Current Path : /compat/linux/proc/self/root/usr/src/lib/libusb/ |
FreeBSD hs32.drive.ne.jp 9.1-RELEASE FreeBSD 9.1-RELEASE #1: Wed Jan 14 12:18:08 JST 2015 root@hs32.drive.ne.jp:/sys/amd64/compile/hs32 amd64 |
Current File : //compat/linux/proc/self/root/usr/src/lib/libusb/libusb20_desc.c |
/* $FreeBSD: release/9.1.0/lib/libusb/libusb20_desc.c 235004 2012-05-04 15:27:18Z hselasky $ */ /*- * Copyright (c) 2008 Hans Petter Selasky. All rights reserved. * * Redistribution and use in source and binary forms, with or without * modification, are permitted provided that the following conditions * are met: * 1. Redistributions of source code must retain the above copyright * notice, this list of conditions and the following disclaimer. * 2. Redistributions in binary form must reproduce the above copyright * notice, this list of conditions and the following disclaimer in the * documentation and/or other materials provided with the distribution. * * THIS SOFTWARE IS PROVIDED BY THE AUTHOR AND CONTRIBUTORS ``AS IS'' AND * ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE * IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR PURPOSE * ARE DISCLAIMED. IN NO EVENT SHALL THE AUTHOR OR CONTRIBUTORS BE LIABLE * FOR ANY DIRECT, INDIRECT, INCIDENTAL, SPECIAL, EXEMPLARY, OR CONSEQUENTIAL * DAMAGES (INCLUDING, BUT NOT LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS * OR SERVICES; LOSS OF USE, DATA, OR PROFITS; OR BUSINESS INTERRUPTION) * HOWEVER CAUSED AND ON ANY THEORY OF LIABILITY, WHETHER IN CONTRACT, STRICT * LIABILITY, OR TORT (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY * OUT OF THE USE OF THIS SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF * SUCH DAMAGE. */ #include <sys/queue.h> #include <stdio.h> #include <stdlib.h> #include <string.h> #include "libusb20.h" #include "libusb20_desc.h" #include "libusb20_int.h" static const uint32_t libusb20_me_encode_empty[2]; /* dummy */ LIBUSB20_MAKE_STRUCT_FORMAT(LIBUSB20_DEVICE_DESC); LIBUSB20_MAKE_STRUCT_FORMAT(LIBUSB20_ENDPOINT_DESC); LIBUSB20_MAKE_STRUCT_FORMAT(LIBUSB20_INTERFACE_DESC); LIBUSB20_MAKE_STRUCT_FORMAT(LIBUSB20_CONFIG_DESC); LIBUSB20_MAKE_STRUCT_FORMAT(LIBUSB20_CONTROL_SETUP); LIBUSB20_MAKE_STRUCT_FORMAT(LIBUSB20_SS_ENDPT_COMP_DESC); LIBUSB20_MAKE_STRUCT_FORMAT(LIBUSB20_USB_20_DEVCAP_DESC); LIBUSB20_MAKE_STRUCT_FORMAT(LIBUSB20_SS_USB_DEVCAP_DESC); LIBUSB20_MAKE_STRUCT_FORMAT(LIBUSB20_BOS_DESCRIPTOR); /*------------------------------------------------------------------------* * libusb20_parse_config_desc * * Return values: * NULL: Out of memory. * Else: A valid config structure pointer which must be passed to "free()" *------------------------------------------------------------------------*/ struct libusb20_config * libusb20_parse_config_desc(const void *config_desc) { struct libusb20_config *lub_config; struct libusb20_interface *lub_interface; struct libusb20_interface *lub_alt_interface; struct libusb20_interface *last_if; struct libusb20_endpoint *lub_endpoint; struct libusb20_endpoint *last_ep; struct libusb20_me_struct pcdesc; const uint8_t *ptr; uint32_t size; uint16_t niface_no_alt; uint16_t niface; uint16_t nendpoint; uint16_t iface_no; ptr = config_desc; if (ptr[1] != LIBUSB20_DT_CONFIG) { return (NULL); /* not config descriptor */ } /* * The first "bInterfaceNumber" should never have the value 0xff. * Then it is corrupt. */ niface_no_alt = 0; nendpoint = 0; niface = 0; iface_no = 0xFFFF; ptr = NULL; /* get "wTotalLength" and setup "pcdesc" */ pcdesc.ptr = LIBUSB20_ADD_BYTES(config_desc, 0); pcdesc.len = ((const uint8_t *)config_desc)[2] | (((const uint8_t *)config_desc)[3] << 8); pcdesc.type = LIBUSB20_ME_IS_RAW; /* descriptor pre-scan */ while ((ptr = libusb20_desc_foreach(&pcdesc, ptr))) { if (ptr[1] == LIBUSB20_DT_ENDPOINT) { nendpoint++; } else if ((ptr[1] == LIBUSB20_DT_INTERFACE) && (ptr[0] >= 4)) { niface++; /* check "bInterfaceNumber" */ if (ptr[2] != iface_no) { iface_no = ptr[2]; niface_no_alt++; } } } /* sanity checking */ if (niface >= 256) { return (NULL); /* corrupt */ } if (nendpoint >= 256) { return (NULL); /* corrupt */ } size = sizeof(*lub_config) + (niface * sizeof(*lub_interface)) + (nendpoint * sizeof(*lub_endpoint)) + pcdesc.len; lub_config = malloc(size); if (lub_config == NULL) { return (NULL); /* out of memory */ } /* make sure memory is initialised */ memset(lub_config, 0, size); lub_interface = (void *)(lub_config + 1); lub_alt_interface = (void *)(lub_interface + niface_no_alt); lub_endpoint = (void *)(lub_interface + niface); /* * Make a copy of the config descriptor, so that the caller can free * the inital config descriptor pointer! */ ptr = (void *)(lub_endpoint + nendpoint); memcpy(LIBUSB20_ADD_BYTES(ptr, 0), config_desc, pcdesc.len); pcdesc.ptr = LIBUSB20_ADD_BYTES(ptr, 0); config_desc = LIBUSB20_ADD_BYTES(ptr, 0); /* init config structure */ ptr = config_desc; LIBUSB20_INIT(LIBUSB20_CONFIG_DESC, &lub_config->desc); if (libusb20_me_decode(ptr, ptr[0], &lub_config->desc)) { /* ignore */ } lub_config->num_interface = 0; lub_config->interface = lub_interface; lub_config->extra.ptr = LIBUSB20_ADD_BYTES(ptr, ptr[0]); lub_config->extra.len = -ptr[0]; lub_config->extra.type = LIBUSB20_ME_IS_RAW; /* reset states */ niface = 0; iface_no = 0xFFFF; ptr = NULL; lub_interface--; lub_endpoint--; last_if = NULL; last_ep = NULL; /* descriptor pre-scan */ while ((ptr = libusb20_desc_foreach(&pcdesc, ptr))) { if (ptr[1] == LIBUSB20_DT_ENDPOINT) { if (last_if) { lub_endpoint++; last_ep = lub_endpoint; last_if->num_endpoints++; LIBUSB20_INIT(LIBUSB20_ENDPOINT_DESC, &last_ep->desc); if (libusb20_me_decode(ptr, ptr[0], &last_ep->desc)) { /* ignore */ } last_ep->extra.ptr = LIBUSB20_ADD_BYTES(ptr, ptr[0]); last_ep->extra.len = 0; last_ep->extra.type = LIBUSB20_ME_IS_RAW; } else { lub_config->extra.len += ptr[0]; } } else if ((ptr[1] == LIBUSB20_DT_INTERFACE) && (ptr[0] >= 4)) { if (ptr[2] != iface_no) { /* new interface */ iface_no = ptr[2]; lub_interface++; lub_config->num_interface++; last_if = lub_interface; niface++; } else { /* one more alternate setting */ lub_interface->num_altsetting++; last_if = lub_alt_interface; lub_alt_interface++; } LIBUSB20_INIT(LIBUSB20_INTERFACE_DESC, &last_if->desc); if (libusb20_me_decode(ptr, ptr[0], &last_if->desc)) { /* ignore */ } /* * Sometimes USB devices have corrupt interface * descriptors and we need to overwrite the provided * interface number! */ last_if->desc.bInterfaceNumber = niface - 1; last_if->extra.ptr = LIBUSB20_ADD_BYTES(ptr, ptr[0]); last_if->extra.len = 0; last_if->extra.type = LIBUSB20_ME_IS_RAW; last_if->endpoints = lub_endpoint + 1; last_if->altsetting = lub_alt_interface; last_if->num_altsetting = 0; last_if->num_endpoints = 0; last_ep = NULL; } else { /* unknown descriptor */ if (last_if) { if (last_ep) { last_ep->extra.len += ptr[0]; } else { last_if->extra.len += ptr[0]; } } else { lub_config->extra.len += ptr[0]; } } } return (lub_config); } /*------------------------------------------------------------------------* * libusb20_desc_foreach * * Safe traversal of USB descriptors. * * Return values: * NULL: End of descriptors * Else: Pointer to next descriptor *------------------------------------------------------------------------*/ const uint8_t * libusb20_desc_foreach(const struct libusb20_me_struct *pdesc, const uint8_t *psubdesc) { const uint8_t *start; const uint8_t *end; const uint8_t *desc_next; /* be NULL safe */ if (pdesc == NULL) return (NULL); start = (const uint8_t *)pdesc->ptr; end = LIBUSB20_ADD_BYTES(start, pdesc->len); /* get start of next descriptor */ if (psubdesc == NULL) psubdesc = start; else psubdesc = psubdesc + psubdesc[0]; /* check that the next USB descriptor is within the range */ if ((psubdesc < start) || (psubdesc >= end)) return (NULL); /* out of range, or EOD */ /* check start of the second next USB descriptor, if any */ desc_next = psubdesc + psubdesc[0]; if ((desc_next < start) || (desc_next > end)) return (NULL); /* out of range */ /* check minimum descriptor length */ if (psubdesc[0] < 3) return (NULL); /* too short descriptor */ return (psubdesc); /* return start of next descriptor */ } /*------------------------------------------------------------------------* * libusb20_me_get_1 - safety wrapper to read out one byte *------------------------------------------------------------------------*/ uint8_t libusb20_me_get_1(const struct libusb20_me_struct *ie, uint16_t offset) { if (offset < ie->len) { return (*((uint8_t *)LIBUSB20_ADD_BYTES(ie->ptr, offset))); } return (0); } /*------------------------------------------------------------------------* * libusb20_me_get_2 - safety wrapper to read out one word *------------------------------------------------------------------------*/ uint16_t libusb20_me_get_2(const struct libusb20_me_struct *ie, uint16_t offset) { return (libusb20_me_get_1(ie, offset) | (libusb20_me_get_1(ie, offset + 1) << 8)); } /*------------------------------------------------------------------------* * libusb20_me_encode - encode a message structure * * Description of parameters: * "len" - maximum length of output buffer * "ptr" - pointer to output buffer. If NULL, no data will be written * "pd" - source structure * * Return values: * 0..65535 - Number of bytes used, limited by the "len" input parameter. *------------------------------------------------------------------------*/ uint16_t libusb20_me_encode(void *ptr, uint16_t len, const void *pd) { const uint8_t *pf; /* pointer to format data */ uint8_t *buf; /* pointer to output buffer */ uint32_t pd_offset; /* decoded structure offset */ uint16_t len_old; /* old length */ uint16_t pd_count; /* decoded element count */ uint8_t me; /* message element */ /* initialise */ len_old = len; buf = ptr; pd_offset = sizeof(void *); pf = (*((struct libusb20_me_format *const *)pd))->format; /* scan */ while (1) { /* get information element */ me = (pf[0]) & LIBUSB20_ME_MASK; pd_count = pf[1] | (pf[2] << 8); pf += 3; /* encode the message element */ switch (me) { case LIBUSB20_ME_INT8: while (pd_count--) { uint8_t temp; if (len < 1) /* overflow */ goto done; if (buf) { temp = *((const uint8_t *) LIBUSB20_ADD_BYTES(pd, pd_offset)); buf[0] = temp; buf += 1; } pd_offset += 1; len -= 1; } break; case LIBUSB20_ME_INT16: pd_offset = -((-pd_offset) & ~1); /* align */ while (pd_count--) { uint16_t temp; if (len < 2) /* overflow */ goto done; if (buf) { temp = *((const uint16_t *) LIBUSB20_ADD_BYTES(pd, pd_offset)); buf[1] = (temp >> 8) & 0xFF; buf[0] = temp & 0xFF; buf += 2; } pd_offset += 2; len -= 2; } break; case LIBUSB20_ME_INT32: pd_offset = -((-pd_offset) & ~3); /* align */ while (pd_count--) { uint32_t temp; if (len < 4) /* overflow */ goto done; if (buf) { temp = *((const uint32_t *) LIBUSB20_ADD_BYTES(pd, pd_offset)); buf[3] = (temp >> 24) & 0xFF; buf[2] = (temp >> 16) & 0xFF; buf[1] = (temp >> 8) & 0xFF; buf[0] = temp & 0xFF; buf += 4; } pd_offset += 4; len -= 4; } break; case LIBUSB20_ME_INT64: pd_offset = -((-pd_offset) & ~7); /* align */ while (pd_count--) { uint64_t temp; if (len < 8) /* overflow */ goto done; if (buf) { temp = *((const uint64_t *) LIBUSB20_ADD_BYTES(pd, pd_offset)); buf[7] = (temp >> 56) & 0xFF; buf[6] = (temp >> 48) & 0xFF; buf[5] = (temp >> 40) & 0xFF; buf[4] = (temp >> 32) & 0xFF; buf[3] = (temp >> 24) & 0xFF; buf[2] = (temp >> 16) & 0xFF; buf[1] = (temp >> 8) & 0xFF; buf[0] = temp & 0xFF; buf += 8; } pd_offset += 8; len -= 8; } break; case LIBUSB20_ME_STRUCT: pd_offset = -((-pd_offset) & ~(LIBUSB20_ME_STRUCT_ALIGN - 1)); /* align */ while (pd_count--) { void *src_ptr; uint16_t src_len; struct libusb20_me_struct *ps; ps = LIBUSB20_ADD_BYTES(pd, pd_offset); switch (ps->type) { case LIBUSB20_ME_IS_RAW: src_len = ps->len; src_ptr = ps->ptr; break; case LIBUSB20_ME_IS_ENCODED: if (ps->len == 0) { /* * Length is encoded * in the data itself * and should be * correct: */ ps->len = 0xFFFF; } src_len = libusb20_me_get_1(pd, 0); src_ptr = LIBUSB20_ADD_BYTES(ps->ptr, 1); if (src_len == 0xFF) { /* length is escaped */ src_len = libusb20_me_get_2(pd, 1); src_ptr = LIBUSB20_ADD_BYTES(ps->ptr, 3); } break; case LIBUSB20_ME_IS_DECODED: /* reserve 3 length bytes */ src_len = libusb20_me_encode(NULL, 0xFFFF - 3, ps->ptr); src_ptr = NULL; break; default: /* empty structure */ src_len = 0; src_ptr = NULL; break; } if (src_len > 0xFE) { if (src_len > (0xFFFF - 3)) /* overflow */ goto done; if (len < (src_len + 3)) /* overflow */ goto done; if (buf) { buf[0] = 0xFF; buf[1] = (src_len & 0xFF); buf[2] = (src_len >> 8) & 0xFF; buf += 3; } len -= (src_len + 3); } else { if (len < (src_len + 1)) /* overflow */ goto done; if (buf) { buf[0] = (src_len & 0xFF); buf += 1; } len -= (src_len + 1); } /* check for buffer and non-zero length */ if (buf && src_len) { if (ps->type == LIBUSB20_ME_IS_DECODED) { /* * Repeat encode * procedure - we have * room for the * complete structure: */ uint16_t dummy; dummy = libusb20_me_encode(buf, 0xFFFF - 3, ps->ptr); } else { bcopy(src_ptr, buf, src_len); } buf += src_len; } pd_offset += sizeof(struct libusb20_me_struct); } break; default: goto done; } } done: return (len_old - len); } /*------------------------------------------------------------------------* * libusb20_me_decode - decode a message into a decoded structure * * Description of parameters: * "ptr" - message pointer * "len" - message length * "pd" - pointer to decoded structure * * Returns: * "0..65535" - number of bytes decoded, limited by "len" *------------------------------------------------------------------------*/ uint16_t libusb20_me_decode(const void *ptr, uint16_t len, void *pd) { const uint8_t *pf; /* pointer to format data */ const uint8_t *buf; /* pointer to input buffer */ uint32_t pd_offset; /* decoded structure offset */ uint16_t len_old; /* old length */ uint16_t pd_count; /* decoded element count */ uint8_t me; /* message element */ /* initialise */ len_old = len; buf = ptr; pd_offset = sizeof(void *); pf = (*((struct libusb20_me_format **)pd))->format; /* scan */ while (1) { /* get information element */ me = (pf[0]) & LIBUSB20_ME_MASK; pd_count = pf[1] | (pf[2] << 8); pf += 3; /* decode the message element by type */ switch (me) { case LIBUSB20_ME_INT8: while (pd_count--) { uint8_t temp; if (len < 1) { len = 0; temp = 0; } else { len -= 1; temp = buf[0]; buf++; } *((uint8_t *)LIBUSB20_ADD_BYTES(pd, pd_offset)) = temp; pd_offset += 1; } break; case LIBUSB20_ME_INT16: pd_offset = -((-pd_offset) & ~1); /* align */ while (pd_count--) { uint16_t temp; if (len < 2) { len = 0; temp = 0; } else { len -= 2; temp = buf[1] << 8; temp |= buf[0]; buf += 2; } *((uint16_t *)LIBUSB20_ADD_BYTES(pd, pd_offset)) = temp; pd_offset += 2; } break; case LIBUSB20_ME_INT32: pd_offset = -((-pd_offset) & ~3); /* align */ while (pd_count--) { uint32_t temp; if (len < 4) { len = 0; temp = 0; } else { len -= 4; temp = buf[3] << 24; temp |= buf[2] << 16; temp |= buf[1] << 8; temp |= buf[0]; buf += 4; } *((uint32_t *)LIBUSB20_ADD_BYTES(pd, pd_offset)) = temp; pd_offset += 4; } break; case LIBUSB20_ME_INT64: pd_offset = -((-pd_offset) & ~7); /* align */ while (pd_count--) { uint64_t temp; if (len < 8) { len = 0; temp = 0; } else { len -= 8; temp = ((uint64_t)buf[7]) << 56; temp |= ((uint64_t)buf[6]) << 48; temp |= ((uint64_t)buf[5]) << 40; temp |= ((uint64_t)buf[4]) << 32; temp |= buf[3] << 24; temp |= buf[2] << 16; temp |= buf[1] << 8; temp |= buf[0]; buf += 8; } *((uint64_t *)LIBUSB20_ADD_BYTES(pd, pd_offset)) = temp; pd_offset += 8; } break; case LIBUSB20_ME_STRUCT: pd_offset = -((-pd_offset) & ~(LIBUSB20_ME_STRUCT_ALIGN - 1)); /* align */ while (pd_count--) { uint16_t temp; uint16_t dummy; struct libusb20_me_struct *ps; ps = LIBUSB20_ADD_BYTES(pd, pd_offset); if (ps->type == LIBUSB20_ME_IS_ENCODED) { /* * Pre-store a de-constified * pointer to the raw * structure: */ ps->ptr = LIBUSB20_ADD_BYTES(buf, 0); /* * Get the correct number of * length bytes: */ if (len != 0) { if (buf[0] == 0xFF) { ps->len = 3; } else { ps->len = 1; } } else { ps->len = 0; } } /* get the structure length */ if (len != 0) { if (buf[0] == 0xFF) { if (len < 3) { len = 0; temp = 0; } else { len -= 3; temp = buf[1] | (buf[2] << 8); buf += 3; } } else { len -= 1; temp = buf[0]; buf += 1; } } else { len = 0; temp = 0; } /* check for invalid length */ if (temp > len) { len = 0; temp = 0; } /* check wanted structure type */ switch (ps->type) { case LIBUSB20_ME_IS_ENCODED: /* check for zero length */ if (temp == 0) { /* * The pointer must * be valid: */ ps->ptr = LIBUSB20_ADD_BYTES( libusb20_me_encode_empty, 0); ps->len = 1; } else { ps->len += temp; } break; case LIBUSB20_ME_IS_RAW: /* update length and pointer */ ps->len = temp; ps->ptr = LIBUSB20_ADD_BYTES(buf, 0); break; case LIBUSB20_ME_IS_EMPTY: case LIBUSB20_ME_IS_DECODED: /* check for non-zero length */ if (temp != 0) { /* update type */ ps->type = LIBUSB20_ME_IS_DECODED; ps->len = 0; /* * Recursivly decode * the next structure */ dummy = libusb20_me_decode(buf, temp, ps->ptr); } else { /* update type */ ps->type = LIBUSB20_ME_IS_EMPTY; ps->len = 0; } break; default: /* * nothing to do - should * not happen */ ps->ptr = NULL; ps->len = 0; break; } buf += temp; len -= temp; pd_offset += sizeof(struct libusb20_me_struct); } break; default: goto done; } } done: return (len_old - len); }