/* * * Copyright (C) 2010 Patrick Georgi * Copyright (C) 2013 secunet Security Networks AG * * 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. * 3. The name of the author may not be used to endorse or promote products * derived from this software without specific prior written permission. * * THIS SOFTWARE IS PROVIDED BY THE AUTHOR AND CONTRIBUTORS ``AS IS'' AND * ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE * IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR PURPOSE * ARE DISCLAIMED. IN NO EVENT SHALL THE AUTHOR OR CONTRIBUTORS BE LIABLE * FOR ANY DIRECT, INDIRECT, INCIDENTAL, SPECIAL, EXEMPLARY, OR CONSEQUENTIAL * DAMAGES (INCLUDING, BUT NOT LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS * OR SERVICES; LOSS OF USE, DATA, OR PROFITS; OR BUSINESS INTERRUPTION) * HOWEVER CAUSED AND ON ANY THEORY OF LIABILITY, WHETHER IN CONTRACT, STRICT * LIABILITY, OR TORT (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY * OUT OF THE USE OF THIS SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF * SUCH DAMAGE. */ //#define XHCI_SPEW_DEBUG #include #include #include "xhci_private.h" #include "xhci.h" static void xhci_start (hci_t *controller); static void xhci_stop (hci_t *controller); static void xhci_reset (hci_t *controller); static void xhci_reinit (hci_t *controller); static void xhci_shutdown (hci_t *controller); static int xhci_bulk (endpoint_t *ep, int size, u8 *data, int finalize); static int xhci_control (usbdev_t *dev, direction_t dir, int drlen, void *devreq, int dalen, u8 *data); static void* xhci_create_intr_queue (endpoint_t *ep, int reqsize, int reqcount, int reqtiming); static void xhci_destroy_intr_queue (endpoint_t *ep, void *queue); static u8* xhci_poll_intr_queue (void *queue); /* * Some structures must not cross page boundaries. To get this, * we align them by their size (or the next greater power of 2). */ void * xhci_align(const size_t min_align, const size_t size) { size_t align; if (!(size & (size - 1))) align = size; /* It's a power of 2 */ else align = 1 << ((sizeof(unsigned) << 3) - __builtin_clz(size)); if (align < min_align) align = min_align; xhci_spew("Aligning %zu to %zu\n", size, align); return dma_memalign(align, size); } void xhci_clear_trb(trb_t *const trb, const int pcs) { trb->ptr_low = 0; trb->ptr_high = 0; trb->status = 0; trb->control = !pcs; } void xhci_init_cycle_ring(transfer_ring_t *const tr, const size_t ring_size) { memset((void *)tr->ring, 0, ring_size * sizeof(*tr->ring)); TRB_SET(TT, &tr->ring[ring_size - 1], TRB_LINK); TRB_SET(TC, &tr->ring[ring_size - 1], 1); /* only one segment that points to itself */ tr->ring[ring_size - 1].ptr_low = virt_to_phys(tr->ring); tr->pcs = 1; tr->cur = tr->ring; } /* On Panther Point: switch ports shared with EHCI to xHCI */ #if CONFIG(LP_USB_PCI) static void xhci_switch_ppt_ports(pcidev_t addr) { if (pci_read_config32(addr, 0x00) == 0x1e318086) { u32 reg32 = pci_read_config32(addr, 0xdc) & 0xf; xhci_debug("Ports capable of SuperSpeed: 0x%"PRIx32"\n", reg32); /* For now, do not enable SuperSpeed on any ports */ //pci_write_config32(addr, 0xd8, reg32); pci_write_config32(addr, 0xd8, 0x00000000); reg32 = pci_read_config32(addr, 0xd8) & 0xf; xhci_debug("Configured for SuperSpeed: 0x%"PRIx32"\n", reg32); reg32 = pci_read_config32(addr, 0xd4) & 0xf; xhci_debug("Trying to switch over: 0x%"PRIx32"\n", reg32); pci_write_config32(addr, 0xd0, reg32); reg32 = pci_read_config32(addr, 0xd0) & 0xf; xhci_debug("Actually switched over: 0x%"PRIx32"\n", reg32); } } #endif #if CONFIG(LP_USB_PCI) /* On Panther Point: switch all ports back to EHCI */ static void xhci_switchback_ppt_ports(pcidev_t addr) { if (pci_read_config32(addr, 0x00) == 0x1e318086) { u32 reg32 = pci_read_config32(addr, 0xd0) & 0xf; xhci_debug("Switching ports back: 0x%"PRIx32"\n", reg32); pci_write_config32(addr, 0xd0, 0x00000000); reg32 = pci_read_config32(addr, 0xd0) & 0xf; xhci_debug("Still switched to xHCI: 0x%"PRIx32"\n", reg32); } } #endif static long xhci_handshake(volatile u32 *const reg, u32 mask, u32 wait_for, long timeout_us) { while ((*reg & mask) != wait_for && timeout_us--) udelay(1); return timeout_us; } static int xhci_wait_ready(xhci_t *const xhci) { xhci_debug("Waiting for controller to be ready... "); if (!xhci_handshake(&xhci->opreg->usbsts, USBSTS_CNR, 0, 100000L)) { usb_debug("timeout!\n"); return -1; } usb_debug("ok.\n"); return 0; } hci_t * xhci_init (unsigned long physical_bar) { int i; /* First, allocate and initialize static controller structures */ hci_t *const controller = new_controller(); controller->type = XHCI; controller->start = xhci_start; controller->stop = xhci_stop; controller->reset = xhci_reset; controller->init = xhci_reinit; controller->shutdown = xhci_shutdown; controller->bulk = xhci_bulk; controller->control = xhci_control; controller->set_address = xhci_set_address; controller->finish_device_config= xhci_finish_device_config; controller->destroy_device = xhci_destroy_dev; controller->create_intr_queue = xhci_create_intr_queue; controller->destroy_intr_queue = xhci_destroy_intr_queue; controller->poll_intr_queue = xhci_poll_intr_queue; controller->pcidev = 0; controller->reg_base = (uintptr_t)physical_bar; controller->instance = xzalloc(sizeof(xhci_t)); xhci_t *const xhci = (xhci_t *)controller->instance; init_device_entry(controller, 0); xhci->roothub = controller->devices[0]; xhci->cr.ring = xhci_align(64, COMMAND_RING_SIZE * sizeof(trb_t)); xhci->er.ring = xhci_align(64, EVENT_RING_SIZE * sizeof(trb_t)); xhci->ev_ring_table = xhci_align(64, sizeof(erst_entry_t)); if (!xhci->roothub || !xhci->cr.ring || !xhci->er.ring || !xhci->ev_ring_table) { xhci_debug("Out of memory\n"); goto _free_xhci; } xhci->capreg = phys_to_virt(physical_bar); xhci->opreg = phys_to_virt(physical_bar) + CAP_GET(CAPLEN, xhci->capreg); xhci->hcrreg = phys_to_virt(physical_bar) + xhci->capreg->rtsoff; xhci->dbreg = phys_to_virt(physical_bar) + xhci->capreg->dboff; xhci_debug("regbase: 0x%"PRIx32"\n", physical_bar); xhci_debug("caplen: 0x%"PRIx32"\n", CAP_GET(CAPLEN, xhci->capreg)); xhci_debug("rtsoff: 0x%"PRIx32"\n", xhci->capreg->rtsoff); xhci_debug("dboff: 0x%"PRIx32"\n", xhci->capreg->dboff); xhci_debug("hciversion: %"PRIx8".%"PRIx8"\n", CAP_GET(CAPVER_HI, xhci->capreg), CAP_GET(CAPVER_LO, xhci->capreg)); if ((CAP_GET(CAPVER, xhci->capreg) < 0x96) || (CAP_GET(CAPVER, xhci->capreg) > 0x120)) { xhci_debug("Unsupported xHCI version\n"); goto _free_xhci; } xhci_debug("context size: %dB\n", CTXSIZE(xhci)); xhci_debug("maxslots: 0x%02lx\n", CAP_GET(MAXSLOTS, xhci->capreg)); xhci_debug("maxports: 0x%02lx\n", CAP_GET(MAXPORTS, xhci->capreg)); const unsigned pagesize = xhci->opreg->pagesize << 12; xhci_debug("pagesize: 0x%04x\n", pagesize); /* * We haven't touched the hardware yet. So we allocate all dynamic * structures at first and can still chicken out easily if we run out * of memory. */ xhci->max_slots_en = CAP_GET(MAXSLOTS, xhci->capreg) & CONFIG_LP_MASK_MaxSlotsEn; xhci->dcbaa = xhci_align(64, (xhci->max_slots_en + 1) * sizeof(u64)); xhci->dev = malloc((xhci->max_slots_en + 1) * sizeof(*xhci->dev)); if (!xhci->dcbaa || !xhci->dev) { xhci_debug("Out of memory\n"); goto _free_xhci; } memset(xhci->dcbaa, 0x00, (xhci->max_slots_en + 1) * sizeof(u64)); memset(xhci->dev, 0x00, (xhci->max_slots_en + 1) * sizeof(*xhci->dev)); /* * Let dcbaa[0] point to another array of pointers, sp_ptrs. * The pointers therein point to scratchpad buffers (pages). */ const size_t max_sp_bufs = CAP_GET(MAX_SCRATCH_BUFS_HI, xhci->capreg) << 5 | CAP_GET(MAX_SCRATCH_BUFS_LO, xhci->capreg); xhci_debug("max scratchpad bufs: 0x%zx\n", max_sp_bufs); if (max_sp_bufs) { const size_t sp_ptrs_size = max_sp_bufs * sizeof(u64); xhci->sp_ptrs = xhci_align(64, sp_ptrs_size); if (!xhci->sp_ptrs) { xhci_debug("Out of memory\n"); goto _free_xhci_structs; } memset(xhci->sp_ptrs, 0x00, sp_ptrs_size); for (i = 0; i < max_sp_bufs; ++i) { /* Could use mmap() here if we had it. Maybe there is another way. */ void *const page = memalign(pagesize, pagesize); if (!page) { xhci_debug("Out of memory\n"); goto _free_xhci_structs; } xhci->sp_ptrs[i] = virt_to_phys(page); } xhci->dcbaa[0] = virt_to_phys(xhci->sp_ptrs); } if (dma_initialized()) { xhci->dma_buffer = dma_memalign(64 * 1024, DMA_SIZE); if (!xhci->dma_buffer) { xhci_debug("Not enough memory for DMA bounce buffer\n"); goto _free_xhci_structs; } } /* Now start working on the hardware */ if (xhci_wait_ready(xhci)) goto _free_xhci_structs; /* TODO: Check if BIOS claims ownership (and hand over) */ xhci_reset(controller); xhci_reinit(controller); xhci->roothub->controller = controller; xhci->roothub->init = xhci_rh_init; xhci->roothub->init(xhci->roothub); return controller; _free_xhci_structs: free(xhci->dma_buffer); if (xhci->sp_ptrs) { for (i = 0; i < max_sp_bufs; ++i) { if (xhci->sp_ptrs[i]) free(phys_to_virt(xhci->sp_ptrs[i])); } } free(xhci->sp_ptrs); free(xhci->dcbaa); _free_xhci: free((void *)xhci->ev_ring_table); free((void *)xhci->er.ring); free((void *)xhci->cr.ring); free(xhci->roothub); free(xhci->dev); free(xhci); /* _free_controller: */ detach_controller(controller); free(controller); return NULL; } #if CONFIG(LP_USB_PCI) hci_t * xhci_pci_init (pcidev_t addr) { u32 reg_addr; hci_t *controller; reg_addr = pci_read_config32(addr, PCI_BASE_ADDRESS_0) & PCI_BASE_ADDRESS_MEM_MASK; if (pci_read_config32(addr, PCI_BASE_ADDRESS_1) > 0) fatal("We don't do 64bit addressing.\n"); controller = xhci_init((unsigned long)reg_addr); if (controller) { xhci_t *xhci = controller->instance; controller->pcidev = addr; xhci_switch_ppt_ports(addr); /* Set up any quirks for controller root hub */ xhci->roothub->quirks = pci_quirk_check(addr); } return controller; } #endif static void xhci_reset(hci_t *const controller) { xhci_t *const xhci = XHCI_INST(controller); xhci_stop(controller); xhci->opreg->usbcmd |= USBCMD_HCRST; /* Existing Intel xHCI controllers require a delay of 1 ms, * after setting the CMD_RESET bit, and before accessing any * HC registers. This allows the HC to complete the * reset operation and be ready for HC register access. * Without this delay, the subsequent HC register access, * may result in a system hang very rarely. */ if (CONFIG(LP_ARCH_X86)) mdelay(1); xhci_debug("Resetting controller... "); if (!xhci_handshake(&xhci->opreg->usbcmd, USBCMD_HCRST, 0, 1000000L)) usb_debug("timeout!\n"); else usb_debug("ok.\n"); } static void xhci_reinit (hci_t *controller) { xhci_t *const xhci = XHCI_INST(controller); if (xhci_wait_ready(xhci)) return; /* Enable all available slots */ xhci->opreg->config = xhci->max_slots_en; /* Set DCBAA */ xhci->opreg->dcbaap_lo = virt_to_phys(xhci->dcbaa); xhci->opreg->dcbaap_hi = 0; /* Initialize command ring */ xhci_init_cycle_ring(&xhci->cr, COMMAND_RING_SIZE); xhci_debug("command ring @%p (0x%08x)\n", xhci->cr.ring, virt_to_phys(xhci->cr.ring)); xhci->opreg->crcr_lo = virt_to_phys(xhci->cr.ring) | CRCR_RCS; xhci->opreg->crcr_hi = 0; /* Make sure interrupts are disabled */ xhci->opreg->usbcmd &= ~USBCMD_INTE; /* Initialize event ring */ xhci_reset_event_ring(&xhci->er); xhci_debug("event ring @%p (0x%08x)\n", xhci->er.ring, virt_to_phys(xhci->er.ring)); xhci_debug("ERST Max: 0x%lx -> 0x%lx entries\n", CAP_GET(ERST_MAX, xhci->capreg), 1 << CAP_GET(ERST_MAX, xhci->capreg)); memset((void*)xhci->ev_ring_table, 0x00, sizeof(erst_entry_t)); xhci->ev_ring_table[0].seg_base_lo = virt_to_phys(xhci->er.ring); xhci->ev_ring_table[0].seg_base_hi = 0; xhci->ev_ring_table[0].seg_size = EVENT_RING_SIZE; /* pass event ring table to hardware */ wmb(); /* Initialize primary interrupter */ xhci->hcrreg->intrrs[0].erstsz = 1; xhci_update_event_dq(xhci); /* erstba has to be written at last */ xhci->hcrreg->intrrs[0].erstba_lo = virt_to_phys(xhci->ev_ring_table); xhci->hcrreg->intrrs[0].erstba_hi = 0; xhci_start(controller); #ifdef USB_DEBUG int i; for (i = 0; i < 32; ++i) { xhci_debug("NOOP run #%d\n", i); trb_t *const cmd = xhci_next_command_trb(xhci); TRB_SET(TT, cmd, TRB_CMD_NOOP); xhci_post_command(xhci); /* Wait for result in event ring */ int cc = xhci_wait_for_command_done(xhci, cmd, 1); xhci_debug("Command ring is %srunning: cc: %d\n", (xhci->opreg->crcr_lo & CRCR_CRR) ? "" : "not ", cc); if (cc != CC_SUCCESS) xhci_debug("noop command failed.\n"); } #endif } static void xhci_shutdown(hci_t *const controller) { int i; if (controller == 0) return; detach_controller(controller); xhci_t *const xhci = XHCI_INST(controller); xhci_stop(controller); #if CONFIG(LP_USB_PCI) if (controller->pcidev) xhci_switchback_ppt_ports(controller->pcidev); #endif if (xhci->sp_ptrs) { const size_t max_sp_bufs = CAP_GET(MAX_SCRATCH_BUFS_HI, xhci->capreg) << 5 | CAP_GET(MAX_SCRATCH_BUFS_LO, xhci->capreg); for (i = 0; i < max_sp_bufs; ++i) { if (xhci->sp_ptrs[i]) free(phys_to_virt(xhci->sp_ptrs[i])); } } free(xhci->sp_ptrs); free(xhci->dma_buffer); free(xhci->dcbaa); free(xhci->dev); free((void *)xhci->ev_ring_table); free((void *)xhci->er.ring); free((void *)xhci->cr.ring); free(xhci); free(controller); } static void xhci_start (hci_t *controller) { xhci_t *const xhci = XHCI_INST(controller); xhci->opreg->usbcmd |= USBCMD_RS; if (!xhci_handshake(&xhci->opreg->usbsts, USBSTS_HCH, 0, 1000000L)) xhci_debug("Controller didn't start within 1s\n"); } static void xhci_stop (hci_t *controller) { xhci_t *const xhci = XHCI_INST(controller); xhci->opreg->usbcmd &= ~USBCMD_RS; if (!xhci_handshake(&xhci->opreg->usbsts, USBSTS_HCH, USBSTS_HCH, 1000000L)) xhci_debug("Controller didn't halt within 1s\n"); } static int xhci_reset_endpoint(usbdev_t *const dev, endpoint_t *const ep) { xhci_t *const xhci = XHCI_INST(dev->controller); const int slot_id = dev->address; const int ep_id = ep ? xhci_ep_id(ep) : 1; epctx_t *const epctx = xhci->dev[slot_id].ctx.ep[ep_id]; xhci_debug("Resetting ID %d EP %d (ep state: %d)\n", slot_id, ep_id, EC_GET(STATE, epctx)); /* Run Reset Endpoint Command if the EP is in Halted state */ if (EC_GET(STATE, epctx) == 2) { const int cc = xhci_cmd_reset_endpoint(xhci, slot_id, ep_id); if (cc != CC_SUCCESS) { xhci_debug("Reset Endpoint Command failed: %d\n", cc); return 1; } } /* Clear TT buffer for bulk and control endpoints behind a TT */ const int hub = dev->hub; if (hub && dev->speed < HIGH_SPEED && dev->controller->devices[hub]->speed == HIGH_SPEED) /* TODO */; /* Reset transfer ring if the endpoint is in the right state */ const unsigned ep_state = EC_GET(STATE, epctx); if (ep_state == 3 || ep_state == 4) { transfer_ring_t *const tr = xhci->dev[slot_id].transfer_rings[ep_id]; const int cc = xhci_cmd_set_tr_dq(xhci, slot_id, ep_id, tr->ring, 1); if (cc != CC_SUCCESS) { xhci_debug("Set TR Dequeue Command failed: %d\n", cc); return 1; } xhci_init_cycle_ring(tr, TRANSFER_RING_SIZE); } xhci_debug("Finished resetting ID %d EP %d (ep state: %d)\n", slot_id, ep_id, EC_GET(STATE, epctx)); return 0; } static void xhci_enqueue_trb(transfer_ring_t *const tr) { const int chain = TRB_GET(CH, tr->cur); TRB_SET(C, tr->cur, tr->pcs); ++tr->cur; while (TRB_GET(TT, tr->cur) == TRB_LINK) { xhci_spew("Handling LINK pointer\n"); const int tc = TRB_GET(TC, tr->cur); TRB_SET(CH, tr->cur, chain); wmb(); TRB_SET(C, tr->cur, tr->pcs); tr->cur = phys_to_virt(tr->cur->ptr_low); if (tc) tr->pcs ^= 1; } } static void xhci_ring_doorbell(endpoint_t *const ep) { /* Ensure all TRB changes are written to memory. */ wmb(); XHCI_INST(ep->dev->controller)->dbreg[ep->dev->address] = xhci_ep_id(ep); } static void xhci_enqueue_td(transfer_ring_t *const tr, const int ep, const size_t mps, const int dalen, void *const data, const int dir) { trb_t *trb = NULL; /* cur TRB */ u8 *cur_start = data; /* cur data pointer */ size_t length = dalen; /* remaining bytes */ size_t packets = (length + mps - 1) / mps; /* remaining packets */ size_t residue = 0; /* residue from last TRB */ size_t trb_count = 0; /* TRBs added so far */ while (length || !trb_count /* enqueue at least one */) { const size_t cur_end = ((size_t)cur_start + 0x10000) & ~0xffff; size_t cur_length = cur_end - (size_t)cur_start; if (length < cur_length) { cur_length = length; packets = 0; length = 0; } else if (!CONFIG(LP_USB_XHCI_MTK_QUIRK)) { packets -= (residue + cur_length) / mps; residue = (residue + cur_length) % mps; length -= cur_length; } trb = tr->cur; xhci_clear_trb(trb, tr->pcs); trb->ptr_low = virt_to_phys(cur_start); TRB_SET(TL, trb, cur_length); TRB_SET(TDS, trb, MIN(TRB_MAX_TD_SIZE, packets)); TRB_SET(CH, trb, 1); if (length && CONFIG(LP_USB_XHCI_MTK_QUIRK)) { /* * For MTK's xHCI controller, TDS defines a number of * packets that remain to be transferred for a TD after * processing all Max packets in all previous TRBs, that * means don't include the current TRB's. */ packets -= (residue + cur_length) / mps; residue = (residue + cur_length) % mps; length -= cur_length; } /* Check for first, data stage TRB */ if (!trb_count && ep == 1) { TRB_SET(DIR, trb, dir); TRB_SET(TT, trb, TRB_DATA_STAGE); } else { TRB_SET(TT, trb, TRB_NORMAL); } /* * This is a workaround for Synopsys DWC3. If the ENT flag is * not set for the Normal and Data Stage TRBs. We get Event TRB * with length 0x20d from the controller when we enqueue a TRB * for the IN endpoint with length 0x200. */ if (!length) TRB_SET(ENT, trb, 1); xhci_enqueue_trb(tr); cur_start += cur_length; ++trb_count; } trb = tr->cur; xhci_clear_trb(trb, tr->pcs); trb->ptr_low = virt_to_phys(trb); /* for easier debugging only */ TRB_SET(TT, trb, TRB_EVENT_DATA); TRB_SET(IOC, trb, 1); xhci_enqueue_trb(tr); } static int xhci_control(usbdev_t *const dev, const direction_t dir, const int drlen, void *const devreq, const int dalen, unsigned char *const src) { unsigned char *data = src; xhci_t *const xhci = XHCI_INST(dev->controller); epctx_t *const epctx = xhci->dev[dev->address].ctx.ep0; transfer_ring_t *const tr = xhci->dev[dev->address].transfer_rings[1]; const size_t off = (size_t)data & 0xffff; if ((off + dalen) > ((TRANSFER_RING_SIZE - 4) << 16)) { xhci_debug("Unsupported transfer size\n"); return -1; } /* Reset endpoint if it's not running */ const unsigned ep_state = EC_GET(STATE, epctx); if (ep_state > 1) { if (xhci_reset_endpoint(dev, NULL)) return -1; } if (dalen && !dma_coherent(src)) { data = xhci->dma_buffer; if (dalen > DMA_SIZE) { xhci_debug("Control transfer too large: %d\n", dalen); return -1; } if (dir == OUT) memcpy(data, src, dalen); } /* Fill and enqueue setup TRB */ trb_t *const setup = tr->cur; xhci_clear_trb(setup, tr->pcs); setup->ptr_low = ((u32 *)devreq)[0]; setup->ptr_high = ((u32 *)devreq)[1]; TRB_SET(TL, setup, 8); TRB_SET(TRT, setup, (dalen) ? ((dir == OUT) ? TRB_TRT_OUT_DATA : TRB_TRT_IN_DATA) : TRB_TRT_NO_DATA); TRB_SET(TT, setup, TRB_SETUP_STAGE); TRB_SET(IDT, setup, 1); TRB_SET(IOC, setup, 1); xhci_enqueue_trb(tr); /* Fill and enqueue data TRBs (if any) */ if (dalen) { const unsigned mps = EC_GET(MPS, epctx); const unsigned dt_dir = (dir == OUT) ? TRB_DIR_OUT : TRB_DIR_IN; xhci_enqueue_td(tr, 1, mps, dalen, data, dt_dir); } /* Fill status TRB */ trb_t *const status = tr->cur; xhci_clear_trb(status, tr->pcs); TRB_SET(DIR, status, (dir == OUT) ? TRB_DIR_IN : TRB_DIR_OUT); TRB_SET(TT, status, TRB_STATUS_STAGE); TRB_SET(IOC, status, 1); xhci_enqueue_trb(tr); /* Ring doorbell for EP0 */ xhci_ring_doorbell(&dev->endpoints[0]); /* Wait for transfer events */ int i, transferred = 0; const int n_stages = 2 + !!dalen; for (i = 0; i < n_stages; ++i) { const int ret = xhci_wait_for_transfer(xhci, dev->address, 1); transferred += ret; if (ret < 0) { if (ret == TIMEOUT) { xhci_debug("Stopping ID %d EP 1\n", dev->address); xhci_cmd_stop_endpoint(xhci, dev->address, 1); } xhci_debug("Stage %d/%d failed: %d\n" " trb ring: @%p\n" " setup trb: @%p\n" " status trb: @%p\n" " ep state: %d -> %d\n" " usbsts: 0x%08"PRIx32"\n", i, n_stages, ret, tr->ring, setup, status, ep_state, EC_GET(STATE, epctx), xhci->opreg->usbsts); return ret; } } if (dir == IN && data != src) memcpy(src, data, transferred); return transferred; } /* finalize == 1: if data is of packet aligned size, add a zero length packet */ static int xhci_bulk(endpoint_t *const ep, const int size, u8 *const src, const int finalize) { /* finalize: Hopefully the xHCI controller always does this. We have no control over the packets. */ u8 *data = src; xhci_t *const xhci = XHCI_INST(ep->dev->controller); const int slot_id = ep->dev->address; const int ep_id = xhci_ep_id(ep); epctx_t *const epctx = xhci->dev[slot_id].ctx.ep[ep_id]; transfer_ring_t *const tr = xhci->dev[slot_id].transfer_rings[ep_id]; const size_t off = (size_t)data & 0xffff; if ((off + size) > ((TRANSFER_RING_SIZE - 2) << 16)) { xhci_debug("Unsupported transfer size\n"); return -1; } if (!dma_coherent(src)) { data = xhci->dma_buffer; if (size > DMA_SIZE) { xhci_debug("Bulk transfer too large: %d\n", size); return -1; } if (ep->direction == OUT) memcpy(data, src, size); } /* Reset endpoint if it's not running */ const unsigned ep_state = EC_GET(STATE, epctx); if (ep_state > 1) { if (xhci_reset_endpoint(ep->dev, ep)) return -1; } /* Enqueue transfer and ring doorbell */ const unsigned mps = EC_GET(MPS, epctx); const unsigned dir = (ep->direction == OUT) ? TRB_DIR_OUT : TRB_DIR_IN; xhci_enqueue_td(tr, ep_id, mps, size, data, dir); xhci_ring_doorbell(ep); /* Wait for transfer event */ const int ret = xhci_wait_for_transfer(xhci, ep->dev->address, ep_id); if (ret < 0) { if (ret == TIMEOUT) { xhci_debug("Stopping ID %d EP %d\n", ep->dev->address, ep_id); xhci_cmd_stop_endpoint(xhci, ep->dev->address, ep_id); } xhci_debug("Bulk transfer failed: %d\n" " ep state: %d -> %d\n" " usbsts: 0x%08"PRIx32"\n", ret, ep_state, EC_GET(STATE, epctx), xhci->opreg->usbsts); return ret; } if (ep->direction == IN && data != src) memcpy(src, data, ret); return ret; } static trb_t * xhci_next_trb(trb_t *cur, int *const pcs) { ++cur; while (TRB_GET(TT, cur) == TRB_LINK) { if (pcs && TRB_GET(TC, cur)) *pcs ^= 1; cur = phys_to_virt(cur->ptr_low); } return cur; } /* create and hook-up an intr queue into device schedule */ static void * xhci_create_intr_queue(endpoint_t *const ep, const int reqsize, const int reqcount, const int reqtiming) { /* reqtiming: We ignore it and use the interval from the endpoint descriptor configured earlier. */ xhci_t *const xhci = XHCI_INST(ep->dev->controller); const int slot_id = ep->dev->address; const int ep_id = xhci_ep_id(ep); transfer_ring_t *const tr = xhci->dev[slot_id].transfer_rings[ep_id]; if (reqcount > (TRANSFER_RING_SIZE - 2)) { xhci_debug("reqcount is too high, at most %d supported\n", TRANSFER_RING_SIZE - 2); return NULL; } if (reqsize > 0x10000) { xhci_debug("reqsize is too large, at most 64KiB supported\n"); return NULL; } if (xhci->dev[slot_id].interrupt_queues[ep_id]) { xhci_debug("Only one interrupt queue per endpoint supported\n"); return NULL; } /* Allocate intrq structure and reqdata chunks */ intrq_t *const intrq = malloc(sizeof(*intrq)); if (!intrq) { xhci_debug("Out of memory\n"); return NULL; } int i; int pcs = tr->pcs; trb_t *cur = tr->cur; for (i = 0; i < reqcount; ++i) { if (TRB_GET(C, cur) == pcs) { xhci_debug("Not enough empty TRBs\n"); goto _free_return; } void *const reqdata = xhci_align(1, reqsize); if (!reqdata) { xhci_debug("Out of memory\n"); goto _free_return; } xhci_clear_trb(cur, pcs); cur->ptr_low = virt_to_phys(reqdata); cur->ptr_high = 0; TRB_SET(TL, cur, reqsize); TRB_SET(TT, cur, TRB_NORMAL); TRB_SET(ISP, cur, 1); TRB_SET(IOC, cur, 1); cur = xhci_next_trb(cur, &pcs); } intrq->size = reqsize; intrq->count = reqcount; intrq->next = tr->cur; intrq->ready = NULL; intrq->ep = ep; xhci->dev[slot_id].interrupt_queues[ep_id] = intrq; /* Now enqueue all the prepared TRBs but the last and ring the doorbell. */ for (i = 0; i < (reqcount - 1); ++i) xhci_enqueue_trb(tr); xhci_ring_doorbell(ep); return intrq; _free_return: cur = tr->cur; for (--i; i >= 0; --i) { free(phys_to_virt(cur->ptr_low)); cur = xhci_next_trb(cur, NULL); } free(intrq); return NULL; } /* remove queue from device schedule, dropping all data that came in */ static void xhci_destroy_intr_queue(endpoint_t *const ep, void *const q) { xhci_t *const xhci = XHCI_INST(ep->dev->controller); const int slot_id = ep->dev->address; const int ep_id = xhci_ep_id(ep); transfer_ring_t *const tr = xhci->dev[slot_id].transfer_rings[ep_id]; intrq_t *const intrq = (intrq_t *)q; /* Make sure the endpoint is stopped */ if (EC_GET(STATE, xhci->dev[slot_id].ctx.ep[ep_id]) == 1) { const int cc = xhci_cmd_stop_endpoint(xhci, slot_id, ep_id); if (cc != CC_SUCCESS) xhci_debug("Warning: Failed to stop endpoint\n"); } /* Process all remaining transfer events */ xhci_handle_events(xhci); /* Free all pending transfers and the interrupt queue structure */ int i; for (i = 0; i < intrq->count; ++i) { free(phys_to_virt(intrq->next->ptr_low)); intrq->next = xhci_next_trb(intrq->next, NULL); } xhci->dev[slot_id].interrupt_queues[ep_id] = NULL; free((void *)intrq); /* Reset the controller's dequeue pointer and reinitialize the ring */ xhci_cmd_set_tr_dq(xhci, slot_id, ep_id, tr->ring, 1); xhci_init_cycle_ring(tr, TRANSFER_RING_SIZE); } /* read one intr-packet from queue, if available. extend the queue for new input. return NULL if nothing new available. Recommended use: while (data=poll_intr_queue(q)) process(data); */ static u8 * xhci_poll_intr_queue(void *const q) { if (!q) return NULL; intrq_t *const intrq = (intrq_t *)q; endpoint_t *const ep = intrq->ep; xhci_t *const xhci = XHCI_INST(ep->dev->controller); /* TODO: Reset interrupt queue if it gets halted? */ xhci_handle_events(xhci); u8 *reqdata = NULL; while (!reqdata && intrq->ready) { const int ep_id = xhci_ep_id(ep); transfer_ring_t *const tr = xhci->dev[ep->dev->address].transfer_rings[ep_id]; /* Fetch the request's buffer */ reqdata = phys_to_virt(intrq->next->ptr_low); /* Enqueue the last (spare) TRB and ring doorbell */ xhci_enqueue_trb(tr); xhci_ring_doorbell(ep); /* Reuse the current buffer for the next spare TRB */ xhci_clear_trb(tr->cur, tr->pcs); tr->cur->ptr_low = virt_to_phys(reqdata); tr->cur->ptr_high = 0; TRB_SET(TL, tr->cur, intrq->size); TRB_SET(TT, tr->cur, TRB_NORMAL); TRB_SET(ISP, tr->cur, 1); TRB_SET(IOC, tr->cur, 1); /* Check if anything was transferred */ const size_t read = TRB_GET(TL, intrq->next); if (!read) reqdata = NULL; else if (read < intrq->size) /* At least zero it, poll interface is rather limited */ memset(reqdata + read, 0x00, intrq->size - read); /* Advance the interrupt queue */ if (intrq->ready == intrq->next) /* This was last TRB being ready */ intrq->ready = NULL; intrq->next = xhci_next_trb(intrq->next, NULL); } return reqdata; }