mbs); if (mbs.param[0] != MBOX_COMMAND_COMPLETE) { return; } isp->isp_residx = isp->isp_resodx = mbs.param[5]; MBSINIT(&mbs, MBOX_INIT_REQ_QUEUE_A64, MBLOGALL, 0); mbs.param[1] = RQUEST_QUEUE_LEN(isp); mbs.param[2] = DMA_WD1(isp->isp_rquest_dma); mbs.param[3] = DMA_WD0(isp->isp_rquest_dma); mbs.param[5] = 0; mbs.param[6] = DMA_WD3(isp->isp_result_dma); mbs.param[7] = DMA_WD2(isp->isp_result_dma); isp_mboxcmd(isp, &mbs); if (mbs.param[0] != MBOX_COMMAND_COMPLETE) { return; } isp->isp_reqidx = isp->isp_reqodx = mbs.param[4]; } else { MBSINIT(&mbs, MBOX_INIT_RES_QUEUE, MBLOGALL, 0); mbs.param[1] = RESULT_QUEUE_LEN(isp); mbs.param[2] = DMA_WD1(isp->isp_result_dma); mbs.param[3] = DMA_WD0(isp->isp_result_dma); mbs.param[4] = 0; isp_mboxcmd(isp, &mbs); if (mbs.param[0] != MBOX_COMMAND_COMPLETE) { return; } isp->isp_residx = isp->isp_resodx = mbs.param[5]; MBSINIT(&mbs, MBOX_INIT_REQ_QUEUE, MBLOGALL, 0); mbs.param[1] = RQUEST_QUEUE_LEN(isp); mbs.param[2] = DMA_WD1(isp->isp_rquest_dma); mbs.param[3] = DMA_WD0(isp->isp_rquest_dma); mbs.param[5] = 0; isp_mboxcmd(isp, &mbs); if (mbs.param[0] != MBOX_COMMAND_COMPLETE) { return; } isp->isp_reqidx = isp->isp_reqodx = mbs.param[4]; } /* * Turn on LVD transitions for ULTRA2 or better and other features * * Now that we have 32 bit handles, don't do any fast posting * any more. For Ultra2/Ultra3 cards, we can turn on 32 bit RIO * operation or use fast posting. To be conservative, we'll only * do this for Ultra3 cards now because the other cards are so * rare for this author to find and test with. */ MBSINIT(&mbs, MBOX_SET_FW_FEATURES, MBLOGALL, 0); if (IS_ULTRA2(isp)) mbs.param[1] |= FW_FEATURE_LVD_NOTIFY; #ifdef ISP_NO_RIO if (IS_ULTRA3(isp)) mbs.param[1] |= FW_FEATURE_FAST_POST; #else if (IS_ULTRA3(isp)) mbs.param[1] |= FW_FEATURE_RIO_32BIT; #endif if (mbs.param[1] != 0) { uint16_t sfeat = mbs.param[1]; isp_mboxcmd(isp, &mbs); if (mbs.param[0] == MBOX_COMMAND_COMPLETE) { isp_prt(isp, ISP_LOGINFO, "Enabled FW features (0x%x)", sfeat); } } isp->isp_state = ISP_RUNSTATE; } static void isp_scsi_channel_init(ispsoftc_t *isp, int chan) { sdparam *sdp; mbreg_t mbs; int tgt; sdp = SDPARAM(isp, chan); /* * Set (possibly new) Initiator ID. */ MBSINIT(&mbs, MBOX_SET_INIT_SCSI_ID, MBLOGALL, 0); mbs.param[1] = (chan << 7) | sdp->isp_initiator_id; isp_mboxcmd(isp, &mbs); if (mbs.param[0] != MBOX_COMMAND_COMPLETE) { return; } isp_prt(isp, ISP_LOGINFO, "Chan %d Initiator ID is %d", chan, sdp->isp_initiator_id); /* * Set current per-target parameters to an initial safe minimum. */ for (tgt = 0; tgt < MAX_TARGETS; tgt++) { int lun; uint16_t sdf; if (sdp->isp_devparam[tgt].dev_enable == 0) { continue; } #ifndef ISP_TARGET_MODE sdf = sdp->isp_devparam[tgt].goal_flags; sdf &= DPARM_SAFE_DFLT; /* * It is not quite clear when this changed over so that * we could force narrow and async for 1000/1020 cards, * but assume that this is only the case for loaded * firmware. */ if (isp->isp_loaded_fw) { sdf |= DPARM_NARROW | DPARM_ASYNC; } #else /* * The !$*!)$!$)* f/w uses the same index into some * internal table to decide how to respond to negotiations, * so if we've said "let's be safe" for ID X, and ID X * selects *us*, the negotiations will back to 'safe' * (as in narrow/async). What the f/w *should* do is * use the initiator id settings to decide how to respond. */ sdp->isp_devparam[tgt].goal_flags = sdf = DPARM_DEFAULT; #endif MBSINIT(&mbs, MBOX_SET_TARGET_PARAMS, MBLOGNONE, 0); mbs.param[1] = (chan << 15) | (tgt << 8); mbs.param[2] = sdf; if ((sdf & DPARM_SYNC) == 0) { mbs.param[3] = 0; } else { mbs.param[3] = (sdp->isp_devparam[tgt].goal_offset << 8) | (sdp->isp_devparam[tgt].goal_period); } isp_prt(isp, ISP_LOGDEBUG0, "Initial Settings bus%d tgt%d flags 0x%x off 0x%x per 0x%x", chan, tgt, mbs.param[2], mbs.param[3] >> 8, mbs.param[3] & 0xff); isp_mboxcmd(isp, &mbs); if (mbs.param[0] != MBOX_COMMAND_COMPLETE) { sdf = DPARM_SAFE_DFLT; MBSINIT(&mbs, MBOX_SET_TARGET_PARAMS, MBLOGALL, 0); mbs.param[1] = (tgt << 8) | (chan << 15); mbs.param[2] = sdf; mbs.param[3] = 0; isp_mboxcmd(isp, &mbs); if (mbs.param[0] != MBOX_COMMAND_COMPLETE) { continue; } } /* * We don't update any information directly from the f/w * because we need to run at least one command to cause a * new state to be latched up. So, we just assume that we * converge to the values we just had set. * * Ensure that we don't believe tagged queuing is enabled yet. * It turns out that sometimes the ISP just ignores our * attempts to set parameters for devices that it hasn't * seen yet. */ sdp->isp_devparam[tgt].actv_flags = sdf & ~DPARM_TQING; for (lun = 0; lun < (int) isp->isp_maxluns; lun++) { MBSINIT(&mbs, MBOX_SET_DEV_QUEUE_PARAMS, MBLOGALL, 0); mbs.param[1] = (chan << 15) | (tgt << 8) | lun; mbs.param[2] = sdp->isp_max_queue_depth; mbs.param[3] = sdp->isp_devparam[tgt].exc_throttle; isp_mboxcmd(isp, &mbs); if (mbs.param[0] != MBOX_COMMAND_COMPLETE) { break; } } } for (tgt = 0; tgt < MAX_TARGETS; tgt++) { if (sdp->isp_devparam[tgt].dev_refresh) { sdp->sendmarker = 1; sdp->update = 1; break; } } } /* * Fibre Channel specific initialization. */ static void isp_fibre_init(ispsoftc_t *isp) { fcparam *fcp; isp_icb_t local, *icbp = &local; mbreg_t mbs; int ownloopid; /* * We only support one channel on non-24XX cards */ fcp = FCPARAM(isp, 0); if (fcp->role == ISP_ROLE_NONE) return; isp->isp_state = ISP_INITSTATE; ISP_MEMZERO(icbp, sizeof (*icbp)); icbp->icb_version = ICB_VERSION1; icbp->icb_fwoptions = fcp->isp_fwoptions; /* * Firmware Options are either retrieved from NVRAM or * are patched elsewhere. We check them for sanity here * and make changes based on board revision, but otherwise * let others decide policy. */ /* * If this is a 2100 < revision 5, we have to turn off FAIRNESS. */ if (IS_2100(isp) && isp->isp_revision < 5) { icbp->icb_fwoptions &= ~ICBOPT_FAIRNESS; } /* * We have to use FULL LOGIN even though it resets the loop too much * because otherwise port database entries don't get updated after * a LIP- this is a known f/w bug for 2100 f/w less than 1.17.0. */ if (!ISP_FW_NEWER_THAN(isp, 1, 17, 0)) { icbp->icb_fwoptions |= ICBOPT_FULL_LOGIN; } /* * Insist on Port Database Update Async notifications */ icbp->icb_fwoptions |= ICBOPT_PDBCHANGE_AE; /* * Make sure that target role reflects into fwoptions. */ if (fcp->role & ISP_ROLE_TARGET) { icbp->icb_fwoptions |= ICBOPT_TGT_ENABLE; } else { icbp->icb_fwoptions &= ~ICBOPT_TGT_ENABLE; } /* * For some reason my 2200 does not generate ATIOs in target mode * if initiator is disabled. Extra logins are better then target * not working at all. */ if ((fcp->role & ISP_ROLE_INITIATOR) || IS_2100(isp) || IS_2200(isp)) { icbp->icb_fwoptions &= ~ICBOPT_INI_DISABLE; } else { icbp->icb_fwoptions |= ICBOPT_INI_DISABLE; } icbp->icb_maxfrmlen = DEFAULT_FRAMESIZE(isp); if (icbp->icb_maxfrmlen < ICB_MIN_FRMLEN || icbp->icb_maxfrmlen > ICB_MAX_FRMLEN) { isp_prt(isp, ISP_LOGERR, "bad frame length (%d) from NVRAM- using %d", DEFAULT_FRAMESIZE(isp), ICB_DFLT_FRMLEN); icbp->icb_maxfrmlen = ICB_DFLT_FRMLEN; } icbp->icb_maxalloc = fcp->isp_maxalloc; if (icbp->icb_maxalloc < 1) { isp_prt(isp, ISP_LOGERR, "bad maximum allocation (%d)- using 16", fcp->isp_maxalloc); icbp->icb_maxalloc = 16; } icbp->icb_execthrottle = DEFAULT_EXEC_THROTTLE(isp); if (icbp->icb_execthrottle < 1) { isp_prt(isp, ISP_LOGERR, "bad execution throttle of %d- using %d", DEFAULT_EXEC_THROTTLE(isp), ICB_DFLT_THROTTLE); icbp->icb_execthrottle = ICB_DFLT_THROTTLE; } icbp->icb_retry_delay = fcp->isp_retry_delay; icbp->icb_retry_count = fcp->isp_retry_count; icbp->icb_hardaddr = fcp->isp_loopid; ownloopid = (isp->isp_confopts & ISP_CFG_OWNLOOPID) != 0; if (icbp->icb_hardaddr >= LOCAL_LOOP_LIM) { icbp->icb_hardaddr = 0; ownloopid = 0; } /* * Our life seems so much better with 2200s and later with * the latest f/w if we set Hard Address. */ if (ownloopid || ISP_FW_NEWER_THAN(isp, 2, 2, 5)) { icbp->icb_fwoptions |= ICBOPT_HARD_ADDRESS; } /* * Right now we just set extended options to prefer point-to-point * over loop based upon some soft config options. * * NB: for the 2300, ICBOPT_EXTENDED is required. */ if (IS_2100(isp)) { /* * We can't have Fast Posting any more- we now * have 32 bit handles. */ icbp->icb_fwoptions &= ~ICBOPT_FAST_POST; } else if (IS_2200(isp) || IS_23XX(isp)) { icbp->icb_fwoptions |= ICBOPT_EXTENDED; icbp->icb_xfwoptions = fcp->isp_xfwoptions; if (ISP_CAP_FCTAPE(isp)) { if (isp->isp_confopts & ISP_CFG_NOFCTAPE) icbp->icb_xfwoptions &= ~ICBXOPT_FCTAPE; if (isp->isp_confopts & ISP_CFG_FCTAPE) icbp->icb_xfwoptions |= ICBXOPT_FCTAPE; if (icbp->icb_xfwoptions & ICBXOPT_FCTAPE) { icbp->icb_fwoptions &= ~ICBOPT_FULL_LOGIN; /* per documents */ icbp->icb_xfwoptions |= ICBXOPT_FCTAPE_CCQ|ICBXOPT_FCTAPE_CONFIRM; FCPARAM(isp, 0)->fctape_enabled = 1; } else { FCPARAM(isp, 0)->fctape_enabled = 0; } } else { icbp->icb_xfwoptions &= ~ICBXOPT_FCTAPE; FCPARAM(isp, 0)->fctape_enabled = 0; } /* * Prefer or force Point-To-Point instead Loop? */ switch (isp->isp_confopts & ISP_CFG_PORT_PREF) { case ISP_CFG_LPORT_ONLY: icbp->icb_xfwoptions &= ~ICBXOPT_TOPO_MASK; icbp->icb_xfwoptions |= ICBXOPT_LOOP_ONLY; break; case ISP_CFG_NPORT_ONLY: icbp->icb_xfwoptions &= ~ICBXOPT_TOPO_MASK; icbp->icb_xfwoptions |= ICBXOPT_PTP_ONLY; break; case ISP_CFG_LPORT: icbp->icb_xfwoptions &= ~ICBXOPT_TOPO_MASK; icbp->icb_xfwoptions |= ICBXOPT_LOOP_2_PTP; break; case ISP_CFG_NPORT: icbp->icb_xfwoptions &= ~ICBXOPT_TOPO_MASK; icbp->icb_xfwoptions |= ICBXOPT_PTP_2_LOOP; break; default: /* Let NVRAM settings define it if they are sane */ switch (icbp->icb_xfwoptions & ICBXOPT_TOPO_MASK) { case ICBXOPT_PTP_2_LOOP: case ICBXOPT_PTP_ONLY: case ICBXOPT_LOOP_ONLY: case ICBXOPT_LOOP_2_PTP: break; default: icbp->icb_xfwoptions &= ~ICBXOPT_TOPO_MASK; icbp->icb_xfwoptions |= ICBXOPT_LOOP_2_PTP; } break; } if (IS_2200(isp)) { /* * We can't have Fast Posting any more- we now * have 32 bit handles. * * RIO seemed to have to much breakage. * * Just opt for safety. */ icbp->icb_xfwoptions &= ~ICBXOPT_RIO_16BIT; icbp->icb_fwoptions &= ~ICBOPT_FAST_POST; } else { /* * QLogic recommends that FAST Posting be turned * off for 23XX cards and instead allow the HBA * to write response queue entries and interrupt * after a delay (ZIO). */ icbp->icb_fwoptions &= ~ICBOPT_FAST_POST; if ((fcp->isp_xfwoptions & ICBXOPT_TIMER_MASK) == ICBXOPT_ZIO) { icbp->icb_xfwoptions |= ICBXOPT_ZIO; icbp->icb_idelaytimer = 10; } icbp->icb_zfwoptions = fcp->isp_zfwoptions; if (isp->isp_confopts & ISP_CFG_1GB) { icbp->icb_zfwoptions &= ~ICBZOPT_RATE_MASK; icbp->icb_zfwoptions |= ICBZOPT_RATE_1GB; } else if (isp->isp_confopts & ISP_CFG_2GB) { icbp->icb_zfwoptions &= ~ICBZOPT_RATE_MASK; icbp->icb_zfwoptions |= ICBZOPT_RATE_2GB; } else { switch (icbp->icb_zfwoptions & ICBZOPT_RATE_MASK) { case ICBZOPT_RATE_1GB: case ICBZOPT_RATE_2GB: case ICBZOPT_RATE_AUTO: break; default: icbp->icb_zfwoptions &= ~ICBZOPT_RATE_MASK; icbp->icb_zfwoptions |= ICBZOPT_RATE_AUTO; break; } } } } /* * For 22XX > 2.1.26 && 23XX, set some options. */ if (ISP_FW_NEWER_THAN(isp, 2, 26, 0)) { MBSINIT(&mbs, MBOX_SET_FIRMWARE_OPTIONS, MBLOGALL, 0); mbs.param[1] = IFCOPT1_DISF7SWTCH|IFCOPT1_LIPASYNC|IFCOPT1_LIPF8; mbs.param[2] = 0; mbs.param[3] = 0; if (ISP_FW_NEWER_THAN(isp, 3, 16, 0)) { mbs.param[1] |= IFCOPT1_EQFQASYNC|IFCOPT1_CTIO_RETRY; if (fcp->role & ISP_ROLE_TARGET) { if (ISP_FW_NEWER_THAN(isp, 3, 25, 0)) { mbs.param[1] |= IFCOPT1_ENAPURE; } mbs.param[3] = IFCOPT3_NOPRLI; } } isp_mboxcmd(isp, &mbs); if (mbs.param[0] != MBOX_COMMAND_COMPLETE) { return; } } icbp->icb_logintime = ICB_LOGIN_TOV; #ifdef ISP_TARGET_MODE if (icbp->icb_fwoptions & ICBOPT_TGT_ENABLE) { icbp->icb_lunenables = 0xffff; icbp->icb_ccnt = 0xff; icbp->icb_icnt = 0xff; icbp->icb_lunetimeout = ICB_LUN_ENABLE_TOV; } #endif if (fcp->isp_wwnn && fcp->isp_wwpn) { icbp->icb_fwoptions |= ICBOPT_BOTH_WWNS; MAKE_NODE_NAME_FROM_WWN(icbp->icb_nodename, fcp->isp_wwnn); MAKE_NODE_NAME_FROM_WWN(icbp->icb_portname, fcp->isp_wwpn); isp_prt(isp, ISP_LOGDEBUG1, "Setting ICB Node 0x%08x%08x Port 0x%08x%08x", ((uint32_t) (fcp->isp_wwnn >> 32)), ((uint32_t) (fcp->isp_wwnn)), ((uint32_t) (fcp->isp_wwpn >> 32)), ((uint32_t) (fcp->isp_wwpn))); } else if (fcp->isp_wwpn) { icbp->icb_fwoptions &= ~ICBOPT_BOTH_WWNS; MAKE_NODE_NAME_FROM_WWN(icbp->icb_portname, fcp->isp_wwpn); isp_prt(isp, ISP_LOGDEBUG1, "Setting ICB Port 0x%08x%08x", ((uint32_t) (fcp->isp_wwpn >> 32)), ((uint32_t) (fcp->isp_wwpn))); } else { isp_prt(isp, ISP_LOGERR, "No valid WWNs to use"); return; } icbp->icb_rqstqlen = RQUEST_QUEUE_LEN(isp); if (icbp->icb_rqstqlen < 1) { isp_prt(isp, ISP_LOGERR, "bad request queue length"); } icbp->icb_rsltqlen = RESULT_QUEUE_LEN(isp); if (icbp->icb_rsltqlen < 1) { isp_prt(isp, ISP_LOGERR, "bad result queue length"); } icbp->icb_rqstaddr[RQRSP_ADDR0015] = DMA_WD0(isp->isp_rquest_dma); icbp->icb_rqstaddr[RQRSP_ADDR1631] = DMA_WD1(isp->isp_rquest_dma); icbp->icb_rqstaddr[RQRSP_ADDR3247] = DMA_WD2(isp->isp_rquest_dma); icbp->icb_rqstaddr[RQRSP_ADDR4863] = DMA_WD3(isp->isp_rquest_dma); icbp->icb_respaddr[RQRSP_ADDR0015] = DMA_WD0(isp->isp_result_dma); icbp->icb_respaddr[RQRSP_ADDR1631] = DMA_WD1(isp->isp_result_dma); icbp->icb_respaddr[RQRSP_ADDR3247] = DMA_WD2(isp->isp_result_dma); icbp->icb_respaddr[RQRSP_ADDR4863] = DMA_WD3(isp->isp_result_dma); if (FC_SCRATCH_ACQUIRE(isp, 0)) { isp_prt(isp, ISP_LOGERR, sacq); return; } isp_prt(isp, ISP_LOGDEBUG0, "isp_fibre_init: fwopt 0x%x xfwopt 0x%x zfwopt 0x%x", icbp->icb_fwoptions, icbp->icb_xfwoptions, icbp->icb_zfwoptions); isp_put_icb(isp, icbp, (isp_icb_t *)fcp->isp_scratch); if (isp->isp_dblev & ISP_LOGDEBUG1) { isp_print_bytes(isp, "isp_fibre_init", sizeof(*icbp), fcp->isp_scratch); } /* * Init the firmware */ MBSINIT(&mbs, MBOX_INIT_FIRMWARE, MBLOGALL, 30000000); mbs.param[1] = 0; mbs.param[2] = DMA_WD1(fcp->isp_scdma); mbs.param[3] = DMA_WD0(fcp->isp_scdma); mbs.param[6] = DMA_WD3(fcp->isp_scdma); mbs.param[7] = DMA_WD2(fcp->isp_scdma); isp_prt(isp, ISP_LOGDEBUG0, "INIT F/W from %p (%08x%08x)", fcp->isp_scratch, (uint32_t) ((uint64_t)fcp->isp_scdma >> 32), (uint32_t) fcp->isp_scdma); MEMORYBARRIER(isp, SYNC_SFORDEV, 0, sizeof (*icbp), 0); isp_mboxcmd(isp, &mbs); FC_SCRATCH_RELEASE(isp, 0); if (mbs.param[0] != MBOX_COMMAND_COMPLETE) return; isp->isp_reqidx = 0; isp->isp_reqodx = 0; isp->isp_residx = 0; isp->isp_resodx = 0; /* * Whatever happens, we're now committed to being here. */ isp->isp_state = ISP_RUNSTATE; } static void isp_fibre_init_2400(ispsoftc_t *isp) { fcparam *fcp; isp_icb_2400_t local, *icbp = &local; mbreg_t mbs; int chan; int ownloopid = 0; /* * Check to see whether all channels have *some* kind of role */ for (chan = 0; chan < isp->isp_nchan; chan++) { fcp = FCPARAM(isp, chan); if (fcp->role != ISP_ROLE_NONE) { break; } } if (chan == isp->isp_nchan) { isp_prt(isp, ISP_LOG_WARN1, "all %d channels with role 'none'", chan); return; } isp->isp_state = ISP_INITSTATE; /* * Start with channel 0. */ fcp = FCPARAM(isp, 0); /* * Turn on LIP F8 async event (1) */ MBSINIT(&mbs, MBOX_SET_FIRMWARE_OPTIONS, MBLOGALL, 0); mbs.param[1] = 1; isp_mboxcmd(isp, &mbs); if (mbs.param[0] != MBOX_COMMAND_COMPLETE) { return; } ISP_MEMZERO(icbp, sizeof (*icbp)); icbp->icb_fwoptions1 = fcp->isp_fwoptions; icbp->icb_fwoptions2 = fcp->isp_xfwoptions; icbp->icb_fwoptions3 = fcp->isp_zfwoptions; if (isp->isp_nchan > 1 && ISP_CAP_VP0(isp)) { icbp->icb_fwoptions1 &= ~ICB2400_OPT1_INI_DISABLE; icbp->icb_fwoptions1 |= ICB2400_OPT1_TGT_ENABLE; } else { if (fcp->role & ISP_ROLE_TARGET) icbp->icb_fwoptions1 |= ICB2400_OPT1_TGT_ENABLE; else icbp->icb_fwoptions1 &= ~ICB2400_OPT1_TGT_ENABLE; if (fcp->role & ISP_ROLE_INITIATOR) icbp->icb_fwoptions1 &= ~ICB2400_OPT1_INI_DISABLE; else icbp->icb_fwoptions1 |= ICB2400_OPT1_INI_DISABLE; } icbp->icb_version = ICB_VERSION1; icbp->icb_maxfrmlen = DEFAULT_FRAMESIZE(isp); if (icbp->icb_maxfrmlen < ICB_MIN_FRMLEN || icbp->icb_maxfrmlen > ICB_MAX_FRMLEN) { isp_prt(isp, ISP_LOGERR, "bad frame length (%d) from NVRAM- using %d", DEFAULT_FRAMESIZE(isp), ICB_DFLT_FRMLEN); icbp->icb_maxfrmlen = ICB_DFLT_FRMLEN; } icbp->icb_execthrottle = DEFAULT_EXEC_THROTTLE(isp); if (icbp->icb_execthrottle < 1 && !IS_26XX(isp)) { isp_prt(isp, ISP_LOGERR, "bad execution throttle of %d- using %d", DEFAULT_EXEC_THROTTLE(isp), ICB_DFLT_THROTTLE); icbp->icb_execthrottle = ICB_DFLT_THROTTLE; } /* * Set target exchange count. Take half if we are supporting both roles. */ if (icbp->icb_fwoptions1 & ICB2400_OPT1_TGT_ENABLE) { icbp->icb_xchgcnt = isp->isp_maxcmds; if ((icbp->icb_fwoptions1 & ICB2400_OPT1_INI_DISABLE) == 0) icbp->icb_xchgcnt >>= 1; } ownloopid = (isp->isp_confopts & ISP_CFG_OWNLOOPID) != 0; icbp->icb_hardaddr = fcp->isp_loopid; if (icbp->icb_hardaddr >= LOCAL_LOOP_LIM) { icbp->icb_hardaddr = 0; ownloopid = 0; } if (ownloopid) icbp->icb_fwoptions1 |= ICB2400_OPT1_HARD_ADDRESS; if (isp->isp_confopts & ISP_CFG_NOFCTAPE) { icbp->icb_fwoptions2 &= ~ICB2400_OPT2_FCTAPE; } if (isp->isp_confopts & ISP_CFG_FCTAPE) { icbp->icb_fwoptions2 |= ICB2400_OPT2_FCTAPE; } for (chan = 0; chan < isp->isp_nchan; chan++) { if (icbp->icb_fwoptions2 & ICB2400_OPT2_FCTAPE) FCPARAM(isp, chan)->fctape_enabled = 1; else FCPARAM(isp, chan)->fctape_enabled = 0; } switch (isp->isp_confopts & ISP_CFG_PORT_PREF) { case ISP_CFG_LPORT_ONLY: icbp->icb_fwoptions2 &= ~ICB2400_OPT2_TOPO_MASK; icbp->icb_fwoptions2 |= ICB2400_OPT2_LOOP_ONLY; break; case ISP_CFG_NPORT_ONLY: icbp->icb_fwoptions2 &= ~ICB2400_OPT2_TOPO_MASK; icbp->icb_fwoptions2 |= ICB2400_OPT2_PTP_ONLY; break; case ISP_CFG_NPORT: /* ISP_CFG_PTP_2_LOOP not available in 24XX/25XX */ case ISP_CFG_LPORT: icbp->icb_fwoptions2 &= ~ICB2400_OPT2_TOPO_MASK; icbp->icb_fwoptions2 |= ICB2400_OPT2_LOOP_2_PTP; break; default: /* Let NVRAM settings define it if they are sane */ switch (icbp->icb_fwoptions2 & ICB2400_OPT2_TOPO_MASK) { case ICB2400_OPT2_LOOP_ONLY: case ICB2400_OPT2_PTP_ONLY: case ICB2400_OPT2_LOOP_2_PTP: break; default: icbp->icb_fwoptions2 &= ~ICB2400_OPT2_TOPO_MASK; icbp->icb_fwoptions2 |= ICB2400_OPT2_LOOP_2_PTP; } break; } switch (icbp->icb_fwoptions2 & ICB2400_OPT2_TIMER_MASK) { case ICB2400_OPT2_ZIO: case ICB2400_OPT2_ZIO1: icbp->icb_idelaytimer = 0; break; case 0: break; default: isp_prt(isp, ISP_LOGWARN, "bad value %x in fwopt2 timer field", icbp->icb_fwoptions2 & ICB2400_OPT2_TIMER_MASK); icbp->icb_fwoptions2 &= ~ICB2400_OPT2_TIMER_MASK; break; } if (IS_26XX(isp)) { /* Use handshake to reduce global lock congestion. */ icbp->icb_fwoptions2 |= ICB2400_OPT2_ENA_IHR; icbp->icb_fwoptions2 |= ICB2400_OPT2_ENA_IHA; } if ((icbp->icb_fwoptions3 & ICB2400_OPT3_RSPSZ_MASK) == 0) { icbp->icb_fwoptions3 |= ICB2400_OPT3_RSPSZ_24; } if (isp->isp_confopts & ISP_CFG_1GB) { icbp->icb_fwoptions3 &= ~ICB2400_OPT3_RATE_MASK; icbp->icb_fwoptions3 |= ICB2400_OPT3_RATE_1GB; } else if (isp->isp_confopts & ISP_CFG_2GB) { icbp->icb_fwoptions3 &= ~ICB2400_OPT3_RATE_MASK; icbp->icb_fwoptions3 |= ICB2400_OPT3_RATE_2GB; } else if (isp->isp_confopts & ISP_CFG_4GB) { icbp->icb_fwoptions3 &= ~ICB2400_OPT3_RATE_MASK; icbp->icb_fwoptions3 |= ICB2400_OPT3_RATE_4GB; } else if (isp->isp_confopts & ISP_CFG_8GB) { icbp->icb_fwoptions3 &= ~ICB2400_OPT3_RATE_MASK; icbp->icb_fwoptions3 |= ICB2400_OPT3_RATE_8GB; } else if (isp->isp_confopts & ISP_CFG_16GB) { icbp->icb_fwoptions3 &= ~ICB2400_OPT3_RATE_MASK; icbp->icb_fwoptions3 |= ICB2400_OPT3_RATE_16GB; } else if (isp->isp_confopts & ISP_CFG_32GB) { icbp->icb_fwoptions3 &= ~ICB2400_OPT3_RATE_MASK; icbp->icb_fwoptions3 |= ICB2400_OPT3_RATE_32GB; } else { switch (icbp->icb_fwoptions3 & ICB2400_OPT3_RATE_MASK) { case ICB2400_OPT3_RATE_4GB: case ICB2400_OPT3_RATE_8GB: case ICB2400_OPT3_RATE_16GB: case ICB2400_OPT3_RATE_32GB: case ICB2400_OPT3_RATE_AUTO: break; case ICB2400_OPT3_RATE_2GB: if (isp->isp_type <= ISP_HA_FC_2500) break; /*FALLTHROUGH*/ case ICB2400_OPT3_RATE_1GB: if (isp->isp_type <= ISP_HA_FC_2400) break; /*FALLTHROUGH*/ default: icbp->icb_fwoptions3 &= ~ICB2400_OPT3_RATE_MASK; icbp->icb_fwoptions3 |= ICB2400_OPT3_RATE_AUTO; break; } } if (ownloopid == 0) { icbp->icb_fwoptions3 |= ICB2400_OPT3_SOFTID; } icbp->icb_logintime = ICB_LOGIN_TOV; if (fcp->isp_wwnn && fcp->isp_wwpn) { icbp->icb_fwoptions1 |= ICB2400_OPT1_BOTH_WWNS; MAKE_NODE_NAME_FROM_WWN(icbp->icb_portname, fcp->isp_wwpn); MAKE_NODE_NAME_FROM_WWN(icbp->icb_nodename, fcp->isp_wwnn); isp_prt(isp, ISP_LOGDEBUG1, "Setting ICB Node 0x%08x%08x Port 0x%08x%08x", ((uint32_t) (fcp->isp_wwnn >> 32)), ((uint32_t) (fcp->isp_wwnn)), ((uint32_t) (fcp->isp_wwpn >> 32)), ((uint32_t) (fcp->isp_wwpn))); } else if (fcp->isp_wwpn) { icbp->icb_fwoptions1 &= ~ICB2400_OPT1_BOTH_WWNS; MAKE_NODE_NAME_FROM_WWN(icbp->icb_portname, fcp->isp_wwpn); isp_prt(isp, ISP_LOGDEBUG1, "Setting ICB Node to be same as Port 0x%08x%08x", ((uint32_t) (fcp->isp_wwpn >> 32)), ((uint32_t) (fcp->isp_wwpn))); } else { isp_prt(isp, ISP_LOGERR, "No valid WWNs to use"); return; } icbp->icb_retry_count = fcp->isp_retry_count; icbp->icb_rqstqlen = RQUEST_QUEUE_LEN(isp); if (icbp->icb_rqstqlen < 8) { isp_prt(isp, ISP_LOGERR, "bad request queue length %d", icbp->icb_rqstqlen); return; } icbp->icb_rsltqlen = RESULT_QUEUE_LEN(isp); if (icbp->icb_rsltqlen < 8) { isp_prt(isp, ISP_LOGERR, "bad result queue length %d", icbp->icb_rsltqlen); return; } icbp->icb_rqstaddr[RQRSP_ADDR0015] = DMA_WD0(isp->isp_rquest_dma); icbp->icb_rqstaddr[RQRSP_ADDR1631] = DMA_WD1(isp->isp_rquest_dma); icbp->icb_rqstaddr[RQRSP_ADDR3247] = DMA_WD2(isp->isp_rquest_dma); icbp->icb_rqstaddr[RQRSP_ADDR4863] = DMA_WD3(isp->isp_rquest_dma); icbp->icb_respaddr[RQRSP_ADDR0015] = DMA_WD0(isp->isp_result_dma); icbp->icb_respaddr[RQRSP_ADDR1631] = DMA_WD1(isp->isp_result_dma); icbp->icb_respaddr[RQRSP_ADDR3247] = DMA_WD2(isp->isp_result_dma); icbp->icb_respaddr[RQRSP_ADDR4863] = DMA_WD3(isp->isp_result_dma); #ifdef ISP_TARGET_MODE /* unconditionally set up the ATIO queue if we support target mode */ icbp->icb_atioqlen = RESULT_QUEUE_LEN(isp); if (icbp->icb_atioqlen < 8) { isp_prt(isp, ISP_LOGERR, "bad ATIO queue length %d", icbp->icb_atioqlen); return; } icbp->icb_atioqaddr[RQRSP_ADDR0015] = DMA_WD0(isp->isp_atioq_dma); icbp->icb_atioqaddr[RQRSP_ADDR1631] = DMA_WD1(isp->isp_atioq_dma); icbp->icb_atioqaddr[RQRSP_ADDR3247] = DMA_WD2(isp->isp_atioq_dma); icbp->icb_atioqaddr[RQRSP_ADDR4863] = DMA_WD3(isp->isp_atioq_dma); isp_prt(isp, ISP_LOGDEBUG0, "isp_fibre_init_2400: atioq %04x%04x%04x%04x", DMA_WD3(isp->isp_atioq_dma), DMA_WD2(isp->isp_atioq_dma), DMA_WD1(isp->isp_atioq_dma), DMA_WD0(isp->isp_atioq_dma)); #endif if (ISP_CAP_MSIX(isp) && isp->isp_nirq >= 2) { icbp->icb_msixresp = 1; if (IS_26XX(isp) && isp->isp_nirq >= 3) icbp->icb_msixatio = 2; } isp_prt(isp, ISP_LOGDEBUG0, "isp_fibre_init_2400: fwopt1 0x%x fwopt2 0x%x fwopt3 0x%x", icbp->icb_fwoptions1, icbp->icb_fwoptions2, icbp->icb_fwoptions3); isp_prt(isp, ISP_LOGDEBUG0, "isp_fibre_init_2400: rqst %04x%04x%04x%04x rsp %04x%04x%04x%04x", DMA_WD3(isp->isp_rquest_dma), DMA_WD2(isp->isp_rquest_dma), DMA_WD1(isp->isp_rquest_dma), DMA_WD0(isp->isp_rquest_dma), DMA_WD3(isp->isp_result_dma), DMA_WD2(isp->isp_result_dma), DMA_WD1(isp->isp_result_dma), DMA_WD0(isp->isp_result_dma)); if (FC_SCRATCH_ACQUIRE(isp, 0)) { isp_prt(isp, ISP_LOGERR, sacq); return; } ISP_MEMZERO(fcp->isp_scratch, ISP_FC_SCRLEN); isp_put_icb_2400(isp, icbp, fcp->isp_scratch); if (isp->isp_dblev & ISP_LOGDEBUG1) { isp_print_bytes(isp, "isp_fibre_init_2400", sizeof (*icbp), fcp->isp_scratch); } /* * Now fill in information about any additional channels */ if (isp->isp_nchan > 1) { isp_icb_2400_vpinfo_t vpinfo, *vdst; vp_port_info_t pi, *pdst; size_t amt = 0; uint8_t *off; vpinfo.vp_global_options = ICB2400_VPGOPT_GEN_RIDA; if (ISP_CAP_VP0(isp)) { vpinfo.vp_global_options |= ICB2400_VPGOPT_VP0_DECOUPLE; vpinfo.vp_count = isp->isp_nchan; chan = 0; } else { vpinfo.vp_count = isp->isp_nchan - 1; chan = 1; } off = fcp->isp_scratch; off += ICB2400_VPINFO_OFF; vdst = (isp_icb_2400_vpinfo_t *) off; isp_put_icb_2400_vpinfo(isp, &vpinfo, vdst); amt = ICB2400_VPINFO_OFF + sizeof (isp_icb_2400_vpinfo_t); for (; chan < isp->isp_nchan; chan++) { fcparam *fcp2; ISP_MEMZERO(&pi, sizeof (pi)); fcp2 = FCPARAM(isp, chan); if (fcp2->role != ISP_ROLE_NONE) { pi.vp_port_options = ICB2400_VPOPT_ENABLED | ICB2400_VPOPT_ENA_SNSLOGIN; if (fcp2->role & ISP_ROLE_INITIATOR) pi.vp_port_options |= ICB2400_VPOPT_INI_ENABLE; if ((fcp2->role & ISP_ROLE_TARGET) == 0) pi.vp_port_options |= ICB2400_VPOPT_TGT_DISABLE; if (fcp2->isp_loopid < LOCAL_LOOP_LIM) { pi.vp_port_loopid = fcp2->isp_loopid; if (isp->isp_confopts & ISP_CFG_OWNLOOPID) pi.vp_port_options |= ICB2400_VPOPT_HARD_ADDRESS; } } MAKE_NODE_NAME_FROM_WWN(pi.vp_port_portname, fcp2->isp_wwpn); MAKE_NODE_NAME_FROM_WWN(pi.vp_port_nodename, fcp2->isp_wwnn); off = fcp->isp_scratch; if (ISP_CAP_VP0(isp)) off += ICB2400_VPINFO_PORT_OFF(chan); else off += ICB2400_VPINFO_PORT_OFF(chan - 1); pdst = (vp_port_info_t *) off; isp_put_vp_port_info(isp, &pi, pdst); amt += ICB2400_VPOPT_WRITE_SIZE; } if (isp->isp_dblev & ISP_LOGDEBUG1) { isp_print_bytes(isp, "isp_fibre_init_2400", amt - ICB2400_VPINFO_OFF, (char *)fcp->isp_scratch + ICB2400_VPINFO_OFF); } } /* * Init the firmware */ MBSINIT(&mbs, 0, MBLOGALL, 30000000); if (isp->isp_nchan > 1) { mbs.param[0] = MBOX_INIT_FIRMWARE_MULTI_ID; } else { mbs.param[0] = MBOX_INIT_FIRMWARE; } mbs.param[1] = 0; mbs.param[2] = DMA_WD1(fcp->isp_scdma); mbs.param[3] = DMA_WD0(fcp->isp_scdma); mbs.param[6] = DMA_WD3(fcp->isp_scdma); mbs.param[7] = DMA_WD2(fcp->isp_scdma); isp_prt(isp, ISP_LOGDEBUG0, "INIT F/W from %04x%04x%04x%04x", DMA_WD3(fcp->isp_scdma), DMA_WD2(fcp->isp_scdma), DMA_WD1(fcp->isp_scdma), DMA_WD0(fcp->isp_scdma)); MEMORYBARRIER(isp, SYNC_SFORDEV, 0, sizeof (*icbp), 0); isp_mboxcmd(isp, &mbs); FC_SCRATCH_RELEASE(isp, 0); if (mbs.param[0] != MBOX_COMMAND_COMPLETE) { return; } isp->isp_reqidx = 0; isp->isp_reqodx = 0; isp->isp_residx = 0; isp->isp_resodx = 0; isp->isp_atioodx = 0; /* * Whatever happens, we're now committed to being here. */ isp->isp_state = ISP_RUNSTATE; } static int isp_fc_enable_vp(ispsoftc_t *isp, int chan) { fcparam *fcp = FCPARAM(isp, chan); vp_modify_t vp; void *reqp; uint8_t resp[QENTRY_LEN]; /* Build a VP MODIFY command in memory */ ISP_MEMZERO(&vp, sizeof(vp)); vp.vp_mod_hdr.rqs_entry_type = RQSTYPE_VP_MODIFY; vp.vp_mod_hdr.rqs_entry_count = 1; vp.vp_mod_cnt = 1; vp.vp_mod_idx0 = chan; vp.vp_mod_cmd = VP_MODIFY_ENA; vp.vp_mod_ports[0].options = ICB2400_VPOPT_ENABLED | ICB2400_VPOPT_ENA_SNSLOGIN; if (fcp->role & ISP_ROLE_INITIATOR) vp.vp_mod_ports[0].options |= ICB2400_VPOPT_INI_ENABLE; if ((fcp->role & ISP_ROLE_TARGET) == 0) vp.vp_mod_ports[0].options |= ICB2400_VPOPT_TGT_DISABLE; if (fcp->isp_loopid < LOCAL_LOOP_LIM) { vp.vp_mod_ports[0].loopid = fcp->isp_loopid; if (isp->isp_confopts & ISP_CFG_OWNLOOPID) vp.vp_mod_ports[0].options |= ICB2400_VPOPT_HARD_ADDRESS; } MAKE_NODE_NAME_FROM_WWN(vp.vp_mod_ports[0].wwpn, fcp->isp_wwpn); MAKE_NODE_NAME_FROM_WWN(vp.vp_mod_ports[0].wwnn, fcp->isp_wwnn); /* Prepare space for response in memory */ memset(resp, 0xff, sizeof(resp)); vp.vp_mod_hdl = isp_allocate_handle(isp, resp, ISP_HANDLE_CTRL); if (vp.vp_mod_hdl == 0) { isp_prt(isp, ISP_LOGERR, "%s: VP_MODIFY of Chan %d out of handles", __func__, chan); return (EIO); } /* Send request and wait for response. */ reqp = isp_getrqentry(isp); if (reqp == NULL) { isp_prt(isp, ISP_LOGERR, "%s: VP_MODIFY of Chan %d out of rqent", __func__, chan); isp_destroy_handle(isp, vp.vp_mod_hdl); return (EIO); } isp_put_vp_modify(isp, &vp, (vp_modify_t *)reqp); if (isp->isp_dblev & ISP_LOGDEBUG1) isp_print_bytes(isp, "IOCB VP_MODIFY", QENTRY_LEN, reqp); ISP_SYNC_REQUEST(isp); if (msleep(resp, &isp->isp_lock, 0, "VP_MODIFY", 5*hz) == EWOULDBLOCK) { isp_prt(isp, ISP_LOGERR, "%s: VP_MODIFY of Chan %d timed out", __func__, chan); isp_destroy_handle(isp, vp.vp_mod_hdl); return (EIO); } if (isp->isp_dblev & ISP_LOGDEBUG1) isp_print_bytes(isp, "IOCB VP_MODIFY response", QENTRY_LEN, resp); isp_get_vp_modify(isp, (vp_modify_t *)resp, &vp); if (vp.vp_mod_hdr.rqs_flags != 0 || vp.vp_mod_status != VP_STS_OK) { isp_prt(isp, ISP_LOGERR, "%s: VP_MODIFY of Chan %d failed with flags %x status %d", __func__, chan, vp.vp_mod_hdr.rqs_flags, vp.vp_mod_status); return (EIO); } return (0); } static int isp_fc_disable_vp(ispsoftc_t *isp, int chan) { vp_ctrl_info_t vp; void *reqp; uint8_t resp[QENTRY_LEN]; /* Build a VP CTRL command in memory */ ISP_MEMZERO(&vp, sizeof(vp)); vp.vp_ctrl_hdr.rqs_entry_type = RQSTYPE_VP_CTRL; vp.vp_ctrl_hdr.rqs_entry_count = 1; if (ISP_CAP_VP0(isp)) { vp.vp_ctrl_status = 1; } else { vp.vp_ctrl_status = 0; chan--; /* VP0 can not be controlled in this case. */ } vp.vp_ctrl_command = VP_CTRL_CMD_DISABLE_VP_LOGO_ALL; vp.vp_ctrl_vp_count = 1; vp.vp_ctrl_idmap[chan / 16] |= (1 << chan % 16); /* Prepare space for response in memory */ memset(resp, 0xff, sizeof(resp)); vp.vp_ctrl_handle = isp_allocate_handle(isp, resp, ISP_HANDLE_CTRL); if (vp.vp_ctrl_handle == 0) { isp_prt(isp, ISP_LOGERR, "%s: VP_CTRL of Chan %d out of handles", __func__, chan); return (EIO); } /* Send request and wait for response. */ reqp = isp_getrqentry(isp); if (reqp == NULL) { isp_prt(isp, ISP_LOGERR, "%s: VP_CTRL of Chan %d out of rqent", __func__, chan); isp_destroy_handle(isp, vp.vp_ctrl_handle); return (EIO); } isp_put_vp_ctrl_info(isp, &vp, (vp_ctrl_info_t *)reqp); if (isp->isp_dblev & ISP_LOGDEBUG1) isp_print_bytes(isp, "IOCB VP_CTRL", QENTRY_LEN, reqp); ISP_SYNC_REQUEST(isp); if (msleep(resp, &isp->isp_lock, 0, "VP_CTRL", 5*hz) == EWOULDBLOCK) { isp_prt(isp, ISP_LOGERR, "%s: VP_CTRL of Chan %d timed out", __func__, chan); isp_destroy_handle(isp, vp.vp_ctrl_handle); return (EIO); } if (isp->isp_dblev & ISP_LOGDEBUG1) isp_print_bytes(isp, "IOCB VP_CTRL response", QENTRY_LEN, resp); isp_get_vp_ctrl_info(isp, (vp_ctrl_info_t *)resp, &vp); if (vp.vp_ctrl_hdr.rqs_flags != 0 || vp.vp_ctrl_status != 0) { isp_prt(isp, ISP_LOGERR, "%s: VP_CTRL of Chan %d failed with flags %x status %d %d", __func__, chan, vp.vp_ctrl_hdr.rqs_flags, vp.vp_ctrl_status, vp.vp_ctrl_index_fail); return (EIO); } return (0); } static int isp_fc_change_role(ispsoftc_t *isp, int chan, int new_role) { fcparam *fcp = FCPARAM(isp, chan); int i, was, res = 0; if (chan >= isp->isp_nchan) { isp_prt(isp, ISP_LOGWARN, "%s: bad channel %d", __func__, chan); return (ENXIO); } if (fcp->role == new_role) return (0); for (was = 0, i = 0; i < isp->isp_nchan; i++) { if (FCPARAM(isp, i)->role != ISP_ROLE_NONE) was++; } if (was == 0 || (was == 1 && fcp->role != ISP_ROLE_NONE)) { fcp->role = new_role; return (isp_reinit(isp, 0)); } if (fcp->role != ISP_ROLE_NONE) { res = isp_fc_disable_vp(isp, chan); isp_clear_portdb(isp, chan); } fcp->role = new_role; if (fcp->role != ISP_ROLE_NONE) res = isp_fc_enable_vp(isp, chan); return (res); } static void isp_clear_portdb(ispsoftc_t *isp, int chan) { fcparam *fcp = FCPARAM(isp, chan); fcportdb_t *lp; int i; for (i = 0; i < MAX_FC_TARG; i++) { lp = &fcp->portdb[i]; switch (lp->state) { case FC_PORTDB_STATE_DEAD: case FC_PORTDB_STATE_CHANGED: case FC_PORTDB_STATE_VALID: lp->state = FC_PORTDB_STATE_NIL; isp_async(isp, ISPASYNC_DEV_GONE, chan, lp); break; case FC_PORTDB_STATE_NIL: case FC_PORTDB_STATE_NEW: lp->state = FC_PORTDB_STATE_NIL; break; case FC_PORTDB_STATE_ZOMBIE: break; default: panic("Don't know how to clear state %d\n", lp->state); } } } static void isp_mark_portdb(ispsoftc_t *isp, int chan) { fcparam *fcp = FCPARAM(isp, chan); fcportdb_t *lp; int i; for (i = 0; i < MAX_FC_TARG; i++) { lp = &fcp->portdb[i]; if (lp->state == FC_PORTDB_STATE_NIL) continue; if (lp->portid >= DOMAIN_CONTROLLER_BASE && lp->portid <= DOMAIN_CONTROLLER_END) continue; fcp->portdb[i].probational = 1; } } /* * Perform an IOCB PLOGI or LOGO via EXECUTE IOCB A64 for 24XX cards * or via FABRIC LOGIN/FABRIC LOGOUT for other cards. */ static int isp_plogx(ispsoftc_t *isp, int chan, uint16_t handle, uint32_t portid, int flags) { isp_plogx_t pl; void *reqp; uint8_t resp[QENTRY_LEN]; uint32_t sst, parm1; int rval, lev; const char *msg; char buf[64]; isp_prt(isp, ISP_LOG_SANCFG, "Chan %d PLOGX %s PortID 0x%06x nphdl 0x%x", chan, (flags & PLOGX_FLG_CMD_MASK) == PLOGX_FLG_CMD_PLOGI ? "Login":"Logout", portid, handle); if (!IS_24XX(isp)) { int action = flags & PLOGX_FLG_CMD_MASK; if (action == PLOGX_FLG_CMD_PLOGI) { return (isp_port_login(isp, handle, portid)); } else if (action == PLOGX_FLG_CMD_LOGO) { return (isp_port_logout(isp, handle, portid)); } else { return (MBOX_INVALID_COMMAND); } } ISP_MEMZERO(&pl, sizeof(pl)); pl.plogx_header.rqs_entry_count = 1; pl.plogx_header.rqs_entry_type = RQSTYPE_LOGIN; pl.plogx_nphdl = handle; pl.plogx_vphdl = chan; pl.plogx_portlo = portid; pl.plogx_rspsz_porthi = (portid >> 16) & 0xff; pl.plogx_flags = flags; /* Prepare space for response in memory */ memset(resp, 0xff, sizeof(resp)); pl.plogx_handle = isp_allocate_handle(isp, resp, ISP_HANDLE_CTRL); if (pl.plogx_handle == 0) { isp_prt(isp, ISP_LOGERR, "%s: PLOGX of Chan %d out of handles", __func__, chan); return (-1); } /* Send request and wait for response. */ reqp = isp_getrqentry(isp); if (reqp == NULL) { isp_prt(isp, ISP_LOGERR, "%s: PLOGX of Chan %d out of rqent", __func__, chan); isp_destroy_handle(isp, pl.plogx_handle); return (-1); } isp_put_plogx(isp, &pl, (isp_plogx_t *)reqp); if (isp->isp_dblev & ISP_LOGDEBUG1) isp_print_bytes(isp, "IOCB LOGX", QENTRY_LEN, reqp); FCPARAM(isp, chan)->isp_login_hdl = handle; ISP_SYNC_REQUEST(isp); if (msleep(resp, &isp->isp_lock, 0, "PLOGX", 3 * ICB_LOGIN_TOV * hz) == EWOULDBLOCK) { isp_prt(isp, ISP_LOGERR, "%s: PLOGX of Chan %d timed out", __func__, chan); isp_destroy_handle(isp, pl.plogx_handle); return (-1); } FCPARAM(isp, chan)->isp_login_hdl = NIL_HANDLE; if (isp->isp_dblev & ISP_LOGDEBUG1) isp_print_bytes(isp, "IOCB LOGX response", QENTRY_LEN, resp); isp_get_plogx(isp, (isp_plogx_t *)resp, &pl); if (pl.plogx_status == PLOGX_STATUS_OK) { return (0); } else if (pl.plogx_status != PLOGX_STATUS_IOCBERR) { isp_prt(isp, ISP_LOGWARN, "status 0x%x on port login IOCB channel %d", pl.plogx_status, chan); return (-1); } sst = pl.plogx_ioparm[0].lo16 | (pl.plogx_ioparm[0].hi16 << 16); parm1 = pl.plogx_ioparm[1].lo16 | (pl.plogx_ioparm[1].hi16 << 16); rval = -1; lev = ISP_LOGERR; msg = NULL; switch (sst) { case PLOGX_IOCBERR_NOLINK: msg = "no link"; break; case PLOGX_IOCBERR_NOIOCB: msg = "no IOCB buffer"; break; case PLOGX_IOCBERR_NOXGHG: msg = "no Exchange Control Block"; break; case PLOGX_IOCBERR_FAILED: ISP_SNPRINTF(buf, sizeof (buf), "reason 0x%x (last LOGIN state 0x%x)", parm1 & 0xff, (parm1 >> 8) & 0xff); msg = buf; break; case PLOGX_IOCBERR_NOFABRIC: msg = "no fabric"; break; case PLOGX_IOCBERR_NOTREADY: msg = "firmware not ready"; break; case PLOGX_IOCBERR_NOLOGIN: ISP_SNPRINTF(buf, sizeof (buf), "not logged in (last state 0x%x)", parm1); msg = buf; rval = MBOX_NOT_LOGGED_IN; break; case PLOGX_IOCBERR_REJECT: ISP_SNPRINTF(buf, sizeof (buf), "LS_RJT = 0x%x", parm1); msg = buf; break; case PLOGX_IOCBERR_NOPCB: msg = "no PCB allocated"; break; case PLOGX_IOCBERR_EINVAL: ISP_SNPRINTF(buf, sizeof (buf), "invalid parameter at offset 0x%x", parm1); msg = buf; break; case PLOGX_IOCBERR_PORTUSED: lev = ISP_LOG_SANCFG|ISP_LOG_WARN1; ISP_SNPRINTF(buf, sizeof (buf), "already logged in with N-Port handle 0x%x", parm1); msg = buf; rval = MBOX_PORT_ID_USED | (parm1 << 16); break; case PLOGX_IOCBERR_HNDLUSED: lev = ISP_LOG_SANCFG|ISP_LOG_WARN1; ISP_SNPRINTF(buf, sizeof (buf), "handle already used for PortID 0x%06x", parm1); msg = buf; rval = MBOX_LOOP_ID_USED; break; case PLOGX_IOCBERR_NOHANDLE: msg = "no handle allocated"; break; case PLOGX_IOCBERR_NOFLOGI: msg = "no FLOGI_ACC"; break; default: ISP_SNPRINTF(buf, sizeof (buf), "status %x from %x", pl.plogx_status, flags); msg = buf; break; } if (msg) { isp_prt(isp, lev, "Chan %d PLOGX PortID 0x%06x to N-Port handle 0x%x: %s", chan, portid, handle, msg); } return (rval); } static int isp_port_login(ispsoftc_t *isp, uint16_t handle, uint32_t portid) { mbreg_t mbs; MBSINIT(&mbs, MBOX_FABRIC_LOGIN, MBLOGNONE, 500000); if (ISP_CAP_2KLOGIN(isp)) { mbs.param[1] = handle; mbs.ibits = (1 << 10); } else { mbs.param[1] = handle << 8; } mbs.param[2] = portid >> 16; mbs.param[3] = portid; mbs.logval = MBLOGNONE; mbs.timeout = 500000; isp_mboxcmd(isp, &mbs); switch (mbs.param[0]) { case MBOX_PORT_ID_USED: isp_prt(isp, ISP_LOG_SANCFG|ISP_LOG_WARN1, "isp_port_login: portid 0x%06x already logged in as 0x%x", portid, mbs.param[1]); return (MBOX_PORT_ID_USED | (mbs.param[1] << 16)); case MBOX_LOOP_ID_USED: isp_prt(isp, ISP_LOG_SANCFG|ISP_LOG_WARN1, "isp_port_login: handle 0x%x in use for port id 0x%02xXXXX", handle, mbs.param[1] & 0xff); return (MBOX_LOOP_ID_USED); case MBOX_COMMAND_COMPLETE: return (0); case MBOX_COMMAND_ERROR: isp_prt(isp, ISP_LOG_SANCFG|ISP_LOG_WARN1, "isp_port_login: error 0x%x in PLOGI to port 0x%06x", mbs.param[1], portid); return (MBOX_COMMAND_ERROR); case MBOX_ALL_IDS_USED: isp_prt(isp, ISP_LOG_SANCFG|ISP_LOG_WARN1, "isp_port_login: all IDs used for fabric login"); return (MBOX_ALL_IDS_USED); default: isp_prt(isp, ISP_LOG_SANCFG, "isp_port_login: error 0x%x on port login of 0x%06x@0x%0x", mbs.param[0], portid, handle); return (mbs.param[0]); } } /* * Pre-24XX fabric port logout * * Note that portid is not used */ static int isp_port_logout(ispsoftc_t *isp, uint16_t handle, uint32_t portid) { mbreg_t mbs; MBSINIT(&mbs, MBOX_FABRIC_LOGOUT, MBLOGNONE, 500000); if (ISP_CAP_2KLOGIN(isp)) { mbs.param[1] = handle; mbs.ibits = (1 << 10); } else { mbs.param[1] = handle << 8; } isp_mboxcmd(isp, &mbs); return (mbs.param[0] == MBOX_COMMAND_COMPLETE? 0 : mbs.param[0]); } static int isp_getpdb(ispsoftc_t *isp, int chan, uint16_t id, isp_pdb_t *pdb) { mbreg_t mbs; union { isp_pdb_21xx_t fred; isp_pdb_24xx_t bill; } un; MBSINIT(&mbs, MBOX_GET_PORT_DB, MBLOGALL & ~MBLOGMASK(MBOX_COMMAND_PARAM_ERROR), 250000); if (IS_24XX(isp)) { mbs.ibits = (1 << 9)|(1 << 10); mbs.param[1] = id; mbs.param[9] = chan; } else if (ISP_CAP_2KLOGIN(isp)) { mbs.param[1] = id; } else { mbs.param[1] = id << 8; } mbs.param[2] = DMA_WD1(isp->isp_iocb_dma); mbs.param[3] = DMA_WD0(isp->isp_iocb_dma); mbs.param[6] = DMA_WD3(isp->isp_iocb_dma); mbs.param[7] = DMA_WD2(isp->isp_iocb_dma); MEMORYBARRIER(isp, SYNC_IFORDEV, 0, sizeof(un), chan); isp_mboxcmd(isp, &mbs); if (mbs.param[0] != MBOX_COMMAND_COMPLETE) return (mbs.param[0] | (mbs.param[1] << 16)); MEMORYBARRIER(isp, SYNC_IFORCPU, 0, sizeof(un), chan); if (IS_24XX(isp)) { isp_get_pdb_24xx(isp, isp->isp_iocb, &un.bill); pdb->handle = un.bill.pdb_handle; + pdb->prli_word0 = un.bill.pdb_prli_svc0; pdb->prli_word3 = un.bill.pdb_prli_svc3; pdb->portid = BITS2WORD_24XX(un.bill.pdb_portid_bits); ISP_MEMCPY(pdb->portname, un.bill.pdb_portname, 8); ISP_MEMCPY(pdb->nodename, un.bill.pdb_nodename, 8); isp_prt(isp, ISP_LOGDEBUG0, "Chan %d handle 0x%x Port 0x%06x flags 0x%x curstate %x laststate %x", chan, id, pdb->portid, un.bill.pdb_flags, un.bill.pdb_curstate, un.bill.pdb_laststate); if (un.bill.pdb_curstate < PDB2400_STATE_PLOGI_DONE || un.bill.pdb_curstate > PDB2400_STATE_LOGGED_IN) { mbs.param[0] = MBOX_NOT_LOGGED_IN; return (mbs.param[0]); } } else { isp_get_pdb_21xx(isp, isp->isp_iocb, &un.fred); pdb->handle = un.fred.pdb_loopid; + pdb->prli_word0 = un.fred.pdb_prli_svc0; pdb->prli_word3 = un.fred.pdb_prli_svc3; pdb->portid = BITS2WORD(un.fred.pdb_portid_bits); ISP_MEMCPY(pdb->portname, un.fred.pdb_portname, 8); ISP_MEMCPY(pdb->nodename, un.fred.pdb_nodename, 8); isp_prt(isp, ISP_LOGDEBUG1, "Chan %d handle 0x%x Port 0x%06x", chan, id, pdb->portid); } return (0); } static int isp_gethandles(ispsoftc_t *isp, int chan, uint16_t *handles, int *num, int loop) { fcparam *fcp = FCPARAM(isp, chan); mbreg_t mbs; isp_pnhle_21xx_t el1, *elp1; isp_pnhle_23xx_t el3, *elp3; isp_pnhle_24xx_t el4, *elp4; int i, j; uint32_t p; uint16_t h; MBSINIT(&mbs, MBOX_GET_ID_LIST, MBLOGALL, 250000); if (IS_24XX(isp)) { mbs.param[2] = DMA_WD1(fcp->isp_scdma); mbs.param[3] = DMA_WD0(fcp->isp_scdma); mbs.param[6] = DMA_WD3(fcp->isp_scdma); mbs.param[7] = DMA_WD2(fcp->isp_scdma); mbs.param[8] = ISP_FC_SCRLEN; mbs.param[9] = chan; } else { mbs.ibits = (1 << 1)|(1 << 2)|(1 << 3)|(1 << 6); mbs.param[1] = DMA_WD1(fcp->isp_scdma); mbs.param[2] = DMA_WD0(fcp->isp_scdma); mbs.param[3] = DMA_WD3(fcp->isp_scdma); mbs.param[6] = DMA_WD2(fcp->isp_scdma); } if (FC_SCRATCH_ACQUIRE(isp, chan)) { isp_prt(isp, ISP_LOGERR, sacq); return (-1); } MEMORYBARRIER(isp, SYNC_SFORDEV, 0, ISP_FC_SCRLEN, chan); isp_mboxcmd(isp, &mbs); if (mbs.param[0] != MBOX_COMMAND_COMPLETE) { FC_SCRATCH_RELEASE(isp, chan); return (mbs.param[0] | (mbs.param[1] << 16)); } MEMORYBARRIER(isp, SYNC_SFORCPU, 0, ISP_FC_SCRLEN, chan); elp1 = fcp->isp_scratch; elp3 = fcp->isp_scratch; elp4 = fcp->isp_scratch; for (i = 0, j = 0; i < mbs.param[1] && j < *num; i++) { if (IS_24XX(isp)) { isp_get_pnhle_24xx(isp, &elp4[i], &el4); p = el4.pnhle_port_id_lo | (el4.pnhle_port_id_hi << 16); h = el4.pnhle_handle; } else if (IS_23XX(isp)) { isp_get_pnhle_23xx(isp, &elp3[i], &el3); p = el3.pnhle_port_id_lo | (el3.pnhle_port_id_hi << 16); h = el3.pnhle_handle; } else { /* 21xx */ isp_get_pnhle_21xx(isp, &elp1[i], &el1); p = el1.pnhle_port_id_lo | ((el1.pnhle_port_id_hi_handle & 0xff) << 16); h = el1.pnhle_port_id_hi_handle >> 8; } if (loop && (p >> 8) != (fcp->isp_portid >> 8)) continue; handles[j++] = h; } *num = j; FC_SCRATCH_RELEASE(isp, chan); return (0); } static void isp_dump_chip_portdb(ispsoftc_t *isp, int chan) { isp_pdb_t pdb; uint16_t lim, nphdl; isp_prt(isp, ISP_LOG_SANCFG|ISP_LOGINFO, "Chan %d chip port dump", chan); if (ISP_CAP_2KLOGIN(isp)) { lim = NPH_MAX_2K; } else { lim = NPH_MAX; } for (nphdl = 0; nphdl != lim; nphdl++) { if (isp_getpdb(isp, chan, nphdl, &pdb)) { continue; } isp_prt(isp, ISP_LOG_SANCFG|ISP_LOGINFO, "Chan %d Handle 0x%04x " "PortID 0x%06x WWPN 0x%02x%02x%02x%02x%02x%02x%02x%02x", chan, nphdl, pdb.portid, pdb.portname[0], pdb.portname[1], pdb.portname[2], pdb.portname[3], pdb.portname[4], pdb.portname[5], pdb.portname[6], pdb.portname[7]); } } static uint64_t isp_get_wwn(ispsoftc_t *isp, int chan, int nphdl, int nodename) { uint64_t wwn = INI_NONE; mbreg_t mbs; MBSINIT(&mbs, MBOX_GET_PORT_NAME, MBLOGALL & ~MBLOGMASK(MBOX_COMMAND_PARAM_ERROR), 500000); if (ISP_CAP_2KLOGIN(isp)) { mbs.param[1] = nphdl; if (nodename) { mbs.param[10] = 1; } mbs.param[9] = chan; } else { mbs.ibitm = 3; mbs.param[1] = nphdl << 8; if (nodename) { mbs.param[1] |= 1; } } isp_mboxcmd(isp, &mbs); if (mbs.param[0] != MBOX_COMMAND_COMPLETE) { return (wwn); } if (IS_24XX(isp)) { wwn = (((uint64_t)(mbs.param[2] >> 8)) << 56) | (((uint64_t)(mbs.param[2] & 0xff)) << 48) | (((uint64_t)(mbs.param[3] >> 8)) << 40) | (((uint64_t)(mbs.param[3] & 0xff)) << 32) | (((uint64_t)(mbs.param[6] >> 8)) << 24) | (((uint64_t)(mbs.param[6] & 0xff)) << 16) | (((uint64_t)(mbs.param[7] >> 8)) << 8) | (((uint64_t)(mbs.param[7] & 0xff))); } else { wwn = (((uint64_t)(mbs.param[2] & 0xff)) << 56) | (((uint64_t)(mbs.param[2] >> 8)) << 48) | (((uint64_t)(mbs.param[3] & 0xff)) << 40) | (((uint64_t)(mbs.param[3] >> 8)) << 32) | (((uint64_t)(mbs.param[6] & 0xff)) << 24) | (((uint64_t)(mbs.param[6] >> 8)) << 16) | (((uint64_t)(mbs.param[7] & 0xff)) << 8) | (((uint64_t)(mbs.param[7] >> 8))); } return (wwn); } /* * Make sure we have good FC link. */ static int isp_fclink_test(ispsoftc_t *isp, int chan, int usdelay) { mbreg_t mbs; int i, r; uint16_t nphdl; fcparam *fcp; isp_pdb_t pdb; NANOTIME_T hra, hrb; fcp = FCPARAM(isp, chan); if (fcp->isp_loopstate < LOOP_HAVE_LINK) return (-1); if (fcp->isp_loopstate >= LOOP_LTEST_DONE) return (0); isp_prt(isp, ISP_LOG_SANCFG, "Chan %d FC link test", chan); /* * Wait up to N microseconds for F/W to go to a ready state. */ GET_NANOTIME(&hra); while (1) { isp_change_fw_state(isp, chan, isp_fw_state(isp, chan)); if (fcp->isp_fwstate == FW_READY) { break; } if (fcp->isp_loopstate < LOOP_HAVE_LINK) goto abort; GET_NANOTIME(&hrb); if ((NANOTIME_SUB(&hrb, &hra) / 1000 + 1000 >= usdelay)) break; ISP_SLEEP(isp, 1000); } if (fcp->isp_fwstate != FW_READY) { isp_prt(isp, ISP_LOG_SANCFG, "Chan %d Firmware is not ready (%s)", chan, isp_fc_fw_statename(fcp->isp_fwstate)); return (-1); } /* * Get our Loop ID and Port ID. */ MBSINIT(&mbs, MBOX_GET_LOOP_ID, MBLOGALL, 0); mbs.param[9] = chan; isp_mboxcmd(isp, &mbs); if (mbs.param[0] != MBOX_COMMAND_COMPLETE) { return (-1); } if (IS_2100(isp)) { /* * Don't bother with fabric if we are using really old * 2100 firmware. It's just not worth it. */ if (ISP_FW_NEWER_THAN(isp, 1, 15, 37)) fcp->isp_topo = TOPO_FL_PORT; else fcp->isp_topo = TOPO_NL_PORT; } else { int topo = (int) mbs.param[6]; if (topo < TOPO_NL_PORT || topo > TOPO_PTP_STUB) { topo = TOPO_PTP_STUB; } fcp->isp_topo = topo; } fcp->isp_portid = mbs.param[2] | (mbs.param[3] << 16); if (!TOPO_IS_FABRIC(fcp->isp_topo)) { fcp->isp_loopid = mbs.param[1] & 0xff; } else if (fcp->isp_topo != TOPO_F_PORT) { uint8_t alpa = fcp->isp_portid; for (i = 0; alpa_map[i]; i++) { if (alpa_map[i] == alpa) break; } if (alpa_map[i]) fcp->isp_loopid = i; } #if 0 fcp->isp_loopstate = LOOP_HAVE_ADDR; #endif fcp->isp_loopstate = LOOP_TESTING_LINK; if (fcp->isp_topo == TOPO_F_PORT || fcp->isp_topo == TOPO_FL_PORT) { nphdl = IS_24XX(isp) ? NPH_FL_ID : FL_ID; r = isp_getpdb(isp, chan, nphdl, &pdb); if (r != 0 || pdb.portid == 0) { if (IS_2100(isp)) { fcp->isp_topo = TOPO_NL_PORT; } else { isp_prt(isp, ISP_LOGWARN, "fabric topology, but cannot get info about fabric controller (0x%x)", r); fcp->isp_topo = TOPO_PTP_STUB; } goto not_on_fabric; } if (IS_24XX(isp)) { fcp->isp_fabric_params = mbs.param[7]; fcp->isp_sns_hdl = NPH_SNS_ID; r = isp_register_fc4_type(isp, chan); if (fcp->isp_loopstate < LOOP_TESTING_LINK) goto abort; if (r != 0) goto not_on_fabric; r = isp_register_fc4_features_24xx(isp, chan); if (fcp->isp_loopstate < LOOP_TESTING_LINK) goto abort; if (r != 0) goto not_on_fabric; r = isp_register_port_name_24xx(isp, chan); if (fcp->isp_loopstate < LOOP_TESTING_LINK) goto abort; if (r != 0) goto not_on_fabric; isp_register_node_name_24xx(isp, chan); if (fcp->isp_loopstate < LOOP_TESTING_LINK) goto abort; } else { fcp->isp_sns_hdl = SNS_ID; r = isp_register_fc4_type(isp, chan); if (r != 0) goto not_on_fabric; if (fcp->role == ISP_ROLE_TARGET) isp_send_change_request(isp, chan); } } not_on_fabric: /* Get link speed. */ fcp->isp_gbspeed = 1; if (IS_23XX(isp) || IS_24XX(isp)) { MBSINIT(&mbs, MBOX_GET_SET_DATA_RATE, MBLOGALL, 3000000); mbs.param[1] = MBGSD_GET_RATE; /* mbs.param[2] undefined if we're just getting rate */ isp_mboxcmd(isp, &mbs); if (mbs.param[0] == MBOX_COMMAND_COMPLETE) { if (mbs.param[1] == MBGSD_10GB) fcp->isp_gbspeed = 10; else if (mbs.param[1] == MBGSD_32GB) fcp->isp_gbspeed = 32; else if (mbs.param[1] == MBGSD_16GB) fcp->isp_gbspeed = 16; else if (mbs.param[1] == MBGSD_8GB) fcp->isp_gbspeed = 8; else if (mbs.param[1] == MBGSD_4GB) fcp->isp_gbspeed = 4; else if (mbs.param[1] == MBGSD_2GB) fcp->isp_gbspeed = 2; else if (mbs.param[1] == MBGSD_1GB) fcp->isp_gbspeed = 1; } } if (fcp->isp_loopstate < LOOP_TESTING_LINK) { abort: isp_prt(isp, ISP_LOG_SANCFG, "Chan %d FC link test aborted", chan); return (1); } fcp->isp_loopstate = LOOP_LTEST_DONE; isp_prt(isp, ISP_LOG_SANCFG|ISP_LOGCONFIG, "Chan %d WWPN %016jx WWNN %016jx", chan, (uintmax_t)fcp->isp_wwpn, (uintmax_t)fcp->isp_wwnn); isp_prt(isp, ISP_LOG_SANCFG|ISP_LOGCONFIG, "Chan %d %dGb %s PortID 0x%06x LoopID 0x%02x", chan, fcp->isp_gbspeed, isp_fc_toponame(fcp), fcp->isp_portid, fcp->isp_loopid); isp_prt(isp, ISP_LOG_SANCFG, "Chan %d FC link test done", chan); return (0); } /* * Complete the synchronization of our Port Database. * * At this point, we've scanned the local loop (if any) and the fabric * and performed fabric logins on all new devices. * * Our task here is to go through our port database removing any entities * that are still marked probational (issuing PLOGO for ones which we had * PLOGI'd into) or are dead, and notifying upper layers about new/changed * devices. */ static int isp_pdb_sync(ispsoftc_t *isp, int chan) { fcparam *fcp = FCPARAM(isp, chan); fcportdb_t *lp; uint16_t dbidx; if (fcp->isp_loopstate < LOOP_FSCAN_DONE) return (-1); if (fcp->isp_loopstate >= LOOP_READY) return (0); isp_prt(isp, ISP_LOG_SANCFG, "Chan %d FC PDB sync", chan); fcp->isp_loopstate = LOOP_SYNCING_PDB; for (dbidx = 0; dbidx < MAX_FC_TARG; dbidx++) { lp = &fcp->portdb[dbidx]; if (lp->state == FC_PORTDB_STATE_NIL) continue; if (lp->probational && lp->state != FC_PORTDB_STATE_ZOMBIE) lp->state = FC_PORTDB_STATE_DEAD; switch (lp->state) { case FC_PORTDB_STATE_DEAD: lp->state = FC_PORTDB_STATE_NIL; isp_async(isp, ISPASYNC_DEV_GONE, chan, lp); if ((lp->portid & 0xffff00) != 0) { (void) isp_plogx(isp, chan, lp->handle, lp->portid, PLOGX_FLG_CMD_LOGO | PLOGX_FLG_IMPLICIT | PLOGX_FLG_FREE_NPHDL); } /* * Note that we might come out of this with our state * set to FC_PORTDB_STATE_ZOMBIE. */ break; case FC_PORTDB_STATE_NEW: lp->state = FC_PORTDB_STATE_VALID; isp_async(isp, ISPASYNC_DEV_ARRIVED, chan, lp); break; case FC_PORTDB_STATE_CHANGED: lp->state = FC_PORTDB_STATE_VALID; isp_async(isp, ISPASYNC_DEV_CHANGED, chan, lp); lp->portid = lp->new_portid; + lp->prli_word0 = lp->new_prli_word0; lp->prli_word3 = lp->new_prli_word3; break; case FC_PORTDB_STATE_VALID: isp_async(isp, ISPASYNC_DEV_STAYED, chan, lp); break; case FC_PORTDB_STATE_ZOMBIE: break; default: isp_prt(isp, ISP_LOGWARN, "isp_pdb_sync: state %d for idx %d", lp->state, dbidx); isp_dump_portdb(isp, chan); } } if (fcp->isp_loopstate < LOOP_SYNCING_PDB) { isp_prt(isp, ISP_LOG_SANCFG, "Chan %d FC PDB sync aborted", chan); return (1); } fcp->isp_loopstate = LOOP_READY; isp_prt(isp, ISP_LOG_SANCFG, "Chan %d FC PDB sync done", chan); return (0); } static void isp_pdb_add_update(ispsoftc_t *isp, int chan, isp_pdb_t *pdb) { fcportdb_t *lp; uint64_t wwnn, wwpn; MAKE_WWN_FROM_NODE_NAME(wwnn, pdb->nodename); MAKE_WWN_FROM_NODE_NAME(wwpn, pdb->portname); /* Search port database for the same WWPN. */ if (isp_find_pdb_by_wwpn(isp, chan, wwpn, &lp)) { if (!lp->probational) { isp_prt(isp, ISP_LOGERR, "Chan %d Port 0x%06x@0x%04x [%d] is not probational (0x%x)", chan, lp->portid, lp->handle, FC_PORTDB_TGT(isp, chan, lp), lp->state); isp_dump_portdb(isp, chan); return; } lp->probational = 0; lp->node_wwn = wwnn; /* Old device, nothing new. */ if (lp->portid == pdb->portid && lp->handle == pdb->handle && - lp->prli_word3 == pdb->prli_word3) { + lp->prli_word3 == pdb->prli_word3 && + ((pdb->prli_word0 & PRLI_WD0_EST_IMAGE_PAIR) == 0)) { if (lp->state != FC_PORTDB_STATE_NEW) lp->state = FC_PORTDB_STATE_VALID; isp_prt(isp, ISP_LOG_SANCFG, "Chan %d Port 0x%06x@0x%04x is valid", chan, pdb->portid, pdb->handle); return; } /* Something has changed. */ lp->state = FC_PORTDB_STATE_CHANGED; lp->handle = pdb->handle; lp->new_portid = pdb->portid; + lp->new_prli_word0 = pdb->prli_word0; lp->new_prli_word3 = pdb->prli_word3; isp_prt(isp, ISP_LOG_SANCFG, "Chan %d Port 0x%06x@0x%04x is changed", chan, pdb->portid, pdb->handle); return; } /* It seems like a new port. Find an empty slot for it. */ if (!isp_find_pdb_empty(isp, chan, &lp)) { isp_prt(isp, ISP_LOGERR, "Chan %d out of portdb entries", chan); return; } ISP_MEMZERO(lp, sizeof (fcportdb_t)); lp->probational = 0; lp->state = FC_PORTDB_STATE_NEW; lp->portid = lp->new_portid = pdb->portid; lp->prli_word3 = lp->new_prli_word3 = pdb->prli_word3; lp->handle = pdb->handle; lp->port_wwn = wwpn; lp->node_wwn = wwnn; isp_prt(isp, ISP_LOG_SANCFG, "Chan %d Port 0x%06x@0x%04x is new", chan, pdb->portid, pdb->handle); } /* * Fix port IDs for logged-in initiators on pre-2400 chips. * For those chips we are not receiving login events, adding initiators * based on ATIO requests, but there is no port ID in that structure. */ static void isp_fix_portids(ispsoftc_t *isp, int chan) { fcparam *fcp = FCPARAM(isp, chan); isp_pdb_t pdb; uint64_t wwpn; int i, r; for (i = 0; i < MAX_FC_TARG; i++) { fcportdb_t *lp = &fcp->portdb[i]; if (lp->state == FC_PORTDB_STATE_NIL || lp->state == FC_PORTDB_STATE_ZOMBIE) continue; if (VALID_PORT(lp->portid)) continue; r = isp_getpdb(isp, chan, lp->handle, &pdb); if (fcp->isp_loopstate < LOOP_SCANNING_LOOP) return; if (r != 0) { isp_prt(isp, ISP_LOGDEBUG1, "Chan %d FC Scan Loop handle %d returned %x", chan, lp->handle, r); continue; } MAKE_WWN_FROM_NODE_NAME(wwpn, pdb.portname); if (lp->port_wwn != wwpn) continue; lp->portid = lp->new_portid = pdb.portid; isp_prt(isp, ISP_LOG_SANCFG, "Chan %d Port 0x%06x@0x%04x is fixed", chan, pdb.portid, pdb.handle); } } /* * Scan local loop for devices. */ static int isp_scan_loop(ispsoftc_t *isp, int chan) { fcparam *fcp = FCPARAM(isp, chan); int idx, lim, r; isp_pdb_t pdb; uint16_t *handles; uint16_t handle; if (fcp->isp_loopstate < LOOP_LTEST_DONE) return (-1); if (fcp->isp_loopstate >= LOOP_LSCAN_DONE) return (0); isp_prt(isp, ISP_LOG_SANCFG, "Chan %d FC loop scan", chan); fcp->isp_loopstate = LOOP_SCANNING_LOOP; if (TOPO_IS_FABRIC(fcp->isp_topo)) { if (!IS_24XX(isp)) { isp_fix_portids(isp, chan); if (fcp->isp_loopstate < LOOP_SCANNING_LOOP) goto abort; } isp_prt(isp, ISP_LOG_SANCFG, "Chan %d FC loop scan done (no loop)", chan); fcp->isp_loopstate = LOOP_LSCAN_DONE; return (0); } handles = (uint16_t *)fcp->isp_scanscratch; lim = ISP_FC_SCRLEN / 2; r = isp_gethandles(isp, chan, handles, &lim, 1); if (r != 0) { isp_prt(isp, ISP_LOG_SANCFG, "Chan %d Getting list of handles failed with %x", chan, r); isp_prt(isp, ISP_LOG_SANCFG, "Chan %d FC loop scan done (bad)", chan); return (-1); } isp_prt(isp, ISP_LOG_SANCFG, "Chan %d Got %d handles", chan, lim); /* * Run through the list and get the port database info for each one. */ isp_mark_portdb(isp, chan); for (idx = 0; idx < lim; idx++) { handle = handles[idx]; /* * Don't scan "special" ids. */ if (ISP_CAP_2KLOGIN(isp)) { if (handle >= NPH_RESERVED) continue; } else { if (handle >= FL_ID && handle <= SNS_ID) continue; } /* * In older cards with older f/w GET_PORT_DATABASE has been * known to hang. This trick gets around that problem. */ if (IS_2100(isp) || IS_2200(isp)) { uint64_t node_wwn = isp_get_wwn(isp, chan, handle, 1); if (fcp->isp_loopstate < LOOP_SCANNING_LOOP) { abort: isp_prt(isp, ISP_LOG_SANCFG, "Chan %d FC loop scan aborted", chan); return (1); } if (node_wwn == INI_NONE) { continue; } } /* * Get the port database entity for this index. */ r = isp_getpdb(isp, chan, handle, &pdb); if (fcp->isp_loopstate < LOOP_SCANNING_LOOP) goto abort; if (r != 0) { isp_prt(isp, ISP_LOGDEBUG1, "Chan %d FC Scan Loop handle %d returned %x", chan, handle, r); continue; } isp_pdb_add_update(isp, chan, &pdb); } if (fcp->isp_loopstate < LOOP_SCANNING_LOOP) goto abort; fcp->isp_loopstate = LOOP_LSCAN_DONE; isp_prt(isp, ISP_LOG_SANCFG, "Chan %d FC loop scan done", chan); return (0); } static int isp_ct_sns(ispsoftc_t *isp, int chan, uint32_t cmd_bcnt, uint32_t rsp_bcnt) { fcparam *fcp = FCPARAM(isp, chan); mbreg_t mbs; if (isp->isp_dblev & ISP_LOGDEBUG1) isp_print_bytes(isp, "CT SNS request", cmd_bcnt, fcp->isp_scratch); MEMORYBARRIER(isp, SYNC_SFORDEV, 0, cmd_bcnt, chan); MBSINIT(&mbs, MBOX_SEND_SNS, MBLOGALL, 10000000); mbs.param[1] = cmd_bcnt >> 1; mbs.param[2] = DMA_WD1(fcp->isp_scdma); mbs.param[3] = DMA_WD0(fcp->isp_scdma); mbs.param[6] = DMA_WD3(fcp->isp_scdma); mbs.param[7] = DMA_WD2(fcp->isp_scdma); isp_mboxcmd(isp, &mbs); if (mbs.param[0] != MBOX_COMMAND_COMPLETE) { if (mbs.param[0] == MBOX_INVALID_COMMAND) { return (1); } else { return (-1); } } MEMORYBARRIER(isp, SYNC_SFORCPU, 0, rsp_bcnt, chan); if (isp->isp_dblev & ISP_LOGDEBUG1) isp_print_bytes(isp, "CT response", rsp_bcnt, fcp->isp_scratch); return (0); } static int isp_ct_passthru(ispsoftc_t *isp, int chan, uint32_t cmd_bcnt, uint32_t rsp_bcnt) { fcparam *fcp = FCPARAM(isp, chan); isp_ct_pt_t pt; void *reqp; uint8_t resp[QENTRY_LEN]; if (isp->isp_dblev & ISP_LOGDEBUG1) isp_print_bytes(isp, "CT request", cmd_bcnt, fcp->isp_scratch); /* * Build a Passthrough IOCB in memory. */ ISP_MEMZERO(&pt, sizeof(pt)); pt.ctp_header.rqs_entry_count = 1; pt.ctp_header.rqs_entry_type = RQSTYPE_CT_PASSTHRU; pt.ctp_nphdl = fcp->isp_sns_hdl; pt.ctp_cmd_cnt = 1; pt.ctp_vpidx = ISP_GET_VPIDX(isp, chan); pt.ctp_time = 10; pt.ctp_rsp_cnt = 1; pt.ctp_rsp_bcnt = rsp_bcnt; pt.ctp_cmd_bcnt = cmd_bcnt; pt.ctp_dataseg[0].ds_base = DMA_LO32(fcp->isp_scdma); pt.ctp_dataseg[0].ds_basehi = DMA_HI32(fcp->isp_scdma); pt.ctp_dataseg[0].ds_count = cmd_bcnt; pt.ctp_dataseg[1].ds_base = DMA_LO32(fcp->isp_scdma); pt.ctp_dataseg[1].ds_basehi = DMA_HI32(fcp->isp_scdma); pt.ctp_dataseg[1].ds_count = rsp_bcnt; /* Prepare space for response in memory */ memset(resp, 0xff, sizeof(resp)); pt.ctp_handle = isp_allocate_handle(isp, resp, ISP_HANDLE_CTRL); if (pt.ctp_handle == 0) { isp_prt(isp, ISP_LOGERR, "%s: CTP of Chan %d out of handles", __func__, chan); return (-1); } /* Send request and wait for response. */ reqp = isp_getrqentry(isp); if (reqp == NULL) { isp_prt(isp, ISP_LOGERR, "%s: CTP of Chan %d out of rqent", __func__, chan); isp_destroy_handle(isp, pt.ctp_handle); return (-1); } isp_put_ct_pt(isp, &pt, (isp_ct_pt_t *)reqp); if (isp->isp_dblev & ISP_LOGDEBUG1) isp_print_bytes(isp, "CT IOCB request", QENTRY_LEN, reqp); ISP_SYNC_REQUEST(isp); if (msleep(resp, &isp->isp_lock, 0, "CTP", pt.ctp_time*hz) == EWOULDBLOCK) { isp_prt(isp, ISP_LOGERR, "%s: CTP of Chan %d timed out", __func__, chan); isp_destroy_handle(isp, pt.ctp_handle); return (-1); } if (isp->isp_dblev & ISP_LOGDEBUG1) isp_print_bytes(isp, "CT IOCB response", QENTRY_LEN, resp); isp_get_ct_pt(isp, (isp_ct_pt_t *)resp, &pt); if (pt.ctp_status && pt.ctp_status != RQCS_DATA_UNDERRUN) { isp_prt(isp, ISP_LOGWARN, "Chan %d CT pass-through returned 0x%x", chan, pt.ctp_status); return (-1); } if (isp->isp_dblev & ISP_LOGDEBUG1) isp_print_bytes(isp, "CT response", rsp_bcnt, fcp->isp_scratch); return (0); } /* * Scan the fabric for devices and add them to our port database. * * Use the GID_PT command to get list of all Nx_Port IDs SNS knows. * Use GFF_ID and GFT_ID to check port type (FCP) and features (target). * * For 2100-23XX cards, we use the SNS mailbox command to pass simple name * server commands to the switch management server via the QLogic f/w. * * For the 24XX and above card, we use CT Pass-through IOCB. */ #define GIDLEN ISP_FC_SCRLEN #define NGENT ((GIDLEN - 16) >> 2) static int isp_gid_pt(ispsoftc_t *isp, int chan) { fcparam *fcp = FCPARAM(isp, chan); ct_hdr_t ct; sns_gid_pt_req_t rq; uint8_t *scp = fcp->isp_scratch; isp_prt(isp, ISP_LOGDEBUG0, "Chan %d requesting GID_PT", chan); if (FC_SCRATCH_ACQUIRE(isp, chan)) { isp_prt(isp, ISP_LOGERR, sacq); return (-1); } if (IS_24XX(isp)) { /* Build the CT command and execute via pass-through. */ ISP_MEMZERO(&ct, sizeof (ct)); ct.ct_revision = CT_REVISION; ct.ct_fcs_type = CT_FC_TYPE_FC; ct.ct_fcs_subtype = CT_FC_SUBTYPE_NS; ct.ct_cmd_resp = SNS_GID_PT; ct.ct_bcnt_resid = (GIDLEN - 16) >> 2; isp_put_ct_hdr(isp, &ct, (ct_hdr_t *)scp); scp[sizeof(ct)] = 0x7f; /* Port Type = Nx_Port */ scp[sizeof(ct)+1] = 0; /* Domain_ID = any */ scp[sizeof(ct)+2] = 0; /* Area_ID = any */ scp[sizeof(ct)+3] = 0; /* Flags = no Area_ID */ if (isp_ct_passthru(isp, chan, sizeof(ct) + sizeof(uint32_t), GIDLEN)) { FC_SCRATCH_RELEASE(isp, chan); return (-1); } } else { /* Build the SNS request and execute via firmware. */ ISP_MEMZERO(&rq, SNS_GID_PT_REQ_SIZE); rq.snscb_rblen = GIDLEN >> 1; rq.snscb_addr[RQRSP_ADDR0015] = DMA_WD0(fcp->isp_scdma); rq.snscb_addr[RQRSP_ADDR1631] = DMA_WD1(fcp->isp_scdma); rq.snscb_addr[RQRSP_ADDR3247] = DMA_WD2(fcp->isp_scdma); rq.snscb_addr[RQRSP_ADDR4863] = DMA_WD3(fcp->isp_scdma); rq.snscb_sblen = 6; rq.snscb_cmd = SNS_GID_PT; rq.snscb_mword_div_2 = NGENT; rq.snscb_port_type = 0x7f; /* Port Type = Nx_Port */ rq.snscb_domain = 0; /* Domain_ID = any */ rq.snscb_area = 0; /* Area_ID = any */ rq.snscb_flags = 0; /* Flags = no Area_ID */ isp_put_gid_pt_request(isp, &rq, (sns_gid_pt_req_t *)scp); if (isp_ct_sns(isp, chan, sizeof(rq), NGENT)) { FC_SCRATCH_RELEASE(isp, chan); return (-1); } } isp_get_gid_xx_response(isp, (sns_gid_xx_rsp_t *)scp, (sns_gid_xx_rsp_t *)fcp->isp_scanscratch, NGENT); FC_SCRATCH_RELEASE(isp, chan); return (0); } static int isp_gff_id(ispsoftc_t *isp, int chan, uint32_t portid) { fcparam *fcp = FCPARAM(isp, chan); ct_hdr_t ct; uint32_t *rp; uint8_t *scp = fcp->isp_scratch; sns_gff_id_rsp_t rsp; int i, res = -1; if (!fcp->isp_use_gff_id) /* User may block GFF_ID use. */ return (res); if (!IS_24XX(isp)) /* Old chips can't request GFF_ID. */ return (res); isp_prt(isp, ISP_LOGDEBUG0, "Chan %d requesting GFF_ID", chan); if (FC_SCRATCH_ACQUIRE(isp, chan)) { isp_prt(isp, ISP_LOGERR, sacq); return (res); } /* Build the CT command and execute via pass-through. */ ISP_MEMZERO(&ct, sizeof (ct)); ct.ct_revision = CT_REVISION; ct.ct_fcs_type = CT_FC_TYPE_FC; ct.ct_fcs_subtype = CT_FC_SUBTYPE_NS; ct.ct_cmd_resp = SNS_GFF_ID; ct.ct_bcnt_resid = (SNS_GFF_ID_RESP_SIZE - sizeof(ct)) / 4; isp_put_ct_hdr(isp, &ct, (ct_hdr_t *)scp); rp = (uint32_t *) &scp[sizeof(ct)]; ISP_IOZPUT_32(isp, portid, rp); if (isp_ct_passthru(isp, chan, sizeof(ct) + sizeof(uint32_t), SNS_GFF_ID_RESP_SIZE)) { FC_SCRATCH_RELEASE(isp, chan); return (res); } isp_get_gff_id_response(isp, (sns_gff_id_rsp_t *)scp, &rsp); if (rsp.snscb_cthdr.ct_cmd_resp == LS_ACC) { for (i = 0; i < 32; i++) { if (rsp.snscb_fc4_features[i] != 0) { res = 0; break; } } if (((rsp.snscb_fc4_features[FC4_SCSI / 8] >> ((FC4_SCSI % 8) * 4)) & 0x01) != 0) res = 1; /* Workaround for broken Brocade firmware. */ if (((ISP_SWAP32(isp, rsp.snscb_fc4_features[FC4_SCSI / 8]) >> ((FC4_SCSI % 8) * 4)) & 0x01) != 0) res = 1; } FC_SCRATCH_RELEASE(isp, chan); isp_prt(isp, ISP_LOGDEBUG0, "Chan %d GFF_ID result is %d", chan, res); return (res); } static int isp_gft_id(ispsoftc_t *isp, int chan, uint32_t portid) { fcparam *fcp = FCPARAM(isp, chan); ct_hdr_t ct; sns_gxx_id_req_t rq; uint32_t *rp; uint8_t *scp = fcp->isp_scratch; sns_gft_id_rsp_t rsp; int i, res = -1; if (!fcp->isp_use_gft_id) /* User may block GFT_ID use. */ return (res); isp_prt(isp, ISP_LOGDEBUG0, "Chan %d requesting GFT_ID", chan); if (FC_SCRATCH_ACQUIRE(isp, chan)) { isp_prt(isp, ISP_LOGERR, sacq); return (res); } if (IS_24XX(isp)) { /* Build the CT command and execute via pass-through. */ ISP_MEMZERO(&ct, sizeof (ct)); ct.ct_revision = CT_REVISION; ct.ct_fcs_type = CT_FC_TYPE_FC; ct.ct_fcs_subtype = CT_FC_SUBTYPE_NS; ct.ct_cmd_resp = SNS_GFT_ID; ct.ct_bcnt_resid = (SNS_GFT_ID_RESP_SIZE - sizeof(ct)) / 4; isp_put_ct_hdr(isp, &ct, (ct_hdr_t *)scp); rp = (uint32_t *) &scp[sizeof(ct)]; ISP_IOZPUT_32(isp, portid, rp); if (isp_ct_passthru(isp, chan, sizeof(ct) + sizeof(uint32_t), SNS_GFT_ID_RESP_SIZE)) { FC_SCRATCH_RELEASE(isp, chan); return (res); } } else { /* Build the SNS request and execute via firmware. */ ISP_MEMZERO(&rq, SNS_GXX_ID_REQ_SIZE); rq.snscb_rblen = SNS_GFT_ID_RESP_SIZE >> 1; rq.snscb_addr[RQRSP_ADDR0015] = DMA_WD0(fcp->isp_scdma); rq.snscb_addr[RQRSP_ADDR1631] = DMA_WD1(fcp->isp_scdma); rq.snscb_addr[RQRSP_ADDR3247] = DMA_WD2(fcp->isp_scdma); rq.snscb_addr[RQRSP_ADDR4863] = DMA_WD3(fcp->isp_scdma); rq.snscb_sblen = 6; rq.snscb_cmd = SNS_GFT_ID; rq.snscb_mword_div_2 = (SNS_GFT_ID_RESP_SIZE - sizeof(ct)) / 4; rq.snscb_portid = portid; isp_put_gxx_id_request(isp, &rq, (sns_gxx_id_req_t *)scp); if (isp_ct_sns(isp, chan, sizeof(rq), SNS_GFT_ID_RESP_SIZE)) { FC_SCRATCH_RELEASE(isp, chan); return (res); } } isp_get_gft_id_response(isp, (sns_gft_id_rsp_t *)scp, &rsp); if (rsp.snscb_cthdr.ct_cmd_resp == LS_ACC) { for (i = 0; i < 8; i++) { if (rsp.snscb_fc4_types[i] != 0) { res = 0; break; } } if (((rsp.snscb_fc4_types[FC4_SCSI / 32] >> (FC4_SCSI % 32)) & 0x01) != 0) res = 1; } FC_SCRATCH_RELEASE(isp, chan); isp_prt(isp, ISP_LOGDEBUG0, "Chan %d GFT_ID result is %d", chan, res); return (res); } static int isp_scan_fabric(ispsoftc_t *isp, int chan) { fcparam *fcp = FCPARAM(isp, chan); fcportdb_t *lp; uint32_t portid; uint16_t nphdl; isp_pdb_t pdb; int portidx, portlim, r; sns_gid_xx_rsp_t *rs; if (fcp->isp_loopstate < LOOP_LSCAN_DONE) return (-1); if (fcp->isp_loopstate >= LOOP_FSCAN_DONE) return (0); isp_prt(isp, ISP_LOG_SANCFG, "Chan %d FC fabric scan", chan); fcp->isp_loopstate = LOOP_SCANNING_FABRIC; if (!TOPO_IS_FABRIC(fcp->isp_topo)) { fcp->isp_loopstate = LOOP_FSCAN_DONE; isp_prt(isp, ISP_LOG_SANCFG, "Chan %d FC fabric scan done (no fabric)", chan); return (0); } if (fcp->isp_loopstate < LOOP_SCANNING_FABRIC) { abort: FC_SCRATCH_RELEASE(isp, chan); isp_prt(isp, ISP_LOG_SANCFG, "Chan %d FC fabric scan aborted", chan); return (1); } /* * Make sure we still are logged into the fabric controller. */ nphdl = IS_24XX(isp) ? NPH_FL_ID : FL_ID; r = isp_getpdb(isp, chan, nphdl, &pdb); if ((r & 0xffff) == MBOX_NOT_LOGGED_IN) { isp_dump_chip_portdb(isp, chan); } if (r) { fcp->isp_loopstate = LOOP_LTEST_DONE; fail: isp_prt(isp, ISP_LOG_SANCFG, "Chan %d FC fabric scan done (bad)", chan); return (-1); } /* Get list of port IDs from SNS. */ r = isp_gid_pt(isp, chan); if (fcp->isp_loopstate < LOOP_SCANNING_FABRIC) goto abort; if (r > 0) { fcp->isp_loopstate = LOOP_FSCAN_DONE; return (-1); } else if (r < 0) { fcp->isp_loopstate = LOOP_LTEST_DONE; /* try again */ return (-1); } rs = (sns_gid_xx_rsp_t *) fcp->isp_scanscratch; if (fcp->isp_loopstate < LOOP_SCANNING_FABRIC) goto abort; if (rs->snscb_cthdr.ct_cmd_resp != LS_ACC) { int level; /* FC-4 Type and Port Type not registered are not errors. */ if (rs->snscb_cthdr.ct_reason == 9 && (rs->snscb_cthdr.ct_explanation == 0x07 || rs->snscb_cthdr.ct_explanation == 0x0a)) { level = ISP_LOG_SANCFG; } else { level = ISP_LOGWARN; } isp_prt(isp, level, "Chan %d Fabric Nameserver rejected GID_PT" " (Reason=0x%x Expl=0x%x)", chan, rs->snscb_cthdr.ct_reason, rs->snscb_cthdr.ct_explanation); fcp->isp_loopstate = LOOP_FSCAN_DONE; return (-1); } /* Check our buffer was big enough to get the full list. */ for (portidx = 0; portidx < NGENT-1; portidx++) { if (rs->snscb_ports[portidx].control & 0x80) break; } if ((rs->snscb_ports[portidx].control & 0x80) == 0) { isp_prt(isp, ISP_LOGWARN, "fabric too big for scratch area: increase ISP_FC_SCRLEN"); } portlim = portidx + 1; isp_prt(isp, ISP_LOG_SANCFG, "Chan %d Got %d ports back from name server", chan, portlim); /* Go through the list and remove duplicate port ids. */ for (portidx = 0; portidx < portlim; portidx++) { int npidx; portid = ((rs->snscb_ports[portidx].portid[0]) << 16) | ((rs->snscb_ports[portidx].portid[1]) << 8) | ((rs->snscb_ports[portidx].portid[2])); for (npidx = portidx + 1; npidx < portlim; npidx++) { uint32_t new_portid = ((rs->snscb_ports[npidx].portid[0]) << 16) | ((rs->snscb_ports[npidx].portid[1]) << 8) | ((rs->snscb_ports[npidx].portid[2])); if (new_portid == portid) { break; } } if (npidx < portlim) { rs->snscb_ports[npidx].portid[0] = 0; rs->snscb_ports[npidx].portid[1] = 0; rs->snscb_ports[npidx].portid[2] = 0; isp_prt(isp, ISP_LOG_SANCFG, "Chan %d removing duplicate PortID 0x%06x entry from list", chan, portid); } } /* * We now have a list of Port IDs for all FC4 SCSI devices * that the Fabric Name server knows about. * * For each entry on this list go through our port database looking * for probational entries- if we find one, then an old entry is * maybe still this one. We get some information to find out. * * Otherwise, it's a new fabric device, and we log into it * (unconditionally). After searching the entire database * again to make sure that we never ever ever ever have more * than one entry that has the same PortID or the same * WWNN/WWPN duple, we enter the device into our database. */ isp_mark_portdb(isp, chan); for (portidx = 0; portidx < portlim; portidx++) { portid = ((rs->snscb_ports[portidx].portid[0]) << 16) | ((rs->snscb_ports[portidx].portid[1]) << 8) | ((rs->snscb_ports[portidx].portid[2])); isp_prt(isp, ISP_LOG_SANCFG, "Chan %d Checking fabric port 0x%06x", chan, portid); if (portid == 0) { isp_prt(isp, ISP_LOG_SANCFG, "Chan %d Port at idx %d is zero", chan, portidx); continue; } if (portid == fcp->isp_portid) { isp_prt(isp, ISP_LOG_SANCFG, "Chan %d Port 0x%06x is our", chan, portid); continue; } /* Now search the entire port database for the same portid. */ if (isp_find_pdb_by_portid(isp, chan, portid, &lp)) { if (!lp->probational) { isp_prt(isp, ISP_LOGERR, "Chan %d Port 0x%06x@0x%04x [%d] is not probational (0x%x)", chan, lp->portid, lp->handle, FC_PORTDB_TGT(isp, chan, lp), lp->state); isp_dump_portdb(isp, chan); goto fail; } if (lp->state == FC_PORTDB_STATE_ZOMBIE) goto relogin; /* * See if we're still logged into it. * * If we aren't, mark it as a dead device and * leave the new portid in the database entry * for somebody further along to decide what to * do (policy choice). * * If we are, check to see if it's the same * device still (it should be). If for some * reason it isn't, mark it as a changed device * and leave the new portid and role in the * database entry for somebody further along to * decide what to do (policy choice). */ r = isp_getpdb(isp, chan, lp->handle, &pdb); if (fcp->isp_loopstate < LOOP_SCANNING_FABRIC) goto abort; if (r != 0) { lp->state = FC_PORTDB_STATE_DEAD; isp_prt(isp, ISP_LOG_SANCFG, "Chan %d Port 0x%06x handle 0x%x is dead (%d)", chan, portid, lp->handle, r); goto relogin; } isp_pdb_add_update(isp, chan, &pdb); continue; } relogin: if ((fcp->role & ISP_ROLE_INITIATOR) == 0) { isp_prt(isp, ISP_LOG_SANCFG, "Chan %d Port 0x%06x is not logged in", chan, portid); continue; } r = isp_gff_id(isp, chan, portid); if (r == 0) { isp_prt(isp, ISP_LOG_SANCFG, "Chan %d Port 0x%06x is not an FCP target", chan, portid); continue; } if (r < 0) r = isp_gft_id(isp, chan, portid); if (r == 0) { isp_prt(isp, ISP_LOG_SANCFG, "Chan %d Port 0x%06x is not FCP", chan, portid); continue; } if (isp_login_device(isp, chan, portid, &pdb, &FCPARAM(isp, 0)->isp_lasthdl)) { if (fcp->isp_loopstate < LOOP_SCANNING_FABRIC) goto abort; continue; } isp_pdb_add_update(isp, chan, &pdb); } if (fcp->isp_loopstate < LOOP_SCANNING_FABRIC) goto abort; fcp->isp_loopstate = LOOP_FSCAN_DONE; isp_prt(isp, ISP_LOG_SANCFG, "Chan %d FC fabric scan done", chan); return (0); } /* * Find an unused handle and try and use to login to a port. */ static int isp_login_device(ispsoftc_t *isp, int chan, uint32_t portid, isp_pdb_t *p, uint16_t *ohp) { int lim, i, r; uint16_t handle; if (ISP_CAP_2KLOGIN(isp)) { lim = NPH_MAX_2K; } else { lim = NPH_MAX; } handle = isp_next_handle(isp, ohp); for (i = 0; i < lim; i++) { if (FCPARAM(isp, chan)->isp_loopstate != LOOP_SCANNING_FABRIC) return (-1); /* Check if this handle is free. */ r = isp_getpdb(isp, chan, handle, p); if (r == 0) { if (p->portid != portid) { /* This handle is busy, try next one. */ handle = isp_next_handle(isp, ohp); continue; } break; } if (FCPARAM(isp, chan)->isp_loopstate != LOOP_SCANNING_FABRIC) return (-1); /* * Now try and log into the device */ r = isp_plogx(isp, chan, handle, portid, PLOGX_FLG_CMD_PLOGI); if (r == 0) { break; } else if ((r & 0xffff) == MBOX_PORT_ID_USED) { /* * If we get here, then the firmwware still thinks we're logged into this device, but with a different * handle. We need to break that association. We used to try and just substitute the handle, but then * failed to get any data via isp_getpdb (below). */ if (isp_plogx(isp, chan, r >> 16, portid, PLOGX_FLG_CMD_LOGO | PLOGX_FLG_IMPLICIT | PLOGX_FLG_FREE_NPHDL)) { isp_prt(isp, ISP_LOGERR, "baw... logout of %x failed", r >> 16); } if (FCPARAM(isp, chan)->isp_loopstate != LOOP_SCANNING_FABRIC) return (-1); r = isp_plogx(isp, chan, handle, portid, PLOGX_FLG_CMD_PLOGI); if (r != 0) i = lim; break; } else if ((r & 0xffff) == MBOX_LOOP_ID_USED) { /* Try the next handle. */ handle = isp_next_handle(isp, ohp); } else { /* Give up. */ i = lim; break; } } if (i == lim) { isp_prt(isp, ISP_LOGWARN, "Chan %d PLOGI 0x%06x failed", chan, portid); return (-1); } /* * If we successfully logged into it, get the PDB for it * so we can crosscheck that it is still what we think it * is and that we also have the role it plays */ r = isp_getpdb(isp, chan, handle, p); if (r != 0) { isp_prt(isp, ISP_LOGERR, "Chan %d new device 0x%06x@0x%x disappeared", chan, portid, handle); return (-1); } if (p->handle != handle || p->portid != portid) { isp_prt(isp, ISP_LOGERR, "Chan %d new device 0x%06x@0x%x changed (0x%06x@0x%0x)", chan, portid, handle, p->portid, p->handle); return (-1); } return (0); } static int isp_send_change_request(ispsoftc_t *isp, int chan) { mbreg_t mbs; MBSINIT(&mbs, MBOX_SEND_CHANGE_REQUEST, MBLOGALL, 500000); mbs.param[1] = 0x03; mbs.param[9] = chan; isp_mboxcmd(isp, &mbs); if (mbs.param[0] == MBOX_COMMAND_COMPLETE) { return (0); } else { isp_prt(isp, ISP_LOGWARN, "Chan %d Send Change Request: 0x%x", chan, mbs.param[0]); return (-1); } } static int isp_register_fc4_type(ispsoftc_t *isp, int chan) { fcparam *fcp = FCPARAM(isp, chan); rft_id_t rp; ct_hdr_t *ct = &rp.rftid_hdr; uint8_t local[SNS_RFT_ID_REQ_SIZE]; sns_screq_t *reqp = (sns_screq_t *) local; uint8_t *scp = fcp->isp_scratch; if (FC_SCRATCH_ACQUIRE(isp, chan)) { isp_prt(isp, ISP_LOGERR, sacq); return (-1); } if (IS_24XX(isp)) { /* Build the CT command and execute via pass-through. */ ISP_MEMZERO(&rp, sizeof(rp)); ct->ct_revision = CT_REVISION; ct->ct_fcs_type = CT_FC_TYPE_FC; ct->ct_fcs_subtype = CT_FC_SUBTYPE_NS; ct->ct_cmd_resp = SNS_RFT_ID; ct->ct_bcnt_resid = (sizeof (rft_id_t) - sizeof (ct_hdr_t)) >> 2; rp.rftid_portid[0] = fcp->isp_portid >> 16; rp.rftid_portid[1] = fcp->isp_portid >> 8; rp.rftid_portid[2] = fcp->isp_portid; rp.rftid_fc4types[FC4_SCSI >> 5] = 1 << (FC4_SCSI & 0x1f); isp_put_rft_id(isp, &rp, (rft_id_t *)scp); if (isp_ct_passthru(isp, chan, sizeof(rft_id_t), sizeof(ct_hdr_t))) { FC_SCRATCH_RELEASE(isp, chan); return (-1); } } else { /* Build the SNS request and execute via firmware. */ ISP_MEMZERO((void *) reqp, SNS_RFT_ID_REQ_SIZE); reqp->snscb_rblen = sizeof (ct_hdr_t) >> 1; reqp->snscb_addr[RQRSP_ADDR0015] = DMA_WD0(fcp->isp_scdma); reqp->snscb_addr[RQRSP_ADDR1631] = DMA_WD1(fcp->isp_scdma); reqp->snscb_addr[RQRSP_ADDR3247] = DMA_WD2(fcp->isp_scdma); reqp->snscb_addr[RQRSP_ADDR4863] = DMA_WD3(fcp->isp_scdma); reqp->snscb_sblen = 22; reqp->snscb_data[0] = SNS_RFT_ID; reqp->snscb_data[4] = fcp->isp_portid & 0xffff; reqp->snscb_data[5] = (fcp->isp_portid >> 16) & 0xff; reqp->snscb_data[6] = (1 << FC4_SCSI); isp_put_sns_request(isp, reqp, (sns_screq_t *)scp); if (isp_ct_sns(isp, chan, SNS_RFT_ID_REQ_SIZE, sizeof(ct_hdr_t))) { FC_SCRATCH_RELEASE(isp, chan); return (-1); } } isp_get_ct_hdr(isp, (ct_hdr_t *) scp, ct); FC_SCRATCH_RELEASE(isp, chan); if (ct->ct_cmd_resp == LS_RJT) { isp_prt(isp, ISP_LOG_SANCFG|ISP_LOG_WARN1, "Chan %d Register FC4 Type rejected", chan); return (-1); } else if (ct->ct_cmd_resp == LS_ACC) { isp_prt(isp, ISP_LOG_SANCFG, "Chan %d Register FC4 Type accepted", chan); } else { isp_prt(isp, ISP_LOGWARN, "Chan %d Register FC4 Type: 0x%x", chan, ct->ct_cmd_resp); return (-1); } return (0); } static int isp_register_fc4_features_24xx(ispsoftc_t *isp, int chan) { fcparam *fcp = FCPARAM(isp, chan); ct_hdr_t *ct; rff_id_t rp; uint8_t *scp = fcp->isp_scratch; if (FC_SCRATCH_ACQUIRE(isp, chan)) { isp_prt(isp, ISP_LOGERR, sacq); return (-1); } /* * Build the CT header and command in memory. */ ISP_MEMZERO(&rp, sizeof(rp)); ct = &rp.rffid_hdr; ct->ct_revision = CT_REVISION; ct->ct_fcs_type = CT_FC_TYPE_FC; ct->ct_fcs_subtype = CT_FC_SUBTYPE_NS; ct->ct_cmd_resp = SNS_RFF_ID; ct->ct_bcnt_resid = (sizeof (rff_id_t) - sizeof (ct_hdr_t)) >> 2; rp.rffid_portid[0] = fcp->isp_portid >> 16; rp.rffid_portid[1] = fcp->isp_portid >> 8; rp.rffid_portid[2] = fcp->isp_portid; rp.rffid_fc4features = 0; if (fcp->role & ISP_ROLE_TARGET) rp.rffid_fc4features |= 1; if (fcp->role & ISP_ROLE_INITIATOR) rp.rffid_fc4features |= 2; rp.rffid_fc4type = FC4_SCSI; isp_put_rff_id(isp, &rp, (rff_id_t *)scp); if (isp->isp_dblev & ISP_LOGDEBUG1) isp_print_bytes(isp, "CT request", sizeof(rft_id_t), scp); if (isp_ct_passthru(isp, chan, sizeof(rft_id_t), sizeof(ct_hdr_t))) { FC_SCRATCH_RELEASE(isp, chan); return (-1); } isp_get_ct_hdr(isp, (ct_hdr_t *) scp, ct); FC_SCRATCH_RELEASE(isp, chan); if (ct->ct_cmd_resp == LS_RJT) { isp_prt(isp, ISP_LOG_SANCFG|ISP_LOG_WARN1, "Chan %d Register FC4 Features rejected", chan); return (-1); } else if (ct->ct_cmd_resp == LS_ACC) { isp_prt(isp, ISP_LOG_SANCFG, "Chan %d Register FC4 Features accepted", chan); } else { isp_prt(isp, ISP_LOGWARN, "Chan %d Register FC4 Features: 0x%x", chan, ct->ct_cmd_resp); return (-1); } return (0); } static int isp_register_port_name_24xx(ispsoftc_t *isp, int chan) { fcparam *fcp = FCPARAM(isp, chan); ct_hdr_t *ct; rspn_id_t rp; uint8_t *scp = fcp->isp_scratch; int len; if (FC_SCRATCH_ACQUIRE(isp, chan)) { isp_prt(isp, ISP_LOGERR, sacq); return (-1); } /* * Build the CT header and command in memory. */ ISP_MEMZERO(&rp, sizeof(rp)); ct = &rp.rspnid_hdr; ct->ct_revision = CT_REVISION; ct->ct_fcs_type = CT_FC_TYPE_FC; ct->ct_fcs_subtype = CT_FC_SUBTYPE_NS; ct->ct_cmd_resp = SNS_RSPN_ID; rp.rspnid_portid[0] = fcp->isp_portid >> 16; rp.rspnid_portid[1] = fcp->isp_portid >> 8; rp.rspnid_portid[2] = fcp->isp_portid; rp.rspnid_length = 0; len = offsetof(rspn_id_t, rspnid_name); mtx_lock(&prison0.pr_mtx); rp.rspnid_length += sprintf(&scp[len + rp.rspnid_length], "%s", prison0.pr_hostname[0] ? prison0.pr_hostname : "FreeBSD"); mtx_unlock(&prison0.pr_mtx); rp.rspnid_length += sprintf(&scp[len + rp.rspnid_length], ":%s", device_get_nameunit(isp->isp_dev)); if (chan != 0) { rp.rspnid_length += sprintf(&scp[len + rp.rspnid_length], "/%d", chan); } len += rp.rspnid_length; ct->ct_bcnt_resid = (len - sizeof(ct_hdr_t)) >> 2; isp_put_rspn_id(isp, &rp, (rspn_id_t *)scp); if (isp_ct_passthru(isp, chan, len, sizeof(ct_hdr_t))) { FC_SCRATCH_RELEASE(isp, chan); return (-1); } isp_get_ct_hdr(isp, (ct_hdr_t *) scp, ct); FC_SCRATCH_RELEASE(isp, chan); if (ct->ct_cmd_resp == LS_RJT) { isp_prt(isp, ISP_LOG_SANCFG|ISP_LOG_WARN1, "Chan %d Register Symbolic Port Name rejected", chan); return (-1); } else if (ct->ct_cmd_resp == LS_ACC) { isp_prt(isp, ISP_LOG_SANCFG, "Chan %d Register Symbolic Port Name accepted", chan); } else { isp_prt(isp, ISP_LOGWARN, "Chan %d Register Symbolic Port Name: 0x%x", chan, ct->ct_cmd_resp); return (-1); } return (0); } static int isp_register_node_name_24xx(ispsoftc_t *isp, int chan) { fcparam *fcp = FCPARAM(isp, chan); ct_hdr_t *ct; rsnn_nn_t rp; uint8_t *scp = fcp->isp_scratch; int len; if (FC_SCRATCH_ACQUIRE(isp, chan)) { isp_prt(isp, ISP_LOGERR, sacq); return (-1); } /* * Build the CT header and command in memory. */ ISP_MEMZERO(&rp, sizeof(rp)); ct = &rp.rsnnnn_hdr; ct->ct_revision = CT_REVISION; ct->ct_fcs_type = CT_FC_TYPE_FC; ct->ct_fcs_subtype = CT_FC_SUBTYPE_NS; ct->ct_cmd_resp = SNS_RSNN_NN; MAKE_NODE_NAME_FROM_WWN(rp.rsnnnn_nodename, fcp->isp_wwnn); rp.rsnnnn_length = 0; len = offsetof(rsnn_nn_t, rsnnnn_name); mtx_lock(&prison0.pr_mtx); rp.rsnnnn_length += sprintf(&scp[len + rp.rsnnnn_length], "%s", prison0.pr_hostname[0] ? prison0.pr_hostname : "FreeBSD"); mtx_unlock(&prison0.pr_mtx); len += rp.rsnnnn_length; ct->ct_bcnt_resid = (len - sizeof(ct_hdr_t)) >> 2; isp_put_rsnn_nn(isp, &rp, (rsnn_nn_t *)scp); if (isp_ct_passthru(isp, chan, len, sizeof(ct_hdr_t))) { FC_SCRATCH_RELEASE(isp, chan); return (-1); } isp_get_ct_hdr(isp, (ct_hdr_t *) scp, ct); FC_SCRATCH_RELEASE(isp, chan); if (ct->ct_cmd_resp == LS_RJT) { isp_prt(isp, ISP_LOG_SANCFG|ISP_LOG_WARN1, "Chan %d Register Symbolic Node Name rejected", chan); return (-1); } else if (ct->ct_cmd_resp == LS_ACC) { isp_prt(isp, ISP_LOG_SANCFG, "Chan %d Register Symbolic Node Name accepted", chan); } else { isp_prt(isp, ISP_LOGWARN, "Chan %d Register Symbolic Node Name: 0x%x", chan, ct->ct_cmd_resp); return (-1); } return (0); } static uint16_t isp_next_handle(ispsoftc_t *isp, uint16_t *ohp) { fcparam *fcp; int i, chan, wrap; uint16_t handle, minh, maxh; handle = *ohp; if (ISP_CAP_2KLOGIN(isp)) { minh = 0; maxh = NPH_RESERVED - 1; } else { minh = SNS_ID + 1; maxh = NPH_MAX - 1; } wrap = 0; next: if (handle == NIL_HANDLE) { handle = minh; } else { handle++; if (handle > maxh) { if (++wrap >= 2) { isp_prt(isp, ISP_LOGERR, "Out of port handles!"); return (NIL_HANDLE); } handle = minh; } } for (chan = 0; chan < isp->isp_nchan; chan++) { fcp = FCPARAM(isp, chan); if (fcp->role == ISP_ROLE_NONE) continue; for (i = 0; i < MAX_FC_TARG; i++) { if (fcp->portdb[i].state != FC_PORTDB_STATE_NIL && fcp->portdb[i].handle == handle) goto next; } } *ohp = handle; return (handle); } /* * Start a command. Locking is assumed done in the caller. */ int isp_start(XS_T *xs) { ispsoftc_t *isp; uint32_t cdblen; uint8_t local[QENTRY_LEN]; ispreq_t *reqp; void *cdbp, *qep; uint16_t *tptr; fcportdb_t *lp; int target, dmaresult; XS_INITERR(xs); isp = XS_ISP(xs); /* * Check command CDB length, etc.. We really are limited to 16 bytes * for Fibre Channel, but can do up to 44 bytes in parallel SCSI, * but probably only if we're running fairly new firmware (we'll * let the old f/w choke on an extended command queue entry). */ if (XS_CDBLEN(xs) > (IS_FC(isp)? 16 : 44) || XS_CDBLEN(xs) == 0) { isp_prt(isp, ISP_LOGERR, "unsupported cdb length (%d, CDB[0]=0x%x)", XS_CDBLEN(xs), XS_CDBP(xs)[0] & 0xff); XS_SETERR(xs, HBA_REQINVAL); return (CMD_COMPLETE); } /* * Translate the target to device handle as appropriate, checking * for correct device state as well. */ target = XS_TGT(xs); if (IS_FC(isp)) { fcparam *fcp = FCPARAM(isp, XS_CHANNEL(xs)); if ((fcp->role & ISP_ROLE_INITIATOR) == 0) { isp_prt(isp, ISP_LOG_WARN1, "%d.%d.%jx I am not an initiator", XS_CHANNEL(xs), target, (uintmax_t)XS_LUN(xs)); XS_SETERR(xs, HBA_SELTIMEOUT); return (CMD_COMPLETE); } if (isp->isp_state != ISP_RUNSTATE) { isp_prt(isp, ISP_LOGERR, "Adapter not at RUNSTATE"); XS_SETERR(xs, HBA_BOTCH); return (CMD_COMPLETE); } isp_prt(isp, ISP_LOGDEBUG2, "XS_TGT(xs)=%d", target); lp = &fcp->portdb[target]; if (target < 0 || target >= MAX_FC_TARG || lp->is_target == 0) { XS_SETERR(xs, HBA_SELTIMEOUT); return (CMD_COMPLETE); } if (fcp->isp_loopstate != LOOP_READY) { isp_prt(isp, ISP_LOGDEBUG1, "%d.%d.%jx loop is not ready", XS_CHANNEL(xs), target, (uintmax_t)XS_LUN(xs)); return (CMD_RQLATER); } if (lp->state == FC_PORTDB_STATE_ZOMBIE) { isp_prt(isp, ISP_LOGDEBUG1, "%d.%d.%jx target zombie", XS_CHANNEL(xs), target, (uintmax_t)XS_LUN(xs)); return (CMD_RQLATER); } if (lp->state != FC_PORTDB_STATE_VALID) { isp_prt(isp, ISP_LOGDEBUG1, "%d.%d.%jx bad db port state 0x%x", XS_CHANNEL(xs), target, (uintmax_t)XS_LUN(xs), lp->state); XS_SETERR(xs, HBA_SELTIMEOUT); return (CMD_COMPLETE); } } else { sdparam *sdp = SDPARAM(isp, XS_CHANNEL(xs)); if (isp->isp_state != ISP_RUNSTATE) { isp_prt(isp, ISP_LOGERR, "Adapter not at RUNSTATE"); XS_SETERR(xs, HBA_BOTCH); return (CMD_COMPLETE); } if (sdp->update) { isp_spi_update(isp, XS_CHANNEL(xs)); } lp = NULL; } start_again: qep = isp_getrqentry(isp); if (qep == NULL) { isp_prt(isp, ISP_LOG_WARN1, "Request Queue Overflow"); XS_SETERR(xs, HBA_BOTCH); return (CMD_EAGAIN); } XS_SETERR(xs, HBA_NOERROR); /* * Now see if we need to synchronize the ISP with respect to anything. * We do dual duty here (cough) for synchronizing for buses other * than which we got here to send a command to. */ reqp = (ispreq_t *) local; ISP_MEMZERO(local, QENTRY_LEN); if (ISP_TST_SENDMARKER(isp, XS_CHANNEL(xs))) { if (IS_24XX(isp)) { isp_marker_24xx_t *m = (isp_marker_24xx_t *) reqp; m->mrk_header.rqs_entry_count = 1; m->mrk_header.rqs_entry_type = RQSTYPE_MARKER; m->mrk_modifier = SYNC_ALL; m->mrk_vphdl = XS_CHANNEL(xs); isp_put_marker_24xx(isp, m, qep); } else { isp_marker_t *m = (isp_marker_t *) reqp; m->mrk_header.rqs_entry_count = 1; m->mrk_header.rqs_entry_type = RQSTYPE_MARKER; m->mrk_target = (XS_CHANNEL(xs) << 7); /* bus # */ m->mrk_modifier = SYNC_ALL; isp_put_marker(isp, m, qep); } ISP_SYNC_REQUEST(isp); ISP_SET_SENDMARKER(isp, XS_CHANNEL(xs), 0); goto start_again; } reqp->req_header.rqs_entry_count = 1; /* * Select and install Header Code. * Note that it might be overridden before going out * if we're on a 64 bit platform. The lower level * code (isp_send_cmd) will select the appropriate * 64 bit variant if it needs to. */ if (IS_24XX(isp)) { reqp->req_header.rqs_entry_type = RQSTYPE_T7RQS; } else if (IS_FC(isp)) { reqp->req_header.rqs_entry_type = RQSTYPE_T2RQS; } else { if (XS_CDBLEN(xs) > 12) { reqp->req_header.rqs_entry_type = RQSTYPE_CMDONLY; } else { reqp->req_header.rqs_entry_type = RQSTYPE_REQUEST; } } /* * Set task attributes */ if (IS_24XX(isp)) { int ttype; if (XS_TAG_P(xs)) { ttype = XS_TAG_TYPE(xs); } else { ttype = REQFLAG_STAG; } if (ttype == REQFLAG_OTAG) { ttype = FCP_CMND_TASK_ATTR_ORDERED; } else if (ttype == REQFLAG_HTAG) { ttype = FCP_CMND_TASK_ATTR_HEAD; } else { ttype = FCP_CMND_TASK_ATTR_SIMPLE; } ((ispreqt7_t *)reqp)->req_task_attribute = ttype; } else if (IS_FC(isp)) { /* * See comment in isp_intr_respq */ /* XS_SET_RESID(xs, 0); */ /* * Fibre Channel always requires some kind of tag. * The Qlogic drivers seem be happy not to use a tag, * but this breaks for some devices (IBM drives). */ if (XS_TAG_P(xs)) { ((ispreqt2_t *)reqp)->req_flags = XS_TAG_TYPE(xs); } else { ((ispreqt2_t *)reqp)->req_flags = REQFLAG_STAG; } } else { sdparam *sdp = SDPARAM(isp, XS_CHANNEL(xs)); if ((sdp->isp_devparam[target].actv_flags & DPARM_TQING) && XS_TAG_P(xs)) { reqp->req_flags = XS_TAG_TYPE(xs); } } /* * NB: we do not support long CDBs (yet) */ cdblen = XS_CDBLEN(xs); if (IS_SCSI(isp)) { if (cdblen > sizeof (reqp->req_cdb)) { isp_prt(isp, ISP_LOGERR, "Command Length %u too long for this chip", cdblen); XS_SETERR(xs, HBA_REQINVAL); return (CMD_COMPLETE); } reqp->req_target = target | (XS_CHANNEL(xs) << 7); reqp->req_lun_trn = XS_LUN(xs); reqp->req_cdblen = cdblen; tptr = &reqp->req_time; cdbp = reqp->req_cdb; } else if (IS_24XX(isp)) { ispreqt7_t *t7 = (ispreqt7_t *)local; if (cdblen > sizeof (t7->req_cdb)) { isp_prt(isp, ISP_LOGERR, "Command Length %u too long for this chip", cdblen); XS_SETERR(xs, HBA_REQINVAL); return (CMD_COMPLETE); } t7->req_nphdl = lp->handle; t7->req_tidlo = lp->portid; t7->req_tidhi = lp->portid >> 16; t7->req_vpidx = ISP_GET_VPIDX(isp, XS_CHANNEL(xs)); be64enc(t7->req_lun, CAM_EXTLUN_BYTE_SWIZZLE(XS_LUN(xs))); if (FCPARAM(isp, XS_CHANNEL(xs))->fctape_enabled && (lp->prli_word3 & PRLI_WD3_RETRY)) { if (FCP_NEXT_CRN(isp, &t7->req_crn, xs)) { isp_prt(isp, ISP_LOG_WARN1, "%d.%d.%jx cannot generate next CRN", XS_CHANNEL(xs), target, (uintmax_t)XS_LUN(xs)); XS_SETERR(xs, HBA_BOTCH); return (CMD_EAGAIN); } } tptr = &t7->req_time; cdbp = t7->req_cdb; } else { ispreqt2_t *t2 = (ispreqt2_t *)local; if (cdblen > sizeof t2->req_cdb) { isp_prt(isp, ISP_LOGERR, "Command Length %u too long for this chip", cdblen); XS_SETERR(xs, HBA_REQINVAL); return (CMD_COMPLETE); } if (FCPARAM(isp, XS_CHANNEL(xs))->fctape_enabled && (lp->prli_word3 & PRLI_WD3_RETRY)) { if (FCP_NEXT_CRN(isp, &t2->req_crn, xs)) { isp_prt(isp, ISP_LOG_WARN1, "%d.%d.%jx cannot generate next CRN", XS_CHANNEL(xs), target, (uintmax_t)XS_LUN(xs)); XS_SETERR(xs, HBA_BOTCH); return (CMD_EAGAIN); } } if (ISP_CAP_2KLOGIN(isp)) { ispreqt2e_t *t2e = (ispreqt2e_t *)local; t2e->req_target = lp->handle; t2e->req_scclun = XS_LUN(xs); tptr = &t2e->req_time; cdbp = t2e->req_cdb; } else if (ISP_CAP_SCCFW(isp)) { t2->req_target = lp->handle; t2->req_scclun = XS_LUN(xs); tptr = &t2->req_time; cdbp = t2->req_cdb; } else { t2->req_target = lp->handle; t2->req_lun_trn = XS_LUN(xs); tptr = &t2->req_time; cdbp = t2->req_cdb; } } *tptr = XS_TIME(xs); ISP_MEMCPY(cdbp, XS_CDBP(xs), cdblen); /* Whew. Thankfully the same for type 7 requests */ reqp->req_handle = isp_allocate_handle(isp, xs, ISP_HANDLE_INITIATOR); if (reqp->req_handle == 0) { isp_prt(isp, ISP_LOG_WARN1, "out of xflist pointers"); XS_SETERR(xs, HBA_BOTCH); return (CMD_EAGAIN); } /* * Set up DMA and/or do any platform dependent swizzling of the request entry * so that the Qlogic F/W understands what is being asked of it. * * The callee is responsible for adding all requests at this point. */ dmaresult = ISP_DMASETUP(isp, xs, reqp); if (dmaresult != CMD_QUEUED) { isp_destroy_handle(isp, reqp->req_handle); /* * dmasetup sets actual error in packet, and * return what we were given to return. */ return (dmaresult); } isp_xs_prt(isp, xs, ISP_LOGDEBUG0, "START cmd cdb[0]=0x%x datalen %ld", XS_CDBP(xs)[0], (long) XS_XFRLEN(xs)); return (CMD_QUEUED); } /* * isp control * Locks (ints blocked) assumed held. */ int isp_control(ispsoftc_t *isp, ispctl_t ctl, ...) { XS_T *xs; mbreg_t *mbr, mbs; int chan, tgt; uint32_t handle; va_list ap; switch (ctl) { case ISPCTL_RESET_BUS: /* * Issue a bus reset. */ if (IS_24XX(isp)) { isp_prt(isp, ISP_LOGERR, "BUS RESET NOT IMPLEMENTED"); break; } else if (IS_FC(isp)) { mbs.param[1] = 10; chan = 0; } else { va_start(ap, ctl); chan = va_arg(ap, int); va_end(ap); mbs.param[1] = SDPARAM(isp, chan)->isp_bus_reset_delay; if (mbs.param[1] < 2) { mbs.param[1] = 2; } mbs.param[2] = chan; } MBSINIT(&mbs, MBOX_BUS_RESET, MBLOGALL, 0); ISP_SET_SENDMARKER(isp, chan, 1); isp_mboxcmd(isp, &mbs); if (mbs.param[0] != MBOX_COMMAND_COMPLETE) { break; } isp_prt(isp, ISP_LOGINFO, "driver initiated bus reset of bus %d", chan); return (0); case ISPCTL_RESET_DEV: va_start(ap, ctl); chan = va_arg(ap, int); tgt = va_arg(ap, int); va_end(ap); if (IS_24XX(isp)) { uint8_t local[QENTRY_LEN]; isp24xx_tmf_t *tmf; isp24xx_statusreq_t *sp; fcparam *fcp = FCPARAM(isp, chan); fcportdb_t *lp; if (tgt < 0 || tgt >= MAX_FC_TARG) { isp_prt(isp, ISP_LOGWARN, "Chan %d trying to reset bad target %d", chan, tgt); break; } lp = &fcp->portdb[tgt]; if (lp->is_target == 0 || lp->state != FC_PORTDB_STATE_VALID) { isp_prt(isp, ISP_LOGWARN, "Chan %d abort of no longer valid target %d", chan, tgt); break; } tmf = (isp24xx_tmf_t *) local; ISP_MEMZERO(tmf, QENTRY_LEN); tmf->tmf_header.rqs_entry_type = RQSTYPE_TSK_MGMT; tmf->tmf_header.rqs_entry_count = 1; tmf->tmf_nphdl = lp->handle; tmf->tmf_delay = 2; tmf->tmf_timeout = 4; tmf->tmf_flags = ISP24XX_TMF_TARGET_RESET; tmf->tmf_tidlo = lp->portid; tmf->tmf_tidhi = lp->portid >> 16; tmf->tmf_vpidx = ISP_GET_VPIDX(isp, chan); isp_put_24xx_tmf(isp, tmf, isp->isp_iocb); if (isp->isp_dblev & ISP_LOGDEBUG1) isp_print_bytes(isp, "TMF IOCB request", QENTRY_LEN, isp->isp_iocb); MEMORYBARRIER(isp, SYNC_IFORDEV, 0, QENTRY_LEN, chan); fcp->sendmarker = 1; isp_prt(isp, ISP_LOGALL, "Chan %d Reset N-Port Handle 0x%04x @ Port 0x%06x", chan, lp->handle, lp->portid); MBSINIT(&mbs, MBOX_EXEC_COMMAND_IOCB_A64, MBLOGALL, MBCMD_DEFAULT_TIMEOUT + tmf->tmf_timeout * 1000000); mbs.param[1] = QENTRY_LEN; mbs.param[2] = DMA_WD1(isp->isp_iocb_dma); mbs.param[3] = DMA_WD0(isp->isp_iocb_dma); mbs.param[6] = DMA_WD3(isp->isp_iocb_dma); mbs.param[7] = DMA_WD2(isp->isp_iocb_dma); isp_mboxcmd(isp, &mbs); if (mbs.param[0] != MBOX_COMMAND_COMPLETE) break; MEMORYBARRIER(isp, SYNC_IFORCPU, QENTRY_LEN, QENTRY_LEN, chan); if (isp->isp_dblev & ISP_LOGDEBUG1) isp_print_bytes(isp, "TMF IOCB response", QENTRY_LEN, &((isp24xx_statusreq_t *)isp->isp_iocb)[1]); sp = (isp24xx_statusreq_t *) local; isp_get_24xx_response(isp, &((isp24xx_statusreq_t *)isp->isp_iocb)[1], sp); if (sp->req_completion_status == 0) { return (0); } isp_prt(isp, ISP_LOGWARN, "Chan %d reset of target %d returned 0x%x", chan, tgt, sp->req_completion_status); break; } else if (IS_FC(isp)) { if (ISP_CAP_2KLOGIN(isp)) { mbs.param[1] = tgt; mbs.ibits = (1 << 10); } else { mbs.param[1] = (tgt << 8); } } else { mbs.param[1] = (chan << 15) | (tgt << 8); } MBSINIT(&mbs, MBOX_ABORT_TARGET, MBLOGALL, 0); mbs.param[2] = 3; /* 'delay', in seconds */ isp_mboxcmd(isp, &mbs); if (mbs.param[0] != MBOX_COMMAND_COMPLETE) { break; } isp_prt(isp, ISP_LOGINFO, "Target %d on Bus %d Reset Succeeded", tgt, chan); ISP_SET_SENDMARKER(isp, chan, 1); return (0); case ISPCTL_ABORT_CMD: va_start(ap, ctl); xs = va_arg(ap, XS_T *); va_end(ap); tgt = XS_TGT(xs); chan = XS_CHANNEL(xs); handle = isp_find_handle(isp, xs); if (handle == 0) { isp_prt(isp, ISP_LOGWARN, "cannot find handle for command to abort"); break; } if (IS_24XX(isp)) { isp24xx_abrt_t local, *ab = &local; fcparam *fcp; fcportdb_t *lp; fcp = FCPARAM(isp, chan); if (tgt < 0 || tgt >= MAX_FC_TARG) { isp_prt(isp, ISP_LOGWARN, "Chan %d trying to abort bad target %d", chan, tgt); break; } lp = &fcp->portdb[tgt]; if (lp->is_target == 0 || lp->state != FC_PORTDB_STATE_VALID) { isp_prt(isp, ISP_LOGWARN, "Chan %d abort of no longer valid target %d", chan, tgt); break; } isp_prt(isp, ISP_LOGALL, "Chan %d Abort Cmd for N-Port 0x%04x @ Port 0x%06x", chan, lp->handle, lp->portid); ISP_MEMZERO(ab, QENTRY_LEN); ab->abrt_header.rqs_entry_type = RQSTYPE_ABORT_IO; ab->abrt_header.rqs_entry_count = 1; ab->abrt_handle = lp->handle; ab->abrt_cmd_handle = handle; ab->abrt_tidlo = lp->portid; ab->abrt_tidhi = lp->portid >> 16; ab->abrt_vpidx = ISP_GET_VPIDX(isp, chan); isp_put_24xx_abrt(isp, ab, isp->isp_iocb); if (isp->isp_dblev & ISP_LOGDEBUG1) isp_print_bytes(isp, "AB IOCB quest", QENTRY_LEN, isp->isp_iocb); MEMORYBARRIER(isp, SYNC_IFORDEV, 0, 2 * QENTRY_LEN, chan); ISP_MEMZERO(&mbs, sizeof (mbs)); MBSINIT(&mbs, MBOX_EXEC_COMMAND_IOCB_A64, MBLOGALL, 5000000); mbs.param[1] = QENTRY_LEN; mbs.param[2] = DMA_WD1(isp->isp_iocb_dma); mbs.param[3] = DMA_WD0(isp->isp_iocb_dma); mbs.param[6] = DMA_WD3(isp->isp_iocb_dma); mbs.param[7] = DMA_WD2(isp->isp_iocb_dma); isp_mboxcmd(isp, &mbs); if (mbs.param[0] != MBOX_COMMAND_COMPLETE) break; MEMORYBARRIER(isp, SYNC_IFORCPU, QENTRY_LEN, QENTRY_LEN, chan); if (isp->isp_dblev & ISP_LOGDEBUG1) isp_print_bytes(isp, "AB IOCB response", QENTRY_LEN, &((isp24xx_abrt_t *)isp->isp_iocb)[1]); isp_get_24xx_abrt(isp, &((isp24xx_abrt_t *)isp->isp_iocb)[1], ab); if (ab->abrt_nphdl == ISP24XX_ABRT_OKAY) { return (0); } isp_prt(isp, ISP_LOGWARN, "Chan %d handle %d abort returned 0x%x", chan, tgt, ab->abrt_nphdl); break; } else if (IS_FC(isp)) { if (ISP_CAP_SCCFW(isp)) { if (ISP_CAP_2KLOGIN(isp)) { mbs.param[1] = tgt; } else { mbs.param[1] = tgt << 8; } mbs.param[6] = XS_LUN(xs); } else { mbs.param[1] = tgt << 8 | XS_LUN(xs); } } else { mbs.param[1] = (chan << 15) | (tgt << 8) | XS_LUN(xs); } MBSINIT(&mbs, MBOX_ABORT, MBLOGALL & ~MBLOGMASK(MBOX_COMMAND_ERROR), 0); mbs.param[2] = handle; isp_mboxcmd(isp, &mbs); if (mbs.param[0] != MBOX_COMMAND_COMPLETE) { break; } return (0); case ISPCTL_UPDATE_PARAMS: va_start(ap, ctl); chan = va_arg(ap, int); va_end(ap); isp_spi_update(isp, chan); return (0); case ISPCTL_FCLINK_TEST: if (IS_FC(isp)) { int usdelay; va_start(ap, ctl); chan = va_arg(ap, int); usdelay = va_arg(ap, int); va_end(ap); if (usdelay == 0) { usdelay = 250000; } return (isp_fclink_test(isp, chan, usdelay)); } break; case ISPCTL_SCAN_FABRIC: if (IS_FC(isp)) { va_start(ap, ctl); chan = va_arg(ap, int); va_end(ap); return (isp_scan_fabric(isp, chan)); } break; case ISPCTL_SCAN_LOOP: if (IS_FC(isp)) { va_start(ap, ctl); chan = va_arg(ap, int); va_end(ap); return (isp_scan_loop(isp, chan)); } break; case ISPCTL_PDB_SYNC: if (IS_FC(isp)) { va_start(ap, ctl); chan = va_arg(ap, int); va_end(ap); return (isp_pdb_sync(isp, chan)); } break; case ISPCTL_SEND_LIP: if (IS_FC(isp) && !IS_24XX(isp)) { MBSINIT(&mbs, MBOX_INIT_LIP, MBLOGALL, 0); if (ISP_CAP_2KLOGIN(isp)) { mbs.ibits = (1 << 10); } isp_mboxcmd(isp, &mbs); if (mbs.param[0] == MBOX_COMMAND_COMPLETE) { return (0); } } break; case ISPCTL_GET_PDB: if (IS_FC(isp)) { isp_pdb_t *pdb; va_start(ap, ctl); chan = va_arg(ap, int); tgt = va_arg(ap, int); pdb = va_arg(ap, isp_pdb_t *); va_end(ap); return (isp_getpdb(isp, chan, tgt, pdb)); } break; case ISPCTL_GET_NAMES: { uint64_t *wwnn, *wwnp; va_start(ap, ctl); chan = va_arg(ap, int); tgt = va_arg(ap, int); wwnn = va_arg(ap, uint64_t *); wwnp = va_arg(ap, uint64_t *); va_end(ap); if (wwnn == NULL && wwnp == NULL) { break; } if (wwnn) { *wwnn = isp_get_wwn(isp, chan, tgt, 1); if (*wwnn == INI_NONE) { break; } } if (wwnp) { *wwnp = isp_get_wwn(isp, chan, tgt, 0); if (*wwnp == INI_NONE) { break; } } return (0); } case ISPCTL_RUN_MBOXCMD: { va_start(ap, ctl); mbr = va_arg(ap, mbreg_t *); va_end(ap); isp_mboxcmd(isp, mbr); return (0); } case ISPCTL_PLOGX: { isp_plcmd_t *p; int r; va_start(ap, ctl); p = va_arg(ap, isp_plcmd_t *); va_end(ap); if ((p->flags & PLOGX_FLG_CMD_MASK) != PLOGX_FLG_CMD_PLOGI || (p->handle != NIL_HANDLE)) { return (isp_plogx(isp, p->channel, p->handle, p->portid, p->flags)); } do { isp_next_handle(isp, &p->handle); r = isp_plogx(isp, p->channel, p->handle, p->portid, p->flags); if ((r & 0xffff) == MBOX_PORT_ID_USED) { p->handle = r >> 16; r = 0; break; } } while ((r & 0xffff) == MBOX_LOOP_ID_USED); return (r); } case ISPCTL_CHANGE_ROLE: if (IS_FC(isp)) { int role, r; va_start(ap, ctl); chan = va_arg(ap, int); role = va_arg(ap, int); va_end(ap); r = isp_fc_change_role(isp, chan, role); return (r); } break; default: isp_prt(isp, ISP_LOGERR, "Unknown Control Opcode 0x%x", ctl); break; } return (-1); } /* * Interrupt Service Routine(s). * * External (OS) framework has done the appropriate locking, * and the locking will be held throughout this function. */ #ifdef ISP_TARGET_MODE void isp_intr_atioq(ispsoftc_t *isp) { uint8_t qe[QENTRY_LEN]; isphdr_t *hp; void *addr; uint32_t iptr, optr, oop; iptr = ISP_READ(isp, BIU2400_ATIO_RSPINP); optr = isp->isp_atioodx; while (optr != iptr) { oop = optr; MEMORYBARRIER(isp, SYNC_ATIOQ, oop, QENTRY_LEN, -1); addr = ISP_QUEUE_ENTRY(isp->isp_atioq, oop); isp_get_hdr(isp, addr, (isphdr_t *)qe); hp = (isphdr_t *)qe; switch (hp->rqs_entry_type) { case RQSTYPE_NOTIFY: case RQSTYPE_ATIO: (void) isp_target_notify(isp, addr, &oop); break; default: isp_print_qentry(isp, "?ATIOQ entry?", oop, addr); break; } optr = ISP_NXT_QENTRY(oop, RESULT_QUEUE_LEN(isp)); } if (isp->isp_atioodx != optr) { ISP_WRITE(isp, BIU2400_ATIO_RSPOUTP, optr); isp->isp_atioodx = optr; } } #endif void isp_intr_async(ispsoftc_t *isp, uint16_t event) { if (IS_FC(isp)) isp_parse_async_fc(isp, event); else isp_parse_async(isp, event); } void isp_intr_mbox(ispsoftc_t *isp, uint16_t mbox0) { int i, obits; if (!isp->isp_mboxbsy) { isp_prt(isp, ISP_LOGWARN, "mailbox 0x%x with no waiters", mbox0); return; } obits = isp->isp_obits; isp->isp_mboxtmp[0] = mbox0; for (i = 1; i < ISP_NMBOX(isp); i++) { if ((obits & (1 << i)) == 0) continue; isp->isp_mboxtmp[i] = ISP_READ(isp, MBOX_OFF(i)); } MBOX_NOTIFY_COMPLETE(isp); } void isp_intr_respq(ispsoftc_t *isp) { XS_T *xs, *cont_xs; uint8_t qe[QENTRY_LEN]; ispstatusreq_t *sp = (ispstatusreq_t *)qe; isp24xx_statusreq_t *sp2 = (isp24xx_statusreq_t *)qe; isphdr_t *hp; uint8_t *resp, *snsp; int buddaboom, completion_status, cont = 0, etype, i; int req_status_flags, req_state_flags, scsi_status; uint32_t iptr, junk, cptr, optr, rlen, slen, sptr, totslen, resid; /* * We can't be getting this now. */ if (isp->isp_state != ISP_RUNSTATE) { isp_prt(isp, ISP_LOGINFO, "respq interrupt when not ready"); return; } iptr = ISP_READ(isp, isp->isp_respinrp); /* Debounce the 2300 if revision less than 2. */ if (IS_2100(isp) || (IS_2300(isp) && isp->isp_revision < 2)) { do { junk = iptr; iptr = ISP_READ(isp, isp->isp_respinrp); } while (junk != iptr); } isp->isp_residx = iptr; optr = isp->isp_resodx; while (optr != iptr) { sptr = cptr = optr; hp = (isphdr_t *) ISP_QUEUE_ENTRY(isp->isp_result, cptr); optr = ISP_NXT_QENTRY(optr, RESULT_QUEUE_LEN(isp)); /* * Synchronize our view of this response queue entry. */ MEMORYBARRIER(isp, SYNC_RESULT, cptr, QENTRY_LEN, -1); if (isp->isp_dblev & ISP_LOGDEBUG1) isp_print_qentry(isp, "Response Queue Entry", cptr, hp); isp_get_hdr(isp, hp, &sp->req_header); etype = sp->req_header.rqs_entry_type; /* We expected Status Continuation, but got different IOCB. */ if (cont > 0 && etype != RQSTYPE_STATUS_CONT) { cont = 0; isp_done(cont_xs); } if (IS_24XX(isp) && etype == RQSTYPE_RESPONSE) { isp_get_24xx_response(isp, (isp24xx_statusreq_t *)hp, sp2); scsi_status = sp2->req_scsi_status; completion_status = sp2->req_completion_status; req_status_flags = 0; if ((scsi_status & 0xff) != 0) req_state_flags = RQSF_GOT_STATUS; else req_state_flags = 0; resid = sp2->req_resid; } else if (etype == RQSTYPE_RESPONSE) { isp_get_response(isp, (ispstatusreq_t *) hp, sp); scsi_status = sp->req_scsi_status; completion_status = sp->req_completion_status; req_status_flags = sp->req_status_flags; req_state_flags = sp->req_state_flags; resid = sp->req_resid; } else if (etype == RQSTYPE_RIO1) { isp_rio1_t *rio = (isp_rio1_t *) qe; isp_get_rio1(isp, (isp_rio1_t *) hp, rio); for (i = 0; i < rio->req_header.rqs_seqno; i++) { isp_fastpost_complete(isp, rio->req_handles[i]); } ISP_MEMZERO(hp, QENTRY_LEN); /* PERF */ continue; } else if (etype == RQSTYPE_RIO2) { isp_prt(isp, ISP_LOGERR, "dropping RIO2 response"); ISP_MEMZERO(hp, QENTRY_LEN); /* PERF */ continue; } else if (etype == RQSTYPE_STATUS_CONT) { ispstatus_cont_t *scp = (ispstatus_cont_t *)qe; isp_get_cont_response(isp, (ispstatus_cont_t *)hp, scp); if (cont > 0) { i = min(cont, sizeof(scp->req_sense_data)); XS_SENSE_APPEND(cont_xs, scp->req_sense_data, i); cont -= i; if (cont == 0) { isp_done(cont_xs); } else { isp_prt(isp, ISP_LOGDEBUG0|ISP_LOG_CWARN, "Expecting Status Continuations for %u bytes", cont); } } else { isp_prt(isp, ISP_LOG_WARN1, "Ignored Continuation Response"); } ISP_MEMZERO(hp, QENTRY_LEN); /* PERF */ continue; } else if (isp_handle_other_response(isp, etype, hp, &cptr)) { /* More then one IOCB could be consumed. */ while (sptr != cptr) { ISP_MEMZERO(hp, QENTRY_LEN); /* PERF */ sptr = ISP_NXT_QENTRY(sptr, RESULT_QUEUE_LEN(isp)); hp = (isphdr_t *)ISP_QUEUE_ENTRY(isp->isp_result, sptr); } ISP_MEMZERO(hp, QENTRY_LEN); /* PERF */ optr = ISP_NXT_QENTRY(cptr, RESULT_QUEUE_LEN(isp)); continue; } else { /* We don't know what was this -- log and skip. */ isp_prt(isp, ISP_LOGERR, notresp, etype, cptr, optr); ISP_MEMZERO(hp, QENTRY_LEN); /* PERF */ continue; } buddaboom = 0; if (sp->req_header.rqs_flags & RQSFLAG_MASK) { if (sp->req_header.rqs_flags & RQSFLAG_CONTINUATION) { isp_print_qentry(isp, "unexpected continuation segment", cptr, hp); continue; } if (sp->req_header.rqs_flags & RQSFLAG_FULL) { isp_prt(isp, ISP_LOG_WARN1, "internal queues full"); /* * We'll synthesize a QUEUE FULL message below. */ } if (sp->req_header.rqs_flags & RQSFLAG_BADHEADER) { isp_print_qentry(isp, "bad header flag", cptr, hp); buddaboom++; } if (sp->req_header.rqs_flags & RQSFLAG_BADPACKET) { isp_print_qentry(isp, "bad request packet", cptr, hp); buddaboom++; } if (sp->req_header.rqs_flags & RQSFLAG_BADCOUNT) { isp_print_qentry(isp, "invalid entry count", cptr, hp); buddaboom++; } if (sp->req_header.rqs_flags & RQSFLAG_BADORDER) { isp_print_qentry(isp, "invalid IOCB ordering", cptr, hp); continue; } } xs = isp_find_xs(isp, sp->req_handle); if (xs == NULL) { uint8_t ts = completion_status & 0xff; /* * Only whine if this isn't the expected fallout of * aborting the command or resetting the target. */ if (etype != RQSTYPE_RESPONSE) { isp_prt(isp, ISP_LOGERR, "cannot find handle 0x%x (type 0x%x)", sp->req_handle, etype); } else if (ts != RQCS_ABORTED && ts != RQCS_RESET_OCCURRED) { isp_prt(isp, ISP_LOGERR, "cannot find handle 0x%x (status 0x%x)", sp->req_handle, ts); } ISP_MEMZERO(hp, QENTRY_LEN); /* PERF */ continue; } if (req_status_flags & RQSTF_BUS_RESET) { isp_prt(isp, ISP_LOG_WARN1, "%d.%d.%jx bus was reset", XS_CHANNEL(xs), XS_TGT(xs), (uintmax_t)XS_LUN(xs)); XS_SETERR(xs, HBA_BUSRESET); ISP_SET_SENDMARKER(isp, XS_CHANNEL(xs), 1); } if (buddaboom) { isp_prt(isp, ISP_LOG_WARN1, "%d.%d.%jx buddaboom", XS_CHANNEL(xs), XS_TGT(xs), (uintmax_t)XS_LUN(xs)); XS_SETERR(xs, HBA_BOTCH); } resp = snsp = NULL; rlen = slen = totslen = 0; if (IS_24XX(isp) && (scsi_status & (RQCS_RV|RQCS_SV)) != 0) { resp = sp2->req_rsp_sense; rlen = sp2->req_response_len; } else if (IS_FC(isp) && (scsi_status & RQCS_RV) != 0) { resp = sp->req_response; rlen = sp->req_response_len; } if (IS_FC(isp) && (scsi_status & RQCS_SV) != 0) { /* * Fibre Channel F/W doesn't say we got status * if there's Sense Data instead. I guess they * think it goes w/o saying. */ req_state_flags |= RQSF_GOT_STATUS|RQSF_GOT_SENSE; if (IS_24XX(isp)) { snsp = sp2->req_rsp_sense; snsp += rlen; totslen = sp2->req_sense_len; slen = sizeof(sp2->req_rsp_sense) - rlen; } else { snsp = sp->req_sense_data; totslen = sp->req_sense_len; slen = sizeof(sp->req_sense_data); } } else if (IS_SCSI(isp) && (req_state_flags & RQSF_GOT_SENSE)) { snsp = sp->req_sense_data; totslen = sp->req_sense_len; slen = sizeof (sp->req_sense_data); } if (slen > totslen) slen = totslen; if (req_state_flags & RQSF_GOT_STATUS) *XS_STSP(xs) = scsi_status & 0xff; if (rlen >= 4 && resp[FCP_RSPNS_CODE_OFFSET] != 0) { const char *ptr; char lb[64]; const char *rnames[10] = { "Task Management function complete", "FCP_DATA length different than FCP_BURST_LEN", "FCP_CMND fields invalid", "FCP_DATA parameter mismatch with FCP_DATA_RO", "Task Management function rejected", "Task Management function failed", NULL, NULL, "Task Management function succeeded", "Task Management function incorrect logical unit number", }; uint8_t code = resp[FCP_RSPNS_CODE_OFFSET]; if (code >= 10 || rnames[code] == NULL) { ISP_SNPRINTF(lb, sizeof(lb), "Unknown FCP Response Code 0x%x", code); ptr = lb; } else { ptr = rnames[code]; } isp_xs_prt(isp, xs, ISP_LOGWARN, "FCP RESPONSE, LENGTH %u: %s CDB0=0x%02x", rlen, ptr, XS_CDBP(xs)[0] & 0xff); if (code != 0 && code != 8) XS_SETERR(xs, HBA_BOTCH); } if (IS_24XX(isp)) isp_parse_status_24xx(isp, sp2, xs, &resid); else isp_parse_status(isp, sp, xs, &resid); if ((XS_NOERR(xs) || XS_ERR(xs) == HBA_NOERROR) && (*XS_STSP(xs) == SCSI_BUSY)) XS_SETERR(xs, HBA_TGTBSY); if (IS_SCSI(isp)) { XS_SET_RESID(xs, resid); /* * A new synchronous rate was negotiated for * this target. Mark state such that we'll go * look up that which has changed later. */ if (req_status_flags & RQSTF_NEGOTIATION) { int t = XS_TGT(xs); sdparam *sdp = SDPARAM(isp, XS_CHANNEL(xs)); sdp->isp_devparam[t].dev_refresh = 1; sdp->update = 1; } } else { if (req_status_flags & RQSF_XFER_COMPLETE) { XS_SET_RESID(xs, 0); } else if (scsi_status & RQCS_RESID) { XS_SET_RESID(xs, resid); } else { XS_SET_RESID(xs, 0); } } if (slen > 0) { XS_SAVE_SENSE(xs, snsp, slen); if (totslen > slen) { cont = totslen - slen; cont_xs = xs; isp_prt(isp, ISP_LOGDEBUG0|ISP_LOG_CWARN, "Expecting Status Continuations for %u bytes", cont); } } isp_prt(isp, ISP_LOGDEBUG2, "asked for %lu got raw resid %lu settled for %lu", (u_long)XS_XFRLEN(xs), (u_long)resid, (u_long)XS_GET_RESID(xs)); if (XS_XFRLEN(xs)) ISP_DMAFREE(isp, xs, sp->req_handle); isp_destroy_handle(isp, sp->req_handle); ISP_MEMZERO(hp, QENTRY_LEN); /* PERF */ /* Complete command if we expect no Status Continuations. */ if (cont == 0) isp_done(xs); } /* We haven't received all Status Continuations, but that is it. */ if (cont > 0) isp_done(cont_xs); /* If we processed any IOCBs, let ISP know about it. */ if (optr != isp->isp_resodx) { ISP_WRITE(isp, isp->isp_respoutrp, optr); isp->isp_resodx = optr; } } /* * Parse an ASYNC mailbox complete */ static void isp_parse_async(ispsoftc_t *isp, uint16_t mbox) { uint32_t h1 = 0, h2 = 0; uint16_t chan = 0; /* * Pick up the channel, but not if this is a ASYNC_RIO32_2, * where Mailboxes 6/7 have the second handle. */ if (mbox != ASYNC_RIO32_2) { if (IS_DUALBUS(isp)) { chan = ISP_READ(isp, OUTMAILBOX6); } } isp_prt(isp, ISP_LOGDEBUG2, "Async Mbox 0x%x", mbox); switch (mbox) { case ASYNC_BUS_RESET: ISP_SET_SENDMARKER(isp, chan, 1); #ifdef ISP_TARGET_MODE isp_target_async(isp, chan, mbox); #endif isp_async(isp, ISPASYNC_BUS_RESET, chan); break; case ASYNC_SYSTEM_ERROR: isp->isp_state = ISP_CRASHED; /* * Were we waiting for a mailbox command to complete? * If so, it's dead, so wake up the waiter. */ if (isp->isp_mboxbsy) { isp->isp_obits = 1; isp->isp_mboxtmp[0] = MBOX_HOST_INTERFACE_ERROR; MBOX_NOTIFY_COMPLETE(isp); } /* * It's up to the handler for isp_async to reinit stuff and * restart the firmware */ isp_async(isp, ISPASYNC_FW_CRASH); break; case ASYNC_RQS_XFER_ERR: isp_prt(isp, ISP_LOGERR, "Request Queue Transfer Error"); break; case ASYNC_RSP_XFER_ERR: isp_prt(isp, ISP_LOGERR, "Response Queue Transfer Error"); break; case ASYNC_QWAKEUP: /* * We've just been notified that the Queue has woken up. * We don't need to be chatty about this- just unlatch things * and move on. */ mbox = ISP_READ(isp, isp->isp_rqstoutrp); break; case ASYNC_TIMEOUT_RESET: isp_prt(isp, ISP_LOGWARN, "timeout initiated SCSI bus reset of chan %d", chan); ISP_SET_SENDMARKER(isp, chan, 1); #ifdef ISP_TARGET_MODE isp_target_async(isp, chan, mbox); #endif break; case ASYNC_DEVICE_RESET: isp_prt(isp, ISP_LOGINFO, "device reset on chan %d", chan); ISP_SET_SENDMARKER(isp, chan, 1); #ifdef ISP_TARGET_MODE isp_target_async(isp, chan, mbox); #endif break; case ASYNC_EXTMSG_UNDERRUN: isp_prt(isp, ISP_LOGWARN, "extended message underrun"); break; case ASYNC_SCAM_INT: isp_prt(isp, ISP_LOGINFO, "SCAM interrupt"); break; case ASYNC_HUNG_SCSI: isp_prt(isp, ISP_LOGERR, "stalled SCSI Bus after DATA Overrun"); /* XXX: Need to issue SCSI reset at this point */ break; case ASYNC_KILLED_BUS: isp_prt(isp, ISP_LOGERR, "SCSI Bus reset after DATA Overrun"); break; case ASYNC_BUS_TRANSIT: mbox = ISP_READ(isp, OUTMAILBOX2); switch (mbox & SXP_PINS_MODE_MASK) { case SXP_PINS_LVD_MODE: isp_prt(isp, ISP_LOGINFO, "Transition to LVD mode"); SDPARAM(isp, chan)->isp_diffmode = 0; SDPARAM(isp, chan)->isp_ultramode = 0; SDPARAM(isp, chan)->isp_lvdmode = 1; break; case SXP_PINS_HVD_MODE: isp_prt(isp, ISP_LOGINFO, "Transition to Differential mode"); SDPARAM(isp, chan)->isp_diffmode = 1; SDPARAM(isp, chan)->isp_ultramode = 0; SDPARAM(isp, chan)->isp_lvdmode = 0; break; case SXP_PINS_SE_MODE: isp_prt(isp, ISP_LOGINFO, "Transition to Single Ended mode"); SDPARAM(isp, chan)->isp_diffmode = 0; SDPARAM(isp, chan)->isp_ultramode = 1; SDPARAM(isp, chan)->isp_lvdmode = 0; break; default: isp_prt(isp, ISP_LOGWARN, "Transition to Unknown Mode 0x%x", mbox); break; } /* * XXX: Set up to renegotiate again! */ /* Can only be for a 1080... */ ISP_SET_SENDMARKER(isp, chan, 1); break; case ASYNC_CMD_CMPLT: case ASYNC_RIO32_1: if (!IS_ULTRA3(isp)) { isp_prt(isp, ISP_LOGERR, "unexpected fast posting completion"); break; } /* FALLTHROUGH */ h1 = (ISP_READ(isp, OUTMAILBOX2) << 16) | ISP_READ(isp, OUTMAILBOX1); break; case ASYNC_RIO32_2: h1 = (ISP_READ(isp, OUTMAILBOX2) << 16) | ISP_READ(isp, OUTMAILBOX1); h2 = (ISP_READ(isp, OUTMAILBOX7) << 16) | ISP_READ(isp, OUTMAILBOX6); break; case ASYNC_RIO16_5: case ASYNC_RIO16_4: case ASYNC_RIO16_3: case ASYNC_RIO16_2: case ASYNC_RIO16_1: isp_prt(isp, ISP_LOGERR, "unexpected 16 bit RIO handle"); break; default: isp_prt(isp, ISP_LOGWARN, "%s: unhandled async code 0x%x", __func__, mbox); break; } if (h1 || h2) { isp_prt(isp, ISP_LOGDEBUG3, "fast post/rio completion of 0x%08x", h1); isp_fastpost_complete(isp, h1); if (h2) { isp_prt(isp, ISP_LOGDEBUG3, "fast post/rio completion of 0x%08x", h2); isp_fastpost_complete(isp, h2); } } } static void isp_parse_async_fc(ispsoftc_t *isp, uint16_t mbox) { fcparam *fcp; uint16_t chan; if (IS_DUALBUS(isp)) { chan = ISP_READ(isp, OUTMAILBOX6); } else { chan = 0; } isp_prt(isp, ISP_LOGDEBUG2, "Async Mbox 0x%x", mbox); switch (mbox) { case ASYNC_SYSTEM_ERROR: isp->isp_state = ISP_CRASHED; FCPARAM(isp, chan)->isp_loopstate = LOOP_NIL; isp_change_fw_state(isp, chan, FW_CONFIG_WAIT); /* * Were we waiting for a mailbox command to complete? * If so, it's dead, so wake up the waiter. */ if (isp->isp_mboxbsy) { isp->isp_obits = 1; isp->isp_mboxtmp[0] = MBOX_HOST_INTERFACE_ERROR; MBOX_NOTIFY_COMPLETE(isp); } /* * It's up to the handler for isp_async to reinit stuff and * restart the firmware */ isp_async(isp, ISPASYNC_FW_CRASH); break; case ASYNC_RQS_XFER_ERR: isp_prt(isp, ISP_LOGERR, "Request Queue Transfer Error"); break; case ASYNC_RSP_XFER_ERR: isp_prt(isp, ISP_LOGERR, "Response Queue Transfer Error"); break; case ASYNC_QWAKEUP: #ifdef ISP_TARGET_MODE if (IS_24XX(isp)) { isp_prt(isp, ISP_LOGERR, "ATIO Queue Transfer Error"); break; } #endif isp_prt(isp, ISP_LOGERR, "%s: unexpected ASYNC_QWAKEUP code", __func__); break; case ASYNC_CMD_CMPLT: isp_fastpost_complete(isp, (ISP_READ(isp, OUTMAILBOX2) << 16) | ISP_READ(isp, OUTMAILBOX1)); break; case ASYNC_RIOZIO_STALL: isp_intr_respq(isp); break; case ASYNC_CTIO_DONE: #ifdef ISP_TARGET_MODE isp_target_async(isp, (ISP_READ(isp, OUTMAILBOX2) << 16) | ISP_READ(isp, OUTMAILBOX1), mbox); #else isp_prt(isp, ISP_LOGWARN, "unexpected ASYNC CTIO done"); #endif break; case ASYNC_LIP_ERROR: case ASYNC_LIP_NOS_OLS_RECV: case ASYNC_LIP_OCCURRED: case ASYNC_PTPMODE: /* * These are broadcast events that have to be sent across * all active channels. */ for (chan = 0; chan < isp->isp_nchan; chan++) { fcp = FCPARAM(isp, chan); int topo = fcp->isp_topo; if (fcp->role == ISP_ROLE_NONE) continue; if (fcp->isp_loopstate > LOOP_HAVE_LINK) fcp->isp_loopstate = LOOP_HAVE_LINK; ISP_SET_SENDMARKER(isp, chan, 1); isp_async(isp, ISPASYNC_LIP, chan); #ifdef ISP_TARGET_MODE isp_target_async(isp, chan, mbox); #endif /* * We've had problems with data corruption occurring on * commands that complete (with no apparent error) after * we receive a LIP. This has been observed mostly on * Local Loop topologies. To be safe, let's just mark * all active initiator commands as dead. */ if (topo == TOPO_NL_PORT || topo == TOPO_FL_PORT) { int i, j; for (i = j = 0; i < isp->isp_maxcmds; i++) { XS_T *xs; isp_hdl_t *hdp; hdp = &isp->isp_xflist[i]; if (ISP_H2HT(hdp->handle) != ISP_HANDLE_INITIATOR) { continue; } xs = hdp->cmd; if (XS_CHANNEL(xs) != chan) { continue; } j++; isp_prt(isp, ISP_LOG_WARN1, "%d.%d.%jx bus reset set at %s:%u", XS_CHANNEL(xs), XS_TGT(xs), (uintmax_t)XS_LUN(xs), __func__, __LINE__); XS_SETERR(xs, HBA_BUSRESET); } if (j) { isp_prt(isp, ISP_LOGERR, lipd, chan, j); } } } break; case ASYNC_LOOP_UP: /* * This is a broadcast event that has to be sent across * all active channels. */ for (chan = 0; chan < isp->isp_nchan; chan++) { fcp = FCPARAM(isp, chan); if (fcp->role == ISP_ROLE_NONE) continue; fcp->isp_linkstate = 1; if (fcp->isp_loopstate < LOOP_HAVE_LINK) fcp->isp_loopstate = LOOP_HAVE_LINK; ISP_SET_SENDMARKER(isp, chan, 1); isp_async(isp, ISPASYNC_LOOP_UP, chan); #ifdef ISP_TARGET_MODE isp_target_async(isp, chan, mbox); #endif } break; case ASYNC_LOOP_DOWN: /* * This is a broadcast event that has to be sent across * all active channels. */ for (chan = 0; chan < isp->isp_nchan; chan++) { fcp = FCPARAM(isp, chan); if (fcp->role == ISP_ROLE_NONE) continue; ISP_SET_SENDMARKER(isp, chan, 1); fcp->isp_linkstate = 0; fcp->isp_loopstate = LOOP_NIL; isp_async(isp, ISPASYNC_LOOP_DOWN, chan); #ifdef ISP_TARGET_MODE isp_target_async(isp, chan, mbox); #endif } break; case ASYNC_LOOP_RESET: /* * This is a broadcast event that has to be sent across * all active channels. */ for (chan = 0; chan < isp->isp_nchan; chan++) { fcp = FCPARAM(isp, chan); if (fcp->role == ISP_ROLE_NONE) continue; ISP_SET_SENDMARKER(isp, chan, 1); if (fcp->isp_loopstate > LOOP_HAVE_LINK) fcp->isp_loopstate = LOOP_HAVE_LINK; isp_async(isp, ISPASYNC_LOOP_RESET, chan); #ifdef ISP_TARGET_MODE isp_target_async(isp, chan, mbox); #endif } break; case ASYNC_PDB_CHANGED: { int echan, nphdl, nlstate, reason; if (IS_23XX(isp) || IS_24XX(isp)) { nphdl = ISP_READ(isp, OUTMAILBOX1); nlstate = ISP_READ(isp, OUTMAILBOX2); } else { nphdl = nlstate = 0xffff; } if (IS_24XX(isp)) reason = ISP_READ(isp, OUTMAILBOX3) >> 8; else reason = 0xff; if (ISP_CAP_MULTI_ID(isp)) { chan = ISP_READ(isp, OUTMAILBOX3) & 0xff; if (chan == 0xff || nphdl == NIL_HANDLE) { chan = 0; echan = isp->isp_nchan - 1; } else if (chan >= isp->isp_nchan) { break; } else { echan = chan; } } else { chan = echan = 0; } for (; chan <= echan; chan++) { fcp = FCPARAM(isp, chan); if (fcp->role == ISP_ROLE_NONE) continue; if (fcp->isp_loopstate > LOOP_LTEST_DONE) { if (nphdl != NIL_HANDLE && nphdl == fcp->isp_login_hdl && reason == PDB24XX_AE_OPN_2) continue; fcp->isp_loopstate = LOOP_LTEST_DONE; } else if (fcp->isp_loopstate < LOOP_HAVE_LINK) fcp->isp_loopstate = LOOP_HAVE_LINK; isp_async(isp, ISPASYNC_CHANGE_NOTIFY, chan, ISPASYNC_CHANGE_PDB, nphdl, nlstate, reason); } break; } case ASYNC_CHANGE_NOTIFY: { int portid; portid = ((ISP_READ(isp, OUTMAILBOX1) & 0xff) << 16) | ISP_READ(isp, OUTMAILBOX2); if (ISP_CAP_MULTI_ID(isp)) { chan = ISP_READ(isp, OUTMAILBOX3) & 0xff; if (chan >= isp->isp_nchan) break; } else { chan = 0; } fcp = FCPARAM(isp, chan); if (fcp->role == ISP_ROLE_NONE) break; if (fcp->isp_loopstate > LOOP_LTEST_DONE) fcp->isp_loopstate = LOOP_LTEST_DONE; else if (fcp->isp_loopstate < LOOP_HAVE_LINK) fcp->isp_loopstate = LOOP_HAVE_LINK; isp_async(isp, ISPASYNC_CHANGE_NOTIFY, chan, ISPASYNC_CHANGE_SNS, portid); break; } case ASYNC_ERR_LOGGING_DISABLED: isp_prt(isp, ISP_LOGWARN, "Error logging disabled (reason 0x%x)", ISP_READ(isp, OUTMAILBOX1)); break; case ASYNC_CONNMODE: /* * This only applies to 2100 amd 2200 cards */ if (!IS_2200(isp) && !IS_2100(isp)) { isp_prt(isp, ISP_LOGWARN, "bad card for ASYNC_CONNMODE event"); break; } chan = 0; mbox = ISP_READ(isp, OUTMAILBOX1); switch (mbox) { case ISP_CONN_LOOP: isp_prt(isp, ISP_LOGINFO, "Point-to-Point -> Loop mode"); break; case ISP_CONN_PTP: isp_prt(isp, ISP_LOGINFO, "Loop -> Point-to-Point mode"); break; case ISP_CONN_BADLIP: isp_prt(isp, ISP_LOGWARN, "Point-to-Point -> Loop mode (BAD LIP)"); break; case ISP_CONN_FATAL: isp->isp_state = ISP_CRASHED; isp_prt(isp, ISP_LOGERR, "FATAL CONNECTION ERROR"); isp_async(isp, ISPASYNC_FW_CRASH); return; case ISP_CONN_LOOPBACK: isp_prt(isp, ISP_LOGWARN, "Looped Back in Point-to-Point mode"); break; default: isp_prt(isp, ISP_LOGWARN, "Unknown connection mode (0x%x)", mbox); break; } ISP_SET_SENDMARKER(isp, chan, 1); FCPARAM(isp, chan)->isp_loopstate = LOOP_HAVE_LINK; isp_async(isp, ISPASYNC_CHANGE_NOTIFY, chan, ISPASYNC_CHANGE_OTHER); break; case ASYNC_P2P_INIT_ERR: isp_prt(isp, ISP_LOGWARN, "P2P init error (reason 0x%x)", ISP_READ(isp, OUTMAILBOX1)); break; case ASYNC_RCV_ERR: if (IS_24XX(isp)) { isp_prt(isp, ISP_LOGWARN, "Receive Error"); } else { isp_prt(isp, ISP_LOGWARN, "unexpected ASYNC_RCV_ERR"); } break; case ASYNC_RJT_SENT: /* same as ASYNC_QFULL_SENT */ if (IS_24XX(isp)) { isp_prt(isp, ISP_LOGTDEBUG0, "LS_RJT sent"); break; } else { isp_prt(isp, ISP_LOGTDEBUG0, "QFULL sent"); break; } case ASYNC_FW_RESTART_COMPLETE: isp_prt(isp, ISP_LOGDEBUG0, "FW restart complete"); break; case ASYNC_TEMPERATURE_ALERT: isp_prt(isp, ISP_LOGERR, "Temperature alert (subcode 0x%x)", ISP_READ(isp, OUTMAILBOX1)); break; case ASYNC_TRANSCEIVER_INSERTION: isp_prt(isp, ISP_LOGDEBUG0, "Transceiver insertion (0x%x)", ISP_READ(isp, OUTMAILBOX1)); break; case ASYNC_TRANSCEIVER_REMOVAL: isp_prt(isp, ISP_LOGDEBUG0, "Transceiver removal"); break; case ASYNC_AUTOLOAD_FW_COMPLETE: isp_prt(isp, ISP_LOGDEBUG0, "Autoload FW init complete"); break; case ASYNC_AUTOLOAD_FW_FAILURE: isp_prt(isp, ISP_LOGERR, "Autoload FW init failure"); break; default: isp_prt(isp, ISP_LOGWARN, "Unknown Async Code 0x%x", mbox); break; } } /* * Handle other response entries. A pointer to the request queue output * index is here in case we want to eat several entries at once, although * this is not used currently. */ static int isp_handle_other_response(ispsoftc_t *isp, int type, isphdr_t *hp, uint32_t *optrp) { isp_ridacq_t rid; int chan, c; uint32_t hdl, portid; void *ptr; switch (type) { case RQSTYPE_MARKER: isp_prt(isp, ISP_LOG_WARN1, "Marker Response"); return (1); case RQSTYPE_RPT_ID_ACQ: isp_get_ridacq(isp, (isp_ridacq_t *)hp, &rid); portid = (uint32_t)rid.ridacq_vp_port_hi << 16 | rid.ridacq_vp_port_lo; if (rid.ridacq_format == 0) { for (chan = 0; chan < isp->isp_nchan; chan++) { fcparam *fcp = FCPARAM(isp, chan); if (fcp->role == ISP_ROLE_NONE) continue; c = (chan == 0) ? 127 : (chan - 1); if (rid.ridacq_map[c / 16] & (1 << (c % 16)) || chan == 0) { fcp->isp_loopstate = LOOP_HAVE_LINK; isp_async(isp, ISPASYNC_CHANGE_NOTIFY, chan, ISPASYNC_CHANGE_OTHER); } else { fcp->isp_loopstate = LOOP_NIL; isp_async(isp, ISPASYNC_LOOP_DOWN, chan); } } } else { fcparam *fcp = FCPARAM(isp, rid.ridacq_vp_index); if (rid.ridacq_vp_status == RIDACQ_STS_COMPLETE || rid.ridacq_vp_status == RIDACQ_STS_CHANGED) { fcp->isp_topo = (rid.ridacq_map[0] >> 9) & 0x7; fcp->isp_portid = portid; fcp->isp_loopstate = LOOP_HAVE_ADDR; isp_async(isp, ISPASYNC_CHANGE_NOTIFY, rid.ridacq_vp_index, ISPASYNC_CHANGE_OTHER); } else { fcp->isp_loopstate = LOOP_NIL; isp_async(isp, ISPASYNC_LOOP_DOWN, rid.ridacq_vp_index); } } return (1); case RQSTYPE_CT_PASSTHRU: case RQSTYPE_VP_MODIFY: case RQSTYPE_VP_CTRL: case RQSTYPE_LOGIN: ISP_IOXGET_32(isp, (uint32_t *)(hp + 1), hdl); ptr = isp_find_xs(isp, hdl); if (ptr != NULL) { isp_destroy_handle(isp, hdl); memcpy(ptr, hp, QENTRY_LEN); wakeup(ptr); } return (1); case RQSTYPE_ATIO: case RQSTYPE_CTIO: case RQSTYPE_NOTIFY: case RQSTYPE_NOTIFY_ACK: case RQSTYPE_CTIO1: case RQSTYPE_ATIO2: case RQSTYPE_CTIO2: case RQSTYPE_CTIO3: case RQSTYPE_CTIO7: case RQSTYPE_ABTS_RCVD: case RQSTYPE_ABTS_RSP: #ifdef ISP_TARGET_MODE return (isp_target_notify(isp, (ispstatusreq_t *) hp, optrp)); #endif /* FALLTHROUGH */ case RQSTYPE_REQUEST: default: return (0); } } static void isp_parse_status(ispsoftc_t *isp, ispstatusreq_t *sp, XS_T *xs, uint32_t *rp) { switch (sp->req_completion_status & 0xff) { case RQCS_COMPLETE: if (XS_NOERR(xs)) { XS_SETERR(xs, HBA_NOERROR); } return; case RQCS_INCOMPLETE: if ((sp->req_state_flags & RQSF_GOT_TARGET) == 0) { isp_xs_prt(isp, xs, ISP_LOG_WARN1, "Selection Timeout @ %s:%d", __func__, __LINE__); if (XS_NOERR(xs)) { XS_SETERR(xs, HBA_SELTIMEOUT); *rp = XS_XFRLEN(xs); } return; } isp_xs_prt(isp, xs, ISP_LOGERR, "Command Incomplete, state 0x%x", sp->req_state_flags); break; case RQCS_DMA_ERROR: isp_xs_prt(isp, xs, ISP_LOGERR, "DMA Error"); *rp = XS_XFRLEN(xs); break; case RQCS_TRANSPORT_ERROR: { char buf[172]; ISP_SNPRINTF(buf, sizeof (buf), "states=>"); if (sp->req_state_flags & RQSF_GOT_BUS) { ISP_SNPRINTF(buf, sizeof (buf), "%s GOT_BUS", buf); } if (sp->req_state_flags & RQSF_GOT_TARGET) { ISP_SNPRINTF(buf, sizeof (buf), "%s GOT_TGT", buf); } if (sp->req_state_flags & RQSF_SENT_CDB) { ISP_SNPRINTF(buf, sizeof (buf), "%s SENT_CDB", buf); } if (sp->req_state_flags & RQSF_XFRD_DATA) { ISP_SNPRINTF(buf, sizeof (buf), "%s XFRD_DATA", buf); } if (sp->req_state_flags & RQSF_GOT_STATUS) { ISP_SNPRINTF(buf, sizeof (buf), "%s GOT_STS", buf); } if (sp->req_state_flags & RQSF_GOT_SENSE) { ISP_SNPRINTF(buf, sizeof (buf), "%s GOT_SNS", buf); } if (sp->req_state_flags & RQSF_XFER_COMPLETE) { ISP_SNPRINTF(buf, sizeof (buf), "%s XFR_CMPLT", buf); } ISP_SNPRINTF(buf, sizeof (buf), "%s\nstatus=>", buf); if (sp->req_status_flags & RQSTF_DISCONNECT) { ISP_SNPRINTF(buf, sizeof (buf), "%s Disconnect", buf); } if (sp->req_status_flags & RQSTF_SYNCHRONOUS) { ISP_SNPRINTF(buf, sizeof (buf), "%s Sync_xfr", buf); } if (sp->req_status_flags & RQSTF_PARITY_ERROR) { ISP_SNPRINTF(buf, sizeof (buf), "%s Parity", buf); } if (sp->req_status_flags & RQSTF_BUS_RESET) { ISP_SNPRINTF(buf, sizeof (buf), "%s Bus_Reset", buf); } if (sp->req_status_flags & RQSTF_DEVICE_RESET) { ISP_SNPRINTF(buf, sizeof (buf), "%s Device_Reset", buf); } if (sp->req_status_flags & RQSTF_ABORTED) { ISP_SNPRINTF(buf, sizeof (buf), "%s Aborted", buf); } if (sp->req_status_flags & RQSTF_TIMEOUT) { ISP_SNPRINTF(buf, sizeof (buf), "%s Timeout", buf); } if (sp->req_status_flags & RQSTF_NEGOTIATION) { ISP_SNPRINTF(buf, sizeof (buf), "%s Negotiation", buf); } isp_xs_prt(isp, xs, ISP_LOGERR, "Transport Error: %s", buf); *rp = XS_XFRLEN(xs); break; } case RQCS_RESET_OCCURRED: { int chan; isp_xs_prt(isp, xs, ISP_LOGWARN, "Bus Reset destroyed command"); for (chan = 0; chan < isp->isp_nchan; chan++) { FCPARAM(isp, chan)->sendmarker = 1; } if (XS_NOERR(xs)) { XS_SETERR(xs, HBA_BUSRESET); } *rp = XS_XFRLEN(xs); return; } case RQCS_ABORTED: isp_xs_prt(isp, xs, ISP_LOGERR, "Command Aborted"); ISP_SET_SENDMARKER(isp, XS_CHANNEL(xs), 1); if (XS_NOERR(xs)) { XS_SETERR(xs, HBA_ABORTED); } return; case RQCS_TIMEOUT: isp_xs_prt(isp, xs, ISP_LOGWARN, "Command timed out"); /* * XXX: Check to see if we logged out of the device. */ if (XS_NOERR(xs)) { XS_SETERR(xs, HBA_CMDTIMEOUT); } return; case RQCS_DATA_OVERRUN: XS_SET_RESID(xs, sp->req_resid); isp_xs_prt(isp, xs, ISP_LOGERR, "data overrun (%ld)", (long) XS_GET_RESID(xs)); if (XS_NOERR(xs)) { XS_SETERR(xs, HBA_DATAOVR); } return; case RQCS_COMMAND_OVERRUN: isp_xs_prt(isp, xs, ISP_LOGERR, "command overrun"); break; case RQCS_STATUS_OVERRUN: isp_xs_prt(isp, xs, ISP_LOGERR, "status overrun"); break; case RQCS_BAD_MESSAGE: isp_xs_prt(isp, xs, ISP_LOGERR, "msg not COMMAND COMPLETE after status"); break; case RQCS_NO_MESSAGE_OUT: isp_xs_prt(isp, xs, ISP_LOGERR, "No MESSAGE OUT phase after selection"); break; case RQCS_EXT_ID_FAILED: isp_xs_prt(isp, xs, ISP_LOGERR, "EXTENDED IDENTIFY failed"); break; case RQCS_IDE_MSG_FAILED: isp_xs_prt(isp, xs, ISP_LOGERR, "INITIATOR DETECTED ERROR rejected"); break; case RQCS_ABORT_MSG_FAILED: isp_xs_prt(isp, xs, ISP_LOGERR, "ABORT OPERATION rejected"); break; case RQCS_REJECT_MSG_FAILED: isp_xs_prt(isp, xs, ISP_LOGERR, "MESSAGE REJECT rejected"); break; case RQCS_NOP_MSG_FAILED: isp_xs_prt(isp, xs, ISP_LOGERR, "NOP rejected"); break; case RQCS_PARITY_ERROR_MSG_FAILED: isp_xs_prt(isp, xs, ISP_LOGERR, "MESSAGE PARITY ERROR rejected"); break; case RQCS_DEVICE_RESET_MSG_FAILED: isp_xs_prt(isp, xs, ISP_LOGWARN, "BUS DEVICE RESET rejected"); break; case RQCS_ID_MSG_FAILED: isp_xs_prt(isp, xs, ISP_LOGERR, "IDENTIFY rejected"); break; case RQCS_UNEXP_BUS_FREE: isp_xs_prt(isp, xs, ISP_LOGERR, "Unexpected Bus Free"); break; case RQCS_DATA_UNDERRUN: { if (IS_FC(isp)) { int ru_marked = (sp->req_scsi_status & RQCS_RU) != 0; if (!ru_marked || sp->req_resid > XS_XFRLEN(xs)) { isp_xs_prt(isp, xs, ISP_LOGWARN, bun, XS_XFRLEN(xs), sp->req_resid, (ru_marked)? "marked" : "not marked"); if (XS_NOERR(xs)) { XS_SETERR(xs, HBA_BOTCH); } return; } } XS_SET_RESID(xs, sp->req_resid); if (XS_NOERR(xs)) { XS_SETERR(xs, HBA_NOERROR); } return; } case RQCS_XACT_ERR1: isp_xs_prt(isp, xs, ISP_LOGERR, "HBA attempted queued transaction with disconnect not set"); break; case RQCS_XACT_ERR2: isp_xs_prt(isp, xs, ISP_LOGERR, "HBA attempted queued transaction to target routine %jx", (uintmax_t)XS_LUN(xs)); break; case RQCS_XACT_ERR3: isp_xs_prt(isp, xs, ISP_LOGERR, "HBA attempted queued cmd when queueing disabled"); break; case RQCS_BAD_ENTRY: isp_prt(isp, ISP_LOGERR, "Invalid IOCB entry type detected"); break; case RQCS_QUEUE_FULL: isp_xs_prt(isp, xs, ISP_LOG_WARN1, "internal queues full status 0x%x", *XS_STSP(xs)); /* * If QFULL or some other status byte is set, then this * isn't an error, per se. * * Unfortunately, some QLogic f/w writers have, in * some cases, omitted to *set* status to QFULL. */ #if 0 if (*XS_STSP(xs) != SCSI_GOOD && XS_NOERR(xs)) { XS_SETERR(xs, HBA_NOERROR); return; } #endif *XS_STSP(xs) = SCSI_QFULL; XS_SETERR(xs, HBA_NOERROR); return; case RQCS_PHASE_SKIPPED: isp_xs_prt(isp, xs, ISP_LOGERR, "SCSI phase skipped"); break; case RQCS_ARQS_FAILED: isp_xs_prt(isp, xs, ISP_LOGERR, "Auto Request Sense Failed"); if (XS_NOERR(xs)) { XS_SETERR(xs, HBA_ARQFAIL); } return; case RQCS_WIDE_FAILED: isp_xs_prt(isp, xs, ISP_LOGERR, "Wide Negotiation Failed"); if (IS_SCSI(isp)) { sdparam *sdp = SDPARAM(isp, XS_CHANNEL(xs)); sdp->isp_devparam[XS_TGT(xs)].goal_flags &= ~DPARM_WIDE; sdp->isp_devparam[XS_TGT(xs)].dev_update = 1; sdp->update = 1; } if (XS_NOERR(xs)) { XS_SETERR(xs, HBA_NOERROR); } return; case RQCS_SYNCXFER_FAILED: isp_xs_prt(isp, xs, ISP_LOGERR, "SDTR Message Failed"); if (IS_SCSI(isp)) { sdparam *sdp = SDPARAM(isp, XS_CHANNEL(xs)); sdp += XS_CHANNEL(xs); sdp->isp_devparam[XS_TGT(xs)].goal_flags &= ~DPARM_SYNC; sdp->isp_devparam[XS_TGT(xs)].dev_update = 1; sdp->update = 1; } break; case RQCS_LVD_BUSERR: isp_xs_prt(isp, xs, ISP_LOGERR, "Bad LVD condition"); break; case RQCS_PORT_UNAVAILABLE: /* * No such port on the loop. Moral equivalent of SELTIMEO */ case RQCS_PORT_LOGGED_OUT: { const char *reason; uint8_t sts = sp->req_completion_status & 0xff; fcparam *fcp = FCPARAM(isp, 0); fcportdb_t *lp; /* * It was there (maybe)- treat as a selection timeout. */ if (sts == RQCS_PORT_UNAVAILABLE) { reason = "unavailable"; } else { reason = "logout"; } isp_prt(isp, ISP_LOGINFO, "port %s for target %d", reason, XS_TGT(xs)); /* XXX: Should we trigger rescan or FW announce change? */ if (XS_NOERR(xs)) { lp = &fcp->portdb[XS_TGT(xs)]; if (lp->state == FC_PORTDB_STATE_ZOMBIE) { *XS_STSP(xs) = SCSI_BUSY; XS_SETERR(xs, HBA_TGTBSY); } else XS_SETERR(xs, HBA_SELTIMEOUT); } return; } case RQCS_PORT_CHANGED: isp_prt(isp, ISP_LOGWARN, "port changed for target %d", XS_TGT(xs)); if (XS_NOERR(xs)) { *XS_STSP(xs) = SCSI_BUSY; XS_SETERR(xs, HBA_TGTBSY); } return; case RQCS_PORT_BUSY: isp_prt(isp, ISP_LOGWARN, "port busy for target %d", XS_TGT(xs)); if (XS_NOERR(xs)) { *XS_STSP(xs) = SCSI_BUSY; XS_SETERR(xs, HBA_TGTBSY); } return; default: isp_prt(isp, ISP_LOGERR, "Unknown Completion Status 0x%x", sp->req_completion_status); break; } if (XS_NOERR(xs)) { XS_SETERR(xs, HBA_BOTCH); } } static void isp_parse_status_24xx(ispsoftc_t *isp, isp24xx_statusreq_t *sp, XS_T *xs, uint32_t *rp) { int ru_marked, sv_marked; int chan = XS_CHANNEL(xs); switch (sp->req_completion_status) { case RQCS_COMPLETE: if (XS_NOERR(xs)) { XS_SETERR(xs, HBA_NOERROR); } return; case RQCS_DMA_ERROR: isp_xs_prt(isp, xs, ISP_LOGERR, "DMA error"); break; case RQCS_TRANSPORT_ERROR: isp_xs_prt(isp, xs, ISP_LOGERR, "Transport Error"); break; case RQCS_RESET_OCCURRED: isp_xs_prt(isp, xs, ISP_LOGWARN, "reset destroyed command"); FCPARAM(isp, chan)->sendmarker = 1; if (XS_NOERR(xs)) { XS_SETERR(xs, HBA_BUSRESET); } return; case RQCS_ABORTED: isp_xs_prt(isp, xs, ISP_LOGERR, "Command Aborted"); FCPARAM(isp, chan)->sendmarker = 1; if (XS_NOERR(xs)) { XS_SETERR(xs, HBA_ABORTED); } return; case RQCS_TIMEOUT: isp_xs_prt(isp, xs, ISP_LOGWARN, "Command Timed Out"); if (XS_NOERR(xs)) { XS_SETERR(xs, HBA_CMDTIMEOUT); } return; case RQCS_DATA_OVERRUN: XS_SET_RESID(xs, sp->req_resid); isp_xs_prt(isp, xs, ISP_LOGERR, "Data Overrun"); if (XS_NOERR(xs)) { XS_SETERR(xs, HBA_DATAOVR); } return; case RQCS_24XX_DRE: /* data reassembly error */ isp_prt(isp, ISP_LOGERR, "Chan %d data reassembly error for target %d", chan, XS_TGT(xs)); if (XS_NOERR(xs)) { XS_SETERR(xs, HBA_ABORTED); } *rp = XS_XFRLEN(xs); return; case RQCS_24XX_TABORT: /* aborted by target */ isp_prt(isp, ISP_LOGERR, "Chan %d target %d sent ABTS", chan, XS_TGT(xs)); if (XS_NOERR(xs)) { XS_SETERR(xs, HBA_ABORTED); } return; case RQCS_DATA_UNDERRUN: ru_marked = (sp->req_scsi_status & RQCS_RU) != 0; /* * We can get an underrun w/o things being marked * if we got a non-zero status. */ sv_marked = (sp->req_scsi_status & (RQCS_SV|RQCS_RV)) != 0; if ((ru_marked == 0 && sv_marked == 0) || (sp->req_resid > XS_XFRLEN(xs))) { isp_xs_prt(isp, xs, ISP_LOGWARN, bun, XS_XFRLEN(xs), sp->req_resid, (ru_marked)? "marked" : "not marked"); if (XS_NOERR(xs)) { XS_SETERR(xs, HBA_BOTCH); } return; } XS_SET_RESID(xs, sp->req_resid); isp_xs_prt(isp, xs, ISP_LOG_WARN1, "Data Underrun (%d) for command 0x%x", sp->req_resid, XS_CDBP(xs)[0] & 0xff); if (XS_NOERR(xs)) { XS_SETERR(xs, HBA_NOERROR); } return; case RQCS_PORT_UNAVAILABLE: /* * No such port on the loop. Moral equivalent of SELTIMEO */ case RQCS_PORT_LOGGED_OUT: { const char *reason; uint8_t sts = sp->req_completion_status & 0xff; fcparam *fcp = FCPARAM(isp, XS_CHANNEL(xs)); fcportdb_t *lp; /* * It was there (maybe)- treat as a selection timeout. */ if (sts == RQCS_PORT_UNAVAILABLE) { reason = "unavailable"; } else { reason = "logout"; } isp_prt(isp, ISP_LOGINFO, "Chan %d port %s for target %d", chan, reason, XS_TGT(xs)); /* XXX: Should we trigger rescan or FW announce change? */ if (XS_NOERR(xs)) { lp = &fcp->portdb[XS_TGT(xs)]; if (lp->state == FC_PORTDB_STATE_ZOMBIE) { *XS_STSP(xs) = SCSI_BUSY; XS_SETERR(xs, HBA_TGTBSY); } else XS_SETERR(xs, HBA_SELTIMEOUT); } return; } case RQCS_PORT_CHANGED: isp_prt(isp, ISP_LOGWARN, "port changed for target %d chan %d", XS_TGT(xs), chan); if (XS_NOERR(xs)) { *XS_STSP(xs) = SCSI_BUSY; XS_SETERR(xs, HBA_TGTBSY); } return; case RQCS_24XX_ENOMEM: /* f/w resource unavailable */ isp_prt(isp, ISP_LOGWARN, "f/w resource unavailable for target %d chan %d", XS_TGT(xs), chan); if (XS_NOERR(xs)) { *XS_STSP(xs) = SCSI_BUSY; XS_SETERR(xs, HBA_TGTBSY); } return; case RQCS_24XX_TMO: /* task management overrun */ isp_prt(isp, ISP_LOGWARN, "command for target %d overlapped task management for chan %d", XS_TGT(xs), chan); if (XS_NOERR(xs)) { *XS_STSP(xs) = SCSI_BUSY; XS_SETERR(xs, HBA_TGTBSY); } return; default: isp_prt(isp, ISP_LOGERR, "Unknown Completion Status 0x%x on chan %d", sp->req_completion_status, chan); break; } if (XS_NOERR(xs)) { XS_SETERR(xs, HBA_BOTCH); } } static void isp_fastpost_complete(ispsoftc_t *isp, uint32_t fph) { XS_T *xs; if (fph == 0) { return; } xs = isp_find_xs(isp, fph); if (xs == NULL) { isp_prt(isp, ISP_LOGWARN, "Command for fast post handle 0x%x not found", fph); return; } isp_destroy_handle(isp, fph); /* * Since we don't have a result queue entry item, * we must believe that SCSI status is zero and * that all data transferred. */ XS_SET_RESID(xs, 0); *XS_STSP(xs) = SCSI_GOOD; if (XS_XFRLEN(xs)) { ISP_DMAFREE(isp, xs, fph); } isp_done(xs); } #define ISP_SCSI_IBITS(op) (mbpscsi[((op)<<1)]) #define ISP_SCSI_OBITS(op) (mbpscsi[((op)<<1) + 1]) #define ISP_SCSI_OPMAP(in, out) in, out static const uint8_t mbpscsi[] = { ISP_SCSI_OPMAP(0x01, 0x01), /* 0x00: MBOX_NO_OP */ ISP_SCSI_OPMAP(0x1f, 0x01), /* 0x01: MBOX_LOAD_RAM */ ISP_SCSI_OPMAP(0x03, 0x01), /* 0x02: MBOX_EXEC_FIRMWARE */ ISP_SCSI_OPMAP(0x1f, 0x01), /* 0x03: MBOX_DUMP_RAM */ ISP_SCSI_OPMAP(0x07, 0x07), /* 0x04: MBOX_WRITE_RAM_WORD */ ISP_SCSI_OPMAP(0x03, 0x07), /* 0x05: MBOX_READ_RAM_WORD */ ISP_SCSI_OPMAP(0x3f, 0x3f), /* 0x06: MBOX_MAILBOX_REG_TEST */ ISP_SCSI_OPMAP(0x07, 0x07), /* 0x07: MBOX_VERIFY_CHECKSUM */ ISP_SCSI_OPMAP(0x01, 0x0f), /* 0x08: MBOX_ABOUT_FIRMWARE */ ISP_SCSI_OPMAP(0x00, 0x00), /* 0x09: */ ISP_SCSI_OPMAP(0x00, 0x00), /* 0x0a: */ ISP_SCSI_OPMAP(0x00, 0x00), /* 0x0b: */ ISP_SCSI_OPMAP(0x00, 0x00), /* 0x0c: */ ISP_SCSI_OPMAP(0x00, 0x00), /* 0x0d: */ ISP_SCSI_OPMAP(0x01, 0x05), /* 0x0e: MBOX_CHECK_FIRMWARE */ ISP_SCSI_OPMAP(0x00, 0x00), /* 0x0f: */ ISP_SCSI_OPMAP(0x1f, 0x1f), /* 0x10: MBOX_INIT_REQ_QUEUE */ ISP_SCSI_OPMAP(0x3f, 0x3f), /* 0x11: MBOX_INIT_RES_QUEUE */ ISP_SCSI_OPMAP(0x0f, 0x0f), /* 0x12: MBOX_EXECUTE_IOCB */ ISP_SCSI_OPMAP(0x03, 0x03), /* 0x13: MBOX_WAKE_UP */ ISP_SCSI_OPMAP(0x01, 0x3f), /* 0x14: MBOX_STOP_FIRMWARE */ ISP_SCSI_OPMAP(0x0f, 0x0f), /* 0x15: MBOX_ABORT */ ISP_SCSI_OPMAP(0x03, 0x03), /* 0x16: MBOX_ABORT_DEVICE */ ISP_SCSI_OPMAP(0x07, 0x07), /* 0x17: MBOX_ABORT_TARGET */ ISP_SCSI_OPMAP(0x07, 0x07), /* 0x18: MBOX_BUS_RESET */ ISP_SCSI_OPMAP(0x03, 0x07), /* 0x19: MBOX_STOP_QUEUE */ ISP_SCSI_OPMAP(0x03, 0x07), /* 0x1a: MBOX_START_QUEUE */ ISP_SCSI_OPMAP(0x03, 0x07), /* 0x1b: MBOX_SINGLE_STEP_QUEUE */ ISP_SCSI_OPMAP(0x03, 0x07), /* 0x1c: MBOX_ABORT_QUEUE */ ISP_SCSI_OPMAP(0x03, 0x4f), /* 0x1d: MBOX_GET_DEV_QUEUE_STATUS */ ISP_SCSI_OPMAP(0x00, 0x00), /* 0x1e: */ ISP_SCSI_OPMAP(0x01, 0x07), /* 0x1f: MBOX_GET_FIRMWARE_STATUS */ ISP_SCSI_OPMAP(0x01, 0x07), /* 0x20: MBOX_GET_INIT_SCSI_ID */ ISP_SCSI_OPMAP(0x01, 0x07), /* 0x21: MBOX_GET_SELECT_TIMEOUT */ ISP_SCSI_OPMAP(0x01, 0xc7), /* 0x22: MBOX_GET_RETRY_COUNT */ ISP_SCSI_OPMAP(0x01, 0x07), /* 0x23: MBOX_GET_TAG_AGE_LIMIT */ ISP_SCSI_OPMAP(0x01, 0x03), /* 0x24: MBOX_GET_CLOCK_RATE */ ISP_SCSI_OPMAP(0x01, 0x07), /* 0x25: MBOX_GET_ACT_NEG_STATE */ ISP_SCSI_OPMAP(0x01, 0x07), /* 0x26: MBOX_GET_ASYNC_DATA_SETUP_TIME */ ISP_SCSI_OPMAP(0x01, 0x07), /* 0x27: MBOX_GET_PCI_PARAMS */ ISP_SCSI_OPMAP(0x03, 0x4f), /* 0x28: MBOX_GET_TARGET_PARAMS */ ISP_SCSI_OPMAP(0x03, 0x0f), /* 0x29: MBOX_GET_DEV_QUEUE_PARAMS */ ISP_SCSI_OPMAP(0x01, 0x07), /* 0x2a: MBOX_GET_RESET_DELAY_PARAMS */ ISP_SCSI_OPMAP(0x00, 0x00), /* 0x2b: */ ISP_SCSI_OPMAP(0x00, 0x00), /* 0x2c: */ ISP_SCSI_OPMAP(0x00, 0x00), /* 0x2d: */ ISP_SCSI_OPMAP(0x00, 0x00), /* 0x2e: */ ISP_SCSI_OPMAP(0x00, 0x00), /* 0x2f: */ ISP_SCSI_OPMAP(0x03, 0x03), /* 0x30: MBOX_SET_INIT_SCSI_ID */ ISP_SCSI_OPMAP(0x07, 0x07), /* 0x31: MBOX_SET_SELECT_TIMEOUT */ ISP_SCSI_OPMAP(0xc7, 0xc7), /* 0x32: MBOX_SET_RETRY_COUNT */ ISP_SCSI_OPMAP(0x07, 0x07), /* 0x33: MBOX_SET_TAG_AGE_LIMIT */ ISP_SCSI_OPMAP(0x03, 0x03), /* 0x34: MBOX_SET_CLOCK_RATE */ ISP_SCSI_OPMAP(0x07, 0x07), /* 0x35: MBOX_SET_ACT_NEG_STATE */ ISP_SCSI_OPMAP(0x07, 0x07), /* 0x36: MBOX_SET_ASYNC_DATA_SETUP_TIME */ ISP_SCSI_OPMAP(0x07, 0x07), /* 0x37: MBOX_SET_PCI_CONTROL_PARAMS */ ISP_SCSI_OPMAP(0x4f, 0x4f), /* 0x38: MBOX_SET_TARGET_PARAMS */ ISP_SCSI_OPMAP(0x0f, 0x0f), /* 0x39: MBOX_SET_DEV_QUEUE_PARAMS */ ISP_SCSI_OPMAP(0x07, 0x07), /* 0x3a: MBOX_SET_RESET_DELAY_PARAMS */ ISP_SCSI_OPMAP(0x00, 0x00), /* 0x3b: */ ISP_SCSI_OPMAP(0x00, 0x00), /* 0x3c: */ ISP_SCSI_OPMAP(0x00, 0x00), /* 0x3d: */ ISP_SCSI_OPMAP(0x00, 0x00), /* 0x3e: */ ISP_SCSI_OPMAP(0x00, 0x00), /* 0x3f: */ ISP_SCSI_OPMAP(0x01, 0x03), /* 0x40: MBOX_RETURN_BIOS_BLOCK_ADDR */ ISP_SCSI_OPMAP(0x3f, 0x01), /* 0x41: MBOX_WRITE_FOUR_RAM_WORDS */ ISP_SCSI_OPMAP(0x03, 0x07), /* 0x42: MBOX_EXEC_BIOS_IOCB */ ISP_SCSI_OPMAP(0x00, 0x00), /* 0x43: */ ISP_SCSI_OPMAP(0x00, 0x00), /* 0x44: */ ISP_SCSI_OPMAP(0x03, 0x03), /* 0x45: SET SYSTEM PARAMETER */ ISP_SCSI_OPMAP(0x01, 0x03), /* 0x46: GET SYSTEM PARAMETER */ ISP_SCSI_OPMAP(0x00, 0x00), /* 0x47: */ ISP_SCSI_OPMAP(0x01, 0xcf), /* 0x48: GET SCAM CONFIGURATION */ ISP_SCSI_OPMAP(0xcf, 0xcf), /* 0x49: SET SCAM CONFIGURATION */ ISP_SCSI_OPMAP(0x03, 0x03), /* 0x4a: MBOX_SET_FIRMWARE_FEATURES */ ISP_SCSI_OPMAP(0x01, 0x03), /* 0x4b: MBOX_GET_FIRMWARE_FEATURES */ ISP_SCSI_OPMAP(0x00, 0x00), /* 0x4c: */ ISP_SCSI_OPMAP(0x00, 0x00), /* 0x4d: */ ISP_SCSI_OPMAP(0x00, 0x00), /* 0x4e: */ ISP_SCSI_OPMAP(0x00, 0x00), /* 0x4f: */ ISP_SCSI_OPMAP(0xdf, 0xdf), /* 0x50: LOAD RAM A64 */ ISP_SCSI_OPMAP(0xdf, 0xdf), /* 0x51: DUMP RAM A64 */ ISP_SCSI_OPMAP(0xdf, 0xff), /* 0x52: INITIALIZE REQUEST QUEUE A64 */ ISP_SCSI_OPMAP(0xef, 0xff), /* 0x53: INITIALIZE RESPONSE QUEUE A64 */ ISP_SCSI_OPMAP(0xcf, 0x01), /* 0x54: EXECUCUTE COMMAND IOCB A64 */ ISP_SCSI_OPMAP(0x07, 0x01), /* 0x55: ENABLE TARGET MODE */ ISP_SCSI_OPMAP(0x03, 0x0f), /* 0x56: GET TARGET STATUS */ ISP_SCSI_OPMAP(0x00, 0x00), /* 0x57: */ ISP_SCSI_OPMAP(0x00, 0x00), /* 0x58: */ ISP_SCSI_OPMAP(0x00, 0x00), /* 0x59: */ ISP_SCSI_OPMAP(0x03, 0x03), /* 0x5a: SET DATA OVERRUN RECOVERY MODE */ ISP_SCSI_OPMAP(0x01, 0x03), /* 0x5b: GET DATA OVERRUN RECOVERY MODE */ ISP_SCSI_OPMAP(0x0f, 0x0f), /* 0x5c: SET HOST DATA */ ISP_SCSI_OPMAP(0x01, 0x01) /* 0x5d: GET NOST DATA */ }; #define MAX_SCSI_OPCODE 0x5d static const char *scsi_mbcmd_names[] = { "NO-OP", "LOAD RAM", "EXEC FIRMWARE", "DUMP RAM", "WRITE RAM WORD", "READ RAM WORD", "MAILBOX REG TEST", "VERIFY CHECKSUM", "ABOUT FIRMWARE", NULL, NULL, NULL, NULL, NULL, "CHECK FIRMWARE", NULL, "INIT REQUEST QUEUE", "INIT RESULT QUEUE", "EXECUTE IOCB", "WAKE UP", "STOP FIRMWARE", "ABORT", "ABORT DEVICE", "ABORT TARGET", "BUS RESET", "STOP QUEUE", "START QUEUE", "SINGLE STEP QUEUE", "ABORT QUEUE", "GET DEV QUEUE STATUS", NULL, "GET FIRMWARE STATUS", "GET INIT SCSI ID", "GET SELECT TIMEOUT", "GET RETRY COUNT", "GET TAG AGE LIMIT", "GET CLOCK RATE", "GET ACT NEG STATE", "GET ASYNC DATA SETUP TIME", "GET PCI PARAMS", "GET TARGET PARAMS", "GET DEV QUEUE PARAMS", "GET RESET DELAY PARAMS", NULL, NULL, NULL, NULL, NULL, "SET INIT SCSI ID", "SET SELECT TIMEOUT", "SET RETRY COUNT", "SET TAG AGE LIMIT", "SET CLOCK RATE", "SET ACT NEG STATE", "SET ASYNC DATA SETUP TIME", "SET PCI CONTROL PARAMS", "SET TARGET PARAMS", "SET DEV QUEUE PARAMS", "SET RESET DELAY PARAMS", NULL, NULL, NULL, NULL, NULL, "RETURN BIOS BLOCK ADDR", "WRITE FOUR RAM WORDS", "EXEC BIOS IOCB", NULL, NULL, "SET SYSTEM PARAMETER", "GET SYSTEM PARAMETER", NULL, "GET SCAM CONFIGURATION", "SET SCAM CONFIGURATION", "SET FIRMWARE FEATURES", "GET FIRMWARE FEATURES", NULL, NULL, NULL, NULL, "LOAD RAM A64", "DUMP RAM A64", "INITIALIZE REQUEST QUEUE A64", "INITIALIZE RESPONSE QUEUE A64", "EXECUTE IOCB A64", "ENABLE TARGET MODE", "GET TARGET MODE STATE", NULL, NULL, NULL, "SET DATA OVERRUN RECOVERY MODE", "GET DATA OVERRUN RECOVERY MODE", "SET HOST DATA", "GET NOST DATA", }; #define ISP_FC_IBITS(op) ((mbpfc[((op)<<3) + 0] << 24) | (mbpfc[((op)<<3) + 1] << 16) | (mbpfc[((op)<<3) + 2] << 8) | (mbpfc[((op)<<3) + 3])) #define ISP_FC_OBITS(op) ((mbpfc[((op)<<3) + 4] << 24) | (mbpfc[((op)<<3) + 5] << 16) | (mbpfc[((op)<<3) + 6] << 8) | (mbpfc[((op)<<3) + 7])) #define ISP_FC_OPMAP(in0, out0) 0, 0, 0, in0, 0, 0, 0, out0 #define ISP_FC_OPMAP_HALF(in1, in0, out1, out0) 0, 0, in1, in0, 0, 0, out1, out0 #define ISP_FC_OPMAP_FULL(in3, in2, in1, in0, out3, out2, out1, out0) in3, in2, in1, in0, out3, out2, out1, out0 static const uint32_t mbpfc[] = { ISP_FC_OPMAP(0x01, 0x01), /* 0x00: MBOX_NO_OP */ ISP_FC_OPMAP(0x1f, 0x01), /* 0x01: MBOX_LOAD_RAM */ ISP_FC_OPMAP_HALF(0x07, 0xff, 0x00, 0x1f), /* 0x02: MBOX_EXEC_FIRMWARE */ ISP_FC_OPMAP(0xdf, 0x01), /* 0x03: MBOX_DUMP_RAM */ ISP_FC_OPMAP(0x07, 0x07), /* 0x04: MBOX_WRITE_RAM_WORD */ ISP_FC_OPMAP(0x03, 0x07), /* 0x05: MBOX_READ_RAM_WORD */ ISP_FC_OPMAP_FULL(0xff, 0xff, 0xff, 0xff, 0xff, 0xff, 0xff, 0xff), /* 0x06: MBOX_MAILBOX_REG_TEST */ ISP_FC_OPMAP(0x07, 0x07), /* 0x07: MBOX_VERIFY_CHECKSUM */ ISP_FC_OPMAP_FULL(0x0, 0x0, 0x0, 0x01, 0x0, 0x3, 0x80, 0x7f), /* 0x08: MBOX_ABOUT_FIRMWARE */ ISP_FC_OPMAP(0xdf, 0x01), /* 0x09: MBOX_LOAD_RISC_RAM_2100 */ ISP_FC_OPMAP(0xdf, 0x01), /* 0x0a: DUMP RAM */ ISP_FC_OPMAP_HALF(0x1, 0xff, 0x0, 0x01), /* 0x0b: MBOX_LOAD_RISC_RAM */ ISP_FC_OPMAP(0x00, 0x00), /* 0x0c: */ ISP_FC_OPMAP_HALF(0x1, 0x0f, 0x0, 0x01), /* 0x0d: MBOX_WRITE_RAM_WORD_EXTENDED */ ISP_FC_OPMAP(0x01, 0x05), /* 0x0e: MBOX_CHECK_FIRMWARE */ ISP_FC_OPMAP_HALF(0x1, 0x03, 0x0, 0x0d), /* 0x0f: MBOX_READ_RAM_WORD_EXTENDED */ ISP_FC_OPMAP(0x1f, 0x11), /* 0x10: MBOX_INIT_REQ_QUEUE */ ISP_FC_OPMAP(0x2f, 0x21), /* 0x11: MBOX_INIT_RES_QUEUE */ ISP_FC_OPMAP(0x0f, 0x01), /* 0x12: MBOX_EXECUTE_IOCB */ ISP_FC_OPMAP(0x03, 0x03), /* 0x13: MBOX_WAKE_UP */ ISP_FC_OPMAP_HALF(0x1, 0xff, 0x0, 0x03), /* 0x14: MBOX_STOP_FIRMWARE */ ISP_FC_OPMAP(0x4f, 0x01), /* 0x15: MBOX_ABORT */ ISP_FC_OPMAP(0x07, 0x01), /* 0x16: MBOX_ABORT_DEVICE */ ISP_FC_OPMAP(0x07, 0x01), /* 0x17: MBOX_ABORT_TARGET */ ISP_FC_OPMAP(0x03, 0x03), /* 0x18: MBOX_BUS_RESET */ ISP_FC_OPMAP(0x07, 0x05), /* 0x19: MBOX_STOP_QUEUE */ ISP_FC_OPMAP(0x07, 0x05), /* 0x1a: MBOX_START_QUEUE */ ISP_FC_OPMAP(0x07, 0x05), /* 0x1b: MBOX_SINGLE_STEP_QUEUE */ ISP_FC_OPMAP(0x07, 0x05), /* 0x1c: MBOX_ABORT_QUEUE */ ISP_FC_OPMAP(0x07, 0x03), /* 0x1d: MBOX_GET_DEV_QUEUE_STATUS */ ISP_FC_OPMAP(0x00, 0x00), /* 0x1e: */ ISP_FC_OPMAP(0x01, 0x07), /* 0x1f: MBOX_GET_FIRMWARE_STATUS */ ISP_FC_OPMAP_HALF(0x2, 0x01, 0x7e, 0xcf), /* 0x20: MBOX_GET_LOOP_ID */ ISP_FC_OPMAP(0x00, 0x00), /* 0x21: */ ISP_FC_OPMAP(0x03, 0x4b), /* 0x22: MBOX_GET_TIMEOUT_PARAMS */ ISP_FC_OPMAP(0x00, 0x00), /* 0x23: */ ISP_FC_OPMAP(0x00, 0x00), /* 0x24: */ ISP_FC_OPMAP(0x00, 0x00), /* 0x25: */ ISP_FC_OPMAP(0x00, 0x00), /* 0x26: */ ISP_FC_OPMAP(0x00, 0x00), /* 0x27: */ ISP_FC_OPMAP(0x01, 0x03), /* 0x28: MBOX_GET_FIRMWARE_OPTIONS */ ISP_FC_OPMAP(0x03, 0x07), /* 0x29: MBOX_GET_PORT_QUEUE_PARAMS */ ISP_FC_OPMAP(0x00, 0x00), /* 0x2a: */ ISP_FC_OPMAP(0x00, 0x00), /* 0x2b: */ ISP_FC_OPMAP(0x00, 0x00), /* 0x2c: */ ISP_FC_OPMAP(0x00, 0x00), /* 0x2d: */ ISP_FC_OPMAP(0x00, 0x00), /* 0x2e: */ ISP_FC_OPMAP(0x00, 0x00), /* 0x2f: */ ISP_FC_OPMAP(0x00, 0x00), /* 0x30: */ ISP_FC_OPMAP(0x00, 0x00), /* 0x31: */ ISP_FC_OPMAP(0x4b, 0x4b), /* 0x32: MBOX_SET_TIMEOUT_PARAMS */ ISP_FC_OPMAP(0x00, 0x00), /* 0x33: */ ISP_FC_OPMAP(0x00, 0x00), /* 0x34: */ ISP_FC_OPMAP(0x00, 0x00), /* 0x35: */ ISP_FC_OPMAP(0x00, 0x00), /* 0x36: */ ISP_FC_OPMAP(0x00, 0x00), /* 0x37: */ ISP_FC_OPMAP(0x0f, 0x01), /* 0x38: MBOX_SET_FIRMWARE_OPTIONS */ ISP_FC_OPMAP(0x0f, 0x07), /* 0x39: MBOX_SET_PORT_QUEUE_PARAMS */ ISP_FC_OPMAP(0x00, 0x00), /* 0x3a: */ ISP_FC_OPMAP(0x00, 0x00), /* 0x3b: */ ISP_FC_OPMAP(0x00, 0x00), /* 0x3c: */ ISP_FC_OPMAP(0x00, 0x00), /* 0x3d: */ ISP_FC_OPMAP(0x00, 0x00), /* 0x3e: */ ISP_FC_OPMAP(0x00, 0x00), /* 0x3f: */ ISP_FC_OPMAP(0x03, 0x01), /* 0x40: MBOX_LOOP_PORT_BYPASS */ ISP_FC_OPMAP(0x03, 0x01), /* 0x41: MBOX_LOOP_PORT_ENABLE */ ISP_FC_OPMAP_HALF(0x0, 0x01, 0x1f, 0xcf), /* 0x42: MBOX_GET_RESOURCE_COUNT */ ISP_FC_OPMAP(0x01, 0x01), /* 0x43: MBOX_REQUEST_OFFLINE_MODE */ ISP_FC_OPMAP(0x00, 0x00), /* 0x44: */ ISP_FC_OPMAP(0x00, 0x00), /* 0x45: */ ISP_FC_OPMAP(0x00, 0x00), /* 0x46: */ ISP_FC_OPMAP(0xcf, 0x03), /* 0x47: GET PORT_DATABASE ENHANCED */ ISP_FC_OPMAP(0xcf, 0x0f), /* 0x48: MBOX_INIT_FIRMWARE_MULTI_ID */ ISP_FC_OPMAP(0xcd, 0x01), /* 0x49: MBOX_GET_VP_DATABASE */ ISP_FC_OPMAP_HALF(0x2, 0xcd, 0x0, 0x01), /* 0x4a: MBOX_GET_VP_DATABASE_ENTRY */ ISP_FC_OPMAP(0x00, 0x00), /* 0x4b: */ ISP_FC_OPMAP(0x00, 0x00), /* 0x4c: */ ISP_FC_OPMAP(0x00, 0x00), /* 0x4d: */ ISP_FC_OPMAP(0x00, 0x00), /* 0x4e: */ ISP_FC_OPMAP(0x00, 0x00), /* 0x4f: */ ISP_FC_OPMAP(0x00, 0x00), /* 0x50: */ ISP_FC_OPMAP(0x00, 0x00), /* 0x51: */ ISP_FC_OPMAP(0x00, 0x00), /* 0x52: */ ISP_FC_OPMAP(0x00, 0x00), /* 0x53: */ ISP_FC_OPMAP(0xcf, 0x01), /* 0x54: EXECUTE IOCB A64 */ ISP_FC_OPMAP(0x00, 0x00), /* 0x55: */ ISP_FC_OPMAP(0x00, 0x00), /* 0x56: */ ISP_FC_OPMAP(0x00, 0x00), /* 0x57: */ ISP_FC_OPMAP(0x00, 0x00), /* 0x58: */ ISP_FC_OPMAP(0x00, 0x00), /* 0x59: */ ISP_FC_OPMAP(0x00, 0x00), /* 0x5a: */ ISP_FC_OPMAP(0x03, 0x01), /* 0x5b: MBOX_DRIVER_HEARTBEAT */ ISP_FC_OPMAP(0xcf, 0x01), /* 0x5c: MBOX_FW_HEARTBEAT */ ISP_FC_OPMAP(0x07, 0x1f), /* 0x5d: MBOX_GET_SET_DATA_RATE */ ISP_FC_OPMAP(0x00, 0x00), /* 0x5e: */ ISP_FC_OPMAP(0x00, 0x00), /* 0x5f: */ ISP_FC_OPMAP(0xcf, 0x0f), /* 0x60: MBOX_INIT_FIRMWARE */ ISP_FC_OPMAP(0x00, 0x00), /* 0x61: */ ISP_FC_OPMAP(0x01, 0x01), /* 0x62: MBOX_INIT_LIP */ ISP_FC_OPMAP(0xcd, 0x03), /* 0x63: MBOX_GET_FC_AL_POSITION_MAP */ ISP_FC_OPMAP(0xcf, 0x01), /* 0x64: MBOX_GET_PORT_DB */ ISP_FC_OPMAP(0x07, 0x01), /* 0x65: MBOX_CLEAR_ACA */ ISP_FC_OPMAP(0x07, 0x01), /* 0x66: MBOX_TARGET_RESET */ ISP_FC_OPMAP(0x07, 0x01), /* 0x67: MBOX_CLEAR_TASK_SET */ ISP_FC_OPMAP(0x07, 0x01), /* 0x68: MBOX_ABORT_TASK_SET */ ISP_FC_OPMAP_HALF(0x00, 0x01, 0x0f, 0x1f), /* 0x69: MBOX_GET_FW_STATE */ ISP_FC_OPMAP_HALF(0x6, 0x03, 0x0, 0xcf), /* 0x6a: MBOX_GET_PORT_NAME */ ISP_FC_OPMAP(0xcf, 0x01), /* 0x6b: MBOX_GET_LINK_STATUS */ ISP_FC_OPMAP(0x0f, 0x01), /* 0x6c: MBOX_INIT_LIP_RESET */ ISP_FC_OPMAP(0x00, 0x00), /* 0x6d: */ ISP_FC_OPMAP(0xcf, 0x03), /* 0x6e: MBOX_SEND_SNS */ ISP_FC_OPMAP(0x0f, 0x07), /* 0x6f: MBOX_FABRIC_LOGIN */ ISP_FC_OPMAP_HALF(0x02, 0x03, 0x00, 0x03), /* 0x70: MBOX_SEND_CHANGE_REQUEST */ ISP_FC_OPMAP(0x03, 0x03), /* 0x71: MBOX_FABRIC_LOGOUT */ ISP_FC_OPMAP(0x0f, 0x0f), /* 0x72: MBOX_INIT_LIP_LOGIN */ ISP_FC_OPMAP(0x00, 0x00), /* 0x73: */ ISP_FC_OPMAP(0x07, 0x01), /* 0x74: LOGIN LOOP PORT */ ISP_FC_OPMAP_HALF(0x03, 0xcf, 0x00, 0x07), /* 0x75: GET PORT/NODE NAME LIST */ ISP_FC_OPMAP(0x4f, 0x01), /* 0x76: SET VENDOR ID */ ISP_FC_OPMAP(0xcd, 0x01), /* 0x77: INITIALIZE IP MAILBOX */ ISP_FC_OPMAP(0x00, 0x00), /* 0x78: */ ISP_FC_OPMAP(0x00, 0x00), /* 0x79: */ ISP_FC_OPMAP(0x00, 0x00), /* 0x7a: */ ISP_FC_OPMAP(0x00, 0x00), /* 0x7b: */ ISP_FC_OPMAP_HALF(0x03, 0x4f, 0x00, 0x07), /* 0x7c: Get ID List */ ISP_FC_OPMAP(0xcf, 0x01), /* 0x7d: SEND LFA */ ISP_FC_OPMAP(0x0f, 0x01) /* 0x7e: LUN RESET */ }; #define MAX_FC_OPCODE 0x7e /* * Footnotes * * (1): this sets bits 21..16 in mailbox register #8, which we nominally * do not access at this time in the core driver. The caller is * responsible for setting this register first (Gross!). The assumption * is that we won't overflow. */ static const char *fc_mbcmd_names[] = { "NO-OP", /* 00h */ "LOAD RAM", "EXEC FIRMWARE", "DUMP RAM", "WRITE RAM WORD", "READ RAM WORD", "MAILBOX REG TEST", "VERIFY CHECKSUM", "ABOUT FIRMWARE", "LOAD RAM (2100)", "DUMP RAM", "LOAD RISC RAM", "DUMP RISC RAM", "WRITE RAM WORD EXTENDED", "CHECK FIRMWARE", "READ RAM WORD EXTENDED", "INIT REQUEST QUEUE", /* 10h */ "INIT RESULT QUEUE", "EXECUTE IOCB", "WAKE UP", "STOP FIRMWARE", "ABORT", "ABORT DEVICE", "ABORT TARGET", "BUS RESET", "STOP QUEUE", "START QUEUE", "SINGLE STEP QUEUE", "ABORT QUEUE", "GET DEV QUEUE STATUS", NULL, "GET FIRMWARE STATUS", "GET LOOP ID", /* 20h */ NULL, "GET TIMEOUT PARAMS", NULL, NULL, NULL, NULL, NULL, "GET FIRMWARE OPTIONS", "GET PORT QUEUE PARAMS", "GENERATE SYSTEM ERROR", NULL, NULL, NULL, NULL, NULL, "WRITE SFP", /* 30h */ "READ SFP", "SET TIMEOUT PARAMS", NULL, NULL, NULL, NULL, NULL, "SET FIRMWARE OPTIONS", "SET PORT QUEUE PARAMS", NULL, "SET FC LED CONF", NULL, "RESTART NIC FIRMWARE", "ACCESS CONTROL", NULL, "LOOP PORT BYPASS", /* 40h */ "LOOP PORT ENABLE", "GET RESOURCE COUNT", "REQUEST NON PARTICIPATING MODE", "DIAGNOSTIC ECHO TEST", "DIAGNOSTIC LOOPBACK", NULL, "GET PORT DATABASE ENHANCED", "INIT FIRMWARE MULTI ID", "GET VP DATABASE", "GET VP DATABASE ENTRY", NULL, NULL, NULL, NULL, NULL, "GET FCF LIST", /* 50h */ "GET DCBX PARAMETERS", NULL, "HOST MEMORY COPY", "EXECUTE IOCB A64", NULL, NULL, "SEND RNID", NULL, "SET PARAMETERS", "GET PARAMETERS", "DRIVER HEARTBEAT", "FIRMWARE HEARTBEAT", "GET/SET DATA RATE", "SEND RNFT", NULL, "INIT FIRMWARE", /* 60h */ "GET INIT CONTROL BLOCK", "INIT LIP", "GET FC-AL POSITION MAP", "GET PORT DATABASE", "CLEAR ACA", "TARGET RESET", "CLEAR TASK SET", "ABORT TASK SET", "GET FW STATE", "GET PORT NAME", "GET LINK STATUS", "INIT LIP RESET", "GET LINK STATS & PRIVATE DATA CNTS", "SEND SNS", "FABRIC LOGIN", "SEND CHANGE REQUEST", /* 70h */ "FABRIC LOGOUT", "INIT LIP LOGIN", NULL, "LOGIN LOOP PORT", "GET PORT/NODE NAME LIST", "SET VENDOR ID", "INITIALIZE IP MAILBOX", NULL, NULL, "GET XGMAC STATS", NULL, "GET ID LIST", "SEND LFA", "LUN RESET" }; static void isp_mboxcmd(ispsoftc_t *isp, mbreg_t *mbp) { const char *cname, *xname, *sname; char tname[16], mname[16]; unsigned int ibits, obits, box, opcode; opcode = mbp->param[0]; if (IS_FC(isp)) { if (opcode > MAX_FC_OPCODE) { mbp->param[0] = MBOX_INVALID_COMMAND; isp_prt(isp, ISP_LOGERR, "Unknown Command 0x%x", opcode); return; } cname = fc_mbcmd_names[opcode]; ibits = ISP_FC_IBITS(opcode); obits = ISP_FC_OBITS(opcode); } else { if (opcode > MAX_SCSI_OPCODE) { mbp->param[0] = MBOX_INVALID_COMMAND; isp_prt(isp, ISP_LOGERR, "Unknown Command 0x%x", opcode); return; } cname = scsi_mbcmd_names[opcode]; ibits = ISP_SCSI_IBITS(opcode); obits = ISP_SCSI_OBITS(opcode); } if (cname == NULL) { cname = tname; ISP_SNPRINTF(tname, sizeof tname, "opcode %x", opcode); } isp_prt(isp, ISP_LOGDEBUG3, "Mailbox Command '%s'", cname); /* * Pick up any additional bits that the caller might have set. */ ibits |= mbp->ibits; obits |= mbp->obits; /* * Mask any bits that the caller wants us to mask */ ibits &= mbp->ibitm; obits &= mbp->obitm; if (ibits == 0 && obits == 0) { mbp->param[0] = MBOX_COMMAND_PARAM_ERROR; isp_prt(isp, ISP_LOGERR, "no parameters for 0x%x", opcode); return; } /* * Get exclusive usage of mailbox registers. */ if (MBOX_ACQUIRE(isp)) { mbp->param[0] = MBOX_REGS_BUSY; goto out; } for (box = 0; box < ISP_NMBOX(isp); box++) { if (ibits & (1 << box)) { isp_prt(isp, ISP_LOGDEBUG3, "IN mbox %d = 0x%04x", box, mbp->param[box]); ISP_WRITE(isp, MBOX_OFF(box), mbp->param[box]); } isp->isp_mboxtmp[box] = mbp->param[box] = 0; } isp->isp_lastmbxcmd = opcode; /* * We assume that we can't overwrite a previous command. */ isp->isp_obits = obits; isp->isp_mboxbsy = 1; /* * Set Host Interrupt condition so that RISC will pick up mailbox regs. */ if (IS_24XX(isp)) { ISP_WRITE(isp, BIU2400_HCCR, HCCR_2400_CMD_SET_HOST_INT); } else { ISP_WRITE(isp, HCCR, HCCR_CMD_SET_HOST_INT); } /* * While we haven't finished the command, spin our wheels here. */ MBOX_WAIT_COMPLETE(isp, mbp); /* * Did the command time out? */ if (mbp->param[0] == MBOX_TIMEOUT) { isp->isp_mboxbsy = 0; MBOX_RELEASE(isp); goto out; } /* * Copy back output registers. */ for (box = 0; box < ISP_NMBOX(isp); box++) { if (obits & (1 << box)) { mbp->param[box] = isp->isp_mboxtmp[box]; isp_prt(isp, ISP_LOGDEBUG3, "OUT mbox %d = 0x%04x", box, mbp->param[box]); } } isp->isp_mboxbsy = 0; MBOX_RELEASE(isp); out: if (mbp->logval == 0 || mbp->param[0] == MBOX_COMMAND_COMPLETE) return; if ((mbp->param[0] & 0xbfe0) == 0 && (mbp->logval & MBLOGMASK(mbp->param[0])) == 0) return; xname = NULL; sname = ""; switch (mbp->param[0]) { case MBOX_INVALID_COMMAND: xname = "INVALID COMMAND"; break; case MBOX_HOST_INTERFACE_ERROR: xname = "HOST INTERFACE ERROR"; break; case MBOX_TEST_FAILED: xname = "TEST FAILED"; break; case MBOX_COMMAND_ERROR: xname = "COMMAND ERROR"; ISP_SNPRINTF(mname, sizeof(mname), " subcode 0x%x", mbp->param[1]); sname = mname; break; case MBOX_COMMAND_PARAM_ERROR: xname = "COMMAND PARAMETER ERROR"; break; case MBOX_PORT_ID_USED: xname = "PORT ID ALREADY IN USE"; break; case MBOX_LOOP_ID_USED: xname = "LOOP ID ALREADY IN USE"; break; case MBOX_ALL_IDS_USED: xname = "ALL LOOP IDS IN USE"; break; case MBOX_NOT_LOGGED_IN: xname = "NOT LOGGED IN"; break; case MBOX_LINK_DOWN_ERROR: xname = "LINK DOWN ERROR"; break; case MBOX_LOOPBACK_ERROR: xname = "LOOPBACK ERROR"; break; case MBOX_CHECKSUM_ERROR: xname = "CHECKSUM ERROR"; break; case MBOX_INVALID_PRODUCT_KEY: xname = "INVALID PRODUCT KEY"; break; case MBOX_REGS_BUSY: xname = "REGISTERS BUSY"; break; case MBOX_TIMEOUT: xname = "TIMEOUT"; break; default: ISP_SNPRINTF(mname, sizeof mname, "error 0x%x", mbp->param[0]); xname = mname; break; } if (xname) { isp_prt(isp, ISP_LOGALL, "Mailbox Command '%s' failed (%s%s)", cname, xname, sname); } } static int isp_fw_state(ispsoftc_t *isp, int chan) { if (IS_FC(isp)) { mbreg_t mbs; MBSINIT(&mbs, MBOX_GET_FW_STATE, MBLOGALL, 0); isp_mboxcmd(isp, &mbs); if (mbs.param[0] == MBOX_COMMAND_COMPLETE) { return (mbs.param[1]); } } return (FW_ERROR); } static void isp_spi_update(ispsoftc_t *isp, int chan) { int tgt; mbreg_t mbs; sdparam *sdp; if (IS_FC(isp)) { /* * There are no 'per-bus' settings for Fibre Channel. */ return; } sdp = SDPARAM(isp, chan); sdp->update = 0; for (tgt = 0; tgt < MAX_TARGETS; tgt++) { uint16_t flags, period, offset; int get; if (sdp->isp_devparam[tgt].dev_enable == 0) { sdp->isp_devparam[tgt].dev_update = 0; sdp->isp_devparam[tgt].dev_refresh = 0; isp_prt(isp, ISP_LOGDEBUG0, "skipping target %d bus %d update", tgt, chan); continue; } /* * If the goal is to update the status of the device, * take what's in goal_flags and try and set the device * toward that. Otherwise, if we're just refreshing the * current device state, get the current parameters. */ MBSINIT(&mbs, 0, MBLOGALL, 0); /* * Refresh overrides set */ if (sdp->isp_devparam[tgt].dev_refresh) { mbs.param[0] = MBOX_GET_TARGET_PARAMS; get = 1; } else if (sdp->isp_devparam[tgt].dev_update) { mbs.param[0] = MBOX_SET_TARGET_PARAMS; /* * Make sure goal_flags has "Renegotiate on Error" * on and "Freeze Queue on Error" off. */ sdp->isp_devparam[tgt].goal_flags |= DPARM_RENEG; sdp->isp_devparam[tgt].goal_flags &= ~DPARM_QFRZ; mbs.param[2] = sdp->isp_devparam[tgt].goal_flags; /* * Insist that PARITY must be enabled * if SYNC or WIDE is enabled. */ if ((mbs.param[2] & (DPARM_SYNC|DPARM_WIDE)) != 0) { mbs.param[2] |= DPARM_PARITY; } if (mbs.param[2] & DPARM_SYNC) { mbs.param[3] = (sdp->isp_devparam[tgt].goal_offset << 8) | (sdp->isp_devparam[tgt].goal_period); } /* * A command completion later that has * RQSTF_NEGOTIATION set can cause * the dev_refresh/announce cycle also. * * Note: It is really important to update our current * flags with at least the state of TAG capabilities- * otherwise we might try and send a tagged command * when we have it all turned off. So change it here * to say that current already matches goal. */ sdp->isp_devparam[tgt].actv_flags &= ~DPARM_TQING; sdp->isp_devparam[tgt].actv_flags |= (sdp->isp_devparam[tgt].goal_flags & DPARM_TQING); isp_prt(isp, ISP_LOGDEBUG0, "bus %d set tgt %d flags 0x%x off 0x%x period 0x%x", chan, tgt, mbs.param[2], mbs.param[3] >> 8, mbs.param[3] & 0xff); get = 0; } else { continue; } mbs.param[1] = (chan << 15) | (tgt << 8); isp_mboxcmd(isp, &mbs); if (mbs.param[0] != MBOX_COMMAND_COMPLETE) { continue; } if (get == 0) { sdp->sendmarker = 1; sdp->isp_devparam[tgt].dev_update = 0; sdp->isp_devparam[tgt].dev_refresh = 1; } else { sdp->isp_devparam[tgt].dev_refresh = 0; flags = mbs.param[2]; period = mbs.param[3] & 0xff; offset = mbs.param[3] >> 8; sdp->isp_devparam[tgt].actv_flags = flags; sdp->isp_devparam[tgt].actv_period = period; sdp->isp_devparam[tgt].actv_offset = offset; isp_async(isp, ISPASYNC_NEW_TGT_PARAMS, chan, tgt); } } for (tgt = 0; tgt < MAX_TARGETS; tgt++) { if (sdp->isp_devparam[tgt].dev_update || sdp->isp_devparam[tgt].dev_refresh) { sdp->update = 1; break; } } } static void isp_setdfltsdparm(ispsoftc_t *isp) { int tgt; sdparam *sdp, *sdp1; sdp = SDPARAM(isp, 0); if (IS_DUALBUS(isp)) sdp1 = sdp + 1; else sdp1 = NULL; /* * Establish some default parameters. */ sdp->isp_cmd_dma_burst_enable = 0; sdp->isp_data_dma_burst_enabl = 1; sdp->isp_fifo_threshold = 0; sdp->isp_initiator_id = DEFAULT_IID(isp, 0); if (isp->isp_type >= ISP_HA_SCSI_1040) { sdp->isp_async_data_setup = 9; } else { sdp->isp_async_data_setup = 6; } sdp->isp_selection_timeout = 250; sdp->isp_max_queue_depth = MAXISPREQUEST(isp); sdp->isp_tag_aging = 8; sdp->isp_bus_reset_delay = 5; /* * Don't retry selection, busy or queue full automatically- reflect * these back to us. */ sdp->isp_retry_count = 0; sdp->isp_retry_delay = 0; for (tgt = 0; tgt < MAX_TARGETS; tgt++) { sdp->isp_devparam[tgt].exc_throttle = ISP_EXEC_THROTTLE; sdp->isp_devparam[tgt].dev_enable = 1; } /* * The trick here is to establish a default for the default (honk!) * state (goal_flags). Then try and get the current status from * the card to fill in the current state. We don't, in fact, set * the default to the SAFE default state- that's not the goal state. */ for (tgt = 0; tgt < MAX_TARGETS; tgt++) { uint8_t off, per; sdp->isp_devparam[tgt].actv_offset = 0; sdp->isp_devparam[tgt].actv_period = 0; sdp->isp_devparam[tgt].actv_flags = 0; sdp->isp_devparam[tgt].goal_flags = sdp->isp_devparam[tgt].nvrm_flags = DPARM_DEFAULT; /* * We default to Wide/Fast for versions less than a 1040 * (unless it's SBus). */ if (IS_ULTRA3(isp)) { off = ISP_80M_SYNCPARMS >> 8; per = ISP_80M_SYNCPARMS & 0xff; } else if (IS_ULTRA2(isp)) { off = ISP_40M_SYNCPARMS >> 8; per = ISP_40M_SYNCPARMS & 0xff; } else if (IS_1240(isp)) { off = ISP_20M_SYNCPARMS >> 8; per = ISP_20M_SYNCPARMS & 0xff; } else if ((isp->isp_bustype == ISP_BT_SBUS && isp->isp_type < ISP_HA_SCSI_1020A) || (isp->isp_bustype == ISP_BT_PCI && isp->isp_type < ISP_HA_SCSI_1040) || (isp->isp_clock && isp->isp_clock < 60) || (sdp->isp_ultramode == 0)) { off = ISP_10M_SYNCPARMS >> 8; per = ISP_10M_SYNCPARMS & 0xff; } else { off = ISP_20M_SYNCPARMS_1040 >> 8; per = ISP_20M_SYNCPARMS_1040 & 0xff; } sdp->isp_devparam[tgt].goal_offset = sdp->isp_devparam[tgt].nvrm_offset = off; sdp->isp_devparam[tgt].goal_period = sdp->isp_devparam[tgt].nvrm_period = per; } /* * If we're a dual bus card, just copy the data over */ if (sdp1) { *sdp1 = *sdp; sdp1->isp_initiator_id = DEFAULT_IID(isp, 1); } /* * If we've not been told to avoid reading NVRAM, try and read it. * If we're successful reading it, we can then return because NVRAM * will tell us what the desired settings are. Otherwise, we establish * some reasonable 'fake' nvram and goal defaults. */ if ((isp->isp_confopts & ISP_CFG_NONVRAM) == 0) { mbreg_t mbs; if (isp_read_nvram(isp, 0) == 0) { if (IS_DUALBUS(isp)) { if (isp_read_nvram(isp, 1) == 0) { return; } } } MBSINIT(&mbs, MBOX_GET_ACT_NEG_STATE, MBLOGNONE, 0); isp_mboxcmd(isp, &mbs); if (mbs.param[0] != MBOX_COMMAND_COMPLETE) { sdp->isp_req_ack_active_neg = 1; sdp->isp_data_line_active_neg = 1; if (sdp1) { sdp1->isp_req_ack_active_neg = 1; sdp1->isp_data_line_active_neg = 1; } } else { sdp->isp_req_ack_active_neg = (mbs.param[1] >> 4) & 0x1; sdp->isp_data_line_active_neg = (mbs.param[1] >> 5) & 0x1; if (sdp1) { sdp1->isp_req_ack_active_neg = (mbs.param[2] >> 4) & 0x1; sdp1->isp_data_line_active_neg = (mbs.param[2] >> 5) & 0x1; } } } } static void isp_setdfltfcparm(ispsoftc_t *isp, int chan) { fcparam *fcp = FCPARAM(isp, chan); /* * Establish some default parameters. */ fcp->role = DEFAULT_ROLE(isp, chan); fcp->isp_maxalloc = ICB_DFLT_ALLOC; fcp->isp_retry_delay = ICB_DFLT_RDELAY; fcp->isp_retry_count = ICB_DFLT_RCOUNT; fcp->isp_loopid = DEFAULT_LOOPID(isp, chan); fcp->isp_wwnn_nvram = DEFAULT_NODEWWN(isp, chan); fcp->isp_wwpn_nvram = DEFAULT_PORTWWN(isp, chan); fcp->isp_fwoptions = 0; fcp->isp_xfwoptions = 0; fcp->isp_zfwoptions = 0; fcp->isp_lasthdl = NIL_HANDLE; fcp->isp_login_hdl = NIL_HANDLE; if (IS_24XX(isp)) { fcp->isp_fwoptions |= ICB2400_OPT1_FAIRNESS; fcp->isp_fwoptions |= ICB2400_OPT1_HARD_ADDRESS; if (isp->isp_confopts & ISP_CFG_FULL_DUPLEX) fcp->isp_fwoptions |= ICB2400_OPT1_FULL_DUPLEX; fcp->isp_fwoptions |= ICB2400_OPT1_BOTH_WWNS; fcp->isp_xfwoptions |= ICB2400_OPT2_LOOP_2_PTP; fcp->isp_zfwoptions |= ICB2400_OPT3_RATE_AUTO; } else { fcp->isp_fwoptions |= ICBOPT_FAIRNESS; fcp->isp_fwoptions |= ICBOPT_PDBCHANGE_AE; fcp->isp_fwoptions |= ICBOPT_HARD_ADDRESS; if (isp->isp_confopts & ISP_CFG_FULL_DUPLEX) fcp->isp_fwoptions |= ICBOPT_FULL_DUPLEX; /* * Make sure this is turned off now until we get * extended options from NVRAM */ fcp->isp_fwoptions &= ~ICBOPT_EXTENDED; fcp->isp_xfwoptions |= ICBXOPT_LOOP_2_PTP; fcp->isp_zfwoptions |= ICBZOPT_RATE_AUTO; } /* * Now try and read NVRAM unless told to not do so. * This will set fcparam's isp_wwnn_nvram && isp_wwpn_nvram. */ if ((isp->isp_confopts & ISP_CFG_NONVRAM) == 0) { int i, j = 0; /* * Give a couple of tries at reading NVRAM. */ for (i = 0; i < 2; i++) { j = isp_read_nvram(isp, chan); if (j == 0) { break; } } if (j) { isp->isp_confopts |= ISP_CFG_NONVRAM; } } fcp->isp_wwnn = ACTIVE_NODEWWN(isp, chan); fcp->isp_wwpn = ACTIVE_PORTWWN(isp, chan); isp_prt(isp, ISP_LOGCONFIG, "Chan %d 0x%08x%08x/0x%08x%08x Role %s", chan, (uint32_t) (fcp->isp_wwnn >> 32), (uint32_t) (fcp->isp_wwnn), (uint32_t) (fcp->isp_wwpn >> 32), (uint32_t) (fcp->isp_wwpn), isp_class3_roles[fcp->role]); } /* * Re-initialize the ISP and complete all orphaned commands * with a 'botched' notice. The reset/init routines should * not disturb an already active list of commands. */ int isp_reinit(ispsoftc_t *isp, int do_load_defaults) { int i, res = 0; if (isp->isp_state > ISP_RESETSTATE) isp_stop(isp); if (isp->isp_state != ISP_RESETSTATE) isp_reset(isp, do_load_defaults); if (isp->isp_state != ISP_RESETSTATE) { res = EIO; isp_prt(isp, ISP_LOGERR, "%s: cannot reset card", __func__); goto cleanup; } isp_init(isp); if (isp->isp_state > ISP_RESETSTATE && isp->isp_state != ISP_RUNSTATE) { res = EIO; isp_prt(isp, ISP_LOGERR, "%s: cannot init card", __func__); ISP_DISABLE_INTS(isp); if (IS_FC(isp)) { /* * If we're in ISP_ROLE_NONE, turn off the lasers. */ if (!IS_24XX(isp)) { ISP_WRITE(isp, BIU2100_CSR, BIU2100_FPM0_REGS); ISP_WRITE(isp, FPM_DIAG_CONFIG, FPM_SOFT_RESET); ISP_WRITE(isp, BIU2100_CSR, BIU2100_FB_REGS); ISP_WRITE(isp, FBM_CMD, FBMCMD_FIFO_RESET_ALL); ISP_WRITE(isp, BIU2100_CSR, BIU2100_RISC_REGS); } } } cleanup: isp_clear_commands(isp); if (IS_FC(isp)) { for (i = 0; i < isp->isp_nchan; i++) isp_clear_portdb(isp, i); } return (res); } /* * NVRAM Routines */ static int isp_read_nvram(ispsoftc_t *isp, int bus) { int i, amt, retval; uint8_t csum, minversion; union { uint8_t _x[ISP2400_NVRAM_SIZE]; uint16_t _s[ISP2400_NVRAM_SIZE>>1]; } _n; #define nvram_data _n._x #define nvram_words _n._s if (IS_24XX(isp)) { return (isp_read_nvram_2400(isp, nvram_data)); } else if (IS_FC(isp)) { amt = ISP2100_NVRAM_SIZE; minversion = 1; } else if (IS_ULTRA2(isp)) { amt = ISP1080_NVRAM_SIZE; minversion = 0; } else { amt = ISP_NVRAM_SIZE; minversion = 2; } for (i = 0; i < amt>>1; i++) { isp_rdnvram_word(isp, i, &nvram_words[i]); } if (nvram_data[0] != 'I' || nvram_data[1] != 'S' || nvram_data[2] != 'P') { if (isp->isp_bustype != ISP_BT_SBUS) { isp_prt(isp, ISP_LOGWARN, "invalid NVRAM header"); isp_prt(isp, ISP_LOGDEBUG0, "%x %x %x", nvram_data[0], nvram_data[1], nvram_data[2]); } retval = -1; goto out; } for (csum = 0, i = 0; i < amt; i++) { csum += nvram_data[i]; } if (csum != 0) { isp_prt(isp, ISP_LOGWARN, "invalid NVRAM checksum"); retval = -1; goto out; } if (ISP_NVRAM_VERSION(nvram_data) < minversion) { isp_prt(isp, ISP_LOGWARN, "version %d NVRAM not understood", ISP_NVRAM_VERSION(nvram_data)); retval = -1; goto out; } if (IS_ULTRA3(isp)) { isp_parse_nvram_12160(isp, bus, nvram_data); } else if (IS_1080(isp)) { isp_parse_nvram_1080(isp, bus, nvram_data); } else if (IS_1280(isp) || IS_1240(isp)) { isp_parse_nvram_1080(isp, bus, nvram_data); } else if (IS_SCSI(isp)) { isp_parse_nvram_1020(isp, nvram_data); } else { isp_parse_nvram_2100(isp, nvram_data); } retval = 0; out: return (retval); #undef nvram_data #undef nvram_words } static int isp_read_nvram_2400(ispsoftc_t *isp, uint8_t *nvram_data) { int retval = 0; uint32_t addr, csum, lwrds, *dptr; if (isp->isp_port) { addr = ISP2400_NVRAM_PORT1_ADDR; } else { addr = ISP2400_NVRAM_PORT0_ADDR; } dptr = (uint32_t *) nvram_data; for (lwrds = 0; lwrds < ISP2400_NVRAM_SIZE >> 2; lwrds++) { isp_rd_2400_nvram(isp, addr++, dptr++); } if (nvram_data[0] != 'I' || nvram_data[1] != 'S' || nvram_data[2] != 'P') { isp_prt(isp, ISP_LOGWARN, "invalid NVRAM header (%x %x %x)", nvram_data[0], nvram_data[1], nvram_data[2]); retval = -1; goto out; } dptr = (uint32_t *) nvram_data; for (csum = 0, lwrds = 0; lwrds < ISP2400_NVRAM_SIZE >> 2; lwrds++) { uint32_t tmp; ISP_IOXGET_32(isp, &dptr[lwrds], tmp); csum += tmp; } if (csum != 0) { isp_prt(isp, ISP_LOGWARN, "invalid NVRAM checksum"); retval = -1; goto out; } isp_parse_nvram_2400(isp, nvram_data); out: return (retval); } static void isp_rdnvram_word(ispsoftc_t *isp, int wo, uint16_t *rp) { int i, cbits; uint16_t bit, rqst, junk; ISP_WRITE(isp, BIU_NVRAM, BIU_NVRAM_SELECT); ISP_DELAY(10); ISP_WRITE(isp, BIU_NVRAM, BIU_NVRAM_SELECT|BIU_NVRAM_CLOCK); ISP_DELAY(10); if (IS_FC(isp)) { wo &= ((ISP2100_NVRAM_SIZE >> 1) - 1); if (IS_2312(isp) && isp->isp_port) { wo += 128; } rqst = (ISP_NVRAM_READ << 8) | wo; cbits = 10; } else if (IS_ULTRA2(isp)) { wo &= ((ISP1080_NVRAM_SIZE >> 1) - 1); rqst = (ISP_NVRAM_READ << 8) | wo; cbits = 10; } else { wo &= ((ISP_NVRAM_SIZE >> 1) - 1); rqst = (ISP_NVRAM_READ << 6) | wo; cbits = 8; } /* * Clock the word select request out... */ for (i = cbits; i >= 0; i--) { if ((rqst >> i) & 1) { bit = BIU_NVRAM_SELECT | BIU_NVRAM_DATAOUT; } else { bit = BIU_NVRAM_SELECT; } ISP_WRITE(isp, BIU_NVRAM, bit); ISP_DELAY(10); junk = ISP_READ(isp, BIU_NVRAM); /* force PCI flush */ ISP_WRITE(isp, BIU_NVRAM, bit | BIU_NVRAM_CLOCK); ISP_DELAY(10); junk = ISP_READ(isp, BIU_NVRAM); /* force PCI flush */ ISP_WRITE(isp, BIU_NVRAM, bit); ISP_DELAY(10); junk = ISP_READ(isp, BIU_NVRAM); /* force PCI flush */ } /* * Now read the result back in (bits come back in MSB format). */ *rp = 0; for (i = 0; i < 16; i++) { uint16_t rv; *rp <<= 1; ISP_WRITE(isp, BIU_NVRAM, BIU_NVRAM_SELECT|BIU_NVRAM_CLOCK); ISP_DELAY(10); rv = ISP_READ(isp, BIU_NVRAM); if (rv & BIU_NVRAM_DATAIN) { *rp |= 1; } ISP_DELAY(10); ISP_WRITE(isp, BIU_NVRAM, BIU_NVRAM_SELECT); ISP_DELAY(10); junk = ISP_READ(isp, BIU_NVRAM); /* force PCI flush */ } ISP_WRITE(isp, BIU_NVRAM, 0); ISP_DELAY(10); junk = ISP_READ(isp, BIU_NVRAM); /* force PCI flush */ ISP_SWIZZLE_NVRAM_WORD(isp, rp); } static void isp_rd_2400_nvram(ispsoftc_t *isp, uint32_t addr, uint32_t *rp) { int loops = 0; uint32_t base = 0x7ffe0000; uint32_t tmp = 0; if (IS_26XX(isp)) { base = 0x7fe7c000; /* XXX: Observation, may be wrong. */ } else if (IS_25XX(isp)) { base = 0x7ff00000 | 0x48000; } ISP_WRITE(isp, BIU2400_FLASH_ADDR, base | addr); for (loops = 0; loops < 5000; loops++) { ISP_DELAY(10); tmp = ISP_READ(isp, BIU2400_FLASH_ADDR); if ((tmp & (1U << 31)) != 0) { break; } } if (tmp & (1U << 31)) { *rp = ISP_READ(isp, BIU2400_FLASH_DATA); ISP_SWIZZLE_NVRAM_LONG(isp, rp); } else { *rp = 0xffffffff; } } static void isp_parse_nvram_1020(ispsoftc_t *isp, uint8_t *nvram_data) { sdparam *sdp = SDPARAM(isp, 0); int tgt; sdp->isp_fifo_threshold = ISP_NVRAM_FIFO_THRESHOLD(nvram_data) | (ISP_NVRAM_FIFO_THRESHOLD_128(nvram_data) << 2); if ((isp->isp_confopts & ISP_CFG_OWNLOOPID) == 0) sdp->isp_initiator_id = ISP_NVRAM_INITIATOR_ID(nvram_data); sdp->isp_bus_reset_delay = ISP_NVRAM_BUS_RESET_DELAY(nvram_data); sdp->isp_retry_count = ISP_NVRAM_BUS_RETRY_COUNT(nvram_data); sdp->isp_retry_delay = ISP_NVRAM_BUS_RETRY_DELAY(nvram_data); sdp->isp_async_data_setup = ISP_NVRAM_ASYNC_DATA_SETUP_TIME(nvram_data); if (isp->isp_type >= ISP_HA_SCSI_1040) { if (sdp->isp_async_data_setup < 9) { sdp->isp_async_data_setup = 9; } } else { if (sdp->isp_async_data_setup != 6) { sdp->isp_async_data_setup = 6; } } sdp->isp_req_ack_active_neg = ISP_NVRAM_REQ_ACK_ACTIVE_NEGATION(nvram_data); sdp->isp_data_line_active_neg = ISP_NVRAM_DATA_LINE_ACTIVE_NEGATION(nvram_data); sdp->isp_data_dma_burst_enabl = ISP_NVRAM_DATA_DMA_BURST_ENABLE(nvram_data); sdp->isp_cmd_dma_burst_enable = ISP_NVRAM_CMD_DMA_BURST_ENABLE(nvram_data); sdp->isp_tag_aging = ISP_NVRAM_TAG_AGE_LIMIT(nvram_data); sdp->isp_selection_timeout = ISP_NVRAM_SELECTION_TIMEOUT(nvram_data); sdp->isp_max_queue_depth = ISP_NVRAM_MAX_QUEUE_DEPTH(nvram_data); sdp->isp_fast_mttr = ISP_NVRAM_FAST_MTTR_ENABLE(nvram_data); for (tgt = 0; tgt < MAX_TARGETS; tgt++) { sdp->isp_devparam[tgt].dev_enable = ISP_NVRAM_TGT_DEVICE_ENABLE(nvram_data, tgt); sdp->isp_devparam[tgt].exc_throttle = ISP_NVRAM_TGT_EXEC_THROTTLE(nvram_data, tgt); sdp->isp_devparam[tgt].nvrm_offset = ISP_NVRAM_TGT_SYNC_OFFSET(nvram_data, tgt); sdp->isp_devparam[tgt].nvrm_period = ISP_NVRAM_TGT_SYNC_PERIOD(nvram_data, tgt); /* * We probably shouldn't lie about this, but it * it makes it much safer if we limit NVRAM values * to sanity. */ if (isp->isp_type < ISP_HA_SCSI_1040) { /* * If we're not ultra, we can't possibly * be a shorter period than this. */ if (sdp->isp_devparam[tgt].nvrm_period < 0x19) { sdp->isp_devparam[tgt].nvrm_period = 0x19; } if (sdp->isp_devparam[tgt].nvrm_offset > 0xc) { sdp->isp_devparam[tgt].nvrm_offset = 0x0c; } } else { if (sdp->isp_devparam[tgt].nvrm_offset > 0x8) { sdp->isp_devparam[tgt].nvrm_offset = 0x8; } } sdp->isp_devparam[tgt].nvrm_flags = 0; if (ISP_NVRAM_TGT_RENEG(nvram_data, tgt)) sdp->isp_devparam[tgt].nvrm_flags |= DPARM_RENEG; sdp->isp_devparam[tgt].nvrm_flags |= DPARM_ARQ; if (ISP_NVRAM_TGT_TQING(nvram_data, tgt)) sdp->isp_devparam[tgt].nvrm_flags |= DPARM_TQING; if (ISP_NVRAM_TGT_SYNC(nvram_data, tgt)) sdp->isp_devparam[tgt].nvrm_flags |= DPARM_SYNC; if (ISP_NVRAM_TGT_WIDE(nvram_data, tgt)) sdp->isp_devparam[tgt].nvrm_flags |= DPARM_WIDE; if (ISP_NVRAM_TGT_PARITY(nvram_data, tgt)) sdp->isp_devparam[tgt].nvrm_flags |= DPARM_PARITY; if (ISP_NVRAM_TGT_DISC(nvram_data, tgt)) sdp->isp_devparam[tgt].nvrm_flags |= DPARM_DISC; sdp->isp_devparam[tgt].actv_flags = 0; /* we don't know */ sdp->isp_devparam[tgt].goal_offset = sdp->isp_devparam[tgt].nvrm_offset; sdp->isp_devparam[tgt].goal_period = sdp->isp_devparam[tgt].nvrm_period; sdp->isp_devparam[tgt].goal_flags = sdp->isp_devparam[tgt].nvrm_flags; } } static void isp_parse_nvram_1080(ispsoftc_t *isp, int bus, uint8_t *nvram_data) { sdparam *sdp = SDPARAM(isp, bus); int tgt; sdp->isp_fifo_threshold = ISP1080_NVRAM_FIFO_THRESHOLD(nvram_data); if ((isp->isp_confopts & ISP_CFG_OWNLOOPID) == 0) sdp->isp_initiator_id = ISP1080_NVRAM_INITIATOR_ID(nvram_data, bus); sdp->isp_bus_reset_delay = ISP1080_NVRAM_BUS_RESET_DELAY(nvram_data, bus); sdp->isp_retry_count = ISP1080_NVRAM_BUS_RETRY_COUNT(nvram_data, bus); sdp->isp_retry_delay = ISP1080_NVRAM_BUS_RETRY_DELAY(nvram_data, bus); sdp->isp_async_data_setup = ISP1080_NVRAM_ASYNC_DATA_SETUP_TIME(nvram_data, bus); sdp->isp_req_ack_active_neg = ISP1080_NVRAM_REQ_ACK_ACTIVE_NEGATION(nvram_data, bus); sdp->isp_data_line_active_neg = ISP1080_NVRAM_DATA_LINE_ACTIVE_NEGATION(nvram_data, bus); sdp->isp_data_dma_burst_enabl = ISP1080_NVRAM_BURST_ENABLE(nvram_data); sdp->isp_cmd_dma_burst_enable = ISP1080_NVRAM_BURST_ENABLE(nvram_data); sdp->isp_selection_timeout = ISP1080_NVRAM_SELECTION_TIMEOUT(nvram_data, bus); sdp->isp_max_queue_depth = ISP1080_NVRAM_MAX_QUEUE_DEPTH(nvram_data, bus); for (tgt = 0; tgt < MAX_TARGETS; tgt++) { sdp->isp_devparam[tgt].dev_enable = ISP1080_NVRAM_TGT_DEVICE_ENABLE(nvram_data, tgt, bus); sdp->isp_devparam[tgt].exc_throttle = ISP1080_NVRAM_TGT_EXEC_THROTTLE(nvram_data, tgt, bus); sdp->isp_devparam[tgt].nvrm_offset = ISP1080_NVRAM_TGT_SYNC_OFFSET(nvram_data, tgt, bus); sdp->isp_devparam[tgt].nvrm_period = ISP1080_NVRAM_TGT_SYNC_PERIOD(nvram_data, tgt, bus); sdp->isp_devparam[tgt].nvrm_flags = 0; if (ISP1080_NVRAM_TGT_RENEG(nvram_data, tgt, bus)) sdp->isp_devparam[tgt].nvrm_flags |= DPARM_RENEG; sdp->isp_devparam[tgt].nvrm_flags |= DPARM_ARQ; if (ISP1080_NVRAM_TGT_TQING(nvram_data, tgt, bus)) sdp->isp_devparam[tgt].nvrm_flags |= DPARM_TQING; if (ISP1080_NVRAM_TGT_SYNC(nvram_data, tgt, bus)) sdp->isp_devparam[tgt].nvrm_flags |= DPARM_SYNC; if (ISP1080_NVRAM_TGT_WIDE(nvram_data, tgt, bus)) sdp->isp_devparam[tgt].nvrm_flags |= DPARM_WIDE; if (ISP1080_NVRAM_TGT_PARITY(nvram_data, tgt, bus)) sdp->isp_devparam[tgt].nvrm_flags |= DPARM_PARITY; if (ISP1080_NVRAM_TGT_DISC(nvram_data, tgt, bus)) sdp->isp_devparam[tgt].nvrm_flags |= DPARM_DISC; sdp->isp_devparam[tgt].actv_flags = 0; sdp->isp_devparam[tgt].goal_offset = sdp->isp_devparam[tgt].nvrm_offset; sdp->isp_devparam[tgt].goal_period = sdp->isp_devparam[tgt].nvrm_period; sdp->isp_devparam[tgt].goal_flags = sdp->isp_devparam[tgt].nvrm_flags; } } static void isp_parse_nvram_12160(ispsoftc_t *isp, int bus, uint8_t *nvram_data) { sdparam *sdp = SDPARAM(isp, bus); int tgt; sdp->isp_fifo_threshold = ISP12160_NVRAM_FIFO_THRESHOLD(nvram_data); if ((isp->isp_confopts & ISP_CFG_OWNLOOPID) == 0) sdp->isp_initiator_id = ISP12160_NVRAM_INITIATOR_ID(nvram_data, bus); sdp->isp_bus_reset_delay = ISP12160_NVRAM_BUS_RESET_DELAY(nvram_data, bus); sdp->isp_retry_count = ISP12160_NVRAM_BUS_RETRY_COUNT(nvram_data, bus); sdp->isp_retry_delay = ISP12160_NVRAM_BUS_RETRY_DELAY(nvram_data, bus); sdp->isp_async_data_setup = ISP12160_NVRAM_ASYNC_DATA_SETUP_TIME(nvram_data, bus); sdp->isp_req_ack_active_neg = ISP12160_NVRAM_REQ_ACK_ACTIVE_NEGATION(nvram_data, bus); sdp->isp_data_line_active_neg = ISP12160_NVRAM_DATA_LINE_ACTIVE_NEGATION(nvram_data, bus); sdp->isp_data_dma_burst_enabl = ISP12160_NVRAM_BURST_ENABLE(nvram_data); sdp->isp_cmd_dma_burst_enable = ISP12160_NVRAM_BURST_ENABLE(nvram_data); sdp->isp_selection_timeout = ISP12160_NVRAM_SELECTION_TIMEOUT(nvram_data, bus); sdp->isp_max_queue_depth = ISP12160_NVRAM_MAX_QUEUE_DEPTH(nvram_data, bus); for (tgt = 0; tgt < MAX_TARGETS; tgt++) { sdp->isp_devparam[tgt].dev_enable = ISP12160_NVRAM_TGT_DEVICE_ENABLE(nvram_data, tgt, bus); sdp->isp_devparam[tgt].exc_throttle = ISP12160_NVRAM_TGT_EXEC_THROTTLE(nvram_data, tgt, bus); sdp->isp_devparam[tgt].nvrm_offset = ISP12160_NVRAM_TGT_SYNC_OFFSET(nvram_data, tgt, bus); sdp->isp_devparam[tgt].nvrm_period = ISP12160_NVRAM_TGT_SYNC_PERIOD(nvram_data, tgt, bus); sdp->isp_devparam[tgt].nvrm_flags = 0; if (ISP12160_NVRAM_TGT_RENEG(nvram_data, tgt, bus)) sdp->isp_devparam[tgt].nvrm_flags |= DPARM_RENEG; sdp->isp_devparam[tgt].nvrm_flags |= DPARM_ARQ; if (ISP12160_NVRAM_TGT_TQING(nvram_data, tgt, bus)) sdp->isp_devparam[tgt].nvrm_flags |= DPARM_TQING; if (ISP12160_NVRAM_TGT_SYNC(nvram_data, tgt, bus)) sdp->isp_devparam[tgt].nvrm_flags |= DPARM_SYNC; if (ISP12160_NVRAM_TGT_WIDE(nvram_data, tgt, bus)) sdp->isp_devparam[tgt].nvrm_flags |= DPARM_WIDE; if (ISP12160_NVRAM_TGT_PARITY(nvram_data, tgt, bus)) sdp->isp_devparam[tgt].nvrm_flags |= DPARM_PARITY; if (ISP12160_NVRAM_TGT_DISC(nvram_data, tgt, bus)) sdp->isp_devparam[tgt].nvrm_flags |= DPARM_DISC; sdp->isp_devparam[tgt].actv_flags = 0; sdp->isp_devparam[tgt].goal_offset = sdp->isp_devparam[tgt].nvrm_offset; sdp->isp_devparam[tgt].goal_period = sdp->isp_devparam[tgt].nvrm_period; sdp->isp_devparam[tgt].goal_flags = sdp->isp_devparam[tgt].nvrm_flags; } } static void isp_parse_nvram_2100(ispsoftc_t *isp, uint8_t *nvram_data) { fcparam *fcp = FCPARAM(isp, 0); uint64_t wwn; /* * There is NVRAM storage for both Port and Node entities- * but the Node entity appears to be unused on all the cards * I can find. However, we should account for this being set * at some point in the future. * * Qlogic WWNs have an NAA of 2, but usually nothing shows up in * bits 48..60. In the case of the 2202, it appears that they do * use bit 48 to distinguish between the two instances on the card. * The 2204, which I've never seen, *probably* extends this method. */ wwn = ISP2100_NVRAM_PORT_NAME(nvram_data); if (wwn) { isp_prt(isp, ISP_LOGCONFIG, "NVRAM Port WWN 0x%08x%08x", (uint32_t) (wwn >> 32), (uint32_t) (wwn)); if ((wwn >> 60) == 0) { wwn |= (((uint64_t) 2)<< 60); } } fcp->isp_wwpn_nvram = wwn; if (IS_2200(isp) || IS_23XX(isp)) { wwn = ISP2100_NVRAM_NODE_NAME(nvram_data); if (wwn) { isp_prt(isp, ISP_LOGCONFIG, "NVRAM Node WWN 0x%08x%08x", (uint32_t) (wwn >> 32), (uint32_t) (wwn)); if ((wwn >> 60) == 0) { wwn |= (((uint64_t) 2)<< 60); } } else { wwn = fcp->isp_wwpn_nvram & ~((uint64_t) 0xfff << 48); } } else { wwn &= ~((uint64_t) 0xfff << 48); } fcp->isp_wwnn_nvram = wwn; fcp->isp_maxalloc = ISP2100_NVRAM_MAXIOCBALLOCATION(nvram_data); if ((isp->isp_confopts & ISP_CFG_OWNFSZ) == 0) { DEFAULT_FRAMESIZE(isp) = ISP2100_NVRAM_MAXFRAMELENGTH(nvram_data); } fcp->isp_retry_delay = ISP2100_NVRAM_RETRY_DELAY(nvram_data); fcp->isp_retry_count = ISP2100_NVRAM_RETRY_COUNT(nvram_data); if ((isp->isp_confopts & ISP_CFG_OWNLOOPID) == 0) { fcp->isp_loopid = ISP2100_NVRAM_HARDLOOPID(nvram_data); } if ((isp->isp_confopts & ISP_CFG_OWNEXCTHROTTLE) == 0) { DEFAULT_EXEC_THROTTLE(isp) = ISP2100_NVRAM_EXECUTION_THROTTLE(nvram_data); } fcp->isp_fwoptions = ISP2100_NVRAM_OPTIONS(nvram_data); isp_prt(isp, ISP_LOGDEBUG0, "NVRAM 0x%08x%08x 0x%08x%08x maxalloc %d maxframelen %d", (uint32_t) (fcp->isp_wwnn_nvram >> 32), (uint32_t) fcp->isp_wwnn_nvram, (uint32_t) (fcp->isp_wwpn_nvram >> 32), (uint32_t) fcp->isp_wwpn_nvram, ISP2100_NVRAM_MAXIOCBALLOCATION(nvram_data), ISP2100_NVRAM_MAXFRAMELENGTH(nvram_data)); isp_prt(isp, ISP_LOGDEBUG0, "execthrottle %d fwoptions 0x%x hardloop %d tov %d", ISP2100_NVRAM_EXECUTION_THROTTLE(nvram_data), ISP2100_NVRAM_OPTIONS(nvram_data), ISP2100_NVRAM_HARDLOOPID(nvram_data), ISP2100_NVRAM_TOV(nvram_data)); fcp->isp_xfwoptions = ISP2100_XFW_OPTIONS(nvram_data); fcp->isp_zfwoptions = ISP2100_ZFW_OPTIONS(nvram_data); isp_prt(isp, ISP_LOGDEBUG0, "xfwoptions 0x%x zfw options 0x%x", ISP2100_XFW_OPTIONS(nvram_data), ISP2100_ZFW_OPTIONS(nvram_data)); } static void isp_parse_nvram_2400(ispsoftc_t *isp, uint8_t *nvram_data) { fcparam *fcp = FCPARAM(isp, 0); uint64_t wwn; isp_prt(isp, ISP_LOGDEBUG0, "NVRAM 0x%08x%08x 0x%08x%08x exchg_cnt %d maxframelen %d", (uint32_t) (ISP2400_NVRAM_NODE_NAME(nvram_data) >> 32), (uint32_t) (ISP2400_NVRAM_NODE_NAME(nvram_data)), (uint32_t) (ISP2400_NVRAM_PORT_NAME(nvram_data) >> 32), (uint32_t) (ISP2400_NVRAM_PORT_NAME(nvram_data)), ISP2400_NVRAM_EXCHANGE_COUNT(nvram_data), ISP2400_NVRAM_MAXFRAMELENGTH(nvram_data)); isp_prt(isp, ISP_LOGDEBUG0, "NVRAM execthr %d loopid %d fwopt1 0x%x fwopt2 0x%x fwopt3 0x%x", ISP2400_NVRAM_EXECUTION_THROTTLE(nvram_data), ISP2400_NVRAM_HARDLOOPID(nvram_data), ISP2400_NVRAM_FIRMWARE_OPTIONS1(nvram_data), ISP2400_NVRAM_FIRMWARE_OPTIONS2(nvram_data), ISP2400_NVRAM_FIRMWARE_OPTIONS3(nvram_data)); wwn = ISP2400_NVRAM_PORT_NAME(nvram_data); fcp->isp_wwpn_nvram = wwn; wwn = ISP2400_NVRAM_NODE_NAME(nvram_data); if (wwn) { if ((wwn >> 60) != 2 && (wwn >> 60) != 5) { wwn = 0; } } if (wwn == 0 && (fcp->isp_wwpn_nvram >> 60) == 2) { wwn = fcp->isp_wwpn_nvram; wwn &= ~((uint64_t) 0xfff << 48); } fcp->isp_wwnn_nvram = wwn; if (ISP2400_NVRAM_EXCHANGE_COUNT(nvram_data)) { fcp->isp_maxalloc = ISP2400_NVRAM_EXCHANGE_COUNT(nvram_data); } if ((isp->isp_confopts & ISP_CFG_OWNFSZ) == 0) { DEFAULT_FRAMESIZE(isp) = ISP2400_NVRAM_MAXFRAMELENGTH(nvram_data); } if ((isp->isp_confopts & ISP_CFG_OWNLOOPID) == 0) { fcp->isp_loopid = ISP2400_NVRAM_HARDLOOPID(nvram_data); } if ((isp->isp_confopts & ISP_CFG_OWNEXCTHROTTLE) == 0) { DEFAULT_EXEC_THROTTLE(isp) = ISP2400_NVRAM_EXECUTION_THROTTLE(nvram_data); } fcp->isp_fwoptions = ISP2400_NVRAM_FIRMWARE_OPTIONS1(nvram_data); fcp->isp_xfwoptions = ISP2400_NVRAM_FIRMWARE_OPTIONS2(nvram_data); fcp->isp_zfwoptions = ISP2400_NVRAM_FIRMWARE_OPTIONS3(nvram_data); } Index: head/sys/dev/isp/isp_freebsd.c =================================================================== --- head/sys/dev/isp/isp_freebsd.c (revision 345007) +++ head/sys/dev/isp/isp_freebsd.c (revision 345008) @@ -1,4314 +1,4328 @@ /*- * SPDX-License-Identifier: BSD-2-Clause-FreeBSD * * Copyright (c) 2009-2017 Alexander Motin * Copyright (c) 1997-2009 by Matthew Jacob * 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 immediately at the beginning of the file, without modification, * this list of conditions, and the following disclaimer. * 2. The name of the author may not be used to endorse or promote products * derived from this software without specific prior written permission. * * THIS SOFTWARE IS PROVIDED BY THE AUTHOR AND CONTRIBUTORS ``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 OR CONTRIBUTORS 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. */ /* * Platform (FreeBSD) dependent common attachment code for Qlogic adapters. */ #include __FBSDID("$FreeBSD$"); #include #include #include #include #include #include #include #include #include #include MODULE_VERSION(isp, 1); MODULE_DEPEND(isp, cam, 1, 1, 1); int isp_announced = 0; int isp_loop_down_limit = 60; /* default loop down limit */ int isp_quickboot_time = 7; /* don't wait more than N secs for loop up */ int isp_gone_device_time = 30; /* grace time before reporting device lost */ static const char prom3[] = "Chan %d [%u] PortID 0x%06x Departed because of %s"; static void isp_freeze_loopdown(ispsoftc_t *, int); static void isp_loop_changed(ispsoftc_t *isp, int chan); static d_ioctl_t ispioctl; static void isp_cam_async(void *, uint32_t, struct cam_path *, void *); static void isp_poll(struct cam_sim *); static timeout_t isp_watchdog; static timeout_t isp_gdt; static task_fn_t isp_gdt_task; static void isp_kthread(void *); static void isp_action(struct cam_sim *, union ccb *); static int isp_timer_count; static void isp_timer(void *); static struct cdevsw isp_cdevsw = { .d_version = D_VERSION, .d_ioctl = ispioctl, .d_name = "isp", }; static int isp_role_sysctl(SYSCTL_HANDLER_ARGS) { ispsoftc_t *isp = (ispsoftc_t *)arg1; int chan = arg2; int error, old, value; value = FCPARAM(isp, chan)->role; error = sysctl_handle_int(oidp, &value, 0, req); if ((error != 0) || (req->newptr == NULL)) return (error); if (value < ISP_ROLE_NONE || value > ISP_ROLE_BOTH) return (EINVAL); ISP_LOCK(isp); old = FCPARAM(isp, chan)->role; /* We don't allow target mode switch from here. */ value = (old & ISP_ROLE_TARGET) | (value & ISP_ROLE_INITIATOR); /* If nothing has changed -- we are done. */ if (value == old) { ISP_UNLOCK(isp); return (0); } /* Actually change the role. */ error = isp_control(isp, ISPCTL_CHANGE_ROLE, chan, value); ISP_UNLOCK(isp); return (error); } static int isp_attach_chan(ispsoftc_t *isp, struct cam_devq *devq, int chan) { struct ccb_setasync csa; struct cam_sim *sim; struct cam_path *path; #ifdef ISP_TARGET_MODE int i; #endif sim = cam_sim_alloc(isp_action, isp_poll, "isp", isp, device_get_unit(isp->isp_dev), &isp->isp_lock, isp->isp_maxcmds, isp->isp_maxcmds, devq); if (sim == NULL) return (ENOMEM); ISP_LOCK(isp); if (xpt_bus_register(sim, isp->isp_dev, chan) != CAM_SUCCESS) { ISP_UNLOCK(isp); cam_sim_free(sim, FALSE); return (EIO); } ISP_UNLOCK(isp); if (xpt_create_path(&path, NULL, cam_sim_path(sim), CAM_TARGET_WILDCARD, CAM_LUN_WILDCARD) != CAM_REQ_CMP) { ISP_LOCK(isp); xpt_bus_deregister(cam_sim_path(sim)); ISP_UNLOCK(isp); cam_sim_free(sim, FALSE); return (ENXIO); } xpt_setup_ccb(&csa.ccb_h, path, 5); csa.ccb_h.func_code = XPT_SASYNC_CB; csa.event_enable = AC_LOST_DEVICE; csa.callback = isp_cam_async; csa.callback_arg = sim; ISP_LOCK(isp); xpt_action((union ccb *)&csa); ISP_UNLOCK(isp); if (IS_SCSI(isp)) { struct isp_spi *spi = ISP_SPI_PC(isp, chan); spi->sim = sim; spi->path = path; #ifdef ISP_TARGET_MODE TAILQ_INIT(&spi->waitq); STAILQ_INIT(&spi->ntfree); for (i = 0; i < ATPDPSIZE; i++) STAILQ_INSERT_TAIL(&spi->ntfree, &spi->ntpool[i], next); LIST_INIT(&spi->atfree); for (i = ATPDPSIZE-1; i >= 0; i--) LIST_INSERT_HEAD(&spi->atfree, &spi->atpool[i], next); for (i = 0; i < ATPDPHASHSIZE; i++) LIST_INIT(&spi->atused[i]); #endif } else { fcparam *fcp = FCPARAM(isp, chan); struct isp_fc *fc = ISP_FC_PC(isp, chan); struct sysctl_ctx_list *ctx = device_get_sysctl_ctx(isp->isp_osinfo.dev); struct sysctl_oid *tree = device_get_sysctl_tree(isp->isp_osinfo.dev); char name[16]; ISP_LOCK(isp); fc->sim = sim; fc->path = path; fc->isp = isp; fc->ready = 1; fcp->isp_use_gft_id = 1; fcp->isp_use_gff_id = 1; callout_init_mtx(&fc->gdt, &isp->isp_lock, 0); TASK_INIT(&fc->gtask, 1, isp_gdt_task, fc); #ifdef ISP_TARGET_MODE TAILQ_INIT(&fc->waitq); STAILQ_INIT(&fc->ntfree); for (i = 0; i < ATPDPSIZE; i++) STAILQ_INSERT_TAIL(&fc->ntfree, &fc->ntpool[i], next); LIST_INIT(&fc->atfree); for (i = ATPDPSIZE-1; i >= 0; i--) LIST_INSERT_HEAD(&fc->atfree, &fc->atpool[i], next); for (i = 0; i < ATPDPHASHSIZE; i++) LIST_INIT(&fc->atused[i]); #endif isp_loop_changed(isp, chan); ISP_UNLOCK(isp); if (kproc_create(isp_kthread, fc, &fc->kproc, 0, 0, "%s_%d", device_get_nameunit(isp->isp_osinfo.dev), chan)) { xpt_free_path(fc->path); ISP_LOCK(isp); xpt_bus_deregister(cam_sim_path(fc->sim)); ISP_UNLOCK(isp); cam_sim_free(fc->sim, FALSE); return (ENOMEM); } fc->num_threads += 1; if (chan > 0) { snprintf(name, sizeof(name), "chan%d", chan); tree = SYSCTL_ADD_NODE(ctx, SYSCTL_CHILDREN(tree), OID_AUTO, name, CTLFLAG_RW, 0, "Virtual channel"); } SYSCTL_ADD_QUAD(ctx, SYSCTL_CHILDREN(tree), OID_AUTO, "wwnn", CTLFLAG_RD, &fcp->isp_wwnn, "World Wide Node Name"); SYSCTL_ADD_QUAD(ctx, SYSCTL_CHILDREN(tree), OID_AUTO, "wwpn", CTLFLAG_RD, &fcp->isp_wwpn, "World Wide Port Name"); SYSCTL_ADD_UINT(ctx, SYSCTL_CHILDREN(tree), OID_AUTO, "loop_down_limit", CTLFLAG_RW, &fc->loop_down_limit, 0, "Loop Down Limit"); SYSCTL_ADD_UINT(ctx, SYSCTL_CHILDREN(tree), OID_AUTO, "gone_device_time", CTLFLAG_RW, &fc->gone_device_time, 0, "Gone Device Time"); #if defined(ISP_TARGET_MODE) && defined(DEBUG) SYSCTL_ADD_UINT(ctx, SYSCTL_CHILDREN(tree), OID_AUTO, "inject_lost_data_frame", CTLFLAG_RW, &fc->inject_lost_data_frame, 0, "Cause a Lost Frame on a Read"); #endif SYSCTL_ADD_PROC(ctx, SYSCTL_CHILDREN(tree), OID_AUTO, "role", CTLTYPE_INT | CTLFLAG_RW, isp, chan, isp_role_sysctl, "I", "Current role"); SYSCTL_ADD_UINT(ctx, SYSCTL_CHILDREN(tree), OID_AUTO, "speed", CTLFLAG_RD, &fcp->isp_gbspeed, 0, "Connection speed in gigabits"); SYSCTL_ADD_UINT(ctx, SYSCTL_CHILDREN(tree), OID_AUTO, "linkstate", CTLFLAG_RD, &fcp->isp_linkstate, 0, "Link state"); SYSCTL_ADD_UINT(ctx, SYSCTL_CHILDREN(tree), OID_AUTO, "fwstate", CTLFLAG_RD, &fcp->isp_fwstate, 0, "Firmware state"); SYSCTL_ADD_UINT(ctx, SYSCTL_CHILDREN(tree), OID_AUTO, "loopstate", CTLFLAG_RD, &fcp->isp_loopstate, 0, "Loop state"); SYSCTL_ADD_UINT(ctx, SYSCTL_CHILDREN(tree), OID_AUTO, "topo", CTLFLAG_RD, &fcp->isp_topo, 0, "Connection topology"); SYSCTL_ADD_INT(ctx, SYSCTL_CHILDREN(tree), OID_AUTO, "use_gft_id", CTLFLAG_RWTUN, &fcp->isp_use_gft_id, 0, "Use GFT_ID during fabric scan"); SYSCTL_ADD_INT(ctx, SYSCTL_CHILDREN(tree), OID_AUTO, "use_gff_id", CTLFLAG_RWTUN, &fcp->isp_use_gff_id, 0, "Use GFF_ID during fabric scan"); } return (0); } static void isp_detach_chan(ispsoftc_t *isp, int chan) { struct cam_sim *sim; struct cam_path *path; struct ccb_setasync csa; int *num_threads; ISP_GET_PC(isp, chan, sim, sim); ISP_GET_PC(isp, chan, path, path); ISP_GET_PC_ADDR(isp, chan, num_threads, num_threads); xpt_setup_ccb(&csa.ccb_h, path, 5); csa.ccb_h.func_code = XPT_SASYNC_CB; csa.event_enable = 0; csa.callback = isp_cam_async; csa.callback_arg = sim; xpt_action((union ccb *)&csa); xpt_free_path(path); xpt_bus_deregister(cam_sim_path(sim)); cam_sim_free(sim, FALSE); /* Wait for the channel's spawned threads to exit. */ wakeup(isp->isp_osinfo.pc.ptr); while (*num_threads != 0) mtx_sleep(isp, &isp->isp_lock, PRIBIO, "isp_reap", 100); } int isp_attach(ispsoftc_t *isp) { const char *nu = device_get_nameunit(isp->isp_osinfo.dev); int du = device_get_unit(isp->isp_dev); int chan; /* * Create the device queue for our SIM(s). */ isp->isp_osinfo.devq = cam_simq_alloc(isp->isp_maxcmds); if (isp->isp_osinfo.devq == NULL) { return (EIO); } for (chan = 0; chan < isp->isp_nchan; chan++) { if (isp_attach_chan(isp, isp->isp_osinfo.devq, chan)) { goto unwind; } } callout_init_mtx(&isp->isp_osinfo.tmo, &isp->isp_lock, 0); isp_timer_count = hz >> 2; callout_reset(&isp->isp_osinfo.tmo, isp_timer_count, isp_timer, isp); isp->isp_osinfo.cdev = make_dev(&isp_cdevsw, du, UID_ROOT, GID_OPERATOR, 0600, "%s", nu); if (isp->isp_osinfo.cdev) { isp->isp_osinfo.cdev->si_drv1 = isp; } return (0); unwind: while (--chan >= 0) { struct cam_sim *sim; struct cam_path *path; ISP_GET_PC(isp, chan, sim, sim); ISP_GET_PC(isp, chan, path, path); xpt_free_path(path); ISP_LOCK(isp); xpt_bus_deregister(cam_sim_path(sim)); ISP_UNLOCK(isp); cam_sim_free(sim, FALSE); } cam_simq_free(isp->isp_osinfo.devq); isp->isp_osinfo.devq = NULL; return (-1); } int isp_detach(ispsoftc_t *isp) { int chan; if (isp->isp_osinfo.cdev) { destroy_dev(isp->isp_osinfo.cdev); isp->isp_osinfo.cdev = NULL; } ISP_LOCK(isp); /* Tell spawned threads that we're exiting. */ isp->isp_osinfo.is_exiting = 1; for (chan = isp->isp_nchan - 1; chan >= 0; chan -= 1) isp_detach_chan(isp, chan); ISP_UNLOCK(isp); callout_drain(&isp->isp_osinfo.tmo); cam_simq_free(isp->isp_osinfo.devq); return (0); } static void isp_freeze_loopdown(ispsoftc_t *isp, int chan) { struct isp_fc *fc = ISP_FC_PC(isp, chan); if (fc->sim == NULL) return; if (fc->simqfrozen == 0) { isp_prt(isp, ISP_LOGDEBUG0, "Chan %d Freeze simq (loopdown)", chan); fc->simqfrozen = SIMQFRZ_LOOPDOWN; xpt_hold_boot(); xpt_freeze_simq(fc->sim, 1); } else { isp_prt(isp, ISP_LOGDEBUG0, "Chan %d Mark simq frozen (loopdown)", chan); fc->simqfrozen |= SIMQFRZ_LOOPDOWN; } } static void isp_unfreeze_loopdown(ispsoftc_t *isp, int chan) { struct isp_fc *fc = ISP_FC_PC(isp, chan); if (fc->sim == NULL) return; int wasfrozen = fc->simqfrozen & SIMQFRZ_LOOPDOWN; fc->simqfrozen &= ~SIMQFRZ_LOOPDOWN; if (wasfrozen && fc->simqfrozen == 0) { isp_prt(isp, ISP_LOGDEBUG0, "Chan %d Release simq", chan); xpt_release_simq(fc->sim, 1); xpt_release_boot(); } } static int ispioctl(struct cdev *dev, u_long c, caddr_t addr, int flags, struct thread *td) { ispsoftc_t *isp; int nr, chan, retval = ENOTTY; isp = dev->si_drv1; switch (c) { case ISP_SDBLEV: { int olddblev = isp->isp_dblev; isp->isp_dblev = *(int *)addr; *(int *)addr = olddblev; retval = 0; break; } case ISP_GETROLE: chan = *(int *)addr; if (chan < 0 || chan >= isp->isp_nchan) { retval = -ENXIO; break; } if (IS_FC(isp)) { *(int *)addr = FCPARAM(isp, chan)->role; } else { *(int *)addr = ISP_ROLE_INITIATOR; } retval = 0; break; case ISP_SETROLE: if (IS_SCSI(isp)) break; nr = *(int *)addr; chan = nr >> 8; if (chan < 0 || chan >= isp->isp_nchan) { retval = -ENXIO; break; } nr &= 0xff; if (nr & ~(ISP_ROLE_INITIATOR|ISP_ROLE_TARGET)) { retval = EINVAL; break; } ISP_LOCK(isp); *(int *)addr = FCPARAM(isp, chan)->role; retval = isp_control(isp, ISPCTL_CHANGE_ROLE, chan, nr); ISP_UNLOCK(isp); retval = 0; break; case ISP_RESETHBA: ISP_LOCK(isp); isp_reinit(isp, 0); ISP_UNLOCK(isp); retval = 0; break; case ISP_RESCAN: if (IS_FC(isp)) { chan = *(intptr_t *)addr; if (chan < 0 || chan >= isp->isp_nchan) { retval = -ENXIO; break; } ISP_LOCK(isp); if (isp_fc_runstate(isp, chan, 5 * 1000000) != LOOP_READY) { retval = EIO; } else { retval = 0; } ISP_UNLOCK(isp); } break; case ISP_FC_LIP: if (IS_FC(isp)) { chan = *(intptr_t *)addr; if (chan < 0 || chan >= isp->isp_nchan) { retval = -ENXIO; break; } ISP_LOCK(isp); if (isp_control(isp, ISPCTL_SEND_LIP, chan)) { retval = EIO; } else { retval = 0; } ISP_UNLOCK(isp); } break; case ISP_FC_GETDINFO: { struct isp_fc_device *ifc = (struct isp_fc_device *) addr; fcportdb_t *lp; if (IS_SCSI(isp)) { break; } if (ifc->loopid >= MAX_FC_TARG) { retval = EINVAL; break; } lp = &FCPARAM(isp, ifc->chan)->portdb[ifc->loopid]; if (lp->state != FC_PORTDB_STATE_NIL) { ifc->role = (lp->prli_word3 & SVC3_ROLE_MASK) >> SVC3_ROLE_SHIFT; ifc->loopid = lp->handle; ifc->portid = lp->portid; ifc->node_wwn = lp->node_wwn; ifc->port_wwn = lp->port_wwn; retval = 0; } else { retval = ENODEV; } break; } case ISP_FC_GETHINFO: { struct isp_hba_device *hba = (struct isp_hba_device *) addr; int chan = hba->fc_channel; if (chan < 0 || chan >= isp->isp_nchan) { retval = ENXIO; break; } hba->fc_fw_major = ISP_FW_MAJORX(isp->isp_fwrev); hba->fc_fw_minor = ISP_FW_MINORX(isp->isp_fwrev); hba->fc_fw_micro = ISP_FW_MICROX(isp->isp_fwrev); hba->fc_nchannels = isp->isp_nchan; if (IS_FC(isp)) { hba->fc_nports = MAX_FC_TARG; hba->fc_speed = FCPARAM(isp, hba->fc_channel)->isp_gbspeed; hba->fc_topology = FCPARAM(isp, chan)->isp_topo + 1; hba->fc_loopid = FCPARAM(isp, chan)->isp_loopid; hba->nvram_node_wwn = FCPARAM(isp, chan)->isp_wwnn_nvram; hba->nvram_port_wwn = FCPARAM(isp, chan)->isp_wwpn_nvram; hba->active_node_wwn = FCPARAM(isp, chan)->isp_wwnn; hba->active_port_wwn = FCPARAM(isp, chan)->isp_wwpn; } else { hba->fc_nports = MAX_TARGETS; hba->fc_speed = 0; hba->fc_topology = 0; hba->nvram_node_wwn = 0ull; hba->nvram_port_wwn = 0ull; hba->active_node_wwn = 0ull; hba->active_port_wwn = 0ull; } retval = 0; break; } case ISP_TSK_MGMT: { int needmarker; struct isp_fc_tsk_mgmt *fct = (struct isp_fc_tsk_mgmt *) addr; uint16_t nphdl; mbreg_t mbs; if (IS_SCSI(isp)) { break; } chan = fct->chan; if (chan < 0 || chan >= isp->isp_nchan) { retval = -ENXIO; break; } needmarker = retval = 0; nphdl = fct->loopid; ISP_LOCK(isp); if (IS_24XX(isp)) { void *reqp; uint8_t resp[QENTRY_LEN]; isp24xx_tmf_t tmf; isp24xx_statusreq_t sp; fcparam *fcp = FCPARAM(isp, chan); fcportdb_t *lp; int i; for (i = 0; i < MAX_FC_TARG; i++) { lp = &fcp->portdb[i]; if (lp->handle == nphdl) { break; } } if (i == MAX_FC_TARG) { retval = ENXIO; ISP_UNLOCK(isp); break; } ISP_MEMZERO(&tmf, sizeof(tmf)); tmf.tmf_header.rqs_entry_type = RQSTYPE_TSK_MGMT; tmf.tmf_header.rqs_entry_count = 1; tmf.tmf_nphdl = lp->handle; tmf.tmf_delay = 2; tmf.tmf_timeout = 4; tmf.tmf_tidlo = lp->portid; tmf.tmf_tidhi = lp->portid >> 16; tmf.tmf_vpidx = ISP_GET_VPIDX(isp, chan); tmf.tmf_lun[1] = fct->lun & 0xff; if (fct->lun >= 256) { tmf.tmf_lun[0] = 0x40 | (fct->lun >> 8); } switch (fct->action) { case IPT_CLEAR_ACA: tmf.tmf_flags = ISP24XX_TMF_CLEAR_ACA; break; case IPT_TARGET_RESET: tmf.tmf_flags = ISP24XX_TMF_TARGET_RESET; needmarker = 1; break; case IPT_LUN_RESET: tmf.tmf_flags = ISP24XX_TMF_LUN_RESET; needmarker = 1; break; case IPT_CLEAR_TASK_SET: tmf.tmf_flags = ISP24XX_TMF_CLEAR_TASK_SET; needmarker = 1; break; case IPT_ABORT_TASK_SET: tmf.tmf_flags = ISP24XX_TMF_ABORT_TASK_SET; needmarker = 1; break; default: retval = EINVAL; break; } if (retval) { ISP_UNLOCK(isp); break; } /* Prepare space for response in memory */ memset(resp, 0xff, sizeof(resp)); tmf.tmf_handle = isp_allocate_handle(isp, resp, ISP_HANDLE_CTRL); if (tmf.tmf_handle == 0) { isp_prt(isp, ISP_LOGERR, "%s: TMF of Chan %d out of handles", __func__, chan); ISP_UNLOCK(isp); retval = ENOMEM; break; } /* Send request and wait for response. */ reqp = isp_getrqentry(isp); if (reqp == NULL) { isp_prt(isp, ISP_LOGERR, "%s: TMF of Chan %d out of rqent", __func__, chan); isp_destroy_handle(isp, tmf.tmf_handle); ISP_UNLOCK(isp); retval = EIO; break; } isp_put_24xx_tmf(isp, &tmf, (isp24xx_tmf_t *)reqp); if (isp->isp_dblev & ISP_LOGDEBUG1) isp_print_bytes(isp, "IOCB TMF", QENTRY_LEN, reqp); ISP_SYNC_REQUEST(isp); if (msleep(resp, &isp->isp_lock, 0, "TMF", 5*hz) == EWOULDBLOCK) { isp_prt(isp, ISP_LOGERR, "%s: TMF of Chan %d timed out", __func__, chan); isp_destroy_handle(isp, tmf.tmf_handle); ISP_UNLOCK(isp); retval = EIO; break; } if (isp->isp_dblev & ISP_LOGDEBUG1) isp_print_bytes(isp, "IOCB TMF response", QENTRY_LEN, resp); isp_get_24xx_response(isp, (isp24xx_statusreq_t *)resp, &sp); if (sp.req_completion_status != 0) retval = EIO; else if (needmarker) fcp->sendmarker = 1; } else { MBSINIT(&mbs, 0, MBLOGALL, 0); if (ISP_CAP_2KLOGIN(isp) == 0) { nphdl <<= 8; } switch (fct->action) { case IPT_CLEAR_ACA: mbs.param[0] = MBOX_CLEAR_ACA; mbs.param[1] = nphdl; mbs.param[2] = fct->lun; break; case IPT_TARGET_RESET: mbs.param[0] = MBOX_TARGET_RESET; mbs.param[1] = nphdl; needmarker = 1; break; case IPT_LUN_RESET: mbs.param[0] = MBOX_LUN_RESET; mbs.param[1] = nphdl; mbs.param[2] = fct->lun; needmarker = 1; break; case IPT_CLEAR_TASK_SET: mbs.param[0] = MBOX_CLEAR_TASK_SET; mbs.param[1] = nphdl; mbs.param[2] = fct->lun; needmarker = 1; break; case IPT_ABORT_TASK_SET: mbs.param[0] = MBOX_ABORT_TASK_SET; mbs.param[1] = nphdl; mbs.param[2] = fct->lun; needmarker = 1; break; default: retval = EINVAL; break; } if (retval == 0) { if (needmarker) { FCPARAM(isp, chan)->sendmarker = 1; } retval = isp_control(isp, ISPCTL_RUN_MBOXCMD, &mbs); if (retval) { retval = EIO; } } } ISP_UNLOCK(isp); break; } default: break; } return (retval); } /* * Local Inlines */ static ISP_INLINE int isp_get_pcmd(ispsoftc_t *, union ccb *); static ISP_INLINE void isp_free_pcmd(ispsoftc_t *, union ccb *); static ISP_INLINE int isp_get_pcmd(ispsoftc_t *isp, union ccb *ccb) { ISP_PCMD(ccb) = isp->isp_osinfo.pcmd_free; if (ISP_PCMD(ccb) == NULL) { return (-1); } isp->isp_osinfo.pcmd_free = ((struct isp_pcmd *)ISP_PCMD(ccb))->next; return (0); } static ISP_INLINE void isp_free_pcmd(ispsoftc_t *isp, union ccb *ccb) { if (ISP_PCMD(ccb)) { #ifdef ISP_TARGET_MODE PISP_PCMD(ccb)->datalen = 0; #endif PISP_PCMD(ccb)->next = isp->isp_osinfo.pcmd_free; isp->isp_osinfo.pcmd_free = ISP_PCMD(ccb); ISP_PCMD(ccb) = NULL; } } /* * Put the target mode functions here, because some are inlines */ #ifdef ISP_TARGET_MODE static ISP_INLINE tstate_t *get_lun_statep(ispsoftc_t *, int, lun_id_t); static atio_private_data_t *isp_get_atpd(ispsoftc_t *, int, uint32_t); static atio_private_data_t *isp_find_atpd(ispsoftc_t *, int, uint32_t); static void isp_put_atpd(ispsoftc_t *, int, atio_private_data_t *); static inot_private_data_t *isp_get_ntpd(ispsoftc_t *, int); static inot_private_data_t *isp_find_ntpd(ispsoftc_t *, int, uint32_t, uint32_t); static void isp_put_ntpd(ispsoftc_t *, int, inot_private_data_t *); static cam_status create_lun_state(ispsoftc_t *, int, struct cam_path *, tstate_t **); static void destroy_lun_state(ispsoftc_t *, int, tstate_t *); static void isp_enable_lun(ispsoftc_t *, union ccb *); static void isp_disable_lun(ispsoftc_t *, union ccb *); static timeout_t isp_refire_putback_atio; static timeout_t isp_refire_notify_ack; static void isp_complete_ctio(union ccb *); static void isp_target_putback_atio(union ccb *); enum Start_Ctio_How { FROM_CAM, FROM_TIMER, FROM_SRR, FROM_CTIO_DONE }; static void isp_target_start_ctio(ispsoftc_t *, union ccb *, enum Start_Ctio_How); static void isp_handle_platform_atio2(ispsoftc_t *, at2_entry_t *); static void isp_handle_platform_atio7(ispsoftc_t *, at7_entry_t *); static void isp_handle_platform_ctio(ispsoftc_t *, void *); static int isp_handle_platform_target_notify_ack(ispsoftc_t *, isp_notify_t *, uint32_t rsp); static void isp_handle_platform_target_tmf(ispsoftc_t *, isp_notify_t *); static void isp_target_mark_aborted_early(ispsoftc_t *, int chan, tstate_t *, uint32_t); static ISP_INLINE tstate_t * get_lun_statep(ispsoftc_t *isp, int bus, lun_id_t lun) { tstate_t *tptr = NULL; struct tslist *lhp; if (bus < isp->isp_nchan) { ISP_GET_PC_ADDR(isp, bus, lun_hash[LUN_HASH_FUNC(lun)], lhp); SLIST_FOREACH(tptr, lhp, next) { if (tptr->ts_lun == lun) return (tptr); } } return (NULL); } static int isp_atio_restart(ispsoftc_t *isp, int bus, tstate_t *tptr) { inot_private_data_t *ntp; struct ntpdlist rq; if (STAILQ_EMPTY(&tptr->restart_queue)) return (0); STAILQ_INIT(&rq); STAILQ_CONCAT(&rq, &tptr->restart_queue); while ((ntp = STAILQ_FIRST(&rq)) != NULL) { STAILQ_REMOVE_HEAD(&rq, next); if (IS_24XX(isp)) { isp_prt(isp, ISP_LOGTDEBUG0, "%s: restarting resrc deprived %x", __func__, ((at7_entry_t *)ntp->data)->at_rxid); isp_handle_platform_atio7(isp, (at7_entry_t *) ntp->data); } else { isp_prt(isp, ISP_LOGTDEBUG0, "%s: restarting resrc deprived %x", __func__, ((at2_entry_t *)ntp->data)->at_rxid); isp_handle_platform_atio2(isp, (at2_entry_t *) ntp->data); } isp_put_ntpd(isp, bus, ntp); if (!STAILQ_EMPTY(&tptr->restart_queue)) break; } if (!STAILQ_EMPTY(&rq)) { STAILQ_CONCAT(&rq, &tptr->restart_queue); STAILQ_CONCAT(&tptr->restart_queue, &rq); } return (!STAILQ_EMPTY(&tptr->restart_queue)); } static void isp_tmcmd_restart(ispsoftc_t *isp) { tstate_t *tptr; union ccb *ccb; struct tslist *lhp; struct isp_ccbq *waitq; int bus, i; for (bus = 0; bus < isp->isp_nchan; bus++) { for (i = 0; i < LUN_HASH_SIZE; i++) { ISP_GET_PC_ADDR(isp, bus, lun_hash[i], lhp); SLIST_FOREACH(tptr, lhp, next) isp_atio_restart(isp, bus, tptr); } /* * We only need to do this once per channel. */ ISP_GET_PC_ADDR(isp, bus, waitq, waitq); ccb = (union ccb *)TAILQ_FIRST(waitq); if (ccb != NULL) { TAILQ_REMOVE(waitq, &ccb->ccb_h, sim_links.tqe); isp_target_start_ctio(isp, ccb, FROM_TIMER); } } } static atio_private_data_t * isp_get_atpd(ispsoftc_t *isp, int chan, uint32_t tag) { struct atpdlist *atfree; struct atpdlist *atused; atio_private_data_t *atp; ISP_GET_PC_ADDR(isp, chan, atfree, atfree); atp = LIST_FIRST(atfree); if (atp) { LIST_REMOVE(atp, next); atp->tag = tag; ISP_GET_PC(isp, chan, atused, atused); LIST_INSERT_HEAD(&atused[ATPDPHASH(tag)], atp, next); } return (atp); } static atio_private_data_t * isp_find_atpd(ispsoftc_t *isp, int chan, uint32_t tag) { struct atpdlist *atused; atio_private_data_t *atp; ISP_GET_PC(isp, chan, atused, atused); LIST_FOREACH(atp, &atused[ATPDPHASH(tag)], next) { if (atp->tag == tag) return (atp); } return (NULL); } static void isp_put_atpd(ispsoftc_t *isp, int chan, atio_private_data_t *atp) { struct atpdlist *atfree; if (atp->ests) { isp_put_ecmd(isp, atp->ests); } LIST_REMOVE(atp, next); memset(atp, 0, sizeof (*atp)); ISP_GET_PC_ADDR(isp, chan, atfree, atfree); LIST_INSERT_HEAD(atfree, atp, next); } static void isp_dump_atpd(ispsoftc_t *isp, int chan) { atio_private_data_t *atp, *atpool; const char *states[8] = { "Free", "ATIO", "CAM", "CTIO", "LAST_CTIO", "PDON", "?6", "7" }; ISP_GET_PC(isp, chan, atpool, atpool); for (atp = atpool; atp < &atpool[ATPDPSIZE]; atp++) { if (atp->state == ATPD_STATE_FREE) continue; isp_prt(isp, ISP_LOGALL, "Chan %d ATP [0x%x] origdlen %u bytes_xfrd %u lun %jx nphdl 0x%04x s_id 0x%06x d_id 0x%06x oxid 0x%04x state %s", chan, atp->tag, atp->orig_datalen, atp->bytes_xfered, (uintmax_t)atp->lun, atp->nphdl, atp->sid, atp->did, atp->oxid, states[atp->state & 0x7]); } } static inot_private_data_t * isp_get_ntpd(ispsoftc_t *isp, int chan) { struct ntpdlist *ntfree; inot_private_data_t *ntp; ISP_GET_PC_ADDR(isp, chan, ntfree, ntfree); ntp = STAILQ_FIRST(ntfree); if (ntp) STAILQ_REMOVE_HEAD(ntfree, next); return (ntp); } static inot_private_data_t * isp_find_ntpd(ispsoftc_t *isp, int chan, uint32_t tag_id, uint32_t seq_id) { inot_private_data_t *ntp, *ntp2; ISP_GET_PC(isp, chan, ntpool, ntp); ISP_GET_PC_ADDR(isp, chan, ntpool[ATPDPSIZE], ntp2); for (; ntp < ntp2; ntp++) { if (ntp->tag_id == tag_id && ntp->seq_id == seq_id) return (ntp); } return (NULL); } static void isp_put_ntpd(ispsoftc_t *isp, int chan, inot_private_data_t *ntp) { struct ntpdlist *ntfree; ntp->tag_id = ntp->seq_id = 0; ISP_GET_PC_ADDR(isp, chan, ntfree, ntfree); STAILQ_INSERT_HEAD(ntfree, ntp, next); } static cam_status create_lun_state(ispsoftc_t *isp, int bus, struct cam_path *path, tstate_t **rslt) { lun_id_t lun; struct tslist *lhp; tstate_t *tptr; lun = xpt_path_lun_id(path); if (lun != CAM_LUN_WILDCARD) { if (ISP_MAX_LUNS(isp) > 0 && lun >= ISP_MAX_LUNS(isp)) { return (CAM_LUN_INVALID); } } tptr = malloc(sizeof (tstate_t), M_DEVBUF, M_NOWAIT|M_ZERO); if (tptr == NULL) { return (CAM_RESRC_UNAVAIL); } tptr->ts_lun = lun; SLIST_INIT(&tptr->atios); SLIST_INIT(&tptr->inots); STAILQ_INIT(&tptr->restart_queue); ISP_GET_PC_ADDR(isp, bus, lun_hash[LUN_HASH_FUNC(lun)], lhp); SLIST_INSERT_HEAD(lhp, tptr, next); *rslt = tptr; ISP_PATH_PRT(isp, ISP_LOGTDEBUG0, path, "created tstate\n"); return (CAM_REQ_CMP); } static void destroy_lun_state(ispsoftc_t *isp, int bus, tstate_t *tptr) { union ccb *ccb; struct tslist *lhp; inot_private_data_t *ntp; while ((ccb = (union ccb *)SLIST_FIRST(&tptr->atios)) != NULL) { SLIST_REMOVE_HEAD(&tptr->atios, sim_links.sle); ccb->ccb_h.status = CAM_REQ_ABORTED; xpt_done(ccb); }; while ((ccb = (union ccb *)SLIST_FIRST(&tptr->inots)) != NULL) { SLIST_REMOVE_HEAD(&tptr->inots, sim_links.sle); ccb->ccb_h.status = CAM_REQ_ABORTED; xpt_done(ccb); } while ((ntp = STAILQ_FIRST(&tptr->restart_queue)) != NULL) { isp_endcmd(isp, ntp->data, NIL_HANDLE, bus, SCSI_STATUS_BUSY, 0); STAILQ_REMOVE_HEAD(&tptr->restart_queue, next); isp_put_ntpd(isp, bus, ntp); } ISP_GET_PC_ADDR(isp, bus, lun_hash[LUN_HASH_FUNC(tptr->ts_lun)], lhp); SLIST_REMOVE(lhp, tptr, tstate, next); free(tptr, M_DEVBUF); } static void isp_enable_lun(ispsoftc_t *isp, union ccb *ccb) { tstate_t *tptr; int bus; target_id_t target; lun_id_t lun; if (!IS_FC(isp) || !ISP_CAP_TMODE(isp) || !ISP_CAP_SCCFW(isp)) { xpt_print(ccb->ccb_h.path, "Target mode is not supported\n"); ccb->ccb_h.status = CAM_FUNC_NOTAVAIL; xpt_done(ccb); return; } /* * We only support either target and lun both wildcard * or target and lun both non-wildcard. */ bus = XS_CHANNEL(ccb); target = ccb->ccb_h.target_id; lun = ccb->ccb_h.target_lun; ISP_PATH_PRT(isp, ISP_LOGTDEBUG0|ISP_LOGCONFIG, ccb->ccb_h.path, "enabling lun %jx\n", (uintmax_t)lun); if ((target == CAM_TARGET_WILDCARD) != (lun == CAM_LUN_WILDCARD)) { ccb->ccb_h.status = CAM_LUN_INVALID; xpt_done(ccb); return; } /* Create the state pointer. It should not already exist. */ tptr = get_lun_statep(isp, bus, lun); if (tptr) { ccb->ccb_h.status = CAM_LUN_ALRDY_ENA; xpt_done(ccb); return; } ccb->ccb_h.status = create_lun_state(isp, bus, ccb->ccb_h.path, &tptr); if (ccb->ccb_h.status != CAM_REQ_CMP) { xpt_done(ccb); return; } ccb->ccb_h.status = CAM_REQ_CMP; xpt_done(ccb); } static void isp_disable_lun(ispsoftc_t *isp, union ccb *ccb) { tstate_t *tptr = NULL; int bus; target_id_t target; lun_id_t lun; bus = XS_CHANNEL(ccb); target = ccb->ccb_h.target_id; lun = ccb->ccb_h.target_lun; ISP_PATH_PRT(isp, ISP_LOGTDEBUG0|ISP_LOGCONFIG, ccb->ccb_h.path, "disabling lun %jx\n", (uintmax_t)lun); if ((target == CAM_TARGET_WILDCARD) != (lun == CAM_LUN_WILDCARD)) { ccb->ccb_h.status = CAM_LUN_INVALID; xpt_done(ccb); return; } /* Find the state pointer. */ if ((tptr = get_lun_statep(isp, bus, lun)) == NULL) { ccb->ccb_h.status = CAM_PATH_INVALID; xpt_done(ccb); return; } destroy_lun_state(isp, bus, tptr); ccb->ccb_h.status = CAM_REQ_CMP; xpt_done(ccb); } static void isp_target_start_ctio(ispsoftc_t *isp, union ccb *ccb, enum Start_Ctio_How how) { int fctape, sendstatus, resid; fcparam *fcp; atio_private_data_t *atp; struct ccb_scsiio *cso; struct isp_ccbq *waitq; uint32_t dmaresult, handle, xfrlen, sense_length, tmp; uint8_t local[QENTRY_LEN]; isp_prt(isp, ISP_LOGTDEBUG0, "%s: ENTRY[0x%x] how %u xfrlen %u sendstatus %d sense_len %u", __func__, ccb->csio.tag_id, how, ccb->csio.dxfer_len, (ccb->ccb_h.flags & CAM_SEND_STATUS) != 0, ((ccb->ccb_h.flags & CAM_SEND_SENSE)? ccb->csio.sense_len : 0)); ISP_GET_PC_ADDR(isp, XS_CHANNEL(ccb), waitq, waitq); switch (how) { case FROM_CAM: /* * Insert at the tail of the list, if any, waiting CTIO CCBs */ TAILQ_INSERT_TAIL(waitq, &ccb->ccb_h, sim_links.tqe); break; case FROM_TIMER: case FROM_SRR: case FROM_CTIO_DONE: TAILQ_INSERT_HEAD(waitq, &ccb->ccb_h, sim_links.tqe); break; } while ((ccb = (union ccb *) TAILQ_FIRST(waitq)) != NULL) { TAILQ_REMOVE(waitq, &ccb->ccb_h, sim_links.tqe); cso = &ccb->csio; xfrlen = cso->dxfer_len; if (xfrlen == 0) { if ((ccb->ccb_h.flags & CAM_SEND_STATUS) == 0) { ISP_PATH_PRT(isp, ISP_LOGERR, ccb->ccb_h.path, "a data transfer length of zero but no status to send is wrong\n"); ccb->ccb_h.status = CAM_REQ_INVALID; xpt_done(ccb); continue; } } atp = isp_find_atpd(isp, XS_CHANNEL(ccb), cso->tag_id); if (atp == NULL) { isp_prt(isp, ISP_LOGERR, "%s: [0x%x] cannot find private data adjunct in %s", __func__, cso->tag_id, __func__); isp_dump_atpd(isp, XS_CHANNEL(ccb)); ccb->ccb_h.status = CAM_REQ_CMP_ERR; xpt_done(ccb); continue; } /* * Is this command a dead duck? */ if (atp->dead) { isp_prt(isp, ISP_LOGERR, "%s: [0x%x] not sending a CTIO for a dead command", __func__, cso->tag_id); ccb->ccb_h.status = CAM_REQ_ABORTED; xpt_done(ccb); continue; } /* * Check to make sure we're still in target mode. */ fcp = FCPARAM(isp, XS_CHANNEL(ccb)); if ((fcp->role & ISP_ROLE_TARGET) == 0) { isp_prt(isp, ISP_LOGERR, "%s: [0x%x] stopping sending a CTIO because we're no longer in target mode", __func__, cso->tag_id); ccb->ccb_h.status = CAM_PROVIDE_FAIL; xpt_done(ccb); continue; } /* * We're only handling ATPD_CCB_OUTSTANDING outstanding CCB at a time (one of which * could be split into two CTIOs to split data and status). */ if (atp->ctcnt >= ATPD_CCB_OUTSTANDING) { isp_prt(isp, ISP_LOGTINFO, "[0x%x] handling only %d CCBs at a time (flags for this ccb: 0x%x)", cso->tag_id, ATPD_CCB_OUTSTANDING, ccb->ccb_h.flags); TAILQ_INSERT_HEAD(waitq, &ccb->ccb_h, sim_links.tqe); break; } /* * Does the initiator expect FC-Tape style responses? */ if ((atp->word3 & PRLI_WD3_RETRY) && fcp->fctape_enabled) { fctape = 1; } else { fctape = 0; } /* * If we already did the data xfer portion of a CTIO that sends data * and status, don't do it again and do the status portion now. */ if (atp->sendst) { isp_prt(isp, ISP_LOGTDEBUG0, "[0x%x] now sending synthesized status orig_dl=%u xfered=%u bit=%u", cso->tag_id, atp->orig_datalen, atp->bytes_xfered, atp->bytes_in_transit); xfrlen = 0; /* we already did the data transfer */ atp->sendst = 0; } if (ccb->ccb_h.flags & CAM_SEND_STATUS) { sendstatus = 1; } else { sendstatus = 0; } if (ccb->ccb_h.flags & CAM_SEND_SENSE) { KASSERT((sendstatus != 0), ("how can you have CAM_SEND_SENSE w/o CAM_SEND_STATUS?")); /* * Sense length is not the entire sense data structure size. Periph * drivers don't seem to be setting sense_len to reflect the actual * size. We'll peek inside to get the right amount. */ sense_length = cso->sense_len; /* * This 'cannot' happen */ if (sense_length > (XCMD_SIZE - MIN_FCP_RESPONSE_SIZE)) { sense_length = XCMD_SIZE - MIN_FCP_RESPONSE_SIZE; } } else { sense_length = 0; } memset(local, 0, QENTRY_LEN); /* * Check for overflow */ tmp = atp->bytes_xfered + atp->bytes_in_transit; if (xfrlen > 0 && tmp > atp->orig_datalen) { isp_prt(isp, ISP_LOGERR, "%s: [0x%x] data overflow by %u bytes", __func__, cso->tag_id, tmp + xfrlen - atp->orig_datalen); ccb->ccb_h.status = CAM_DATA_RUN_ERR; xpt_done(ccb); continue; } if (xfrlen > atp->orig_datalen - tmp) { xfrlen = atp->orig_datalen - tmp; if (xfrlen == 0 && !sendstatus) { cso->resid = cso->dxfer_len; ccb->ccb_h.status = CAM_REQ_CMP; xpt_done(ccb); continue; } } if (IS_24XX(isp)) { ct7_entry_t *cto = (ct7_entry_t *) local; cto->ct_header.rqs_entry_type = RQSTYPE_CTIO7; cto->ct_header.rqs_entry_count = 1; cto->ct_header.rqs_seqno |= ATPD_SEQ_NOTIFY_CAM; ATPD_SET_SEQNO(cto, atp); cto->ct_nphdl = atp->nphdl; cto->ct_rxid = atp->tag; cto->ct_iid_lo = atp->sid; cto->ct_iid_hi = atp->sid >> 16; cto->ct_oxid = atp->oxid; cto->ct_vpidx = ISP_GET_VPIDX(isp, XS_CHANNEL(ccb)); cto->ct_timeout = XS_TIME(ccb); cto->ct_flags = atp->tattr << CT7_TASK_ATTR_SHIFT; /* * Mode 1, status, no data. Only possible when we are sending status, have * no data to transfer, and any sense data can fit into a ct7_entry_t. * * Mode 2, status, no data. We have to use this in the case that * the sense data won't fit into a ct7_entry_t. * */ if (sendstatus && xfrlen == 0) { cto->ct_flags |= CT7_SENDSTATUS | CT7_NO_DATA; resid = atp->orig_datalen - atp->bytes_xfered - atp->bytes_in_transit; if (sense_length <= MAXRESPLEN_24XX) { cto->ct_flags |= CT7_FLAG_MODE1; cto->ct_scsi_status = cso->scsi_status; if (resid < 0) { cto->ct_resid = -resid; cto->ct_scsi_status |= (FCP_RESID_OVERFLOW << 8); } else if (resid > 0) { cto->ct_resid = resid; cto->ct_scsi_status |= (FCP_RESID_UNDERFLOW << 8); } if (fctape) { cto->ct_flags |= CT7_CONFIRM|CT7_EXPLCT_CONF; } if (sense_length) { cto->ct_scsi_status |= (FCP_SNSLEN_VALID << 8); cto->rsp.m1.ct_resplen = cto->ct_senselen = sense_length; memcpy(cto->rsp.m1.ct_resp, &cso->sense_data, sense_length); } } else { bus_addr_t addr; char buf[XCMD_SIZE]; fcp_rsp_iu_t *rp; if (atp->ests == NULL) { atp->ests = isp_get_ecmd(isp); if (atp->ests == NULL) { TAILQ_INSERT_HEAD(waitq, &ccb->ccb_h, sim_links.tqe); break; } } memset(buf, 0, sizeof (buf)); rp = (fcp_rsp_iu_t *)buf; if (fctape) { cto->ct_flags |= CT7_CONFIRM|CT7_EXPLCT_CONF; rp->fcp_rsp_bits |= FCP_CONF_REQ; } cto->ct_flags |= CT7_FLAG_MODE2; rp->fcp_rsp_scsi_status = cso->scsi_status; if (resid < 0) { rp->fcp_rsp_resid = -resid; rp->fcp_rsp_bits |= FCP_RESID_OVERFLOW; } else if (resid > 0) { rp->fcp_rsp_resid = resid; rp->fcp_rsp_bits |= FCP_RESID_UNDERFLOW; } if (sense_length) { rp->fcp_rsp_snslen = sense_length; cto->ct_senselen = sense_length; rp->fcp_rsp_bits |= FCP_SNSLEN_VALID; isp_put_fcp_rsp_iu(isp, rp, atp->ests); memcpy(((fcp_rsp_iu_t *)atp->ests)->fcp_rsp_extra, &cso->sense_data, sense_length); } else { isp_put_fcp_rsp_iu(isp, rp, atp->ests); } if (isp->isp_dblev & ISP_LOGTDEBUG1) { isp_print_bytes(isp, "FCP Response Frame After Swizzling", MIN_FCP_RESPONSE_SIZE + sense_length, atp->ests); } addr = isp->isp_osinfo.ecmd_dma; addr += ((((isp_ecmd_t *)atp->ests) - isp->isp_osinfo.ecmd_base) * XCMD_SIZE); isp_prt(isp, ISP_LOGTDEBUG0, "%s: ests base %p vaddr %p ecmd_dma %jx addr %jx len %u", __func__, isp->isp_osinfo.ecmd_base, atp->ests, (uintmax_t) isp->isp_osinfo.ecmd_dma, (uintmax_t)addr, MIN_FCP_RESPONSE_SIZE + sense_length); cto->rsp.m2.ct_datalen = MIN_FCP_RESPONSE_SIZE + sense_length; cto->rsp.m2.ct_fcp_rsp_iudata.ds_base = DMA_LO32(addr); cto->rsp.m2.ct_fcp_rsp_iudata.ds_basehi = DMA_HI32(addr); cto->rsp.m2.ct_fcp_rsp_iudata.ds_count = MIN_FCP_RESPONSE_SIZE + sense_length; } if (sense_length) { isp_prt(isp, ISP_LOGTDEBUG0, "%s: CTIO7[0x%x] seq %u nc %d CDB0=%x sstatus=0x%x flags=0x%x resid=%d slen %u sense: %x %x/%x/%x", __func__, cto->ct_rxid, ATPD_GET_SEQNO(cto), ATPD_GET_NCAM(cto), atp->cdb0, cto->ct_scsi_status, cto->ct_flags, cto->ct_resid, sense_length, cso->sense_data.error_code, cso->sense_data.sense_buf[1], cso->sense_data.sense_buf[11], cso->sense_data.sense_buf[12]); } else { isp_prt(isp, ISP_LOGDEBUG0, "%s: CTIO7[0x%x] seq %u nc %d CDB0=%x sstatus=0x%x flags=0x%x resid=%d", __func__, cto->ct_rxid, ATPD_GET_SEQNO(cto), ATPD_GET_NCAM(cto), atp->cdb0, cto->ct_scsi_status, cto->ct_flags, cto->ct_resid); } atp->state = ATPD_STATE_LAST_CTIO; } /* * Mode 0 data transfers, *possibly* with status. */ if (xfrlen != 0) { cto->ct_flags |= CT7_FLAG_MODE0; if ((cso->ccb_h.flags & CAM_DIR_MASK) == CAM_DIR_IN) { cto->ct_flags |= CT7_DATA_IN; } else { cto->ct_flags |= CT7_DATA_OUT; } cto->rsp.m0.reloff = atp->bytes_xfered + atp->bytes_in_transit; cto->rsp.m0.ct_xfrlen = xfrlen; #ifdef DEBUG if (ISP_FC_PC(isp, XS_CHANNEL(ccb))->inject_lost_data_frame && xfrlen > ISP_FC_PC(isp, XS_CHANNEL(ccb))->inject_lost_data_frame) { isp_prt(isp, ISP_LOGWARN, "%s: truncating data frame with xfrlen %d to %d", __func__, xfrlen, xfrlen - (xfrlen >> 2)); ISP_FC_PC(isp, XS_CHANNEL(ccb))->inject_lost_data_frame = 0; cto->rsp.m0.ct_xfrlen -= xfrlen >> 2; } #endif if (sendstatus) { resid = atp->orig_datalen - atp->bytes_xfered - xfrlen; if (cso->scsi_status == SCSI_STATUS_OK && resid == 0 /* && fctape == 0 */) { cto->ct_flags |= CT7_SENDSTATUS; atp->state = ATPD_STATE_LAST_CTIO; if (fctape) { cto->ct_flags |= CT7_CONFIRM|CT7_EXPLCT_CONF; } } else { atp->sendst = 1; /* send status later */ cto->ct_header.rqs_seqno &= ~ATPD_SEQ_NOTIFY_CAM; atp->state = ATPD_STATE_CTIO; } } else { atp->state = ATPD_STATE_CTIO; } isp_prt(isp, ISP_LOGTDEBUG0, "%s: CTIO7[0x%x] seq %u nc %d CDB0=%x sstatus=0x%x flags=0x%x xfrlen=%u off=%u", __func__, cto->ct_rxid, ATPD_GET_SEQNO(cto), ATPD_GET_NCAM(cto), atp->cdb0, cto->ct_scsi_status, cto->ct_flags, xfrlen, atp->bytes_xfered); } } else { ct2_entry_t *cto = (ct2_entry_t *) local; cto->ct_header.rqs_entry_type = RQSTYPE_CTIO2; cto->ct_header.rqs_entry_count = 1; cto->ct_header.rqs_seqno |= ATPD_SEQ_NOTIFY_CAM; ATPD_SET_SEQNO(cto, atp); if (ISP_CAP_2KLOGIN(isp)) { ((ct2e_entry_t *)cto)->ct_iid = atp->nphdl; } else { cto->ct_iid = atp->nphdl; if (ISP_CAP_SCCFW(isp) == 0) { cto->ct_lun = ccb->ccb_h.target_lun; } } cto->ct_timeout = XS_TIME(ccb); cto->ct_rxid = cso->tag_id; /* * Mode 1, status, no data. Only possible when we are sending status, have * no data to transfer, and the sense length can fit in the ct7_entry. * * Mode 2, status, no data. We have to use this in the case the response * length won't fit into a ct2_entry_t. * * We'll fill out this structure with information as if this were a * Mode 1. The hardware layer will create the Mode 2 FCP RSP IU as * needed based upon this. */ if (sendstatus && xfrlen == 0) { cto->ct_flags |= CT2_SENDSTATUS | CT2_NO_DATA; resid = atp->orig_datalen - atp->bytes_xfered - atp->bytes_in_transit; if (sense_length <= MAXRESPLEN) { if (resid < 0) { cto->ct_resid = -resid; } else if (resid > 0) { cto->ct_resid = resid; } cto->ct_flags |= CT2_FLAG_MODE1; cto->rsp.m1.ct_scsi_status = cso->scsi_status; if (resid < 0) { cto->rsp.m1.ct_scsi_status |= CT2_DATA_OVER; } else if (resid > 0) { cto->rsp.m1.ct_scsi_status |= CT2_DATA_UNDER; } if (fctape) { cto->ct_flags |= CT2_CONFIRM; } if (sense_length) { cto->rsp.m1.ct_scsi_status |= CT2_SNSLEN_VALID; cto->rsp.m1.ct_resplen = cto->rsp.m1.ct_senselen = sense_length; memcpy(cto->rsp.m1.ct_resp, &cso->sense_data, sense_length); } } else { bus_addr_t addr; char buf[XCMD_SIZE]; fcp_rsp_iu_t *rp; if (atp->ests == NULL) { atp->ests = isp_get_ecmd(isp); if (atp->ests == NULL) { TAILQ_INSERT_HEAD(waitq, &ccb->ccb_h, sim_links.tqe); break; } } memset(buf, 0, sizeof (buf)); rp = (fcp_rsp_iu_t *)buf; if (fctape) { cto->ct_flags |= CT2_CONFIRM; rp->fcp_rsp_bits |= FCP_CONF_REQ; } cto->ct_flags |= CT2_FLAG_MODE2; rp->fcp_rsp_scsi_status = cso->scsi_status; if (resid < 0) { rp->fcp_rsp_resid = -resid; rp->fcp_rsp_bits |= FCP_RESID_OVERFLOW; } else if (resid > 0) { rp->fcp_rsp_resid = resid; rp->fcp_rsp_bits |= FCP_RESID_UNDERFLOW; } if (sense_length) { rp->fcp_rsp_snslen = sense_length; rp->fcp_rsp_bits |= FCP_SNSLEN_VALID; isp_put_fcp_rsp_iu(isp, rp, atp->ests); memcpy(((fcp_rsp_iu_t *)atp->ests)->fcp_rsp_extra, &cso->sense_data, sense_length); } else { isp_put_fcp_rsp_iu(isp, rp, atp->ests); } if (isp->isp_dblev & ISP_LOGTDEBUG1) { isp_print_bytes(isp, "FCP Response Frame After Swizzling", MIN_FCP_RESPONSE_SIZE + sense_length, atp->ests); } addr = isp->isp_osinfo.ecmd_dma; addr += ((((isp_ecmd_t *)atp->ests) - isp->isp_osinfo.ecmd_base) * XCMD_SIZE); isp_prt(isp, ISP_LOGTDEBUG0, "%s: ests base %p vaddr %p ecmd_dma %jx addr %jx len %u", __func__, isp->isp_osinfo.ecmd_base, atp->ests, (uintmax_t) isp->isp_osinfo.ecmd_dma, (uintmax_t)addr, MIN_FCP_RESPONSE_SIZE + sense_length); cto->rsp.m2.ct_datalen = MIN_FCP_RESPONSE_SIZE + sense_length; cto->rsp.m2.u.ct_fcp_rsp_iudata_32.ds_base = DMA_LO32(addr); cto->rsp.m2.u.ct_fcp_rsp_iudata_32.ds_count = MIN_FCP_RESPONSE_SIZE + sense_length; } if (sense_length) { isp_prt(isp, ISP_LOGTDEBUG0, "%s: CTIO2[0x%x] seq %u nc %d CDB0=%x sstatus=0x%x flags=0x%x resid=%d sense: %x %x/%x/%x", __func__, cto->ct_rxid, ATPD_GET_SEQNO(cto), ATPD_GET_NCAM(cto), atp->cdb0, cso->scsi_status, cto->ct_flags, cto->ct_resid, cso->sense_data.error_code, cso->sense_data.sense_buf[1], cso->sense_data.sense_buf[11], cso->sense_data.sense_buf[12]); } else { isp_prt(isp, ISP_LOGTDEBUG0, "%s: CTIO2[0x%x] seq %u nc %d CDB0=%x sstatus=0x%x flags=0x%x resid=%d", __func__, cto->ct_rxid, ATPD_GET_SEQNO(cto), ATPD_GET_NCAM(cto), atp->cdb0, cso->scsi_status, cto->ct_flags, cto->ct_resid); } atp->state = ATPD_STATE_LAST_CTIO; } if (xfrlen != 0) { cto->ct_flags |= CT2_FLAG_MODE0; if ((cso->ccb_h.flags & CAM_DIR_MASK) == CAM_DIR_IN) { cto->ct_flags |= CT2_DATA_IN; } else { cto->ct_flags |= CT2_DATA_OUT; } cto->ct_reloff = atp->bytes_xfered + atp->bytes_in_transit; cto->rsp.m0.ct_xfrlen = xfrlen; if (sendstatus) { resid = atp->orig_datalen - atp->bytes_xfered - xfrlen; if (cso->scsi_status == SCSI_STATUS_OK && resid == 0 /*&& fctape == 0*/) { cto->ct_flags |= CT2_SENDSTATUS; atp->state = ATPD_STATE_LAST_CTIO; if (fctape) { cto->ct_flags |= CT2_CONFIRM; } } else { atp->sendst = 1; /* send status later */ cto->ct_header.rqs_seqno &= ~ATPD_SEQ_NOTIFY_CAM; atp->state = ATPD_STATE_CTIO; } } else { atp->state = ATPD_STATE_CTIO; } } isp_prt(isp, ISP_LOGTDEBUG0, "%s: CTIO2[%x] seq %u nc %d CDB0=%x scsi status %x flags %x resid %d xfrlen %u offset %u", __func__, cto->ct_rxid, ATPD_GET_SEQNO(cto), ATPD_GET_NCAM(cto), atp->cdb0, cso->scsi_status, cto->ct_flags, cto->ct_resid, cso->dxfer_len, atp->bytes_xfered); } if (isp_get_pcmd(isp, ccb)) { ISP_PATH_PRT(isp, ISP_LOGWARN, ccb->ccb_h.path, "out of PCMDs\n"); TAILQ_INSERT_HEAD(waitq, &ccb->ccb_h, sim_links.tqe); break; } handle = isp_allocate_handle(isp, ccb, ISP_HANDLE_TARGET); if (handle == 0) { ISP_PATH_PRT(isp, ISP_LOGWARN, ccb->ccb_h.path, "No XFLIST pointers for %s\n", __func__); TAILQ_INSERT_HEAD(waitq, &ccb->ccb_h, sim_links.tqe); isp_free_pcmd(isp, ccb); break; } atp->bytes_in_transit += xfrlen; PISP_PCMD(ccb)->datalen = xfrlen; /* * Call the dma setup routines for this entry (and any subsequent * CTIOs) if there's data to move, and then tell the f/w it's got * new things to play with. As with isp_start's usage of DMA setup, * any swizzling is done in the machine dependent layer. Because * of this, we put the request onto the queue area first in native * format. */ if (IS_24XX(isp)) { ct7_entry_t *cto = (ct7_entry_t *) local; cto->ct_syshandle = handle; } else { ct2_entry_t *cto = (ct2_entry_t *) local; cto->ct_syshandle = handle; } dmaresult = ISP_DMASETUP(isp, cso, (ispreq_t *) local); if (dmaresult != CMD_QUEUED) { isp_destroy_handle(isp, handle); isp_free_pcmd(isp, ccb); if (dmaresult == CMD_EAGAIN) { TAILQ_INSERT_HEAD(waitq, &ccb->ccb_h, sim_links.tqe); break; } ccb->ccb_h.status = CAM_REQ_CMP_ERR; xpt_done(ccb); continue; } ccb->ccb_h.status = CAM_REQ_INPROG | CAM_SIM_QUEUED; if (xfrlen) { ccb->ccb_h.spriv_field0 = atp->bytes_xfered; } else { ccb->ccb_h.spriv_field0 = ~0; } atp->ctcnt++; atp->seqno++; } } static void isp_refire_putback_atio(void *arg) { union ccb *ccb = arg; ISP_ASSERT_LOCKED((ispsoftc_t *)XS_ISP(ccb)); isp_target_putback_atio(ccb); } static void isp_refire_notify_ack(void *arg) { isp_tna_t *tp = arg; ispsoftc_t *isp = tp->isp; ISP_ASSERT_LOCKED(isp); if (isp_notify_ack(isp, tp->not)) { callout_schedule(&tp->timer, 5); } else { free(tp, M_DEVBUF); } } static void isp_target_putback_atio(union ccb *ccb) { ispsoftc_t *isp = XS_ISP(ccb); struct ccb_scsiio *cso = &ccb->csio; at2_entry_t local, *at = &local; ISP_MEMZERO(at, sizeof (at2_entry_t)); at->at_header.rqs_entry_type = RQSTYPE_ATIO2; at->at_header.rqs_entry_count = 1; if (ISP_CAP_SCCFW(isp)) { at->at_scclun = (uint16_t) ccb->ccb_h.target_lun; } else { at->at_lun = (uint8_t) ccb->ccb_h.target_lun; } at->at_status = CT_OK; at->at_rxid = cso->tag_id; at->at_iid = cso->init_id; if (isp_target_put_entry(isp, at)) { callout_reset(&PISP_PCMD(ccb)->wdog, 10, isp_refire_putback_atio, ccb); } else isp_complete_ctio(ccb); } static void isp_complete_ctio(union ccb *ccb) { if ((ccb->ccb_h.status & CAM_STATUS_MASK) != CAM_REQ_INPROG) { ccb->ccb_h.status &= ~CAM_SIM_QUEUED; xpt_done(ccb); } } static void isp_handle_platform_atio2(ispsoftc_t *isp, at2_entry_t *aep) { fcparam *fcp; lun_id_t lun; fcportdb_t *lp; tstate_t *tptr; struct ccb_accept_tio *atiop; uint16_t nphdl; atio_private_data_t *atp; inot_private_data_t *ntp; /* * The firmware status (except for the QLTM_SVALID bit) * indicates why this ATIO was sent to us. * * If QLTM_SVALID is set, the firmware has recommended Sense Data. */ if ((aep->at_status & ~QLTM_SVALID) != AT_CDB) { isp_prt(isp, ISP_LOGWARN, "bogus atio (0x%x) leaked to platform", aep->at_status); isp_endcmd(isp, aep, NIL_HANDLE, 0, SCSI_STATUS_BUSY, 0); return; } fcp = FCPARAM(isp, 0); if (ISP_CAP_SCCFW(isp)) { lun = aep->at_scclun; } else { lun = aep->at_lun; } if (ISP_CAP_2KLOGIN(isp)) { nphdl = ((at2e_entry_t *)aep)->at_iid; } else { nphdl = aep->at_iid; } tptr = get_lun_statep(isp, 0, lun); if (tptr == NULL) { tptr = get_lun_statep(isp, 0, CAM_LUN_WILDCARD); if (tptr == NULL) { isp_prt(isp, ISP_LOGWARN, "%s: [0x%x] no state pointer for lun %jx or wildcard", __func__, aep->at_rxid, (uintmax_t)lun); if (lun == 0) { isp_endcmd(isp, aep, nphdl, 0, SCSI_STATUS_BUSY, 0); } else { isp_endcmd(isp, aep, nphdl, 0, SCSI_STATUS_CHECK_COND | ECMD_SVALID | (0x5 << 12) | (0x25 << 16), 0); } return; } } /* * Start any commands pending resources first. */ if (isp_atio_restart(isp, 0, tptr)) goto noresrc; atiop = (struct ccb_accept_tio *) SLIST_FIRST(&tptr->atios); if (atiop == NULL) { goto noresrc; } atp = isp_get_atpd(isp, 0, aep->at_rxid); if (atp == NULL) { goto noresrc; } atp->state = ATPD_STATE_ATIO; SLIST_REMOVE_HEAD(&tptr->atios, sim_links.sle); ISP_PATH_PRT(isp, ISP_LOGTDEBUG2, atiop->ccb_h.path, "Take FREE ATIO\n"); atiop->ccb_h.target_id = ISP_MAX_TARGETS(isp); atiop->ccb_h.target_lun = lun; /* * We don't get 'suggested' sense data as we do with SCSI cards. */ atiop->sense_len = 0; /* * If we're not in the port database, add ourselves. */ if (IS_2100(isp)) atiop->init_id = nphdl; else { if (isp_find_pdb_by_handle(isp, 0, nphdl, &lp)) { atiop->init_id = FC_PORTDB_TGT(isp, 0, lp); } else { isp_prt(isp, ISP_LOGTINFO, "%s: port %x isn't in PDB", __func__, nphdl); isp_dump_portdb(isp, 0); isp_endcmd(isp, aep, NIL_HANDLE, 0, ECMD_TERMINATE, 0); return; } } atiop->cdb_len = ATIO2_CDBLEN; ISP_MEMCPY(atiop->cdb_io.cdb_bytes, aep->at_cdb, ATIO2_CDBLEN); atiop->ccb_h.status = CAM_CDB_RECVD; atiop->tag_id = atp->tag; switch (aep->at_taskflags & ATIO2_TC_ATTR_MASK) { case ATIO2_TC_ATTR_SIMPLEQ: atiop->ccb_h.flags |= CAM_TAG_ACTION_VALID; atiop->tag_action = MSG_SIMPLE_Q_TAG; break; case ATIO2_TC_ATTR_HEADOFQ: atiop->ccb_h.flags |= CAM_TAG_ACTION_VALID; atiop->tag_action = MSG_HEAD_OF_Q_TAG; break; case ATIO2_TC_ATTR_ORDERED: atiop->ccb_h.flags |= CAM_TAG_ACTION_VALID; atiop->tag_action = MSG_ORDERED_Q_TAG; break; case ATIO2_TC_ATTR_ACAQ: /* ?? */ case ATIO2_TC_ATTR_UNTAGGED: default: atiop->tag_action = 0; break; } atp->orig_datalen = aep->at_datalen; atp->bytes_xfered = 0; atp->lun = lun; atp->nphdl = nphdl; atp->sid = PORT_ANY; atp->oxid = aep->at_oxid; atp->cdb0 = aep->at_cdb[0]; atp->tattr = aep->at_taskflags & ATIO2_TC_ATTR_MASK; atp->state = ATPD_STATE_CAM; xpt_done((union ccb *)atiop); isp_prt(isp, ISP_LOGTDEBUG0, "ATIO2[0x%x] CDB=0x%x lun %jx datalen %u", aep->at_rxid, atp->cdb0, (uintmax_t)lun, atp->orig_datalen); return; noresrc: ntp = isp_get_ntpd(isp, 0); if (ntp == NULL) { isp_endcmd(isp, aep, nphdl, 0, SCSI_STATUS_BUSY, 0); return; } memcpy(ntp->data, aep, QENTRY_LEN); STAILQ_INSERT_TAIL(&tptr->restart_queue, ntp, next); } static void isp_handle_platform_atio7(ispsoftc_t *isp, at7_entry_t *aep) { int cdbxlen; lun_id_t lun; uint16_t chan, nphdl = NIL_HANDLE; uint32_t did, sid; fcportdb_t *lp; tstate_t *tptr; struct ccb_accept_tio *atiop; atio_private_data_t *atp = NULL; atio_private_data_t *oatp; inot_private_data_t *ntp; did = (aep->at_hdr.d_id[0] << 16) | (aep->at_hdr.d_id[1] << 8) | aep->at_hdr.d_id[2]; sid = (aep->at_hdr.s_id[0] << 16) | (aep->at_hdr.s_id[1] << 8) | aep->at_hdr.s_id[2]; lun = CAM_EXTLUN_BYTE_SWIZZLE(be64dec(aep->at_cmnd.fcp_cmnd_lun)); if (ISP_CAP_MULTI_ID(isp) && isp->isp_nchan > 1) { /* Channel has to be derived from D_ID */ isp_find_chan_by_did(isp, did, &chan); if (chan == ISP_NOCHAN) { isp_prt(isp, ISP_LOGWARN, "%s: [RX_ID 0x%x] D_ID %x not found on any channel", __func__, aep->at_rxid, did); isp_endcmd(isp, aep, NIL_HANDLE, ISP_NOCHAN, ECMD_TERMINATE, 0); return; } } else { chan = 0; } /* * Find the PDB entry for this initiator */ if (isp_find_pdb_by_portid(isp, chan, sid, &lp) == 0) { /* * If we're not in the port database terminate the exchange. */ isp_prt(isp, ISP_LOGTINFO, "%s: [RX_ID 0x%x] D_ID 0x%06x found on Chan %d for S_ID 0x%06x wasn't in PDB already", __func__, aep->at_rxid, did, chan, sid); isp_dump_portdb(isp, chan); isp_endcmd(isp, aep, NIL_HANDLE, chan, ECMD_TERMINATE, 0); return; } nphdl = lp->handle; /* * Get the tstate pointer */ tptr = get_lun_statep(isp, chan, lun); if (tptr == NULL) { tptr = get_lun_statep(isp, chan, CAM_LUN_WILDCARD); if (tptr == NULL) { isp_prt(isp, ISP_LOGWARN, "%s: [0x%x] no state pointer for lun %jx or wildcard", __func__, aep->at_rxid, (uintmax_t)lun); if (lun == 0) { isp_endcmd(isp, aep, nphdl, chan, SCSI_STATUS_BUSY, 0); } else { isp_endcmd(isp, aep, nphdl, chan, SCSI_STATUS_CHECK_COND | ECMD_SVALID | (0x5 << 12) | (0x25 << 16), 0); } return; } } /* * Start any commands pending resources first. */ if (isp_atio_restart(isp, chan, tptr)) goto noresrc; /* * If the f/w is out of resources, just send a BUSY status back. */ if (aep->at_rxid == AT7_NORESRC_RXID) { isp_endcmd(isp, aep, nphdl, chan, SCSI_BUSY, 0); return; } /* * If we're out of resources, just send a BUSY status back. */ atiop = (struct ccb_accept_tio *) SLIST_FIRST(&tptr->atios); if (atiop == NULL) { isp_prt(isp, ISP_LOGTDEBUG0, "[0x%x] out of atios", aep->at_rxid); goto noresrc; } oatp = isp_find_atpd(isp, chan, aep->at_rxid); if (oatp) { isp_prt(isp, ISP_LOGTDEBUG0, "[0x%x] tag wraparound in isp_handle_platforms_atio7 (N-Port Handle 0x%04x S_ID 0x%04x OX_ID 0x%04x) oatp state %d", aep->at_rxid, nphdl, sid, aep->at_hdr.ox_id, oatp->state); /* * It's not a "no resource" condition- but we can treat it like one */ goto noresrc; } atp = isp_get_atpd(isp, chan, aep->at_rxid); if (atp == NULL) { isp_prt(isp, ISP_LOGTDEBUG0, "[0x%x] out of atps", aep->at_rxid); goto noresrc; } atp->word3 = lp->prli_word3; atp->state = ATPD_STATE_ATIO; SLIST_REMOVE_HEAD(&tptr->atios, sim_links.sle); ISP_PATH_PRT(isp, ISP_LOGTDEBUG2, atiop->ccb_h.path, "Take FREE ATIO\n"); atiop->init_id = FC_PORTDB_TGT(isp, chan, lp); atiop->ccb_h.target_id = ISP_MAX_TARGETS(isp); atiop->ccb_h.target_lun = lun; atiop->sense_len = 0; cdbxlen = aep->at_cmnd.fcp_cmnd_alen_datadir >> FCP_CMND_ADDTL_CDBLEN_SHIFT; if (cdbxlen) { isp_prt(isp, ISP_LOGWARN, "additional CDBLEN ignored"); } cdbxlen = sizeof (aep->at_cmnd.cdb_dl.sf.fcp_cmnd_cdb); ISP_MEMCPY(atiop->cdb_io.cdb_bytes, aep->at_cmnd.cdb_dl.sf.fcp_cmnd_cdb, cdbxlen); atiop->cdb_len = cdbxlen; atiop->ccb_h.status = CAM_CDB_RECVD; atiop->tag_id = atp->tag; switch (aep->at_cmnd.fcp_cmnd_task_attribute & FCP_CMND_TASK_ATTR_MASK) { case FCP_CMND_TASK_ATTR_SIMPLE: atiop->ccb_h.flags |= CAM_TAG_ACTION_VALID; atiop->tag_action = MSG_SIMPLE_Q_TAG; break; case FCP_CMND_TASK_ATTR_HEAD: atiop->ccb_h.flags |= CAM_TAG_ACTION_VALID; atiop->tag_action = MSG_HEAD_OF_Q_TAG; break; case FCP_CMND_TASK_ATTR_ORDERED: atiop->ccb_h.flags |= CAM_TAG_ACTION_VALID; atiop->tag_action = MSG_ORDERED_Q_TAG; break; default: /* FALLTHROUGH */ case FCP_CMND_TASK_ATTR_ACA: case FCP_CMND_TASK_ATTR_UNTAGGED: atiop->tag_action = 0; break; } atp->orig_datalen = aep->at_cmnd.cdb_dl.sf.fcp_cmnd_dl; atp->bytes_xfered = 0; atp->lun = lun; atp->nphdl = nphdl; atp->sid = sid; atp->did = did; atp->oxid = aep->at_hdr.ox_id; atp->rxid = aep->at_hdr.rx_id; atp->cdb0 = atiop->cdb_io.cdb_bytes[0]; atp->tattr = aep->at_cmnd.fcp_cmnd_task_attribute & FCP_CMND_TASK_ATTR_MASK; atp->state = ATPD_STATE_CAM; isp_prt(isp, ISP_LOGTDEBUG0, "ATIO7[0x%x] CDB=0x%x lun %jx datalen %u", aep->at_rxid, atp->cdb0, (uintmax_t)lun, atp->orig_datalen); xpt_done((union ccb *)atiop); return; noresrc: if (atp) isp_put_atpd(isp, chan, atp); ntp = isp_get_ntpd(isp, chan); if (ntp == NULL) { isp_endcmd(isp, aep, nphdl, chan, SCSI_STATUS_BUSY, 0); return; } memcpy(ntp->data, aep, QENTRY_LEN); STAILQ_INSERT_TAIL(&tptr->restart_queue, ntp, next); } /* * Handle starting an SRR (sequence retransmit request) * We get here when we've gotten the immediate notify * and the return of all outstanding CTIOs for this * transaction. */ static void isp_handle_srr_start(ispsoftc_t *isp, atio_private_data_t *atp) { in_fcentry_24xx_t *inot; uint32_t srr_off, ccb_off, ccb_len, ccb_end; union ccb *ccb; inot = (in_fcentry_24xx_t *)atp->srr; srr_off = inot->in_srr_reloff_lo | (inot->in_srr_reloff_hi << 16); ccb = atp->srr_ccb; atp->srr_ccb = NULL; atp->nsrr++; if (ccb == NULL) { isp_prt(isp, ISP_LOGWARN, "SRR[0x%x] null ccb", atp->tag); goto fail; } ccb_off = ccb->ccb_h.spriv_field0; ccb_len = ccb->csio.dxfer_len; ccb_end = (ccb_off == ~0)? ~0 : ccb_off + ccb_len; switch (inot->in_srr_iu) { case R_CTL_INFO_SOLICITED_DATA: /* * We have to restart a FCP_DATA data out transaction */ atp->sendst = 0; atp->bytes_xfered = srr_off; if (ccb_len == 0) { isp_prt(isp, ISP_LOGWARN, "SRR[0x%x] SRR offset 0x%x but current CCB doesn't transfer data", atp->tag, srr_off); goto mdp; } if (srr_off < ccb_off || ccb_off > srr_off + ccb_len) { isp_prt(isp, ISP_LOGWARN, "SRR[0x%x] SRR offset 0x%x not covered by current CCB data range [0x%x..0x%x]", atp->tag, srr_off, ccb_off, ccb_end); goto mdp; } isp_prt(isp, ISP_LOGWARN, "SRR[0x%x] SRR offset 0x%x covered by current CCB data range [0x%x..0x%x]", atp->tag, srr_off, ccb_off, ccb_end); break; case R_CTL_INFO_COMMAND_STATUS: isp_prt(isp, ISP_LOGTINFO, "SRR[0x%x] Got an FCP RSP SRR- resending status", atp->tag); atp->sendst = 1; /* * We have to restart a FCP_RSP IU transaction */ break; case R_CTL_INFO_DATA_DESCRIPTOR: /* * We have to restart an FCP DATA in transaction */ isp_prt(isp, ISP_LOGWARN, "Got an FCP DATA IN SRR- dropping"); goto fail; default: isp_prt(isp, ISP_LOGWARN, "Got an unknown information (%x) SRR- dropping", inot->in_srr_iu); goto fail; } /* * We can't do anything until this is acked, so we might as well start it now. * We aren't going to do the usual asynchronous ack issue because we need * to make sure this gets on the wire first. */ if (isp_notify_ack(isp, inot)) { isp_prt(isp, ISP_LOGWARN, "could not push positive ack for SRR- you lose"); goto fail; } isp_target_start_ctio(isp, ccb, FROM_SRR); return; fail: inot->in_reserved = 1; isp_async(isp, ISPASYNC_TARGET_NOTIFY_ACK, inot); ccb->ccb_h.status &= ~CAM_STATUS_MASK; ccb->ccb_h.status |= CAM_REQ_CMP_ERR; isp_complete_ctio(ccb); return; mdp: if (isp_notify_ack(isp, inot)) { isp_prt(isp, ISP_LOGWARN, "could not push positive ack for SRR- you lose"); goto fail; } ccb->ccb_h.status &= ~CAM_STATUS_MASK; ccb->ccb_h.status = CAM_MESSAGE_RECV; /* * This is not a strict interpretation of MDP, but it's close */ ccb->csio.msg_ptr = &ccb->csio.sense_data.sense_buf[SSD_FULL_SIZE - 16]; ccb->csio.msg_len = 7; ccb->csio.msg_ptr[0] = MSG_EXTENDED; ccb->csio.msg_ptr[1] = 5; ccb->csio.msg_ptr[2] = 0; /* modify data pointer */ ccb->csio.msg_ptr[3] = srr_off >> 24; ccb->csio.msg_ptr[4] = srr_off >> 16; ccb->csio.msg_ptr[5] = srr_off >> 8; ccb->csio.msg_ptr[6] = srr_off; isp_complete_ctio(ccb); } static void isp_handle_platform_srr(ispsoftc_t *isp, isp_notify_t *notify) { in_fcentry_24xx_t *inot = notify->nt_lreserved; atio_private_data_t *atp; uint32_t tag = notify->nt_tagval & 0xffffffff; atp = isp_find_atpd(isp, notify->nt_channel, tag); if (atp == NULL) { isp_prt(isp, ISP_LOGERR, "%s: cannot find adjunct for %x in SRR Notify", __func__, tag); isp_async(isp, ISPASYNC_TARGET_NOTIFY_ACK, inot); return; } atp->srr_notify_rcvd = 1; memcpy(atp->srr, inot, sizeof (atp->srr)); isp_prt(isp, ISP_LOGTINFO, "SRR[0x%x] flags 0x%x srr_iu %x reloff 0x%x", inot->in_rxid, inot->in_flags, inot->in_srr_iu, ((uint32_t)inot->in_srr_reloff_hi << 16) | inot->in_srr_reloff_lo); if (atp->srr_ccb) isp_handle_srr_start(isp, atp); } static void isp_handle_platform_ctio(ispsoftc_t *isp, void *arg) { union ccb *ccb; int sentstatus = 0, ok = 0, notify_cam = 0, failure = 0; atio_private_data_t *atp = NULL; int bus; uint32_t handle, data_requested, resid; handle = ((ct2_entry_t *)arg)->ct_syshandle; ccb = isp_find_xs(isp, handle); if (ccb == NULL) { isp_print_bytes(isp, "null ccb in isp_handle_platform_ctio", QENTRY_LEN, arg); return; } isp_destroy_handle(isp, handle); resid = data_requested = PISP_PCMD(ccb)->datalen; isp_free_pcmd(isp, ccb); bus = XS_CHANNEL(ccb); if (IS_24XX(isp)) { atp = isp_find_atpd(isp, bus, ((ct7_entry_t *)arg)->ct_rxid); } else { atp = isp_find_atpd(isp, bus, ((ct2_entry_t *)arg)->ct_rxid); } if (atp == NULL) { /* * XXX: isp_clear_commands() generates fake CTIO with zero * ct_rxid value, filling only ct_syshandle. Workaround * that using tag_id from the CCB, pointed by ct_syshandle. */ atp = isp_find_atpd(isp, bus, ccb->csio.tag_id); } if (atp == NULL) { isp_prt(isp, ISP_LOGERR, "%s: cannot find adjunct for %x after I/O", __func__, ccb->csio.tag_id); return; } KASSERT((atp->ctcnt > 0), ("ctio count not greater than zero")); atp->bytes_in_transit -= data_requested; atp->ctcnt -= 1; ccb->ccb_h.status &= ~CAM_STATUS_MASK; if (IS_24XX(isp)) { ct7_entry_t *ct = arg; if (ct->ct_nphdl == CT7_SRR) { atp->srr_ccb = ccb; if (atp->srr_notify_rcvd) isp_handle_srr_start(isp, atp); return; } if (ct->ct_nphdl == CT_HBA_RESET) { sentstatus = (ccb->ccb_h.flags & CAM_SEND_STATUS) && (atp->sendst == 0); failure = CAM_UNREC_HBA_ERROR; } else { sentstatus = ct->ct_flags & CT7_SENDSTATUS; ok = (ct->ct_nphdl == CT7_OK); notify_cam = (ct->ct_header.rqs_seqno & ATPD_SEQ_NOTIFY_CAM) != 0; if ((ct->ct_flags & CT7_DATAMASK) != CT7_NO_DATA) resid = ct->ct_resid; } isp_prt(isp, ok? ISP_LOGTDEBUG0 : ISP_LOGWARN, "%s: CTIO7[%x] seq %u nc %d sts 0x%x flg 0x%x sns %d resid %d %s", __func__, ct->ct_rxid, ATPD_GET_SEQNO(ct), notify_cam, ct->ct_nphdl, ct->ct_flags, (ccb->ccb_h.status & CAM_SENT_SENSE) != 0, resid, sentstatus? "FIN" : "MID"); } else { ct2_entry_t *ct = arg; if (ct->ct_status == CT_SRR) { atp->srr_ccb = ccb; if (atp->srr_notify_rcvd) isp_handle_srr_start(isp, atp); isp_target_putback_atio(ccb); return; } if (ct->ct_status == CT_HBA_RESET) { sentstatus = (ccb->ccb_h.flags & CAM_SEND_STATUS) && (atp->sendst == 0); failure = CAM_UNREC_HBA_ERROR; } else { sentstatus = ct->ct_flags & CT2_SENDSTATUS; ok = (ct->ct_status & ~QLTM_SVALID) == CT_OK; notify_cam = (ct->ct_header.rqs_seqno & ATPD_SEQ_NOTIFY_CAM) != 0; if ((ct->ct_flags & CT2_DATAMASK) != CT2_NO_DATA) resid = ct->ct_resid; } isp_prt(isp, ok? ISP_LOGTDEBUG0 : ISP_LOGWARN, "%s: CTIO2[%x] seq %u nc %d sts 0x%x flg 0x%x sns %d resid %d %s", __func__, ct->ct_rxid, ATPD_GET_SEQNO(ct), notify_cam, ct->ct_status, ct->ct_flags, (ccb->ccb_h.status & CAM_SENT_SENSE) != 0, resid, sentstatus? "FIN" : "MID"); } if (ok) { if (data_requested > 0) { atp->bytes_xfered += data_requested - resid; ccb->csio.resid = ccb->csio.dxfer_len - (data_requested - resid); } if (sentstatus && (ccb->ccb_h.flags & CAM_SEND_SENSE)) ccb->ccb_h.status |= CAM_SENT_SENSE; ccb->ccb_h.status |= CAM_REQ_CMP; } else { notify_cam = 1; if (failure == CAM_UNREC_HBA_ERROR) ccb->ccb_h.status |= CAM_UNREC_HBA_ERROR; else ccb->ccb_h.status |= CAM_REQ_CMP_ERR; } atp->state = ATPD_STATE_PDON; /* * We never *not* notify CAM when there has been any error (ok == 0), * so we never need to do an ATIO putback if we're not notifying CAM. */ isp_prt(isp, ISP_LOGTDEBUG0, "%s CTIO[0x%x] done (ok=%d nc=%d nowsendstatus=%d ccb ss=%d)", (sentstatus)? " FINAL " : "MIDTERM ", atp->tag, ok, notify_cam, atp->sendst, (ccb->ccb_h.flags & CAM_SEND_STATUS) != 0); if (notify_cam == 0) { if (atp->sendst) { isp_target_start_ctio(isp, ccb, FROM_CTIO_DONE); } return; } /* * We are done with this ATIO if we successfully sent status. * In all other cases expect either another CTIO or XPT_ABORT. */ if (ok && sentstatus) isp_put_atpd(isp, bus, atp); /* * We're telling CAM we're done with this CTIO transaction. * * 24XX cards never need an ATIO put back. * * Other cards need one put back only on error. * In the latter case, a timeout will re-fire * and try again in case we didn't have * queue resources to do so at first. In any case, * once the putback is done we do the completion * call. */ if (ok || IS_24XX(isp)) { isp_complete_ctio(ccb); } else { isp_target_putback_atio(ccb); } } static int isp_handle_platform_target_notify_ack(ispsoftc_t *isp, isp_notify_t *mp, uint32_t rsp) { if (isp->isp_state != ISP_RUNSTATE) { isp_prt(isp, ISP_LOGTINFO, "Notify Code 0x%x (qevalid=%d) acked- h/w not ready (dropping)", mp->nt_ncode, mp->nt_lreserved != NULL); return (0); } /* * This case is for a Task Management Function, which shows up as an ATIO7 entry. */ if (IS_24XX(isp) && mp->nt_lreserved && ((isphdr_t *)mp->nt_lreserved)->rqs_entry_type == RQSTYPE_ATIO) { ct7_entry_t local, *cto = &local; at7_entry_t *aep = (at7_entry_t *)mp->nt_lreserved; fcportdb_t *lp; uint32_t sid; uint16_t nphdl; sid = (aep->at_hdr.s_id[0] << 16) | (aep->at_hdr.s_id[1] << 8) | aep->at_hdr.s_id[2]; if (isp_find_pdb_by_portid(isp, mp->nt_channel, sid, &lp)) { nphdl = lp->handle; } else { nphdl = NIL_HANDLE; } ISP_MEMZERO(&local, sizeof (local)); cto->ct_header.rqs_entry_type = RQSTYPE_CTIO7; cto->ct_header.rqs_entry_count = 1; cto->ct_nphdl = nphdl; cto->ct_rxid = aep->at_rxid; cto->ct_vpidx = mp->nt_channel; cto->ct_iid_lo = sid; cto->ct_iid_hi = sid >> 16; cto->ct_oxid = aep->at_hdr.ox_id; cto->ct_flags = CT7_SENDSTATUS|CT7_NOACK|CT7_NO_DATA|CT7_FLAG_MODE1; cto->ct_flags |= (aep->at_ta_len >> 12) << CT7_TASK_ATTR_SHIFT; if (rsp != 0) { cto->ct_scsi_status |= (FCP_RSPLEN_VALID << 8); cto->rsp.m1.ct_resplen = 4; ISP_MEMZERO(cto->rsp.m1.ct_resp, sizeof (cto->rsp.m1.ct_resp)); cto->rsp.m1.ct_resp[0] = rsp & 0xff; cto->rsp.m1.ct_resp[1] = (rsp >> 8) & 0xff; cto->rsp.m1.ct_resp[2] = (rsp >> 16) & 0xff; cto->rsp.m1.ct_resp[3] = (rsp >> 24) & 0xff; } return (isp_target_put_entry(isp, &local)); } /* * This case is for a responding to an ABTS frame */ if (IS_24XX(isp) && mp->nt_lreserved && ((isphdr_t *)mp->nt_lreserved)->rqs_entry_type == RQSTYPE_ABTS_RCVD) { /* * Overload nt_need_ack here to mark whether we've terminated the associated command. */ if (mp->nt_need_ack) { uint8_t storage[QENTRY_LEN]; ct7_entry_t *cto = (ct7_entry_t *) storage; abts_t *abts = (abts_t *)mp->nt_lreserved; ISP_MEMZERO(cto, sizeof (ct7_entry_t)); isp_prt(isp, ISP_LOGTDEBUG0, "%s: [%x] terminating after ABTS received", __func__, abts->abts_rxid_task); cto->ct_header.rqs_entry_type = RQSTYPE_CTIO7; cto->ct_header.rqs_entry_count = 1; cto->ct_nphdl = mp->nt_nphdl; cto->ct_rxid = abts->abts_rxid_task; cto->ct_iid_lo = mp->nt_sid; cto->ct_iid_hi = mp->nt_sid >> 16; cto->ct_oxid = abts->abts_ox_id; cto->ct_vpidx = mp->nt_channel; cto->ct_flags = CT7_NOACK|CT7_TERMINATE; if (isp_target_put_entry(isp, cto)) { return (ENOMEM); } mp->nt_need_ack = 0; } if (isp_acknak_abts(isp, mp->nt_lreserved, 0) == ENOMEM) { return (ENOMEM); } else { return (0); } } /* * Handle logout cases here */ if (mp->nt_ncode == NT_GLOBAL_LOGOUT) { isp_del_all_wwn_entries(isp, mp->nt_channel); } if (mp->nt_ncode == NT_LOGOUT) { if (!IS_2100(isp) && IS_FC(isp)) { isp_del_wwn_entries(isp, mp); } } /* * General purpose acknowledgement */ if (mp->nt_need_ack) { isp_prt(isp, ISP_LOGTINFO, "Notify Code 0x%x (qevalid=%d) being acked", mp->nt_ncode, mp->nt_lreserved != NULL); /* * Don't need to use the guaranteed send because the caller can retry */ return (isp_notify_ack(isp, mp->nt_lreserved)); } return (0); } /* * Handle task management functions. * * We show up here with a notify structure filled out. * * The nt_lreserved tag points to the original queue entry */ static void isp_handle_platform_target_tmf(ispsoftc_t *isp, isp_notify_t *notify) { tstate_t *tptr; fcportdb_t *lp; struct ccb_immediate_notify *inot; inot_private_data_t *ntp = NULL; atio_private_data_t *atp; lun_id_t lun; isp_prt(isp, ISP_LOGTDEBUG0, "%s: code 0x%x sid 0x%x tagval 0x%016llx chan %d lun %jx", __func__, notify->nt_ncode, notify->nt_sid, (unsigned long long) notify->nt_tagval, notify->nt_channel, notify->nt_lun); if (notify->nt_lun == LUN_ANY) { if (notify->nt_tagval == TAG_ANY) { lun = CAM_LUN_WILDCARD; } else { atp = isp_find_atpd(isp, notify->nt_channel, notify->nt_tagval & 0xffffffff); lun = atp ? atp->lun : CAM_LUN_WILDCARD; } } else { lun = notify->nt_lun; } tptr = get_lun_statep(isp, notify->nt_channel, lun); if (tptr == NULL) { tptr = get_lun_statep(isp, notify->nt_channel, CAM_LUN_WILDCARD); if (tptr == NULL) { isp_prt(isp, ISP_LOGWARN, "%s: no state pointer found for chan %d lun %#jx", __func__, notify->nt_channel, (uintmax_t)lun); goto bad; } } inot = (struct ccb_immediate_notify *) SLIST_FIRST(&tptr->inots); if (inot == NULL) { isp_prt(isp, ISP_LOGWARN, "%s: out of immediate notify structures for chan %d lun %#jx", __func__, notify->nt_channel, (uintmax_t)lun); goto bad; } inot->ccb_h.target_id = ISP_MAX_TARGETS(isp); inot->ccb_h.target_lun = lun; if (isp_find_pdb_by_portid(isp, notify->nt_channel, notify->nt_sid, &lp) == 0 && isp_find_pdb_by_handle(isp, notify->nt_channel, notify->nt_nphdl, &lp) == 0) { inot->initiator_id = CAM_TARGET_WILDCARD; } else { inot->initiator_id = FC_PORTDB_TGT(isp, notify->nt_channel, lp); } inot->seq_id = notify->nt_tagval; inot->tag_id = notify->nt_tagval >> 32; switch (notify->nt_ncode) { case NT_ABORT_TASK: isp_target_mark_aborted_early(isp, notify->nt_channel, tptr, inot->tag_id); inot->arg = MSG_ABORT_TASK; break; case NT_ABORT_TASK_SET: isp_target_mark_aborted_early(isp, notify->nt_channel, tptr, TAG_ANY); inot->arg = MSG_ABORT_TASK_SET; break; case NT_CLEAR_ACA: inot->arg = MSG_CLEAR_ACA; break; case NT_CLEAR_TASK_SET: inot->arg = MSG_CLEAR_TASK_SET; break; case NT_LUN_RESET: inot->arg = MSG_LOGICAL_UNIT_RESET; break; case NT_TARGET_RESET: inot->arg = MSG_TARGET_RESET; break; case NT_QUERY_TASK_SET: inot->arg = MSG_QUERY_TASK_SET; break; case NT_QUERY_ASYNC_EVENT: inot->arg = MSG_QUERY_ASYNC_EVENT; break; default: isp_prt(isp, ISP_LOGWARN, "%s: unknown TMF code 0x%x for chan %d lun %#jx", __func__, notify->nt_ncode, notify->nt_channel, (uintmax_t)lun); goto bad; } ntp = isp_get_ntpd(isp, notify->nt_channel); if (ntp == NULL) { isp_prt(isp, ISP_LOGWARN, "%s: out of inotify private structures", __func__); goto bad; } ISP_MEMCPY(&ntp->nt, notify, sizeof (isp_notify_t)); if (notify->nt_lreserved) { ISP_MEMCPY(&ntp->data, notify->nt_lreserved, QENTRY_LEN); ntp->nt.nt_lreserved = &ntp->data; } ntp->seq_id = notify->nt_tagval; ntp->tag_id = notify->nt_tagval >> 32; SLIST_REMOVE_HEAD(&tptr->inots, sim_links.sle); ISP_PATH_PRT(isp, ISP_LOGTDEBUG2, inot->ccb_h.path, "Take FREE INOT\n"); inot->ccb_h.status = CAM_MESSAGE_RECV; xpt_done((union ccb *)inot); return; bad: if (notify->nt_need_ack) { if (((isphdr_t *)notify->nt_lreserved)->rqs_entry_type == RQSTYPE_ABTS_RCVD) { if (isp_acknak_abts(isp, notify->nt_lreserved, ENOMEM)) { isp_prt(isp, ISP_LOGWARN, "you lose- unable to send an ACKNAK"); } } else { isp_async(isp, ISPASYNC_TARGET_NOTIFY_ACK, notify->nt_lreserved); } } } static void isp_target_mark_aborted_early(ispsoftc_t *isp, int chan, tstate_t *tptr, uint32_t tag_id) { atio_private_data_t *atp, *atpool; inot_private_data_t *ntp, *tmp; uint32_t this_tag_id; /* * First, clean any commands pending restart */ STAILQ_FOREACH_SAFE(ntp, &tptr->restart_queue, next, tmp) { if (IS_24XX(isp)) this_tag_id = ((at7_entry_t *)ntp->data)->at_rxid; else this_tag_id = ((at2_entry_t *)ntp->data)->at_rxid; if ((uint64_t)tag_id == TAG_ANY || tag_id == this_tag_id) { isp_endcmd(isp, ntp->data, NIL_HANDLE, chan, ECMD_TERMINATE, 0); isp_put_ntpd(isp, chan, ntp); STAILQ_REMOVE(&tptr->restart_queue, ntp, inot_private_data, next); } } /* * Now mark other ones dead as well. */ ISP_GET_PC(isp, chan, atpool, atpool); for (atp = atpool; atp < &atpool[ATPDPSIZE]; atp++) { if (atp->lun != tptr->ts_lun) continue; if ((uint64_t)tag_id == TAG_ANY || atp->tag == tag_id) atp->dead = 1; } } #endif static void isp_cam_async(void *cbarg, uint32_t code, struct cam_path *path, void *arg) { struct cam_sim *sim; int bus, tgt; ispsoftc_t *isp; sim = (struct cam_sim *)cbarg; isp = (ispsoftc_t *) cam_sim_softc(sim); bus = cam_sim_bus(sim); tgt = xpt_path_target_id(path); switch (code) { case AC_LOST_DEVICE: if (IS_SCSI(isp)) { uint16_t oflags, nflags; sdparam *sdp = SDPARAM(isp, bus); if (tgt >= 0) { nflags = sdp->isp_devparam[tgt].nvrm_flags; nflags &= DPARM_SAFE_DFLT; if (isp->isp_loaded_fw) { nflags |= DPARM_NARROW | DPARM_ASYNC; } oflags = sdp->isp_devparam[tgt].goal_flags; sdp->isp_devparam[tgt].goal_flags = nflags; sdp->isp_devparam[tgt].dev_update = 1; sdp->update = 1; (void) isp_control(isp, ISPCTL_UPDATE_PARAMS, bus); sdp->isp_devparam[tgt].goal_flags = oflags; } } break; default: isp_prt(isp, ISP_LOGWARN, "isp_cam_async: Code 0x%x", code); break; } } static void isp_poll(struct cam_sim *sim) { ispsoftc_t *isp = cam_sim_softc(sim); ISP_RUN_ISR(isp); } static void isp_watchdog(void *arg) { struct ccb_scsiio *xs = arg; ispsoftc_t *isp; uint32_t ohandle = ISP_HANDLE_FREE, handle; isp = XS_ISP(xs); handle = isp_find_handle(isp, xs); /* * Hand crank the interrupt code just to be sure the command isn't stuck somewhere. */ if (handle != ISP_HANDLE_FREE) { ISP_RUN_ISR(isp); ohandle = handle; handle = isp_find_handle(isp, xs); } if (handle != ISP_HANDLE_FREE) { /* * Try and make sure the command is really dead before * we release the handle (and DMA resources) for reuse. * * If we are successful in aborting the command then * we're done here because we'll get the command returned * back separately. */ if (isp_control(isp, ISPCTL_ABORT_CMD, xs) == 0) { return; } /* * Note that after calling the above, the command may in * fact have been completed. */ xs = isp_find_xs(isp, handle); /* * If the command no longer exists, then we won't * be able to find the xs again with this handle. */ if (xs == NULL) { return; } /* * After this point, the command is really dead. */ if (XS_XFRLEN(xs)) { ISP_DMAFREE(isp, xs, handle); } isp_destroy_handle(isp, handle); isp_prt(isp, ISP_LOGERR, "%s: timeout for handle 0x%x", __func__, handle); XS_SETERR(xs, CAM_CMD_TIMEOUT); isp_done(xs); } else { if (ohandle != ISP_HANDLE_FREE) { isp_prt(isp, ISP_LOGWARN, "%s: timeout for handle 0x%x, recovered during interrupt", __func__, ohandle); } else { isp_prt(isp, ISP_LOGWARN, "%s: timeout for handle already free", __func__); } } } static void isp_make_here(ispsoftc_t *isp, fcportdb_t *fcp, int chan, int tgt) { union ccb *ccb; struct isp_fc *fc = ISP_FC_PC(isp, chan); /* * Allocate a CCB, create a wildcard path for this target and schedule a rescan. */ ccb = xpt_alloc_ccb_nowait(); if (ccb == NULL) { isp_prt(isp, ISP_LOGWARN, "Chan %d unable to alloc CCB for rescan", chan); return; } if (xpt_create_path(&ccb->ccb_h.path, NULL, cam_sim_path(fc->sim), tgt, CAM_LUN_WILDCARD) != CAM_REQ_CMP) { isp_prt(isp, ISP_LOGWARN, "unable to create path for rescan"); xpt_free_ccb(ccb); return; } xpt_rescan(ccb); } static void isp_make_gone(ispsoftc_t *isp, fcportdb_t *fcp, int chan, int tgt) { struct cam_path *tp; struct isp_fc *fc = ISP_FC_PC(isp, chan); if (xpt_create_path(&tp, NULL, cam_sim_path(fc->sim), tgt, CAM_LUN_WILDCARD) == CAM_REQ_CMP) { xpt_async(AC_LOST_DEVICE, tp, NULL); xpt_free_path(tp); } } /* * Gone Device Timer Function- when we have decided that a device has gone * away, we wait a specific period of time prior to telling the OS it has * gone away. * * This timer function fires once a second and then scans the port database * for devices that are marked dead but still have a virtual target assigned. * We decrement a counter for that port database entry, and when it hits zero, * we tell the OS the device has gone away. */ static void isp_gdt(void *arg) { struct isp_fc *fc = arg; taskqueue_enqueue(taskqueue_thread, &fc->gtask); } static void isp_gdt_task(void *arg, int pending) { struct isp_fc *fc = arg; ispsoftc_t *isp = fc->isp; int chan = fc - isp->isp_osinfo.pc.fc; fcportdb_t *lp; struct ac_contract ac; struct ac_device_changed *adc; int dbidx, more_to_do = 0; ISP_LOCK(isp); isp_prt(isp, ISP_LOGDEBUG0, "Chan %d GDT timer expired", chan); for (dbidx = 0; dbidx < MAX_FC_TARG; dbidx++) { lp = &FCPARAM(isp, chan)->portdb[dbidx]; if (lp->state != FC_PORTDB_STATE_ZOMBIE) { continue; } if (lp->gone_timer != 0) { lp->gone_timer -= 1; more_to_do++; continue; } isp_prt(isp, ISP_LOGCONFIG, prom3, chan, dbidx, lp->portid, "Gone Device Timeout"); if (lp->is_target) { lp->is_target = 0; isp_make_gone(isp, lp, chan, dbidx); } if (lp->is_initiator) { lp->is_initiator = 0; ac.contract_number = AC_CONTRACT_DEV_CHG; adc = (struct ac_device_changed *) ac.contract_data; adc->wwpn = lp->port_wwn; adc->port = lp->portid; adc->target = dbidx; adc->arrived = 0; xpt_async(AC_CONTRACT, fc->path, &ac); } lp->state = FC_PORTDB_STATE_NIL; } if (fc->ready) { if (more_to_do) { callout_reset(&fc->gdt, hz, isp_gdt, fc); } else { callout_deactivate(&fc->gdt); isp_prt(isp, ISP_LOG_SANCFG, "Chan %d Stopping Gone Device Timer @ %lu", chan, (unsigned long) time_uptime); } } ISP_UNLOCK(isp); } /* * When loop goes down we remember the time and freeze CAM command queue. * During some time period we are trying to reprobe the loop. But if we * fail, we tell the OS that devices have gone away and drop the freeze. * * We don't clear the devices out of our port database because, when loop * come back up, we have to do some actual cleanup with the chip at that * point (implicit PLOGO, e.g., to get the chip's port database state right). */ static void isp_loop_changed(ispsoftc_t *isp, int chan) { fcparam *fcp = FCPARAM(isp, chan); struct isp_fc *fc = ISP_FC_PC(isp, chan); if (fc->loop_down_time) return; isp_prt(isp, ISP_LOG_SANCFG|ISP_LOGDEBUG0, "Chan %d Loop changed", chan); if (fcp->role & ISP_ROLE_INITIATOR) isp_freeze_loopdown(isp, chan); fc->loop_down_time = time_uptime; wakeup(fc); } static void isp_loop_up(ispsoftc_t *isp, int chan) { struct isp_fc *fc = ISP_FC_PC(isp, chan); isp_prt(isp, ISP_LOG_SANCFG|ISP_LOGDEBUG0, "Chan %d Loop is up", chan); fc->loop_seen_once = 1; fc->loop_down_time = 0; isp_unfreeze_loopdown(isp, chan); } static void isp_loop_dead(ispsoftc_t *isp, int chan) { fcparam *fcp = FCPARAM(isp, chan); struct isp_fc *fc = ISP_FC_PC(isp, chan); fcportdb_t *lp; struct ac_contract ac; struct ac_device_changed *adc; int dbidx, i; isp_prt(isp, ISP_LOG_SANCFG|ISP_LOGDEBUG0, "Chan %d Loop is dead", chan); /* * Notify to the OS all targets who we now consider have departed. */ for (dbidx = 0; dbidx < MAX_FC_TARG; dbidx++) { lp = &fcp->portdb[dbidx]; if (lp->state == FC_PORTDB_STATE_NIL) continue; for (i = 0; i < isp->isp_maxcmds; i++) { struct ccb_scsiio *xs; if (ISP_H2HT(isp->isp_xflist[i].handle) != ISP_HANDLE_INITIATOR) { continue; } if ((xs = isp->isp_xflist[i].cmd) == NULL) { continue; } if (dbidx != XS_TGT(xs)) { continue; } isp_prt(isp, ISP_LOGWARN, "command handle 0x%x for %d.%d.%jx orphaned by loop down timeout", isp->isp_xflist[i].handle, chan, XS_TGT(xs), (uintmax_t)XS_LUN(xs)); /* * Just like in isp_watchdog, abort the outstanding * command or immediately free its resources if it is * not active */ if (isp_control(isp, ISPCTL_ABORT_CMD, xs) == 0) { continue; } if (XS_XFRLEN(xs)) { ISP_DMAFREE(isp, xs, isp->isp_xflist[i].handle); } isp_destroy_handle(isp, isp->isp_xflist[i].handle); isp_prt(isp, ISP_LOGWARN, "command handle 0x%x for %d.%d.%jx could not be aborted and was destroyed", isp->isp_xflist[i].handle, chan, XS_TGT(xs), (uintmax_t)XS_LUN(xs)); XS_SETERR(xs, HBA_BUSRESET); isp_done(xs); } isp_prt(isp, ISP_LOGCONFIG, prom3, chan, dbidx, lp->portid, "Loop Down Timeout"); if (lp->is_target) { lp->is_target = 0; isp_make_gone(isp, lp, chan, dbidx); } if (lp->is_initiator) { lp->is_initiator = 0; ac.contract_number = AC_CONTRACT_DEV_CHG; adc = (struct ac_device_changed *) ac.contract_data; adc->wwpn = lp->port_wwn; adc->port = lp->portid; adc->target = dbidx; adc->arrived = 0; xpt_async(AC_CONTRACT, fc->path, &ac); } } isp_unfreeze_loopdown(isp, chan); fc->loop_down_time = 0; } static void isp_kthread(void *arg) { struct isp_fc *fc = arg; ispsoftc_t *isp = fc->isp; int chan = fc - isp->isp_osinfo.pc.fc; int slp = 0, d; int lb, lim; ISP_LOCK(isp); while (isp->isp_osinfo.is_exiting == 0) { isp_prt(isp, ISP_LOG_SANCFG|ISP_LOGDEBUG0, "Chan %d Checking FC state", chan); lb = isp_fc_runstate(isp, chan, 250000); isp_prt(isp, ISP_LOG_SANCFG|ISP_LOGDEBUG0, "Chan %d FC got to %s state", chan, isp_fc_loop_statename(lb)); /* * Our action is different based upon whether we're supporting * Initiator mode or not. If we are, we might freeze the simq * when loop is down and set all sorts of different delays to * check again. * * If not, we simply just wait for loop to come up. */ if (lb == LOOP_READY || lb < 0) { slp = 0; } else { /* * If we've never seen loop up and we've waited longer * than quickboot time, or we've seen loop up but we've * waited longer than loop_down_limit, give up and go * to sleep until loop comes up. */ if (fc->loop_seen_once == 0) lim = isp_quickboot_time; else lim = fc->loop_down_limit; d = time_uptime - fc->loop_down_time; if (d >= lim) slp = 0; else if (d < 10) slp = 1; else if (d < 30) slp = 5; else if (d < 60) slp = 10; else if (d < 120) slp = 20; else slp = 30; } if (slp == 0) { if (lb == LOOP_READY) isp_loop_up(isp, chan); else isp_loop_dead(isp, chan); } isp_prt(isp, ISP_LOG_SANCFG|ISP_LOGDEBUG0, "Chan %d sleep for %d seconds", chan, slp); msleep(fc, &isp->isp_lock, PRIBIO, "ispf", slp * hz); } fc->num_threads -= 1; ISP_UNLOCK(isp); kthread_exit(); } #ifdef ISP_TARGET_MODE static void isp_abort_atio(ispsoftc_t *isp, union ccb *ccb) { atio_private_data_t *atp; union ccb *accb = ccb->cab.abort_ccb; struct ccb_hdr *sccb; tstate_t *tptr; tptr = get_lun_statep(isp, XS_CHANNEL(accb), XS_LUN(accb)); if (tptr != NULL) { /* Search for the ATIO among queueued. */ SLIST_FOREACH(sccb, &tptr->atios, sim_links.sle) { if (sccb != &accb->ccb_h) continue; SLIST_REMOVE(&tptr->atios, sccb, ccb_hdr, sim_links.sle); ISP_PATH_PRT(isp, ISP_LOGTDEBUG2, sccb->path, "Abort FREE ATIO\n"); accb->ccb_h.status = CAM_REQ_ABORTED; xpt_done(accb); ccb->ccb_h.status = CAM_REQ_CMP; return; } } /* Search for the ATIO among running. */ atp = isp_find_atpd(isp, XS_CHANNEL(accb), accb->atio.tag_id); if (atp != NULL) { /* Send TERMINATE to firmware. */ if (!atp->dead && IS_24XX(isp)) { uint8_t storage[QENTRY_LEN]; ct7_entry_t *cto = (ct7_entry_t *) storage; ISP_MEMZERO(cto, sizeof (ct7_entry_t)); cto->ct_header.rqs_entry_type = RQSTYPE_CTIO7; cto->ct_header.rqs_entry_count = 1; cto->ct_nphdl = atp->nphdl; cto->ct_rxid = atp->tag; cto->ct_iid_lo = atp->sid; cto->ct_iid_hi = atp->sid >> 16; cto->ct_oxid = atp->oxid; cto->ct_vpidx = XS_CHANNEL(accb); cto->ct_flags = CT7_NOACK|CT7_TERMINATE; isp_target_put_entry(isp, cto); } isp_put_atpd(isp, XS_CHANNEL(accb), atp); ccb->ccb_h.status = CAM_REQ_CMP; } else { ccb->ccb_h.status = CAM_UA_ABORT; } } static void isp_abort_inot(ispsoftc_t *isp, union ccb *ccb) { inot_private_data_t *ntp; union ccb *accb = ccb->cab.abort_ccb; struct ccb_hdr *sccb; tstate_t *tptr; tptr = get_lun_statep(isp, XS_CHANNEL(accb), XS_LUN(accb)); if (tptr != NULL) { /* Search for the INOT among queueued. */ SLIST_FOREACH(sccb, &tptr->inots, sim_links.sle) { if (sccb != &accb->ccb_h) continue; SLIST_REMOVE(&tptr->inots, sccb, ccb_hdr, sim_links.sle); ISP_PATH_PRT(isp, ISP_LOGTDEBUG2, sccb->path, "Abort FREE INOT\n"); accb->ccb_h.status = CAM_REQ_ABORTED; xpt_done(accb); ccb->ccb_h.status = CAM_REQ_CMP; return; } } /* Search for the INOT among running. */ ntp = isp_find_ntpd(isp, XS_CHANNEL(accb), accb->cin1.tag_id, accb->cin1.seq_id); if (ntp != NULL) { if (ntp->nt.nt_need_ack) { isp_async(isp, ISPASYNC_TARGET_NOTIFY_ACK, ntp->nt.nt_lreserved); } isp_put_ntpd(isp, XS_CHANNEL(accb), ntp); ccb->ccb_h.status = CAM_REQ_CMP; } else { ccb->ccb_h.status = CAM_UA_ABORT; return; } } #endif static void isp_action(struct cam_sim *sim, union ccb *ccb) { int bus, tgt, error; ispsoftc_t *isp; struct ccb_trans_settings *cts; sbintime_t ts; CAM_DEBUG(ccb->ccb_h.path, CAM_DEBUG_TRACE, ("isp_action\n")); isp = (ispsoftc_t *)cam_sim_softc(sim); ISP_ASSERT_LOCKED(isp); bus = cam_sim_bus(sim); isp_prt(isp, ISP_LOGDEBUG2, "isp_action code %x", ccb->ccb_h.func_code); ISP_PCMD(ccb) = NULL; switch (ccb->ccb_h.func_code) { case XPT_SCSI_IO: /* Execute the requested I/O operation */ /* * Do a couple of preliminary checks... */ if ((ccb->ccb_h.flags & CAM_CDB_POINTER) != 0) { if ((ccb->ccb_h.flags & CAM_CDB_PHYS) != 0) { ccb->ccb_h.status = CAM_REQ_INVALID; isp_done((struct ccb_scsiio *) ccb); break; } } ccb->csio.req_map = NULL; #ifdef DIAGNOSTIC if (ccb->ccb_h.target_id >= ISP_MAX_TARGETS(isp)) { xpt_print(ccb->ccb_h.path, "invalid target\n"); ccb->ccb_h.status = CAM_PATH_INVALID; } else if (ISP_MAX_LUNS(isp) > 0 && ccb->ccb_h.target_lun >= ISP_MAX_LUNS(isp)) { xpt_print(ccb->ccb_h.path, "invalid lun\n"); ccb->ccb_h.status = CAM_PATH_INVALID; } if (ccb->ccb_h.status == CAM_PATH_INVALID) { xpt_done(ccb); break; } #endif ccb->csio.scsi_status = SCSI_STATUS_OK; if (isp_get_pcmd(isp, ccb)) { isp_prt(isp, ISP_LOGWARN, "out of PCMDs"); cam_freeze_devq(ccb->ccb_h.path); cam_release_devq(ccb->ccb_h.path, RELSIM_RELEASE_AFTER_TIMEOUT, 0, 250, 0); ccb->ccb_h.status = CAM_REQUEUE_REQ; xpt_done(ccb); break; } error = isp_start((XS_T *) ccb); switch (error) { case CMD_QUEUED: ccb->ccb_h.status |= CAM_SIM_QUEUED; if (ccb->ccb_h.timeout == CAM_TIME_INFINITY) break; /* Give firmware extra 10s to handle timeout. */ ts = SBT_1MS * ccb->ccb_h.timeout + 10 * SBT_1S; callout_reset_sbt(&PISP_PCMD(ccb)->wdog, ts, 0, isp_watchdog, ccb, 0); break; case CMD_RQLATER: isp_prt(isp, ISP_LOGDEBUG0, "%d.%jx retry later", XS_TGT(ccb), (uintmax_t)XS_LUN(ccb)); cam_freeze_devq(ccb->ccb_h.path); cam_release_devq(ccb->ccb_h.path, RELSIM_RELEASE_AFTER_TIMEOUT, 0, 1000, 0); ccb->ccb_h.status = CAM_REQUEUE_REQ; isp_free_pcmd(isp, ccb); xpt_done(ccb); break; case CMD_EAGAIN: isp_free_pcmd(isp, ccb); cam_freeze_devq(ccb->ccb_h.path); cam_release_devq(ccb->ccb_h.path, RELSIM_RELEASE_AFTER_TIMEOUT, 0, 100, 0); ccb->ccb_h.status = CAM_REQUEUE_REQ; xpt_done(ccb); break; case CMD_COMPLETE: isp_done((struct ccb_scsiio *) ccb); break; default: isp_prt(isp, ISP_LOGERR, "What's this? 0x%x at %d in file %s", error, __LINE__, __FILE__); ccb->ccb_h.status = CAM_REQUEUE_REQ; isp_free_pcmd(isp, ccb); xpt_done(ccb); } break; #ifdef ISP_TARGET_MODE case XPT_EN_LUN: /* Enable/Disable LUN as a target */ if (ccb->cel.enable) { isp_enable_lun(isp, ccb); } else { isp_disable_lun(isp, ccb); } break; case XPT_IMMEDIATE_NOTIFY: /* Add Immediate Notify Resource */ case XPT_ACCEPT_TARGET_IO: /* Add Accept Target IO Resource */ { tstate_t *tptr = get_lun_statep(isp, XS_CHANNEL(ccb), ccb->ccb_h.target_lun); if (tptr == NULL) { const char *str; if (ccb->ccb_h.func_code == XPT_IMMEDIATE_NOTIFY) str = "XPT_IMMEDIATE_NOTIFY"; else str = "XPT_ACCEPT_TARGET_IO"; ISP_PATH_PRT(isp, ISP_LOGWARN, ccb->ccb_h.path, "%s: no state pointer found for %s\n", __func__, str); ccb->ccb_h.status = CAM_DEV_NOT_THERE; xpt_done(ccb); break; } ccb->ccb_h.spriv_field0 = 0; ccb->ccb_h.spriv_ptr1 = isp; if (ccb->ccb_h.func_code == XPT_ACCEPT_TARGET_IO) { ccb->atio.tag_id = 0; SLIST_INSERT_HEAD(&tptr->atios, &ccb->ccb_h, sim_links.sle); ISP_PATH_PRT(isp, ISP_LOGTDEBUG2, ccb->ccb_h.path, "Put FREE ATIO\n"); } else if (ccb->ccb_h.func_code == XPT_IMMEDIATE_NOTIFY) { ccb->cin1.seq_id = ccb->cin1.tag_id = 0; SLIST_INSERT_HEAD(&tptr->inots, &ccb->ccb_h, sim_links.sle); ISP_PATH_PRT(isp, ISP_LOGTDEBUG2, ccb->ccb_h.path, "Put FREE INOT\n"); } ccb->ccb_h.status = CAM_REQ_INPROG; break; } case XPT_NOTIFY_ACKNOWLEDGE: /* notify ack */ { inot_private_data_t *ntp; /* * XXX: Because we cannot guarantee that the path information in the notify acknowledge ccb * XXX: matches that for the immediate notify, we have to *search* for the notify structure */ /* * All the relevant path information is in the associated immediate notify */ ISP_PATH_PRT(isp, ISP_LOGTDEBUG0, ccb->ccb_h.path, "%s: [0x%x] NOTIFY ACKNOWLEDGE for 0x%x seen\n", __func__, ccb->cna2.tag_id, ccb->cna2.seq_id); ntp = isp_find_ntpd(isp, XS_CHANNEL(ccb), ccb->cna2.tag_id, ccb->cna2.seq_id); if (ntp == NULL) { ISP_PATH_PRT(isp, ISP_LOGWARN, ccb->ccb_h.path, "%s: [0x%x] XPT_NOTIFY_ACKNOWLEDGE of 0x%x cannot find ntp private data\n", __func__, ccb->cna2.tag_id, ccb->cna2.seq_id); ccb->ccb_h.status = CAM_DEV_NOT_THERE; xpt_done(ccb); break; } if (isp_handle_platform_target_notify_ack(isp, &ntp->nt, (ccb->ccb_h.flags & CAM_SEND_STATUS) ? ccb->cna2.arg : 0)) { cam_freeze_devq(ccb->ccb_h.path); cam_release_devq(ccb->ccb_h.path, RELSIM_RELEASE_AFTER_TIMEOUT, 0, 1000, 0); ccb->ccb_h.status &= ~CAM_STATUS_MASK; ccb->ccb_h.status |= CAM_REQUEUE_REQ; break; } isp_put_ntpd(isp, XS_CHANNEL(ccb), ntp); ccb->ccb_h.status = CAM_REQ_CMP; ISP_PATH_PRT(isp, ISP_LOGTDEBUG0, ccb->ccb_h.path, "%s: [0x%x] calling xpt_done for tag 0x%x\n", __func__, ccb->cna2.tag_id, ccb->cna2.seq_id); xpt_done(ccb); break; } case XPT_CONT_TARGET_IO: isp_target_start_ctio(isp, ccb, FROM_CAM); break; #endif case XPT_RESET_DEV: /* BDR the specified SCSI device */ tgt = ccb->ccb_h.target_id; tgt |= (bus << 16); error = isp_control(isp, ISPCTL_RESET_DEV, bus, tgt); if (error) { ccb->ccb_h.status = CAM_REQ_CMP_ERR; } else { /* * If we have a FC device, reset the Command * Reference Number, because the target will expect * that we re-start the CRN at 1 after a reset. */ if (IS_FC(isp)) isp_fcp_reset_crn(isp, bus, tgt, /*tgt_set*/ 1); ccb->ccb_h.status = CAM_REQ_CMP; } xpt_done(ccb); break; case XPT_ABORT: /* Abort the specified CCB */ { union ccb *accb = ccb->cab.abort_ccb; switch (accb->ccb_h.func_code) { #ifdef ISP_TARGET_MODE case XPT_ACCEPT_TARGET_IO: isp_abort_atio(isp, ccb); break; case XPT_IMMEDIATE_NOTIFY: isp_abort_inot(isp, ccb); break; #endif case XPT_SCSI_IO: error = isp_control(isp, ISPCTL_ABORT_CMD, accb); if (error) { ccb->ccb_h.status = CAM_UA_ABORT; } else { ccb->ccb_h.status = CAM_REQ_CMP; } break; default: ccb->ccb_h.status = CAM_REQ_INVALID; break; } /* * This is not a queued CCB, so the caller expects it to be * complete when control is returned. */ break; } #define IS_CURRENT_SETTINGS(c) (c->type == CTS_TYPE_CURRENT_SETTINGS) case XPT_SET_TRAN_SETTINGS: /* Nexus Settings */ cts = &ccb->cts; if (!IS_CURRENT_SETTINGS(cts)) { ccb->ccb_h.status = CAM_REQ_INVALID; xpt_done(ccb); break; } tgt = cts->ccb_h.target_id; if (IS_SCSI(isp)) { struct ccb_trans_settings_scsi *scsi = &cts->proto_specific.scsi; struct ccb_trans_settings_spi *spi = &cts->xport_specific.spi; sdparam *sdp = SDPARAM(isp, bus); uint16_t *dptr; if (spi->valid == 0 && scsi->valid == 0) { ccb->ccb_h.status = CAM_REQ_CMP; xpt_done(ccb); break; } /* * We always update (internally) from goal_flags * so any request to change settings just gets * vectored to that location. */ dptr = &sdp->isp_devparam[tgt].goal_flags; if ((spi->valid & CTS_SPI_VALID_DISC) != 0) { if ((spi->flags & CTS_SPI_FLAGS_DISC_ENB) != 0) *dptr |= DPARM_DISC; else *dptr &= ~DPARM_DISC; } if ((scsi->valid & CTS_SCSI_VALID_TQ) != 0) { if ((scsi->flags & CTS_SCSI_FLAGS_TAG_ENB) != 0) *dptr |= DPARM_TQING; else *dptr &= ~DPARM_TQING; } if ((spi->valid & CTS_SPI_VALID_BUS_WIDTH) != 0) { if (spi->bus_width == MSG_EXT_WDTR_BUS_16_BIT) *dptr |= DPARM_WIDE; else *dptr &= ~DPARM_WIDE; } /* * XXX: FIX ME */ if ((spi->valid & CTS_SPI_VALID_SYNC_OFFSET) && (spi->valid & CTS_SPI_VALID_SYNC_RATE) && (spi->sync_period && spi->sync_offset)) { *dptr |= DPARM_SYNC; /* * XXX: CHECK FOR LEGALITY */ sdp->isp_devparam[tgt].goal_period = spi->sync_period; sdp->isp_devparam[tgt].goal_offset = spi->sync_offset; } else { *dptr &= ~DPARM_SYNC; } isp_prt(isp, ISP_LOGDEBUG0, "SET (%d.%d.%jx) to flags %x off %x per %x", bus, tgt, (uintmax_t)cts->ccb_h.target_lun, sdp->isp_devparam[tgt].goal_flags, sdp->isp_devparam[tgt].goal_offset, sdp->isp_devparam[tgt].goal_period); sdp->isp_devparam[tgt].dev_update = 1; sdp->update = 1; } ccb->ccb_h.status = CAM_REQ_CMP; xpt_done(ccb); break; case XPT_GET_TRAN_SETTINGS: cts = &ccb->cts; tgt = cts->ccb_h.target_id; if (IS_FC(isp)) { fcparam *fcp = FCPARAM(isp, bus); struct ccb_trans_settings_scsi *scsi = &cts->proto_specific.scsi; struct ccb_trans_settings_fc *fc = &cts->xport_specific.fc; cts->protocol = PROTO_SCSI; cts->protocol_version = SCSI_REV_2; cts->transport = XPORT_FC; cts->transport_version = 0; scsi->valid = CTS_SCSI_VALID_TQ; scsi->flags = CTS_SCSI_FLAGS_TAG_ENB; fc->valid = CTS_FC_VALID_SPEED; fc->bitrate = 100000; fc->bitrate *= fcp->isp_gbspeed; if (tgt < MAX_FC_TARG) { fcportdb_t *lp = &fcp->portdb[tgt]; fc->wwnn = lp->node_wwn; fc->wwpn = lp->port_wwn; fc->port = lp->portid; fc->valid |= CTS_FC_VALID_WWNN | CTS_FC_VALID_WWPN | CTS_FC_VALID_PORT; } } else { struct ccb_trans_settings_scsi *scsi = &cts->proto_specific.scsi; struct ccb_trans_settings_spi *spi = &cts->xport_specific.spi; sdparam *sdp = SDPARAM(isp, bus); uint16_t dval, pval, oval; if (IS_CURRENT_SETTINGS(cts)) { sdp->isp_devparam[tgt].dev_refresh = 1; sdp->update = 1; (void) isp_control(isp, ISPCTL_UPDATE_PARAMS, bus); dval = sdp->isp_devparam[tgt].actv_flags; oval = sdp->isp_devparam[tgt].actv_offset; pval = sdp->isp_devparam[tgt].actv_period; } else { dval = sdp->isp_devparam[tgt].nvrm_flags; oval = sdp->isp_devparam[tgt].nvrm_offset; pval = sdp->isp_devparam[tgt].nvrm_period; } cts->protocol = PROTO_SCSI; cts->protocol_version = SCSI_REV_2; cts->transport = XPORT_SPI; cts->transport_version = 2; spi->valid = 0; scsi->valid = 0; spi->flags = 0; scsi->flags = 0; if (dval & DPARM_DISC) { spi->flags |= CTS_SPI_FLAGS_DISC_ENB; } if ((dval & DPARM_SYNC) && oval && pval) { spi->sync_offset = oval; spi->sync_period = pval; } else { spi->sync_offset = 0; spi->sync_period = 0; } spi->valid |= CTS_SPI_VALID_SYNC_OFFSET; spi->valid |= CTS_SPI_VALID_SYNC_RATE; spi->valid |= CTS_SPI_VALID_BUS_WIDTH; if (dval & DPARM_WIDE) { spi->bus_width = MSG_EXT_WDTR_BUS_16_BIT; } else { spi->bus_width = MSG_EXT_WDTR_BUS_8_BIT; } if (cts->ccb_h.target_lun != CAM_LUN_WILDCARD) { scsi->valid = CTS_SCSI_VALID_TQ; if (dval & DPARM_TQING) { scsi->flags |= CTS_SCSI_FLAGS_TAG_ENB; } spi->valid |= CTS_SPI_VALID_DISC; } isp_prt(isp, ISP_LOGDEBUG0, "GET %s (%d.%d.%jx) to flags %x off %x per %x", IS_CURRENT_SETTINGS(cts)? "ACTIVE" : "NVRAM", bus, tgt, (uintmax_t)cts->ccb_h.target_lun, dval, oval, pval); } ccb->ccb_h.status = CAM_REQ_CMP; xpt_done(ccb); break; case XPT_CALC_GEOMETRY: cam_calc_geometry(&ccb->ccg, 1); xpt_done(ccb); break; case XPT_RESET_BUS: /* Reset the specified bus */ error = isp_control(isp, ISPCTL_RESET_BUS, bus); if (error) { ccb->ccb_h.status = CAM_REQ_CMP_ERR; xpt_done(ccb); break; } if (bootverbose) { xpt_print(ccb->ccb_h.path, "reset bus on channel %d\n", bus); } if (IS_FC(isp)) { xpt_async(AC_BUS_RESET, ISP_FC_PC(isp, bus)->path, 0); } else { xpt_async(AC_BUS_RESET, ISP_SPI_PC(isp, bus)->path, 0); } ccb->ccb_h.status = CAM_REQ_CMP; xpt_done(ccb); break; case XPT_TERM_IO: /* Terminate the I/O process */ ccb->ccb_h.status = CAM_REQ_INVALID; xpt_done(ccb); break; case XPT_SET_SIM_KNOB: /* Set SIM knobs */ { struct ccb_sim_knob *kp = &ccb->knob; fcparam *fcp; if (!IS_FC(isp)) { ccb->ccb_h.status = CAM_REQ_INVALID; xpt_done(ccb); break; } fcp = FCPARAM(isp, bus); if (kp->xport_specific.fc.valid & KNOB_VALID_ADDRESS) { fcp->isp_wwnn = ISP_FC_PC(isp, bus)->def_wwnn = kp->xport_specific.fc.wwnn; fcp->isp_wwpn = ISP_FC_PC(isp, bus)->def_wwpn = kp->xport_specific.fc.wwpn; isp_prt(isp, ISP_LOGALL, "Setting Channel %d wwns to 0x%jx 0x%jx", bus, fcp->isp_wwnn, fcp->isp_wwpn); } ccb->ccb_h.status = CAM_REQ_CMP; if (kp->xport_specific.fc.valid & KNOB_VALID_ROLE) { int rchange = 0; int newrole = 0; switch (kp->xport_specific.fc.role) { case KNOB_ROLE_NONE: if (fcp->role != ISP_ROLE_NONE) { rchange = 1; newrole = ISP_ROLE_NONE; } break; case KNOB_ROLE_TARGET: if (fcp->role != ISP_ROLE_TARGET) { rchange = 1; newrole = ISP_ROLE_TARGET; } break; case KNOB_ROLE_INITIATOR: if (fcp->role != ISP_ROLE_INITIATOR) { rchange = 1; newrole = ISP_ROLE_INITIATOR; } break; case KNOB_ROLE_BOTH: if (fcp->role != ISP_ROLE_BOTH) { rchange = 1; newrole = ISP_ROLE_BOTH; } break; } if (rchange) { ISP_PATH_PRT(isp, ISP_LOGCONFIG, ccb->ccb_h.path, "changing role on from %d to %d\n", fcp->role, newrole); if (isp_control(isp, ISPCTL_CHANGE_ROLE, bus, newrole) != 0) { ccb->ccb_h.status = CAM_REQ_CMP_ERR; xpt_done(ccb); break; } } } xpt_done(ccb); break; } case XPT_GET_SIM_KNOB_OLD: /* Get SIM knobs -- compat value */ case XPT_GET_SIM_KNOB: /* Get SIM knobs */ { struct ccb_sim_knob *kp = &ccb->knob; if (IS_FC(isp)) { fcparam *fcp; fcp = FCPARAM(isp, bus); kp->xport_specific.fc.wwnn = fcp->isp_wwnn; kp->xport_specific.fc.wwpn = fcp->isp_wwpn; switch (fcp->role) { case ISP_ROLE_NONE: kp->xport_specific.fc.role = KNOB_ROLE_NONE; break; case ISP_ROLE_TARGET: kp->xport_specific.fc.role = KNOB_ROLE_TARGET; break; case ISP_ROLE_INITIATOR: kp->xport_specific.fc.role = KNOB_ROLE_INITIATOR; break; case ISP_ROLE_BOTH: kp->xport_specific.fc.role = KNOB_ROLE_BOTH; break; } kp->xport_specific.fc.valid = KNOB_VALID_ADDRESS | KNOB_VALID_ROLE; ccb->ccb_h.status = CAM_REQ_CMP; } else { ccb->ccb_h.status = CAM_REQ_INVALID; } xpt_done(ccb); break; } case XPT_PATH_INQ: /* Path routing inquiry */ { struct ccb_pathinq *cpi = &ccb->cpi; cpi->version_num = 1; #ifdef ISP_TARGET_MODE if (IS_FC(isp) && ISP_CAP_TMODE(isp) && ISP_CAP_SCCFW(isp)) cpi->target_sprt = PIT_PROCESSOR | PIT_DISCONNECT | PIT_TERM_IO; else #endif cpi->target_sprt = 0; cpi->hba_eng_cnt = 0; cpi->max_target = ISP_MAX_TARGETS(isp) - 1; cpi->max_lun = ISP_MAX_LUNS(isp) == 0 ? 255 : ISP_MAX_LUNS(isp) - 1; cpi->bus_id = cam_sim_bus(sim); if (sizeof (bus_size_t) > 4) cpi->maxio = (ISP_NSEG64_MAX - 1) * PAGE_SIZE; else cpi->maxio = (ISP_NSEG_MAX - 1) * PAGE_SIZE; if (IS_FC(isp)) { fcparam *fcp = FCPARAM(isp, bus); cpi->hba_misc = PIM_NOBUSRESET | PIM_UNMAPPED; cpi->hba_misc |= PIM_EXTLUNS | PIM_NOSCAN; /* * Because our loop ID can shift from time to time, * make our initiator ID out of range of our bus. */ cpi->initiator_id = cpi->max_target + 1; /* * Set base transfer capabilities for Fibre Channel, for this HBA. */ if (IS_25XX(isp)) { cpi->base_transfer_speed = 8000000; } else if (IS_24XX(isp)) { cpi->base_transfer_speed = 4000000; } else if (IS_23XX(isp)) { cpi->base_transfer_speed = 2000000; } else { cpi->base_transfer_speed = 1000000; } cpi->hba_inquiry = PI_TAG_ABLE; cpi->transport = XPORT_FC; cpi->transport_version = 0; cpi->xport_specific.fc.wwnn = fcp->isp_wwnn; cpi->xport_specific.fc.wwpn = fcp->isp_wwpn; cpi->xport_specific.fc.port = fcp->isp_portid; cpi->xport_specific.fc.bitrate = fcp->isp_gbspeed * 1000; } else { sdparam *sdp = SDPARAM(isp, bus); cpi->hba_inquiry = PI_SDTR_ABLE|PI_TAG_ABLE|PI_WIDE_16; cpi->hba_misc = PIM_UNMAPPED; cpi->initiator_id = sdp->isp_initiator_id; cpi->base_transfer_speed = 3300; cpi->transport = XPORT_SPI; cpi->transport_version = 2; } cpi->protocol = PROTO_SCSI; cpi->protocol_version = SCSI_REV_2; strlcpy(cpi->sim_vid, "FreeBSD", SIM_IDLEN); strlcpy(cpi->hba_vid, "Qlogic", HBA_IDLEN); strlcpy(cpi->dev_name, cam_sim_name(sim), DEV_IDLEN); cpi->unit_number = cam_sim_unit(sim); cpi->ccb_h.status = CAM_REQ_CMP; xpt_done(ccb); break; } default: ccb->ccb_h.status = CAM_REQ_INVALID; xpt_done(ccb); break; } } void isp_done(XS_T *sccb) { ispsoftc_t *isp = XS_ISP(sccb); uint32_t status; if (XS_NOERR(sccb)) XS_SETERR(sccb, CAM_REQ_CMP); if ((sccb->ccb_h.status & CAM_STATUS_MASK) == CAM_REQ_CMP && (sccb->scsi_status != SCSI_STATUS_OK)) { sccb->ccb_h.status &= ~CAM_STATUS_MASK; if ((sccb->scsi_status == SCSI_STATUS_CHECK_COND) && (sccb->ccb_h.status & CAM_AUTOSNS_VALID) == 0) { sccb->ccb_h.status |= CAM_AUTOSENSE_FAIL; } else { sccb->ccb_h.status |= CAM_SCSI_STATUS_ERROR; } } sccb->ccb_h.status &= ~CAM_SIM_QUEUED; status = sccb->ccb_h.status & CAM_STATUS_MASK; if (status != CAM_REQ_CMP && (sccb->ccb_h.status & CAM_DEV_QFRZN) == 0) { sccb->ccb_h.status |= CAM_DEV_QFRZN; xpt_freeze_devq(sccb->ccb_h.path, 1); } if (ISP_PCMD(sccb)) { if (callout_active(&PISP_PCMD(sccb)->wdog)) callout_stop(&PISP_PCMD(sccb)->wdog); isp_free_pcmd(isp, (union ccb *) sccb); } xpt_done((union ccb *) sccb); } void isp_async(ispsoftc_t *isp, ispasync_t cmd, ...) { int bus; static const char prom[] = "Chan %d [%d] WWPN 0x%16jx PortID 0x%06x handle 0x%x %s %s"; char buf[64]; char *msg = NULL; target_id_t tgt = 0; fcportdb_t *lp; struct isp_fc *fc; struct cam_path *tmppath; struct ac_contract ac; struct ac_device_changed *adc; va_list ap; switch (cmd) { case ISPASYNC_NEW_TGT_PARAMS: { struct ccb_trans_settings_scsi *scsi; struct ccb_trans_settings_spi *spi; int flags, tgt; sdparam *sdp; struct ccb_trans_settings cts; memset(&cts, 0, sizeof (struct ccb_trans_settings)); va_start(ap, cmd); bus = va_arg(ap, int); tgt = va_arg(ap, int); va_end(ap); sdp = SDPARAM(isp, bus); if (xpt_create_path(&tmppath, NULL, cam_sim_path(ISP_SPI_PC(isp, bus)->sim), tgt, CAM_LUN_WILDCARD) != CAM_REQ_CMP) { isp_prt(isp, ISP_LOGWARN, "isp_async cannot make temp path for %d.%d", tgt, bus); break; } flags = sdp->isp_devparam[tgt].actv_flags; cts.type = CTS_TYPE_CURRENT_SETTINGS; cts.protocol = PROTO_SCSI; cts.transport = XPORT_SPI; scsi = &cts.proto_specific.scsi; spi = &cts.xport_specific.spi; if (flags & DPARM_TQING) { scsi->valid |= CTS_SCSI_VALID_TQ; scsi->flags |= CTS_SCSI_FLAGS_TAG_ENB; } if (flags & DPARM_DISC) { spi->valid |= CTS_SPI_VALID_DISC; spi->flags |= CTS_SPI_FLAGS_DISC_ENB; } spi->flags |= CTS_SPI_VALID_BUS_WIDTH; if (flags & DPARM_WIDE) { spi->bus_width = MSG_EXT_WDTR_BUS_16_BIT; } else { spi->bus_width = MSG_EXT_WDTR_BUS_8_BIT; } if (flags & DPARM_SYNC) { spi->valid |= CTS_SPI_VALID_SYNC_RATE; spi->valid |= CTS_SPI_VALID_SYNC_OFFSET; spi->sync_period = sdp->isp_devparam[tgt].actv_period; spi->sync_offset = sdp->isp_devparam[tgt].actv_offset; } isp_prt(isp, ISP_LOGDEBUG2, "NEW_TGT_PARAMS bus %d tgt %d period %x offset %x flags %x", bus, tgt, sdp->isp_devparam[tgt].actv_period, sdp->isp_devparam[tgt].actv_offset, flags); xpt_setup_ccb(&cts.ccb_h, tmppath, 1); xpt_async(AC_TRANSFER_NEG, tmppath, &cts); xpt_free_path(tmppath); break; } case ISPASYNC_BUS_RESET: { va_start(ap, cmd); bus = va_arg(ap, int); va_end(ap); isp_prt(isp, ISP_LOGINFO, "SCSI bus reset on bus %d detected", bus); if (IS_FC(isp)) { xpt_async(AC_BUS_RESET, ISP_FC_PC(isp, bus)->path, NULL); } else { xpt_async(AC_BUS_RESET, ISP_SPI_PC(isp, bus)->path, NULL); } break; } case ISPASYNC_LOOP_RESET: { uint16_t lipp; fcparam *fcp; va_start(ap, cmd); bus = va_arg(ap, int); va_end(ap); lipp = ISP_READ(isp, OUTMAILBOX1); fcp = FCPARAM(isp, bus); isp_prt(isp, ISP_LOGINFO, "Chan %d LOOP Reset, LIP primitive %x", bus, lipp); /* * Per FCP-4, a Reset LIP should result in a CRN reset. Other * LIPs and loop up/down events should never reset the CRN. For * an as of yet unknown reason, 24xx series cards (and * potentially others) can interrupt with a LIP Reset status * when no LIP reset came down the wire. Additionally, the LIP * primitive accompanying this status would not be a valid LIP * Reset primitive, but some variation of an invalid AL_PA * LIP. As a result, we have to verify the AL_PD in the LIP * addresses our port before blindly resetting. */ if (FCP_IS_DEST_ALPD(fcp, (lipp & 0x00FF))) isp_fcp_reset_crn(isp, bus, /*tgt*/0, /*tgt_set*/ 0); isp_loop_changed(isp, bus); break; } case ISPASYNC_LIP: if (msg == NULL) msg = "LIP Received"; /* FALLTHROUGH */ case ISPASYNC_LOOP_DOWN: if (msg == NULL) msg = "LOOP Down"; /* FALLTHROUGH */ case ISPASYNC_LOOP_UP: if (msg == NULL) msg = "LOOP Up"; va_start(ap, cmd); bus = va_arg(ap, int); va_end(ap); isp_loop_changed(isp, bus); isp_prt(isp, ISP_LOGINFO, "Chan %d %s", bus, msg); break; case ISPASYNC_DEV_ARRIVED: va_start(ap, cmd); bus = va_arg(ap, int); lp = va_arg(ap, fcportdb_t *); va_end(ap); fc = ISP_FC_PC(isp, bus); tgt = FC_PORTDB_TGT(isp, bus, lp); isp_gen_role_str(buf, sizeof (buf), lp->prli_word3); isp_prt(isp, ISP_LOGCONFIG, prom, bus, tgt, lp->port_wwn, lp->portid, lp->handle, buf, "arrived"); if ((FCPARAM(isp, bus)->role & ISP_ROLE_INITIATOR) && (lp->prli_word3 & PRLI_WD3_TARGET_FUNCTION)) { lp->is_target = 1; isp_fcp_reset_crn(isp, bus, tgt, /*tgt_set*/ 1); isp_make_here(isp, lp, bus, tgt); } if ((FCPARAM(isp, bus)->role & ISP_ROLE_TARGET) && (lp->prli_word3 & PRLI_WD3_INITIATOR_FUNCTION)) { lp->is_initiator = 1; ac.contract_number = AC_CONTRACT_DEV_CHG; adc = (struct ac_device_changed *) ac.contract_data; adc->wwpn = lp->port_wwn; adc->port = lp->portid; adc->target = tgt; adc->arrived = 1; xpt_async(AC_CONTRACT, fc->path, &ac); } break; case ISPASYNC_DEV_CHANGED: case ISPASYNC_DEV_STAYED: + { + int crn_reset_done; + + crn_reset_done = 0; va_start(ap, cmd); bus = va_arg(ap, int); lp = va_arg(ap, fcportdb_t *); va_end(ap); fc = ISP_FC_PC(isp, bus); tgt = FC_PORTDB_TGT(isp, bus, lp); isp_gen_role_str(buf, sizeof (buf), lp->new_prli_word3); if (cmd == ISPASYNC_DEV_CHANGED) isp_prt(isp, ISP_LOGCONFIG, prom, bus, tgt, lp->port_wwn, lp->new_portid, lp->handle, buf, "changed"); else isp_prt(isp, ISP_LOGCONFIG, prom, bus, tgt, lp->port_wwn, lp->portid, lp->handle, buf, "stayed"); if (lp->is_target != ((FCPARAM(isp, bus)->role & ISP_ROLE_INITIATOR) && (lp->new_prli_word3 & PRLI_WD3_TARGET_FUNCTION))) { lp->is_target = !lp->is_target; if (lp->is_target) { - if (cmd == ISPASYNC_DEV_CHANGED) + if (cmd == ISPASYNC_DEV_CHANGED) { isp_fcp_reset_crn(isp, bus, tgt, /*tgt_set*/ 1); + crn_reset_done = 1; + } isp_make_here(isp, lp, bus, tgt); } else { isp_make_gone(isp, lp, bus, tgt); - if (cmd == ISPASYNC_DEV_CHANGED) + if (cmd == ISPASYNC_DEV_CHANGED) { isp_fcp_reset_crn(isp, bus, tgt, /*tgt_set*/ 1); + crn_reset_done = 1; + } } } if (lp->is_initiator != ((FCPARAM(isp, bus)->role & ISP_ROLE_TARGET) && (lp->new_prli_word3 & PRLI_WD3_INITIATOR_FUNCTION))) { lp->is_initiator = !lp->is_initiator; ac.contract_number = AC_CONTRACT_DEV_CHG; adc = (struct ac_device_changed *) ac.contract_data; adc->wwpn = lp->port_wwn; adc->port = lp->portid; adc->target = tgt; adc->arrived = lp->is_initiator; xpt_async(AC_CONTRACT, fc->path, &ac); } + + if ((lp->new_prli_word0 & PRLI_WD0_EST_IMAGE_PAIR) && + (crn_reset_done == 0)) + isp_fcp_reset_crn(isp, bus, tgt, /*tgt_set*/ 1); + break; + } case ISPASYNC_DEV_GONE: va_start(ap, cmd); bus = va_arg(ap, int); lp = va_arg(ap, fcportdb_t *); va_end(ap); fc = ISP_FC_PC(isp, bus); tgt = FC_PORTDB_TGT(isp, bus, lp); /* * If this has a virtual target or initiator set the isp_gdt * timer running on it to delay its departure. */ isp_gen_role_str(buf, sizeof (buf), lp->prli_word3); if (lp->is_target || lp->is_initiator) { lp->state = FC_PORTDB_STATE_ZOMBIE; lp->gone_timer = fc->gone_device_time; isp_prt(isp, ISP_LOGCONFIG, prom, bus, tgt, lp->port_wwn, lp->portid, lp->handle, buf, "gone zombie"); if (fc->ready && !callout_active(&fc->gdt)) { isp_prt(isp, ISP_LOG_SANCFG|ISP_LOGDEBUG0, "Chan %d Starting Gone Device Timer with %u seconds time now %lu", bus, lp->gone_timer, (unsigned long)time_uptime); callout_reset(&fc->gdt, hz, isp_gdt, fc); } break; } isp_prt(isp, ISP_LOGCONFIG, prom, bus, tgt, lp->port_wwn, lp->portid, lp->handle, buf, "gone"); break; case ISPASYNC_CHANGE_NOTIFY: { char *msg; int evt, nphdl, nlstate, portid, reason; va_start(ap, cmd); bus = va_arg(ap, int); evt = va_arg(ap, int); if (evt == ISPASYNC_CHANGE_PDB) { nphdl = va_arg(ap, int); nlstate = va_arg(ap, int); reason = va_arg(ap, int); } else if (evt == ISPASYNC_CHANGE_SNS) { portid = va_arg(ap, int); } else { nphdl = NIL_HANDLE; nlstate = reason = 0; } va_end(ap); if (evt == ISPASYNC_CHANGE_PDB) { int tgt_set = 0; msg = "Port Database Changed"; isp_prt(isp, ISP_LOGINFO, "Chan %d %s (nphdl 0x%x state 0x%x reason 0x%x)", bus, msg, nphdl, nlstate, reason); /* * Port database syncs are not sufficient for * determining that logins or logouts are done on the * loop, but this information is directly available from * the reason code from the incoming mbox. We must reset * the fcp crn on these events according to FCP-4 */ switch (reason) { case PDB24XX_AE_IMPL_LOGO_1: case PDB24XX_AE_IMPL_LOGO_2: case PDB24XX_AE_IMPL_LOGO_3: case PDB24XX_AE_PLOGI_RCVD: case PDB24XX_AE_PRLI_RCVD: case PDB24XX_AE_PRLO_RCVD: case PDB24XX_AE_LOGO_RCVD: case PDB24XX_AE_PLOGI_DONE: case PDB24XX_AE_PRLI_DONE: /* * If the event is not global, twiddle tgt and * tgt_set to nominate only the target * associated with the nphdl. */ if (nphdl != PDB24XX_AE_GLOBAL) { /* Break if we don't yet have the pdb */ if (!isp_find_pdb_by_handle(isp, bus, nphdl, &lp)) break; tgt = FC_PORTDB_TGT(isp, bus, lp); tgt_set = 1; } isp_fcp_reset_crn(isp, bus, tgt, tgt_set); break; default: break; /* NOP */ } } else if (evt == ISPASYNC_CHANGE_SNS) { msg = "Name Server Database Changed"; isp_prt(isp, ISP_LOGINFO, "Chan %d %s (PortID 0x%06x)", bus, msg, portid); } else { msg = "Other Change Notify"; isp_prt(isp, ISP_LOGINFO, "Chan %d %s", bus, msg); } isp_loop_changed(isp, bus); break; } #ifdef ISP_TARGET_MODE case ISPASYNC_TARGET_NOTIFY: { isp_notify_t *notify; va_start(ap, cmd); notify = va_arg(ap, isp_notify_t *); va_end(ap); switch (notify->nt_ncode) { case NT_ABORT_TASK: case NT_ABORT_TASK_SET: case NT_CLEAR_ACA: case NT_CLEAR_TASK_SET: case NT_LUN_RESET: case NT_TARGET_RESET: case NT_QUERY_TASK_SET: case NT_QUERY_ASYNC_EVENT: /* * These are task management functions. */ isp_handle_platform_target_tmf(isp, notify); break; case NT_BUS_RESET: case NT_LIP_RESET: case NT_LINK_UP: case NT_LINK_DOWN: case NT_HBA_RESET: /* * No action need be taken here. */ break; case NT_GLOBAL_LOGOUT: case NT_LOGOUT: /* * This is device arrival/departure notification */ isp_handle_platform_target_notify_ack(isp, notify, 0); break; case NT_SRR: isp_handle_platform_srr(isp, notify); break; default: isp_prt(isp, ISP_LOGALL, "target notify code 0x%x", notify->nt_ncode); isp_handle_platform_target_notify_ack(isp, notify, 0); break; } break; } case ISPASYNC_TARGET_NOTIFY_ACK: { void *inot; va_start(ap, cmd); inot = va_arg(ap, void *); va_end(ap); if (isp_notify_ack(isp, inot)) { isp_tna_t *tp = malloc(sizeof (*tp), M_DEVBUF, M_NOWAIT); if (tp) { tp->isp = isp; memcpy(tp->data, inot, sizeof (tp->data)); tp->not = tp->data; callout_init_mtx(&tp->timer, &isp->isp_lock, 0); callout_reset(&tp->timer, 5, isp_refire_notify_ack, tp); } else { isp_prt(isp, ISP_LOGERR, "you lose- cannot allocate a notify refire"); } } break; } case ISPASYNC_TARGET_ACTION: { isphdr_t *hp; va_start(ap, cmd); hp = va_arg(ap, isphdr_t *); va_end(ap); switch (hp->rqs_entry_type) { case RQSTYPE_ATIO: isp_handle_platform_atio7(isp, (at7_entry_t *) hp); break; case RQSTYPE_ATIO2: isp_handle_platform_atio2(isp, (at2_entry_t *) hp); break; case RQSTYPE_CTIO7: case RQSTYPE_CTIO3: case RQSTYPE_CTIO2: case RQSTYPE_CTIO: isp_handle_platform_ctio(isp, hp); break; default: isp_prt(isp, ISP_LOGWARN, "%s: unhandled target action 0x%x", __func__, hp->rqs_entry_type); break; } break; } #endif case ISPASYNC_FW_CRASH: { uint16_t mbox1, mbox6; mbox1 = ISP_READ(isp, OUTMAILBOX1); if (IS_DUALBUS(isp)) { mbox6 = ISP_READ(isp, OUTMAILBOX6); } else { mbox6 = 0; } isp_prt(isp, ISP_LOGERR, "Internal Firmware Error on bus %d @ RISC Address 0x%x", mbox6, mbox1); #if 0 mbox1 = isp->isp_osinfo.mbox_sleep_ok; isp->isp_osinfo.mbox_sleep_ok = 0; isp_reinit(isp, 1); isp->isp_osinfo.mbox_sleep_ok = mbox1; isp_async(isp, ISPASYNC_FW_RESTARTED, NULL); #endif break; } default: isp_prt(isp, ISP_LOGERR, "unknown isp_async event %d", cmd); break; } } uint64_t isp_default_wwn(ispsoftc_t * isp, int chan, int isactive, int iswwnn) { uint64_t seed; struct isp_fc *fc = ISP_FC_PC(isp, chan); /* First try to use explicitly configured WWNs. */ seed = iswwnn ? fc->def_wwnn : fc->def_wwpn; if (seed) return (seed); /* Otherwise try to use WWNs from NVRAM. */ if (isactive) { seed = iswwnn ? FCPARAM(isp, chan)->isp_wwnn_nvram : FCPARAM(isp, chan)->isp_wwpn_nvram; if (seed) return (seed); } /* If still no WWNs, try to steal them from the first channel. */ if (chan > 0) { seed = iswwnn ? ISP_FC_PC(isp, 0)->def_wwnn : ISP_FC_PC(isp, 0)->def_wwpn; if (seed == 0) { seed = iswwnn ? FCPARAM(isp, 0)->isp_wwnn_nvram : FCPARAM(isp, 0)->isp_wwpn_nvram; } } /* If still nothing -- improvise. */ if (seed == 0) { seed = 0x400000007F000000ull + device_get_unit(isp->isp_dev); if (!iswwnn) seed ^= 0x0100000000000000ULL; } /* For additional channels we have to improvise even more. */ if (!iswwnn && chan > 0) { /* * We'll stick our channel number plus one first into bits * 57..59 and thence into bits 52..55 which allows for 8 bits * of channel which is enough for our maximum of 255 channels. */ seed ^= 0x0100000000000000ULL; seed ^= ((uint64_t) (chan + 1) & 0xf) << 56; seed ^= ((uint64_t) ((chan + 1) >> 4) & 0xf) << 52; } return (seed); } void isp_prt(ispsoftc_t *isp, int level, const char *fmt, ...) { int loc; char lbuf[200]; va_list ap; if (level != ISP_LOGALL && (level & isp->isp_dblev) == 0) { return; } snprintf(lbuf, sizeof (lbuf), "%s: ", device_get_nameunit(isp->isp_dev)); loc = strlen(lbuf); va_start(ap, fmt); vsnprintf(&lbuf[loc], sizeof (lbuf) - loc - 1, fmt, ap); va_end(ap); printf("%s\n", lbuf); } void isp_xs_prt(ispsoftc_t *isp, XS_T *xs, int level, const char *fmt, ...) { va_list ap; if (level != ISP_LOGALL && (level & isp->isp_dblev) == 0) { return; } xpt_print_path(xs->ccb_h.path); va_start(ap, fmt); vprintf(fmt, ap); va_end(ap); printf("\n"); } uint64_t isp_nanotime_sub(struct timespec *b, struct timespec *a) { uint64_t elapsed; struct timespec x; timespecsub(b, a, &x); elapsed = GET_NANOSEC(&x); if (elapsed == 0) elapsed++; return (elapsed); } int isp_mbox_acquire(ispsoftc_t *isp) { if (isp->isp_osinfo.mboxbsy) { return (1); } else { isp->isp_osinfo.mboxcmd_done = 0; isp->isp_osinfo.mboxbsy = 1; return (0); } } void isp_mbox_wait_complete(ispsoftc_t *isp, mbreg_t *mbp) { u_int t, to; to = (mbp->timeout == 0) ? MBCMD_DEFAULT_TIMEOUT : mbp->timeout; if (isp->isp_osinfo.mbox_sleep_ok) { isp->isp_osinfo.mbox_sleep_ok = 0; isp->isp_osinfo.mbox_sleeping = 1; msleep_sbt(&isp->isp_osinfo.mboxcmd_done, &isp->isp_lock, PRIBIO, "ispmbx_sleep", to * SBT_1US, 0, 0); isp->isp_osinfo.mbox_sleep_ok = 1; isp->isp_osinfo.mbox_sleeping = 0; } else { for (t = 0; t < to; t += 100) { if (isp->isp_osinfo.mboxcmd_done) break; ISP_RUN_ISR(isp); if (isp->isp_osinfo.mboxcmd_done) break; ISP_DELAY(100); } } if (isp->isp_osinfo.mboxcmd_done == 0) { isp_prt(isp, ISP_LOGWARN, "%s Mailbox Command (0x%x) Timeout (%uus) (%s:%d)", isp->isp_osinfo.mbox_sleep_ok? "Interrupting" : "Polled", isp->isp_lastmbxcmd, to, mbp->func, mbp->lineno); mbp->param[0] = MBOX_TIMEOUT; isp->isp_osinfo.mboxcmd_done = 1; } } void isp_mbox_notify_done(ispsoftc_t *isp) { isp->isp_osinfo.mboxcmd_done = 1; if (isp->isp_osinfo.mbox_sleeping) wakeup(&isp->isp_osinfo.mboxcmd_done); } void isp_mbox_release(ispsoftc_t *isp) { isp->isp_osinfo.mboxbsy = 0; } int isp_fc_scratch_acquire(ispsoftc_t *isp, int chan) { int ret = 0; if (isp->isp_osinfo.pc.fc[chan].fcbsy) { ret = -1; } else { isp->isp_osinfo.pc.fc[chan].fcbsy = 1; } return (ret); } void isp_platform_intr(void *arg) { ispsoftc_t *isp = arg; ISP_LOCK(isp); ISP_RUN_ISR(isp); ISP_UNLOCK(isp); } void isp_platform_intr_resp(void *arg) { ispsoftc_t *isp = arg; ISP_LOCK(isp); isp_intr_respq(isp); ISP_UNLOCK(isp); /* We have handshake enabled, so explicitly complete interrupt */ ISP_WRITE(isp, BIU2400_HCCR, HCCR_2400_CMD_CLEAR_RISC_INT); } void isp_platform_intr_atio(void *arg) { ispsoftc_t *isp = arg; ISP_LOCK(isp); #ifdef ISP_TARGET_MODE isp_intr_atioq(isp); #endif ISP_UNLOCK(isp); /* We have handshake enabled, so explicitly complete interrupt */ ISP_WRITE(isp, BIU2400_HCCR, HCCR_2400_CMD_CLEAR_RISC_INT); } void isp_common_dmateardown(ispsoftc_t *isp, struct ccb_scsiio *csio, uint32_t hdl) { if ((csio->ccb_h.flags & CAM_DIR_MASK) == CAM_DIR_IN) { bus_dmamap_sync(isp->isp_osinfo.dmat, PISP_PCMD(csio)->dmap, BUS_DMASYNC_POSTREAD); } else { bus_dmamap_sync(isp->isp_osinfo.dmat, PISP_PCMD(csio)->dmap, BUS_DMASYNC_POSTWRITE); } bus_dmamap_unload(isp->isp_osinfo.dmat, PISP_PCMD(csio)->dmap); } /* * Reset the command reference number for all LUNs on a specific target * (needed when a target arrives again) or for all targets on a port * (needed for events like a LIP). */ void isp_fcp_reset_crn(ispsoftc_t *isp, int chan, uint32_t tgt, int tgt_set) { struct isp_fc *fc = ISP_FC_PC(isp, chan); struct isp_nexus *nxp; int i; if (tgt_set == 0) isp_prt(isp, ISP_LOGDEBUG0, "Chan %d resetting CRN on all targets", chan); else isp_prt(isp, ISP_LOGDEBUG0, "Chan %d resetting CRN on target %u", chan, tgt); for (i = 0; i < NEXUS_HASH_WIDTH; i++) { for (nxp = fc->nexus_hash[i]; nxp != NULL; nxp = nxp->next) { if (tgt_set == 0 || tgt == nxp->tgt) nxp->crnseed = 0; } } } int isp_fcp_next_crn(ispsoftc_t *isp, uint8_t *crnp, XS_T *cmd) { lun_id_t lun; uint32_t chan, tgt; struct isp_fc *fc; struct isp_nexus *nxp; int idx; if (IS_2100(isp)) return (0); chan = XS_CHANNEL(cmd); tgt = XS_TGT(cmd); lun = XS_LUN(cmd); fc = &isp->isp_osinfo.pc.fc[chan]; idx = NEXUS_HASH(tgt, lun); nxp = fc->nexus_hash[idx]; while (nxp) { if (nxp->tgt == tgt && nxp->lun == lun) break; nxp = nxp->next; } if (nxp == NULL) { nxp = fc->nexus_free_list; if (nxp == NULL) { nxp = malloc(sizeof (struct isp_nexus), M_DEVBUF, M_ZERO|M_NOWAIT); if (nxp == NULL) { return (-1); } } else { fc->nexus_free_list = nxp->next; } nxp->tgt = tgt; nxp->lun = lun; nxp->next = fc->nexus_hash[idx]; fc->nexus_hash[idx] = nxp; } if (nxp->crnseed == 0) nxp->crnseed = 1; *crnp = nxp->crnseed++; return (0); } /* * We enter with the lock held */ void isp_timer(void *arg) { ispsoftc_t *isp = arg; #ifdef ISP_TARGET_MODE isp_tmcmd_restart(isp); #endif callout_reset(&isp->isp_osinfo.tmo, isp_timer_count, isp_timer, isp); } isp_ecmd_t * isp_get_ecmd(ispsoftc_t *isp) { isp_ecmd_t *ecmd = isp->isp_osinfo.ecmd_free; if (ecmd) { isp->isp_osinfo.ecmd_free = ecmd->next; } return (ecmd); } void isp_put_ecmd(ispsoftc_t *isp, isp_ecmd_t *ecmd) { ecmd->next = isp->isp_osinfo.ecmd_free; isp->isp_osinfo.ecmd_free = ecmd; } Index: head/sys/dev/isp/isp_stds.h =================================================================== --- head/sys/dev/isp/isp_stds.h (revision 345007) +++ head/sys/dev/isp/isp_stds.h (revision 345008) @@ -1,332 +1,340 @@ /* $FreeBSD$ */ /*- * SPDX-License-Identifier: BSD-2-Clause-FreeBSD * * Copyright (c) 1997-2009 by Matthew Jacob * 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 AUTHOR AND CONTRIBUTORS ``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 AUTHOR OR CONTRIBUTORS 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. * */ /* * Structures that derive directly from public standards. */ #ifndef _ISP_STDS_H #define _ISP_STDS_H /* * FC Frame Header * * Source: dpANS-X3.xxx-199x, section 18 (AKA FC-PH-2) * */ typedef struct { uint8_t r_ctl; uint8_t d_id[3]; uint8_t cs_ctl; uint8_t s_id[3]; uint8_t type; uint8_t f_ctl[3]; uint8_t seq_id; uint8_t df_ctl; uint16_t seq_cnt; uint16_t ox_id; uint16_t rx_id; uint32_t parameter; } fc_hdr_t; /* * FCP_CMND_IU Payload * * Source: NICTS T10, Project 1144D, Revision 07a, Section 9 (AKA fcp2-r07a) * * Notes: * When additional cdb length is defined in fcp_cmnd_alen_datadir, * bits 2..7, the actual cdb length is 16 + ((fcp_cmnd_alen_datadir>>2)*4), * with the datalength following in MSB format just after. */ typedef struct { uint8_t fcp_cmnd_lun[8]; uint8_t fcp_cmnd_crn; uint8_t fcp_cmnd_task_attribute; uint8_t fcp_cmnd_task_management; uint8_t fcp_cmnd_alen_datadir; union { struct { uint8_t fcp_cmnd_cdb[16]; uint32_t fcp_cmnd_dl; } sf; struct { uint8_t fcp_cmnd_cdb[1]; } lf; } cdb_dl; } fcp_cmnd_iu_t; #define FCP_CMND_TASK_ATTR_SIMPLE 0x00 #define FCP_CMND_TASK_ATTR_HEAD 0x01 #define FCP_CMND_TASK_ATTR_ORDERED 0x02 #define FCP_CMND_TASK_ATTR_ACA 0x04 #define FCP_CMND_TASK_ATTR_UNTAGGED 0x05 #define FCP_CMND_TASK_ATTR_MASK 0x07 #define FCP_CMND_ADDTL_CDBLEN_SHIFT 2 #define FCP_CMND_DATA_WRITE 0x01 #define FCP_CMND_DATA_READ 0x02 #define FCP_CMND_DATA_DIR_MASK 0x03 #define FCP_CMND_TMF_CLEAR_ACA 0x40 #define FCP_CMND_TMF_TGT_RESET 0x20 #define FCP_CMND_TMF_LUN_RESET 0x10 #define FCP_CMND_TMF_QUERY_ASYNC_EVENT 0x08 #define FCP_CMND_TMF_CLEAR_TASK_SET 0x04 #define FCP_CMND_TMF_ABORT_TASK_SET 0x02 #define FCP_CMND_TMF_QUERY_TASK_SET 0x01 /* * Basic CT IU Header * * Source: X3.288-199x Generic Services 2 Rev 5.3 (FC-GS-2) Section 4.3.1 */ typedef struct { uint8_t ct_revision; uint8_t ct_in_id[3]; uint8_t ct_fcs_type; uint8_t ct_fcs_subtype; uint8_t ct_options; uint8_t ct_reserved0; uint16_t ct_cmd_resp; uint16_t ct_bcnt_resid; uint8_t ct_reserved1; uint8_t ct_reason; uint8_t ct_explanation; uint8_t ct_vunique; } ct_hdr_t; #define CT_REVISION 1 #define CT_FC_TYPE_FC 0xFC #define CT_FC_SUBTYPE_NS 0x02 /* * RFT_ID Requet CT_IU * * Source: NCITS xxx-200x Generic Services- 5 Rev 8.5 Section 5.2.5.30 */ typedef struct { ct_hdr_t rftid_hdr; uint8_t rftid_reserved; uint8_t rftid_portid[3]; uint32_t rftid_fc4types[8]; } rft_id_t; /* * RSPN_ID Requet CT_IU * * Source: INCITS 463-2010 Generic Services 6 Section 5.2.5.32 */ typedef struct { ct_hdr_t rspnid_hdr; uint8_t rspnid_reserved; uint8_t rspnid_portid[3]; uint8_t rspnid_length; uint8_t rspnid_name[0]; } rspn_id_t; /* * RFF_ID Requet CT_IU * * Source: INCITS 463-2010 Generic Services 6 Section 5.2.5.34 */ typedef struct { ct_hdr_t rffid_hdr; uint8_t rffid_reserved; uint8_t rffid_portid[3]; uint16_t rffid_reserved2; uint8_t rffid_fc4features; uint8_t rffid_fc4type; } rff_id_t; /* * RSNN_NN Requet CT_IU * * Source: INCITS 463-2010 Generic Services 6 Section 5.2.5.35 */ typedef struct { ct_hdr_t rsnnnn_hdr; uint8_t rsnnnn_nodename[8]; uint8_t rsnnnn_length; uint8_t rsnnnn_name[0]; } rsnn_nn_t; /* * FCP Response IU and bits of interest * Source: NCITS T10, Project 1828D, Revision 02b (aka FCP4r02b) */ typedef struct { uint8_t fcp_rsp_reserved[8]; uint16_t fcp_rsp_status_qualifier; /* SAM-5 Status Qualifier */ uint8_t fcp_rsp_bits; uint8_t fcp_rsp_scsi_status; /* SAM-5 SCSI Status Byte */ uint32_t fcp_rsp_resid; uint32_t fcp_rsp_snslen; uint32_t fcp_rsp_rsplen; /* * In the bytes that follow, it's going to be * FCP RESPONSE INFO (max 8 bytes, possibly 0) * FCP SENSE INFO (if any) * FCP BIDIRECTIONAL READ RESID (if any) */ uint8_t fcp_rsp_extra[0]; } fcp_rsp_iu_t; #define MIN_FCP_RESPONSE_SIZE 24 #define FCP_BIDIR_RSP 0x80 /* Bi-Directional response */ #define FCP_BIDIR_RESID_UNDERFLOW 0x40 #define FCP_BIDIR_RESID_OVERFLOW 0x20 #define FCP_CONF_REQ 0x10 #define FCP_RESID_UNDERFLOW 0x08 #define FCP_RESID_OVERFLOW 0x04 #define FCP_SNSLEN_VALID 0x02 #define FCP_RSPLEN_VALID 0x01 #define FCP_MAX_RSPLEN 0x08 /* * FCP Response Code Definitions * Source: NCITS T10, Project 1144D, Revision 08 (aka FCP2r08) */ #define FCP_RSPNS_CODE_OFFSET 3 #define FCP_RSPNS_TMF_DONE 0 #define FCP_RSPNS_DLBRSTX 1 #define FCP_RSPNS_BADCMND 2 #define FCP_RSPNS_EROFS 3 #define FCP_RSPNS_TMF_REJECT 4 #define FCP_RSPNS_TMF_FAILED 5 #define FCP_RSPNS_TMF_SUCCEEDED 8 #define FCP_RSPNS_TMF_INCORRECT_LUN 9 /* * R_CTL field definitions * * Bits 31-28 are ROUTING * Bits 27-24 are INFORMATION * * These are nibble values, not bits */ #define R_CTL_ROUTE_DATA 0x00 #define R_CTL_ROUTE_ELS 0x02 #define R_CTL_ROUTE_FC4_LINK 0x03 #define R_CTL_ROUTE_VDATA 0x04 #define R_CTL_ROUTE_EXENDED 0x05 #define R_CTL_ROUTE_BASIC 0x08 #define R_CTL_ROUTE_LINK 0x0c #define R_CTL_ROUTE_EXT_ROUTING 0x0f #define R_CTL_INFO_UNCATEGORIZED 0x00 #define R_CTL_INFO_SOLICITED_DATA 0x01 #define R_CTL_INFO_UNSOLICITED_CONTROL 0x02 #define R_CTL_INFO_SOLICITED_CONTROL 0x03 #define R_CTL_INFO_UNSOLICITED_DATA 0x04 #define R_CTL_INFO_DATA_DESCRIPTOR 0x05 #define R_CTL_INFO_UNSOLICITED_COMMAND 0x06 #define R_CTL_INFO_COMMAND_STATUS 0x07 #define MAKE_RCTL(a, b) (((a) << 4) | (b)) /* unconverted miscellany */ /* * Basic FC Link Service defines */ /* #define ABTS MAKE_RCTL(R_CTL_ROUTE_BASIC, R_CTL_INFO_SOLICITED_DATA) */ #define BA_ACC MAKE_RCTL(R_CTL_ROUTE_BASIC, R_CTL_INFO_UNSOLICITED_DATA) /* of ABORT */ #define BA_RJT MAKE_RCTL(R_CTL_ROUTE_BASIC, R_CTL_INFO_DATA_DESCRIPTOR) /* of ABORT */ /* * Link Service Accept/Reject */ #define LS_ACC 0x8002 #define LS_RJT 0x8001 /* * FC ELS Codes- bits 31-24 of the first payload word of an ELS frame. */ #define PLOGI 0x03 #define FLOGI 0x04 #define LOGO 0x05 #define ABTX 0x06 #define PRLI 0x20 #define PRLO 0x21 #define SCN 0x22 #define TPRLO 0x24 #define PDISC 0x50 #define ADISC 0x52 #define RNC 0x53 /* + * PRLI Word 0 definitions + * FPC4-r02b January, 2011 + */ +#define PRLI_WD0_TYPE_MASK 0xff000000 +#define PRLI_WD0_TC_EXT_MASK 0x00ff0000 +#define PRLI_WD0_EST_IMAGE_PAIR (1 << 13) + +/* * PRLI Word 3 definitions * FPC4-r02b January, 2011 */ #define PRLI_WD3_ENHANCED_DISCOVERY (1 << 11) #define PRLI_WD3_REC_SUPPORT (1 << 10) #define PRLI_WD3_TASK_RETRY_IDENTIFICATION_REQUESTED (1 << 9) #define PRLI_WD3_RETRY (1 << 8) #define PRLI_WD3_CONFIRMED_COMPLETION_ALLOWED (1 << 7) #define PRLI_WD3_DATA_OVERLAY_ALLOWED (1 << 6) #define PRLI_WD3_INITIATOR_FUNCTION (1 << 5) #define PRLI_WD3_TARGET_FUNCTION (1 << 4) #define PRLI_WD3_READ_FCP_XFER_RDY_DISABLED (1 << 1) /* definitely supposed to be set */ #define PRLI_WD3_WRITE_FCP_XFER_RDY_DISABLED (1 << 0) /* * FC4 defines */ #define FC4_IP 5 /* ISO/EEC 8802-2 LLC/SNAP */ #define FC4_SCSI 8 /* SCSI-3 via Fibre Channel Protocol (FCP) */ #define FC4_FC_SVC 0x20 /* Fibre Channel Services */ #ifndef MSG_ABORT #define MSG_ABORT 0x06 #endif #ifndef MSG_BUS_DEV_RESET #define MSG_BUS_DEV_RESET 0x0c #endif #ifndef MSG_ABORT_TAG #define MSG_ABORT_TAG 0x0d #endif #ifndef MSG_CLEAR_QUEUE #define MSG_CLEAR_QUEUE 0x0e #endif #ifndef MSG_REL_RECOVERY #define MSG_REL_RECOVERY 0x10 #endif #ifndef MSG_TERM_IO_PROC #define MSG_TERM_IO_PROC 0x11 #endif #ifndef MSG_LUN_RESET #define MSG_LUN_RESET 0x17 #endif #endif /* _ISP_STDS_H */ Index: head/sys/dev/isp/ispmbox.h =================================================================== --- head/sys/dev/isp/ispmbox.h (revision 345007) +++ head/sys/dev/isp/ispmbox.h (revision 345008) @@ -1,2717 +1,2718 @@ /* $FreeBSD$ */ /*- * SPDX-License-Identifier: BSD-2-Clause-FreeBSD * * Copyright (c) 2009-2018 Alexander Motin * Copyright (c) 1997-2009 by Matthew Jacob * 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 AUTHOR AND CONTRIBUTORS ``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 AUTHOR OR CONTRIBUTORS 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. * */ /* * Mailbox and Queue Entry Definitions for for Qlogic ISP SCSI adapters. */ #ifndef _ISPMBOX_H #define _ISPMBOX_H /* * Mailbox Command Opcodes */ #define MBOX_NO_OP 0x0000 #define MBOX_LOAD_RAM 0x0001 #define MBOX_EXEC_FIRMWARE 0x0002 #define MBOX_DUMP_RAM 0x0003 #define MBOX_WRITE_RAM_WORD 0x0004 #define MBOX_READ_RAM_WORD 0x0005 #define MBOX_MAILBOX_REG_TEST 0x0006 #define MBOX_VERIFY_CHECKSUM 0x0007 #define MBOX_ABOUT_FIRMWARE 0x0008 #define MBOX_LOAD_RISC_RAM_2100 0x0009 /* a */ #define MBOX_LOAD_RISC_RAM 0x000b #define MBOX_DUMP_RISC_RAM 0x000c #define MBOX_WRITE_RAM_WORD_EXTENDED 0x000d #define MBOX_CHECK_FIRMWARE 0x000e #define MBOX_READ_RAM_WORD_EXTENDED 0x000f #define MBOX_INIT_REQ_QUEUE 0x0010 #define MBOX_INIT_RES_QUEUE 0x0011 #define MBOX_EXECUTE_IOCB 0x0012 #define MBOX_WAKE_UP 0x0013 #define MBOX_STOP_FIRMWARE 0x0014 #define MBOX_ABORT 0x0015 #define MBOX_ABORT_DEVICE 0x0016 #define MBOX_ABORT_TARGET 0x0017 #define MBOX_BUS_RESET 0x0018 #define MBOX_STOP_QUEUE 0x0019 #define MBOX_START_QUEUE 0x001a #define MBOX_SINGLE_STEP_QUEUE 0x001b #define MBOX_ABORT_QUEUE 0x001c #define MBOX_GET_DEV_QUEUE_STATUS 0x001d /* 1e */ #define MBOX_GET_FIRMWARE_STATUS 0x001f #define MBOX_GET_INIT_SCSI_ID 0x0020 #define MBOX_GET_SELECT_TIMEOUT 0x0021 #define MBOX_GET_RETRY_COUNT 0x0022 #define MBOX_GET_TAG_AGE_LIMIT 0x0023 #define MBOX_GET_CLOCK_RATE 0x0024 #define MBOX_GET_ACT_NEG_STATE 0x0025 #define MBOX_GET_ASYNC_DATA_SETUP_TIME 0x0026 #define MBOX_GET_SBUS_PARAMS 0x0027 #define MBOX_GET_PCI_PARAMS MBOX_GET_SBUS_PARAMS #define MBOX_GET_TARGET_PARAMS 0x0028 #define MBOX_GET_DEV_QUEUE_PARAMS 0x0029 #define MBOX_GET_RESET_DELAY_PARAMS 0x002a /* 2b */ /* 2c */ /* 2d */ /* 2e */ /* 2f */ #define MBOX_SET_INIT_SCSI_ID 0x0030 #define MBOX_SET_SELECT_TIMEOUT 0x0031 #define MBOX_SET_RETRY_COUNT 0x0032 #define MBOX_SET_TAG_AGE_LIMIT 0x0033 #define MBOX_SET_CLOCK_RATE 0x0034 #define MBOX_SET_ACT_NEG_STATE 0x0035 #define MBOX_SET_ASYNC_DATA_SETUP_TIME 0x0036 #define MBOX_SET_SBUS_CONTROL_PARAMS 0x0037 #define MBOX_SET_PCI_PARAMETERS 0x0037 #define MBOX_SET_TARGET_PARAMS 0x0038 #define MBOX_SET_DEV_QUEUE_PARAMS 0x0039 #define MBOX_SET_RESET_DELAY_PARAMS 0x003a /* 3b */ /* 3c */ /* 3d */ /* 3e */ /* 3f */ #define MBOX_RETURN_BIOS_BLOCK_ADDR 0x0040 #define MBOX_WRITE_FOUR_RAM_WORDS 0x0041 #define MBOX_EXEC_BIOS_IOCB 0x0042 #define MBOX_SET_FW_FEATURES 0x004a #define MBOX_GET_FW_FEATURES 0x004b #define FW_FEATURE_FAST_POST 0x1 #define FW_FEATURE_LVD_NOTIFY 0x2 #define FW_FEATURE_RIO_32BIT 0x4 #define FW_FEATURE_RIO_16BIT 0x8 #define MBOX_INIT_REQ_QUEUE_A64 0x0052 #define MBOX_INIT_RES_QUEUE_A64 0x0053 #define MBOX_ENABLE_TARGET_MODE 0x0055 #define ENABLE_TARGET_FLAG 0x8000 #define ENABLE_TQING_FLAG 0x0004 #define ENABLE_MANDATORY_DISC 0x0002 #define MBOX_GET_TARGET_STATUS 0x0056 /* These are for the ISP2X00 FC cards */ #define MBOX_LOAD_FLASH_FIRMWARE 0x0003 #define MBOX_WRITE_FC_SERDES_REG 0x0003 /* FC only */ #define MBOX_READ_FC_SERDES_REG 0x0004 /* FC only */ #define MBOX_GET_IO_STATUS 0x0012 #define MBOX_SET_TRANSMIT_PARAMS 0x0019 #define MBOX_SET_PORT_PARAMS 0x001a #define MBOX_LOAD_OP_FW_PARAMS 0x001b #define MBOX_INIT_MULTIPLE_QUEUE 0x001f #define MBOX_GET_LOOP_ID 0x0020 /* for 24XX cards, outgoing mailbox 7 has these values for F or FL topologies */ #define ISP24XX_INORDER 0x0100 #define ISP24XX_NPIV_SAN 0x0400 #define ISP24XX_VSAN_SAN 0x1000 #define ISP24XX_FC_SP_SAN 0x2000 #define MBOX_GET_TIMEOUT_PARAMS 0x0022 #define MBOX_GET_FIRMWARE_OPTIONS 0x0028 #define MBOX_GENERATE_SYSTEM_ERROR 0x002a #define MBOX_WRITE_SFP 0x0030 #define MBOX_READ_SFP 0x0031 #define MBOX_SET_TIMEOUT_PARAMS 0x0032 #define MBOX_SET_FIRMWARE_OPTIONS 0x0038 #define MBOX_GET_SET_FC_LED_CONF 0x003b #define MBOX_RESTART_NIC_FIRMWARE 0x003d /* FCoE only */ #define MBOX_ACCESS_CONTROL 0x003e #define MBOX_LOOP_PORT_BYPASS 0x0040 /* FC only */ #define MBOX_LOOP_PORT_ENABLE 0x0041 /* FC only */ #define MBOX_GET_RESOURCE_COUNT 0x0042 #define MBOX_REQUEST_OFFLINE_MODE 0x0043 #define MBOX_DIAGNOSTIC_ECHO_TEST 0x0044 #define MBOX_DIAGNOSTIC_LOOPBACK 0x0045 #define MBOX_ENHANCED_GET_PDB 0x0047 #define MBOX_INIT_FIRMWARE_MULTI_ID 0x0048 /* 2400 only */ #define MBOX_GET_VP_DATABASE 0x0049 /* 2400 only */ #define MBOX_GET_VP_DATABASE_ENTRY 0x004a /* 2400 only */ #define MBOX_GET_FCF_LIST 0x0050 /* FCoE only */ #define MBOX_GET_DCBX_PARAMETERS 0x0051 /* FCoE only */ #define MBOX_HOST_MEMORY_COPY 0x0053 #define MBOX_EXEC_COMMAND_IOCB_A64 0x0054 #define MBOX_SEND_RNID 0x0057 #define MBOX_SET_PARAMETERS 0x0059 #define MBOX_GET_PARAMETERS 0x005a #define MBOX_DRIVER_HEARTBEAT 0x005B /* FC only */ #define MBOX_FW_HEARTBEAT 0x005C #define MBOX_GET_SET_DATA_RATE 0x005D /* >=23XX only */ #define MBGSD_GET_RATE 0 #define MBGSD_SET_RATE 1 #define MBGSD_SET_RATE_NOW 2 /* 24XX only */ #define MBGSD_1GB 0x00 #define MBGSD_2GB 0x01 #define MBGSD_AUTO 0x02 #define MBGSD_4GB 0x03 /* 24XX only */ #define MBGSD_8GB 0x04 /* 25XX only */ #define MBGSD_16GB 0x05 /* 26XX only */ #define MBGSD_32GB 0x06 /* 27XX only */ #define MBGSD_10GB 0x13 /* 26XX only */ #define MBOX_SEND_RNFT 0x005e #define MBOX_INIT_FIRMWARE 0x0060 #define MBOX_GET_INIT_CONTROL_BLOCK 0x0061 #define MBOX_INIT_LIP 0x0062 #define MBOX_GET_FC_AL_POSITION_MAP 0x0063 #define MBOX_GET_PORT_DB 0x0064 #define MBOX_CLEAR_ACA 0x0065 #define MBOX_TARGET_RESET 0x0066 #define MBOX_CLEAR_TASK_SET 0x0067 #define MBOX_ABORT_TASK_SET 0x0068 #define MBOX_GET_FW_STATE 0x0069 #define MBOX_GET_PORT_NAME 0x006A #define MBOX_GET_LINK_STATUS 0x006B #define MBOX_INIT_LIP_RESET 0x006C #define MBOX_GET_LINK_STAT_PR_DATA_CNT 0x006D #define MBOX_SEND_SNS 0x006E #define MBOX_FABRIC_LOGIN 0x006F #define MBOX_SEND_CHANGE_REQUEST 0x0070 #define MBOX_FABRIC_LOGOUT 0x0071 #define MBOX_INIT_LIP_LOGIN 0x0072 #define MBOX_GET_PORT_NODE_NAME_LIST 0x0075 #define MBOX_SET_VENDOR_ID 0x0076 #define MBOX_GET_XGMAC_STATS 0x007a #define MBOX_GET_ID_LIST 0x007C #define MBOX_SEND_LFA 0x007d #define MBOX_LUN_RESET 0x007E #define ISP2100_SET_PCI_PARAM 0x00ff #define MBOX_BUSY 0x04 /* * Mailbox Command Complete Status Codes */ #define MBOX_COMMAND_COMPLETE 0x4000 #define MBOX_INVALID_COMMAND 0x4001 #define MBOX_HOST_INTERFACE_ERROR 0x4002 #define MBOX_TEST_FAILED 0x4003 #define MBOX_COMMAND_ERROR 0x4005 #define MBOX_COMMAND_PARAM_ERROR 0x4006 #define MBOX_PORT_ID_USED 0x4007 #define MBOX_LOOP_ID_USED 0x4008 #define MBOX_ALL_IDS_USED 0x4009 #define MBOX_NOT_LOGGED_IN 0x400A #define MBOX_LINK_DOWN_ERROR 0x400B #define MBOX_LOOPBACK_ERROR 0x400C #define MBOX_CHECKSUM_ERROR 0x4010 #define MBOX_INVALID_PRODUCT_KEY 0x4020 /* pseudo mailbox completion codes */ #define MBOX_REGS_BUSY 0x6000 /* registers in use */ #define MBOX_TIMEOUT 0x6001 /* command timed out */ #define MBLOGALL 0xffffffff #define MBLOGNONE 0x00000000 #define MBLOGMASK(x) (1 << (((x) - 1) & 0x1f)) /* * Asynchronous event status codes */ #define ASYNC_BUS_RESET 0x8001 #define ASYNC_SYSTEM_ERROR 0x8002 #define ASYNC_RQS_XFER_ERR 0x8003 #define ASYNC_RSP_XFER_ERR 0x8004 #define ASYNC_QWAKEUP 0x8005 #define ASYNC_TIMEOUT_RESET 0x8006 #define ASYNC_DEVICE_RESET 0x8007 #define ASYNC_EXTMSG_UNDERRUN 0x800A #define ASYNC_SCAM_INT 0x800B #define ASYNC_HUNG_SCSI 0x800C #define ASYNC_KILLED_BUS 0x800D #define ASYNC_BUS_TRANSIT 0x800E /* LVD -> HVD, eg. */ #define ASYNC_LIP_OCCURRED 0x8010 /* FC only */ #define ASYNC_LOOP_UP 0x8011 #define ASYNC_LOOP_DOWN 0x8012 #define ASYNC_LOOP_RESET 0x8013 /* FC only */ #define ASYNC_PDB_CHANGED 0x8014 #define ASYNC_CHANGE_NOTIFY 0x8015 #define ASYNC_LIP_NOS_OLS_RECV 0x8016 /* FC only */ #define ASYNC_LIP_ERROR 0x8017 /* FC only */ #define ASYNC_AUTO_PLOGI_RJT 0x8018 #define ASYNC_SECURITY_UPDATE 0x801B #define ASYNC_CMD_CMPLT 0x8020 #define ASYNC_CTIO_DONE 0x8021 #define ASYNC_RIO32_1 0x8021 #define ASYNC_RIO32_2 0x8022 #define ASYNC_IP_XMIT_DONE 0x8022 #define ASYNC_IP_RECV_DONE 0x8023 #define ASYNC_IP_BROADCAST 0x8024 #define ASYNC_IP_RCVQ_LOW 0x8025 #define ASYNC_IP_RCVQ_EMPTY 0x8026 #define ASYNC_IP_RECV_DONE_ALIGNED 0x8027 #define ASYNC_ERR_LOGGING_DISABLED 0x8029 #define ASYNC_PTPMODE 0x8030 /* FC only */ #define ASYNC_RIO16_1 0x8031 #define ASYNC_RIO16_2 0x8032 #define ASYNC_RIO16_3 0x8033 #define ASYNC_RIO16_4 0x8034 #define ASYNC_RIO16_5 0x8035 #define ASYNC_CONNMODE 0x8036 #define ISP_CONN_LOOP 1 #define ISP_CONN_PTP 2 #define ISP_CONN_BADLIP 3 #define ISP_CONN_FATAL 4 #define ISP_CONN_LOOPBACK 5 #define ASYNC_P2P_INIT_ERR 0x8037 #define ASYNC_RIOZIO_STALL 0x8040 /* there's a RIO/ZIO entry that hasn't been serviced */ #define ASYNC_RIO32_2_2200 0x8042 /* same as ASYNC_RIO32_2, but for 2100/2200 */ #define ASYNC_RCV_ERR 0x8048 /* * 2.01.31 2200 Only. Need Bit 13 in Mailbox 1 for Set Firmware Options * mailbox command to enable this. */ #define ASYNC_QFULL_SENT 0x8049 #define ASYNC_RJT_SENT 0x8049 /* 24XX only */ #define ASYNC_SEL_CLASS2_P_RJT_SENT 0x804f #define ASYNC_FW_RESTART_COMPLETE 0x8060 #define ASYNC_TEMPERATURE_ALERT 0x8070 #define ASYNC_INTER_DRIVER_COMP 0x8100 /* FCoE only */ #define ASYNC_INTER_DRIVER_NOTIFY 0x8101 /* FCoE only */ #define ASYNC_INTER_DRIVER_TIME_EXT 0x8102 /* FCoE only */ #define ASYNC_TRANSCEIVER_INSERTION 0x8130 #define ASYNC_TRANSCEIVER_REMOVAL 0x8131 #define ASYNC_NIC_FW_STATE_CHANGE 0x8200 /* FCoE only */ #define ASYNC_AUTOLOAD_FW_COMPLETE 0x8400 #define ASYNC_AUTOLOAD_FW_FAILURE 0x8401 /* * Firmware Options. There are a lot of them. * * IFCOPTN - ISP Fibre Channel Option Word N */ #define IFCOPT1_EQFQASYNC (1 << 13) /* enable QFULL notification */ #define IFCOPT1_EAABSRCVD (1 << 12) #define IFCOPT1_RJTASYNC (1 << 11) /* enable 8018 notification */ #define IFCOPT1_ENAPURE (1 << 10) #define IFCOPT1_ENA8017 (1 << 7) #define IFCOPT1_DISGPIO67 (1 << 6) #define IFCOPT1_LIPLOSSIMM (1 << 5) #define IFCOPT1_DISF7SWTCH (1 << 4) #define IFCOPT1_CTIO_RETRY (1 << 3) #define IFCOPT1_LIPASYNC (1 << 1) #define IFCOPT1_LIPF8 (1 << 0) #define IFCOPT2_LOOPBACK (1 << 1) #define IFCOPT2_ATIO3_ONLY (1 << 0) #define IFCOPT3_NOPRLI (1 << 4) /* disable automatic sending of PRLI on local loops */ #define IFCOPT3_RNDASYNC (1 << 1) /* * All IOCB Queue entries are this size */ #define QENTRY_LEN 64 /* * Command Structure Definitions */ typedef struct { uint32_t ds_base; uint32_t ds_count; } ispds_t; typedef struct { uint32_t ds_base; uint32_t ds_basehi; uint32_t ds_count; } ispds64_t; #define DSTYPE_32BIT 0 #define DSTYPE_64BIT 1 typedef struct { uint16_t ds_type; /* 0-> ispds_t, 1-> ispds64_t */ uint32_t ds_segment; /* unused */ uint32_t ds_base; /* 32 bit address of DSD list */ } ispdslist_t; typedef struct { uint8_t rqs_entry_type; uint8_t rqs_entry_count; uint8_t rqs_seqno; uint8_t rqs_flags; } isphdr_t; /* RQS Flag definitions */ #define RQSFLAG_CONTINUATION 0x01 #define RQSFLAG_FULL 0x02 #define RQSFLAG_BADHEADER 0x04 #define RQSFLAG_BADPACKET 0x08 #define RQSFLAG_BADCOUNT 0x10 #define RQSFLAG_BADORDER 0x20 #define RQSFLAG_MASK 0x3f /* RQS entry_type definitions */ #define RQSTYPE_REQUEST 0x01 #define RQSTYPE_DATASEG 0x02 #define RQSTYPE_RESPONSE 0x03 #define RQSTYPE_MARKER 0x04 #define RQSTYPE_CMDONLY 0x05 #define RQSTYPE_ATIO 0x06 /* Target Mode */ #define RQSTYPE_CTIO 0x07 /* Target Mode */ #define RQSTYPE_SCAM 0x08 #define RQSTYPE_A64 0x09 #define RQSTYPE_A64_CONT 0x0a #define RQSTYPE_ENABLE_LUN 0x0b /* Target Mode */ #define RQSTYPE_MODIFY_LUN 0x0c /* Target Mode */ #define RQSTYPE_NOTIFY 0x0d /* Target Mode */ #define RQSTYPE_NOTIFY_ACK 0x0e /* Target Mode */ #define RQSTYPE_CTIO1 0x0f /* Target Mode */ #define RQSTYPE_STATUS_CONT 0x10 #define RQSTYPE_T2RQS 0x11 #define RQSTYPE_CTIO7 0x12 #define RQSTYPE_IP_XMIT 0x13 #define RQSTYPE_TSK_MGMT 0x14 #define RQSTYPE_T4RQS 0x15 #define RQSTYPE_ATIO2 0x16 /* Target Mode */ #define RQSTYPE_CTIO2 0x17 /* Target Mode */ #define RQSTYPE_T7RQS 0x18 #define RQSTYPE_T3RQS 0x19 #define RQSTYPE_IP_XMIT_64 0x1b #define RQSTYPE_CTIO4 0x1e /* Target Mode */ #define RQSTYPE_CTIO3 0x1f /* Target Mode */ #define RQSTYPE_RIO1 0x21 #define RQSTYPE_RIO2 0x22 #define RQSTYPE_IP_RECV 0x23 #define RQSTYPE_IP_RECV_CONT 0x24 #define RQSTYPE_CT_PASSTHRU 0x29 #define RQSTYPE_MS_PASSTHRU 0x29 #define RQSTYPE_VP_CTRL 0x30 /* 24XX only */ #define RQSTYPE_VP_MODIFY 0x31 /* 24XX only */ #define RQSTYPE_RPT_ID_ACQ 0x32 /* 24XX only */ #define RQSTYPE_ABORT_IO 0x33 #define RQSTYPE_T6RQS 0x48 #define RQSTYPE_LOGIN 0x52 #define RQSTYPE_ABTS_RCVD 0x54 /* 24XX only */ #define RQSTYPE_ABTS_RSP 0x55 /* 24XX only */ #define ISP_RQDSEG 4 typedef struct { isphdr_t req_header; uint32_t req_handle; uint8_t req_lun_trn; uint8_t req_target; uint16_t req_cdblen; uint16_t req_flags; uint16_t req_reserved; uint16_t req_time; uint16_t req_seg_count; uint8_t req_cdb[12]; ispds_t req_dataseg[ISP_RQDSEG]; } ispreq_t; #define ISP_RQDSEG_A64 2 typedef struct { isphdr_t mrk_header; uint32_t mrk_handle; uint8_t mrk_reserved0; uint8_t mrk_target; uint16_t mrk_modifier; uint16_t mrk_flags; uint16_t mrk_lun; uint8_t mrk_reserved1[48]; } isp_marker_t; typedef struct { isphdr_t mrk_header; uint32_t mrk_handle; uint16_t mrk_nphdl; uint8_t mrk_modifier; uint8_t mrk_reserved0; uint8_t mrk_reserved1; uint8_t mrk_vphdl; uint16_t mrk_reserved2; uint8_t mrk_lun[8]; uint8_t mrk_reserved3[40]; } isp_marker_24xx_t; #define SYNC_DEVICE 0 #define SYNC_TARGET 1 #define SYNC_ALL 2 #define SYNC_LIP 3 #define ISP_RQDSEG_T2 3 typedef struct { isphdr_t req_header; uint32_t req_handle; uint8_t req_lun_trn; uint8_t req_target; uint16_t req_scclun; uint16_t req_flags; uint8_t req_crn; uint8_t req_reserved; uint16_t req_time; uint16_t req_seg_count; uint8_t req_cdb[16]; uint32_t req_totalcnt; ispds_t req_dataseg[ISP_RQDSEG_T2]; } ispreqt2_t; typedef struct { isphdr_t req_header; uint32_t req_handle; uint16_t req_target; uint16_t req_scclun; uint16_t req_flags; uint8_t req_crn; uint8_t req_reserved; uint16_t req_time; uint16_t req_seg_count; uint8_t req_cdb[16]; uint32_t req_totalcnt; ispds_t req_dataseg[ISP_RQDSEG_T2]; } ispreqt2e_t; #define ISP_RQDSEG_T3 2 typedef struct { isphdr_t req_header; uint32_t req_handle; uint8_t req_lun_trn; uint8_t req_target; uint16_t req_scclun; uint16_t req_flags; uint8_t req_crn; uint8_t req_reserved; uint16_t req_time; uint16_t req_seg_count; uint8_t req_cdb[16]; uint32_t req_totalcnt; ispds64_t req_dataseg[ISP_RQDSEG_T3]; } ispreqt3_t; #define ispreq64_t ispreqt3_t /* same as.... */ typedef struct { isphdr_t req_header; uint32_t req_handle; uint16_t req_target; uint16_t req_scclun; uint16_t req_flags; uint8_t req_crn; uint8_t req_reserved; uint16_t req_time; uint16_t req_seg_count; uint8_t req_cdb[16]; uint32_t req_totalcnt; ispds64_t req_dataseg[ISP_RQDSEG_T3]; } ispreqt3e_t; /* req_flag values */ #define REQFLAG_NODISCON 0x0001 #define REQFLAG_HTAG 0x0002 #define REQFLAG_OTAG 0x0004 #define REQFLAG_STAG 0x0008 #define REQFLAG_TARGET_RTN 0x0010 #define REQFLAG_NODATA 0x0000 #define REQFLAG_DATA_IN 0x0020 #define REQFLAG_DATA_OUT 0x0040 #define REQFLAG_DATA_UNKNOWN 0x0060 #define REQFLAG_DISARQ 0x0100 #define REQFLAG_FRC_ASYNC 0x0200 #define REQFLAG_FRC_SYNC 0x0400 #define REQFLAG_FRC_WIDE 0x0800 #define REQFLAG_NOPARITY 0x1000 #define REQFLAG_STOPQ 0x2000 #define REQFLAG_XTRASNS 0x4000 #define REQFLAG_PRIORITY 0x8000 typedef struct { isphdr_t req_header; uint32_t req_handle; uint8_t req_lun_trn; uint8_t req_target; uint16_t req_cdblen; uint16_t req_flags; uint16_t req_reserved; uint16_t req_time; uint16_t req_seg_count; uint8_t req_cdb[44]; } ispextreq_t; /* * ISP24XX structures */ typedef struct { isphdr_t req_header; uint32_t req_handle; uint16_t req_nphdl; uint16_t req_time; uint16_t req_seg_count; uint16_t req_reserved; uint8_t req_lun[8]; uint8_t req_alen_datadir; uint8_t req_task_management; uint8_t req_task_attribute; uint8_t req_crn; uint8_t req_cdb[16]; uint32_t req_dl; uint16_t req_tidlo; uint8_t req_tidhi; uint8_t req_vpidx; ispds64_t req_dataseg; } ispreqt7_t; /* Task Management Request Function */ typedef struct { isphdr_t tmf_header; uint32_t tmf_handle; uint16_t tmf_nphdl; uint8_t tmf_reserved0[2]; uint16_t tmf_delay; uint16_t tmf_timeout; uint8_t tmf_lun[8]; uint32_t tmf_flags; uint8_t tmf_reserved1[20]; uint16_t tmf_tidlo; uint8_t tmf_tidhi; uint8_t tmf_vpidx; uint8_t tmf_reserved2[12]; } isp24xx_tmf_t; #define ISP24XX_TMF_NOSEND 0x80000000 #define ISP24XX_TMF_LUN_RESET 0x00000010 #define ISP24XX_TMF_ABORT_TASK_SET 0x00000008 #define ISP24XX_TMF_CLEAR_TASK_SET 0x00000004 #define ISP24XX_TMF_TARGET_RESET 0x00000002 #define ISP24XX_TMF_CLEAR_ACA 0x00000001 /* I/O Abort Structure */ typedef struct { isphdr_t abrt_header; uint32_t abrt_handle; uint16_t abrt_nphdl; uint16_t abrt_options; uint32_t abrt_cmd_handle; uint16_t abrt_queue_number; uint8_t abrt_reserved[30]; uint16_t abrt_tidlo; uint8_t abrt_tidhi; uint8_t abrt_vpidx; uint8_t abrt_reserved1[12]; } isp24xx_abrt_t; #define ISP24XX_ABRT_NOSEND 0x01 /* don't actually send ABTS */ #define ISP24XX_ABRT_OKAY 0x00 /* in nphdl on return */ #define ISP24XX_ABRT_ENXIO 0x31 /* in nphdl on return */ #define ISP_CDSEG 7 typedef struct { isphdr_t req_header; uint32_t req_reserved; ispds_t req_dataseg[ISP_CDSEG]; } ispcontreq_t; #define ISP_CDSEG64 5 typedef struct { isphdr_t req_header; ispds64_t req_dataseg[ISP_CDSEG64]; } ispcontreq64_t; typedef struct { isphdr_t req_header; uint32_t req_handle; uint16_t req_scsi_status; uint16_t req_completion_status; uint16_t req_state_flags; uint16_t req_status_flags; uint16_t req_time; #define req_response_len req_time /* FC only */ uint16_t req_sense_len; uint32_t req_resid; uint8_t req_response[8]; /* FC only */ uint8_t req_sense_data[32]; } ispstatusreq_t; /* * Status Continuation */ typedef struct { isphdr_t req_header; uint8_t req_sense_data[60]; } ispstatus_cont_t; /* * 24XX Type 0 status */ typedef struct { isphdr_t req_header; uint32_t req_handle; uint16_t req_completion_status; uint16_t req_oxid; uint32_t req_resid; uint16_t req_reserved0; uint16_t req_state_flags; uint16_t req_retry_delay; /* aka Status Qualifier */ uint16_t req_scsi_status; uint32_t req_fcp_residual; uint32_t req_sense_len; uint32_t req_response_len; uint8_t req_rsp_sense[28]; } isp24xx_statusreq_t; /* * For Qlogic 2X00, the high order byte of SCSI status has * additional meaning. */ #define RQCS_CR 0x1000 /* Confirmation Request */ #define RQCS_RU 0x0800 /* Residual Under */ #define RQCS_RO 0x0400 /* Residual Over */ #define RQCS_RESID (RQCS_RU|RQCS_RO) #define RQCS_SV 0x0200 /* Sense Length Valid */ #define RQCS_RV 0x0100 /* FCP Response Length Valid */ /* * CT Passthru IOCB */ typedef struct { isphdr_t ctp_header; uint32_t ctp_handle; uint16_t ctp_status; uint16_t ctp_nphdl; /* n-port handle */ uint16_t ctp_cmd_cnt; /* Command DSD count */ uint8_t ctp_vpidx; uint8_t ctp_reserved0; uint16_t ctp_time; uint16_t ctp_reserved1; uint16_t ctp_rsp_cnt; /* Response DSD count */ uint16_t ctp_reserved2[5]; uint32_t ctp_rsp_bcnt; /* Response byte count */ uint32_t ctp_cmd_bcnt; /* Command byte count */ ispds64_t ctp_dataseg[2]; } isp_ct_pt_t; /* * MS Passthru IOCB */ typedef struct { isphdr_t ms_header; uint32_t ms_handle; uint16_t ms_nphdl; /* handle in high byte for !2k f/w */ uint16_t ms_status; uint16_t ms_flags; uint16_t ms_reserved1; /* low 8 bits */ uint16_t ms_time; uint16_t ms_cmd_cnt; /* Command DSD count */ uint16_t ms_tot_cnt; /* Total DSD Count */ uint8_t ms_type; /* MS type */ uint8_t ms_r_ctl; /* R_CTL */ uint16_t ms_rxid; /* RX_ID */ uint16_t ms_reserved2; uint32_t ms_handle2; uint32_t ms_rsp_bcnt; /* Response byte count */ uint32_t ms_cmd_bcnt; /* Command byte count */ ispds64_t ms_dataseg[2]; } isp_ms_t; /* * Completion Status Codes. */ #define RQCS_COMPLETE 0x0000 #define RQCS_DMA_ERROR 0x0002 #define RQCS_RESET_OCCURRED 0x0004 #define RQCS_ABORTED 0x0005 #define RQCS_TIMEOUT 0x0006 #define RQCS_DATA_OVERRUN 0x0007 #define RQCS_DATA_UNDERRUN 0x0015 #define RQCS_QUEUE_FULL 0x001C /* 1X00 Only Completion Codes */ #define RQCS_INCOMPLETE 0x0001 #define RQCS_TRANSPORT_ERROR 0x0003 #define RQCS_COMMAND_OVERRUN 0x0008 #define RQCS_STATUS_OVERRUN 0x0009 #define RQCS_BAD_MESSAGE 0x000a #define RQCS_NO_MESSAGE_OUT 0x000b #define RQCS_EXT_ID_FAILED 0x000c #define RQCS_IDE_MSG_FAILED 0x000d #define RQCS_ABORT_MSG_FAILED 0x000e #define RQCS_REJECT_MSG_FAILED 0x000f #define RQCS_NOP_MSG_FAILED 0x0010 #define RQCS_PARITY_ERROR_MSG_FAILED 0x0011 #define RQCS_DEVICE_RESET_MSG_FAILED 0x0012 #define RQCS_ID_MSG_FAILED 0x0013 #define RQCS_UNEXP_BUS_FREE 0x0014 #define RQCS_XACT_ERR1 0x0018 #define RQCS_XACT_ERR2 0x0019 #define RQCS_XACT_ERR3 0x001A #define RQCS_BAD_ENTRY 0x001B #define RQCS_PHASE_SKIPPED 0x001D #define RQCS_ARQS_FAILED 0x001E #define RQCS_WIDE_FAILED 0x001F #define RQCS_SYNCXFER_FAILED 0x0020 #define RQCS_LVD_BUSERR 0x0021 /* 2X00 Only Completion Codes */ #define RQCS_PORT_UNAVAILABLE 0x0028 #define RQCS_PORT_LOGGED_OUT 0x0029 #define RQCS_PORT_CHANGED 0x002A #define RQCS_PORT_BUSY 0x002B /* 24XX Only Completion Codes */ #define RQCS_24XX_DRE 0x0011 /* data reassembly error */ #define RQCS_24XX_TABORT 0x0013 /* aborted by target */ #define RQCS_24XX_ENOMEM 0x002C /* f/w resource unavailable */ #define RQCS_24XX_TMO 0x0030 /* task management overrun */ /* * 1X00 specific State Flags */ #define RQSF_GOT_BUS 0x0100 #define RQSF_GOT_TARGET 0x0200 #define RQSF_SENT_CDB 0x0400 #define RQSF_XFRD_DATA 0x0800 #define RQSF_GOT_STATUS 0x1000 #define RQSF_GOT_SENSE 0x2000 #define RQSF_XFER_COMPLETE 0x4000 /* * 2X00 specific State Flags * (same as 1X00 except RQSF_GOT_BUS/RQSF_GOT_TARGET are not available) */ #define RQSF_DATA_IN 0x0020 #define RQSF_DATA_OUT 0x0040 #define RQSF_STAG 0x0008 #define RQSF_OTAG 0x0004 #define RQSF_HTAG 0x0002 /* * 1X00 Status Flags */ #define RQSTF_DISCONNECT 0x0001 #define RQSTF_SYNCHRONOUS 0x0002 #define RQSTF_PARITY_ERROR 0x0004 #define RQSTF_BUS_RESET 0x0008 #define RQSTF_DEVICE_RESET 0x0010 #define RQSTF_ABORTED 0x0020 #define RQSTF_TIMEOUT 0x0040 #define RQSTF_NEGOTIATION 0x0080 /* * 2X00 specific state flags */ /* RQSF_SENT_CDB */ /* RQSF_XFRD_DATA */ /* RQSF_GOT_STATUS */ /* RQSF_XFER_COMPLETE */ /* * 2X00 specific status flags */ /* RQSTF_ABORTED */ /* RQSTF_TIMEOUT */ #define RQSTF_DMA_ERROR 0x0080 #define RQSTF_LOGOUT 0x2000 /* * Miscellaneous */ #ifndef ISP_EXEC_THROTTLE #define ISP_EXEC_THROTTLE 16 #endif /* * About Firmware returns an 'attribute' word in mailbox 6. * These attributes are for 2200 and 2300. */ #define ISP_FW_ATTR_TMODE 0x0001 #define ISP_FW_ATTR_SCCLUN 0x0002 #define ISP_FW_ATTR_FABRIC 0x0004 #define ISP_FW_ATTR_CLASS2 0x0008 #define ISP_FW_ATTR_FCTAPE 0x0010 #define ISP_FW_ATTR_IP 0x0020 #define ISP_FW_ATTR_VI 0x0040 #define ISP_FW_ATTR_VI_SOLARIS 0x0080 #define ISP_FW_ATTR_2KLOGINS 0x0100 /* just a guess... */ /* and these are for the 2400 */ #define ISP2400_FW_ATTR_CLASS2 0x0001 #define ISP2400_FW_ATTR_IP 0x0002 #define ISP2400_FW_ATTR_MULTIID 0x0004 #define ISP2400_FW_ATTR_SB2 0x0008 #define ISP2400_FW_ATTR_T10CRC 0x0010 #define ISP2400_FW_ATTR_VI 0x0020 #define ISP2400_FW_ATTR_MQ 0x0040 #define ISP2400_FW_ATTR_MSIX 0x0080 #define ISP2400_FW_ATTR_FCOE 0x0800 #define ISP2400_FW_ATTR_VP0 0x1000 #define ISP2400_FW_ATTR_EXPFW 0x2000 #define ISP2400_FW_ATTR_HOTFW 0x4000 #define ISP2400_FW_ATTR_EXTNDED 0x8000 #define ISP2400_FW_ATTR_EXTVP 0x00010000 #define ISP2400_FW_ATTR_VN2VN 0x00040000 #define ISP2400_FW_ATTR_EXMOFF 0x00080000 #define ISP2400_FW_ATTR_NPMOFF 0x00100000 #define ISP2400_FW_ATTR_DIFCHOP 0x00400000 #define ISP2400_FW_ATTR_SRIOV 0x02000000 #define ISP2400_FW_ATTR_ASICTMP 0x0200000000 #define ISP2400_FW_ATTR_ATIOMQ 0x0400000000 /* * These are either manifestly true or are dependent on f/w attributes */ #define ISP_CAP_TMODE(isp) \ (IS_24XX(isp)? 1 : (isp->isp_fwattr & ISP_FW_ATTR_TMODE)) #define ISP_CAP_SCCFW(isp) \ (IS_24XX(isp)? 1 : (isp->isp_fwattr & ISP_FW_ATTR_SCCLUN)) #define ISP_CAP_2KLOGIN(isp) \ (IS_24XX(isp)? 1 : (isp->isp_fwattr & ISP_FW_ATTR_2KLOGINS)) /* * This is only true for 24XX cards with this f/w attribute */ #define ISP_CAP_MULTI_ID(isp) \ (IS_24XX(isp)? (isp->isp_fwattr & ISP2400_FW_ATTR_MULTIID) : 0) #define ISP_GET_VPIDX(isp, tag) \ (ISP_CAP_MULTI_ID(isp) ? tag : 0) #define ISP_CAP_MSIX(isp) \ (IS_24XX(isp)? (isp->isp_fwattr & ISP2400_FW_ATTR_MSIX) : 0) #define ISP_CAP_VP0(isp) \ (IS_24XX(isp)? (isp->isp_fwattr & ISP2400_FW_ATTR_VP0) : 0) /* * This is true manifestly or is dependent on a f/w attribute * but may or may not actually be *enabled*. In any case, it * is enabled on a per-channel basis. */ #define ISP_CAP_FCTAPE(isp) \ (IS_24XX(isp)? 1 : (isp->isp_fwattr & ISP_FW_ATTR_FCTAPE)) #define ISP_FCTAPE_ENABLED(isp, chan) \ (IS_24XX(isp)? (FCPARAM(isp, chan)->isp_xfwoptions & ICB2400_OPT2_FCTAPE) != 0 : (FCPARAM(isp, chan)->isp_xfwoptions & ICBXOPT_FCTAPE) != 0) /* * Reduced Interrupt Operation Response Queue Entries */ typedef struct { isphdr_t req_header; uint32_t req_handles[15]; } isp_rio1_t; typedef struct { isphdr_t req_header; uint16_t req_handles[30]; } isp_rio2_t; /* * FC (ISP2100/ISP2200/ISP2300/ISP2400) specific data structures */ /* * Initialization Control Block * * Version One (prime) format. */ typedef struct { uint8_t icb_version; uint8_t icb_reserved0; uint16_t icb_fwoptions; uint16_t icb_maxfrmlen; uint16_t icb_maxalloc; uint16_t icb_execthrottle; uint8_t icb_retry_count; uint8_t icb_retry_delay; uint8_t icb_portname[8]; uint16_t icb_hardaddr; uint8_t icb_iqdevtype; uint8_t icb_logintime; uint8_t icb_nodename[8]; uint16_t icb_rqstout; uint16_t icb_rspnsin; uint16_t icb_rqstqlen; uint16_t icb_rsltqlen; uint16_t icb_rqstaddr[4]; uint16_t icb_respaddr[4]; uint16_t icb_lunenables; uint8_t icb_ccnt; uint8_t icb_icnt; uint16_t icb_lunetimeout; uint16_t icb_reserved1; uint16_t icb_xfwoptions; uint8_t icb_racctimer; uint8_t icb_idelaytimer; uint16_t icb_zfwoptions; uint16_t icb_reserved2[13]; } isp_icb_t; #define ICB_VERSION1 1 #define ICBOPT_EXTENDED 0x8000 #define ICBOPT_BOTH_WWNS 0x4000 #define ICBOPT_FULL_LOGIN 0x2000 #define ICBOPT_STOP_ON_QFULL 0x1000 /* 2200/2100 only */ #define ICBOPT_PREV_ADDRESS 0x0800 #define ICBOPT_SRCHDOWN 0x0400 #define ICBOPT_NOLIP 0x0200 #define ICBOPT_PDBCHANGE_AE 0x0100 #define ICBOPT_TGT_TYPE 0x0080 #define ICBOPT_INI_ADISC 0x0040 #define ICBOPT_INI_DISABLE 0x0020 #define ICBOPT_TGT_ENABLE 0x0010 #define ICBOPT_FAST_POST 0x0008 #define ICBOPT_FULL_DUPLEX 0x0004 #define ICBOPT_FAIRNESS 0x0002 #define ICBOPT_HARD_ADDRESS 0x0001 #define ICBXOPT_NO_LOGOUT 0x8000 /* no logout on link failure */ #define ICBXOPT_FCTAPE_CCQ 0x4000 /* FC-Tape Command Queueing */ #define ICBXOPT_FCTAPE_CONFIRM 0x2000 #define ICBXOPT_FCTAPE 0x1000 #define ICBXOPT_CLASS2_ACK0 0x0200 #define ICBXOPT_CLASS2 0x0100 #define ICBXOPT_NO_PLAY 0x0080 /* don't play if can't get hard addr */ #define ICBXOPT_TOPO_MASK 0x0070 #define ICBXOPT_LOOP_ONLY 0x0000 #define ICBXOPT_PTP_ONLY 0x0010 #define ICBXOPT_LOOP_2_PTP 0x0020 #define ICBXOPT_PTP_2_LOOP 0x0030 /* * The lower 4 bits of the xfwoptions field are the OPERATION MODE bits. * RIO is not defined for the 23XX cards (just 2200) */ #define ICBXOPT_RIO_OFF 0 #define ICBXOPT_RIO_16BIT 1 #define ICBXOPT_RIO_32BIT 2 #define ICBXOPT_RIO_16BIT_IOCB 3 #define ICBXOPT_RIO_32BIT_IOCB 4 #define ICBXOPT_ZIO 5 #define ICBXOPT_TIMER_MASK 0x7 #define ICBZOPT_RATE_MASK 0xC000 #define ICBZOPT_RATE_1GB 0x0000 #define ICBZOPT_RATE_AUTO 0x8000 #define ICBZOPT_RATE_2GB 0x4000 #define ICBZOPT_50_OHM 0x2000 #define ICBZOPT_NO_LOCAL_PLOGI 0x0080 #define ICBZOPT_ENA_OOF 0x0040 /* out of order frame handling */ #define ICBZOPT_RSPSZ_MASK 0x0030 #define ICBZOPT_RSPSZ_24 0x0000 #define ICBZOPT_RSPSZ_12 0x0010 #define ICBZOPT_RSPSZ_24A 0x0020 #define ICBZOPT_RSPSZ_32 0x0030 #define ICBZOPT_SOFTID 0x0002 #define ICBZOPT_ENA_RDXFR_RDY 0x0001 /* 2400 F/W options */ #define ICB2400_OPT1_BOTH_WWNS 0x00004000 #define ICB2400_OPT1_FULL_LOGIN 0x00002000 #define ICB2400_OPT1_PREV_ADDRESS 0x00000800 #define ICB2400_OPT1_SRCHDOWN 0x00000400 #define ICB2400_OPT1_NOLIP 0x00000200 #define ICB2400_OPT1_INI_DISABLE 0x00000020 #define ICB2400_OPT1_TGT_ENABLE 0x00000010 #define ICB2400_OPT1_FULL_DUPLEX 0x00000004 #define ICB2400_OPT1_FAIRNESS 0x00000002 #define ICB2400_OPT1_HARD_ADDRESS 0x00000001 #define ICB2400_OPT2_ENA_ATIOMQ 0x08000000 #define ICB2400_OPT2_ENA_IHA 0x04000000 #define ICB2400_OPT2_QOS 0x02000000 #define ICB2400_OPT2_IOCBS 0x01000000 #define ICB2400_OPT2_ENA_IHR 0x00400000 #define ICB2400_OPT2_ENA_VMS 0x00200000 #define ICB2400_OPT2_ENA_TA 0x00100000 #define ICB2400_OPT2_TPRLIC 0x00004000 #define ICB2400_OPT2_FCTAPE 0x00001000 #define ICB2400_OPT2_FCSP 0x00000800 #define ICB2400_OPT2_CLASS2_ACK0 0x00000200 #define ICB2400_OPT2_CLASS2 0x00000100 #define ICB2400_OPT2_NO_PLAY 0x00000080 #define ICB2400_OPT2_TOPO_MASK 0x00000070 #define ICB2400_OPT2_LOOP_ONLY 0x00000000 #define ICB2400_OPT2_PTP_ONLY 0x00000010 #define ICB2400_OPT2_LOOP_2_PTP 0x00000020 #define ICB2400_OPT2_TIMER_MASK 0x0000000f #define ICB2400_OPT2_ZIO 0x00000005 #define ICB2400_OPT2_ZIO1 0x00000006 #define ICB2400_OPT3_NO_CTXDIS 0x40000000 #define ICB2400_OPT3_ENA_ETH_RESP 0x08000000 #define ICB2400_OPT3_ENA_ETH_ATIO 0x04000000 #define ICB2400_OPT3_ENA_MFCF 0x00020000 #define ICB2400_OPT3_SKIP_4GB 0x00010000 #define ICB2400_OPT3_RATE_MASK 0x0000E000 #define ICB2400_OPT3_RATE_1GB 0x00000000 #define ICB2400_OPT3_RATE_2GB 0x00002000 #define ICB2400_OPT3_RATE_AUTO 0x00004000 #define ICB2400_OPT3_RATE_4GB 0x00006000 #define ICB2400_OPT3_RATE_8GB 0x00008000 #define ICB2400_OPT3_RATE_16GB 0x0000A000 #define ICB2400_OPT3_RATE_32GB 0x0000C000 #define ICB2400_OPT3_ENA_OOF_XFRDY 0x00000200 #define ICB2400_OPT3_NO_N2N_LOGI 0x00000100 #define ICB2400_OPT3_NO_LOCAL_PLOGI 0x00000080 #define ICB2400_OPT3_ENA_OOF 0x00000040 /* note that a response size flag of zero is reserved! */ #define ICB2400_OPT3_RSPSZ_MASK 0x00000030 #define ICB2400_OPT3_RSPSZ_12 0x00000010 #define ICB2400_OPT3_RSPSZ_24 0x00000020 #define ICB2400_OPT3_RSPSZ_32 0x00000030 #define ICB2400_OPT3_SOFTID 0x00000002 #define ICB_MIN_FRMLEN 256 #define ICB_MAX_FRMLEN 2112 #define ICB_DFLT_FRMLEN 1024 #define ICB_DFLT_ALLOC 256 #define ICB_DFLT_THROTTLE 16 #define ICB_DFLT_RDELAY 5 #define ICB_DFLT_RCOUNT 3 #define ICB_LOGIN_TOV 10 #define ICB_LUN_ENABLE_TOV 15 /* * And somebody at QLogic had a great idea that you could just change * the structure *and* keep the version number the same as the other cards. */ typedef struct { uint16_t icb_version; uint16_t icb_reserved0; uint16_t icb_maxfrmlen; uint16_t icb_execthrottle; uint16_t icb_xchgcnt; uint16_t icb_hardaddr; uint8_t icb_portname[8]; uint8_t icb_nodename[8]; uint16_t icb_rspnsin; uint16_t icb_rqstout; uint16_t icb_retry_count; uint16_t icb_priout; uint16_t icb_rsltqlen; uint16_t icb_rqstqlen; uint16_t icb_ldn_nols; uint16_t icb_prqstqlen; uint16_t icb_rqstaddr[4]; uint16_t icb_respaddr[4]; uint16_t icb_priaddr[4]; uint16_t icb_msixresp; uint16_t icb_msixatio; uint16_t icb_reserved1[2]; uint16_t icb_atio_in; uint16_t icb_atioqlen; uint16_t icb_atioqaddr[4]; uint16_t icb_idelaytimer; uint16_t icb_logintime; uint32_t icb_fwoptions1; uint32_t icb_fwoptions2; uint32_t icb_fwoptions3; uint16_t icb_qos; uint16_t icb_reserved2[3]; uint16_t icb_enodemac[3]; uint16_t icb_disctime; uint16_t icb_reserved3[4]; } isp_icb_2400_t; #define RQRSP_ADDR0015 0 #define RQRSP_ADDR1631 1 #define RQRSP_ADDR3247 2 #define RQRSP_ADDR4863 3 #define ICB_NNM0 7 #define ICB_NNM1 6 #define ICB_NNM2 5 #define ICB_NNM3 4 #define ICB_NNM4 3 #define ICB_NNM5 2 #define ICB_NNM6 1 #define ICB_NNM7 0 #define MAKE_NODE_NAME_FROM_WWN(array, wwn) \ array[ICB_NNM0] = (uint8_t) ((wwn >> 0) & 0xff), \ array[ICB_NNM1] = (uint8_t) ((wwn >> 8) & 0xff), \ array[ICB_NNM2] = (uint8_t) ((wwn >> 16) & 0xff), \ array[ICB_NNM3] = (uint8_t) ((wwn >> 24) & 0xff), \ array[ICB_NNM4] = (uint8_t) ((wwn >> 32) & 0xff), \ array[ICB_NNM5] = (uint8_t) ((wwn >> 40) & 0xff), \ array[ICB_NNM6] = (uint8_t) ((wwn >> 48) & 0xff), \ array[ICB_NNM7] = (uint8_t) ((wwn >> 56) & 0xff) #define MAKE_WWN_FROM_NODE_NAME(wwn, array) \ wwn = ((uint64_t) array[ICB_NNM0]) | \ ((uint64_t) array[ICB_NNM1] << 8) | \ ((uint64_t) array[ICB_NNM2] << 16) | \ ((uint64_t) array[ICB_NNM3] << 24) | \ ((uint64_t) array[ICB_NNM4] << 32) | \ ((uint64_t) array[ICB_NNM5] << 40) | \ ((uint64_t) array[ICB_NNM6] << 48) | \ ((uint64_t) array[ICB_NNM7] << 56) /* * For MULTI_ID firmware, this describes a * virtual port entity for getting status. */ typedef struct { uint16_t vp_port_status; uint8_t vp_port_options; uint8_t vp_port_loopid; uint8_t vp_port_portname[8]; uint8_t vp_port_nodename[8]; uint16_t vp_port_portid_lo; /* not present when trailing icb */ uint16_t vp_port_portid_hi; /* not present when trailing icb */ } vp_port_info_t; #define ICB2400_VPOPT_ENA_SNSLOGIN 0x00000040 /* Enable SNS Login and SCR for Virtual Ports */ #define ICB2400_VPOPT_TGT_DISABLE 0x00000020 /* Target Mode Disabled */ #define ICB2400_VPOPT_INI_ENABLE 0x00000010 /* Initiator Mode Enabled */ #define ICB2400_VPOPT_ENABLED 0x00000008 /* VP Enabled */ #define ICB2400_VPOPT_NOPLAY 0x00000004 /* ID Not Acquired */ #define ICB2400_VPOPT_PREV_ADDRESS 0x00000002 /* Previously Assigned ID */ #define ICB2400_VPOPT_HARD_ADDRESS 0x00000001 /* Hard Assigned ID */ #define ICB2400_VPOPT_WRITE_SIZE 20 /* * For MULTI_ID firmware, we append this structure * to the isp_icb_2400_t above, followed by a list * structures that are *most* of the vp_port_info_t. */ typedef struct { uint16_t vp_count; uint16_t vp_global_options; } isp_icb_2400_vpinfo_t; #define ICB2400_VPINFO_OFF 0x80 /* offset from start of ICB */ #define ICB2400_VPINFO_PORT_OFF(chan) \ (ICB2400_VPINFO_OFF + \ sizeof (isp_icb_2400_vpinfo_t) + ((chan) * ICB2400_VPOPT_WRITE_SIZE)) #define ICB2400_VPGOPT_FCA 0x01 /* Assume Clean Address bit in FLOGI ACC set (works only in static configurations) */ #define ICB2400_VPGOPT_MID_DISABLE 0x02 /* when set, connection mode2 will work with NPIV-capable switched */ #define ICB2400_VPGOPT_VP0_DECOUPLE 0x04 /* Allow VP0 decoupling if firmware supports it */ #define ICB2400_VPGOPT_SUSP_FDISK 0x10 /* Suspend FDISC for Enabled VPs */ #define ICB2400_VPGOPT_GEN_RIDA 0x20 /* Generate RIDA if FLOGI Fails */ typedef struct { isphdr_t vp_ctrl_hdr; uint32_t vp_ctrl_handle; uint16_t vp_ctrl_index_fail; uint16_t vp_ctrl_status; uint16_t vp_ctrl_command; uint16_t vp_ctrl_vp_count; uint16_t vp_ctrl_idmap[16]; uint16_t vp_ctrl_reserved[7]; uint16_t vp_ctrl_fcf_index; } vp_ctrl_info_t; #define VP_CTRL_CMD_ENABLE_VP 0x00 #define VP_CTRL_CMD_DISABLE_VP 0x08 #define VP_CTRL_CMD_DISABLE_VP_REINIT_LINK 0x09 #define VP_CTRL_CMD_DISABLE_VP_LOGO 0x0A #define VP_CTRL_CMD_DISABLE_VP_LOGO_ALL 0x0B /* * We can use this structure for modifying either one or two VP ports after initialization */ typedef struct { isphdr_t vp_mod_hdr; uint32_t vp_mod_hdl; uint16_t vp_mod_reserved0; uint16_t vp_mod_status; uint8_t vp_mod_cmd; uint8_t vp_mod_cnt; uint8_t vp_mod_idx0; uint8_t vp_mod_idx1; struct { uint8_t options; uint8_t loopid; uint16_t reserved1; uint8_t wwpn[8]; uint8_t wwnn[8]; } vp_mod_ports[2]; uint8_t vp_mod_reserved2[8]; } vp_modify_t; #define VP_STS_OK 0x00 #define VP_STS_ERR 0x01 #define VP_CNT_ERR 0x02 #define VP_GEN_ERR 0x03 #define VP_IDX_ERR 0x04 #define VP_STS_BSY 0x05 #define VP_MODIFY 0x00 #define VP_MODIFY_ENA 0x01 #define VP_MODIFY_OPT 0x02 #define VP_RESUME 0x03 /* * Port Data Base Element */ typedef struct { uint16_t pdb_options; uint8_t pdb_mstate; uint8_t pdb_sstate; uint8_t pdb_hardaddr_bits[4]; uint8_t pdb_portid_bits[4]; uint8_t pdb_nodename[8]; uint8_t pdb_portname[8]; uint16_t pdb_execthrottle; uint16_t pdb_exec_count; uint8_t pdb_retry_count; uint8_t pdb_retry_delay; uint16_t pdb_resalloc; uint16_t pdb_curalloc; uint16_t pdb_qhead; uint16_t pdb_qtail; uint16_t pdb_tl_next; uint16_t pdb_tl_last; uint16_t pdb_features; /* PLOGI, Common Service */ uint16_t pdb_pconcurrnt; /* PLOGI, Common Service */ uint16_t pdb_roi; /* PLOGI, Common Service */ uint8_t pdb_target; uint8_t pdb_initiator; /* PLOGI, Class 3 Control Flags */ uint16_t pdb_rdsiz; /* PLOGI, Class 3 */ uint16_t pdb_ncseq; /* PLOGI, Class 3 */ uint16_t pdb_noseq; /* PLOGI, Class 3 */ uint16_t pdb_labrtflg; uint16_t pdb_lstopflg; uint16_t pdb_sqhead; uint16_t pdb_sqtail; uint16_t pdb_ptimer; uint16_t pdb_nxt_seqid; uint16_t pdb_fcount; uint16_t pdb_prli_len; uint16_t pdb_prli_svc0; uint16_t pdb_prli_svc3; uint16_t pdb_loopid; uint16_t pdb_il_ptr; uint16_t pdb_sl_ptr; } isp_pdb_21xx_t; #define PDB_OPTIONS_XMITTING (1<<11) #define PDB_OPTIONS_LNKXMIT (1<<10) #define PDB_OPTIONS_ABORTED (1<<9) #define PDB_OPTIONS_ADISC (1<<1) #define PDB_STATE_DISCOVERY 0 #define PDB_STATE_WDISC_ACK 1 #define PDB_STATE_PLOGI 2 #define PDB_STATE_PLOGI_ACK 3 #define PDB_STATE_PRLI 4 #define PDB_STATE_PRLI_ACK 5 #define PDB_STATE_LOGGED_IN 6 #define PDB_STATE_PORT_UNAVAIL 7 #define PDB_STATE_PRLO 8 #define PDB_STATE_PRLO_ACK 9 #define PDB_STATE_PLOGO 10 #define PDB_STATE_PLOG_ACK 11 #define SVC3_ROLE_MASK 0x30 #define SVC3_ROLE_SHIFT 4 #define BITS2WORD(x) ((x)[0] << 16 | (x)[3] << 8 | (x)[2]) #define BITS2WORD_24XX(x) ((x)[0] << 16 | (x)[1] << 8 | (x)[2]) /* * Port Data Base Element- 24XX cards */ typedef struct { uint16_t pdb_flags; uint8_t pdb_curstate; uint8_t pdb_laststate; uint8_t pdb_hardaddr_bits[4]; uint8_t pdb_portid_bits[4]; #define pdb_nxt_seqid_2400 pdb_portid_bits[3] uint16_t pdb_retry_timer; uint16_t pdb_handle; uint16_t pdb_rcv_dsize; uint16_t pdb_reserved0; uint16_t pdb_prli_svc0; uint16_t pdb_prli_svc3; uint8_t pdb_portname[8]; uint8_t pdb_nodename[8]; uint8_t pdb_reserved1[24]; } isp_pdb_24xx_t; #define PDB2400_TID_SUPPORTED 0x4000 #define PDB2400_FC_TAPE 0x0080 #define PDB2400_CLASS2_ACK0 0x0040 #define PDB2400_FCP_CONF 0x0020 #define PDB2400_CLASS2 0x0010 #define PDB2400_ADDR_VALID 0x0002 #define PDB2400_STATE_PLOGI_PEND 0x03 #define PDB2400_STATE_PLOGI_DONE 0x04 #define PDB2400_STATE_PRLI_PEND 0x05 #define PDB2400_STATE_LOGGED_IN 0x06 #define PDB2400_STATE_PORT_UNAVAIL 0x07 #define PDB2400_STATE_PRLO_PEND 0x09 #define PDB2400_STATE_LOGO_PEND 0x0B /* * Common elements from the above two structures that are actually useful to us. */ typedef struct { uint16_t handle; + uint16_t prli_word0; uint16_t prli_word3; uint32_t : 8, portid : 24; uint8_t portname[8]; uint8_t nodename[8]; } isp_pdb_t; /* * Port/Node Name List Element */ typedef struct { uint8_t pnnle_name[8]; uint16_t pnnle_handle; uint16_t pnnle_reserved; } isp_pnnle_t; #define PNNL_OPTIONS_NODE_NAMES (1<<0) #define PNNL_OPTIONS_PORT_DATA (1<<2) #define PNNL_OPTIONS_INITIATORS (1<<3) /* * Port and N-Port Handle List Element */ typedef struct { uint16_t pnhle_port_id_lo; uint16_t pnhle_port_id_hi_handle; } isp_pnhle_21xx_t; typedef struct { uint16_t pnhle_port_id_lo; uint16_t pnhle_port_id_hi; uint16_t pnhle_handle; } isp_pnhle_23xx_t; typedef struct { uint16_t pnhle_port_id_lo; uint16_t pnhle_port_id_hi; uint16_t pnhle_handle; uint16_t pnhle_reserved; } isp_pnhle_24xx_t; /* * Port Database Changed Async Event information for 24XX cards */ /* N-Port Handle */ #define PDB24XX_AE_GLOBAL 0xFFFF /* Reason Codes */ #define PDB24XX_AE_OK 0x00 #define PDB24XX_AE_IMPL_LOGO_1 0x01 #define PDB24XX_AE_IMPL_LOGO_2 0x02 #define PDB24XX_AE_IMPL_LOGO_3 0x03 #define PDB24XX_AE_PLOGI_RCVD 0x04 #define PDB24XX_AE_PLOGI_RJT 0x05 #define PDB24XX_AE_PRLI_RCVD 0x06 #define PDB24XX_AE_PRLI_RJT 0x07 #define PDB24XX_AE_TPRLO 0x08 #define PDB24XX_AE_TPRLO_RJT 0x09 #define PDB24XX_AE_PRLO_RCVD 0x0a #define PDB24XX_AE_LOGO_RCVD 0x0b #define PDB24XX_AE_TOPO_CHG 0x0c #define PDB24XX_AE_NPORT_CHG 0x0d #define PDB24XX_AE_FLOGI_RJT 0x0e #define PDB24XX_AE_BAD_FANN 0x0f #define PDB24XX_AE_FLOGI_TIMO 0x10 #define PDB24XX_AE_ABX_LOGO 0x11 #define PDB24XX_AE_PLOGI_DONE 0x12 #define PDB24XX_AE_PRLI_DONE 0x13 #define PDB24XX_AE_OPN_1 0x14 #define PDB24XX_AE_OPN_2 0x15 #define PDB24XX_AE_TXERR 0x16 #define PDB24XX_AE_FORCED_LOGO 0x17 #define PDB24XX_AE_DISC_TIMO 0x18 /* * Genericized Port Login/Logout software structure */ typedef struct { uint16_t handle; uint16_t channel; uint32_t flags : 8, portid : 24; } isp_plcmd_t; /* the flags to use are those for PLOGX_FLG_* below */ /* * ISP24XX- Login/Logout Port IOCB */ typedef struct { isphdr_t plogx_header; uint32_t plogx_handle; uint16_t plogx_status; uint16_t plogx_nphdl; uint16_t plogx_flags; uint16_t plogx_vphdl; /* low 8 bits */ uint16_t plogx_portlo; /* low 16 bits */ uint16_t plogx_rspsz_porthi; struct { uint16_t lo16; uint16_t hi16; } plogx_ioparm[11]; } isp_plogx_t; #define PLOGX_STATUS_OK 0x00 #define PLOGX_STATUS_UNAVAIL 0x28 #define PLOGX_STATUS_LOGOUT 0x29 #define PLOGX_STATUS_IOCBERR 0x31 #define PLOGX_IOCBERR_NOLINK 0x01 #define PLOGX_IOCBERR_NOIOCB 0x02 #define PLOGX_IOCBERR_NOXGHG 0x03 #define PLOGX_IOCBERR_FAILED 0x04 /* further info in IOPARM 1 */ #define PLOGX_IOCBERR_NOFABRIC 0x05 #define PLOGX_IOCBERR_NOTREADY 0x07 #define PLOGX_IOCBERR_NOLOGIN 0x09 /* further info in IOPARM 1 */ #define PLOGX_IOCBERR_NOPCB 0x0a #define PLOGX_IOCBERR_REJECT 0x18 /* further info in IOPARM 1 */ #define PLOGX_IOCBERR_EINVAL 0x19 /* further info in IOPARM 1 */ #define PLOGX_IOCBERR_PORTUSED 0x1a /* further info in IOPARM 1 */ #define PLOGX_IOCBERR_HNDLUSED 0x1b /* further info in IOPARM 1 */ #define PLOGX_IOCBERR_NOHANDLE 0x1c #define PLOGX_IOCBERR_NOFLOGI 0x1f /* further info in IOPARM 1 */ #define PLOGX_FLG_CMD_MASK 0xf #define PLOGX_FLG_CMD_PLOGI 0 #define PLOGX_FLG_CMD_PRLI 1 #define PLOGX_FLG_CMD_PDISC 2 #define PLOGX_FLG_CMD_LOGO 8 #define PLOGX_FLG_CMD_PRLO 9 #define PLOGX_FLG_CMD_TPRLO 10 #define PLOGX_FLG_COND_PLOGI 0x10 /* if with PLOGI */ #define PLOGX_FLG_IMPLICIT 0x10 /* if with LOGO, PRLO, TPRLO */ #define PLOGX_FLG_SKIP_PRLI 0x20 /* if with PLOGI */ #define PLOGX_FLG_IMPLICIT_LOGO_ALL 0x20 /* if with LOGO */ #define PLOGX_FLG_EXPLICIT_LOGO 0x40 /* if with LOGO */ #define PLOGX_FLG_COMMON_FEATURES 0x80 /* if with PLOGI */ #define PLOGX_FLG_FREE_NPHDL 0x80 /* if with with LOGO */ #define PLOGX_FLG_CLASS2 0x100 /* if with PLOGI */ #define PLOGX_FLG_FCP2_OVERRIDE 0x200 /* if with PRLOG, PRLI */ /* * Report ID Acquisistion (24XX multi-id firmware) */ typedef struct { isphdr_t ridacq_hdr; uint32_t ridacq_handle; uint8_t ridacq_vp_acquired; uint8_t ridacq_vp_setup; uint8_t ridacq_vp_index; uint8_t ridacq_vp_status; uint16_t ridacq_vp_port_lo; uint8_t ridacq_vp_port_hi; uint8_t ridacq_format; /* 0 or 1 */ uint16_t ridacq_map[8]; uint8_t ridacq_reserved1[32]; } isp_ridacq_t; #define RIDACQ_STS_COMPLETE 0 #define RIDACQ_STS_UNACQUIRED 1 #define RIDACQ_STS_CHANGED 2 #define RIDACQ_STS_SNS_TIMEOUT 3 #define RIDACQ_STS_SNS_REJECTED 4 #define RIDACQ_STS_SCR_TIMEOUT 5 #define RIDACQ_STS_SCR_REJECTED 6 /* * Simple Name Server Data Structures */ #define SNS_GA_NXT 0x100 #define SNS_GPN_ID 0x112 #define SNS_GNN_ID 0x113 #define SNS_GFT_ID 0x117 #define SNS_GFF_ID 0x11F #define SNS_GID_FT 0x171 #define SNS_GID_PT 0x1A1 #define SNS_RFT_ID 0x217 #define SNS_RSPN_ID 0x218 #define SNS_RFF_ID 0x21F #define SNS_RSNN_NN 0x239 typedef struct { uint16_t snscb_rblen; /* response buffer length (words) */ uint16_t snscb_reserved0; uint16_t snscb_addr[4]; /* response buffer address */ uint16_t snscb_sblen; /* subcommand buffer length (words) */ uint16_t snscb_reserved1; uint16_t snscb_data[]; /* variable data */ } sns_screq_t; /* Subcommand Request Structure */ typedef struct { uint16_t snscb_rblen; /* response buffer length (words) */ uint16_t snscb_reserved0; uint16_t snscb_addr[4]; /* response buffer address */ uint16_t snscb_sblen; /* subcommand buffer length (words) */ uint16_t snscb_reserved1; uint16_t snscb_cmd; uint16_t snscb_reserved2; uint32_t snscb_reserved3; uint32_t snscb_port; } sns_ga_nxt_req_t; #define SNS_GA_NXT_REQ_SIZE (sizeof (sns_ga_nxt_req_t)) typedef struct { /* Used for GFT_ID, GFF_ID, etc. */ uint16_t snscb_rblen; /* response buffer length (words) */ uint16_t snscb_reserved0; uint16_t snscb_addr[4]; /* response buffer address */ uint16_t snscb_sblen; /* subcommand buffer length (words) */ uint16_t snscb_reserved1; uint16_t snscb_cmd; uint16_t snscb_mword_div_2; uint32_t snscb_reserved3; uint32_t snscb_portid; } sns_gxx_id_req_t; #define SNS_GXX_ID_REQ_SIZE (sizeof (sns_gxx_id_req_t)) typedef struct { uint16_t snscb_rblen; /* response buffer length (words) */ uint16_t snscb_reserved0; uint16_t snscb_addr[4]; /* response buffer address */ uint16_t snscb_sblen; /* subcommand buffer length (words) */ uint16_t snscb_reserved1; uint16_t snscb_cmd; uint16_t snscb_mword_div_2; uint32_t snscb_reserved3; uint32_t snscb_fc4_type; } sns_gid_ft_req_t; #define SNS_GID_FT_REQ_SIZE (sizeof (sns_gid_ft_req_t)) typedef struct { uint16_t snscb_rblen; /* response buffer length (words) */ uint16_t snscb_reserved0; uint16_t snscb_addr[4]; /* response buffer address */ uint16_t snscb_sblen; /* subcommand buffer length (words) */ uint16_t snscb_reserved1; uint16_t snscb_cmd; uint16_t snscb_mword_div_2; uint32_t snscb_reserved3; uint8_t snscb_port_type; uint8_t snscb_domain; uint8_t snscb_area; uint8_t snscb_flags; } sns_gid_pt_req_t; #define SNS_GID_PT_REQ_SIZE (sizeof (sns_gid_pt_req_t)) typedef struct { uint16_t snscb_rblen; /* response buffer length (words) */ uint16_t snscb_reserved0; uint16_t snscb_addr[4]; /* response buffer address */ uint16_t snscb_sblen; /* subcommand buffer length (words) */ uint16_t snscb_reserved1; uint16_t snscb_cmd; uint16_t snscb_reserved2; uint32_t snscb_reserved3; uint32_t snscb_port; uint32_t snscb_fc4_types[8]; } sns_rft_id_req_t; #define SNS_RFT_ID_REQ_SIZE (sizeof (sns_rft_id_req_t)) typedef struct { ct_hdr_t snscb_cthdr; uint8_t snscb_port_type; uint8_t snscb_port_id[3]; uint8_t snscb_portname[8]; uint16_t snscb_data[]; /* variable data */ } sns_scrsp_t; /* Subcommand Response Structure */ typedef struct { ct_hdr_t snscb_cthdr; uint8_t snscb_port_type; uint8_t snscb_port_id[3]; uint8_t snscb_portname[8]; uint8_t snscb_pnlen; /* symbolic port name length */ uint8_t snscb_pname[255]; /* symbolic port name */ uint8_t snscb_nodename[8]; uint8_t snscb_nnlen; /* symbolic node name length */ uint8_t snscb_nname[255]; /* symbolic node name */ uint8_t snscb_ipassoc[8]; uint8_t snscb_ipaddr[16]; uint8_t snscb_svc_class[4]; uint8_t snscb_fc4_types[32]; uint8_t snscb_fpname[8]; uint8_t snscb_reserved; uint8_t snscb_hardaddr[3]; } sns_ga_nxt_rsp_t; /* Subcommand Response Structure */ #define SNS_GA_NXT_RESP_SIZE (sizeof (sns_ga_nxt_rsp_t)) typedef struct { ct_hdr_t snscb_cthdr; uint8_t snscb_wwn[8]; } sns_gxn_id_rsp_t; #define SNS_GXN_ID_RESP_SIZE (sizeof (sns_gxn_id_rsp_t)) typedef struct { ct_hdr_t snscb_cthdr; uint32_t snscb_fc4_types[8]; } sns_gft_id_rsp_t; #define SNS_GFT_ID_RESP_SIZE (sizeof (sns_gft_id_rsp_t)) typedef struct { ct_hdr_t snscb_cthdr; uint32_t snscb_fc4_features[32]; } sns_gff_id_rsp_t; #define SNS_GFF_ID_RESP_SIZE (sizeof (sns_gff_id_rsp_t)) typedef struct { /* Used for GID_FT, GID_PT, etc. */ ct_hdr_t snscb_cthdr; struct { uint8_t control; uint8_t portid[3]; } snscb_ports[1]; } sns_gid_xx_rsp_t; #define SNS_GID_XX_RESP_SIZE(x) ((sizeof (sns_gid_xx_rsp_t)) + ((x - 1) << 2)) /* * Other Misc Structures */ /* ELS Pass Through */ typedef struct { isphdr_t els_hdr; uint32_t els_handle; uint16_t els_status; uint16_t els_nphdl; uint16_t els_xmit_dsd_count; /* outgoing only */ uint8_t els_vphdl; uint8_t els_sof; uint32_t els_rxid; uint16_t els_recv_dsd_count; /* outgoing only */ uint8_t els_opcode; uint8_t els_reserved1; uint8_t els_did_lo; uint8_t els_did_mid; uint8_t els_did_hi; uint8_t els_reserved2; uint16_t els_reserved3; uint16_t els_ctl_flags; union { struct { uint32_t _els_bytecnt; uint32_t _els_subcode1; uint32_t _els_subcode2; uint8_t _els_reserved4[20]; } in; struct { uint32_t _els_recv_bytecnt; uint32_t _els_xmit_bytecnt; uint32_t _els_xmit_dsd_length; uint16_t _els_xmit_dsd_a1500; uint16_t _els_xmit_dsd_a3116; uint16_t _els_xmit_dsd_a4732; uint16_t _els_xmit_dsd_a6348; uint32_t _els_recv_dsd_length; uint16_t _els_recv_dsd_a1500; uint16_t _els_recv_dsd_a3116; uint16_t _els_recv_dsd_a4732; uint16_t _els_recv_dsd_a6348; } out; } inout; #define els_bytecnt inout.in._els_bytecnt #define els_subcode1 inout.in._els_subcode1 #define els_subcode2 inout.in._els_subcode2 #define els_reserved4 inout.in._els_reserved4 #define els_recv_bytecnt inout.out._els_recv_bytecnt #define els_xmit_bytecnt inout.out._els_xmit_bytecnt #define els_xmit_dsd_length inout.out._els_xmit_dsd_length #define els_xmit_dsd_a1500 inout.out._els_xmit_dsd_a1500 #define els_xmit_dsd_a3116 inout.out._els_xmit_dsd_a3116 #define els_xmit_dsd_a4732 inout.out._els_xmit_dsd_a4732 #define els_xmit_dsd_a6348 inout.out._els_xmit_dsd_a6348 #define els_recv_dsd_length inout.out._els_recv_dsd_length #define els_recv_dsd_a1500 inout.out._els_recv_dsd_a1500 #define els_recv_dsd_a3116 inout.out._els_recv_dsd_a3116 #define els_recv_dsd_a4732 inout.out._els_recv_dsd_a4732 #define els_recv_dsd_a6348 inout.out._els_recv_dsd_a6348 } els_t; /* * A handy package structure for running FC-SCSI commands internally */ typedef struct { uint16_t handle; uint16_t lun; uint32_t channel : 8, portid : 24; uint32_t timeout; union { struct { uint32_t data_length; uint32_t no_wait : 1, do_read : 1; uint8_t cdb[16]; void *data_ptr; } beg; struct { uint32_t data_residual; uint8_t status; uint8_t pad; uint16_t sense_length; uint8_t sense_data[32]; } end; } fcd; } isp_xcmd_t; /* * Target Mode related definitions */ #define QLTM_SENSELEN 18 /* non-FC cards only */ #define QLTM_SVALID 0x80 /* * Structure for Enable Lun and Modify Lun queue entries */ typedef struct { isphdr_t le_header; uint32_t le_reserved; uint8_t le_lun; uint8_t le_rsvd; uint8_t le_ops; /* Modify LUN only */ uint8_t le_tgt; /* Not for FC */ uint32_t le_flags; /* Not for FC */ uint8_t le_status; uint8_t le_reserved2; uint8_t le_cmd_count; uint8_t le_in_count; uint8_t le_cdb6len; /* Not for FC */ uint8_t le_cdb7len; /* Not for FC */ uint16_t le_timeout; uint16_t le_reserved3[20]; } lun_entry_t; /* * le_flags values */ #define LUN_TQAE 0x00000002 /* bit1 Tagged Queue Action Enable */ #define LUN_DSSM 0x01000000 /* bit24 Disable Sending SDP Message */ #define LUN_DISAD 0x02000000 /* bit25 Disable autodisconnect */ #define LUN_DM 0x40000000 /* bit30 Disconnects Mandatory */ /* * le_ops values */ #define LUN_CCINCR 0x01 /* increment command count */ #define LUN_CCDECR 0x02 /* decrement command count */ #define LUN_ININCR 0x40 /* increment immed. notify count */ #define LUN_INDECR 0x80 /* decrement immed. notify count */ /* * le_status values */ #define LUN_OK 0x01 /* we be rockin' */ #define LUN_ERR 0x04 /* request completed with error */ #define LUN_INVAL 0x06 /* invalid request */ #define LUN_NOCAP 0x16 /* can't provide requested capability */ #define LUN_ENABLED 0x3E /* LUN already enabled */ /* * Immediate Notify Entry structure */ #define IN_MSGLEN 8 /* 8 bytes */ #define IN_RSVDLEN 8 /* 8 words */ typedef struct { isphdr_t in_header; uint32_t in_reserved; uint8_t in_lun; /* lun */ uint8_t in_iid; /* initiator */ uint8_t in_reserved2; uint8_t in_tgt; /* target */ uint32_t in_flags; uint8_t in_status; uint8_t in_rsvd2; uint8_t in_tag_val; /* tag value */ uint8_t in_tag_type; /* tag type */ uint16_t in_seqid; /* sequence id */ uint8_t in_msg[IN_MSGLEN]; /* SCSI message bytes */ uint16_t in_reserved3[IN_RSVDLEN]; uint8_t in_sense[QLTM_SENSELEN];/* suggested sense data */ } in_entry_t; typedef struct { isphdr_t in_header; uint32_t in_reserved; uint8_t in_lun; /* lun */ uint8_t in_iid; /* initiator */ uint16_t in_scclun; uint32_t in_reserved2; uint16_t in_status; uint16_t in_task_flags; uint16_t in_seqid; /* sequence id */ } in_fcentry_t; typedef struct { isphdr_t in_header; uint32_t in_reserved; uint16_t in_iid; /* initiator */ uint16_t in_scclun; uint32_t in_reserved2; uint16_t in_status; uint16_t in_task_flags; uint16_t in_seqid; /* sequence id */ } in_fcentry_e_t; /* * Values for the in_status field */ #define IN_REJECT 0x0D /* Message Reject message received */ #define IN_RESET 0x0E /* Bus Reset occurred */ #define IN_NO_RCAP 0x16 /* requested capability not available */ #define IN_IDE_RECEIVED 0x33 /* Initiator Detected Error msg received */ #define IN_RSRC_UNAVAIL 0x34 /* resource unavailable */ #define IN_MSG_RECEIVED 0x36 /* SCSI message received */ #define IN_ABORT_TASK 0x20 /* task named in RX_ID is being aborted (FC) */ #define IN_PORT_LOGOUT 0x29 /* port has logged out (FC) */ #define IN_PORT_CHANGED 0x2A /* port changed */ #define IN_GLOBAL_LOGO 0x2E /* all ports logged out */ #define IN_NO_NEXUS 0x3B /* Nexus not established */ #define IN_SRR_RCVD 0x45 /* SRR received */ /* * Values for the in_task_flags field- should only get one at a time! */ #define TASK_FLAGS_RESERVED_MASK (0xe700) #define TASK_FLAGS_CLEAR_ACA (1<<14) #define TASK_FLAGS_TARGET_RESET (1<<13) #define TASK_FLAGS_LUN_RESET (1<<12) #define TASK_FLAGS_CLEAR_TASK_SET (1<<10) #define TASK_FLAGS_ABORT_TASK_SET (1<<9) /* * ISP24XX Immediate Notify */ typedef struct { isphdr_t in_header; uint32_t in_reserved; uint16_t in_nphdl; uint16_t in_reserved1; uint16_t in_flags; uint16_t in_srr_rxid; uint16_t in_status; uint8_t in_status_subcode; uint8_t in_fwhandle; uint32_t in_rxid; uint16_t in_srr_reloff_lo; uint16_t in_srr_reloff_hi; uint16_t in_srr_iu; uint16_t in_srr_oxid; /* * If bit 2 is set in in_flags, the N-Port and * handle tags are valid. If the received ELS is * a LOGO, then these tags contain the N Port ID * from the LOGO payload. If the received ELS * request is TPRLO, these tags contain the * Third Party Originator N Port ID. */ uint16_t in_nport_id_hi; #define in_prli_options in_nport_id_hi uint8_t in_nport_id_lo; uint8_t in_reserved3; uint16_t in_np_handle; uint8_t in_reserved4[12]; uint8_t in_reserved5; uint8_t in_vpidx; uint32_t in_reserved6; uint16_t in_portid_lo; uint8_t in_portid_hi; uint8_t in_reserved7; uint16_t in_reserved8; uint16_t in_oxid; } in_fcentry_24xx_t; #define IN24XX_FLAG_PUREX_IOCB 0x1 #define IN24XX_FLAG_GLOBAL_LOGOUT 0x2 #define IN24XX_FLAG_NPHDL_VALID 0x4 #define IN24XX_FLAG_N2N_PRLI 0x8 #define IN24XX_FLAG_PN_NN_VALID 0x10 #define IN24XX_LIP_RESET 0x0E #define IN24XX_LINK_RESET 0x0F #define IN24XX_PORT_LOGOUT 0x29 #define IN24XX_PORT_CHANGED 0x2A #define IN24XX_LINK_FAILED 0x2E #define IN24XX_SRR_RCVD 0x45 #define IN24XX_ELS_RCVD 0x46 /* * login-affectin ELS received- check * subcode for specific opcode */ /* * For f/w > 4.0.25, these offsets in the Immediate Notify contain * the WWNN/WWPN if the ELS is PLOGI, PDISC or ADISC. The WWN is in * Big Endian format. */ #define IN24XX_PRLI_WWNN_OFF 0x18 #define IN24XX_PRLI_WWPN_OFF 0x28 #define IN24XX_PLOGI_WWNN_OFF 0x20 #define IN24XX_PLOGI_WWPN_OFF 0x28 /* * For f/w > 4.0.25, this offset in the Immediate Notify contain * the WWPN if the ELS is LOGO. The WWN is in Big Endian format. */ #define IN24XX_LOGO_WWPN_OFF 0x28 /* * Immediate Notify Status Subcodes for IN24XX_PORT_LOGOUT */ #define IN24XX_PORT_LOGOUT_PDISC_TMO 0x00 #define IN24XX_PORT_LOGOUT_UXPR_DISC 0x01 #define IN24XX_PORT_LOGOUT_OWN_OPN 0x02 #define IN24XX_PORT_LOGOUT_OWN_OPN_SFT 0x03 #define IN24XX_PORT_LOGOUT_ABTS_TMO 0x04 #define IN24XX_PORT_LOGOUT_DISC_RJT 0x05 #define IN24XX_PORT_LOGOUT_LOGIN_NEEDED 0x06 #define IN24XX_PORT_LOGOUT_BAD_DISC 0x07 #define IN24XX_PORT_LOGOUT_LOST_ALPA 0x08 #define IN24XX_PORT_LOGOUT_XMIT_FAILURE 0x09 /* * Immediate Notify Status Subcodes for IN24XX_PORT_CHANGED */ #define IN24XX_PORT_CHANGED_BADFAN 0x00 #define IN24XX_PORT_CHANGED_TOPO_CHANGE 0x01 #define IN24XX_PORT_CHANGED_FLOGI_ACC 0x02 #define IN24XX_PORT_CHANGED_FLOGI_RJT 0x03 #define IN24XX_PORT_CHANGED_TIMEOUT 0x04 #define IN24XX_PORT_CHANGED_PORT_CHANGE 0x05 /* * Notify Acknowledge Entry structure */ #define NA_RSVDLEN 22 typedef struct { isphdr_t na_header; uint32_t na_reserved; uint8_t na_lun; /* lun */ uint8_t na_iid; /* initiator */ uint8_t na_reserved2; uint8_t na_tgt; /* target */ uint32_t na_flags; uint8_t na_status; uint8_t na_event; uint16_t na_seqid; /* sequence id */ uint16_t na_reserved3[NA_RSVDLEN]; } na_entry_t; /* * Value for the na_event field */ #define NA_RST_CLRD 0x80 /* Clear an async event notification */ #define NA_OK 0x01 /* Notify Acknowledge Succeeded */ #define NA_INVALID 0x06 /* Invalid Notify Acknowledge */ #define NA2_RSVDLEN 21 typedef struct { isphdr_t na_header; uint32_t na_reserved; uint8_t na_reserved1; uint8_t na_iid; /* initiator loop id */ uint16_t na_response; uint16_t na_flags; uint16_t na_reserved2; uint16_t na_status; uint16_t na_task_flags; uint16_t na_seqid; /* sequence id */ uint16_t na_reserved3[NA2_RSVDLEN]; } na_fcentry_t; typedef struct { isphdr_t na_header; uint32_t na_reserved; uint16_t na_iid; /* initiator loop id */ uint16_t na_response; /* response code */ uint16_t na_flags; uint16_t na_reserved2; uint16_t na_status; uint16_t na_task_flags; uint16_t na_seqid; /* sequence id */ uint16_t na_reserved3[NA2_RSVDLEN]; } na_fcentry_e_t; #define NAFC_RCOUNT 0x80 /* increment resource count */ #define NAFC_RST_CLRD 0x20 /* Clear LIP Reset */ #define NAFC_TVALID 0x10 /* task mangement response code is valid */ /* * ISP24XX Notify Acknowledge */ typedef struct { isphdr_t na_header; uint32_t na_handle; uint16_t na_nphdl; uint16_t na_reserved1; uint16_t na_flags; uint16_t na_srr_rxid; uint16_t na_status; uint8_t na_status_subcode; uint8_t na_fwhandle; uint32_t na_rxid; uint16_t na_srr_reloff_lo; uint16_t na_srr_reloff_hi; uint16_t na_srr_iu; uint16_t na_srr_flags; uint8_t na_reserved3[18]; uint8_t na_reserved4; uint8_t na_vpidx; uint8_t na_srr_reject_vunique; uint8_t na_srr_reject_explanation; uint8_t na_srr_reject_code; uint8_t na_reserved5; uint8_t na_reserved6[6]; uint16_t na_oxid; } na_fcentry_24xx_t; /* * Accept Target I/O Entry structure */ #define ATIO_CDBLEN 26 typedef struct { isphdr_t at_header; uint16_t at_reserved; uint16_t at_handle; uint8_t at_lun; /* lun */ uint8_t at_iid; /* initiator */ uint8_t at_cdblen; /* cdb length */ uint8_t at_tgt; /* target */ uint32_t at_flags; uint8_t at_status; /* firmware status */ uint8_t at_scsi_status; /* scsi status */ uint8_t at_tag_val; /* tag value */ uint8_t at_tag_type; /* tag type */ uint8_t at_cdb[ATIO_CDBLEN]; /* received CDB */ uint8_t at_sense[QLTM_SENSELEN];/* suggested sense data */ } at_entry_t; /* * at_flags values */ #define AT_NODISC 0x00008000 /* disconnect disabled */ #define AT_TQAE 0x00000002 /* Tagged Queue Action enabled */ /* * at_status values */ #define AT_PATH_INVALID 0x07 /* ATIO sent to firmware for disabled lun */ #define AT_RESET 0x0E /* SCSI Bus Reset Occurred */ #define AT_PHASE_ERROR 0x14 /* Bus phase sequence error */ #define AT_NOCAP 0x16 /* Requested capability not available */ #define AT_BDR_MSG 0x17 /* Bus Device Reset msg received */ #define AT_CDB 0x3D /* CDB received */ /* * Macros to create and fetch and test concatenated handle and tag value macros * (SPI only) */ #define AT_MAKE_TAGID(tid, aep) \ tid = aep->at_handle; \ if (aep->at_flags & AT_TQAE) { \ tid |= (aep->at_tag_val << 16); \ tid |= (1 << 24); \ } #define CT_MAKE_TAGID(tid, ct) \ tid = ct->ct_fwhandle; \ if (ct->ct_flags & CT_TQAE) { \ tid |= (ct->ct_tag_val << 16); \ tid |= (1 << 24); \ } #define AT_HAS_TAG(val) ((val) & (1 << 24)) #define AT_GET_TAG(val) (((val) >> 16) & 0xff) #define AT_GET_HANDLE(val) ((val) & 0xffff) #define IN_MAKE_TAGID(tid, inp) \ tid = inp->in_seqid; \ tid |= (inp->in_tag_val << 16); \ tid |= (1 << 24) /* * Accept Target I/O Entry structure, Type 2 */ #define ATIO2_CDBLEN 16 typedef struct { isphdr_t at_header; uint32_t at_reserved; uint8_t at_lun; /* lun or reserved */ uint8_t at_iid; /* initiator */ uint16_t at_rxid; /* response ID */ uint16_t at_flags; uint16_t at_status; /* firmware status */ uint8_t at_crn; /* command reference number */ uint8_t at_taskcodes; uint8_t at_taskflags; uint8_t at_execodes; uint8_t at_cdb[ATIO2_CDBLEN]; /* received CDB */ uint32_t at_datalen; /* allocated data len */ uint16_t at_scclun; /* SCC Lun or reserved */ uint16_t at_wwpn[4]; /* WWPN of initiator */ uint16_t at_reserved2[6]; uint16_t at_oxid; } at2_entry_t; typedef struct { isphdr_t at_header; uint32_t at_reserved; uint16_t at_iid; /* initiator */ uint16_t at_rxid; /* response ID */ uint16_t at_flags; uint16_t at_status; /* firmware status */ uint8_t at_crn; /* command reference number */ uint8_t at_taskcodes; uint8_t at_taskflags; uint8_t at_execodes; uint8_t at_cdb[ATIO2_CDBLEN]; /* received CDB */ uint32_t at_datalen; /* allocated data len */ uint16_t at_scclun; /* SCC Lun or reserved */ uint16_t at_wwpn[4]; /* WWPN of initiator */ uint16_t at_reserved2[6]; uint16_t at_oxid; } at2e_entry_t; #define ATIO2_WWPN_OFFSET 0x2A #define ATIO2_OXID_OFFSET 0x3E #define ATIO2_TC_ATTR_MASK 0x7 #define ATIO2_TC_ATTR_SIMPLEQ 0 #define ATIO2_TC_ATTR_HEADOFQ 1 #define ATIO2_TC_ATTR_ORDERED 2 #define ATIO2_TC_ATTR_ACAQ 4 #define ATIO2_TC_ATTR_UNTAGGED 5 #define ATIO2_EX_WRITE 0x1 #define ATIO2_EX_READ 0x2 /* * Macros to create and fetch and test concatenated handle and tag value macros */ #define AT2_MAKE_TAGID(tid, bus, inst, aep) \ tid = aep->at_rxid; \ tid |= (((uint64_t)inst) << 32); \ tid |= (((uint64_t)bus) << 48) #define CT2_MAKE_TAGID(tid, bus, inst, ct) \ tid = ct->ct_rxid; \ tid |= (((uint64_t)inst) << 32); \ tid |= (((uint64_t)(bus & 0xff)) << 48) #define AT2_HAS_TAG(val) 1 #define AT2_GET_TAG(val) ((val) & 0xffffffff) #define AT2_GET_INST(val) (((val) >> 32) & 0xffff) #define AT2_GET_HANDLE AT2_GET_TAG #define AT2_GET_BUS(val) (((val) >> 48) & 0xff) #define FC_HAS_TAG AT2_HAS_TAG #define FC_GET_TAG AT2_GET_TAG #define FC_GET_INST AT2_GET_INST #define FC_GET_HANDLE AT2_GET_HANDLE #define IN_FC_MAKE_TAGID(tid, bus, inst, seqid) \ tid = seqid; \ tid |= (((uint64_t)inst) << 32); \ tid |= (((uint64_t)(bus & 0xff)) << 48) #define FC_TAG_INSERT_INST(tid, inst) \ tid &= ~0x0000ffff00000000ull; \ tid |= (((uint64_t)inst) << 32) /* * 24XX ATIO Definition * * This is *quite* different from other entry types. * First of all, it has its own queue it comes in on. * * Secondly, it doesn't have a normal header. * * Thirdly, it's just a passthru of the FCP CMND IU * which is recorded in big endian mode. */ typedef struct { uint8_t at_type; uint8_t at_count; /* * Task attribute in high four bits, * the rest is the FCP CMND IU Length. * NB: the command can extend past the * length for a single queue entry. */ uint16_t at_ta_len; uint32_t at_rxid; fc_hdr_t at_hdr; fcp_cmnd_iu_t at_cmnd; } at7_entry_t; #define AT7_NORESRC_RXID 0xffffffff /* * Continue Target I/O Entry structure * Request from driver. The response from the * ISP firmware is the same except that the last 18 * bytes are overwritten by suggested sense data if * the 'autosense valid' bit is set in the status byte. */ typedef struct { isphdr_t ct_header; uint16_t ct_syshandle; uint16_t ct_fwhandle; /* required by f/w */ uint8_t ct_lun; /* lun */ uint8_t ct_iid; /* initiator id */ uint8_t ct_reserved2; uint8_t ct_tgt; /* our target id */ uint32_t ct_flags; uint8_t ct_status; /* isp status */ uint8_t ct_scsi_status; /* scsi status */ uint8_t ct_tag_val; /* tag value */ uint8_t ct_tag_type; /* tag type */ uint32_t ct_xfrlen; /* transfer length */ uint32_t ct_resid; /* residual length */ uint16_t ct_timeout; uint16_t ct_seg_count; ispds_t ct_dataseg[ISP_RQDSEG]; } ct_entry_t; /* * For some of the dual port SCSI adapters, port (bus #) is reported * in the MSbit of ct_iid. Bit fields are a bit too awkward here. * * Note that this does not apply to FC adapters at all which can and * do report IIDs between 0x81 && 0xfe (or 0x7ff) which represent devices * that have logged in across a SCSI fabric. */ #define GET_IID_VAL(x) (x & 0x3f) #define GET_BUS_VAL(x) ((x >> 7) & 0x1) #define SET_IID_VAL(y, x) y = ((y & ~0x3f) | (x & 0x3f)) #define SET_BUS_VAL(y, x) y = ((y & 0x3f) | ((x & 0x1) << 7)) /* * ct_flags values */ #define CT_TQAE 0x00000002 /* bit 1, Tagged Queue Action enable */ #define CT_DATA_IN 0x00000040 /* bits 6&7, Data direction - *to* initiator */ #define CT_DATA_OUT 0x00000080 /* bits 6&7, Data direction - *from* initiator */ #define CT_NO_DATA 0x000000C0 /* bits 6&7, Data direction */ #define CT_CCINCR 0x00000100 /* bit 8, autoincrement atio count */ #define CT_DATAMASK 0x000000C0 /* bits 6&7, Data direction */ #define CT_INISYNCWIDE 0x00004000 /* bit 14, Do Sync/Wide Negotiation */ #define CT_NODISC 0x00008000 /* bit 15, Disconnects disabled */ #define CT_DSDP 0x01000000 /* bit 24, Disable Save Data Pointers */ #define CT_SENDRDP 0x04000000 /* bit 26, Send Restore Pointers msg */ #define CT_SENDSTATUS 0x80000000 /* bit 31, Send SCSI status byte */ /* * ct_status values * - set by the firmware when it returns the CTIO */ #define CT_OK 0x01 /* completed without error */ #define CT_ABORTED 0x02 /* aborted by host */ #define CT_ERR 0x04 /* see sense data for error */ #define CT_INVAL 0x06 /* request for disabled lun */ #define CT_NOPATH 0x07 /* invalid ITL nexus */ #define CT_INVRXID 0x08 /* (FC only) Invalid RX_ID */ #define CT_DATA_OVER 0x09 /* (FC only) Data Overrun */ #define CT_RSELTMO 0x0A /* reselection timeout after 2 tries */ #define CT_TIMEOUT 0x0B /* timed out */ #define CT_RESET 0x0E /* SCSI Bus Reset occurred */ #define CT_PARITY 0x0F /* Uncorrectable Parity Error */ #define CT_BUS_ERROR 0x10 /* (FC Only) DMA PCI Error */ #define CT_PANIC 0x13 /* Unrecoverable Error */ #define CT_PHASE_ERROR 0x14 /* Bus phase sequence error */ #define CT_DATA_UNDER 0x15 /* (FC only) Data Underrun */ #define CT_BDR_MSG 0x17 /* Bus Device Reset msg received */ #define CT_TERMINATED 0x19 /* due to Terminate Transfer mbox cmd */ #define CT_PORTUNAVAIL 0x28 /* port not available */ #define CT_LOGOUT 0x29 /* port logout */ #define CT_PORTCHANGED 0x2A /* port changed */ #define CT_IDE 0x33 /* Initiator Detected Error */ #define CT_NOACK 0x35 /* Outstanding Immed. Notify. entry */ #define CT_SRR 0x45 /* SRR Received */ #define CT_LUN_RESET 0x48 /* Lun Reset Received */ #define CT_HBA_RESET 0xffff /* pseudo error - command destroyed by HBA reset*/ /* * When the firmware returns a CTIO entry, it may overwrite the last * part of the structure with sense data. This starts at offset 0x2E * into the entry, which is in the middle of ct_dataseg[1]. Rather * than define a new struct for this, I'm just using the sense data * offset. */ #define CTIO_SENSE_OFFSET 0x2E /* * Entry length in u_longs. All entries are the same size so * any one will do as the numerator. */ #define UINT32_ENTRY_SIZE (sizeof(at_entry_t)/sizeof(uint32_t)) /* * QLA2100 CTIO (type 2) entry */ #define MAXRESPLEN 26 typedef struct { isphdr_t ct_header; uint32_t ct_syshandle; uint8_t ct_lun; /* lun */ uint8_t ct_iid; /* initiator id */ uint16_t ct_rxid; /* response ID */ uint16_t ct_flags; uint16_t ct_status; /* isp status */ uint16_t ct_timeout; uint16_t ct_seg_count; uint32_t ct_reloff; /* relative offset */ uint32_t ct_resid; /* residual length */ union { /* * The three different modes that the target driver * can set the CTIO{2,3,4} up as. * * The first is for sending FCP_DATA_IUs as well as * (optionally) sending a terminal SCSI status FCP_RSP_IU. * * The second is for sending SCSI sense data in an FCP_RSP_IU. * Note that no FCP_DATA_IUs will be sent. * * The third is for sending FCP_RSP_IUs as built specifically * in system memory as located by the isp_dataseg. */ struct { uint32_t _reserved; uint16_t _reserved2; uint16_t ct_scsi_status; uint32_t ct_xfrlen; union { ispds_t ct_dataseg[ISP_RQDSEG_T2]; ispds64_t ct_dataseg64[ISP_RQDSEG_T3]; ispdslist_t ct_dslist; } u; } m0; struct { uint16_t _reserved; uint16_t _reserved2; uint16_t ct_senselen; uint16_t ct_scsi_status; uint16_t ct_resplen; uint8_t ct_resp[MAXRESPLEN]; } m1; struct { uint32_t _reserved; uint16_t _reserved2; uint16_t _reserved3; uint32_t ct_datalen; union { ispds_t ct_fcp_rsp_iudata_32; ispds64_t ct_fcp_rsp_iudata_64; } u; } m2; } rsp; } ct2_entry_t; typedef struct { isphdr_t ct_header; uint32_t ct_syshandle; uint16_t ct_iid; /* initiator id */ uint16_t ct_rxid; /* response ID */ uint16_t ct_flags; uint16_t ct_status; /* isp status */ uint16_t ct_timeout; uint16_t ct_seg_count; uint32_t ct_reloff; /* relative offset */ uint32_t ct_resid; /* residual length */ union { struct { uint32_t _reserved; uint16_t _reserved2; uint16_t ct_scsi_status; uint32_t ct_xfrlen; union { ispds_t ct_dataseg[ISP_RQDSEG_T2]; ispds64_t ct_dataseg64[ISP_RQDSEG_T3]; ispdslist_t ct_dslist; } u; } m0; struct { uint16_t _reserved; uint16_t _reserved2; uint16_t ct_senselen; uint16_t ct_scsi_status; uint16_t ct_resplen; uint8_t ct_resp[MAXRESPLEN]; } m1; struct { uint32_t _reserved; uint16_t _reserved2; uint16_t _reserved3; uint32_t ct_datalen; union { ispds_t ct_fcp_rsp_iudata_32; ispds64_t ct_fcp_rsp_iudata_64; } u; } m2; } rsp; } ct2e_entry_t; /* * ct_flags values for CTIO2 */ #define CT2_FLAG_MODE0 0x0000 #define CT2_FLAG_MODE1 0x0001 #define CT2_FLAG_MODE2 0x0002 #define CT2_FLAG_MMASK 0x0003 #define CT2_DATA_IN 0x0040 /* *to* initiator */ #define CT2_DATA_OUT 0x0080 /* *from* initiator */ #define CT2_NO_DATA 0x00C0 #define CT2_DATAMASK 0x00C0 #define CT2_CCINCR 0x0100 #define CT2_FASTPOST 0x0200 #define CT2_CONFIRM 0x2000 #define CT2_TERMINATE 0x4000 #define CT2_SENDSTATUS 0x8000 /* * ct_status values are (mostly) the same as that for ct_entry. */ /* * ct_scsi_status values- the low 8 bits are the normal SCSI status * we know and love. The upper 8 bits are validity markers for FCP_RSP_IU * fields. */ #define CT2_RSPLEN_VALID 0x0100 #define CT2_SNSLEN_VALID 0x0200 #define CT2_DATA_OVER 0x0400 #define CT2_DATA_UNDER 0x0800 /* * ISP24XX CTIO */ #define MAXRESPLEN_24XX 24 typedef struct { isphdr_t ct_header; uint32_t ct_syshandle; uint16_t ct_nphdl; /* status on returned CTIOs */ uint16_t ct_timeout; uint16_t ct_seg_count; uint8_t ct_vpidx; uint8_t ct_xflags; uint16_t ct_iid_lo; /* low 16 bits of portid */ uint8_t ct_iid_hi; /* hi 8 bits of portid */ uint8_t ct_reserved; uint32_t ct_rxid; uint16_t ct_senselen; /* mode 1 only */ uint16_t ct_flags; uint32_t ct_resid; /* residual length */ uint16_t ct_oxid; uint16_t ct_scsi_status; /* modes 0 && 1 only */ union { struct { uint32_t reloff; uint32_t reserved0; uint32_t ct_xfrlen; uint32_t reserved1; ispds64_t ds; } m0; struct { uint16_t ct_resplen; uint16_t reserved; uint8_t ct_resp[MAXRESPLEN_24XX]; } m1; struct { uint32_t reserved0; uint32_t reserved1; uint32_t ct_datalen; uint32_t reserved2; ispds64_t ct_fcp_rsp_iudata; } m2; } rsp; } ct7_entry_t; /* * ct_flags values for CTIO7 */ #define CT7_NO_DATA 0x0000 #define CT7_DATA_OUT 0x0001 /* *from* initiator */ #define CT7_DATA_IN 0x0002 /* *to* initiator */ #define CT7_DATAMASK 0x3 #define CT7_DSD_ENABLE 0x0004 #define CT7_CONF_STSFD 0x0010 #define CT7_EXPLCT_CONF 0x0020 #define CT7_FLAG_MODE0 0x0000 #define CT7_FLAG_MODE1 0x0040 #define CT7_FLAG_MODE2 0x0080 #define CT7_FLAG_MMASK 0x00C0 #define CT7_NOACK 0x0100 #define CT7_TASK_ATTR_SHIFT 9 #define CT7_CONFIRM 0x2000 #define CT7_TERMINATE 0x4000 #define CT7_SENDSTATUS 0x8000 /* * Type 7 CTIO status codes */ #define CT7_OK 0x01 /* completed without error */ #define CT7_ABORTED 0x02 /* aborted by host */ #define CT7_ERR 0x04 /* see sense data for error */ #define CT7_INVAL 0x06 /* request for disabled lun */ #define CT7_INVRXID 0x08 /* Invalid RX_ID */ #define CT7_DATA_OVER 0x09 /* Data Overrun */ #define CT7_TIMEOUT 0x0B /* timed out */ #define CT7_RESET 0x0E /* LIP Rset Received */ #define CT7_BUS_ERROR 0x10 /* DMA PCI Error */ #define CT7_REASSY_ERR 0x11 /* DMA reassembly error */ #define CT7_DATA_UNDER 0x15 /* Data Underrun */ #define CT7_PORTUNAVAIL 0x28 /* port not available */ #define CT7_LOGOUT 0x29 /* port logout */ #define CT7_PORTCHANGED 0x2A /* port changed */ #define CT7_SRR 0x45 /* SRR Received */ /* * Other 24XX related target IOCBs */ /* * ABTS Received */ typedef struct { isphdr_t abts_header; uint8_t abts_reserved0[6]; uint16_t abts_nphdl; uint16_t abts_reserved1; uint16_t abts_sof; uint32_t abts_rxid_abts; uint16_t abts_did_lo; uint8_t abts_did_hi; uint8_t abts_r_ctl; uint16_t abts_sid_lo; uint8_t abts_sid_hi; uint8_t abts_cs_ctl; uint16_t abts_fs_ctl; uint8_t abts_f_ctl; uint8_t abts_type; uint16_t abts_seq_cnt; uint8_t abts_df_ctl; uint8_t abts_seq_id; uint16_t abts_rx_id; uint16_t abts_ox_id; uint32_t abts_param; uint8_t abts_reserved2[16]; uint32_t abts_rxid_task; } abts_t; typedef struct { isphdr_t abts_rsp_header; uint32_t abts_rsp_handle; uint16_t abts_rsp_status; uint16_t abts_rsp_nphdl; uint16_t abts_rsp_ctl_flags; uint16_t abts_rsp_sof; uint32_t abts_rsp_rxid_abts; uint16_t abts_rsp_did_lo; uint8_t abts_rsp_did_hi; uint8_t abts_rsp_r_ctl; uint16_t abts_rsp_sid_lo; uint8_t abts_rsp_sid_hi; uint8_t abts_rsp_cs_ctl; uint16_t abts_rsp_f_ctl_lo; uint8_t abts_rsp_f_ctl_hi; uint8_t abts_rsp_type; uint16_t abts_rsp_seq_cnt; uint8_t abts_rsp_df_ctl; uint8_t abts_rsp_seq_id; uint16_t abts_rsp_rx_id; uint16_t abts_rsp_ox_id; uint32_t abts_rsp_param; union { struct { uint16_t reserved; uint8_t last_seq_id; uint8_t seq_id_valid; uint16_t aborted_rx_id; uint16_t aborted_ox_id; uint16_t high_seq_cnt; uint16_t low_seq_cnt; uint8_t reserved2[4]; } ba_acc; struct { uint8_t vendor_unique; uint8_t explanation; uint8_t reason; uint8_t reserved; uint8_t reserved2[12]; } ba_rjt; struct { uint8_t reserved[8]; uint32_t subcode1; uint32_t subcode2; } rsp; uint8_t reserved[16]; } abts_rsp_payload; uint32_t abts_rsp_rxid_task; } abts_rsp_t; /* terminate this ABTS exchange */ #define ISP24XX_ABTS_RSP_TERMINATE 0x01 #define ISP24XX_ABTS_RSP_COMPLETE 0x00 #define ISP24XX_ABTS_RSP_RESET 0x04 #define ISP24XX_ABTS_RSP_ABORTED 0x05 #define ISP24XX_ABTS_RSP_TIMEOUT 0x06 #define ISP24XX_ABTS_RSP_INVXID 0x08 #define ISP24XX_ABTS_RSP_LOGOUT 0x29 #define ISP24XX_ABTS_RSP_SUBCODE 0x31 #define ISP24XX_NO_TASK 0xffffffff /* * Miscellaneous * * These are the limits of the number of dma segments we * can deal with based not on the size of the segment counter * (which is 16 bits), but on the size of the number of * queue entries field (which is 8 bits). We assume no * segments in the first queue entry, so we can either * have 7 dma segments per continuation entry or 5 * (for 64 bit dma).. multiplying out by 254.... */ #define ISP_NSEG_MAX 1778 #define ISP_NSEG64_MAX 1270 #endif /* _ISPMBOX_H */ Index: head/sys/dev/isp/ispvar.h =================================================================== --- head/sys/dev/isp/ispvar.h (revision 345007) +++ head/sys/dev/isp/ispvar.h (revision 345008) @@ -1,1142 +1,1147 @@ /* $FreeBSD$ */ /*- * SPDX-License-Identifier: BSD-2-Clause-FreeBSD * * Copyright (c) 2009-2018 Alexander Motin * Copyright (c) 1997-2009 by Matthew Jacob * 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 AUTHOR AND CONTRIBUTORS ``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 AUTHOR OR CONTRIBUTORS 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. * */ /* * Soft Definitions for for Qlogic ISP SCSI adapters. */ #ifndef _ISPVAR_H #define _ISPVAR_H #if defined(__NetBSD__) || defined(__OpenBSD__) #include #include #endif #ifdef __FreeBSD__ #include #include #endif #ifdef __linux__ #include "isp_stds.h" #include "ispmbox.h" #endif #ifdef __svr4__ #include "isp_stds.h" #include "ispmbox.h" #endif #define ISP_CORE_VERSION_MAJOR 7 #define ISP_CORE_VERSION_MINOR 0 /* * Vector for bus specific code to provide specific services. */ typedef struct ispsoftc ispsoftc_t; struct ispmdvec { void (*dv_run_isr) (ispsoftc_t *); uint32_t (*dv_rd_reg) (ispsoftc_t *, int); void (*dv_wr_reg) (ispsoftc_t *, int, uint32_t); int (*dv_mbxdma) (ispsoftc_t *); int (*dv_dmaset) (ispsoftc_t *, XS_T *, void *); void (*dv_dmaclr) (ispsoftc_t *, XS_T *, uint32_t); int (*dv_irqsetup) (ispsoftc_t *); void (*dv_dregs) (ispsoftc_t *, const char *); const void * dv_ispfw; /* ptr to f/w */ uint16_t dv_conf1; uint16_t dv_clock; /* clock frequency */ }; /* * Overall parameters */ #define MAX_TARGETS 16 #ifndef MAX_FC_TARG #define MAX_FC_TARG 1024 #endif #define ISP_MAX_TARGETS(isp) (IS_FC(isp)? MAX_FC_TARG : MAX_TARGETS) #define ISP_MAX_LUNS(isp) (isp)->isp_maxluns #define ISP_MAX_IRQS 3 /* * Macros to access ISP registers through bus specific layers- * mostly wrappers to vector through the mdvec structure. */ #define ISP_RUN_ISR(isp) \ (*(isp)->isp_mdvec->dv_run_isr)(isp) #define ISP_READ(isp, reg) \ (*(isp)->isp_mdvec->dv_rd_reg)((isp), (reg)) #define ISP_WRITE(isp, reg, val) \ (*(isp)->isp_mdvec->dv_wr_reg)((isp), (reg), (val)) #define ISP_MBOXDMASETUP(isp) \ (*(isp)->isp_mdvec->dv_mbxdma)((isp)) #define ISP_DMASETUP(isp, xs, req) \ (*(isp)->isp_mdvec->dv_dmaset)((isp), (xs), (req)) #define ISP_DMAFREE(isp, xs, hndl) \ if ((isp)->isp_mdvec->dv_dmaclr) \ (*(isp)->isp_mdvec->dv_dmaclr)((isp), (xs), (hndl)) #define ISP_IRQSETUP(isp) \ (((isp)->isp_mdvec->dv_irqsetup) ? (*(isp)->isp_mdvec->dv_irqsetup)(isp) : 0) #define ISP_DUMPREGS(isp, m) \ if ((isp)->isp_mdvec->dv_dregs) (*(isp)->isp_mdvec->dv_dregs)((isp),(m)) #define ISP_SETBITS(isp, reg, val) \ (*(isp)->isp_mdvec->dv_wr_reg)((isp), (reg), ISP_READ((isp), (reg)) | (val)) #define ISP_CLRBITS(isp, reg, val) \ (*(isp)->isp_mdvec->dv_wr_reg)((isp), (reg), ISP_READ((isp), (reg)) & ~(val)) /* * The MEMORYBARRIER macro is defined per platform (to provide synchronization * on Request and Response Queues, Scratch DMA areas, and Registers) * * Defined Memory Barrier Synchronization Types */ #define SYNC_REQUEST 0 /* request queue synchronization */ #define SYNC_RESULT 1 /* result queue synchronization */ #define SYNC_SFORDEV 2 /* scratch, sync for ISP */ #define SYNC_SFORCPU 3 /* scratch, sync for CPU */ #define SYNC_REG 4 /* for registers */ #define SYNC_ATIOQ 5 /* atio result queue (24xx) */ #define SYNC_IFORDEV 6 /* synchrounous IOCB, sync for ISP */ #define SYNC_IFORCPU 7 /* synchrounous IOCB, sync for CPU */ /* * Request/Response Queue defines and macros. * The maximum is defined per platform (and can be based on board type). */ /* This is the size of a queue entry (request and response) */ #define QENTRY_LEN 64 /* Both request and result queue length must be a power of two */ #define RQUEST_QUEUE_LEN(x) MAXISPREQUEST(x) #ifdef ISP_TARGET_MODE #define RESULT_QUEUE_LEN(x) MAXISPREQUEST(x) #else #define RESULT_QUEUE_LEN(x) \ (((MAXISPREQUEST(x) >> 2) < 64)? 64 : MAXISPREQUEST(x) >> 2) #endif #define ISP_QUEUE_ENTRY(q, idx) (((uint8_t *)q) + ((idx) * QENTRY_LEN)) #define ISP_QUEUE_SIZE(n) ((n) * QENTRY_LEN) #define ISP_NXT_QENTRY(idx, qlen) (((idx) + 1) & ((qlen)-1)) #define ISP_QFREE(in, out, qlen) \ ((in == out)? (qlen - 1) : ((in > out)? \ ((qlen - 1) - (in - out)) : (out - in - 1))) #define ISP_QAVAIL(isp) \ ISP_QFREE(isp->isp_reqidx, isp->isp_reqodx, RQUEST_QUEUE_LEN(isp)) #define ISP_ADD_REQUEST(isp, nxti) \ MEMORYBARRIER(isp, SYNC_REQUEST, isp->isp_reqidx, QENTRY_LEN, -1); \ ISP_WRITE(isp, isp->isp_rqstinrp, nxti); \ isp->isp_reqidx = nxti #define ISP_SYNC_REQUEST(isp) \ MEMORYBARRIER(isp, SYNC_REQUEST, isp->isp_reqidx, QENTRY_LEN, -1); \ isp->isp_reqidx = ISP_NXT_QENTRY(isp->isp_reqidx, RQUEST_QUEUE_LEN(isp)); \ ISP_WRITE(isp, isp->isp_rqstinrp, isp->isp_reqidx) /* * SCSI Specific Host Adapter Parameters- per bus, per target */ typedef struct { uint32_t : 8, update : 1, sendmarker : 1, isp_req_ack_active_neg : 1, isp_data_line_active_neg: 1, isp_cmd_dma_burst_enable: 1, isp_data_dma_burst_enabl: 1, isp_fifo_threshold : 3, isp_ptisp : 1, isp_ultramode : 1, isp_diffmode : 1, isp_lvdmode : 1, isp_fast_mttr : 1, /* fast sram */ isp_initiator_id : 4, isp_async_data_setup : 4; uint16_t isp_selection_timeout; uint16_t isp_max_queue_depth; uint8_t isp_tag_aging; uint8_t isp_bus_reset_delay; uint8_t isp_retry_count; uint8_t isp_retry_delay; struct { uint32_t exc_throttle : 8, : 1, dev_enable : 1, /* ignored */ dev_update : 1, dev_refresh : 1, actv_offset : 4, goal_offset : 4, nvrm_offset : 4; uint8_t actv_period; /* current sync period */ uint8_t goal_period; /* goal sync period */ uint8_t nvrm_period; /* nvram sync period */ uint16_t actv_flags; /* current device flags */ uint16_t goal_flags; /* goal device flags */ uint16_t nvrm_flags; /* nvram device flags */ } isp_devparam[MAX_TARGETS]; } sdparam; /* * Device Flags */ #define DPARM_DISC 0x8000 #define DPARM_PARITY 0x4000 #define DPARM_WIDE 0x2000 #define DPARM_SYNC 0x1000 #define DPARM_TQING 0x0800 #define DPARM_ARQ 0x0400 #define DPARM_QFRZ 0x0200 #define DPARM_RENEG 0x0100 #define DPARM_NARROW 0x0080 #define DPARM_ASYNC 0x0040 #define DPARM_PPR 0x0020 #define DPARM_DEFAULT (0xFF00 & ~DPARM_QFRZ) #define DPARM_SAFE_DFLT (DPARM_DEFAULT & ~(DPARM_WIDE|DPARM_SYNC|DPARM_TQING)) /* technically, not really correct, as they need to be rated based upon clock */ #define ISP_80M_SYNCPARMS 0x0c09 #define ISP_40M_SYNCPARMS 0x0c0a #define ISP_20M_SYNCPARMS 0x0c0c #define ISP_20M_SYNCPARMS_1040 0x080c #define ISP_10M_SYNCPARMS 0x0c19 #define ISP_08M_SYNCPARMS 0x0c25 #define ISP_05M_SYNCPARMS 0x0c32 #define ISP_04M_SYNCPARMS 0x0c41 /* * Fibre Channel Specifics */ /* These are for non-2K Login Firmware cards */ #define FL_ID 0x7e /* FL_Port Special ID */ #define SNS_ID 0x80 /* SNS Server Special ID */ #define NPH_MAX 0xfe /* These are for 2K Login Firmware cards */ #define NPH_RESERVED 0x7F0 /* begin of reserved N-port handles */ #define NPH_MGT_ID 0x7FA /* Management Server Special ID */ #define NPH_SNS_ID 0x7FC /* SNS Server Special ID */ #define NPH_FABRIC_CTLR 0x7FD /* Fabric Controller (0xFFFFFD) */ #define NPH_FL_ID 0x7FE /* F Port Special ID (0xFFFFFE) */ #define NPH_IP_BCST 0x7FF /* IP Broadcast Special ID (0xFFFFFF) */ #define NPH_MAX_2K 0x800 /* * "Unassigned" handle to be used internally */ #define NIL_HANDLE 0xffff /* * Limit for devices on an arbitrated loop. */ #define LOCAL_LOOP_LIM 126 /* * Limit for (2K login) N-port handle amounts */ #define MAX_NPORT_HANDLE 2048 /* * Special Constants */ #define INI_NONE ((uint64_t) 0) #define ISP_NOCHAN 0xff /* * Special Port IDs */ #define MANAGEMENT_PORT_ID 0xFFFFFA #define SNS_PORT_ID 0xFFFFFC #define FABRIC_PORT_ID 0xFFFFFE #define PORT_ANY 0xFFFFFF #define PORT_NONE 0 #define VALID_PORT(port) (port != PORT_NONE && port != PORT_ANY) #define DOMAIN_CONTROLLER_BASE 0xFFFC00 #define DOMAIN_CONTROLLER_END 0xFFFCFF /* * Command Handles * * Most QLogic initiator or target have 32 bit handles associated with them. * We want to have a quick way to index back and forth between a local SCSI * command context and what the firmware is passing back to us. We also * want to avoid working on stale information. This structure handles both * at the expense of some local memory. * * The handle is architected thusly: * * 0 means "free handle" * bits 0..12 index commands * bits 13..15 bits index usage * bits 16..31 contain a rolling sequence * * */ typedef struct { void * cmd; /* associated command context */ uint32_t handle; /* handle associated with this command */ } isp_hdl_t; #define ISP_HANDLE_FREE 0x00000000 #define ISP_HANDLE_CMD_MASK 0x00001fff #define ISP_HANDLE_USAGE_MASK 0x0000e000 #define ISP_HANDLE_USAGE_SHIFT 13 #define ISP_H2HT(hdl) ((hdl & ISP_HANDLE_USAGE_MASK) >> ISP_HANDLE_USAGE_SHIFT) # define ISP_HANDLE_NONE 0 # define ISP_HANDLE_INITIATOR 1 # define ISP_HANDLE_TARGET 2 # define ISP_HANDLE_CTRL 3 #define ISP_HANDLE_SEQ_MASK 0xffff0000 #define ISP_HANDLE_SEQ_SHIFT 16 #define ISP_H2SEQ(hdl) ((hdl & ISP_HANDLE_SEQ_MASK) >> ISP_HANDLE_SEQ_SHIFT) #define ISP_VALID_HANDLE(c, hdl) \ ((ISP_H2HT(hdl) == ISP_HANDLE_INITIATOR || \ ISP_H2HT(hdl) == ISP_HANDLE_TARGET || \ ISP_H2HT(hdl) == ISP_HANDLE_CTRL) && \ ((hdl) & ISP_HANDLE_CMD_MASK) < (c)->isp_maxcmds && \ (hdl) == ((c)->isp_xflist[(hdl) & ISP_HANDLE_CMD_MASK].handle)) #define ISP_BAD_HANDLE_INDEX 0xffffffff /* * FC Port Database entry. * * It has a handle that the f/w uses to address commands to a device. * This handle's value may be assigned by the firmware (e.g., for local loop * devices) or by the driver (e.g., for fabric devices). * * It has a state. If the state if VALID, that means that we've logged into * the device. * * Local loop devices the firmware automatically performs PLOGI on for us * (which is why that handle is imposed upon us). Fabric devices we assign * a handle to and perform the PLOGI on. * * When a PORT DATABASE CHANGED asynchronous event occurs, we mark all VALID * entries as PROBATIONAL. This allows us, if policy says to, just keep track * of devices whose handles change but are otherwise the same device (and * thus keep 'target' constant). * * In any case, we search all possible local loop handles. For each one that * has a port database entity returned, we search for any PROBATIONAL entry * that matches it and update as appropriate. Otherwise, as a new entry, we * find room for it in the Port Database. We *try* and use the handle as the * index to put it into the Database, but that's just an optimization. We mark * the entry VALID and make sure that the target index is updated and correct. * * When we get done searching the local loop, we then search similarly for * a list of devices we've gotten from the fabric name controller (if we're * on a fabric). VALID marking is also done similarly. * * When all of this is done, we can march through the database and clean up * any entry that is still PROBATIONAL (these represent devices which have * departed). Then we're done and can resume normal operations. * * Negative invariants that we try and test for are: * * + There can never be two non-NIL entries with the same { Port, Node } WWN * duples. * * + There can never be two non-NIL entries with the same handle. */ typedef struct { /* * This is the handle that the firmware needs in order for us to * send commands to the device. For pre-24XX cards, this would be * the 'loopid'. */ uint16_t handle; /* + * PRLI word 0 contains the Establish Image Pair bit, which is + * important for knowing when to reset the CRN. + * * PRLI word 3 parameters contains role as well as other things. * * The state is the current state of this entry. * * The is_target is the current state of target on this port. * * The is_initiator is the current state of initiator on this port. * * Portid is obvious, as are node && port WWNs. The new_role and * new_portid is for when we are pending a change. */ + uint16_t prli_word0; /* PRLI parameters */ uint16_t prli_word3; /* PRLI parameters */ + uint16_t new_prli_word0; /* Incoming new PRLI parameters */ uint16_t new_prli_word3; /* Incoming new PRLI parameters */ uint16_t : 12, probational : 1, state : 3; uint32_t : 6, is_target : 1, is_initiator : 1, portid : 24; uint32_t : 8, new_portid : 24; uint64_t node_wwn; uint64_t port_wwn; uint32_t gone_timer; } fcportdb_t; #define FC_PORTDB_STATE_NIL 0 /* Empty DB slot */ #define FC_PORTDB_STATE_DEAD 1 /* Was valid, but no more. */ #define FC_PORTDB_STATE_CHANGED 2 /* Was valid, but changed. */ #define FC_PORTDB_STATE_NEW 3 /* Logged in, not announced. */ #define FC_PORTDB_STATE_ZOMBIE 4 /* Invalid, but announced. */ #define FC_PORTDB_STATE_VALID 5 /* Valid */ #define FC_PORTDB_TGT(isp, bus, pdb) (int)(lp - FCPARAM(isp, bus)->portdb) /* * FC card specific information * * This structure is replicated across multiple channels for multi-id * capapble chipsets, with some entities different on a per-channel basis. */ typedef struct { int isp_gbspeed; /* Connection speed */ int isp_linkstate; /* Link state */ int isp_fwstate; /* ISP F/W state */ int isp_loopstate; /* Loop State */ int isp_topo; /* Connection Type */ uint32_t : 4, fctape_enabled : 1, sendmarker : 1, role : 2, isp_portid : 24; /* S_ID */ uint16_t isp_fwoptions; uint16_t isp_xfwoptions; uint16_t isp_zfwoptions; uint16_t isp_loopid; /* hard loop id */ uint16_t isp_sns_hdl; /* N-port handle for SNS */ uint16_t isp_lasthdl; /* only valid for channel 0 */ uint16_t isp_maxalloc; uint16_t isp_fabric_params; uint16_t isp_login_hdl; /* Logging in handle */ uint8_t isp_retry_delay; uint8_t isp_retry_count; int isp_use_gft_id; /* Use GFT_ID */ int isp_use_gff_id; /* Use GFF_ID */ /* * Current active WWNN/WWPN */ uint64_t isp_wwnn; uint64_t isp_wwpn; /* * NVRAM WWNN/WWPN */ uint64_t isp_wwnn_nvram; uint64_t isp_wwpn_nvram; /* * Our Port Data Base */ fcportdb_t portdb[MAX_FC_TARG]; /* * Scratch DMA mapped in area to fetch Port Database stuff, etc. */ void * isp_scratch; XS_DMA_ADDR_T isp_scdma; uint8_t isp_scanscratch[ISP_FC_SCRLEN]; } fcparam; #define FW_CONFIG_WAIT 0 #define FW_WAIT_LINK 1 #define FW_WAIT_LOGIN 2 #define FW_READY 3 #define FW_LOSS_OF_SYNC 4 #define FW_ERROR 5 #define FW_REINIT 6 #define FW_NON_PART 7 #define LOOP_NIL 0 #define LOOP_HAVE_LINK 1 #define LOOP_HAVE_ADDR 2 #define LOOP_TESTING_LINK 3 #define LOOP_LTEST_DONE 4 #define LOOP_SCANNING_LOOP 5 #define LOOP_LSCAN_DONE 6 #define LOOP_SCANNING_FABRIC 7 #define LOOP_FSCAN_DONE 8 #define LOOP_SYNCING_PDB 9 #define LOOP_READY 10 #define TOPO_NL_PORT 0 #define TOPO_FL_PORT 1 #define TOPO_N_PORT 2 #define TOPO_F_PORT 3 #define TOPO_PTP_STUB 4 #define TOPO_IS_FABRIC(x) ((x) == TOPO_FL_PORT || (x) == TOPO_F_PORT) #define FCP_AL_DA_ALL 0xFF #define FCP_AL_PA(fcp) ((uint8_t)(fcp->isp_portid)) #define FCP_IS_DEST_ALPD(fcp, alpd) (FCP_AL_PA((fcp)) == FCP_AL_DA_ALL || FCP_AL_PA((fcp)) == alpd) /* * Soft Structure per host adapter */ struct ispsoftc { /* * Platform (OS) specific data */ struct isposinfo isp_osinfo; /* * Pointer to bus specific functions and data */ struct ispmdvec * isp_mdvec; /* * (Mostly) nonvolatile state. Board specific parameters * may contain some volatile state (e.g., current loop state). */ void * isp_param; /* type specific */ uint64_t isp_fwattr; /* firmware attributes */ uint16_t isp_fwrev[3]; /* Loaded F/W revision */ uint16_t isp_maxcmds; /* max possible I/O cmds */ uint8_t isp_type; /* HBA Chip Type */ uint8_t isp_revision; /* HBA Chip H/W Revision */ uint8_t isp_nirq; /* number of IRQs */ uint16_t isp_nchan; /* number of channels */ uint32_t isp_maxluns; /* maximum luns supported */ uint32_t isp_clock : 8, /* input clock */ : 5, isp_port : 1, /* 23XX/24XX only */ isp_bustype : 1, /* SBus or PCI */ isp_loaded_fw : 1, /* loaded firmware */ isp_dblev : 16; /* debug log mask */ uint32_t isp_confopts; /* config options */ uint32_t isp_rqstinrp; /* register for REQINP */ uint32_t isp_rqstoutrp; /* register for REQOUTP */ uint32_t isp_respinrp; /* register for RESINP */ uint32_t isp_respoutrp; /* register for RESOUTP */ /* * Volatile state */ volatile u_int isp_mboxbsy; /* mailbox command active */ volatile u_int isp_state; volatile mbreg_t isp_curmbx; /* currently active mailbox command */ volatile uint32_t isp_reqodx; /* index of last ISP pickup */ volatile uint32_t isp_reqidx; /* index of next request */ volatile uint32_t isp_residx; /* index of last ISP write */ volatile uint32_t isp_resodx; /* index of next result */ volatile uint32_t isp_atioodx; /* index of next ATIO */ volatile uint32_t isp_obits; /* mailbox command output */ volatile uint32_t isp_serno; /* rolling serial number */ volatile uint16_t isp_mboxtmp[MAX_MAILBOX]; volatile uint16_t isp_lastmbxcmd; /* last mbox command sent */ volatile uint16_t isp_seqno; /* running sequence number */ /* * Active commands are stored here, indexed by handle functions. */ isp_hdl_t *isp_xflist; isp_hdl_t *isp_xffree; /* * DMA mapped in area for synchronous IOCB requests. */ void * isp_iocb; XS_DMA_ADDR_T isp_iocb_dma; /* * request/result queue pointers and DMA handles for them. */ void * isp_rquest; void * isp_result; XS_DMA_ADDR_T isp_rquest_dma; XS_DMA_ADDR_T isp_result_dma; #ifdef ISP_TARGET_MODE /* for 24XX only */ void * isp_atioq; XS_DMA_ADDR_T isp_atioq_dma; #endif }; #define SDPARAM(isp, chan) (&((sdparam *)(isp)->isp_param)[(chan)]) #define FCPARAM(isp, chan) (&((fcparam *)(isp)->isp_param)[(chan)]) #define ISP_SET_SENDMARKER(isp, chan, val) \ if (IS_FC(isp)) { \ FCPARAM(isp, chan)->sendmarker = val; \ } else { \ SDPARAM(isp, chan)->sendmarker = val; \ } #define ISP_TST_SENDMARKER(isp, chan) \ (IS_FC(isp)? \ FCPARAM(isp, chan)->sendmarker != 0 : \ SDPARAM(isp, chan)->sendmarker != 0) /* * ISP Driver Run States */ #define ISP_NILSTATE 0 #define ISP_CRASHED 1 #define ISP_RESETSTATE 2 #define ISP_INITSTATE 3 #define ISP_RUNSTATE 4 /* * ISP Runtime Configuration Options */ #define ISP_CFG_FULL_DUPLEX 0x01 /* Full Duplex (Fibre Channel only) */ #define ISP_CFG_PORT_PREF 0x0e /* Mask for Port Prefs (all FC except 2100) */ #define ISP_CFG_PORT_DEF 0x00 /* prefer connection type from NVRAM */ #define ISP_CFG_LPORT_ONLY 0x02 /* insist on {N/F}L-Port connection */ #define ISP_CFG_NPORT_ONLY 0x04 /* insist on {N/F}-Port connection */ #define ISP_CFG_LPORT 0x06 /* prefer {N/F}L-Port connection */ #define ISP_CFG_NPORT 0x08 /* prefer {N/F}-Port connection */ #define ISP_CFG_1GB 0x10 /* force 1Gb connection (23XX only) */ #define ISP_CFG_2GB 0x20 /* force 2Gb connection (23XX only) */ #define ISP_CFG_NORELOAD 0x80 /* don't download f/w */ #define ISP_CFG_NONVRAM 0x40 /* ignore NVRAM */ #define ISP_CFG_NOFCTAPE 0x100 /* disable FC-Tape */ #define ISP_CFG_FCTAPE 0x200 /* enable FC-Tape */ #define ISP_CFG_OWNFSZ 0x400 /* override NVRAM frame size */ #define ISP_CFG_OWNLOOPID 0x800 /* override NVRAM loopid */ #define ISP_CFG_OWNEXCTHROTTLE 0x1000 /* override NVRAM execution throttle */ #define ISP_CFG_4GB 0x2000 /* force 4Gb connection (24XX only) */ #define ISP_CFG_8GB 0x4000 /* force 8Gb connection (25XX only) */ #define ISP_CFG_16GB 0x8000 /* force 16Gb connection (26XX only) */ #define ISP_CFG_32GB 0x10000 /* force 32Gb connection (27XX only) */ /* * For each channel, the outer layers should know what role that channel * will take: ISP_ROLE_NONE, ISP_ROLE_INITIATOR, ISP_ROLE_TARGET, * ISP_ROLE_BOTH. * * If you set ISP_ROLE_NONE, the cards will be reset, new firmware loaded, * NVRAM read, and defaults set, but any further initialization (e.g. * INITIALIZE CONTROL BLOCK commands for 2X00 cards) won't be done. * * If INITIATOR MODE isn't set, attempts to run commands will be stopped * at isp_start and completed with the equivalent of SELECTION TIMEOUT. * * If TARGET MODE is set, it doesn't mean that the rest of target mode support * needs to be enabled, or will even work. What happens with the 2X00 cards * here is that if you have enabled it with TARGET MODE as part of the ICB * options, but you haven't given the f/w any ram resources for ATIOs or * Immediate Notifies, the f/w just handles what it can and you never see * anything. Basically, it sends a single byte of data (the first byte, * which you can set as part of the INITIALIZE CONTROL BLOCK command) for * INQUIRY, and sends back QUEUE FULL status for any other command. * */ #define ISP_ROLE_NONE 0x0 #define ISP_ROLE_TARGET 0x1 #define ISP_ROLE_INITIATOR 0x2 #define ISP_ROLE_BOTH (ISP_ROLE_TARGET|ISP_ROLE_INITIATOR) #define ISP_ROLE_EITHER ISP_ROLE_BOTH #ifndef ISP_DEFAULT_ROLES /* * Counterintuitively, we prefer to default to role 'none' * if we are enable target mode support. This gives us the * maximum flexibility as to which port will do what. */ #ifdef ISP_TARGET_MODE #define ISP_DEFAULT_ROLES ISP_ROLE_NONE #else #define ISP_DEFAULT_ROLES ISP_ROLE_INITIATOR #endif #endif /* * Firmware related defines */ #define ISP_CODE_ORG 0x1000 /* default f/w code start */ #define ISP_CODE_ORG_2300 0x0800 /* ..except for 2300s */ #define ISP_CODE_ORG_2400 0x100000 /* ..and 2400s */ #define ISP_FW_REV(maj, min, mic) ((maj << 24) | (min << 16) | mic) #define ISP_FW_MAJOR(code) ((code >> 24) & 0xff) #define ISP_FW_MINOR(code) ((code >> 16) & 0xff) #define ISP_FW_MICRO(code) ((code >> 8) & 0xff) #define ISP_FW_REVX(xp) ((xp[0]<<24) | (xp[1] << 16) | xp[2]) #define ISP_FW_MAJORX(xp) (xp[0]) #define ISP_FW_MINORX(xp) (xp[1]) #define ISP_FW_MICROX(xp) (xp[2]) #define ISP_FW_NEWER_THAN(i, major, minor, micro) \ (ISP_FW_REVX((i)->isp_fwrev) > ISP_FW_REV(major, minor, micro)) #define ISP_FW_OLDER_THAN(i, major, minor, micro) \ (ISP_FW_REVX((i)->isp_fwrev) < ISP_FW_REV(major, minor, micro)) /* * Bus (implementation) types */ #define ISP_BT_PCI 0 /* PCI Implementations */ #define ISP_BT_SBUS 1 /* SBus Implementations */ /* * If we have not otherwise defined SBus support away make sure * it is defined here such that the code is included as default */ #ifndef ISP_SBUS_SUPPORTED #define ISP_SBUS_SUPPORTED 1 #endif /* * Chip Types */ #define ISP_HA_SCSI 0xf #define ISP_HA_SCSI_UNKNOWN 0x1 #define ISP_HA_SCSI_1020 0x2 #define ISP_HA_SCSI_1020A 0x3 #define ISP_HA_SCSI_1040 0x4 #define ISP_HA_SCSI_1040A 0x5 #define ISP_HA_SCSI_1040B 0x6 #define ISP_HA_SCSI_1040C 0x7 #define ISP_HA_SCSI_1240 0x8 #define ISP_HA_SCSI_1080 0x9 #define ISP_HA_SCSI_1280 0xa #define ISP_HA_SCSI_10160 0xb #define ISP_HA_SCSI_12160 0xc #define ISP_HA_FC 0xf0 #define ISP_HA_FC_2100 0x10 #define ISP_HA_FC_2200 0x20 #define ISP_HA_FC_2300 0x30 #define ISP_HA_FC_2312 0x40 #define ISP_HA_FC_2322 0x50 #define ISP_HA_FC_2400 0x60 #define ISP_HA_FC_2500 0x70 #define ISP_HA_FC_2600 0x80 #define ISP_HA_FC_2700 0x90 #define IS_SCSI(isp) (isp->isp_type & ISP_HA_SCSI) #define IS_1020(isp) (isp->isp_type < ISP_HA_SCSI_1240) #define IS_1240(isp) (isp->isp_type == ISP_HA_SCSI_1240) #define IS_1080(isp) (isp->isp_type == ISP_HA_SCSI_1080) #define IS_1280(isp) (isp->isp_type == ISP_HA_SCSI_1280) #define IS_10160(isp) (isp->isp_type == ISP_HA_SCSI_10160) #define IS_12160(isp) (isp->isp_type == ISP_HA_SCSI_12160) #define IS_12X0(isp) (IS_1240(isp) || IS_1280(isp)) #define IS_1X160(isp) (IS_10160(isp) || IS_12160(isp)) #define IS_DUALBUS(isp) (IS_12X0(isp) || IS_12160(isp)) #define IS_ULTRA2(isp) (IS_1080(isp) || IS_1280(isp) || IS_1X160(isp)) #define IS_ULTRA3(isp) (IS_1X160(isp)) #define IS_FC(isp) ((isp)->isp_type & ISP_HA_FC) #define IS_2100(isp) ((isp)->isp_type == ISP_HA_FC_2100) #define IS_2200(isp) ((isp)->isp_type == ISP_HA_FC_2200) #define IS_23XX(isp) ((isp)->isp_type >= ISP_HA_FC_2300 && \ (isp)->isp_type < ISP_HA_FC_2400) #define IS_2300(isp) ((isp)->isp_type == ISP_HA_FC_2300) #define IS_2312(isp) ((isp)->isp_type == ISP_HA_FC_2312) #define IS_2322(isp) ((isp)->isp_type == ISP_HA_FC_2322) #define IS_24XX(isp) ((isp)->isp_type >= ISP_HA_FC_2400) #define IS_25XX(isp) ((isp)->isp_type >= ISP_HA_FC_2500) #define IS_26XX(isp) ((isp)->isp_type >= ISP_HA_FC_2600) #define IS_27XX(isp) ((isp)->isp_type >= ISP_HA_FC_2700) /* * DMA related macros */ #define DMA_WD3(x) (((uint16_t)(((uint64_t)x) >> 48)) & 0xffff) #define DMA_WD2(x) (((uint16_t)(((uint64_t)x) >> 32)) & 0xffff) #define DMA_WD1(x) ((uint16_t)((x) >> 16) & 0xffff) #define DMA_WD0(x) ((uint16_t)((x) & 0xffff)) #define DMA_LO32(x) ((uint32_t) (x)) #define DMA_HI32(x) ((uint32_t)(((uint64_t)x) >> 32)) /* * Core System Function Prototypes */ /* * Reset Hardware. Totally. Assumes that you'll follow this with a call to isp_init. */ void isp_reset(ispsoftc_t *, int); /* * Initialize Hardware to known state */ void isp_init(ispsoftc_t *); /* * Reset the ISP and call completion for any orphaned commands. */ int isp_reinit(ispsoftc_t *, int); /* * Shutdown hardware after use. */ void isp_shutdown(ispsoftc_t *); /* * Internal Interrupt Service Routine */ #ifdef ISP_TARGET_MODE void isp_intr_atioq(ispsoftc_t *); #endif void isp_intr_async(ispsoftc_t *, uint16_t event); void isp_intr_mbox(ispsoftc_t *, uint16_t mbox0); void isp_intr_respq(ispsoftc_t *); /* * Command Entry Point- Platform Dependent layers call into this */ int isp_start(XS_T *); /* these values are what isp_start returns */ #define CMD_COMPLETE 101 /* command completed */ #define CMD_EAGAIN 102 /* busy- maybe retry later */ #define CMD_QUEUED 103 /* command has been queued for execution */ #define CMD_RQLATER 104 /* requeue this command later */ /* * Command Completion Point- Core layers call out from this with completed cmds */ void isp_done(XS_T *); /* * Platform Dependent to External to Internal Control Function * * Assumes locks are held on entry. You should note that with many of * these commands locks may be released while this function is called. * * ... ISPCTL_RESET_BUS, int channel); * Reset BUS on this channel * ... ISPCTL_RESET_DEV, int channel, int target); * Reset Device on this channel at this target. * ... ISPCTL_ABORT_CMD, XS_T *xs); * Abort active transaction described by xs. * ... IPCTL_UPDATE_PARAMS); * Update any operating parameters (speed, etc.) * ... ISPCTL_FCLINK_TEST, int channel); * Test FC link status on this channel * ... ISPCTL_SCAN_LOOP, int channel); * Scan local loop on this channel * ... ISPCTL_SCAN_FABRIC, int channel); * Scan fabric on this channel * ... ISPCTL_PDB_SYNC, int channel); * Synchronize port database on this channel * ... ISPCTL_SEND_LIP, int channel); * Send a LIP on this channel * ... ISPCTL_GET_NAMES, int channel, int np, uint64_t *wwnn, uint64_t *wwpn) * Get a WWNN/WWPN for this N-port handle on this channel * ... ISPCTL_RUN_MBOXCMD, mbreg_t *mbp) * Run this mailbox command * ... ISPCTL_GET_PDB, int channel, int nphandle, isp_pdb_t *pdb) * Get PDB on this channel for this N-port handle * ... ISPCTL_PLOGX, isp_plcmd_t *) * Performa a port login/logout * ... ISPCTL_CHANGE_ROLE, int channel, int role); * Change role of specified channel * * ISPCTL_PDB_SYNC is somewhat misnamed. It actually is the final step, in * order, of ISPCTL_FCLINK_TEST, ISPCTL_SCAN_LOOP, and ISPCTL_SCAN_FABRIC. * The main purpose of ISPCTL_PDB_SYNC is to complete management of logging * and logging out of fabric devices (if one is on a fabric) and then marking * the 'loop state' as being ready to now be used for sending commands to * devices. */ typedef enum { ISPCTL_RESET_BUS, ISPCTL_RESET_DEV, ISPCTL_ABORT_CMD, ISPCTL_UPDATE_PARAMS, ISPCTL_FCLINK_TEST, ISPCTL_SCAN_FABRIC, ISPCTL_SCAN_LOOP, ISPCTL_PDB_SYNC, ISPCTL_SEND_LIP, ISPCTL_GET_NAMES, ISPCTL_RUN_MBOXCMD, ISPCTL_GET_PDB, ISPCTL_PLOGX, ISPCTL_CHANGE_ROLE } ispctl_t; int isp_control(ispsoftc_t *, ispctl_t, ...); /* * Platform Dependent to Internal to External Control Function */ typedef enum { ISPASYNC_NEW_TGT_PARAMS, /* SPI New Target Parameters */ ISPASYNC_BUS_RESET, /* All Bus Was Reset */ ISPASYNC_LOOP_DOWN, /* FC Loop Down */ ISPASYNC_LOOP_UP, /* FC Loop Up */ ISPASYNC_LIP, /* FC LIP Received */ ISPASYNC_LOOP_RESET, /* FC Loop Reset Received */ ISPASYNC_CHANGE_NOTIFY, /* FC Change Notification */ ISPASYNC_DEV_ARRIVED, /* FC Device Arrived */ ISPASYNC_DEV_CHANGED, /* FC Device Changed */ ISPASYNC_DEV_STAYED, /* FC Device Stayed */ ISPASYNC_DEV_GONE, /* FC Device Departure */ ISPASYNC_TARGET_NOTIFY, /* All target async notification */ ISPASYNC_TARGET_NOTIFY_ACK, /* All target notify ack required */ ISPASYNC_TARGET_ACTION, /* All target action requested */ ISPASYNC_FW_CRASH, /* All Firmware has crashed */ ISPASYNC_FW_RESTARTED /* All Firmware has been restarted */ } ispasync_t; void isp_async(ispsoftc_t *, ispasync_t, ...); #define ISPASYNC_CHANGE_PDB 0 #define ISPASYNC_CHANGE_SNS 1 #define ISPASYNC_CHANGE_OTHER 2 /* * Platform Dependent Error and Debug Printout * * Two required functions for each platform must be provided: * * void isp_prt(ispsoftc_t *, int level, const char *, ...) * void isp_xs_prt(ispsoftc_t *, XS_T *, int level, const char *, ...) * * but due to compiler differences on different platforms this won't be * formally defined here. Instead, they go in each platform definition file. */ #define ISP_LOGALL 0x0 /* log always */ #define ISP_LOGCONFIG 0x1 /* log configuration messages */ #define ISP_LOGINFO 0x2 /* log informational messages */ #define ISP_LOGWARN 0x4 /* log warning messages */ #define ISP_LOGERR 0x8 /* log error messages */ #define ISP_LOGDEBUG0 0x10 /* log simple debug messages */ #define ISP_LOGDEBUG1 0x20 /* log intermediate debug messages */ #define ISP_LOGDEBUG2 0x40 /* log most debug messages */ #define ISP_LOGDEBUG3 0x80 /* log high frequency debug messages */ #define ISP_LOG_SANCFG 0x100 /* log SAN configuration */ #define ISP_LOG_CWARN 0x200 /* log SCSI command "warnings" (e.g., check conditions) */ #define ISP_LOG_WARN1 0x400 /* log WARNS we might be interested at some time */ #define ISP_LOGTINFO 0x1000 /* log informational messages (target mode) */ #define ISP_LOGTDEBUG0 0x2000 /* log simple debug messages (target mode) */ #define ISP_LOGTDEBUG1 0x4000 /* log intermediate debug messages (target) */ #define ISP_LOGTDEBUG2 0x8000 /* log all debug messages (target) */ /* * Each Platform provides it's own isposinfo substructure of the ispsoftc * defined above. * * Each platform must also provide the following macros/defines: * * * ISP_FC_SCRLEN FC scratch area DMA length * * ISP_MEMZERO(dst, src) platform zeroing function * ISP_MEMCPY(dst, src, count) platform copying function * ISP_SNPRINTF(buf, bufsize, fmt, ...) snprintf * ISP_DELAY(usecs) microsecond spindelay function * ISP_SLEEP(isp, usecs) microsecond sleep function * * ISP_INLINE ___inline or not- depending on how * good your debugger is * ISP_MIN shorthand for ((a) < (b))? (a) : (b) * * NANOTIME_T nanosecond time type * * GET_NANOTIME(NANOTIME_T *) get current nanotime. * * GET_NANOSEC(NANOTIME_T *) get uint64_t from NANOTIME_T * * NANOTIME_SUB(NANOTIME_T *, NANOTIME_T *) * subtract two NANOTIME_T values * * MAXISPREQUEST(ispsoftc_t *) maximum request queue size * for this particular board type * * MEMORYBARRIER(ispsoftc_t *, barrier_type, offset, size, chan) * * Function/Macro the provides memory synchronization on * various objects so that the ISP's and the system's view * of the same object is consistent. * * MBOX_ACQUIRE(ispsoftc_t *) acquire lock on mailbox regs * MBOX_WAIT_COMPLETE(ispsoftc_t *, mbreg_t *) wait for cmd to be done * MBOX_NOTIFY_COMPLETE(ispsoftc_t *) notification of mbox cmd donee * MBOX_RELEASE(ispsoftc_t *) release lock on mailbox regs * * FC_SCRATCH_ACQUIRE(ispsoftc_t *, chan) acquire lock on FC scratch area * return -1 if you cannot * FC_SCRATCH_RELEASE(ispsoftc_t *, chan) acquire lock on FC scratch area * * FCP_NEXT_CRN(ispsoftc_t *, XS_T *, rslt, channel, target, lun) generate the next command reference number. XS_T * may be null. * * SCSI_GOOD SCSI 'Good' Status * SCSI_CHECK SCSI 'Check Condition' Status * SCSI_BUSY SCSI 'Busy' Status * SCSI_QFULL SCSI 'Queue Full' Status * * XS_T Platform SCSI transaction type (i.e., command for HBA) * XS_DMA_ADDR_T Platform PCI DMA Address Type * XS_GET_DMA_SEG(..) Get 32 bit dma segment list value * XS_GET_DMA64_SEG(..) Get 64 bit dma segment list value * XS_NEED_DMA64_SEG(..) dma segment needs 64 bit storage * XS_ISP(xs) gets an instance out of an XS_T * XS_CHANNEL(xs) gets the channel (bus # for DUALBUS cards) "" * XS_TGT(xs) gets the target "" * XS_LUN(xs) gets the lun "" * XS_CDBP(xs) gets a pointer to the scsi CDB "" * XS_CDBLEN(xs) gets the CDB's length "" * XS_XFRLEN(xs) gets the associated data transfer length "" * XS_TIME(xs) gets the time (in seconds) for this command * XS_GET_RESID(xs) gets the current residual count * XS_GET_RESID(xs, resid) sets the current residual count * XS_STSP(xs) gets a pointer to the SCSI status byte "" * XS_SNSP(xs) gets a pointer to the associate sense data * XS_TOT_SNSLEN(xs) gets the total length of sense data storage * XS_CUR_SNSLEN(xs) gets the currently used length of sense data storage * XS_SNSKEY(xs) dereferences XS_SNSP to get the current stored Sense Key * XS_SNSASC(xs) dereferences XS_SNSP to get the current stored Additional Sense Code * XS_SNSASCQ(xs) dereferences XS_SNSP to get the current stored Additional Sense Code Qualifier * XS_TAG_P(xs) predicate of whether this command should be tagged * XS_TAG_TYPE(xs) which type of tag to use * XS_SETERR(xs) set error state * * HBA_NOERROR command has no erros * HBA_BOTCH hba botched something * HBA_CMDTIMEOUT command timed out * HBA_SELTIMEOUT selection timed out (also port logouts for FC) * HBA_TGTBSY target returned a BUSY status * HBA_BUSRESET bus reset destroyed command * HBA_ABORTED command was aborted (by request) * HBA_DATAOVR a data overrun was detected * HBA_ARQFAIL Automatic Request Sense failed * * XS_ERR(xs) return current error state * XS_NOERR(xs) there is no error currently set * XS_INITERR(xs) initialize error state * * XS_SAVE_SENSE(xs, sp, len) save sense data * XS_APPEND_SENSE(xs, sp, len) append more sense data * * XS_SENSE_VALID(xs) indicates whether sense is valid * * DEFAULT_FRAMESIZE(ispsoftc_t *) Default Frame Size * DEFAULT_EXEC_THROTTLE(ispsoftc_t *) Default Execution Throttle * * DEFAULT_ROLE(ispsoftc_t *, int) Get Default Role for a channel * DEFAULT_IID(ispsoftc_t *, int) Default SCSI initiator ID * DEFAULT_LOOPID(ispsoftc_t *, int) Default FC Loop ID * * These establish reasonable defaults for each platform. * These must be available independent of card NVRAM and are * to be used should NVRAM not be readable. * * DEFAULT_NODEWWN(ispsoftc_t *, chan) Default FC Node WWN to use * DEFAULT_PORTWWN(ispsoftc_t *, chan) Default FC Port WWN to use * * These defines are hooks to allow the setting of node and * port WWNs when NVRAM cannot be read or is to be overriden. * * ACTIVE_NODEWWN(ispsoftc_t *, chan) FC Node WWN to use * ACTIVE_PORTWWN(ispsoftc_t *, chan) FC Port WWN to use * * After NVRAM is read, these will be invoked to get the * node and port WWNs that will actually be used for this * channel. * * * ISP_IOXPUT_8(ispsoftc_t *, uint8_t srcval, uint8_t *dstptr) * ISP_IOXPUT_16(ispsoftc_t *, uint16_t srcval, uint16_t *dstptr) * ISP_IOXPUT_32(ispsoftc_t *, uint32_t srcval, uint32_t *dstptr) * * ISP_IOXGET_8(ispsoftc_t *, uint8_t *srcptr, uint8_t dstrval) * ISP_IOXGET_16(ispsoftc_t *, uint16_t *srcptr, uint16_t dstrval) * ISP_IOXGET_32(ispsoftc_t *, uint32_t *srcptr, uint32_t dstrval) * * ISP_SWIZZLE_NVRAM_WORD(ispsoftc_t *, uint16_t *) * ISP_SWIZZLE_NVRAM_LONG(ispsoftc_t *, uint32_t *) * ISP_SWAP16(ispsoftc_t *, uint16_t srcval) * ISP_SWAP32(ispsoftc_t *, uint32_t srcval) */ #ifdef ISP_TARGET_MODE /* * The functions below are for the publicly available * target mode functions that are internal to the Qlogic driver. */ /* * This function handles new response queue entry appropriate for target mode. */ int isp_target_notify(ispsoftc_t *, void *, uint32_t *); /* * This function externalizes the ability to acknowledge an Immediate Notify request. */ int isp_notify_ack(ispsoftc_t *, void *); /* * This function externalized acknowledging (success/fail) an ABTS frame */ int isp_acknak_abts(ispsoftc_t *, void *, int); /* * General request queue 'put' routine for target mode entries. */ int isp_target_put_entry(ispsoftc_t *isp, void *); /* * General routine to put back an ATIO entry- * used for replenishing f/w resource counts. * The argument is a pointer to a source ATIO * or ATIO2. */ int isp_target_put_atio(ispsoftc_t *, void *); /* * General routine to send a final CTIO for a command- used mostly for * local responses. */ int isp_endcmd(ispsoftc_t *, ...); #define ECMD_SVALID 0x100 #define ECMD_RVALID 0x200 #define ECMD_TERMINATE 0x400 /* * Handle an asynchronous event */ void isp_target_async(ispsoftc_t *, int, int); #endif #endif /* _ISPVAR_H */