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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/s3/@/amd64/compile/hs32/modules/usr/src/sys/modules/ispfw/isp_2200/@/dev/twa/tw_osl_freebsd.c |
/* * Copyright (c) 2004-07 Applied Micro Circuits Corporation. * Copyright (c) 2004-05 Vinod Kashyap. * Copyright (c) 2000 Michael Smith * 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. */ #include <sys/cdefs.h> __FBSDID("$FreeBSD: release/9.1.0/sys/dev/twa/tw_osl_freebsd.c 233705 2012-03-30 17:38:28Z jhb $"); /* * AMCC'S 3ware driver for 9000 series storage controllers. * * Author: Vinod Kashyap * Modifications by: Adam Radford * Modifications by: Manjunath Ranganathaiah */ /* * FreeBSD specific functions not related to CAM, and other * miscellaneous functions. */ #include <dev/twa/tw_osl_includes.h> #include <dev/twa/tw_cl_fwif.h> #include <dev/twa/tw_cl_ioctl.h> #include <dev/twa/tw_osl_ioctl.h> #ifdef TW_OSL_DEBUG TW_INT32 TW_DEBUG_LEVEL_FOR_OSL = TW_OSL_DEBUG; TW_INT32 TW_OSL_DEBUG_LEVEL_FOR_CL = TW_OSL_DEBUG; #endif /* TW_OSL_DEBUG */ MALLOC_DEFINE(TW_OSLI_MALLOC_CLASS, "twa_commands", "twa commands"); static d_open_t twa_open; static d_close_t twa_close; static d_ioctl_t twa_ioctl; static struct cdevsw twa_cdevsw = { .d_version = D_VERSION, .d_open = twa_open, .d_close = twa_close, .d_ioctl = twa_ioctl, .d_name = "twa", }; static devclass_t twa_devclass; /* * Function name: twa_open * Description: Called when the controller is opened. * Simply marks the controller as open. * * Input: dev -- control device corresponding to the ctlr * flags -- mode of open * fmt -- device type (character/block etc.) * proc -- current process * Output: None * Return value: 0 -- success * non-zero-- failure */ static TW_INT32 twa_open(struct cdev *dev, TW_INT32 flags, TW_INT32 fmt, struct thread *proc) { struct twa_softc *sc = (struct twa_softc *)(dev->si_drv1); tw_osli_dbg_dprintf(5, sc, "entered"); sc->open = TW_CL_TRUE; return(0); } /* * Function name: twa_close * Description: Called when the controller is closed. * Simply marks the controller as not open. * * Input: dev -- control device corresponding to the ctlr * flags -- mode of corresponding open * fmt -- device type (character/block etc.) * proc -- current process * Output: None * Return value: 0 -- success * non-zero-- failure */ static TW_INT32 twa_close(struct cdev *dev, TW_INT32 flags, TW_INT32 fmt, struct thread *proc) { struct twa_softc *sc = (struct twa_softc *)(dev->si_drv1); tw_osli_dbg_dprintf(5, sc, "entered"); sc->open = TW_CL_FALSE; return(0); } /* * Function name: twa_ioctl * Description: Called when an ioctl is posted to the controller. * Handles any OS Layer specific cmds, passes the rest * on to the Common Layer. * * Input: dev -- control device corresponding to the ctlr * cmd -- ioctl cmd * buf -- ptr to buffer in kernel memory, which is * a copy of the input buffer in user-space * flags -- mode of corresponding open * proc -- current process * Output: buf -- ptr to buffer in kernel memory, which will * be copied to the output buffer in user-space * Return value: 0 -- success * non-zero-- failure */ static TW_INT32 twa_ioctl(struct cdev *dev, u_long cmd, caddr_t buf, TW_INT32 flags, struct thread *proc) { struct twa_softc *sc = (struct twa_softc *)(dev->si_drv1); TW_INT32 error; tw_osli_dbg_dprintf(5, sc, "entered"); switch (cmd) { case TW_OSL_IOCTL_FIRMWARE_PASS_THROUGH: tw_osli_dbg_dprintf(6, sc, "ioctl: fw_passthru"); error = tw_osli_fw_passthru(sc, (TW_INT8 *)buf); break; case TW_OSL_IOCTL_SCAN_BUS: /* Request CAM for a bus scan. */ tw_osli_dbg_dprintf(6, sc, "ioctl: scan bus"); error = tw_osli_request_bus_scan(sc); break; default: tw_osli_dbg_dprintf(6, sc, "ioctl: 0x%lx", cmd); error = tw_cl_ioctl(&sc->ctlr_handle, cmd, buf); break; } return(error); } static TW_INT32 twa_probe(device_t dev); static TW_INT32 twa_attach(device_t dev); static TW_INT32 twa_detach(device_t dev); static TW_INT32 twa_shutdown(device_t dev); static TW_VOID twa_busdma_lock(TW_VOID *lock_arg, bus_dma_lock_op_t op); static TW_VOID twa_pci_intr(TW_VOID *arg); static TW_VOID twa_watchdog(TW_VOID *arg); int twa_setup_intr(struct twa_softc *sc); int twa_teardown_intr(struct twa_softc *sc); static TW_INT32 tw_osli_alloc_mem(struct twa_softc *sc); static TW_VOID tw_osli_free_resources(struct twa_softc *sc); static TW_VOID twa_map_load_data_callback(TW_VOID *arg, bus_dma_segment_t *segs, TW_INT32 nsegments, TW_INT32 error); static TW_VOID twa_map_load_callback(TW_VOID *arg, bus_dma_segment_t *segs, TW_INT32 nsegments, TW_INT32 error); static device_method_t twa_methods[] = { /* Device interface */ DEVMETHOD(device_probe, twa_probe), DEVMETHOD(device_attach, twa_attach), DEVMETHOD(device_detach, twa_detach), DEVMETHOD(device_shutdown, twa_shutdown), DEVMETHOD_END }; static driver_t twa_pci_driver = { "twa", twa_methods, sizeof(struct twa_softc) }; DRIVER_MODULE(twa, pci, twa_pci_driver, twa_devclass, 0, 0); MODULE_DEPEND(twa, cam, 1, 1, 1); MODULE_DEPEND(twa, pci, 1, 1, 1); /* * Function name: twa_probe * Description: Called at driver load time. Claims 9000 ctlrs. * * Input: dev -- bus device corresponding to the ctlr * Output: None * Return value: <= 0 -- success * > 0 -- failure */ static TW_INT32 twa_probe(device_t dev) { static TW_UINT8 first_ctlr = 1; tw_osli_dbg_printf(3, "entered"); if (tw_cl_ctlr_supported(pci_get_vendor(dev), pci_get_device(dev))) { device_set_desc(dev, TW_OSLI_DEVICE_NAME); /* Print the driver version only once. */ if (first_ctlr) { printf("3ware device driver for 9000 series storage " "controllers, version: %s\n", TW_OSL_DRIVER_VERSION_STRING); first_ctlr = 0; } return(0); } return(ENXIO); } int twa_setup_intr(struct twa_softc *sc) { int error = 0; if (!(sc->intr_handle) && (sc->irq_res)) { error = bus_setup_intr(sc->bus_dev, sc->irq_res, INTR_TYPE_CAM | INTR_MPSAFE, NULL, twa_pci_intr, sc, &sc->intr_handle); } return( error ); } int twa_teardown_intr(struct twa_softc *sc) { int error = 0; if ((sc->intr_handle) && (sc->irq_res)) { error = bus_teardown_intr(sc->bus_dev, sc->irq_res, sc->intr_handle); sc->intr_handle = NULL; } return( error ); } /* * Function name: twa_attach * Description: Allocates pci resources; updates sc; adds a node to the * sysctl tree to expose the driver version; makes calls * (to the Common Layer) to initialize ctlr, and to * attach to CAM. * * Input: dev -- bus device corresponding to the ctlr * Output: None * Return value: 0 -- success * non-zero-- failure */ static TW_INT32 twa_attach(device_t dev) { struct twa_softc *sc = device_get_softc(dev); TW_UINT32 command; TW_INT32 bar_num; TW_INT32 bar0_offset; TW_INT32 bar_size; TW_INT32 error; tw_osli_dbg_dprintf(3, sc, "entered"); sc->ctlr_handle.osl_ctlr_ctxt = sc; /* Initialize the softc structure. */ sc->bus_dev = dev; sc->device_id = pci_get_device(dev); /* Initialize the mutexes right here. */ sc->io_lock = &(sc->io_lock_handle); mtx_init(sc->io_lock, "tw_osl_io_lock", NULL, MTX_SPIN); sc->q_lock = &(sc->q_lock_handle); mtx_init(sc->q_lock, "tw_osl_q_lock", NULL, MTX_SPIN); sc->sim_lock = &(sc->sim_lock_handle); mtx_init(sc->sim_lock, "tw_osl_sim_lock", NULL, MTX_DEF | MTX_RECURSE); sysctl_ctx_init(&sc->sysctl_ctxt); sc->sysctl_tree = SYSCTL_ADD_NODE(&sc->sysctl_ctxt, SYSCTL_STATIC_CHILDREN(_hw), OID_AUTO, device_get_nameunit(dev), CTLFLAG_RD, 0, ""); if (sc->sysctl_tree == NULL) { tw_osli_printf(sc, "error = %d", TW_CL_SEVERITY_ERROR_STRING, TW_CL_MESSAGE_SOURCE_FREEBSD_DRIVER, 0x2000, "Cannot add sysctl tree node", ENXIO); return(ENXIO); } SYSCTL_ADD_STRING(&sc->sysctl_ctxt, SYSCTL_CHILDREN(sc->sysctl_tree), OID_AUTO, "driver_version", CTLFLAG_RD, TW_OSL_DRIVER_VERSION_STRING, 0, "TWA driver version"); /* Make sure we are going to be able to talk to this board. */ command = pci_read_config(dev, PCIR_COMMAND, 2); if ((command & PCIM_CMD_PORTEN) == 0) { tw_osli_printf(sc, "error = %d", TW_CL_SEVERITY_ERROR_STRING, TW_CL_MESSAGE_SOURCE_FREEBSD_DRIVER, 0x2001, "Register window not available", ENXIO); tw_osli_free_resources(sc); return(ENXIO); } /* Force the busmaster enable bit on, in case the BIOS forgot. */ command |= PCIM_CMD_BUSMASTEREN; pci_write_config(dev, PCIR_COMMAND, command, 2); /* Allocate the PCI register window. */ if ((error = tw_cl_get_pci_bar_info(sc->device_id, TW_CL_BAR_TYPE_MEM, &bar_num, &bar0_offset, &bar_size))) { tw_osli_printf(sc, "error = %d", TW_CL_SEVERITY_ERROR_STRING, TW_CL_MESSAGE_SOURCE_FREEBSD_DRIVER, 0x201F, "Can't get PCI BAR info", error); tw_osli_free_resources(sc); return(error); } sc->reg_res_id = PCIR_BARS + bar0_offset; if ((sc->reg_res = bus_alloc_resource(dev, SYS_RES_MEMORY, &(sc->reg_res_id), 0, ~0, 1, RF_ACTIVE)) == NULL) { tw_osli_printf(sc, "error = %d", TW_CL_SEVERITY_ERROR_STRING, TW_CL_MESSAGE_SOURCE_FREEBSD_DRIVER, 0x2002, "Can't allocate register window", ENXIO); tw_osli_free_resources(sc); return(ENXIO); } sc->bus_tag = rman_get_bustag(sc->reg_res); sc->bus_handle = rman_get_bushandle(sc->reg_res); /* Allocate and register our interrupt. */ sc->irq_res_id = 0; if ((sc->irq_res = bus_alloc_resource(sc->bus_dev, SYS_RES_IRQ, &(sc->irq_res_id), 0, ~0, 1, RF_SHAREABLE | RF_ACTIVE)) == NULL) { tw_osli_printf(sc, "error = %d", TW_CL_SEVERITY_ERROR_STRING, TW_CL_MESSAGE_SOURCE_FREEBSD_DRIVER, 0x2003, "Can't allocate interrupt", ENXIO); tw_osli_free_resources(sc); return(ENXIO); } if ((error = twa_setup_intr(sc))) { tw_osli_printf(sc, "error = %d", TW_CL_SEVERITY_ERROR_STRING, TW_CL_MESSAGE_SOURCE_FREEBSD_DRIVER, 0x2004, "Can't set up interrupt", error); tw_osli_free_resources(sc); return(error); } if ((error = tw_osli_alloc_mem(sc))) { tw_osli_printf(sc, "error = %d", TW_CL_SEVERITY_ERROR_STRING, TW_CL_MESSAGE_SOURCE_FREEBSD_DRIVER, 0x2005, "Memory allocation failure", error); tw_osli_free_resources(sc); return(error); } /* Initialize the Common Layer for this controller. */ if ((error = tw_cl_init_ctlr(&sc->ctlr_handle, sc->flags, sc->device_id, TW_OSLI_MAX_NUM_REQUESTS, TW_OSLI_MAX_NUM_AENS, sc->non_dma_mem, sc->dma_mem, sc->dma_mem_phys ))) { tw_osli_printf(sc, "error = %d", TW_CL_SEVERITY_ERROR_STRING, TW_CL_MESSAGE_SOURCE_FREEBSD_DRIVER, 0x2006, "Failed to initialize Common Layer/controller", error); tw_osli_free_resources(sc); return(error); } /* Create the control device. */ sc->ctrl_dev = make_dev(&twa_cdevsw, device_get_unit(sc->bus_dev), UID_ROOT, GID_OPERATOR, S_IRUSR | S_IWUSR, "twa%d", device_get_unit(sc->bus_dev)); sc->ctrl_dev->si_drv1 = sc; if ((error = tw_osli_cam_attach(sc))) { tw_osli_free_resources(sc); tw_osli_printf(sc, "error = %d", TW_CL_SEVERITY_ERROR_STRING, TW_CL_MESSAGE_SOURCE_FREEBSD_DRIVER, 0x2007, "Failed to initialize CAM", error); return(error); } sc->watchdog_index = 0; callout_init(&(sc->watchdog_callout[0]), CALLOUT_MPSAFE); callout_init(&(sc->watchdog_callout[1]), CALLOUT_MPSAFE); callout_reset(&(sc->watchdog_callout[0]), 5*hz, twa_watchdog, &sc->ctlr_handle); return(0); } static TW_VOID twa_watchdog(TW_VOID *arg) { struct tw_cl_ctlr_handle *ctlr_handle = (struct tw_cl_ctlr_handle *)arg; struct twa_softc *sc = ctlr_handle->osl_ctlr_ctxt; int i; int i_need_a_reset = 0; int driver_is_active = 0; int my_watchdog_was_pending = 1234; TW_UINT64 current_time; struct tw_osli_req_context *my_req; //============================================================================== current_time = (TW_UINT64) (tw_osl_get_local_time()); for (i = 0; i < TW_OSLI_MAX_NUM_REQUESTS; i++) { my_req = &(sc->req_ctx_buf[i]); if ((my_req->state == TW_OSLI_REQ_STATE_BUSY) && (my_req->deadline) && (my_req->deadline < current_time)) { tw_cl_set_reset_needed(ctlr_handle); #ifdef TW_OSL_DEBUG device_printf((sc)->bus_dev, "Request %d timed out! d = %llu, c = %llu\n", i, my_req->deadline, current_time); #else /* TW_OSL_DEBUG */ device_printf((sc)->bus_dev, "Request %d timed out!\n", i); #endif /* TW_OSL_DEBUG */ break; } } //============================================================================== i_need_a_reset = tw_cl_is_reset_needed(ctlr_handle); i = (int) ((sc->watchdog_index++) & 1); driver_is_active = tw_cl_is_active(ctlr_handle); if (i_need_a_reset) { #ifdef TW_OSL_DEBUG device_printf((sc)->bus_dev, "Watchdog rescheduled in 70 seconds\n"); #endif /* TW_OSL_DEBUG */ my_watchdog_was_pending = callout_reset(&(sc->watchdog_callout[i]), 70*hz, twa_watchdog, &sc->ctlr_handle); tw_cl_reset_ctlr(ctlr_handle); #ifdef TW_OSL_DEBUG device_printf((sc)->bus_dev, "Watchdog reset completed!\n"); #endif /* TW_OSL_DEBUG */ } else if (driver_is_active) { my_watchdog_was_pending = callout_reset(&(sc->watchdog_callout[i]), 5*hz, twa_watchdog, &sc->ctlr_handle); } #ifdef TW_OSL_DEBUG if (i_need_a_reset || my_watchdog_was_pending) device_printf((sc)->bus_dev, "i_need_a_reset = %d, " "driver_is_active = %d, my_watchdog_was_pending = %d\n", i_need_a_reset, driver_is_active, my_watchdog_was_pending); #endif /* TW_OSL_DEBUG */ } /* * Function name: tw_osli_alloc_mem * Description: Allocates memory needed both by CL and OSL. * * Input: sc -- OSL internal controller context * Output: None * Return value: 0 -- success * non-zero-- failure */ static TW_INT32 tw_osli_alloc_mem(struct twa_softc *sc) { struct tw_osli_req_context *req; TW_UINT32 max_sg_elements; TW_UINT32 non_dma_mem_size; TW_UINT32 dma_mem_size; TW_INT32 error; TW_INT32 i; tw_osli_dbg_dprintf(3, sc, "entered"); sc->flags |= (sizeof(bus_addr_t) == 8) ? TW_CL_64BIT_ADDRESSES : 0; sc->flags |= (sizeof(bus_size_t) == 8) ? TW_CL_64BIT_SG_LENGTH : 0; max_sg_elements = (sizeof(bus_addr_t) == 8) ? TW_CL_MAX_64BIT_SG_ELEMENTS : TW_CL_MAX_32BIT_SG_ELEMENTS; if ((error = tw_cl_get_mem_requirements(&sc->ctlr_handle, sc->flags, sc->device_id, TW_OSLI_MAX_NUM_REQUESTS, TW_OSLI_MAX_NUM_AENS, &(sc->alignment), &(sc->sg_size_factor), &non_dma_mem_size, &dma_mem_size ))) { tw_osli_printf(sc, "error = %d", TW_CL_SEVERITY_ERROR_STRING, TW_CL_MESSAGE_SOURCE_FREEBSD_DRIVER, 0x2008, "Can't get Common Layer's memory requirements", error); return(error); } if ((sc->non_dma_mem = malloc(non_dma_mem_size, TW_OSLI_MALLOC_CLASS, M_WAITOK)) == NULL) { tw_osli_printf(sc, "error = %d", TW_CL_SEVERITY_ERROR_STRING, TW_CL_MESSAGE_SOURCE_FREEBSD_DRIVER, 0x2009, "Can't allocate non-dma memory", ENOMEM); return(ENOMEM); } /* Create the parent dma tag. */ if (bus_dma_tag_create(bus_get_dma_tag(sc->bus_dev), /* parent */ sc->alignment, /* alignment */ 0, /* boundary */ BUS_SPACE_MAXADDR, /* lowaddr */ BUS_SPACE_MAXADDR, /* highaddr */ NULL, NULL, /* filter, filterarg */ TW_CL_MAX_IO_SIZE, /* maxsize */ max_sg_elements, /* nsegments */ TW_CL_MAX_IO_SIZE, /* maxsegsize */ 0, /* flags */ NULL, /* lockfunc */ NULL, /* lockfuncarg */ &sc->parent_tag /* tag */)) { tw_osli_printf(sc, "error = %d", TW_CL_SEVERITY_ERROR_STRING, TW_CL_MESSAGE_SOURCE_FREEBSD_DRIVER, 0x200A, "Can't allocate parent DMA tag", ENOMEM); return(ENOMEM); } /* Create a dma tag for Common Layer's DMA'able memory (dma_mem). */ if (bus_dma_tag_create(sc->parent_tag, /* parent */ sc->alignment, /* alignment */ 0, /* boundary */ BUS_SPACE_MAXADDR, /* lowaddr */ BUS_SPACE_MAXADDR, /* highaddr */ NULL, NULL, /* filter, filterarg */ dma_mem_size, /* maxsize */ 1, /* nsegments */ BUS_SPACE_MAXSIZE, /* maxsegsize */ 0, /* flags */ NULL, /* lockfunc */ NULL, /* lockfuncarg */ &sc->cmd_tag /* tag */)) { tw_osli_printf(sc, "error = %d", TW_CL_SEVERITY_ERROR_STRING, TW_CL_MESSAGE_SOURCE_FREEBSD_DRIVER, 0x200B, "Can't allocate DMA tag for Common Layer's " "DMA'able memory", ENOMEM); return(ENOMEM); } if (bus_dmamem_alloc(sc->cmd_tag, &sc->dma_mem, BUS_DMA_NOWAIT, &sc->cmd_map)) { /* Try a second time. */ if (bus_dmamem_alloc(sc->cmd_tag, &sc->dma_mem, BUS_DMA_NOWAIT, &sc->cmd_map)) { tw_osli_printf(sc, "error = %d", TW_CL_SEVERITY_ERROR_STRING, TW_CL_MESSAGE_SOURCE_FREEBSD_DRIVER, 0x200C, "Can't allocate DMA'able memory for the" "Common Layer", ENOMEM); return(ENOMEM); } } bus_dmamap_load(sc->cmd_tag, sc->cmd_map, sc->dma_mem, dma_mem_size, twa_map_load_callback, &sc->dma_mem_phys, 0); /* * Create a dma tag for data buffers; size will be the maximum * possible I/O size (128kB). */ if (bus_dma_tag_create(sc->parent_tag, /* parent */ sc->alignment, /* alignment */ 0, /* boundary */ BUS_SPACE_MAXADDR, /* lowaddr */ BUS_SPACE_MAXADDR, /* highaddr */ NULL, NULL, /* filter, filterarg */ TW_CL_MAX_IO_SIZE, /* maxsize */ max_sg_elements, /* nsegments */ TW_CL_MAX_IO_SIZE, /* maxsegsize */ BUS_DMA_ALLOCNOW, /* flags */ twa_busdma_lock, /* lockfunc */ sc->io_lock, /* lockfuncarg */ &sc->dma_tag /* tag */)) { tw_osli_printf(sc, "error = %d", TW_CL_SEVERITY_ERROR_STRING, TW_CL_MESSAGE_SOURCE_FREEBSD_DRIVER, 0x200F, "Can't allocate DMA tag for data buffers", ENOMEM); return(ENOMEM); } /* * Create a dma tag for ioctl data buffers; size will be the maximum * possible I/O size (128kB). */ if (bus_dma_tag_create(sc->parent_tag, /* parent */ sc->alignment, /* alignment */ 0, /* boundary */ BUS_SPACE_MAXADDR, /* lowaddr */ BUS_SPACE_MAXADDR, /* highaddr */ NULL, NULL, /* filter, filterarg */ TW_CL_MAX_IO_SIZE, /* maxsize */ max_sg_elements, /* nsegments */ TW_CL_MAX_IO_SIZE, /* maxsegsize */ BUS_DMA_ALLOCNOW, /* flags */ twa_busdma_lock, /* lockfunc */ sc->io_lock, /* lockfuncarg */ &sc->ioctl_tag /* tag */)) { tw_osli_printf(sc, "error = %d", TW_CL_SEVERITY_ERROR_STRING, TW_CL_MESSAGE_SOURCE_FREEBSD_DRIVER, 0x2010, "Can't allocate DMA tag for ioctl data buffers", ENOMEM); return(ENOMEM); } /* Create just one map for all ioctl request data buffers. */ if (bus_dmamap_create(sc->ioctl_tag, 0, &sc->ioctl_map)) { tw_osli_printf(sc, "error = %d", TW_CL_SEVERITY_ERROR_STRING, TW_CL_MESSAGE_SOURCE_FREEBSD_DRIVER, 0x2011, "Can't create ioctl map", ENOMEM); return(ENOMEM); } /* Initialize request queues. */ tw_osli_req_q_init(sc, TW_OSLI_FREE_Q); tw_osli_req_q_init(sc, TW_OSLI_BUSY_Q); if ((sc->req_ctx_buf = (struct tw_osli_req_context *) malloc((sizeof(struct tw_osli_req_context) * TW_OSLI_MAX_NUM_REQUESTS), TW_OSLI_MALLOC_CLASS, M_WAITOK)) == NULL) { tw_osli_printf(sc, "error = %d", TW_CL_SEVERITY_ERROR_STRING, TW_CL_MESSAGE_SOURCE_FREEBSD_DRIVER, 0x2012, "Failed to allocate request packets", ENOMEM); return(ENOMEM); } bzero(sc->req_ctx_buf, sizeof(struct tw_osli_req_context) * TW_OSLI_MAX_NUM_REQUESTS); for (i = 0; i < TW_OSLI_MAX_NUM_REQUESTS; i++) { req = &(sc->req_ctx_buf[i]); req->ctlr = sc; if (bus_dmamap_create(sc->dma_tag, 0, &req->dma_map)) { tw_osli_printf(sc, "request # = %d, error = %d", TW_CL_SEVERITY_ERROR_STRING, TW_CL_MESSAGE_SOURCE_FREEBSD_DRIVER, 0x2013, "Can't create dma map", i, ENOMEM); return(ENOMEM); } /* Initialize the ioctl wakeup/ timeout mutex */ req->ioctl_wake_timeout_lock = &(req->ioctl_wake_timeout_lock_handle); mtx_init(req->ioctl_wake_timeout_lock, "tw_ioctl_wake_timeout_lock", NULL, MTX_DEF); /* Insert request into the free queue. */ tw_osli_req_q_insert_tail(req, TW_OSLI_FREE_Q); } return(0); } /* * Function name: tw_osli_free_resources * Description: Performs clean-up at the time of going down. * * Input: sc -- ptr to OSL internal ctlr context * Output: None * Return value: None */ static TW_VOID tw_osli_free_resources(struct twa_softc *sc) { struct tw_osli_req_context *req; TW_INT32 error = 0; tw_osli_dbg_dprintf(3, sc, "entered"); /* Detach from CAM */ tw_osli_cam_detach(sc); if (sc->req_ctx_buf) while ((req = tw_osli_req_q_remove_head(sc, TW_OSLI_FREE_Q)) != NULL) { mtx_destroy(req->ioctl_wake_timeout_lock); if ((error = bus_dmamap_destroy(sc->dma_tag, req->dma_map))) tw_osli_dbg_dprintf(1, sc, "dmamap_destroy(dma) returned %d", error); } if ((sc->ioctl_tag) && (sc->ioctl_map)) if ((error = bus_dmamap_destroy(sc->ioctl_tag, sc->ioctl_map))) tw_osli_dbg_dprintf(1, sc, "dmamap_destroy(ioctl) returned %d", error); /* Free all memory allocated so far. */ if (sc->req_ctx_buf) free(sc->req_ctx_buf, TW_OSLI_MALLOC_CLASS); if (sc->non_dma_mem) free(sc->non_dma_mem, TW_OSLI_MALLOC_CLASS); if (sc->dma_mem) { bus_dmamap_unload(sc->cmd_tag, sc->cmd_map); bus_dmamem_free(sc->cmd_tag, sc->dma_mem, sc->cmd_map); } if (sc->cmd_tag) if ((error = bus_dma_tag_destroy(sc->cmd_tag))) tw_osli_dbg_dprintf(1, sc, "dma_tag_destroy(cmd) returned %d", error); if (sc->dma_tag) if ((error = bus_dma_tag_destroy(sc->dma_tag))) tw_osli_dbg_dprintf(1, sc, "dma_tag_destroy(dma) returned %d", error); if (sc->ioctl_tag) if ((error = bus_dma_tag_destroy(sc->ioctl_tag))) tw_osli_dbg_dprintf(1, sc, "dma_tag_destroy(ioctl) returned %d", error); if (sc->parent_tag) if ((error = bus_dma_tag_destroy(sc->parent_tag))) tw_osli_dbg_dprintf(1, sc, "dma_tag_destroy(parent) returned %d", error); /* Disconnect the interrupt handler. */ if ((error = twa_teardown_intr(sc))) tw_osli_dbg_dprintf(1, sc, "teardown_intr returned %d", error); if (sc->irq_res != NULL) if ((error = bus_release_resource(sc->bus_dev, SYS_RES_IRQ, sc->irq_res_id, sc->irq_res))) tw_osli_dbg_dprintf(1, sc, "release_resource(irq) returned %d", error); /* Release the register window mapping. */ if (sc->reg_res != NULL) if ((error = bus_release_resource(sc->bus_dev, SYS_RES_MEMORY, sc->reg_res_id, sc->reg_res))) tw_osli_dbg_dprintf(1, sc, "release_resource(io) returned %d", error); /* Destroy the control device. */ if (sc->ctrl_dev != (struct cdev *)NULL) destroy_dev(sc->ctrl_dev); if ((error = sysctl_ctx_free(&sc->sysctl_ctxt))) tw_osli_dbg_dprintf(1, sc, "sysctl_ctx_free returned %d", error); } /* * Function name: twa_detach * Description: Called when the controller is being detached from * the pci bus. * * Input: dev -- bus device corresponding to the ctlr * Output: None * Return value: 0 -- success * non-zero-- failure */ static TW_INT32 twa_detach(device_t dev) { struct twa_softc *sc = device_get_softc(dev); TW_INT32 error; tw_osli_dbg_dprintf(3, sc, "entered"); error = EBUSY; if (sc->open) { tw_osli_printf(sc, "error = %d", TW_CL_SEVERITY_ERROR_STRING, TW_CL_MESSAGE_SOURCE_FREEBSD_DRIVER, 0x2014, "Device open", error); goto out; } /* Shut the controller down. */ if ((error = twa_shutdown(dev))) goto out; /* Free all resources associated with this controller. */ tw_osli_free_resources(sc); error = 0; out: return(error); } /* * Function name: twa_shutdown * Description: Called at unload/shutdown time. Lets the controller * know that we are going down. * * Input: dev -- bus device corresponding to the ctlr * Output: None * Return value: 0 -- success * non-zero-- failure */ static TW_INT32 twa_shutdown(device_t dev) { struct twa_softc *sc = device_get_softc(dev); TW_INT32 error = 0; tw_osli_dbg_dprintf(3, sc, "entered"); /* Disconnect interrupts. */ error = twa_teardown_intr(sc); /* Stop watchdog task. */ callout_drain(&(sc->watchdog_callout[0])); callout_drain(&(sc->watchdog_callout[1])); /* Disconnect from the controller. */ if ((error = tw_cl_shutdown_ctlr(&(sc->ctlr_handle), 0))) { tw_osli_printf(sc, "error = %d", TW_CL_SEVERITY_ERROR_STRING, TW_CL_MESSAGE_SOURCE_FREEBSD_DRIVER, 0x2015, "Failed to shutdown Common Layer/controller", error); } return(error); } /* * Function name: twa_busdma_lock * Description: Function to provide synchronization during busdma_swi. * * Input: lock_arg -- lock mutex sent as argument * op -- operation (lock/unlock) expected of the function * Output: None * Return value: None */ TW_VOID twa_busdma_lock(TW_VOID *lock_arg, bus_dma_lock_op_t op) { struct mtx *lock; lock = (struct mtx *)lock_arg; switch (op) { case BUS_DMA_LOCK: mtx_lock_spin(lock); break; case BUS_DMA_UNLOCK: mtx_unlock_spin(lock); break; default: panic("Unknown operation 0x%x for twa_busdma_lock!", op); } } /* * Function name: twa_pci_intr * Description: Interrupt handler. Wrapper for twa_interrupt. * * Input: arg -- ptr to OSL internal ctlr context * Output: None * Return value: None */ static TW_VOID twa_pci_intr(TW_VOID *arg) { struct twa_softc *sc = (struct twa_softc *)arg; tw_osli_dbg_dprintf(10, sc, "entered"); tw_cl_interrupt(&(sc->ctlr_handle)); } /* * Function name: tw_osli_fw_passthru * Description: Builds a fw passthru cmd pkt, and submits it to CL. * * Input: sc -- ptr to OSL internal ctlr context * buf -- ptr to ioctl pkt understood by CL * Output: None * Return value: 0 -- success * non-zero-- failure */ TW_INT32 tw_osli_fw_passthru(struct twa_softc *sc, TW_INT8 *buf) { struct tw_osli_req_context *req; struct tw_osli_ioctl_no_data_buf *user_buf = (struct tw_osli_ioctl_no_data_buf *)buf; TW_TIME end_time; TW_UINT32 timeout = 60; TW_UINT32 data_buf_size_adjusted; struct tw_cl_req_packet *req_pkt; struct tw_cl_passthru_req_packet *pt_req; TW_INT32 error; tw_osli_dbg_dprintf(5, sc, "ioctl: passthru"); if ((req = tw_osli_get_request(sc)) == NULL) return(EBUSY); req->req_handle.osl_req_ctxt = req; req->orig_req = buf; req->flags |= TW_OSLI_REQ_FLAGS_PASSTHRU; req_pkt = &(req->req_pkt); req_pkt->status = 0; req_pkt->tw_osl_callback = tw_osl_complete_passthru; /* Let the Common Layer retry the request on cmd queue full. */ req_pkt->flags |= TW_CL_REQ_RETRY_ON_BUSY; pt_req = &(req_pkt->gen_req_pkt.pt_req); /* * Make sure that the data buffer sent to firmware is a * 512 byte multiple in size. */ data_buf_size_adjusted = (user_buf->driver_pkt.buffer_length + (sc->sg_size_factor - 1)) & ~(sc->sg_size_factor - 1); if ((req->length = data_buf_size_adjusted)) { if ((req->data = malloc(data_buf_size_adjusted, TW_OSLI_MALLOC_CLASS, M_WAITOK)) == NULL) { error = ENOMEM; tw_osli_printf(sc, "error = %d", TW_CL_SEVERITY_ERROR_STRING, TW_CL_MESSAGE_SOURCE_FREEBSD_DRIVER, 0x2016, "Could not alloc mem for " "fw_passthru data_buf", error); goto fw_passthru_err; } /* Copy the payload. */ if ((error = copyin((TW_VOID *)(user_buf->pdata), req->data, user_buf->driver_pkt.buffer_length)) != 0) { tw_osli_printf(sc, "error = %d", TW_CL_SEVERITY_ERROR_STRING, TW_CL_MESSAGE_SOURCE_FREEBSD_DRIVER, 0x2017, "Could not copyin fw_passthru data_buf", error); goto fw_passthru_err; } pt_req->sgl_entries = 1; /* will be updated during mapping */ req->flags |= (TW_OSLI_REQ_FLAGS_DATA_IN | TW_OSLI_REQ_FLAGS_DATA_OUT); } else pt_req->sgl_entries = 0; /* no payload */ pt_req->cmd_pkt = (TW_VOID *)(&(user_buf->cmd_pkt)); pt_req->cmd_pkt_length = sizeof(struct tw_cl_command_packet); if ((error = tw_osli_map_request(req))) goto fw_passthru_err; end_time = tw_osl_get_local_time() + timeout; while (req->state != TW_OSLI_REQ_STATE_COMPLETE) { mtx_lock(req->ioctl_wake_timeout_lock); req->flags |= TW_OSLI_REQ_FLAGS_SLEEPING; error = mtx_sleep(req, req->ioctl_wake_timeout_lock, 0, "twa_passthru", timeout*hz); mtx_unlock(req->ioctl_wake_timeout_lock); if (!(req->flags & TW_OSLI_REQ_FLAGS_SLEEPING)) error = 0; req->flags &= ~TW_OSLI_REQ_FLAGS_SLEEPING; if (! error) { if (((error = req->error_code)) || ((error = (req->state != TW_OSLI_REQ_STATE_COMPLETE))) || ((error = req_pkt->status))) goto fw_passthru_err; break; } if (req_pkt->status) { error = req_pkt->status; goto fw_passthru_err; } if (error == EWOULDBLOCK) { /* Time out! */ if ((!(req->error_code)) && (req->state == TW_OSLI_REQ_STATE_COMPLETE) && (!(req_pkt->status)) ) { #ifdef TW_OSL_DEBUG tw_osli_printf(sc, "request = %p", TW_CL_SEVERITY_ERROR_STRING, TW_CL_MESSAGE_SOURCE_FREEBSD_DRIVER, 0x7777, "FALSE Passthru timeout!", req); #endif /* TW_OSL_DEBUG */ error = 0; /* False error */ break; } if (!(tw_cl_is_reset_needed(&(req->ctlr->ctlr_handle)))) { #ifdef TW_OSL_DEBUG tw_osli_printf(sc, "request = %p", TW_CL_SEVERITY_ERROR_STRING, TW_CL_MESSAGE_SOURCE_FREEBSD_DRIVER, 0x2018, "Passthru request timed out!", req); #else /* TW_OSL_DEBUG */ device_printf((sc)->bus_dev, "Passthru request timed out!\n"); #endif /* TW_OSL_DEBUG */ tw_cl_reset_ctlr(&(req->ctlr->ctlr_handle)); } error = 0; end_time = tw_osl_get_local_time() + timeout; continue; /* * Don't touch req after a reset. It (and any * associated data) will be * unmapped by the callback. */ } /* * Either the request got completed, or we were woken up by a * signal. Calculate the new timeout, in case it was the latter. */ timeout = (end_time - tw_osl_get_local_time()); } /* End of while loop */ /* If there was a payload, copy it back. */ if ((!error) && (req->length)) if ((error = copyout(req->data, user_buf->pdata, user_buf->driver_pkt.buffer_length))) tw_osli_printf(sc, "error = %d", TW_CL_SEVERITY_ERROR_STRING, TW_CL_MESSAGE_SOURCE_FREEBSD_DRIVER, 0x2019, "Could not copyout fw_passthru data_buf", error); fw_passthru_err: if (req_pkt->status == TW_CL_ERR_REQ_BUS_RESET) error = EBUSY; user_buf->driver_pkt.os_status = error; /* Free resources. */ if (req->data) free(req->data, TW_OSLI_MALLOC_CLASS); tw_osli_req_q_insert_tail(req, TW_OSLI_FREE_Q); return(error); } /* * Function name: tw_osl_complete_passthru * Description: Called to complete passthru requests. * * Input: req_handle -- ptr to request handle * Output: None * Return value: None */ TW_VOID tw_osl_complete_passthru(struct tw_cl_req_handle *req_handle) { struct tw_osli_req_context *req = req_handle->osl_req_ctxt; struct tw_cl_req_packet *req_pkt = (struct tw_cl_req_packet *)(&req->req_pkt); struct twa_softc *sc = req->ctlr; tw_osli_dbg_dprintf(5, sc, "entered"); if (req->state != TW_OSLI_REQ_STATE_BUSY) { tw_osli_printf(sc, "request = %p, status = %d", TW_CL_SEVERITY_ERROR_STRING, TW_CL_MESSAGE_SOURCE_FREEBSD_DRIVER, 0x201B, "Unposted command completed!!", req, req->state); } /* * Remove request from the busy queue. Just mark it complete. * There's no need to move it into the complete queue as we are * going to be done with it right now. */ req->state = TW_OSLI_REQ_STATE_COMPLETE; tw_osli_req_q_remove_item(req, TW_OSLI_BUSY_Q); tw_osli_unmap_request(req); /* * Don't do a wake up if there was an error even before the request * was sent down to the Common Layer, and we hadn't gotten an * EINPROGRESS. The request originator will then be returned an * error, and he can do the clean-up. */ if ((req->error_code) && (!(req->flags & TW_OSLI_REQ_FLAGS_IN_PROGRESS))) return; if (req->flags & TW_OSLI_REQ_FLAGS_PASSTHRU) { if (req->flags & TW_OSLI_REQ_FLAGS_SLEEPING) { /* Wake up the sleeping command originator. */ tw_osli_dbg_dprintf(5, sc, "Waking up originator of request %p", req); req->flags &= ~TW_OSLI_REQ_FLAGS_SLEEPING; wakeup_one(req); } else { /* * If the request completed even before mtx_sleep * was called, simply return. */ if (req->flags & TW_OSLI_REQ_FLAGS_MAPPED) return; if (req_pkt->status == TW_CL_ERR_REQ_BUS_RESET) return; tw_osli_printf(sc, "request = %p", TW_CL_SEVERITY_ERROR_STRING, TW_CL_MESSAGE_SOURCE_FREEBSD_DRIVER, 0x201C, "Passthru callback called, " "and caller not sleeping", req); } } else { tw_osli_printf(sc, "request = %p", TW_CL_SEVERITY_ERROR_STRING, TW_CL_MESSAGE_SOURCE_FREEBSD_DRIVER, 0x201D, "Passthru callback called for non-passthru request", req); } } /* * Function name: tw_osli_get_request * Description: Gets a request pkt from the free queue. * * Input: sc -- ptr to OSL internal ctlr context * Output: None * Return value: ptr to request pkt -- success * NULL -- failure */ struct tw_osli_req_context * tw_osli_get_request(struct twa_softc *sc) { struct tw_osli_req_context *req; tw_osli_dbg_dprintf(4, sc, "entered"); /* Get a free request packet. */ req = tw_osli_req_q_remove_head(sc, TW_OSLI_FREE_Q); /* Initialize some fields to their defaults. */ if (req) { req->req_handle.osl_req_ctxt = NULL; req->req_handle.cl_req_ctxt = NULL; req->req_handle.is_io = 0; req->data = NULL; req->length = 0; req->deadline = 0; req->real_data = NULL; req->real_length = 0; req->state = TW_OSLI_REQ_STATE_INIT;/* req being initialized */ req->flags = 0; req->error_code = 0; req->orig_req = NULL; bzero(&(req->req_pkt), sizeof(struct tw_cl_req_packet)); } return(req); } /* * Function name: twa_map_load_data_callback * Description: Callback of bus_dmamap_load for the buffer associated * with data. Updates the cmd pkt (size/sgl_entries * fields, as applicable) to reflect the number of sg * elements. * * Input: arg -- ptr to OSL internal request context * segs -- ptr to a list of segment descriptors * nsegments--# of segments * error -- 0 if no errors encountered before callback, * non-zero if errors were encountered * Output: None * Return value: None */ static TW_VOID twa_map_load_data_callback(TW_VOID *arg, bus_dma_segment_t *segs, TW_INT32 nsegments, TW_INT32 error) { struct tw_osli_req_context *req = (struct tw_osli_req_context *)arg; struct twa_softc *sc = req->ctlr; struct tw_cl_req_packet *req_pkt = &(req->req_pkt); tw_osli_dbg_dprintf(10, sc, "entered"); if (error == EINVAL) { req->error_code = error; return; } /* Mark the request as currently being processed. */ req->state = TW_OSLI_REQ_STATE_BUSY; /* Move the request into the busy queue. */ tw_osli_req_q_insert_tail(req, TW_OSLI_BUSY_Q); req->flags |= TW_OSLI_REQ_FLAGS_MAPPED; if (error == EFBIG) { req->error_code = error; goto out; } if (req->flags & TW_OSLI_REQ_FLAGS_PASSTHRU) { struct tw_cl_passthru_req_packet *pt_req; if (req->flags & TW_OSLI_REQ_FLAGS_DATA_IN) bus_dmamap_sync(sc->ioctl_tag, sc->ioctl_map, BUS_DMASYNC_PREREAD); if (req->flags & TW_OSLI_REQ_FLAGS_DATA_OUT) { /* * If we're using an alignment buffer, and we're * writing data, copy the real data out. */ if (req->flags & TW_OSLI_REQ_FLAGS_DATA_COPY_NEEDED) bcopy(req->real_data, req->data, req->real_length); bus_dmamap_sync(sc->ioctl_tag, sc->ioctl_map, BUS_DMASYNC_PREWRITE); } pt_req = &(req_pkt->gen_req_pkt.pt_req); pt_req->sg_list = (TW_UINT8 *)segs; pt_req->sgl_entries += (nsegments - 1); error = tw_cl_fw_passthru(&(sc->ctlr_handle), req_pkt, &(req->req_handle)); } else { struct tw_cl_scsi_req_packet *scsi_req; if (req->flags & TW_OSLI_REQ_FLAGS_DATA_IN) bus_dmamap_sync(sc->dma_tag, req->dma_map, BUS_DMASYNC_PREREAD); if (req->flags & TW_OSLI_REQ_FLAGS_DATA_OUT) { /* * If we're using an alignment buffer, and we're * writing data, copy the real data out. */ if (req->flags & TW_OSLI_REQ_FLAGS_DATA_COPY_NEEDED) bcopy(req->real_data, req->data, req->real_length); bus_dmamap_sync(sc->dma_tag, req->dma_map, BUS_DMASYNC_PREWRITE); } scsi_req = &(req_pkt->gen_req_pkt.scsi_req); scsi_req->sg_list = (TW_UINT8 *)segs; scsi_req->sgl_entries += (nsegments - 1); error = tw_cl_start_io(&(sc->ctlr_handle), req_pkt, &(req->req_handle)); } out: if (error) { req->error_code = error; req_pkt->tw_osl_callback(&(req->req_handle)); /* * If the caller had been returned EINPROGRESS, and he has * registered a callback for handling completion, the callback * will never get called because we were unable to submit the * request. So, free up the request right here. */ if (req->flags & TW_OSLI_REQ_FLAGS_IN_PROGRESS) tw_osli_req_q_insert_tail(req, TW_OSLI_FREE_Q); } } /* * Function name: twa_map_load_callback * Description: Callback of bus_dmamap_load for the buffer associated * with a cmd pkt. * * Input: arg -- ptr to variable to hold phys addr * segs -- ptr to a list of segment descriptors * nsegments--# of segments * error -- 0 if no errors encountered before callback, * non-zero if errors were encountered * Output: None * Return value: None */ static TW_VOID twa_map_load_callback(TW_VOID *arg, bus_dma_segment_t *segs, TW_INT32 nsegments, TW_INT32 error) { *((bus_addr_t *)arg) = segs[0].ds_addr; } /* * Function name: tw_osli_map_request * Description: Maps a cmd pkt and data associated with it, into * DMA'able memory. * * Input: req -- ptr to request pkt * Output: None * Return value: 0 -- success * non-zero-- failure */ TW_INT32 tw_osli_map_request(struct tw_osli_req_context *req) { struct twa_softc *sc = req->ctlr; TW_INT32 error = 0; tw_osli_dbg_dprintf(10, sc, "entered"); /* If the command involves data, map that too. */ if (req->data != NULL) { /* * It's sufficient for the data pointer to be 4-byte aligned * to work with 9000. However, if 4-byte aligned addresses * are passed to bus_dmamap_load, we can get back sg elements * that are not 512-byte multiples in size. So, we will let * only those buffers that are 512-byte aligned to pass * through, and bounce the rest, so as to make sure that we * always get back sg elements that are 512-byte multiples * in size. */ if (((vm_offset_t)req->data % sc->sg_size_factor) || (req->length % sc->sg_size_factor)) { req->flags |= TW_OSLI_REQ_FLAGS_DATA_COPY_NEEDED; /* Save original data pointer and length. */ req->real_data = req->data; req->real_length = req->length; req->length = (req->length + (sc->sg_size_factor - 1)) & ~(sc->sg_size_factor - 1); req->data = malloc(req->length, TW_OSLI_MALLOC_CLASS, M_NOWAIT); if (req->data == NULL) { tw_osli_printf(sc, "error = %d", TW_CL_SEVERITY_ERROR_STRING, TW_CL_MESSAGE_SOURCE_FREEBSD_DRIVER, 0x201E, "Failed to allocate memory " "for bounce buffer", ENOMEM); /* Restore original data pointer and length. */ req->data = req->real_data; req->length = req->real_length; return(ENOMEM); } } /* * Map the data buffer into bus space and build the SG list. */ if (req->flags & TW_OSLI_REQ_FLAGS_PASSTHRU) { /* Lock against multiple simultaneous ioctl calls. */ mtx_lock_spin(sc->io_lock); error = bus_dmamap_load(sc->ioctl_tag, sc->ioctl_map, req->data, req->length, twa_map_load_data_callback, req, BUS_DMA_WAITOK); mtx_unlock_spin(sc->io_lock); } else { /* * There's only one CAM I/O thread running at a time. * So, there's no need to hold the io_lock. */ error = bus_dmamap_load(sc->dma_tag, req->dma_map, req->data, req->length, twa_map_load_data_callback, req, BUS_DMA_WAITOK); } if (!error) error = req->error_code; else { if (error == EINPROGRESS) { /* * Specifying sc->io_lock as the lockfuncarg * in ...tag_create should protect the access * of ...FLAGS_MAPPED from the callback. */ mtx_lock_spin(sc->io_lock); if (!(req->flags & TW_OSLI_REQ_FLAGS_MAPPED)) req->flags |= TW_OSLI_REQ_FLAGS_IN_PROGRESS; tw_osli_disallow_new_requests(sc, &(req->req_handle)); mtx_unlock_spin(sc->io_lock); error = 0; } else { tw_osli_printf(sc, "error = %d", TW_CL_SEVERITY_ERROR_STRING, TW_CL_MESSAGE_SOURCE_FREEBSD_DRIVER, 0x9999, "Failed to map DMA memory " "for I/O request", error); req->flags |= TW_OSLI_REQ_FLAGS_FAILED; /* Free alignment buffer if it was used. */ if (req->flags & TW_OSLI_REQ_FLAGS_DATA_COPY_NEEDED) { free(req->data, TW_OSLI_MALLOC_CLASS); /* * Restore original data pointer * and length. */ req->data = req->real_data; req->length = req->real_length; } } } } else { /* Mark the request as currently being processed. */ req->state = TW_OSLI_REQ_STATE_BUSY; /* Move the request into the busy queue. */ tw_osli_req_q_insert_tail(req, TW_OSLI_BUSY_Q); if (req->flags & TW_OSLI_REQ_FLAGS_PASSTHRU) error = tw_cl_fw_passthru(&sc->ctlr_handle, &(req->req_pkt), &(req->req_handle)); else error = tw_cl_start_io(&sc->ctlr_handle, &(req->req_pkt), &(req->req_handle)); if (error) { req->error_code = error; req->req_pkt.tw_osl_callback(&(req->req_handle)); } } return(error); } /* * Function name: tw_osli_unmap_request * Description: Undoes the mapping done by tw_osli_map_request. * * Input: req -- ptr to request pkt * Output: None * Return value: None */ TW_VOID tw_osli_unmap_request(struct tw_osli_req_context *req) { struct twa_softc *sc = req->ctlr; tw_osli_dbg_dprintf(10, sc, "entered"); /* If the command involved data, unmap that too. */ if (req->data != NULL) { if (req->flags & TW_OSLI_REQ_FLAGS_PASSTHRU) { /* Lock against multiple simultaneous ioctl calls. */ mtx_lock_spin(sc->io_lock); if (req->flags & TW_OSLI_REQ_FLAGS_DATA_IN) { bus_dmamap_sync(sc->ioctl_tag, sc->ioctl_map, BUS_DMASYNC_POSTREAD); /* * If we are using a bounce buffer, and we are * reading data, copy the real data in. */ if (req->flags & TW_OSLI_REQ_FLAGS_DATA_COPY_NEEDED) bcopy(req->data, req->real_data, req->real_length); } if (req->flags & TW_OSLI_REQ_FLAGS_DATA_OUT) bus_dmamap_sync(sc->ioctl_tag, sc->ioctl_map, BUS_DMASYNC_POSTWRITE); bus_dmamap_unload(sc->ioctl_tag, sc->ioctl_map); mtx_unlock_spin(sc->io_lock); } else { if (req->flags & TW_OSLI_REQ_FLAGS_DATA_IN) { bus_dmamap_sync(sc->dma_tag, req->dma_map, BUS_DMASYNC_POSTREAD); /* * If we are using a bounce buffer, and we are * reading data, copy the real data in. */ if (req->flags & TW_OSLI_REQ_FLAGS_DATA_COPY_NEEDED) bcopy(req->data, req->real_data, req->real_length); } if (req->flags & TW_OSLI_REQ_FLAGS_DATA_OUT) bus_dmamap_sync(sc->dma_tag, req->dma_map, BUS_DMASYNC_POSTWRITE); bus_dmamap_unload(sc->dma_tag, req->dma_map); } } /* Free alignment buffer if it was used. */ if (req->flags & TW_OSLI_REQ_FLAGS_DATA_COPY_NEEDED) { free(req->data, TW_OSLI_MALLOC_CLASS); /* Restore original data pointer and length. */ req->data = req->real_data; req->length = req->real_length; } } #ifdef TW_OSL_DEBUG TW_VOID twa_report_stats(TW_VOID); TW_VOID twa_reset_stats(TW_VOID); TW_VOID tw_osli_print_ctlr_stats(struct twa_softc *sc); TW_VOID twa_print_req_info(struct tw_osli_req_context *req); /* * Function name: twa_report_stats * Description: For being called from ddb. Calls functions that print * OSL and CL internal stats for the controller. * * Input: None * Output: None * Return value: None */ TW_VOID twa_report_stats(TW_VOID) { struct twa_softc *sc; TW_INT32 i; for (i = 0; (sc = devclass_get_softc(twa_devclass, i)) != NULL; i++) { tw_osli_print_ctlr_stats(sc); tw_cl_print_ctlr_stats(&sc->ctlr_handle); } } /* * Function name: tw_osli_print_ctlr_stats * Description: For being called from ddb. Prints OSL controller stats * * Input: sc -- ptr to OSL internal controller context * Output: None * Return value: None */ TW_VOID tw_osli_print_ctlr_stats(struct twa_softc *sc) { twa_printf(sc, "osl_ctlr_ctxt = %p\n", sc); twa_printf(sc, "OSLq type current max\n"); twa_printf(sc, "free %04d %04d\n", sc->q_stats[TW_OSLI_FREE_Q].cur_len, sc->q_stats[TW_OSLI_FREE_Q].max_len); twa_printf(sc, "busy %04d %04d\n", sc->q_stats[TW_OSLI_BUSY_Q].cur_len, sc->q_stats[TW_OSLI_BUSY_Q].max_len); } /* * Function name: twa_print_req_info * Description: For being called from ddb. Calls functions that print * OSL and CL internal details for the request. * * Input: req -- ptr to OSL internal request context * Output: None * Return value: None */ TW_VOID twa_print_req_info(struct tw_osli_req_context *req) { struct twa_softc *sc = req->ctlr; twa_printf(sc, "OSL details for request:\n"); twa_printf(sc, "osl_req_ctxt = %p, cl_req_ctxt = %p\n" "data = %p, length = 0x%x, real_data = %p, real_length = 0x%x\n" "state = 0x%x, flags = 0x%x, error = 0x%x, orig_req = %p\n" "next_req = %p, prev_req = %p, dma_map = %p\n", req->req_handle.osl_req_ctxt, req->req_handle.cl_req_ctxt, req->data, req->length, req->real_data, req->real_length, req->state, req->flags, req->error_code, req->orig_req, req->link.next, req->link.prev, req->dma_map); tw_cl_print_req_info(&(req->req_handle)); } /* * Function name: twa_reset_stats * Description: For being called from ddb. * Resets some OSL controller stats. * * Input: None * Output: None * Return value: None */ TW_VOID twa_reset_stats(TW_VOID) { struct twa_softc *sc; TW_INT32 i; for (i = 0; (sc = devclass_get_softc(twa_devclass, i)) != NULL; i++) { sc->q_stats[TW_OSLI_FREE_Q].max_len = 0; sc->q_stats[TW_OSLI_BUSY_Q].max_len = 0; tw_cl_reset_stats(&sc->ctlr_handle); } } #endif /* TW_OSL_DEBUG */