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FreeBSD hs32.drive.ne.jp 9.1-RELEASE FreeBSD 9.1-RELEASE #1: Wed Jan 14 12:18:08 JST 2015 root@hs32.drive.ne.jp:/sys/amd64/compile/hs32 amd64 |
Current File : //sys/amd64/compile/hs32/modules/usr/src/sys/modules/usb/urtw/@/amd64/compile/hs32/modules/usr/src/sys/modules/random/@/dev/twe/twe.c |
/*- * Copyright (c) 2000 Michael Smith * Copyright (c) 2003 Paul Saab * Copyright (c) 2003 Vinod Kashyap * Copyright (c) 2000 BSDi * All rights reserved. * * Redistribution and use in source and binary forms, with or without * modification, are permitted provided that the following conditions * are met: * 1. Redistributions of source code must retain the above copyright * notice, this list of conditions and the following disclaimer. * 2. Redistributions in binary form must reproduce the above copyright * notice, this list of conditions and the following disclaimer in the * documentation and/or other materials provided with the distribution. * * THIS SOFTWARE IS PROVIDED BY THE AUTHOR 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. * * $FreeBSD: release/9.1.0/sys/dev/twe/twe.c 200991 2009-12-25 17:34:43Z mav $ */ /* * Driver for the 3ware Escalade family of IDE RAID controllers. */ #include <dev/twe/twe_compat.h> #include <dev/twe/twereg.h> #include <dev/twe/tweio.h> #include <dev/twe/twevar.h> #define TWE_DEFINE_TABLES #include <dev/twe/twe_tables.h> /* * Command submission. */ static int twe_get_param_1(struct twe_softc *sc, int table_id, int param_id, u_int8_t *result); static int twe_get_param_2(struct twe_softc *sc, int table_id, int param_id, u_int16_t *result); static int twe_get_param_4(struct twe_softc *sc, int table_id, int param_id, u_int32_t *result); static void *twe_get_param(struct twe_softc *sc, int table_id, int parameter_id, size_t size, void (* func)(struct twe_request *tr)); #ifdef TWE_SHUTDOWN_NOTIFICATION static int twe_set_param_1(struct twe_softc *sc, int table_id, int param_id, u_int8_t value); #endif #if 0 static int twe_set_param_2(struct twe_softc *sc, int table_id, int param_id, u_int16_t value); static int twe_set_param_4(struct twe_softc *sc, int table_id, int param_id, u_int32_t value); #endif static int twe_set_param(struct twe_softc *sc, int table_id, int param_id, int param_size, void *data); static int twe_init_connection(struct twe_softc *sc, int mode); static int twe_wait_request(struct twe_request *tr); static int twe_immediate_request(struct twe_request *tr, int usetmp); static void twe_completeio(struct twe_request *tr); static void twe_reset(struct twe_softc *sc); static int twe_add_unit(struct twe_softc *sc, int unit); static int twe_del_unit(struct twe_softc *sc, int unit); /* * Command I/O to controller. */ static void twe_done(struct twe_softc *sc); static void twe_complete(struct twe_softc *sc); static int twe_wait_status(struct twe_softc *sc, u_int32_t status, int timeout); static int twe_drain_response_queue(struct twe_softc *sc); static int twe_check_bits(struct twe_softc *sc, u_int32_t status_reg); static int twe_soft_reset(struct twe_softc *sc); /* * Interrupt handling. */ static void twe_host_intr(struct twe_softc *sc); static void twe_attention_intr(struct twe_softc *sc); static void twe_command_intr(struct twe_softc *sc); /* * Asynchronous event handling. */ static int twe_fetch_aen(struct twe_softc *sc); static void twe_handle_aen(struct twe_request *tr); static void twe_enqueue_aen(struct twe_softc *sc, u_int16_t aen); static u_int16_t twe_dequeue_aen(struct twe_softc *sc); static int twe_drain_aen_queue(struct twe_softc *sc); static int twe_find_aen(struct twe_softc *sc, u_int16_t aen); /* * Command buffer management. */ static int twe_get_request(struct twe_softc *sc, struct twe_request **tr); static void twe_release_request(struct twe_request *tr); /* * Debugging. */ static char *twe_format_aen(struct twe_softc *sc, u_int16_t aen); static int twe_report_request(struct twe_request *tr); static void twe_panic(struct twe_softc *sc, char *reason); /******************************************************************************** ******************************************************************************** Public Interfaces ******************************************************************************** ********************************************************************************/ /******************************************************************************** * Initialise the controller, set up driver data structures. */ int twe_setup(struct twe_softc *sc) { struct twe_request *tr; TWE_Command *cmd; u_int32_t status_reg; int i; debug_called(4); /* * Initialise request queues. */ twe_initq_free(sc); twe_initq_bio(sc); twe_initq_ready(sc); twe_initq_busy(sc); twe_initq_complete(sc); sc->twe_wait_aen = -1; /* * Allocate request structures up front. */ for (i = 0; i < TWE_Q_LENGTH; i++) { if ((tr = twe_allocate_request(sc, i)) == NULL) return(ENOMEM); /* * Set global defaults that won't change. */ cmd = TWE_FIND_COMMAND(tr); cmd->generic.host_id = sc->twe_host_id; /* controller-assigned host ID */ cmd->generic.request_id = i; /* our index number */ sc->twe_lookup[i] = tr; /* * Put command onto the freelist. */ twe_release_request(tr); } /* * Check status register for errors, clear them. */ status_reg = TWE_STATUS(sc); twe_check_bits(sc, status_reg); /* * Wait for the controller to come ready. */ if (twe_wait_status(sc, TWE_STATUS_MICROCONTROLLER_READY, 60)) { twe_printf(sc, "microcontroller not ready\n"); return(ENXIO); } /* * Disable interrupts from the card. */ twe_disable_interrupts(sc); /* * Soft reset the controller, look for the AEN acknowledging the reset, * check for errors, drain the response queue. */ for (i = 0; i < TWE_MAX_RESET_TRIES; i++) { if (i > 0) twe_printf(sc, "reset %d failed, trying again\n", i); if (!twe_soft_reset(sc)) break; /* reset process complete */ } /* did we give up? */ if (i >= TWE_MAX_RESET_TRIES) { twe_printf(sc, "can't initialise controller, giving up\n"); return(ENXIO); } return(0); } static int twe_add_unit(struct twe_softc *sc, int unit) { struct twe_drive *dr; int table, error = 0; u_int16_t dsize; TWE_Param *drives = NULL, *param = NULL; TWE_Array_Descriptor *ud; if (unit < 0 || unit > TWE_MAX_UNITS) return (EINVAL); /* * The controller is in a safe state, so try to find drives attached to it. */ if ((drives = twe_get_param(sc, TWE_PARAM_UNITSUMMARY, TWE_PARAM_UNITSUMMARY_Status, TWE_MAX_UNITS, NULL)) == NULL) { twe_printf(sc, "can't detect attached units\n"); return (EIO); } dr = &sc->twe_drive[unit]; /* check that the drive is online */ if (!(drives->data[unit] & TWE_PARAM_UNITSTATUS_Online)) { error = ENXIO; goto out; } table = TWE_PARAM_UNITINFO + unit; if (twe_get_param_4(sc, table, TWE_PARAM_UNITINFO_Capacity, &dr->td_size)) { twe_printf(sc, "error fetching capacity for unit %d\n", unit); error = EIO; goto out; } if (twe_get_param_1(sc, table, TWE_PARAM_UNITINFO_Status, &dr->td_state)) { twe_printf(sc, "error fetching state for unit %d\n", unit); error = EIO; goto out; } if (twe_get_param_2(sc, table, TWE_PARAM_UNITINFO_DescriptorSize, &dsize)) { twe_printf(sc, "error fetching descriptor size for unit %d\n", unit); error = EIO; goto out; } if ((param = twe_get_param(sc, table, TWE_PARAM_UNITINFO_Descriptor, dsize - 3, NULL)) == NULL) { twe_printf(sc, "error fetching descriptor for unit %d\n", unit); error = EIO; goto out; } ud = (TWE_Array_Descriptor *)param->data; dr->td_type = ud->configuration; dr->td_stripe = ud->stripe_size; /* build synthetic geometry as per controller internal rules */ if (dr->td_size > 0x200000) { dr->td_heads = 255; dr->td_sectors = 63; } else { dr->td_heads = 64; dr->td_sectors = 32; } dr->td_cylinders = dr->td_size / (dr->td_heads * dr->td_sectors); dr->td_twe_unit = unit; error = twe_attach_drive(sc, dr); out: if (param != NULL) free(param, M_DEVBUF); if (drives != NULL) free(drives, M_DEVBUF); return (error); } static int twe_del_unit(struct twe_softc *sc, int unit) { int error; if (unit < 0 || unit >= TWE_MAX_UNITS) return (ENXIO); if (sc->twe_drive[unit].td_disk == NULL) return (ENXIO); error = twe_detach_drive(sc, unit); return (error); } /******************************************************************************** * Locate disk devices and attach children to them. */ void twe_init(struct twe_softc *sc) { int i; /* * Scan for drives */ for (i = 0; i < TWE_MAX_UNITS; i++) twe_add_unit(sc, i); /* * Initialise connection with controller. */ twe_init_connection(sc, TWE_INIT_MESSAGE_CREDITS); #ifdef TWE_SHUTDOWN_NOTIFICATION /* * Tell the controller we support shutdown notification. */ twe_set_param_1(sc, TWE_PARAM_FEATURES, TWE_PARAM_FEATURES_DriverShutdown, 1); #endif /* * Mark controller up and ready to run. */ sc->twe_state &= ~TWE_STATE_SHUTDOWN; /* * Finally enable interrupts. */ twe_enable_interrupts(sc); } /******************************************************************************** * Stop the controller */ void twe_deinit(struct twe_softc *sc) { /* * Mark the controller as shutting down, and disable any further interrupts. */ sc->twe_state |= TWE_STATE_SHUTDOWN; twe_disable_interrupts(sc); #ifdef TWE_SHUTDOWN_NOTIFICATION /* * Disconnect from the controller */ twe_init_connection(sc, TWE_SHUTDOWN_MESSAGE_CREDITS); #endif } /******************************************************************************* * Take an interrupt, or be poked by other code to look for interrupt-worthy * status. */ void twe_intr(struct twe_softc *sc) { u_int32_t status_reg; debug_called(4); /* * Collect current interrupt status. */ status_reg = TWE_STATUS(sc); twe_check_bits(sc, status_reg); /* * Dispatch based on interrupt status */ if (status_reg & TWE_STATUS_HOST_INTERRUPT) twe_host_intr(sc); if (status_reg & TWE_STATUS_ATTENTION_INTERRUPT) twe_attention_intr(sc); if (status_reg & TWE_STATUS_COMMAND_INTERRUPT) twe_command_intr(sc); if (status_reg & TWE_STATUS_RESPONSE_INTERRUPT) twe_done(sc); }; /******************************************************************************** * Pull as much work off the softc's work queue as possible and give it to the * controller. */ void twe_startio(struct twe_softc *sc) { struct twe_request *tr; TWE_Command *cmd; twe_bio *bp; int error; debug_called(4); if (sc->twe_state & (TWE_STATE_CTLR_BUSY | TWE_STATE_FRZN)) return; /* spin until something prevents us from doing any work */ for (;;) { /* try to get a command that's already ready to go */ tr = twe_dequeue_ready(sc); /* build a command from an outstanding bio */ if (tr == NULL) { /* get a command to handle the bio with */ if (twe_get_request(sc, &tr)) break; /* see if there's work to be done */ if ((bp = twe_dequeue_bio(sc)) == NULL) { twe_release_request(tr); break; } /* connect the bio to the command */ tr->tr_complete = twe_completeio; tr->tr_private = bp; tr->tr_data = TWE_BIO_DATA(bp); tr->tr_length = TWE_BIO_LENGTH(bp); cmd = TWE_FIND_COMMAND(tr); if (TWE_BIO_IS_READ(bp)) { tr->tr_flags |= TWE_CMD_DATAIN; cmd->io.opcode = TWE_OP_READ; } else { tr->tr_flags |= TWE_CMD_DATAOUT; cmd->io.opcode = TWE_OP_WRITE; } /* build a suitable I/O command (assumes 512-byte rounded transfers) */ cmd->io.size = 3; cmd->io.unit = TWE_BIO_UNIT(bp); cmd->io.block_count = (tr->tr_length + TWE_BLOCK_SIZE - 1) / TWE_BLOCK_SIZE; cmd->io.lba = TWE_BIO_LBA(bp); } /* did we find something to do? */ if (tr == NULL) break; /* try to map and submit the command to controller */ error = twe_map_request(tr); if (error != 0) { if (error == EBUSY) break; tr->tr_status = TWE_CMD_ERROR; if (tr->tr_private != NULL) { bp = (twe_bio *)(tr->tr_private); TWE_BIO_SET_ERROR(bp, error); tr->tr_private = NULL; twed_intr(bp); twe_release_request(tr); } else if (tr->tr_flags & TWE_CMD_SLEEPER) wakeup_one(tr); /* wakeup the sleeping owner */ } } } /******************************************************************************** * Write blocks from memory to disk, for system crash dumps. */ int twe_dump_blocks(struct twe_softc *sc, int unit, u_int32_t lba, void *data, int nblks) { struct twe_request *tr; TWE_Command *cmd; int error; if (twe_get_request(sc, &tr)) return(ENOMEM); tr->tr_data = data; tr->tr_status = TWE_CMD_SETUP; tr->tr_length = nblks * TWE_BLOCK_SIZE; tr->tr_flags = TWE_CMD_DATAOUT; cmd = TWE_FIND_COMMAND(tr); cmd->io.opcode = TWE_OP_WRITE; cmd->io.size = 3; cmd->io.unit = unit; cmd->io.block_count = nblks; cmd->io.lba = lba; error = twe_immediate_request(tr, 0); if (error == 0) if (twe_report_request(tr)) error = EIO; twe_release_request(tr); return(error); } /******************************************************************************** * Handle controller-specific control operations. */ int twe_ioctl(struct twe_softc *sc, u_long ioctlcmd, void *addr) { struct twe_usercommand *tu = (struct twe_usercommand *)addr; struct twe_paramcommand *tp = (struct twe_paramcommand *)addr; struct twe_drivecommand *td = (struct twe_drivecommand *)addr; union twe_statrequest *ts = (union twe_statrequest *)addr; TWE_Param *param; TWE_Command *cmd; void *data; u_int16_t *aen_code = (u_int16_t *)addr; struct twe_request *tr; u_int8_t srid; int s, error; error = 0; switch(ioctlcmd) { /* handle a command from userspace */ case TWEIO_COMMAND: /* get a request */ while (twe_get_request(sc, &tr)) tsleep(sc, PPAUSE, "twioctl", hz); /* * Save the command's request ID, copy the user-supplied command in, * restore the request ID. */ cmd = TWE_FIND_COMMAND(tr); srid = cmd->generic.request_id; bcopy(&tu->tu_command, cmd, sizeof(TWE_Command)); cmd->generic.request_id = srid; /* * if there's a data buffer, allocate and copy it in. * Must be in multipled of 512 bytes. */ tr->tr_length = (tu->tu_size + 511) & ~511; if (tr->tr_length > 0) { if ((tr->tr_data = malloc(tr->tr_length, M_DEVBUF, M_WAITOK)) == NULL) { error = ENOMEM; goto cmd_done; } if ((error = copyin(tu->tu_data, tr->tr_data, tu->tu_size)) != 0) goto cmd_done; tr->tr_flags |= TWE_CMD_DATAIN | TWE_CMD_DATAOUT; } /* run the command */ error = twe_wait_request(tr); if (error) goto cmd_done; /* copy the command out again */ bcopy(cmd, &tu->tu_command, sizeof(TWE_Command)); /* if there was a data buffer, copy it out */ if (tr->tr_length > 0) error = copyout(tr->tr_data, tu->tu_data, tu->tu_size); cmd_done: /* free resources */ if (tr->tr_data != NULL) free(tr->tr_data, M_DEVBUF); if (tr != NULL) twe_release_request(tr); break; /* fetch statistics counter */ case TWEIO_STATS: switch (ts->ts_item) { #ifdef TWE_PERFORMANCE_MONITOR case TWEQ_FREE: case TWEQ_BIO: case TWEQ_READY: case TWEQ_BUSY: case TWEQ_COMPLETE: bcopy(&sc->twe_qstat[ts->ts_item], &ts->ts_qstat, sizeof(struct twe_qstat)); break; #endif default: error = ENOENT; break; } break; /* poll for an AEN */ case TWEIO_AEN_POLL: *aen_code = twe_dequeue_aen(sc); break; /* wait for another AEN to show up */ case TWEIO_AEN_WAIT: s = splbio(); while ((*aen_code = twe_dequeue_aen(sc)) == TWE_AEN_QUEUE_EMPTY) { error = tsleep(&sc->twe_aen_queue, PRIBIO | PCATCH, "tweaen", 0); if (error == EINTR) break; } splx(s); break; case TWEIO_GET_PARAM: if ((param = twe_get_param(sc, tp->tp_table_id, tp->tp_param_id, tp->tp_size, NULL)) == NULL) { twe_printf(sc, "TWEIO_GET_PARAM failed for 0x%x/0x%x/%d\n", tp->tp_table_id, tp->tp_param_id, tp->tp_size); error = EINVAL; } else { if (param->parameter_size_bytes > tp->tp_size) { twe_printf(sc, "TWEIO_GET_PARAM parameter too large (%d > %d)\n", param->parameter_size_bytes, tp->tp_size); error = EFAULT; } else { error = copyout(param->data, tp->tp_data, param->parameter_size_bytes); } free(param, M_DEVBUF); } break; case TWEIO_SET_PARAM: if ((data = malloc(tp->tp_size, M_DEVBUF, M_WAITOK)) == NULL) { error = ENOMEM; } else { error = copyin(tp->tp_data, data, tp->tp_size); if (error == 0) error = twe_set_param(sc, tp->tp_table_id, tp->tp_param_id, tp->tp_size, data); free(data, M_DEVBUF); } break; case TWEIO_RESET: twe_reset(sc); break; case TWEIO_ADD_UNIT: error = twe_add_unit(sc, td->td_unit); break; case TWEIO_DEL_UNIT: error = twe_del_unit(sc, td->td_unit); break; /* XXX implement ATA PASSTHROUGH */ /* nothing we understand */ default: error = ENOTTY; } return(error); } /******************************************************************************** * Enable the useful interrupts from the controller. */ void twe_enable_interrupts(struct twe_softc *sc) { sc->twe_state |= TWE_STATE_INTEN; TWE_CONTROL(sc, TWE_CONTROL_CLEAR_ATTENTION_INTERRUPT | TWE_CONTROL_UNMASK_RESPONSE_INTERRUPT | TWE_CONTROL_ENABLE_INTERRUPTS); } /******************************************************************************** * Disable interrupts from the controller. */ void twe_disable_interrupts(struct twe_softc *sc) { TWE_CONTROL(sc, TWE_CONTROL_DISABLE_INTERRUPTS); sc->twe_state &= ~TWE_STATE_INTEN; } /******************************************************************************** ******************************************************************************** Command Submission ******************************************************************************** ********************************************************************************/ /******************************************************************************** * Read integer parameter table entries. */ static int twe_get_param_1(struct twe_softc *sc, int table_id, int param_id, u_int8_t *result) { TWE_Param *param; if ((param = twe_get_param(sc, table_id, param_id, 1, NULL)) == NULL) return(ENOENT); *result = *(u_int8_t *)param->data; free(param, M_DEVBUF); return(0); } static int twe_get_param_2(struct twe_softc *sc, int table_id, int param_id, u_int16_t *result) { TWE_Param *param; if ((param = twe_get_param(sc, table_id, param_id, 2, NULL)) == NULL) return(ENOENT); *result = *(u_int16_t *)param->data; free(param, M_DEVBUF); return(0); } static int twe_get_param_4(struct twe_softc *sc, int table_id, int param_id, u_int32_t *result) { TWE_Param *param; if ((param = twe_get_param(sc, table_id, param_id, 4, NULL)) == NULL) return(ENOENT); *result = *(u_int32_t *)param->data; free(param, M_DEVBUF); return(0); } /******************************************************************************** * Perform a TWE_OP_GET_PARAM command. If a callback function is provided, it * will be called with the command when it's completed. If no callback is * provided, we will wait for the command to complete and then return just the data. * The caller is responsible for freeing the data when done with it. */ static void * twe_get_param(struct twe_softc *sc, int table_id, int param_id, size_t param_size, void (* func)(struct twe_request *tr)) { struct twe_request *tr; TWE_Command *cmd; TWE_Param *param; int error; debug_called(4); tr = NULL; param = NULL; /* get a command */ if (twe_get_request(sc, &tr)) goto err; /* get a buffer */ if ((param = (TWE_Param *)malloc(TWE_SECTOR_SIZE, M_DEVBUF, M_NOWAIT)) == NULL) goto err; tr->tr_data = param; tr->tr_length = TWE_SECTOR_SIZE; tr->tr_flags = TWE_CMD_DATAIN | TWE_CMD_DATAOUT; /* build the command for the controller */ cmd = TWE_FIND_COMMAND(tr); cmd->param.opcode = TWE_OP_GET_PARAM; cmd->param.size = 2; cmd->param.unit = 0; cmd->param.param_count = 1; /* fill in the outbound parameter data */ param->table_id = table_id; param->parameter_id = param_id; param->parameter_size_bytes = param_size; /* submit the command and either wait or let the callback handle it */ if (func == NULL) { /* XXX could use twe_wait_request here if interrupts were enabled? */ error = twe_immediate_request(tr, 1 /* usetmp */); if (error == 0) { if (twe_report_request(tr)) goto err; } else { goto err; } twe_release_request(tr); return(param); } else { tr->tr_complete = func; error = twe_map_request(tr); if ((error == 0) || (error == EBUSY)) return(func); } /* something failed */ err: debug(1, "failed"); if (tr != NULL) twe_release_request(tr); if (param != NULL) free(param, M_DEVBUF); return(NULL); } /******************************************************************************** * Set integer parameter table entries. */ #ifdef TWE_SHUTDOWN_NOTIFICATION static int twe_set_param_1(struct twe_softc *sc, int table_id, int param_id, u_int8_t value) { return(twe_set_param(sc, table_id, param_id, sizeof(value), &value)); } #endif #if 0 static int twe_set_param_2(struct twe_softc *sc, int table_id, int param_id, u_int16_t value) { return(twe_set_param(sc, table_id, param_id, sizeof(value), &value)); } static int twe_set_param_4(struct twe_softc *sc, int table_id, int param_id, u_int32_t value) { return(twe_set_param(sc, table_id, param_id, sizeof(value), &value)); } #endif /******************************************************************************** * Perform a TWE_OP_SET_PARAM command, returns nonzero on error. */ static int twe_set_param(struct twe_softc *sc, int table_id, int param_id, int param_size, void *data) { struct twe_request *tr; TWE_Command *cmd; TWE_Param *param; int error; debug_called(4); tr = NULL; param = NULL; error = ENOMEM; /* get a command */ if (twe_get_request(sc, &tr)) goto out; /* get a buffer */ if ((param = (TWE_Param *)malloc(TWE_SECTOR_SIZE, M_DEVBUF, M_NOWAIT)) == NULL) goto out; tr->tr_data = param; tr->tr_length = TWE_SECTOR_SIZE; tr->tr_flags = TWE_CMD_DATAIN | TWE_CMD_DATAOUT; /* build the command for the controller */ cmd = TWE_FIND_COMMAND(tr); cmd->param.opcode = TWE_OP_SET_PARAM; cmd->param.size = 2; cmd->param.unit = 0; cmd->param.param_count = 1; /* fill in the outbound parameter data */ param->table_id = table_id; param->parameter_id = param_id; param->parameter_size_bytes = param_size; bcopy(data, param->data, param_size); /* XXX could use twe_wait_request here if interrupts were enabled? */ error = twe_immediate_request(tr, 1 /* usetmp */); if (error == 0) { if (twe_report_request(tr)) error = EIO; } out: if (tr != NULL) twe_release_request(tr); if (param != NULL) free(param, M_DEVBUF); return(error); } /******************************************************************************** * Perform a TWE_OP_INIT_CONNECTION command, returns nonzero on error. * * Typically called with interrupts disabled. */ static int twe_init_connection(struct twe_softc *sc, int mode) { struct twe_request *tr; TWE_Command *cmd; int error; debug_called(4); /* get a command */ if (twe_get_request(sc, &tr)) return(0); /* build the command */ cmd = TWE_FIND_COMMAND(tr); cmd->initconnection.opcode = TWE_OP_INIT_CONNECTION; cmd->initconnection.size = 3; cmd->initconnection.host_id = 0; cmd->initconnection.message_credits = mode; cmd->initconnection.response_queue_pointer = 0; /* submit the command */ error = twe_immediate_request(tr, 0 /* usetmp */); twe_release_request(tr); if (mode == TWE_INIT_MESSAGE_CREDITS) sc->twe_host_id = cmd->initconnection.host_id; return(error); } /******************************************************************************** * Start the command (tr) and sleep waiting for it to complete. * * Successfully completed commands are dequeued. */ static int twe_wait_request(struct twe_request *tr) { int s; debug_called(4); tr->tr_flags |= TWE_CMD_SLEEPER; tr->tr_status = TWE_CMD_BUSY; twe_enqueue_ready(tr); twe_startio(tr->tr_sc); s = splbio(); while (tr->tr_status == TWE_CMD_BUSY) tsleep(tr, PRIBIO, "twewait", 0); splx(s); return(tr->tr_status != TWE_CMD_COMPLETE); } /******************************************************************************** * Start the command (tr) and busy-wait for it to complete. * This should only be used when interrupts are actually disabled (although it * will work if they are not). */ static int twe_immediate_request(struct twe_request *tr, int usetmp) { struct twe_softc *sc; int error; int count = 0; debug_called(4); sc = tr->tr_sc; if (usetmp && (tr->tr_data != NULL)) { tr->tr_flags |= TWE_CMD_IMMEDIATE; if (tr->tr_length > MAXBSIZE) return (EINVAL); bcopy(tr->tr_data, sc->twe_immediate, tr->tr_length); } tr->tr_status = TWE_CMD_BUSY; if ((error = twe_map_request(tr)) != 0) if (error != EBUSY) return(error); /* Wait up to 5 seconds for the command to complete */ while ((count++ < 5000) && (tr->tr_status == TWE_CMD_BUSY)){ DELAY(1000); twe_done(sc); } if (usetmp && (tr->tr_data != NULL)) bcopy(sc->twe_immediate, tr->tr_data, tr->tr_length); return(tr->tr_status != TWE_CMD_COMPLETE); } /******************************************************************************** * Handle completion of an I/O command. */ static void twe_completeio(struct twe_request *tr) { TWE_Command *cmd = TWE_FIND_COMMAND(tr); struct twe_softc *sc = tr->tr_sc; twe_bio *bp = (twe_bio *)tr->tr_private; debug_called(4); if (tr->tr_status == TWE_CMD_COMPLETE) { if (cmd->generic.status) if (twe_report_request(tr)) TWE_BIO_SET_ERROR(bp, EIO); } else { twe_panic(sc, "twe_completeio on incomplete command"); } tr->tr_private = NULL; twed_intr(bp); twe_release_request(tr); } /******************************************************************************** * Reset the controller and pull all the active commands back onto the ready * queue. Used to restart a controller that's exhibiting bad behaviour. */ static void twe_reset(struct twe_softc *sc) { struct twe_request *tr; int i, s; /* * Sleep for a short period to allow AENs to be signalled. */ tsleep(sc, PRIBIO, "twereset", hz); /* * Disable interrupts from the controller, and mask any accidental entry * into our interrupt handler. */ twe_printf(sc, "controller reset in progress...\n"); twe_disable_interrupts(sc); s = splbio(); /* * Try to soft-reset the controller. */ for (i = 0; i < TWE_MAX_RESET_TRIES; i++) { if (i > 0) twe_printf(sc, "reset %d failed, trying again\n", i); if (!twe_soft_reset(sc)) break; /* reset process complete */ } /* did we give up? */ if (i >= TWE_MAX_RESET_TRIES) { twe_printf(sc, "can't reset controller, giving up\n"); goto out; } /* * Move all of the commands that were busy back to the ready queue. */ i = 0; while ((tr = twe_dequeue_busy(sc)) != NULL) { twe_enqueue_ready(tr); i++; } /* * Kick the controller to start things going again, then re-enable interrupts. */ twe_startio(sc); twe_enable_interrupts(sc); twe_printf(sc, "controller reset done, %d commands restarted\n", i); out: splx(s); twe_enable_interrupts(sc); } /******************************************************************************** ******************************************************************************** Command I/O to Controller ******************************************************************************** ********************************************************************************/ /******************************************************************************** * Try to deliver (tr) to the controller. * * Can be called at any interrupt level, with or without interrupts enabled. */ int twe_start(struct twe_request *tr) { struct twe_softc *sc = tr->tr_sc; TWE_Command *cmd; int i, s, done; u_int32_t status_reg; debug_called(4); /* mark the command as currently being processed */ tr->tr_status = TWE_CMD_BUSY; cmd = TWE_FIND_COMMAND(tr); /* * Spin briefly waiting for the controller to come ready * * XXX it might be more efficient to return EBUSY immediately * and let the command be rescheduled. */ for (i = 100000, done = 0; (i > 0) && !done; i--) { s = splbio(); /* check to see if we can post a command */ status_reg = TWE_STATUS(sc); twe_check_bits(sc, status_reg); if (!(status_reg & TWE_STATUS_COMMAND_QUEUE_FULL)) { twe_enqueue_busy(tr); TWE_COMMAND_QUEUE(sc, TWE_FIND_COMMANDPHYS(tr)); done = 1; /* move command to work queue */ #ifdef TWE_DEBUG if (tr->tr_complete != NULL) { debug(3, "queued request %d with callback %p", cmd->generic.request_id, tr->tr_complete); } else if (tr->tr_flags & TWE_CMD_SLEEPER) { debug(3, "queued request %d with wait channel %p", cmd->generic.request_id, tr); } else { debug(3, "queued request %d for polling caller", cmd->generic.request_id); } #endif } splx(s); /* drop spl to allow completion interrupts */ } /* command is enqueued */ if (done) return(0); /* * We couldn't get the controller to take the command; try submitting it again later. * This should only happen if something is wrong with the controller, or if we have * overestimated the number of commands it can accept. (Should we actually reject * the command at this point?) */ return(EBUSY); } /******************************************************************************** * Poll the controller (sc) for completed commands. * * Can be called at any interrupt level, with or without interrupts enabled. */ static void twe_done(struct twe_softc *sc) { TWE_Response_Queue rq; TWE_Command *cmd; struct twe_request *tr; int s, found; u_int32_t status_reg; debug_called(5); /* loop collecting completed commands */ found = 0; s = splbio(); for (;;) { status_reg = TWE_STATUS(sc); twe_check_bits(sc, status_reg); /* XXX should this fail? */ if (!(status_reg & TWE_STATUS_RESPONSE_QUEUE_EMPTY)) { found = 1; rq = TWE_RESPONSE_QUEUE(sc); tr = sc->twe_lookup[rq.u.response_id]; /* find command */ cmd = TWE_FIND_COMMAND(tr); if (tr->tr_status != TWE_CMD_BUSY) twe_printf(sc, "completion event for nonbusy command\n"); tr->tr_status = TWE_CMD_COMPLETE; debug(3, "completed request id %d with status %d", cmd->generic.request_id, cmd->generic.status); /* move to completed queue */ twe_remove_busy(tr); twe_enqueue_complete(tr); sc->twe_state &= ~TWE_STATE_CTLR_BUSY; } else { break; /* no response ready */ } } splx(s); /* if we've completed any commands, try posting some more */ if (found) twe_startio(sc); /* handle completion and timeouts */ twe_complete(sc); /* XXX use deferred completion? */ } /******************************************************************************** * Perform post-completion processing for commands on (sc). * * This is split from twe_done as it can be safely deferred and run at a lower * priority level should facilities for such a thing become available. */ static void twe_complete(struct twe_softc *sc) { struct twe_request *tr; debug_called(5); /* * Pull commands off the completed list, dispatch them appropriately */ while ((tr = twe_dequeue_complete(sc)) != NULL) { /* unmap the command's data buffer */ twe_unmap_request(tr); /* dispatch to suit command originator */ if (tr->tr_complete != NULL) { /* completion callback */ debug(2, "call completion handler %p", tr->tr_complete); tr->tr_complete(tr); } else if (tr->tr_flags & TWE_CMD_SLEEPER) { /* caller is asleep waiting */ debug(2, "wake up command owner on %p", tr); wakeup_one(tr); } else { /* caller is polling command */ debug(2, "command left for owner"); } } } /******************************************************************************** * Wait for (status) to be set in the controller status register for up to * (timeout) seconds. Returns 0 if found, nonzero if we time out. * * Note: this busy-waits, rather than sleeping, since we may be called with * eg. clock interrupts masked. */ static int twe_wait_status(struct twe_softc *sc, u_int32_t status, int timeout) { time_t expiry; u_int32_t status_reg; debug_called(4); expiry = time_second + timeout; do { status_reg = TWE_STATUS(sc); if (status_reg & status) /* got the required bit(s)? */ return(0); DELAY(100000); } while (time_second <= expiry); return(1); } /******************************************************************************** * Drain the response queue, which may contain responses to commands we know * nothing about. */ static int twe_drain_response_queue(struct twe_softc *sc) { TWE_Response_Queue rq; u_int32_t status_reg; debug_called(4); for (;;) { /* XXX give up eventually? */ status_reg = TWE_STATUS(sc); if (twe_check_bits(sc, status_reg)) return(1); if (status_reg & TWE_STATUS_RESPONSE_QUEUE_EMPTY) return(0); rq = TWE_RESPONSE_QUEUE(sc); } } /******************************************************************************** * Soft-reset the controller */ static int twe_soft_reset(struct twe_softc *sc) { u_int32_t status_reg; debug_called(2); TWE_SOFT_RESET(sc); if (twe_wait_status(sc, TWE_STATUS_ATTENTION_INTERRUPT, 30)) { twe_printf(sc, "no attention interrupt\n"); return(1); } TWE_CONTROL(sc, TWE_CONTROL_CLEAR_ATTENTION_INTERRUPT); if (twe_drain_aen_queue(sc)) { twe_printf(sc, "can't drain AEN queue\n"); return(1); } if (twe_find_aen(sc, TWE_AEN_SOFT_RESET)) { twe_printf(sc, "reset not reported\n"); return(1); } status_reg = TWE_STATUS(sc); if (TWE_STATUS_ERRORS(status_reg) || twe_check_bits(sc, status_reg)) { twe_printf(sc, "controller errors detected\n"); return(1); } if (twe_drain_response_queue(sc)) { twe_printf(sc, "can't drain response queue\n"); return(1); } return(0); } /******************************************************************************** ******************************************************************************** Interrupt Handling ******************************************************************************** ********************************************************************************/ /******************************************************************************** * Host interrupt. * * XXX what does this mean? */ static void twe_host_intr(struct twe_softc *sc) { debug_called(4); twe_printf(sc, "host interrupt\n"); TWE_CONTROL(sc, TWE_CONTROL_CLEAR_HOST_INTERRUPT); } /******************************************************************************** * Attention interrupt. * * Signalled when the controller has one or more AENs for us. */ static void twe_attention_intr(struct twe_softc *sc) { debug_called(4); /* instigate a poll for AENs */ if (twe_fetch_aen(sc)) { twe_printf(sc, "error polling for signalled AEN\n"); } else { TWE_CONTROL(sc, TWE_CONTROL_CLEAR_ATTENTION_INTERRUPT); } } /******************************************************************************** * Command interrupt. * * Signalled when the controller can handle more commands. */ static void twe_command_intr(struct twe_softc *sc) { debug_called(4); /* * We don't use this, rather we try to submit commands when we receive * them, and when other commands have completed. Mask it so we don't get * another one. */ TWE_CONTROL(sc, TWE_CONTROL_MASK_COMMAND_INTERRUPT); } /******************************************************************************** ******************************************************************************** Asynchronous Event Handling ******************************************************************************** ********************************************************************************/ /******************************************************************************** * Request an AEN from the controller. */ static int twe_fetch_aen(struct twe_softc *sc) { debug_called(4); if ((twe_get_param(sc, TWE_PARAM_AEN, TWE_PARAM_AEN_UnitCode, 2, twe_handle_aen)) == NULL) return(EIO); return(0); } /******************************************************************************** * Handle an AEN returned by the controller. */ static void twe_handle_aen(struct twe_request *tr) { struct twe_softc *sc = tr->tr_sc; TWE_Param *param; u_int16_t aen; debug_called(4); /* XXX check for command success somehow? */ param = (TWE_Param *)tr->tr_data; aen = *(u_int16_t *)(param->data); free(tr->tr_data, M_DEVBUF); twe_release_request(tr); twe_enqueue_aen(sc, aen); /* XXX poll for more AENs? */ } /******************************************************************************** * Pull AENs out of the controller and park them in the queue, in a context where * interrupts aren't active. Return nonzero if we encounter any errors in the * process of obtaining all the available AENs. */ static int twe_drain_aen_queue(struct twe_softc *sc) { u_int16_t aen; for (;;) { if (twe_get_param_2(sc, TWE_PARAM_AEN, TWE_PARAM_AEN_UnitCode, &aen)) return(1); if (aen == TWE_AEN_QUEUE_EMPTY) return(0); twe_enqueue_aen(sc, aen); } } /******************************************************************************** * Push an AEN that we've received onto the queue. * * Note that we have to lock this against reentrance, since it may be called * from both interrupt and non-interrupt context. * * If someone is waiting for the AEN we have, wake them up. */ static void twe_enqueue_aen(struct twe_softc *sc, u_int16_t aen) { char *msg; int s, next, nextnext; debug_called(4); if ((msg = twe_format_aen(sc, aen)) != NULL) twe_printf(sc, "AEN: <%s>\n", msg); s = splbio(); /* enqueue the AEN */ next = ((sc->twe_aen_head + 1) % TWE_Q_LENGTH); nextnext = ((sc->twe_aen_head + 2) % TWE_Q_LENGTH); /* check to see if this is the last free slot, and subvert the AEN if it is */ if (nextnext == sc->twe_aen_tail) aen = TWE_AEN_QUEUE_FULL; /* look to see if there's room for this AEN */ if (next != sc->twe_aen_tail) { sc->twe_aen_queue[sc->twe_aen_head] = aen; sc->twe_aen_head = next; } /* wake up anyone asleep on the queue */ wakeup(&sc->twe_aen_queue); /* anyone looking for this AEN? */ if (sc->twe_wait_aen == aen) { sc->twe_wait_aen = -1; wakeup(&sc->twe_wait_aen); } splx(s); } /******************************************************************************** * Pop an AEN off the queue, or return -1 if there are none left. * * We are more or less interrupt-safe, so don't block interrupts. */ static u_int16_t twe_dequeue_aen(struct twe_softc *sc) { u_int16_t result; debug_called(4); if (sc->twe_aen_tail == sc->twe_aen_head) { result = TWE_AEN_QUEUE_EMPTY; } else { result = sc->twe_aen_queue[sc->twe_aen_tail]; sc->twe_aen_tail = ((sc->twe_aen_tail + 1) % TWE_Q_LENGTH); } return(result); } /******************************************************************************** * Check to see if the requested AEN is in the queue. * * XXX we could probably avoid masking interrupts here */ static int twe_find_aen(struct twe_softc *sc, u_int16_t aen) { int i, s, missing; missing = 1; s = splbio(); for (i = sc->twe_aen_tail; (i != sc->twe_aen_head) && missing; i = (i + 1) % TWE_Q_LENGTH) { if (sc->twe_aen_queue[i] == aen) missing = 0; } splx(s); return(missing); } #if 0 /* currently unused */ /******************************************************************************** * Sleep waiting for at least (timeout) seconds until we see (aen) as * requested. Returns nonzero on timeout or failure. * * XXX: this should not be used in cases where there may be more than one sleeper * without a mechanism for registering multiple sleepers. */ static int twe_wait_aen(struct twe_softc *sc, int aen, int timeout) { time_t expiry; int found, s; debug_called(4); expiry = time_second + timeout; found = 0; s = splbio(); sc->twe_wait_aen = aen; do { twe_fetch_aen(sc); tsleep(&sc->twe_wait_aen, PZERO, "twewaen", hz); if (sc->twe_wait_aen == -1) found = 1; } while ((time_second <= expiry) && !found); splx(s); return(!found); } #endif /******************************************************************************** ******************************************************************************** Command Buffer Management ******************************************************************************** ********************************************************************************/ /******************************************************************************** * Get a new command buffer. * * This will return NULL if all command buffers are in use. */ static int twe_get_request(struct twe_softc *sc, struct twe_request **tr) { TWE_Command *cmd; debug_called(4); /* try to reuse an old buffer */ *tr = twe_dequeue_free(sc); /* initialise some fields to their defaults */ if (*tr != NULL) { cmd = TWE_FIND_COMMAND(*tr); (*tr)->tr_data = NULL; (*tr)->tr_private = NULL; (*tr)->tr_status = TWE_CMD_SETUP; /* command is in setup phase */ (*tr)->tr_flags = 0; (*tr)->tr_complete = NULL; cmd->generic.status = 0; /* before submission to controller */ cmd->generic.flags = 0; /* not used */ } return(*tr == NULL); } /******************************************************************************** * Release a command buffer for reuse. * */ static void twe_release_request(struct twe_request *tr) { debug_called(4); if (tr->tr_private != NULL) twe_panic(tr->tr_sc, "tr_private != NULL"); twe_enqueue_free(tr); } /******************************************************************************** ******************************************************************************** Debugging ******************************************************************************** ********************************************************************************/ /******************************************************************************** * Print some information about the controller */ void twe_describe_controller(struct twe_softc *sc) { TWE_Param *p[6]; u_int8_t ports; u_int32_t size; int i; debug_called(2); /* get the port count */ twe_get_param_1(sc, TWE_PARAM_CONTROLLER, TWE_PARAM_CONTROLLER_PortCount, &ports); /* get version strings */ p[0] = twe_get_param(sc, TWE_PARAM_VERSION, TWE_PARAM_VERSION_FW, 16, NULL); p[1] = twe_get_param(sc, TWE_PARAM_VERSION, TWE_PARAM_VERSION_BIOS, 16, NULL); if (p[0] && p[1]) twe_printf(sc, "%d ports, Firmware %.16s, BIOS %.16s\n", ports, p[0]->data, p[1]->data); if (bootverbose) { p[2] = twe_get_param(sc, TWE_PARAM_VERSION, TWE_PARAM_VERSION_Mon, 16, NULL); p[3] = twe_get_param(sc, TWE_PARAM_VERSION, TWE_PARAM_VERSION_PCB, 8, NULL); p[4] = twe_get_param(sc, TWE_PARAM_VERSION, TWE_PARAM_VERSION_ATA, 8, NULL); p[5] = twe_get_param(sc, TWE_PARAM_VERSION, TWE_PARAM_VERSION_PCI, 8, NULL); if (p[2] && p[3] && p[4] && p[5]) twe_printf(sc, "Monitor %.16s, PCB %.8s, Achip %.8s, Pchip %.8s\n", p[2]->data, p[3]->data, p[4]->data, p[5]->data); if (p[2]) free(p[2], M_DEVBUF); if (p[3]) free(p[3], M_DEVBUF); if (p[4]) free(p[4], M_DEVBUF); if (p[5]) free(p[5], M_DEVBUF); } if (p[0]) free(p[0], M_DEVBUF); if (p[1]) free(p[1], M_DEVBUF); /* print attached drives */ if (bootverbose) { p[0] = twe_get_param(sc, TWE_PARAM_DRIVESUMMARY, TWE_PARAM_DRIVESUMMARY_Status, 16, NULL); for (i = 0; i < ports; i++) { if (p[0]->data[i] != TWE_PARAM_DRIVESTATUS_Present) continue; twe_get_param_4(sc, TWE_PARAM_DRIVEINFO + i, TWE_PARAM_DRIVEINFO_Size, &size); p[1] = twe_get_param(sc, TWE_PARAM_DRIVEINFO + i, TWE_PARAM_DRIVEINFO_Model, 40, NULL); if (p[1] != NULL) { twe_printf(sc, "port %d: %.40s %dMB\n", i, p[1]->data, size / 2048); free(p[1], M_DEVBUF); } else { twe_printf(sc, "port %d, drive status unavailable\n", i); } } if (p[0]) free(p[0], M_DEVBUF); } } /******************************************************************************** * Look up a text description of a numeric code and return a pointer to same. */ char * twe_describe_code(struct twe_code_lookup *table, u_int32_t code) { int i; for (i = 0; table[i].string != NULL; i++) if (table[i].code == code) return(table[i].string); return(table[i+1].string); } /******************************************************************************** * Complain if the status bits aren't what we're expecting. * * Rate-limit the complaints to at most one of each every five seconds, but * always return the correct status. */ static int twe_check_bits(struct twe_softc *sc, u_int32_t status_reg) { int result; static time_t lastwarn[2] = {0, 0}; /* * This can be a little problematic, as twe_panic may call twe_reset if * TWE_DEBUG is not set, which will call us again as part of the soft reset. */ if ((status_reg & TWE_STATUS_PANIC_BITS) != 0) { twe_printf(sc, "FATAL STATUS BIT(S) %b\n", status_reg & TWE_STATUS_PANIC_BITS, TWE_STATUS_BITS_DESCRIPTION); twe_panic(sc, "fatal status bits"); } result = 0; if ((status_reg & TWE_STATUS_EXPECTED_BITS) != TWE_STATUS_EXPECTED_BITS) { if (time_second > (lastwarn[0] + 5)) { twe_printf(sc, "missing expected status bit(s) %b\n", ~status_reg & TWE_STATUS_EXPECTED_BITS, TWE_STATUS_BITS_DESCRIPTION); lastwarn[0] = time_second; } result = 1; } if ((status_reg & TWE_STATUS_UNEXPECTED_BITS) != 0) { if (time_second > (lastwarn[1] + 5)) { twe_printf(sc, "unexpected status bit(s) %b\n", status_reg & TWE_STATUS_UNEXPECTED_BITS, TWE_STATUS_BITS_DESCRIPTION); lastwarn[1] = time_second; } result = 1; if (status_reg & TWE_STATUS_PCI_PARITY_ERROR) { twe_printf(sc, "PCI parity error: Reseat card, move card or buggy device present.\n"); twe_clear_pci_parity_error(sc); } if (status_reg & TWE_STATUS_PCI_ABORT) { twe_printf(sc, "PCI abort, clearing.\n"); twe_clear_pci_abort(sc); } } return(result); } /******************************************************************************** * Return a string describing (aen). * * The low 8 bits of the aen are the code, the high 8 bits give the unit number * where an AEN is specific to a unit. * * Note that we could expand this routine to handle eg. up/downgrading the status * of a drive if we had some idea of what the drive's initial status was. */ static char * twe_format_aen(struct twe_softc *sc, u_int16_t aen) { static char buf[80]; device_t child; char *code, *msg; code = twe_describe_code(twe_table_aen, TWE_AEN_CODE(aen)); msg = code + 2; switch (*code) { case 'q': if (!bootverbose) return(NULL); /* FALLTHROUGH */ case 'a': return(msg); case 'c': if ((child = sc->twe_drive[TWE_AEN_UNIT(aen)].td_disk) != NULL) { sprintf(buf, "twed%d: %s", device_get_unit(child), msg); } else { sprintf(buf, "twe%d: %s for unknown unit %d", device_get_unit(sc->twe_dev), msg, TWE_AEN_UNIT(aen)); } return(buf); case 'p': sprintf(buf, "twe%d: port %d: %s", device_get_unit(sc->twe_dev), TWE_AEN_UNIT(aen), msg); return(buf); case 'x': default: break; } sprintf(buf, "unknown AEN 0x%x", aen); return(buf); } /******************************************************************************** * Print a diagnostic if the status of the command warrants it, and return * either zero (command was ok) or nonzero (command failed). */ static int twe_report_request(struct twe_request *tr) { struct twe_softc *sc = tr->tr_sc; TWE_Command *cmd = TWE_FIND_COMMAND(tr); int result = 0; /* * Check the command status value and handle accordingly. */ if (cmd->generic.status == TWE_STATUS_RESET) { /* * The status code 0xff requests a controller reset. */ twe_printf(sc, "command returned with controller reset request\n"); twe_reset(sc); result = 1; } else if (cmd->generic.status > TWE_STATUS_FATAL) { /* * Fatal errors that don't require controller reset. * * We know a few special flags values. */ switch (cmd->generic.flags) { case 0x1b: device_printf(sc->twe_drive[cmd->generic.unit].td_disk, "drive timeout"); break; case 0x51: device_printf(sc->twe_drive[cmd->generic.unit].td_disk, "unrecoverable drive error"); break; default: device_printf(sc->twe_drive[cmd->generic.unit].td_disk, "controller error - %s (flags = 0x%x)\n", twe_describe_code(twe_table_status, cmd->generic.status), cmd->generic.flags); result = 1; } } else if (cmd->generic.status > TWE_STATUS_WARNING) { /* * Warning level status. */ device_printf(sc->twe_drive[cmd->generic.unit].td_disk, "warning - %s (flags = 0x%x)\n", twe_describe_code(twe_table_status, cmd->generic.status), cmd->generic.flags); } else if (cmd->generic.status > 0x40) { /* * Info level status. */ device_printf(sc->twe_drive[cmd->generic.unit].td_disk, "attention - %s (flags = 0x%x)\n", twe_describe_code(twe_table_status, cmd->generic.status), cmd->generic.flags); } return(result); } /******************************************************************************** * Print some controller state to aid in debugging error/panic conditions */ void twe_print_controller(struct twe_softc *sc) { u_int32_t status_reg; status_reg = TWE_STATUS(sc); twe_printf(sc, "status %b\n", status_reg, TWE_STATUS_BITS_DESCRIPTION); twe_printf(sc, " current max min\n"); twe_printf(sc, "free %04d %04d %04d\n", sc->twe_qstat[TWEQ_FREE].q_length, sc->twe_qstat[TWEQ_FREE].q_max, sc->twe_qstat[TWEQ_FREE].q_min); twe_printf(sc, "ready %04d %04d %04d\n", sc->twe_qstat[TWEQ_READY].q_length, sc->twe_qstat[TWEQ_READY].q_max, sc->twe_qstat[TWEQ_READY].q_min); twe_printf(sc, "busy %04d %04d %04d\n", sc->twe_qstat[TWEQ_BUSY].q_length, sc->twe_qstat[TWEQ_BUSY].q_max, sc->twe_qstat[TWEQ_BUSY].q_min); twe_printf(sc, "complete %04d %04d %04d\n", sc->twe_qstat[TWEQ_COMPLETE].q_length, sc->twe_qstat[TWEQ_COMPLETE].q_max, sc->twe_qstat[TWEQ_COMPLETE].q_min); twe_printf(sc, "bioq %04d %04d %04d\n", sc->twe_qstat[TWEQ_BIO].q_length, sc->twe_qstat[TWEQ_BIO].q_max, sc->twe_qstat[TWEQ_BIO].q_min); twe_printf(sc, "AEN queue head %d tail %d\n", sc->twe_aen_head, sc->twe_aen_tail); } static void twe_panic(struct twe_softc *sc, char *reason) { twe_print_controller(sc); #ifdef TWE_DEBUG panic(reason); #else twe_reset(sc); #endif } #if 0 /******************************************************************************** * Print a request/command in human-readable format. */ static void twe_print_request(struct twe_request *tr) { struct twe_softc *sc = tr->tr_sc; TWE_Command *cmd = TWE_FIND_COMMAND(tr); int i; twe_printf(sc, "CMD: request_id %d opcode <%s> size %d unit %d host_id %d\n", cmd->generic.request_id, twe_describe_code(twe_table_opcode, cmd->generic.opcode), cmd->generic.size, cmd->generic.unit, cmd->generic.host_id); twe_printf(sc, " status %d flags 0x%x count %d sgl_offset %d\n", cmd->generic.status, cmd->generic.flags, cmd->generic.count, cmd->generic.sgl_offset); switch(cmd->generic.opcode) { /* XXX add more opcodes? */ case TWE_OP_READ: case TWE_OP_WRITE: twe_printf(sc, " lba %d\n", cmd->io.lba); for (i = 0; (i < TWE_MAX_SGL_LENGTH) && (cmd->io.sgl[i].length != 0); i++) twe_printf(sc, " %d: 0x%x/%d\n", i, cmd->io.sgl[i].address, cmd->io.sgl[i].length); break; case TWE_OP_GET_PARAM: case TWE_OP_SET_PARAM: for (i = 0; (i < TWE_MAX_SGL_LENGTH) && (cmd->param.sgl[i].length != 0); i++) twe_printf(sc, " %d: 0x%x/%d\n", i, cmd->param.sgl[i].address, cmd->param.sgl[i].length); break; case TWE_OP_INIT_CONNECTION: twe_printf(sc, " response queue pointer 0x%x\n", cmd->initconnection.response_queue_pointer); break; default: break; } twe_printf(sc, " tr_command %p/0x%x tr_data %p/0x%x,%d\n", tr, TWE_FIND_COMMANDPHYS(tr), tr->tr_data, tr->tr_dataphys, tr->tr_length); twe_printf(sc, " tr_status %d tr_flags 0x%x tr_complete %p tr_private %p\n", tr->tr_status, tr->tr_flags, tr->tr_complete, tr->tr_private); } #endif