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Current File : //compat/linux/proc/68247/root/usr/src/lib/libusbhid/parse.c |
/* $NetBSD: parse.c,v 1.11 2000/09/24 02:19:54 augustss Exp $ */ /* * Copyright (c) 1999, 2001 Lennart Augustsson <augustss@netbsd.org> * 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/cdefs.h> __FBSDID("$FreeBSD: release/9.1.0/lib/libusbhid/parse.c 235866 2012-05-24 01:23:30Z mav $"); #include <assert.h> #include <stdlib.h> #include <string.h> #include <sys/time.h> #include <dev/usb/usb.h> #include <dev/usb/usbhid.h> #include "usbhid.h" #include "usbvar.h" #define MAXUSAGE 100 #define MAXPUSH 4 #define MAXID 64 #define ITEMTYPES 3 struct hid_pos_data { int32_t rid; uint32_t pos[ITEMTYPES]; }; struct hid_data { const uint8_t *start; const uint8_t *end; const uint8_t *p; struct hid_item cur[MAXPUSH]; struct hid_pos_data last_pos[MAXID]; uint32_t pos[ITEMTYPES]; int32_t usages_min[MAXUSAGE]; int32_t usages_max[MAXUSAGE]; int32_t usage_last; /* last seen usage */ uint32_t loc_size; /* last seen size */ uint32_t loc_count; /* last seen count */ uint8_t kindset; /* we have 5 kinds so 8 bits are enough */ uint8_t pushlevel; /* current pushlevel */ uint8_t ncount; /* end usage item count */ uint8_t icount; /* current usage item count */ uint8_t nusage; /* end "usages_min/max" index */ uint8_t iusage; /* current "usages_min/max" index */ uint8_t ousage; /* current "usages_min/max" offset */ uint8_t susage; /* usage set flags */ }; /*------------------------------------------------------------------------* * hid_clear_local *------------------------------------------------------------------------*/ static void hid_clear_local(hid_item_t *c) { c->usage = 0; c->usage_minimum = 0; c->usage_maximum = 0; c->designator_index = 0; c->designator_minimum = 0; c->designator_maximum = 0; c->string_index = 0; c->string_minimum = 0; c->string_maximum = 0; c->set_delimiter = 0; } static void hid_switch_rid(struct hid_data *s, struct hid_item *c, int32_t next_rID) { uint8_t i, j; /* check for same report ID - optimise */ if (c->report_ID == next_rID) return; /* save current position for current rID */ if (c->report_ID == 0) { i = 0; } else { for (i = 1; i != MAXID; i++) { if (s->last_pos[i].rid == c->report_ID) break; if (s->last_pos[i].rid == 0) break; } } if (i != MAXID) { s->last_pos[i].rid = c->report_ID; for (j = 0; j < ITEMTYPES; j++) s->last_pos[i].pos[j] = s->pos[j]; } /* store next report ID */ c->report_ID = next_rID; /* lookup last position for next rID */ if (next_rID == 0) { i = 0; } else { for (i = 1; i != MAXID; i++) { if (s->last_pos[i].rid == next_rID) break; if (s->last_pos[i].rid == 0) break; } } if (i != MAXID) { s->last_pos[i].rid = next_rID; for (j = 0; j < ITEMTYPES; j++) s->pos[j] = s->last_pos[i].pos[j]; } else { for (j = 0; j < ITEMTYPES; j++) s->pos[j] = 0; /* Out of RID entries. */ } } /*------------------------------------------------------------------------* * hid_start_parse *------------------------------------------------------------------------*/ hid_data_t hid_start_parse(report_desc_t d, int kindset, int id __unused) { struct hid_data *s; s = malloc(sizeof *s); memset(s, 0, sizeof *s); s->start = s->p = d->data; s->end = d->data + d->size; s->kindset = kindset; return (s); } /*------------------------------------------------------------------------* * hid_end_parse *------------------------------------------------------------------------*/ void hid_end_parse(hid_data_t s) { if (s == NULL) return; free(s); } /*------------------------------------------------------------------------* * get byte from HID descriptor *------------------------------------------------------------------------*/ static uint8_t hid_get_byte(struct hid_data *s, const uint16_t wSize) { const uint8_t *ptr; uint8_t retval; ptr = s->p; /* check if end is reached */ if (ptr == s->end) return (0); /* read out a byte */ retval = *ptr; /* check if data pointer can be advanced by "wSize" bytes */ if ((s->end - ptr) < wSize) ptr = s->end; else ptr += wSize; /* update pointer */ s->p = ptr; return (retval); } /*------------------------------------------------------------------------* * hid_get_item *------------------------------------------------------------------------*/ int hid_get_item(hid_data_t s, hid_item_t *h) { hid_item_t *c; unsigned int bTag, bType, bSize; int32_t mask; int32_t dval; if (s == NULL) return (0); c = &s->cur[s->pushlevel]; top: /* check if there is an array of items */ if (s->icount < s->ncount) { /* get current usage */ if (s->iusage < s->nusage) { dval = s->usages_min[s->iusage] + s->ousage; c->usage = dval; s->usage_last = dval; if (dval == s->usages_max[s->iusage]) { s->iusage ++; s->ousage = 0; } else { s->ousage ++; } } else { /* Using last usage */ dval = s->usage_last; } s->icount ++; /* * Only copy HID item, increment position and return * if correct kindset! */ if (s->kindset & (1 << c->kind)) { *h = *c; h->pos = s->pos[c->kind]; s->pos[c->kind] += c->report_size * c->report_count; return (1); } } /* reset state variables */ s->icount = 0; s->ncount = 0; s->iusage = 0; s->nusage = 0; s->susage = 0; s->ousage = 0; hid_clear_local(c); /* get next item */ while (s->p != s->end) { bSize = hid_get_byte(s, 1); if (bSize == 0xfe) { /* long item */ bSize = hid_get_byte(s, 1); bSize |= hid_get_byte(s, 1) << 8; bTag = hid_get_byte(s, 1); bType = 0xff; /* XXX what should it be */ } else { /* short item */ bTag = bSize >> 4; bType = (bSize >> 2) & 3; bSize &= 3; if (bSize == 3) bSize = 4; } switch(bSize) { case 0: dval = 0; mask = 0; break; case 1: dval = (int8_t)hid_get_byte(s, 1); mask = 0xFF; break; case 2: dval = hid_get_byte(s, 1); dval |= hid_get_byte(s, 1) << 8; dval = (int16_t)dval; mask = 0xFFFF; break; case 4: dval = hid_get_byte(s, 1); dval |= hid_get_byte(s, 1) << 8; dval |= hid_get_byte(s, 1) << 16; dval |= hid_get_byte(s, 1) << 24; mask = 0xFFFFFFFF; break; default: dval = hid_get_byte(s, bSize); continue; } switch (bType) { case 0: /* Main */ switch (bTag) { case 8: /* Input */ c->kind = hid_input; c->flags = dval; ret: c->report_count = s->loc_count; c->report_size = s->loc_size; if (c->flags & HIO_VARIABLE) { /* range check usage count */ if (c->report_count > 255) { s->ncount = 255; } else s->ncount = c->report_count; /* * The "top" loop will return * one and one item: */ c->report_count = 1; c->usage_minimum = 0; c->usage_maximum = 0; } else { s->ncount = 1; } goto top; case 9: /* Output */ c->kind = hid_output; c->flags = dval; goto ret; case 10: /* Collection */ c->kind = hid_collection; c->collection = dval; c->collevel++; c->usage = s->usage_last; *h = *c; return (1); case 11: /* Feature */ c->kind = hid_feature; c->flags = dval; goto ret; case 12: /* End collection */ c->kind = hid_endcollection; if (c->collevel == 0) { /* Invalid end collection. */ return (0); } c->collevel--; *h = *c; return (1); default: break; } break; case 1: /* Global */ switch (bTag) { case 0: c->_usage_page = dval << 16; break; case 1: c->logical_minimum = dval; break; case 2: c->logical_maximum = dval; break; case 3: c->physical_minimum = dval; break; case 4: c->physical_maximum = dval; break; case 5: c->unit_exponent = dval; break; case 6: c->unit = dval; break; case 7: /* mask because value is unsigned */ s->loc_size = dval & mask; break; case 8: hid_switch_rid(s, c, dval & mask); break; case 9: /* mask because value is unsigned */ s->loc_count = dval & mask; break; case 10: /* Push */ s->pushlevel ++; if (s->pushlevel < MAXPUSH) { s->cur[s->pushlevel] = *c; /* store size and count */ c->report_size = s->loc_size; c->report_count = s->loc_count; /* update current item pointer */ c = &s->cur[s->pushlevel]; } break; case 11: /* Pop */ s->pushlevel --; if (s->pushlevel < MAXPUSH) { c = &s->cur[s->pushlevel]; /* restore size and count */ s->loc_size = c->report_size; s->loc_count = c->report_count; c->report_size = 0; c->report_count = 0; } break; default: break; } break; case 2: /* Local */ switch (bTag) { case 0: if (bSize != 4) dval = (dval & mask) | c->_usage_page; /* set last usage, in case of a collection */ s->usage_last = dval; if (s->nusage < MAXUSAGE) { s->usages_min[s->nusage] = dval; s->usages_max[s->nusage] = dval; s->nusage ++; } /* else XXX */ /* clear any pending usage sets */ s->susage = 0; break; case 1: s->susage |= 1; if (bSize != 4) dval = (dval & mask) | c->_usage_page; c->usage_minimum = dval; goto check_set; case 2: s->susage |= 2; if (bSize != 4) dval = (dval & mask) | c->_usage_page; c->usage_maximum = dval; check_set: if (s->susage != 3) break; /* sanity check */ if ((s->nusage < MAXUSAGE) && (c->usage_minimum <= c->usage_maximum)) { /* add usage range */ s->usages_min[s->nusage] = c->usage_minimum; s->usages_max[s->nusage] = c->usage_maximum; s->nusage ++; } /* else XXX */ s->susage = 0; break; case 3: c->designator_index = dval; break; case 4: c->designator_minimum = dval; break; case 5: c->designator_maximum = dval; break; case 7: c->string_index = dval; break; case 8: c->string_minimum = dval; break; case 9: c->string_maximum = dval; break; case 10: c->set_delimiter = dval; break; default: break; } break; default: break; } } return (0); } int hid_report_size(report_desc_t r, enum hid_kind k, int id) { struct hid_data *d; struct hid_item h; uint32_t temp; uint32_t hpos; uint32_t lpos; int report_id = 0; hpos = 0; lpos = 0xFFFFFFFF; memset(&h, 0, sizeof h); for (d = hid_start_parse(r, 1 << k, id); hid_get_item(d, &h); ) { if ((h.report_ID == id || id < 0) && h.kind == k) { /* compute minimum */ if (lpos > h.pos) lpos = h.pos; /* compute end position */ temp = h.pos + (h.report_size * h.report_count); /* compute maximum */ if (hpos < temp) hpos = temp; if (h.report_ID != 0) report_id = 1; } } hid_end_parse(d); /* safety check - can happen in case of currupt descriptors */ if (lpos > hpos) temp = 0; else temp = hpos - lpos; /* return length in bytes rounded up */ return ((temp + 7) / 8 + report_id); } int hid_locate(report_desc_t desc, unsigned int u, enum hid_kind k, hid_item_t *h, int id) { struct hid_data *d; for (d = hid_start_parse(desc, 1 << k, id); hid_get_item(d, h); ) { if (h->kind == k && !(h->flags & HIO_CONST) && h->usage == u) { hid_end_parse(d); return (1); } } hid_end_parse(d); h->report_size = 0; return (0); }