/*- * Copyright (c) 2007-2008, Juniper Networks, Inc. * Copyright (c) 2008, Excito Elektronik i Skåne AB * Copyright (c) 2008, Michael Trimarchi * * All rights reserved. * * This program is free software; you can redistribute it and/or * modify it under the terms of the GNU General Public License as * published by the Free Software Foundation version 2 of * the License. * * This program is distributed in the hope that it will be useful, * but WITHOUT ANY WARRANTY; without even the implied warranty of * MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the * GNU General Public License for more details. * * You should have received a copy of the GNU General Public License * along with this program; if not, write to the Free Software * Foundation, Inc., 59 Temple Place, Suite 330, Boston, * MA 02111-1307 USA */ #include #include #include #include #include #include #include #include #include #include "ehci.h" #ifndef CONFIG_USB_MAX_CONTROLLER_COUNT #define CONFIG_USB_MAX_CONTROLLER_COUNT 1 #endif static struct ehci_ctrl { struct ehci_hccr *hccr; /* R/O registers, not need for volatile */ struct ehci_hcor *hcor; int rootdev; uint16_t portreset; struct QH qh_list __aligned(USB_DMA_MINALIGN); struct QH periodic_queue __aligned(USB_DMA_MINALIGN); uint32_t *periodic_list; int ntds; } ehcic[CONFIG_USB_MAX_CONTROLLER_COUNT]; #define ALIGN_END_ADDR(type, ptr, size) \ ((uint32_t)(ptr) + roundup((size) * sizeof(type), USB_DMA_MINALIGN)) static struct descriptor { struct usb_hub_descriptor hub; struct usb_device_descriptor device; struct usb_linux_config_descriptor config; struct usb_linux_interface_descriptor interface; struct usb_endpoint_descriptor endpoint; } __attribute__ ((packed)) descriptor = { { 0x8, /* bDescLength */ 0x29, /* bDescriptorType: hub descriptor */ 2, /* bNrPorts -- runtime modified */ 0, /* wHubCharacteristics */ 10, /* bPwrOn2PwrGood */ 0, /* bHubCntrCurrent */ {}, /* Device removable */ {} /* at most 7 ports! XXX */ }, { 0x12, /* bLength */ 1, /* bDescriptorType: UDESC_DEVICE */ cpu_to_le16(0x0200), /* bcdUSB: v2.0 */ 9, /* bDeviceClass: UDCLASS_HUB */ 0, /* bDeviceSubClass: UDSUBCLASS_HUB */ 1, /* bDeviceProtocol: UDPROTO_HSHUBSTT */ 64, /* bMaxPacketSize: 64 bytes */ 0x0000, /* idVendor */ 0x0000, /* idProduct */ cpu_to_le16(0x0100), /* bcdDevice */ 1, /* iManufacturer */ 2, /* iProduct */ 0, /* iSerialNumber */ 1 /* bNumConfigurations: 1 */ }, { 0x9, 2, /* bDescriptorType: UDESC_CONFIG */ cpu_to_le16(0x19), 1, /* bNumInterface */ 1, /* bConfigurationValue */ 0, /* iConfiguration */ 0x40, /* bmAttributes: UC_SELF_POWER */ 0 /* bMaxPower */ }, { 0x9, /* bLength */ 4, /* bDescriptorType: UDESC_INTERFACE */ 0, /* bInterfaceNumber */ 0, /* bAlternateSetting */ 1, /* bNumEndpoints */ 9, /* bInterfaceClass: UICLASS_HUB */ 0, /* bInterfaceSubClass: UISUBCLASS_HUB */ 0, /* bInterfaceProtocol: UIPROTO_HSHUBSTT */ 0 /* iInterface */ }, { 0x7, /* bLength */ 5, /* bDescriptorType: UDESC_ENDPOINT */ 0x81, /* bEndpointAddress: * UE_DIR_IN | EHCI_INTR_ENDPT */ 3, /* bmAttributes: UE_INTERRUPT */ 8, /* wMaxPacketSize */ 255 /* bInterval */ }, }; #if defined(CONFIG_EHCI_IS_TDI) #define ehci_is_TDI() (1) #else #define ehci_is_TDI() (0) #endif int __ehci_get_port_speed(struct ehci_hcor *hcor, uint32_t reg) { return PORTSC_PSPD(reg); } int ehci_get_port_speed(struct ehci_hcor *hcor, uint32_t reg) __attribute__((weak, alias("__ehci_get_port_speed"))); void __ehci_set_usbmode(int index) { uint32_t tmp; uint32_t *reg_ptr; reg_ptr = (uint32_t *)((u8 *)&ehcic[index].hcor->or_usbcmd + USBMODE); tmp = ehci_readl(reg_ptr); tmp |= USBMODE_CM_HC; #if defined(CONFIG_EHCI_MMIO_BIG_ENDIAN) tmp |= USBMODE_BE; #endif ehci_writel(reg_ptr, tmp); } void ehci_set_usbmode(int index) __attribute__((weak, alias("__ehci_set_usbmode"))); void __ehci_powerup_fixup(uint32_t *status_reg, uint32_t *reg) { mdelay(50); } void ehci_powerup_fixup(uint32_t *status_reg, uint32_t *reg) __attribute__((weak, alias("__ehci_powerup_fixup"))); static int handshake(uint32_t *ptr, uint32_t mask, uint32_t done, int usec) { uint32_t result; do { result = ehci_readl(ptr); udelay(5); if (result == ~(uint32_t)0) return -1; result &= mask; if (result == done) return 0; usec--; } while (usec > 0); return -1; } static int ehci_reset(int index) { uint32_t cmd; int ret = 0; cmd = ehci_readl(&ehcic[index].hcor->or_usbcmd); cmd = (cmd & ~CMD_RUN) | CMD_RESET; ehci_writel(&ehcic[index].hcor->or_usbcmd, cmd); ret = handshake((uint32_t *)&ehcic[index].hcor->or_usbcmd, CMD_RESET, 0, 250 * 1000); if (ret < 0) { printf("EHCI fail to reset\n"); goto out; } if (ehci_is_TDI()) ehci_set_usbmode(index); #ifdef CONFIG_USB_EHCI_TXFIFO_THRESH cmd = ehci_readl(&ehcic[index].hcor->or_txfilltuning); cmd &= ~TXFIFO_THRESH_MASK; cmd |= TXFIFO_THRESH(CONFIG_USB_EHCI_TXFIFO_THRESH); ehci_writel(&ehcic[index].hcor->or_txfilltuning, cmd); #endif out: return ret; } static int ehci_td_buffer(struct qTD *td, void *buf, size_t sz) { uint32_t delta, next; uint32_t addr = (uint32_t)buf; int idx; if (addr != ALIGN(addr, ARCH_DMA_MINALIGN)) debug("EHCI-HCD: Misaligned buffer address (%p)\n", buf); flush_dcache_range(addr, ALIGN(addr + sz, ARCH_DMA_MINALIGN)); idx = 0; while (idx < QT_BUFFER_CNT) { td->qt_buffer[idx] = cpu_to_hc32(addr); td->qt_buffer_hi[idx] = 0; next = (addr + EHCI_PAGE_SIZE) & ~(EHCI_PAGE_SIZE - 1); delta = next - addr; if (delta >= sz) break; sz -= delta; addr = next; idx++; } if (idx == QT_BUFFER_CNT) { printf("out of buffer pointers (%u bytes left)\n", sz); return -1; } return 0; } static inline u8 ehci_encode_speed(enum usb_device_speed speed) { #define QH_HIGH_SPEED 2 #define QH_FULL_SPEED 0 #define QH_LOW_SPEED 1 if (speed == USB_SPEED_HIGH) return QH_HIGH_SPEED; if (speed == USB_SPEED_LOW) return QH_LOW_SPEED; return QH_FULL_SPEED; } static int ehci_submit_async(struct usb_device *dev, unsigned long pipe, void *buffer, int length, struct devrequest *req) { ALLOC_ALIGN_BUFFER(struct QH, qh, 1, USB_DMA_MINALIGN); struct qTD *qtd; int qtd_count = 0; int qtd_counter = 0; volatile struct qTD *vtd; unsigned long ts; uint32_t *tdp; uint32_t endpt, maxpacket, token, usbsts; uint32_t c, toggle; uint32_t cmd; int timeout; int ret = 0; struct ehci_ctrl *ctrl = dev->controller; debug("dev=%p, pipe=%lx, buffer=%p, length=%d, req=%p\n", dev, pipe, buffer, length, req); if (req != NULL) debug("req=%u (%#x), type=%u (%#x), value=%u (%#x), index=%u\n", req->request, req->request, req->requesttype, req->requesttype, le16_to_cpu(req->value), le16_to_cpu(req->value), le16_to_cpu(req->index)); #define PKT_ALIGN 512 /* * The USB transfer is split into qTD transfers. Eeach qTD transfer is * described by a transfer descriptor (the qTD). The qTDs form a linked * list with a queue head (QH). * * Each qTD transfer starts with a new USB packet, i.e. a packet cannot * have its beginning in a qTD transfer and its end in the following * one, so the qTD transfer lengths have to be chosen accordingly. * * Each qTD transfer uses up to QT_BUFFER_CNT data buffers, mapped to * single pages. The first data buffer can start at any offset within a * page (not considering the cache-line alignment issues), while the * following buffers must be page-aligned. There is no alignment * constraint on the size of a qTD transfer. */ if (req != NULL) /* 1 qTD will be needed for SETUP, and 1 for ACK. */ qtd_count += 1 + 1; if (length > 0 || req == NULL) { /* * Determine the qTD transfer size that will be used for the * data payload (not considering the first qTD transfer, which * may be longer or shorter, and the final one, which may be * shorter). * * In order to keep each packet within a qTD transfer, the qTD * transfer size is aligned to PKT_ALIGN, which is a multiple of * wMaxPacketSize (except in some cases for interrupt transfers, * see comment in submit_int_msg()). * * By default, i.e. if the input buffer is aligned to PKT_ALIGN, * QT_BUFFER_CNT full pages will be used. */ int xfr_sz = QT_BUFFER_CNT; /* * However, if the input buffer is not aligned to PKT_ALIGN, the * qTD transfer size will be one page shorter, and the first qTD * data buffer of each transfer will be page-unaligned. */ if ((uint32_t)buffer & (PKT_ALIGN - 1)) xfr_sz--; /* Convert the qTD transfer size to bytes. */ xfr_sz *= EHCI_PAGE_SIZE; /* * Approximate by excess the number of qTDs that will be * required for the data payload. The exact formula is way more * complicated and saves at most 2 qTDs, i.e. a total of 128 * bytes. */ qtd_count += 2 + length / xfr_sz; } /* * Threshold value based on the worst-case total size of the allocated qTDs for * a mass-storage transfer of 65535 blocks of 512 bytes. */ #if CONFIG_SYS_MALLOC_LEN <= 64 + 128 * 1024 #warning CONFIG_SYS_MALLOC_LEN may be too small for EHCI #endif qtd = memalign(USB_DMA_MINALIGN, qtd_count * sizeof(struct qTD)); if (qtd == NULL) { printf("unable to allocate TDs\n"); return -1; } memset(qh, 0, sizeof(struct QH)); memset(qtd, 0, qtd_count * sizeof(*qtd)); toggle = usb_gettoggle(dev, usb_pipeendpoint(pipe), usb_pipeout(pipe)); /* * Setup QH (3.6 in ehci-r10.pdf) * * qh_link ................. 03-00 H * qh_endpt1 ............... 07-04 H * qh_endpt2 ............... 0B-08 H * - qh_curtd * qh_overlay.qt_next ...... 13-10 H * - qh_overlay.qt_altnext */ qh->qh_link = cpu_to_hc32((uint32_t)&ctrl->qh_list | QH_LINK_TYPE_QH); c = (dev->speed != USB_SPEED_HIGH) && !usb_pipeendpoint(pipe); maxpacket = usb_maxpacket(dev, pipe); endpt = QH_ENDPT1_RL(8) | QH_ENDPT1_C(c) | QH_ENDPT1_MAXPKTLEN(maxpacket) | QH_ENDPT1_H(0) | QH_ENDPT1_DTC(QH_ENDPT1_DTC_DT_FROM_QTD) | QH_ENDPT1_EPS(ehci_encode_speed(dev->speed)) | QH_ENDPT1_ENDPT(usb_pipeendpoint(pipe)) | QH_ENDPT1_I(0) | QH_ENDPT1_DEVADDR(usb_pipedevice(pipe)); qh->qh_endpt1 = cpu_to_hc32(endpt); endpt = QH_ENDPT2_MULT(1) | QH_ENDPT2_PORTNUM(dev->portnr) | QH_ENDPT2_HUBADDR(dev->parent->devnum) | QH_ENDPT2_UFCMASK(0) | QH_ENDPT2_UFSMASK(0); qh->qh_endpt2 = cpu_to_hc32(endpt); qh->qh_overlay.qt_next = cpu_to_hc32(QT_NEXT_TERMINATE); tdp = &qh->qh_overlay.qt_next; if (req != NULL) { /* * Setup request qTD (3.5 in ehci-r10.pdf) * * qt_next ................ 03-00 H * qt_altnext ............. 07-04 H * qt_token ............... 0B-08 H * * [ buffer, buffer_hi ] loaded with "req". */ qtd[qtd_counter].qt_next = cpu_to_hc32(QT_NEXT_TERMINATE); qtd[qtd_counter].qt_altnext = cpu_to_hc32(QT_NEXT_TERMINATE); token = QT_TOKEN_DT(0) | QT_TOKEN_TOTALBYTES(sizeof(*req)) | QT_TOKEN_IOC(0) | QT_TOKEN_CPAGE(0) | QT_TOKEN_CERR(3) | QT_TOKEN_PID(QT_TOKEN_PID_SETUP) | QT_TOKEN_STATUS(QT_TOKEN_STATUS_ACTIVE); qtd[qtd_counter].qt_token = cpu_to_hc32(token); if (ehci_td_buffer(&qtd[qtd_counter], req, sizeof(*req))) { printf("unable to construct SETUP TD\n"); goto fail; } /* Update previous qTD! */ *tdp = cpu_to_hc32((uint32_t)&qtd[qtd_counter]); tdp = &qtd[qtd_counter++].qt_next; toggle = 1; } if (length > 0 || req == NULL) { uint8_t *buf_ptr = buffer; int left_length = length; do { /* * Determine the size of this qTD transfer. By default, * QT_BUFFER_CNT full pages can be used. */ int xfr_bytes = QT_BUFFER_CNT * EHCI_PAGE_SIZE; /* * However, if the input buffer is not page-aligned, the * portion of the first page before the buffer start * offset within that page is unusable. */ xfr_bytes -= (uint32_t)buf_ptr & (EHCI_PAGE_SIZE - 1); /* * In order to keep each packet within a qTD transfer, * align the qTD transfer size to PKT_ALIGN. */ xfr_bytes &= ~(PKT_ALIGN - 1); /* * This transfer may be shorter than the available qTD * transfer size that has just been computed. */ xfr_bytes = min(xfr_bytes, left_length); /* * Setup request qTD (3.5 in ehci-r10.pdf) * * qt_next ................ 03-00 H * qt_altnext ............. 07-04 H * qt_token ............... 0B-08 H * * [ buffer, buffer_hi ] loaded with "buffer". */ qtd[qtd_counter].qt_next = cpu_to_hc32(QT_NEXT_TERMINATE); qtd[qtd_counter].qt_altnext = cpu_to_hc32(QT_NEXT_TERMINATE); token = QT_TOKEN_DT(toggle) | QT_TOKEN_TOTALBYTES(xfr_bytes) | QT_TOKEN_IOC(req == NULL) | QT_TOKEN_CPAGE(0) | QT_TOKEN_CERR(3) | QT_TOKEN_PID(usb_pipein(pipe) ? QT_TOKEN_PID_IN : QT_TOKEN_PID_OUT) | QT_TOKEN_STATUS(QT_TOKEN_STATUS_ACTIVE); qtd[qtd_counter].qt_token = cpu_to_hc32(token); if (ehci_td_buffer(&qtd[qtd_counter], buf_ptr, xfr_bytes)) { printf("unable to construct DATA TD\n"); goto fail; } /* Update previous qTD! */ *tdp = cpu_to_hc32((uint32_t)&qtd[qtd_counter]); tdp = &qtd[qtd_counter++].qt_next; /* * Data toggle has to be adjusted since the qTD transfer * size is not always an even multiple of * wMaxPacketSize. */ if ((xfr_bytes / maxpacket) & 1) toggle ^= 1; buf_ptr += xfr_bytes; left_length -= xfr_bytes; } while (left_length > 0); } if (req != NULL) { /* * Setup request qTD (3.5 in ehci-r10.pdf) * * qt_next ................ 03-00 H * qt_altnext ............. 07-04 H * qt_token ............... 0B-08 H */ qtd[qtd_counter].qt_next = cpu_to_hc32(QT_NEXT_TERMINATE); qtd[qtd_counter].qt_altnext = cpu_to_hc32(QT_NEXT_TERMINATE); token = QT_TOKEN_DT(1) | QT_TOKEN_TOTALBYTES(0) | QT_TOKEN_IOC(1) | QT_TOKEN_CPAGE(0) | QT_TOKEN_CERR(3) | QT_TOKEN_PID(usb_pipein(pipe) ? QT_TOKEN_PID_OUT : QT_TOKEN_PID_IN) | QT_TOKEN_STATUS(QT_TOKEN_STATUS_ACTIVE); qtd[qtd_counter].qt_token = cpu_to_hc32(token); /* Update previous qTD! */ *tdp = cpu_to_hc32((uint32_t)&qtd[qtd_counter]); tdp = &qtd[qtd_counter++].qt_next; } ctrl->qh_list.qh_link = cpu_to_hc32((uint32_t)qh | QH_LINK_TYPE_QH); /* Flush dcache */ flush_dcache_range((uint32_t)&ctrl->qh_list, ALIGN_END_ADDR(struct QH, &ctrl->qh_list, 1)); flush_dcache_range((uint32_t)qh, ALIGN_END_ADDR(struct QH, qh, 1)); flush_dcache_range((uint32_t)qtd, ALIGN_END_ADDR(struct qTD, qtd, qtd_count)); /* Set async. queue head pointer. */ ehci_writel(&ctrl->hcor->or_asynclistaddr, (uint32_t)&ctrl->qh_list); usbsts = ehci_readl(&ctrl->hcor->or_usbsts); ehci_writel(&ctrl->hcor->or_usbsts, (usbsts & 0x3f)); /* Enable async. schedule. */ cmd = ehci_readl(&ctrl->hcor->or_usbcmd); cmd |= CMD_ASE; ehci_writel(&ctrl->hcor->or_usbcmd, cmd); ret = handshake((uint32_t *)&ctrl->hcor->or_usbsts, STS_ASS, STS_ASS, 100 * 1000); if (ret < 0) { printf("EHCI fail timeout STS_ASS set\n"); goto fail; } /* Wait for TDs to be processed. */ ts = get_timer(0); vtd = &qtd[qtd_counter - 1]; timeout = USB_TIMEOUT_MS(pipe); do { /* Invalidate dcache */ invalidate_dcache_range((uint32_t)&ctrl->qh_list, ALIGN_END_ADDR(struct QH, &ctrl->qh_list, 1)); invalidate_dcache_range((uint32_t)qh, ALIGN_END_ADDR(struct QH, qh, 1)); invalidate_dcache_range((uint32_t)qtd, ALIGN_END_ADDR(struct qTD, qtd, qtd_count)); token = hc32_to_cpu(vtd->qt_token); if (!(QT_TOKEN_GET_STATUS(token) & QT_TOKEN_STATUS_ACTIVE)) break; WATCHDOG_RESET(); } while (get_timer(ts) < timeout); /* * Invalidate the memory area occupied by buffer * Don't try to fix the buffer alignment, if it isn't properly * aligned it's upper layer's fault so let invalidate_dcache_range() * vow about it. But we have to fix the length as it's actual * transfer length and can be unaligned. This is potentially * dangerous operation, it's responsibility of the calling * code to make sure enough space is reserved. */ invalidate_dcache_range((uint32_t)buffer, ALIGN((uint32_t)buffer + length, ARCH_DMA_MINALIGN)); /* Check that the TD processing happened */ if (QT_TOKEN_GET_STATUS(token) & QT_TOKEN_STATUS_ACTIVE) printf("EHCI timed out on TD - token=%#x\n", token); /* Disable async schedule. */ cmd = ehci_readl(&ctrl->hcor->or_usbcmd); cmd &= ~CMD_ASE; ehci_writel(&ctrl->hcor->or_usbcmd, cmd); ret = handshake((uint32_t *)&ctrl->hcor->or_usbsts, STS_ASS, 0, 100 * 1000); if (ret < 0) { printf("EHCI fail timeout STS_ASS reset\n"); goto fail; } token = hc32_to_cpu(qh->qh_overlay.qt_token); if (!(QT_TOKEN_GET_STATUS(token) & QT_TOKEN_STATUS_ACTIVE)) { debug("TOKEN=%#x\n", token); switch (QT_TOKEN_GET_STATUS(token) & ~(QT_TOKEN_STATUS_SPLITXSTATE | QT_TOKEN_STATUS_PERR)) { case 0: toggle = QT_TOKEN_GET_DT(token); usb_settoggle(dev, usb_pipeendpoint(pipe), usb_pipeout(pipe), toggle); dev->status = 0; break; case QT_TOKEN_STATUS_HALTED: dev->status = USB_ST_STALLED; break; case QT_TOKEN_STATUS_ACTIVE | QT_TOKEN_STATUS_DATBUFERR: case QT_TOKEN_STATUS_DATBUFERR: dev->status = USB_ST_BUF_ERR; break; case QT_TOKEN_STATUS_HALTED | QT_TOKEN_STATUS_BABBLEDET: case QT_TOKEN_STATUS_BABBLEDET: dev->status = USB_ST_BABBLE_DET; break; default: dev->status = USB_ST_CRC_ERR; if (QT_TOKEN_GET_STATUS(token) & QT_TOKEN_STATUS_HALTED) dev->status |= USB_ST_STALLED; break; } dev->act_len = length - QT_TOKEN_GET_TOTALBYTES(token); } else { dev->act_len = 0; debug("dev=%u, usbsts=%#x, p[1]=%#x, p[2]=%#x\n", dev->devnum, ehci_readl(&ctrl->hcor->or_usbsts), ehci_readl(&ctrl->hcor->or_portsc[0]), ehci_readl(&ctrl->hcor->or_portsc[1])); } free(qtd); return (dev->status != USB_ST_NOT_PROC) ? 0 : -1; fail: free(qtd); return -1; } int ehci_submit_root(struct usb_device *dev, unsigned long pipe, void *buffer, int length, struct devrequest *req) { uint8_t tmpbuf[4]; u16 typeReq; void *srcptr = NULL; int len, srclen; uint32_t reg; uint32_t *status_reg; int port = le16_to_cpu(req->index) & 0xff; struct ehci_ctrl *ctrl = dev->controller; if (port > CONFIG_SYS_USB_EHCI_MAX_ROOT_PORTS) { printf("The request port(%d) is not configured\n", port - 1); return -1; } status_reg = (uint32_t *)&ctrl->hcor->or_portsc[port - 1]; srclen = 0; debug("req=%u (%#x), type=%u (%#x), value=%u, index=%u\n", req->request, req->request, req->requesttype, req->requesttype, le16_to_cpu(req->value), le16_to_cpu(req->index)); typeReq = req->request | req->requesttype << 8; switch (typeReq) { case DeviceRequest | USB_REQ_GET_DESCRIPTOR: switch (le16_to_cpu(req->value) >> 8) { case USB_DT_DEVICE: debug("USB_DT_DEVICE request\n"); srcptr = &descriptor.device; srclen = descriptor.device.bLength; break; case USB_DT_CONFIG: debug("USB_DT_CONFIG config\n"); srcptr = &descriptor.config; srclen = descriptor.config.bLength + descriptor.interface.bLength + descriptor.endpoint.bLength; break; case USB_DT_STRING: debug("USB_DT_STRING config\n"); switch (le16_to_cpu(req->value) & 0xff) { case 0: /* Language */ srcptr = "\4\3\1\0"; srclen = 4; break; case 1: /* Vendor */ srcptr = "\16\3u\0-\0b\0o\0o\0t\0"; srclen = 14; break; case 2: /* Product */ srcptr = "\52\3E\0H\0C\0I\0 " "\0H\0o\0s\0t\0 " "\0C\0o\0n\0t\0r\0o\0l\0l\0e\0r\0"; srclen = 42; break; default: debug("unknown value DT_STRING %x\n", le16_to_cpu(req->value)); goto unknown; } break; default: debug("unknown value %x\n", le16_to_cpu(req->value)); goto unknown; } break; case USB_REQ_GET_DESCRIPTOR | ((USB_DIR_IN | USB_RT_HUB) << 8): switch (le16_to_cpu(req->value) >> 8) { case USB_DT_HUB: debug("USB_DT_HUB config\n"); srcptr = &descriptor.hub; srclen = descriptor.hub.bLength; break; default: debug("unknown value %x\n", le16_to_cpu(req->value)); goto unknown; } break; case USB_REQ_SET_ADDRESS | (USB_RECIP_DEVICE << 8): debug("USB_REQ_SET_ADDRESS\n"); ctrl->rootdev = le16_to_cpu(req->value); break; case DeviceOutRequest | USB_REQ_SET_CONFIGURATION: debug("USB_REQ_SET_CONFIGURATION\n"); /* Nothing to do */ break; case USB_REQ_GET_STATUS | ((USB_DIR_IN | USB_RT_HUB) << 8): tmpbuf[0] = 1; /* USB_STATUS_SELFPOWERED */ tmpbuf[1] = 0; srcptr = tmpbuf; srclen = 2; break; case USB_REQ_GET_STATUS | ((USB_RT_PORT | USB_DIR_IN) << 8): memset(tmpbuf, 0, 4); reg = ehci_readl(status_reg); if (reg & EHCI_PS_CS) tmpbuf[0] |= USB_PORT_STAT_CONNECTION; if (reg & EHCI_PS_PE) tmpbuf[0] |= USB_PORT_STAT_ENABLE; if (reg & EHCI_PS_SUSP) tmpbuf[0] |= USB_PORT_STAT_SUSPEND; if (reg & EHCI_PS_OCA) tmpbuf[0] |= USB_PORT_STAT_OVERCURRENT; if (reg & EHCI_PS_PR) tmpbuf[0] |= USB_PORT_STAT_RESET; if (reg & EHCI_PS_PP) tmpbuf[1] |= USB_PORT_STAT_POWER >> 8; if (ehci_is_TDI()) { switch (ehci_get_port_speed(ctrl->hcor, reg)) { case PORTSC_PSPD_FS: break; case PORTSC_PSPD_LS: tmpbuf[1] |= USB_PORT_STAT_LOW_SPEED >> 8; break; case PORTSC_PSPD_HS: default: tmpbuf[1] |= USB_PORT_STAT_HIGH_SPEED >> 8; break; } } else { tmpbuf[1] |= USB_PORT_STAT_HIGH_SPEED >> 8; } if (reg & EHCI_PS_CSC) tmpbuf[2] |= USB_PORT_STAT_C_CONNECTION; if (reg & EHCI_PS_PEC) tmpbuf[2] |= USB_PORT_STAT_C_ENABLE; if (reg & EHCI_PS_OCC) tmpbuf[2] |= USB_PORT_STAT_C_OVERCURRENT; if (ctrl->portreset & (1 << port)) tmpbuf[2] |= USB_PORT_STAT_C_RESET; srcptr = tmpbuf; srclen = 4; break; case USB_REQ_SET_FEATURE | ((USB_DIR_OUT | USB_RT_PORT) << 8): reg = ehci_readl(status_reg); reg &= ~EHCI_PS_CLEAR; switch (le16_to_cpu(req->value)) { case USB_PORT_FEAT_ENABLE: reg |= EHCI_PS_PE; ehci_writel(status_reg, reg); break; case USB_PORT_FEAT_POWER: if (HCS_PPC(ehci_readl(&ctrl->hccr->cr_hcsparams))) { reg |= EHCI_PS_PP; ehci_writel(status_reg, reg); } break; case USB_PORT_FEAT_RESET: if ((reg & (EHCI_PS_PE | EHCI_PS_CS)) == EHCI_PS_CS && !ehci_is_TDI() && EHCI_PS_IS_LOWSPEED(reg)) { /* Low speed device, give up ownership. */ debug("port %d low speed --> companion\n", port - 1); reg |= EHCI_PS_PO; ehci_writel(status_reg, reg); break; } else { int ret; reg |= EHCI_PS_PR; reg &= ~EHCI_PS_PE; ehci_writel(status_reg, reg); /* * caller must wait, then call GetPortStatus * usb 2.0 specification say 50 ms resets on * root */ ehci_powerup_fixup(status_reg, ®); ehci_writel(status_reg, reg & ~EHCI_PS_PR); /* * A host controller must terminate the reset * and stabilize the state of the port within * 2 milliseconds */ ret = handshake(status_reg, EHCI_PS_PR, 0, 2 * 1000); if (!ret) ctrl->portreset |= 1 << port; else printf("port(%d) reset error\n", port - 1); } break; case USB_PORT_FEAT_TEST: reg &= ~(0xf << 16); reg |= ((le16_to_cpu(req->index) >> 8) & 0xf) << 16; ehci_writel(status_reg, reg); break; default: debug("unknown feature %x\n", le16_to_cpu(req->value)); goto unknown; } /* unblock posted writes */ (void) ehci_readl(&ctrl->hcor->or_usbcmd); break; case USB_REQ_CLEAR_FEATURE | ((USB_DIR_OUT | USB_RT_PORT) << 8): reg = ehci_readl(status_reg); reg &= ~EHCI_PS_CLEAR; switch (le16_to_cpu(req->value)) { case USB_PORT_FEAT_ENABLE: reg &= ~EHCI_PS_PE; break; case USB_PORT_FEAT_C_ENABLE: reg |= EHCI_PS_PE; break; case USB_PORT_FEAT_POWER: if (HCS_PPC(ehci_readl(&ctrl->hccr->cr_hcsparams))) reg &= ~EHCI_PS_PP; break; case USB_PORT_FEAT_C_CONNECTION: reg |= EHCI_PS_CSC; break; case USB_PORT_FEAT_OVER_CURRENT: reg |= EHCI_PS_OCC; break; case USB_PORT_FEAT_C_RESET: ctrl->portreset &= ~(1 << port); break; default: debug("unknown feature %x\n", le16_to_cpu(req->value)); goto unknown; } ehci_writel(status_reg, reg); /* unblock posted write */ (void) ehci_readl(&ctrl->hcor->or_usbcmd); break; default: debug("Unknown request\n"); goto unknown; } mdelay(1); len = min3(srclen, le16_to_cpu(req->length), length); if (srcptr != NULL && len > 0) memcpy(buffer, srcptr, len); else debug("Len is 0\n"); dev->act_len = len; dev->status = 0; return 0; unknown: debug("requesttype=%x, request=%x, value=%x, index=%x, length=%x\n", req->requesttype, req->request, le16_to_cpu(req->value), le16_to_cpu(req->index), le16_to_cpu(req->length)); dev->act_len = 0; dev->status = USB_ST_STALLED; return -1; } int usb_lowlevel_stop(int index) { return ehci_hcd_stop(index); } int usb_lowlevel_init(int index, void **controller) { uint32_t reg; uint32_t cmd; struct QH *qh_list; struct QH *periodic; int i; if (ehci_hcd_init(index, &ehcic[index].hccr, &ehcic[index].hcor)) return -1; /* EHCI spec section 4.1 */ if (ehci_reset(index)) return -1; #if defined(CONFIG_EHCI_HCD_INIT_AFTER_RESET) if (ehci_hcd_init(index, &ehcic[index].hccr, &ehcic[index].hcor)) return -1; #endif /* Set the high address word (aka segment) for 64-bit controller */ if (ehci_readl(&ehcic[index].hccr->cr_hccparams) & 1) ehci_writel(ehcic[index].hcor->or_ctrldssegment, 0); qh_list = &ehcic[index].qh_list; /* Set head of reclaim list */ memset(qh_list, 0, sizeof(*qh_list)); qh_list->qh_link = cpu_to_hc32((uint32_t)qh_list | QH_LINK_TYPE_QH); qh_list->qh_endpt1 = cpu_to_hc32(QH_ENDPT1_H(1) | QH_ENDPT1_EPS(USB_SPEED_HIGH)); qh_list->qh_curtd = cpu_to_hc32(QT_NEXT_TERMINATE); qh_list->qh_overlay.qt_next = cpu_to_hc32(QT_NEXT_TERMINATE); qh_list->qh_overlay.qt_altnext = cpu_to_hc32(QT_NEXT_TERMINATE); qh_list->qh_overlay.qt_token = cpu_to_hc32(QT_TOKEN_STATUS(QT_TOKEN_STATUS_HALTED)); /* Set async. queue head pointer. */ ehci_writel(&ehcic[index].hcor->or_asynclistaddr, (uint32_t)qh_list); /* * Set up periodic list * Step 1: Parent QH for all periodic transfers. */ periodic = &ehcic[index].periodic_queue; memset(periodic, 0, sizeof(*periodic)); periodic->qh_link = cpu_to_hc32(QH_LINK_TERMINATE); periodic->qh_overlay.qt_next = cpu_to_hc32(QT_NEXT_TERMINATE); periodic->qh_overlay.qt_altnext = cpu_to_hc32(QT_NEXT_TERMINATE); /* * Step 2: Setup frame-list: Every microframe, USB tries the same list. * In particular, device specifications on polling frequency * are disregarded. Keyboards seem to send NAK/NYet reliably * when polled with an empty buffer. * * Split Transactions will be spread across microframes using * S-mask and C-mask. */ ehcic[index].periodic_list = memalign(4096, 1024*4); if (!ehcic[index].periodic_list) return -ENOMEM; for (i = 0; i < 1024; i++) { ehcic[index].periodic_list[i] = (uint32_t)periodic | QH_LINK_TYPE_QH; } /* Set periodic list base address */ ehci_writel(&ehcic[index].hcor->or_periodiclistbase, (uint32_t)ehcic[index].periodic_list); reg = ehci_readl(&ehcic[index].hccr->cr_hcsparams); descriptor.hub.bNbrPorts = HCS_N_PORTS(reg); debug("Register %x NbrPorts %d\n", reg, descriptor.hub.bNbrPorts); /* Port Indicators */ if (HCS_INDICATOR(reg)) put_unaligned(get_unaligned(&descriptor.hub.wHubCharacteristics) | 0x80, &descriptor.hub.wHubCharacteristics); /* Port Power Control */ if (HCS_PPC(reg)) put_unaligned(get_unaligned(&descriptor.hub.wHubCharacteristics) | 0x01, &descriptor.hub.wHubCharacteristics); /* Start the host controller. */ cmd = ehci_readl(&ehcic[index].hcor->or_usbcmd); /* * Philips, Intel, and maybe others need CMD_RUN before the * root hub will detect new devices (why?); NEC doesn't */ cmd &= ~(CMD_LRESET|CMD_IAAD|CMD_PSE|CMD_ASE|CMD_RESET); cmd |= CMD_RUN; ehci_writel(&ehcic[index].hcor->or_usbcmd, cmd); /* take control over the ports */ cmd = ehci_readl(&ehcic[index].hcor->or_configflag); cmd |= FLAG_CF; ehci_writel(&ehcic[index].hcor->or_configflag, cmd); /* unblock posted write */ cmd = ehci_readl(&ehcic[index].hcor->or_usbcmd); mdelay(5); reg = HC_VERSION(ehci_readl(&ehcic[index].hccr->cr_capbase)); printf("USB EHCI %x.%02x\n", reg >> 8, reg & 0xff); ehcic[index].rootdev = 0; *controller = &ehcic[index]; return 0; } int submit_bulk_msg(struct usb_device *dev, unsigned long pipe, void *buffer, int length) { if (usb_pipetype(pipe) != PIPE_BULK) { debug("non-bulk pipe (type=%lu)", usb_pipetype(pipe)); return -1; } return ehci_submit_async(dev, pipe, buffer, length, NULL); } int submit_control_msg(struct usb_device *dev, unsigned long pipe, void *buffer, int length, struct devrequest *setup) { struct ehci_ctrl *ctrl = dev->controller; if (usb_pipetype(pipe) != PIPE_CONTROL) { debug("non-control pipe (type=%lu)", usb_pipetype(pipe)); return -1; } if (usb_pipedevice(pipe) == ctrl->rootdev) { if (!ctrl->rootdev) dev->speed = USB_SPEED_HIGH; return ehci_submit_root(dev, pipe, buffer, length, setup); } return ehci_submit_async(dev, pipe, buffer, length, setup); } struct int_queue { struct QH *first; struct QH *current; struct QH *last; struct qTD *tds; }; #define NEXT_QH(qh) (struct QH *)((qh)->qh_link & ~0x1f) static int enable_periodic(struct ehci_ctrl *ctrl) { uint32_t cmd; struct ehci_hcor *hcor = ctrl->hcor; int ret; cmd = ehci_readl(&hcor->or_usbcmd); cmd |= CMD_PSE; ehci_writel(&hcor->or_usbcmd, cmd); ret = handshake((uint32_t *)&hcor->or_usbsts, STS_PSS, STS_PSS, 100 * 1000); if (ret < 0) { printf("EHCI failed: timeout when enabling periodic list\n"); return -ETIMEDOUT; } udelay(1000); return 0; } static int disable_periodic(struct ehci_ctrl *ctrl) { uint32_t cmd; struct ehci_hcor *hcor = ctrl->hcor; int ret; cmd = ehci_readl(&hcor->or_usbcmd); cmd &= ~CMD_PSE; ehci_writel(&hcor->or_usbcmd, cmd); ret = handshake((uint32_t *)&hcor->or_usbsts, STS_PSS, 0, 100 * 1000); if (ret < 0) { printf("EHCI failed: timeout when disabling periodic list\n"); return -ETIMEDOUT; } return 0; } static int periodic_schedules; struct int_queue * create_int_queue(struct usb_device *dev, unsigned long pipe, int queuesize, int elementsize, void *buffer) { struct ehci_ctrl *ctrl = dev->controller; struct int_queue *result = NULL; int i; debug("Enter create_int_queue\n"); if (usb_pipetype(pipe) != PIPE_INTERRUPT) { debug("non-interrupt pipe (type=%lu)", usb_pipetype(pipe)); return NULL; } /* limit to 4 full pages worth of data - * we can safely fit them in a single TD, * no matter the alignment */ if (elementsize >= 16384) { debug("too large elements for interrupt transfers\n"); return NULL; } result = malloc(sizeof(*result)); if (!result) { debug("ehci intr queue: out of memory\n"); goto fail1; } result->first = memalign(32, sizeof(struct QH) * queuesize); if (!result->first) { debug("ehci intr queue: out of memory\n"); goto fail2; } result->current = result->first; result->last = result->first + queuesize - 1; result->tds = memalign(32, sizeof(struct qTD) * queuesize); if (!result->tds) { debug("ehci intr queue: out of memory\n"); goto fail3; } memset(result->first, 0, sizeof(struct QH) * queuesize); memset(result->tds, 0, sizeof(struct qTD) * queuesize); for (i = 0; i < queuesize; i++) { struct QH *qh = result->first + i; struct qTD *td = result->tds + i; void **buf = &qh->buffer; qh->qh_link = (uint32_t)(qh+1) | QH_LINK_TYPE_QH; if (i == queuesize - 1) qh->qh_link = QH_LINK_TERMINATE; qh->qh_overlay.qt_next = (uint32_t)td; qh->qh_endpt1 = (0 << 28) | /* No NAK reload (ehci 4.9) */ (usb_maxpacket(dev, pipe) << 16) | /* MPS */ (1 << 14) | QH_ENDPT1_EPS(ehci_encode_speed(dev->speed)) | (usb_pipeendpoint(pipe) << 8) | /* Endpoint Number */ (usb_pipedevice(pipe) << 0); qh->qh_endpt2 = (1 << 30) | /* 1 Tx per mframe */ (1 << 0); /* S-mask: microframe 0 */ if (dev->speed == USB_SPEED_LOW || dev->speed == USB_SPEED_FULL) { debug("TT: port: %d, hub address: %d\n", dev->portnr, dev->parent->devnum); qh->qh_endpt2 |= (dev->portnr << 23) | (dev->parent->devnum << 16) | (0x1c << 8); /* C-mask: microframes 2-4 */ } td->qt_next = QT_NEXT_TERMINATE; td->qt_altnext = QT_NEXT_TERMINATE; debug("communication direction is '%s'\n", usb_pipein(pipe) ? "in" : "out"); td->qt_token = (elementsize << 16) | ((usb_pipein(pipe) ? 1 : 0) << 8) | /* IN/OUT token */ 0x80; /* active */ td->qt_buffer[0] = (uint32_t)buffer + i * elementsize; td->qt_buffer[1] = (td->qt_buffer[0] + 0x1000) & ~0xfff; td->qt_buffer[2] = (td->qt_buffer[0] + 0x2000) & ~0xfff; td->qt_buffer[3] = (td->qt_buffer[0] + 0x3000) & ~0xfff; td->qt_buffer[4] = (td->qt_buffer[0] + 0x4000) & ~0xfff; *buf = buffer + i * elementsize; } if (disable_periodic(ctrl) < 0) { debug("FATAL: periodic should never fail, but did"); goto fail3; } /* hook up to periodic list */ struct QH *list = &ctrl->periodic_queue; result->last->qh_link = list->qh_link; list->qh_link = (uint32_t)result->first | QH_LINK_TYPE_QH; if (enable_periodic(ctrl) < 0) { debug("FATAL: periodic should never fail, but did"); goto fail3; } periodic_schedules++; debug("Exit create_int_queue\n"); return result; fail3: if (result->tds) free(result->tds); fail2: if (result->first) free(result->first); if (result) free(result); fail1: return NULL; } void *poll_int_queue(struct usb_device *dev, struct int_queue *queue) { struct QH *cur = queue->current; /* depleted queue */ if (cur == NULL) { debug("Exit poll_int_queue with completed queue\n"); return NULL; } /* still active */ if (cur->qh_overlay.qt_token & 0x80) { debug("Exit poll_int_queue with no completed intr transfer. " "token is %x\n", cur->qh_overlay.qt_token); return NULL; } if (!(cur->qh_link & QH_LINK_TERMINATE)) queue->current++; else queue->current = NULL; debug("Exit poll_int_queue with completed intr transfer. " "token is %x at %p (first at %p)\n", cur->qh_overlay.qt_token, &cur->qh_overlay.qt_token, queue->first); return cur->buffer; } /* Do not free buffers associated with QHs, they're owned by someone else */ int destroy_int_queue(struct usb_device *dev, struct int_queue *queue) { struct ehci_ctrl *ctrl = dev->controller; int result = -1; unsigned long timeout; if (disable_periodic(ctrl) < 0) { debug("FATAL: periodic should never fail, but did"); goto out; } periodic_schedules--; struct QH *cur = &ctrl->periodic_queue; timeout = get_timer(0) + 500; /* abort after 500ms */ while (!(cur->qh_link & QH_LINK_TERMINATE)) { debug("considering %p, with qh_link %x\n", cur, cur->qh_link); if (NEXT_QH(cur) == queue->first) { debug("found candidate. removing from chain\n"); cur->qh_link = queue->last->qh_link; result = 0; break; } cur = NEXT_QH(cur); if (get_timer(0) > timeout) { printf("Timeout destroying interrupt endpoint queue\n"); result = -1; goto out; } } if (periodic_schedules > 0) { result = enable_periodic(ctrl); if (result < 0) debug("FATAL: periodic should never fail, but did"); } out: free(queue->tds); free(queue->first); free(queue); return result; } int submit_int_msg(struct usb_device *dev, unsigned long pipe, void *buffer, int length, int interval) { void *backbuffer; struct int_queue *queue; unsigned long timeout; int result = 0, ret; debug("dev=%p, pipe=%lu, buffer=%p, length=%d, interval=%d", dev, pipe, buffer, length, interval); /* * Interrupt transfers requiring several transactions are not supported * because bInterval is ignored. * * Also, ehci_submit_async() relies on wMaxPacketSize being a power of 2 * <= PKT_ALIGN if several qTDs are required, while the USB * specification does not constrain this for interrupt transfers. That * means that ehci_submit_async() would support interrupt transfers * requiring several transactions only as long as the transfer size does * not require more than a single qTD. */ if (length > usb_maxpacket(dev, pipe)) { printf("%s: Interrupt transfers requiring several " "transactions are not supported.\n", __func__); return -1; } queue = create_int_queue(dev, pipe, 1, length, buffer); timeout = get_timer(0) + USB_TIMEOUT_MS(pipe); while ((backbuffer = poll_int_queue(dev, queue)) == NULL) if (get_timer(0) > timeout) { printf("Timeout poll on interrupt endpoint\n"); result = -ETIMEDOUT; break; } if (backbuffer != buffer) { debug("got wrong buffer back (%x instead of %x)\n", (uint32_t)backbuffer, (uint32_t)buffer); return -EINVAL; } ret = destroy_int_queue(dev, queue); if (ret < 0) return ret; /* everything worked out fine */ return result; }