/* * Copyright (c) 2011 Jan Vesely * All rights reserved. * * Redistribution and use in source and binary forms, with or without * modification, are permitted provided that the following conditions * are met: * * - Redistributions of source code must retain the above copyright * notice, this list of conditions and the following disclaimer. * - 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. * - The name of the author may not be used to endorse or promote products * derived from this software without specific prior written permission. * * THIS SOFTWARE IS PROVIDED BY THE AUTHOR ``AS IS'' AND ANY EXPRESS OR * IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE IMPLIED WARRANTIES * OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR PURPOSE ARE DISCLAIMED. * IN NO EVENT SHALL THE AUTHOR BE LIABLE FOR ANY DIRECT, INDIRECT, * INCIDENTAL, SPECIAL, EXEMPLARY, OR CONSEQUENTIAL DAMAGES (INCLUDING, BUT * NOT LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS OR SERVICES; LOSS OF USE, * DATA, OR PROFITS; OR BUSINESS INTERRUPTION) HOWEVER CAUSED AND ON ANY * THEORY OF LIABILITY, WHETHER IN CONTRACT, STRICT LIABILITY, OR TORT * (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY OUT OF THE USE OF * THIS SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF SUCH DAMAGE. */ /** @addtogroup drvusbehcihc * @{ */ /** @file * @brief EHCI Host controller driver routines */ #include #include #include #include #include #include #include #include #include #include #include #include "ehci_batch.h" #include "hc.h" #define EHCI_USED_INTERRUPTS \ (USB_INTR_IRQ_FLAG | USB_INTR_ERR_IRQ_FLAG | USB_INTR_PORT_CHANGE_FLAG | \ USB_INTR_ASYNC_ADVANCE_FLAG | USB_INTR_HOST_ERR_FLAG) static const irq_pio_range_t ehci_pio_ranges[] = { { .base = 0, .size = sizeof(ehci_regs_t) } }; static const irq_cmd_t ehci_irq_commands[] = { { .cmd = CMD_PIO_READ_32, .dstarg = 1, .addr = NULL }, { .cmd = CMD_AND, .srcarg = 1, .dstarg = 2, .value = 0 }, { .cmd = CMD_PREDICATE, .srcarg = 2, .value = 2 }, { .cmd = CMD_PIO_WRITE_A_32, .srcarg = 1, .addr = NULL }, { .cmd = CMD_ACCEPT } }; static int hc_init_memory(hc_t *instance); /** Generate IRQ code. * @param[out] ranges PIO ranges buffer. * @param[in] hw_res Device's resources. * * @return Error code. */ int ehci_hc_gen_irq_code(irq_code_t *code, hcd_t *hcd, const hw_res_list_parsed_t *hw_res) { assert(code); assert(hw_res); hc_t *instance = hcd_get_driver_data(hcd); if (hw_res->irqs.count != 1 || hw_res->mem_ranges.count != 1) return EINVAL; addr_range_t regs = hw_res->mem_ranges.ranges[0]; if (RNGSZ(regs) < sizeof(ehci_regs_t)) return EOVERFLOW; code->ranges = malloc(sizeof(ehci_pio_ranges)); if (code->ranges == NULL) return ENOMEM; code->cmds = malloc(sizeof(ehci_irq_commands)); if (code->cmds == NULL) { free(code->ranges); return ENOMEM; } code->rangecount = ARRAY_SIZE(ehci_pio_ranges); code->cmdcount = ARRAY_SIZE(ehci_irq_commands); memcpy(code->ranges, ehci_pio_ranges, sizeof(ehci_pio_ranges)); code->ranges[0].base = RNGABS(regs); memcpy(code->cmds, ehci_irq_commands, sizeof(ehci_irq_commands)); ehci_regs_t *registers = (ehci_regs_t *)(RNGABSPTR(regs) + EHCI_RD8(instance->caps->caplength)); code->cmds[0].addr = (void *) ®isters->usbsts; code->cmds[3].addr = (void *) ®isters->usbsts; EHCI_WR(code->cmds[1].value, EHCI_USED_INTERRUPTS); usb_log_debug("Memory mapped regs at %p (size %zu), IRQ %d.\n", RNGABSPTR(regs), RNGSZ(regs), hw_res->irqs.irqs[0]); return hw_res->irqs.irqs[0]; } /** Initialize EHCI hc driver structure * * @param[in] instance Memory place for the structure. * @param[in] regs Device's I/O registers range. * @param[in] interrupts True if w interrupts should be used * @return Error code */ int hc_init(hc_t *instance, const hw_res_list_parsed_t *hw_res) { assert(instance); assert(hw_res); if (hw_res->mem_ranges.count != 1 || hw_res->mem_ranges.ranges[0].size < (sizeof(ehci_caps_regs_t) + sizeof(ehci_regs_t))) return EINVAL; int ret = pio_enable_range(&hw_res->mem_ranges.ranges[0], (void **)&instance->caps); if (ret != EOK) { usb_log_error("HC(%p): Failed to gain access to device " "registers: %s.\n", instance, str_error(ret)); return ret; } usb_log_info("HC(%p): Device registers at %"PRIx64" (%zuB) accessible.", instance, hw_res->mem_ranges.ranges[0].address.absolute, hw_res->mem_ranges.ranges[0].size); instance->registers = (void*)instance->caps + EHCI_RD8(instance->caps->caplength); usb_log_info("HC(%p): Device control registers at %" PRIx64, instance, hw_res->mem_ranges.ranges[0].address.absolute + EHCI_RD8(instance->caps->caplength)); list_initialize(&instance->pending_batches); fibril_mutex_initialize(&instance->guard); fibril_condvar_initialize(&instance->async_doorbell); ret = hc_init_memory(instance); if (ret != EOK) { usb_log_error("HC(%p): Failed to create EHCI memory structures:" " %s.", instance, str_error(ret)); return ret; } usb_log_info("HC(%p): Initializing RH(%p).", instance, &instance->rh); ehci_rh_init( &instance->rh, instance->caps, instance->registers, "ehci rh"); ehci_bus_init(&instance->bus, instance); return EOK; } /** Safely dispose host controller internal structures * * @param[in] instance Host controller structure to use. */ void hc_fini(hc_t *instance) { assert(instance); //TODO: stop the hw #if 0 endpoint_list_fini(&instance->async_list); endpoint_list_fini(&instance->int_list); return_page(instance->periodic_list_base); #endif }; void hc_enqueue_endpoint(hc_t *instance, const endpoint_t *ep) { assert(instance); assert(ep); ehci_endpoint_t *ehci_ep = ehci_endpoint_get(ep); usb_log_debug("HC(%p) enqueue EP(%d:%d:%s:%s)\n", instance, ep->target.address, ep->target.endpoint, usb_str_transfer_type_short(ep->transfer_type), usb_str_direction(ep->direction)); switch (ep->transfer_type) { case USB_TRANSFER_CONTROL: case USB_TRANSFER_BULK: endpoint_list_append_ep(&instance->async_list, ehci_ep); break; case USB_TRANSFER_INTERRUPT: endpoint_list_append_ep(&instance->int_list, ehci_ep); break; case USB_TRANSFER_ISOCHRONOUS: /* NOT SUPPORTED */ break; } } void hc_dequeue_endpoint(hc_t *instance, const endpoint_t *ep) { assert(instance); assert(ep); ehci_endpoint_t *ehci_ep = ehci_endpoint_get(ep); usb_log_debug("HC(%p) dequeue EP(%d:%d:%s:%s)\n", instance, ep->target.address, ep->target.endpoint, usb_str_transfer_type_short(ep->transfer_type), usb_str_direction(ep->direction)); switch (ep->transfer_type) { case USB_TRANSFER_INTERRUPT: endpoint_list_remove_ep(&instance->int_list, ehci_ep); /* Fall through */ case USB_TRANSFER_ISOCHRONOUS: /* NOT SUPPORTED */ return; case USB_TRANSFER_CONTROL: case USB_TRANSFER_BULK: endpoint_list_remove_ep(&instance->async_list, ehci_ep); break; } fibril_mutex_lock(&instance->guard); usb_log_debug("HC(%p): Waiting for doorbell", instance); EHCI_SET(instance->registers->usbcmd, USB_CMD_IRQ_ASYNC_DOORBELL); fibril_condvar_wait(&instance->async_doorbell, &instance->guard); usb_log_debug2("HC(%p): Got doorbell", instance); fibril_mutex_unlock(&instance->guard); } int ehci_hc_status(hcd_t *hcd, uint32_t *status) { assert(hcd); hc_t *instance = hcd_get_driver_data(hcd); assert(instance); assert(status); *status = 0; if (instance->registers) { *status = EHCI_RD(instance->registers->usbsts); EHCI_WR(instance->registers->usbsts, *status); } usb_log_debug2("HC(%p): Read status: %x", instance, *status); return EOK; } /** Add USB transfer to the schedule. * * @param[in] hcd HCD driver structure. * @param[in] batch Batch representing the transfer. * @return Error code. */ int ehci_hc_schedule(hcd_t *hcd, usb_transfer_batch_t *batch) { assert(hcd); hc_t *instance = hcd_get_driver_data(hcd); assert(instance); /* Check for root hub communication */ if (batch->ep->target.address == ehci_rh_get_address(&instance->rh)) { usb_log_debug("HC(%p): Scheduling BATCH(%p) for RH(%p)", instance, batch, &instance->rh); return ehci_rh_schedule(&instance->rh, batch); } ehci_transfer_batch_t *ehci_batch = ehci_transfer_batch_get(batch); if (!ehci_batch) return ENOMEM; fibril_mutex_lock(&instance->guard); usb_log_debug2("HC(%p): Appending BATCH(%p)", instance, batch); list_append(&ehci_batch->link, &instance->pending_batches); usb_log_debug("HC(%p): Committing BATCH(%p)", instance, batch); ehci_transfer_batch_commit(ehci_batch); fibril_mutex_unlock(&instance->guard); return EOK; } /** Interrupt handling routine * * @param[in] hcd HCD driver structure. * @param[in] status Value of the status register at the time of interrupt. */ void ehci_hc_interrupt(hcd_t *hcd, uint32_t status) { assert(hcd); hc_t *instance = hcd_get_driver_data(hcd); status = EHCI_RD(status); assert(instance); usb_log_debug2("HC(%p): Interrupt: %"PRIx32, instance, status); if (status & USB_STS_PORT_CHANGE_FLAG) { ehci_rh_interrupt(&instance->rh); } if (status & USB_STS_IRQ_ASYNC_ADVANCE_FLAG) { fibril_mutex_lock(&instance->guard); usb_log_debug2("HC(%p): Signaling doorbell", instance); fibril_condvar_broadcast(&instance->async_doorbell); fibril_mutex_unlock(&instance->guard); } if (status & (USB_STS_IRQ_FLAG | USB_STS_ERR_IRQ_FLAG)) { fibril_mutex_lock(&instance->guard); usb_log_debug2("HC(%p): Scanning %lu pending batches", instance, list_count(&instance->pending_batches)); list_foreach_safe(instance->pending_batches, current, next) { ehci_transfer_batch_t *batch = ehci_transfer_batch_from_link(current); if (ehci_transfer_batch_is_complete(batch)) { list_remove(current); ehci_transfer_batch_finish_dispose(batch); } } fibril_mutex_unlock(&instance->guard); } if (status & USB_STS_HOST_ERROR_FLAG) { usb_log_fatal("HCD(%p): HOST SYSTEM ERROR!", instance); //TODO do something here } } /** EHCI hw initialization routine. * * @param[in] instance EHCI hc driver structure. */ int hc_start(hc_t *instance, bool interrupts) { assert(instance); usb_log_debug("HC(%p): Starting HW.", instance); /* Turn off the HC if it's running, Reseting a running device is * undefined */ if (!(EHCI_RD(instance->registers->usbsts) & USB_STS_HC_HALTED_FLAG)) { /* disable all interrupts */ EHCI_WR(instance->registers->usbintr, 0); /* ack all interrupts */ EHCI_WR(instance->registers->usbsts, 0x3f); /* Stop HC hw */ EHCI_WR(instance->registers->usbcmd, 0); /* Wait until hc is halted */ while ((EHCI_RD(instance->registers->usbsts) & USB_STS_HC_HALTED_FLAG) == 0) { async_usleep(1); } usb_log_info("HC(%p): EHCI turned off.", instance); } else { usb_log_info("HC(%p): EHCI was not running.", instance); } /* Hw initialization sequence, see page 53 (pdf 63) */ EHCI_SET(instance->registers->usbcmd, USB_CMD_HC_RESET_FLAG); usb_log_info("HC(%p): Waiting for HW reset.", instance); while (EHCI_RD(instance->registers->usbcmd) & USB_CMD_HC_RESET_FLAG) { async_usleep(1); } usb_log_debug("HC(%p): HW reset OK.", instance); /* Use the lowest 4G segment */ EHCI_WR(instance->registers->ctrldssegment, 0); /* Enable periodic list */ assert(instance->periodic_list_base); uintptr_t phys_base = addr_to_phys((void*)instance->periodic_list_base); assert((phys_base & USB_PERIODIC_LIST_BASE_MASK) == phys_base); EHCI_WR(instance->registers->periodiclistbase, phys_base); EHCI_SET(instance->registers->usbcmd, USB_CMD_PERIODIC_SCHEDULE_FLAG); usb_log_debug("HC(%p): Enabled periodic list.", instance); /* Enable Async schedule */ phys_base = addr_to_phys((void*)instance->async_list.list_head); assert((phys_base & USB_ASYNCLIST_MASK) == phys_base); EHCI_WR(instance->registers->asynclistaddr, phys_base); EHCI_SET(instance->registers->usbcmd, USB_CMD_ASYNC_SCHEDULE_FLAG); usb_log_debug("HC(%p): Enabled async list.", instance); /* Start hc and get all ports */ EHCI_SET(instance->registers->usbcmd, USB_CMD_RUN_FLAG); EHCI_SET(instance->registers->configflag, USB_CONFIG_FLAG_FLAG); usb_log_debug("HC(%p): HW started.", instance); usb_log_debug2("HC(%p): Registers: \n" "\tUSBCMD(%p): %x(0x00080000 = at least 1ms between interrupts)\n" "\tUSBSTS(%p): %x(0x00001000 = HC halted)\n" "\tUSBINT(%p): %x(0x0 = no interrupts).\n" "\tCONFIG(%p): %x(0x0 = ports controlled by companion hc).\n", instance, &instance->registers->usbcmd, EHCI_RD(instance->registers->usbcmd), &instance->registers->usbsts, EHCI_RD(instance->registers->usbsts), &instance->registers->usbintr, EHCI_RD(instance->registers->usbintr), &instance->registers->configflag, EHCI_RD(instance->registers->configflag)); /* Clear and Enable interrupts */ EHCI_WR(instance->registers->usbsts, EHCI_RD(instance->registers->usbsts)); EHCI_WR(instance->registers->usbintr, EHCI_USED_INTERRUPTS); return EOK; } /** Initialize memory structures used by the EHCI hcd. * * @param[in] instance EHCI hc driver structure. * @return Error code. */ int hc_init_memory(hc_t *instance) { assert(instance); usb_log_debug2("HC(%p): Initializing Async list(%p).", instance, &instance->async_list); int ret = endpoint_list_init(&instance->async_list, "ASYNC"); if (ret != EOK) { usb_log_error("HC(%p): Failed to setup ASYNC list: %s", instance, str_error(ret)); return ret; } /* Specs say "Software must set queue head horizontal pointer T-bits to * a zero for queue heads in the asynchronous schedule" (4.4.0). * So we must maintain circular buffer (all horizontal pointers * have to be valid */ endpoint_list_chain(&instance->async_list, &instance->async_list); usb_log_debug2("HC(%p): Initializing Interrupt list (%p).", instance, &instance->int_list); ret = endpoint_list_init(&instance->int_list, "INT"); if (ret != EOK) { usb_log_error("HC(%p): Failed to setup INT list: %s", instance, str_error(ret)); endpoint_list_fini(&instance->async_list); return ret; } /* Take 1024 periodic list heads, we ignore low mem options */ instance->periodic_list_base = get_page(); if (!instance->periodic_list_base) { usb_log_error("HC(%p): Failed to get ISO schedule page.", instance); endpoint_list_fini(&instance->async_list); endpoint_list_fini(&instance->int_list); return ENOMEM; } usb_log_debug2("HC(%p): Initializing Periodic list.", instance); for (unsigned i = 0; i < PAGE_SIZE/sizeof(instance->periodic_list_base[0]); ++i) { /* Disable everything for now */ instance->periodic_list_base[i] = LINK_POINTER_QH(addr_to_phys(instance->int_list.list_head)); } return EOK; } /** * @} */