/* * Linux host USB redirector * * Copyright (c) 2005 Fabrice Bellard * * Copyright (c) 2008 Max Krasnyansky * Support for host device auto connect & disconnect * Major rewrite to support fully async operation * * Permission is hereby granted, free of charge, to any person obtaining a copy * of this software and associated documentation files (the "Software"), to deal * in the Software without restriction, including without limitation the rights * to use, copy, modify, merge, publish, distribute, sublicense, and/or sell * copies of the Software, and to permit persons to whom the Software is * furnished to do so, subject to the following conditions: * * The above copyright notice and this permission notice shall be included in * all copies or substantial portions of the Software. * * THE SOFTWARE IS PROVIDED "AS IS", WITHOUT WARRANTY OF ANY KIND, EXPRESS OR * IMPLIED, INCLUDING BUT NOT LIMITED TO THE WARRANTIES OF MERCHANTABILITY, * FITNESS FOR A PARTICULAR PURPOSE AND NONINFRINGEMENT. IN NO EVENT SHALL * THE AUTHORS OR COPYRIGHT HOLDERS BE LIABLE FOR ANY CLAIM, DAMAGES OR OTHER * LIABILITY, WHETHER IN AN ACTION OF CONTRACT, TORT OR OTHERWISE, ARISING FROM, * OUT OF OR IN CONNECTION WITH THE SOFTWARE OR THE USE OR OTHER DEALINGS IN * THE SOFTWARE. */ #include "qemu-common.h" #include "qemu-timer.h" #include "console.h" #if defined(__linux__) #include #include #include #include #include #include #include "hw/usb.h" typedef int USBScanFunc(void *opaque, int bus_num, int addr, int class_id, int vendor_id, int product_id, const char *product_name, int speed); static int usb_host_find_device(int *pbus_num, int *paddr, char *product_name, int product_name_size, const char *devname); //#define DEBUG #ifdef DEBUG #define dprintf printf #else #define dprintf(...) #endif #define USBDEVFS_PATH "/proc/bus/usb" #define PRODUCT_NAME_SZ 32 #define MAX_ENDPOINTS 16 /* endpoint association data */ struct endp_data { uint8_t type; uint8_t halted; }; enum { CTRL_STATE_IDLE = 0, CTRL_STATE_SETUP, CTRL_STATE_DATA, CTRL_STATE_ACK }; /* * Control transfer state. * Note that 'buffer' _must_ follow 'req' field because * we need contigious buffer when we submit control URB. */ struct ctrl_struct { uint16_t len; uint16_t offset; uint8_t state; struct usb_ctrlrequest req; uint8_t buffer[1024]; }; typedef struct USBHostDevice { USBDevice dev; int fd; uint8_t descr[1024]; int descr_len; int configuration; int ninterfaces; int closing; struct ctrl_struct ctrl; struct endp_data endp_table[MAX_ENDPOINTS]; /* Host side address */ int bus_num; int addr; struct USBHostDevice *next; } USBHostDevice; static int is_isoc(USBHostDevice *s, int ep) { return s->endp_table[ep - 1].type == USBDEVFS_URB_TYPE_ISO; } static int is_halted(USBHostDevice *s, int ep) { return s->endp_table[ep - 1].halted; } static void clear_halt(USBHostDevice *s, int ep) { s->endp_table[ep - 1].halted = 0; } static void set_halt(USBHostDevice *s, int ep) { s->endp_table[ep - 1].halted = 1; } static USBHostDevice *hostdev_list; static void hostdev_link(USBHostDevice *dev) { dev->next = hostdev_list; hostdev_list = dev; } static void hostdev_unlink(USBHostDevice *dev) { USBHostDevice *pdev = hostdev_list; USBHostDevice **prev = &hostdev_list; while (pdev) { if (pdev == dev) { *prev = dev->next; return; } prev = &pdev->next; pdev = pdev->next; } } static USBHostDevice *hostdev_find(int bus_num, int addr) { USBHostDevice *s = hostdev_list; while (s) { if (s->bus_num == bus_num && s->addr == addr) return s; s = s->next; } return NULL; } /* * Async URB state. * We always allocate one isoc descriptor even for bulk transfers * to simplify allocation and casts. */ typedef struct AsyncURB { struct usbdevfs_urb urb; struct usbdevfs_iso_packet_desc isocpd; USBPacket *packet; USBHostDevice *hdev; } AsyncURB; static AsyncURB *async_alloc(void) { return (AsyncURB *) qemu_mallocz(sizeof(AsyncURB)); } static void async_free(AsyncURB *aurb) { qemu_free(aurb); } static void async_complete_ctrl(USBHostDevice *s, USBPacket *p) { switch(s->ctrl.state) { case CTRL_STATE_SETUP: if (p->len < s->ctrl.len) s->ctrl.len = p->len; s->ctrl.state = CTRL_STATE_DATA; p->len = 8; break; case CTRL_STATE_ACK: s->ctrl.state = CTRL_STATE_IDLE; p->len = 0; break; default: break; } } static void async_complete(void *opaque) { USBHostDevice *s = opaque; AsyncURB *aurb; while (1) { USBPacket *p; int r = ioctl(s->fd, USBDEVFS_REAPURBNDELAY, &aurb); if (r < 0) { if (errno == EAGAIN) return; if (errno == ENODEV && !s->closing) { printf("husb: device %d.%d disconnected\n", s->bus_num, s->addr); usb_device_del_addr(0, s->dev.addr); return; } dprintf("husb: async. reap urb failed errno %d\n", errno); return; } p = aurb->packet; dprintf("husb: async completed. aurb %p status %d alen %d\n", aurb, aurb->urb.status, aurb->urb.actual_length); if (p) { switch (aurb->urb.status) { case 0: p->len = aurb->urb.actual_length; if (aurb->urb.type == USBDEVFS_URB_TYPE_CONTROL) async_complete_ctrl(s, p); break; case -EPIPE: set_halt(s, p->devep); /* fall through */ default: p->len = USB_RET_NAK; break; } usb_packet_complete(p); } async_free(aurb); } } static void async_cancel(USBPacket *unused, void *opaque) { AsyncURB *aurb = opaque; USBHostDevice *s = aurb->hdev; dprintf("husb: async cancel. aurb %p\n", aurb); /* Mark it as dead (see async_complete above) */ aurb->packet = NULL; int r = ioctl(s->fd, USBDEVFS_DISCARDURB, aurb); if (r < 0) { dprintf("husb: async. discard urb failed errno %d\n", errno); } } static int usb_host_claim_interfaces(USBHostDevice *dev, int configuration) { int dev_descr_len, config_descr_len; int interface, nb_interfaces, nb_configurations; int ret, i; if (configuration == 0) /* address state - ignore */ return 1; dprintf("husb: claiming interfaces. config %d\n", configuration); i = 0; dev_descr_len = dev->descr[0]; if (dev_descr_len > dev->descr_len) goto fail; nb_configurations = dev->descr[17]; i += dev_descr_len; while (i < dev->descr_len) { dprintf("husb: i is %d, descr_len is %d, dl %d, dt %d\n", i, dev->descr_len, dev->descr[i], dev->descr[i+1]); if (dev->descr[i+1] != USB_DT_CONFIG) { i += dev->descr[i]; continue; } config_descr_len = dev->descr[i]; printf("husb: config #%d need %d\n", dev->descr[i + 5], configuration); if (configuration < 0 || configuration == dev->descr[i + 5]) { configuration = dev->descr[i + 5]; break; } i += config_descr_len; } if (i >= dev->descr_len) { fprintf(stderr, "husb: update iface failed. no matching configuration\n"); goto fail; } nb_interfaces = dev->descr[i + 4]; #ifdef USBDEVFS_DISCONNECT /* earlier Linux 2.4 do not support that */ { struct usbdevfs_ioctl ctrl; for (interface = 0; interface < nb_interfaces; interface++) { ctrl.ioctl_code = USBDEVFS_DISCONNECT; ctrl.ifno = interface; ret = ioctl(dev->fd, USBDEVFS_IOCTL, &ctrl); if (ret < 0 && errno != ENODATA) { perror("USBDEVFS_DISCONNECT"); goto fail; } } } #endif /* XXX: only grab if all interfaces are free */ for (interface = 0; interface < nb_interfaces; interface++) { ret = ioctl(dev->fd, USBDEVFS_CLAIMINTERFACE, &interface); if (ret < 0) { if (errno == EBUSY) { printf("husb: update iface. device already grabbed\n"); } else { perror("husb: failed to claim interface"); } fail: return 0; } } printf("husb: %d interfaces claimed for configuration %d\n", nb_interfaces, configuration); dev->ninterfaces = nb_interfaces; dev->configuration = configuration; return 1; } static int usb_host_release_interfaces(USBHostDevice *s) { int ret, i; dprintf("husb: releasing interfaces\n"); for (i = 0; i < s->ninterfaces; i++) { ret = ioctl(s->fd, USBDEVFS_RELEASEINTERFACE, &i); if (ret < 0) { perror("husb: failed to release interface"); return 0; } } return 1; } static void usb_host_handle_reset(USBDevice *dev) { USBHostDevice *s = (USBHostDevice *) dev; dprintf("husb: reset device %u.%u\n", s->bus_num, s->addr); ioctl(s->fd, USBDEVFS_RESET); usb_host_claim_interfaces(s, s->configuration); } static void usb_host_handle_destroy(USBDevice *dev) { USBHostDevice *s = (USBHostDevice *)dev; s->closing = 1; qemu_set_fd_handler(s->fd, NULL, NULL, NULL); hostdev_unlink(s); async_complete(s); if (s->fd >= 0) close(s->fd); qemu_free(s); } static int usb_linux_update_endp_table(USBHostDevice *s); static int usb_host_handle_data(USBHostDevice *s, USBPacket *p) { struct usbdevfs_urb *urb; AsyncURB *aurb; int ret; aurb = async_alloc(); if (!aurb) { dprintf("husb: async malloc failed\n"); return USB_RET_NAK; } aurb->hdev = s; aurb->packet = p; urb = &aurb->urb; if (p->pid == USB_TOKEN_IN) urb->endpoint = p->devep | 0x80; else urb->endpoint = p->devep; if (is_halted(s, p->devep)) { ret = ioctl(s->fd, USBDEVFS_CLEAR_HALT, &urb->endpoint); if (ret < 0) { dprintf("husb: failed to clear halt. ep 0x%x errno %d\n", urb->endpoint, errno); return USB_RET_NAK; } clear_halt(s, p->devep); } urb->buffer = p->data; urb->buffer_length = p->len; if (is_isoc(s, p->devep)) { /* Setup ISOC transfer */ urb->type = USBDEVFS_URB_TYPE_ISO; urb->flags = USBDEVFS_URB_ISO_ASAP; urb->number_of_packets = 1; urb->iso_frame_desc[0].length = p->len; } else { /* Setup bulk transfer */ urb->type = USBDEVFS_URB_TYPE_BULK; } urb->usercontext = s; ret = ioctl(s->fd, USBDEVFS_SUBMITURB, urb); dprintf("husb: data submit. ep 0x%x len %u aurb %p\n", urb->endpoint, p->len, aurb); if (ret < 0) { dprintf("husb: submit failed. errno %d\n", errno); async_free(aurb); switch(errno) { case ETIMEDOUT: return USB_RET_NAK; case EPIPE: default: return USB_RET_STALL; } } usb_defer_packet(p, async_cancel, aurb); return USB_RET_ASYNC; } static int ctrl_error(void) { if (errno == ETIMEDOUT) return USB_RET_NAK; else return USB_RET_STALL; } static int usb_host_set_address(USBHostDevice *s, int addr) { dprintf("husb: ctrl set addr %u\n", addr); s->dev.addr = addr; return 0; } static int usb_host_set_config(USBHostDevice *s, int config) { usb_host_release_interfaces(s); int ret = ioctl(s->fd, USBDEVFS_SETCONFIGURATION, &config); dprintf("husb: ctrl set config %d ret %d errno %d\n", config, ret, errno); if (ret < 0) return ctrl_error(); usb_host_claim_interfaces(s, config); return 0; } static int usb_host_set_interface(USBHostDevice *s, int iface, int alt) { struct usbdevfs_setinterface si; int ret; si.interface = iface; si.altsetting = alt; ret = ioctl(s->fd, USBDEVFS_SETINTERFACE, &si); dprintf("husb: ctrl set iface %d altset %d ret %d errno %d\n", iface, alt, ret, errno); if (ret < 0) return ctrl_error(); usb_linux_update_endp_table(s); return 0; } static int usb_host_handle_control(USBHostDevice *s, USBPacket *p) { struct usbdevfs_urb *urb; AsyncURB *aurb; int ret, value, index; /* * Process certain standard device requests. * These are infrequent and are processed synchronously. */ value = le16_to_cpu(s->ctrl.req.wValue); index = le16_to_cpu(s->ctrl.req.wIndex); dprintf("husb: ctrl type 0x%x req 0x%x val 0x%x index %u len %u\n", s->ctrl.req.bRequestType, s->ctrl.req.bRequest, value, index, s->ctrl.len); if (s->ctrl.req.bRequestType == 0) { switch (s->ctrl.req.bRequest) { case USB_REQ_SET_ADDRESS: return usb_host_set_address(s, value); case USB_REQ_SET_CONFIGURATION: return usb_host_set_config(s, value & 0xff); } } if (s->ctrl.req.bRequestType == 1 && s->ctrl.req.bRequest == USB_REQ_SET_INTERFACE) return usb_host_set_interface(s, index, value); /* The rest are asynchronous */ aurb = async_alloc(); if (!aurb) { dprintf("husb: async malloc failed\n"); return USB_RET_NAK; } aurb->hdev = s; aurb->packet = p; /* * Setup ctrl transfer. * * s->ctrl is layed out such that data buffer immediately follows * 'req' struct which is exactly what usbdevfs expects. */ urb = &aurb->urb; urb->type = USBDEVFS_URB_TYPE_CONTROL; urb->endpoint = p->devep; urb->buffer = &s->ctrl.req; urb->buffer_length = 8 + s->ctrl.len; urb->usercontext = s; ret = ioctl(s->fd, USBDEVFS_SUBMITURB, urb); dprintf("husb: submit ctrl. len %u aurb %p\n", urb->buffer_length, aurb); if (ret < 0) { dprintf("husb: submit failed. errno %d\n", errno); async_free(aurb); switch(errno) { case ETIMEDOUT: return USB_RET_NAK; case EPIPE: default: return USB_RET_STALL; } } usb_defer_packet(p, async_cancel, aurb); return USB_RET_ASYNC; } static int do_token_setup(USBDevice *dev, USBPacket *p) { USBHostDevice *s = (USBHostDevice *) dev; int ret = 0; if (p->len != 8) return USB_RET_STALL; memcpy(&s->ctrl.req, p->data, 8); s->ctrl.len = le16_to_cpu(s->ctrl.req.wLength); s->ctrl.offset = 0; s->ctrl.state = CTRL_STATE_SETUP; if (s->ctrl.req.bRequestType & USB_DIR_IN) { ret = usb_host_handle_control(s, p); if (ret < 0) return ret; if (ret < s->ctrl.len) s->ctrl.len = ret; s->ctrl.state = CTRL_STATE_DATA; } else { if (s->ctrl.len == 0) s->ctrl.state = CTRL_STATE_ACK; else s->ctrl.state = CTRL_STATE_DATA; } return ret; } static int do_token_in(USBDevice *dev, USBPacket *p) { USBHostDevice *s = (USBHostDevice *) dev; int ret = 0; if (p->devep != 0) return usb_host_handle_data(s, p); switch(s->ctrl.state) { case CTRL_STATE_ACK: if (!(s->ctrl.req.bRequestType & USB_DIR_IN)) { ret = usb_host_handle_control(s, p); if (ret == USB_RET_ASYNC) return USB_RET_ASYNC; s->ctrl.state = CTRL_STATE_IDLE; return ret > 0 ? 0 : ret; } return 0; case CTRL_STATE_DATA: if (s->ctrl.req.bRequestType & USB_DIR_IN) { int len = s->ctrl.len - s->ctrl.offset; if (len > p->len) len = p->len; memcpy(p->data, s->ctrl.buffer + s->ctrl.offset, len); s->ctrl.offset += len; if (s->ctrl.offset >= s->ctrl.len) s->ctrl.state = CTRL_STATE_ACK; return len; } s->ctrl.state = CTRL_STATE_IDLE; return USB_RET_STALL; default: return USB_RET_STALL; } } static int do_token_out(USBDevice *dev, USBPacket *p) { USBHostDevice *s = (USBHostDevice *) dev; if (p->devep != 0) return usb_host_handle_data(s, p); switch(s->ctrl.state) { case CTRL_STATE_ACK: if (s->ctrl.req.bRequestType & USB_DIR_IN) { s->ctrl.state = CTRL_STATE_IDLE; /* transfer OK */ } else { /* ignore additional output */ } return 0; case CTRL_STATE_DATA: if (!(s->ctrl.req.bRequestType & USB_DIR_IN)) { int len = s->ctrl.len - s->ctrl.offset; if (len > p->len) len = p->len; memcpy(s->ctrl.buffer + s->ctrl.offset, p->data, len); s->ctrl.offset += len; if (s->ctrl.offset >= s->ctrl.len) s->ctrl.state = CTRL_STATE_ACK; return len; } s->ctrl.state = CTRL_STATE_IDLE; return USB_RET_STALL; default: return USB_RET_STALL; } } /* * Packet handler. * Called by the HC (host controller). * * Returns length of the transaction or one of the USB_RET_XXX codes. */ int usb_host_handle_packet(USBDevice *s, USBPacket *p) { switch(p->pid) { case USB_MSG_ATTACH: s->state = USB_STATE_ATTACHED; return 0; case USB_MSG_DETACH: s->state = USB_STATE_NOTATTACHED; return 0; case USB_MSG_RESET: s->remote_wakeup = 0; s->addr = 0; s->state = USB_STATE_DEFAULT; s->handle_reset(s); return 0; } /* Rest of the PIDs must match our address */ if (s->state < USB_STATE_DEFAULT || p->devaddr != s->addr) return USB_RET_NODEV; switch (p->pid) { case USB_TOKEN_SETUP: return do_token_setup(s, p); case USB_TOKEN_IN: return do_token_in(s, p); case USB_TOKEN_OUT: return do_token_out(s, p); default: return USB_RET_STALL; } } /* returns 1 on problem encountered or 0 for success */ static int usb_linux_update_endp_table(USBHostDevice *s) { uint8_t *descriptors; uint8_t devep, type, configuration, alt_interface; struct usbdevfs_ctrltransfer ct; int interface, ret, length, i; ct.bRequestType = USB_DIR_IN; ct.bRequest = USB_REQ_GET_CONFIGURATION; ct.wValue = 0; ct.wIndex = 0; ct.wLength = 1; ct.data = &configuration; ct.timeout = 50; ret = ioctl(s->fd, USBDEVFS_CONTROL, &ct); if (ret < 0) { perror("usb_linux_update_endp_table"); return 1; } /* in address state */ if (configuration == 0) return 1; /* get the desired configuration, interface, and endpoint descriptors * from device description */ descriptors = &s->descr[18]; length = s->descr_len - 18; i = 0; if (descriptors[i + 1] != USB_DT_CONFIG || descriptors[i + 5] != configuration) { dprintf("invalid descriptor data - configuration\n"); return 1; } i += descriptors[i]; while (i < length) { if (descriptors[i + 1] != USB_DT_INTERFACE || (descriptors[i + 1] == USB_DT_INTERFACE && descriptors[i + 4] == 0)) { i += descriptors[i]; continue; } interface = descriptors[i + 2]; ct.bRequestType = USB_DIR_IN | USB_RECIP_INTERFACE; ct.bRequest = USB_REQ_GET_INTERFACE; ct.wValue = 0; ct.wIndex = interface; ct.wLength = 1; ct.data = &alt_interface; ct.timeout = 50; ret = ioctl(s->fd, USBDEVFS_CONTROL, &ct); if (ret < 0) { perror("usb_linux_update_endp_table"); return 1; } /* the current interface descriptor is the active interface * and has endpoints */ if (descriptors[i + 3] != alt_interface) { i += descriptors[i]; continue; } /* advance to the endpoints */ while (i < length && descriptors[i +1] != USB_DT_ENDPOINT) i += descriptors[i]; if (i >= length) break; while (i < length) { if (descriptors[i + 1] != USB_DT_ENDPOINT) break; devep = descriptors[i + 2]; switch (descriptors[i + 3] & 0x3) { case 0x00: type = USBDEVFS_URB_TYPE_CONTROL; break; case 0x01: type = USBDEVFS_URB_TYPE_ISO; break; case 0x02: type = USBDEVFS_URB_TYPE_BULK; break; case 0x03: type = USBDEVFS_URB_TYPE_INTERRUPT; break; default: dprintf("usb_host: malformed endpoint type\n"); type = USBDEVFS_URB_TYPE_BULK; } s->endp_table[(devep & 0xf) - 1].type = type; s->endp_table[(devep & 0xf) - 1].halted = 0; i += descriptors[i]; } } return 0; } static USBDevice *usb_host_device_open_addr(int bus_num, int addr, const char *prod_name) { int fd = -1, ret; USBHostDevice *dev = NULL; struct usbdevfs_connectinfo ci; char buf[1024]; dev = qemu_mallocz(sizeof(USBHostDevice)); if (!dev) goto fail; dev->bus_num = bus_num; dev->addr = addr; printf("husb: open device %d.%d\n", bus_num, addr); snprintf(buf, sizeof(buf), USBDEVFS_PATH "/%03d/%03d", bus_num, addr); fd = open(buf, O_RDWR | O_NONBLOCK); if (fd < 0) { perror(buf); goto fail; } /* read the device description */ dev->descr_len = read(fd, dev->descr, sizeof(dev->descr)); if (dev->descr_len <= 0) { perror("husb: reading device data failed"); goto fail; } #ifdef DEBUG { int x; printf("=== begin dumping device descriptor data ===\n"); for (x = 0; x < dev->descr_len; x++) printf("%02x ", dev->descr[x]); printf("\n=== end dumping device descriptor data ===\n"); } #endif dev->fd = fd; /* * Initial configuration is -1 which makes us claim first * available config. We used to start with 1, which does not * always work. I've seen devices where first config starts * with 2. */ if (!usb_host_claim_interfaces(dev, -1)) goto fail; ret = ioctl(fd, USBDEVFS_CONNECTINFO, &ci); if (ret < 0) { perror("usb_host_device_open: USBDEVFS_CONNECTINFO"); goto fail; } printf("husb: grabbed usb device %d.%d\n", bus_num, addr); ret = usb_linux_update_endp_table(dev); if (ret) goto fail; if (ci.slow) dev->dev.speed = USB_SPEED_LOW; else dev->dev.speed = USB_SPEED_HIGH; dev->dev.handle_packet = usb_host_handle_packet; dev->dev.handle_reset = usb_host_handle_reset; dev->dev.handle_destroy = usb_host_handle_destroy; if (!prod_name || prod_name[0] == '\0') snprintf(dev->dev.devname, sizeof(dev->dev.devname), "host:%d.%d", bus_num, addr); else pstrcpy(dev->dev.devname, sizeof(dev->dev.devname), prod_name); /* USB devio uses 'write' flag to check for async completions */ qemu_set_fd_handler(dev->fd, NULL, async_complete, dev); hostdev_link(dev); return (USBDevice *) dev; fail: if (dev) qemu_free(dev); close(fd); return NULL; } static int usb_host_auto_add(const char *spec); static int usb_host_auto_del(const char *spec); USBDevice *usb_host_device_open(const char *devname) { int bus_num, addr; char product_name[PRODUCT_NAME_SZ]; if (strstr(devname, "auto:")) { usb_host_auto_add(devname); return NULL; } if (usb_host_find_device(&bus_num, &addr, product_name, sizeof(product_name), devname) < 0) return NULL; if (hostdev_find(bus_num, addr)) { term_printf("husb: host usb device %d.%d is already open\n", bus_num, addr); return NULL; } return usb_host_device_open_addr(bus_num, addr, product_name); } int usb_host_device_close(const char *devname) { char product_name[PRODUCT_NAME_SZ]; int bus_num, addr; USBHostDevice *s; if (strstr(devname, "auto:")) return usb_host_auto_del(devname); if (usb_host_find_device(&bus_num, &addr, product_name, sizeof(product_name), devname) < 0) return -1; s = hostdev_find(bus_num, addr); if (s) { usb_device_del_addr(0, s->dev.addr); return 0; } return -1; } static int get_tag_value(char *buf, int buf_size, const char *str, const char *tag, const char *stopchars) { const char *p; char *q; p = strstr(str, tag); if (!p) return -1; p += strlen(tag); while (isspace(*p)) p++; q = buf; while (*p != '\0' && !strchr(stopchars, *p)) { if ((q - buf) < (buf_size - 1)) *q++ = *p; p++; } *q = '\0'; return q - buf; } static int usb_host_scan(void *opaque, USBScanFunc *func) { FILE *f; char line[1024]; char buf[1024]; int bus_num, addr, speed, device_count, class_id, product_id, vendor_id; int ret; char product_name[512]; f = fopen(USBDEVFS_PATH "/devices", "r"); if (!f) { term_printf("husb: could not open %s\n", USBDEVFS_PATH "/devices"); return 0; } device_count = 0; bus_num = addr = speed = class_id = product_id = vendor_id = 0; ret = 0; for(;;) { if (fgets(line, sizeof(line), f) == NULL) break; if (strlen(line) > 0) line[strlen(line) - 1] = '\0'; if (line[0] == 'T' && line[1] == ':') { if (device_count && (vendor_id || product_id)) { /* New device. Add the previously discovered device. */ ret = func(opaque, bus_num, addr, class_id, vendor_id, product_id, product_name, speed); if (ret) goto the_end; } if (get_tag_value(buf, sizeof(buf), line, "Bus=", " ") < 0) goto fail; bus_num = atoi(buf); if (get_tag_value(buf, sizeof(buf), line, "Dev#=", " ") < 0) goto fail; addr = atoi(buf); if (get_tag_value(buf, sizeof(buf), line, "Spd=", " ") < 0) goto fail; if (!strcmp(buf, "480")) speed = USB_SPEED_HIGH; else if (!strcmp(buf, "1.5")) speed = USB_SPEED_LOW; else speed = USB_SPEED_FULL; product_name[0] = '\0'; class_id = 0xff; device_count++; product_id = 0; vendor_id = 0; } else if (line[0] == 'P' && line[1] == ':') { if (get_tag_value(buf, sizeof(buf), line, "Vendor=", " ") < 0) goto fail; vendor_id = strtoul(buf, NULL, 16); if (get_tag_value(buf, sizeof(buf), line, "ProdID=", " ") < 0) goto fail; product_id = strtoul(buf, NULL, 16); } else if (line[0] == 'S' && line[1] == ':') { if (get_tag_value(buf, sizeof(buf), line, "Product=", "") < 0) goto fail; pstrcpy(product_name, sizeof(product_name), buf); } else if (line[0] == 'D' && line[1] == ':') { if (get_tag_value(buf, sizeof(buf), line, "Cls=", " (") < 0) goto fail; class_id = strtoul(buf, NULL, 16); } fail: ; } if (device_count && (vendor_id || product_id)) { /* Add the last device. */ ret = func(opaque, bus_num, addr, class_id, vendor_id, product_id, product_name, speed); } the_end: fclose(f); return ret; } struct USBAutoFilter { struct USBAutoFilter *next; int bus_num; int addr; int vendor_id; int product_id; }; static QEMUTimer *usb_auto_timer; static struct USBAutoFilter *usb_auto_filter; static int usb_host_auto_scan(void *opaque, int bus_num, int addr, int class_id, int vendor_id, int product_id, const char *product_name, int speed) { struct USBAutoFilter *f; struct USBDevice *dev; /* Ignore hubs */ if (class_id == 9) return 0; for (f = usb_auto_filter; f; f = f->next) { if (f->bus_num >= 0 && f->bus_num != bus_num) continue; if (f->addr >= 0 && f->addr != addr) continue; if (f->vendor_id >= 0 && f->vendor_id != vendor_id) continue; if (f->product_id >= 0 && f->product_id != product_id) continue; /* We got a match */ /* Allredy attached ? */ if (hostdev_find(bus_num, addr)) return 0; dprintf("husb: auto open: bus_num %d addr %d\n", bus_num, addr); dev = usb_host_device_open_addr(bus_num, addr, product_name); if (dev) usb_device_add_dev(dev); } return 0; } static void usb_host_auto_timer(void *unused) { usb_host_scan(NULL, usb_host_auto_scan); qemu_mod_timer(usb_auto_timer, qemu_get_clock(rt_clock) + 2000); } /* * Autoconnect filter * Format: * auto:bus:dev[:vid:pid] * auto:bus.dev[:vid:pid] * * bus - bus number (dec, * means any) * dev - device number (dec, * means any) * vid - vendor id (hex, * means any) * pid - product id (hex, * means any) * * See 'lsusb' output. */ static int parse_filter(const char *spec, struct USBAutoFilter *f) { enum { BUS, DEV, VID, PID, DONE }; const char *p = spec; int i; f->bus_num = -1; f->addr = -1; f->vendor_id = -1; f->product_id = -1; for (i = BUS; i < DONE; i++) { p = strpbrk(p, ":."); if (!p) break; p++; if (*p == '*') continue; switch(i) { case BUS: f->bus_num = strtol(p, NULL, 10); break; case DEV: f->addr = strtol(p, NULL, 10); break; case VID: f->vendor_id = strtol(p, NULL, 16); break; case PID: f->product_id = strtol(p, NULL, 16); break; } } if (i < DEV) { fprintf(stderr, "husb: invalid auto filter spec %s\n", spec); return -1; } return 0; } static int match_filter(const struct USBAutoFilter *f1, const struct USBAutoFilter *f2) { return f1->bus_num == f2->bus_num && f1->addr == f2->addr && f1->vendor_id == f2->vendor_id && f1->product_id == f2->product_id; } static int usb_host_auto_add(const char *spec) { struct USBAutoFilter filter, *f; if (parse_filter(spec, &filter) < 0) return -1; f = qemu_mallocz(sizeof(*f)); if (!f) { fprintf(stderr, "husb: failed to allocate auto filter\n"); return -1; } *f = filter; if (!usb_auto_filter) { /* * First entry. Init and start the monitor. * Right now we're using timer to check for new devices. * If this turns out to be too expensive we can move that into a * separate thread. */ usb_auto_timer = qemu_new_timer(rt_clock, usb_host_auto_timer, NULL); if (!usb_auto_timer) { fprintf(stderr, "husb: failed to allocate auto scan timer\n"); qemu_free(f); return -1; } /* Check for new devices every two seconds */ qemu_mod_timer(usb_auto_timer, qemu_get_clock(rt_clock) + 2000); } dprintf("husb: added auto filter: bus_num %d addr %d vid %d pid %d\n", f->bus_num, f->addr, f->vendor_id, f->product_id); f->next = usb_auto_filter; usb_auto_filter = f; return 0; } static int usb_host_auto_del(const char *spec) { struct USBAutoFilter *pf = usb_auto_filter; struct USBAutoFilter **prev = &usb_auto_filter; struct USBAutoFilter filter; if (parse_filter(spec, &filter) < 0) return -1; while (pf) { if (match_filter(pf, &filter)) { dprintf("husb: removed auto filter: bus_num %d addr %d vid %d pid %d\n", pf->bus_num, pf->addr, pf->vendor_id, pf->product_id); *prev = pf->next; if (!usb_auto_filter) { /* No more filters. Stop scanning. */ qemu_del_timer(usb_auto_timer); qemu_free_timer(usb_auto_timer); } return 0; } prev = &pf->next; pf = pf->next; } return -1; } typedef struct FindDeviceState { int vendor_id; int product_id; int bus_num; int addr; char product_name[PRODUCT_NAME_SZ]; } FindDeviceState; static int usb_host_find_device_scan(void *opaque, int bus_num, int addr, int class_id, int vendor_id, int product_id, const char *product_name, int speed) { FindDeviceState *s = opaque; if ((vendor_id == s->vendor_id && product_id == s->product_id) || (bus_num == s->bus_num && addr == s->addr)) { pstrcpy(s->product_name, PRODUCT_NAME_SZ, product_name); s->bus_num = bus_num; s->addr = addr; return 1; } else { return 0; } } /* the syntax is : 'bus.addr' (decimal numbers) or 'vendor_id:product_id' (hexa numbers) */ static int usb_host_find_device(int *pbus_num, int *paddr, char *product_name, int product_name_size, const char *devname) { const char *p; int ret; FindDeviceState fs; p = strchr(devname, '.'); if (p) { *pbus_num = strtoul(devname, NULL, 0); *paddr = strtoul(p + 1, NULL, 0); fs.bus_num = *pbus_num; fs.addr = *paddr; ret = usb_host_scan(&fs, usb_host_find_device_scan); if (ret) pstrcpy(product_name, product_name_size, fs.product_name); return 0; } p = strchr(devname, ':'); if (p) { fs.vendor_id = strtoul(devname, NULL, 16); fs.product_id = strtoul(p + 1, NULL, 16); ret = usb_host_scan(&fs, usb_host_find_device_scan); if (ret) { *pbus_num = fs.bus_num; *paddr = fs.addr; pstrcpy(product_name, product_name_size, fs.product_name); return 0; } } return -1; } /**********************/ /* USB host device info */ struct usb_class_info { int class; const char *class_name; }; static const struct usb_class_info usb_class_info[] = { { USB_CLASS_AUDIO, "Audio"}, { USB_CLASS_COMM, "Communication"}, { USB_CLASS_HID, "HID"}, { USB_CLASS_HUB, "Hub" }, { USB_CLASS_PHYSICAL, "Physical" }, { USB_CLASS_PRINTER, "Printer" }, { USB_CLASS_MASS_STORAGE, "Storage" }, { USB_CLASS_CDC_DATA, "Data" }, { USB_CLASS_APP_SPEC, "Application Specific" }, { USB_CLASS_VENDOR_SPEC, "Vendor Specific" }, { USB_CLASS_STILL_IMAGE, "Still Image" }, { USB_CLASS_CSCID, "Smart Card" }, { USB_CLASS_CONTENT_SEC, "Content Security" }, { -1, NULL } }; static const char *usb_class_str(uint8_t class) { const struct usb_class_info *p; for(p = usb_class_info; p->class != -1; p++) { if (p->class == class) break; } return p->class_name; } static void usb_info_device(int bus_num, int addr, int class_id, int vendor_id, int product_id, const char *product_name, int speed) { const char *class_str, *speed_str; switch(speed) { case USB_SPEED_LOW: speed_str = "1.5"; break; case USB_SPEED_FULL: speed_str = "12"; break; case USB_SPEED_HIGH: speed_str = "480"; break; default: speed_str = "?"; break; } term_printf(" Device %d.%d, speed %s Mb/s\n", bus_num, addr, speed_str); class_str = usb_class_str(class_id); if (class_str) term_printf(" %s:", class_str); else term_printf(" Class %02x:", class_id); term_printf(" USB device %04x:%04x", vendor_id, product_id); if (product_name[0] != '\0') term_printf(", %s", product_name); term_printf("\n"); } static int usb_host_info_device(void *opaque, int bus_num, int addr, int class_id, int vendor_id, int product_id, const char *product_name, int speed) { usb_info_device(bus_num, addr, class_id, vendor_id, product_id, product_name, speed); return 0; } static void dec2str(int val, char *str) { if (val == -1) strcpy(str, "*"); else sprintf(str, "%d", val); } static void hex2str(int val, char *str) { if (val == -1) strcpy(str, "*"); else sprintf(str, "%x", val); } void usb_host_info(void) { struct USBAutoFilter *f; usb_host_scan(NULL, usb_host_info_device); if (usb_auto_filter) term_printf(" Auto filters:\n"); for (f = usb_auto_filter; f; f = f->next) { char bus[10], addr[10], vid[10], pid[10]; dec2str(f->bus_num, bus); dec2str(f->addr, addr); hex2str(f->vendor_id, vid); hex2str(f->product_id, pid); term_printf(" Device %s.%s ID %s:%s\n", bus, addr, vid, pid); } } #else #include "hw/usb.h" void usb_host_info(void) { term_printf("USB host devices not supported\n"); } /* XXX: modify configure to compile the right host driver */ USBDevice *usb_host_device_open(const char *devname) { return NULL; } int usb_host_device_close(const char *devname) { return 0; } #endif