char *parse_mesocyclone (char *buf, NIDS_mesocyclone *c) { c->x_start = GET2(buf); c->y_start = GET2(buf + 2); c->radius = GET2(buf + 4); return buf + 6; }
char *parse_raster_header(char *buf, NIDS_raster *r) { int i; char *p; r->op_flags1 = GET2(buf); r->op_flags2 = GET2(buf + 2); r->x_start = GET2(buf + 4); r->y_start = GET2(buf + 6); r->x_scale_int = GET2(buf + 8); r->x_scale_fract = GET2(buf + 10); r->y_scale_int = GET2(buf + 12); r->y_scale_fract = GET2(buf + 14); r->num_rows = GET2(buf + 16); r->packing = GET2(buf + 18); if (!(r->rows = malloc(r->num_rows * sizeof(NIDS_raster_row)))) ERROR("parse_radial_header"); p = buf + 20; for (i = 0 ; i < r->num_rows ; i++) { p = parse_raster_row(p, r->rows + i); } return p; }
static int get_first_set(const pcre16 *code, PCRE_SPTR16 stringname, int *ovector) #endif { const REAL_PCRE *re = (const REAL_PCRE *)code; int entrysize; pcre_uchar *entry; #ifdef COMPILE_PCRE8 char *first, *last; #else PCRE_UCHAR16 *first, *last; #endif #ifdef COMPILE_PCRE8 if ((re->options & PCRE_DUPNAMES) == 0 && (re->flags & PCRE_JCHANGED) == 0) return pcre_get_stringnumber(code, stringname); entrysize = pcre_get_stringtable_entries(code, stringname, &first, &last); #else if ((re->options & PCRE_DUPNAMES) == 0 && (re->flags & PCRE_JCHANGED) == 0) return pcre16_get_stringnumber(code, stringname); entrysize = pcre16_get_stringtable_entries(code, stringname, &first, &last); #endif if (entrysize <= 0) return entrysize; for (entry = (pcre_uchar *)first; entry <= (pcre_uchar *)last; entry += entrysize) { int n = GET2(entry, 0); if (ovector[n*2] >= 0) return n; } return GET2(entry, 0); }
char *parse_linked_vector(char *buf, NIDS_vector *v, int x_start, int y_start) { v->x_start = x_start; v->y_start = y_start; v->x_end = GET2(buf); v->y_end = GET2(buf + 2); return buf + 4; }
char *parse_hail (char *buf, NIDS_hail *h) { h->x_start = GET2(buf); h->y_start = GET2(buf + 2); h->prob = GET2(buf + 4); h->severe = GET2(buf + 6); h->max_size = GET2(buf + 8); return buf + 10; }
void zft_ftape_extract_file_marks(__u8* address) { int i; TRACE_FUN(ft_t_any); zft_eof_map = NULL; if (ft_format_code == fmt_var || ft_format_code == fmt_big) { __u8* end; __u8* start = ftape_find_end_of_bsm_list(address); zft_nr_eof_marks = 0; if (start) { start += 3; /* skip end of list mark */ end = find_end_of_eof_list(start, address + FT_SEGMENT_SIZE); if (end && end - start <= FT_FSL_SIZE) { zft_nr_eof_marks = ((end - start) / sizeof(eof_mark_union)); zft_eof_map = (eof_mark_union *)start; } else { TRACE(ft_t_err, "EOF Mark List is too long or damaged!"); } } else { TRACE(ft_t_err, "Bad Sector List is too long or damaged !"); } } else { zft_eof_map = (eof_mark_union *)&address[FT_FSL]; zft_nr_eof_marks = GET2(address, FT_FSL_CNT); } TRACE(ft_t_noise, "number of file marks: %d", zft_nr_eof_marks); if (ftape_fmt_version == 1) { TRACE(ft_t_info, "swapping version 1 fields"); /* version 1 format uses swapped sector and segment * fields, correct that ! */ for (i = 0; i < zft_nr_eof_marks; ++i) { __u16 tmp = GET2(&zft_eof_map[i].mark.segment,0); PUT2(&zft_eof_map[i].mark.segment, 0, GET2(&zft_eof_map[i].mark.date,0)); PUT2(&zft_eof_map[i].mark.date, 0, tmp); } } for (i = 0; i < zft_nr_eof_marks; ++i) { TRACE(ft_t_noise, "eof mark: %5d/%2d", GET2(&zft_eof_map[i].mark.segment, 0), GET2(&zft_eof_map[i].mark.date,0)); } TRACE_EXIT; }
static void step4(int *ix, int *mdist, mat_t mstar, mat_t nmstar, mat_t mprime, col_t ccol, col_t crow, int nrows, int ncols, int dmin, int row, int col) { int n, rstar, cstar, primeRow, primeCol; /* generate temporary copy of mstar */ memcpy(nmstar, mstar, sizeof(mat_t)); /* star current zero */ SET2(nmstar, row, col); /* find starred zero in current column */ cstar = col; for (rstar = 0; rstar < nrows; rstar++) if (GET2(mstar, rstar, cstar)) break; while (rstar < nrows) { /* unstar the starred zero */ CLEAR2(nmstar, rstar, cstar); /* find primed zero in current row */ primeRow = rstar; for (primeCol = 0; primeCol < ncols; primeCol++) if (GET2(mprime, primeRow, primeCol)) break; /* star the primed zero */ SET2(nmstar, primeRow, primeCol); /* find starred zero in current column */ cstar = primeCol; for (rstar = 0; rstar < nrows; rstar++) if (GET2(mstar, rstar, cstar)) break; } /* use temporary copy as new mstar */ /* delete all primes, uncover all rows */ memcpy(mstar, nmstar, sizeof(mat_t)); memset(mprime, 0, sizeof(mat_t)); memset(crow, 0, sizeof(col_t)); /* move to step 2a */ step2a(ix, mdist, mstar, nmstar, mprime, ccol, crow, nrows, ncols, dmin); }
static long ctltrans(Ep *ep, uchar *req, long n) { Hostchan *hc; Epio *epio; Block *b; uchar *data; int datalen; epio = ep->aux; if(epio->cb != nil){ freeb(epio->cb); epio->cb = nil; } if(n < Rsetuplen) error(Ebadlen); if(req[Rtype] & Rd2h){ datalen = GET2(req+Rcount); if(datalen <= 0 || datalen > Maxctllen) error(Ebadlen); /* XXX cache madness */ epio->cb = b = allocb(ROUND(datalen, ep->maxpkt) + CACHELINESZ); b->wp = (uchar*)ROUND((uintptr)b->wp, CACHELINESZ); //epio->cb = b = allocb(ROUND(datalen, ep->maxpkt)); //assert(((uintptr)b->wp & (BLOCKALIGN-1)) == 0); memset(b->wp, 0x55, b->lim - b->wp); cachedwbinvse(b->wp, b->lim - b->wp); data = b->wp; }else{ b = nil; datalen = n - Rsetuplen; data = req + Rsetuplen; } hc = chanalloc(ep); if(waserror()){ chanrelease(ep, hc); if(strcmp(up->env->errstr, Estalled) == 0) return 0; nexterror(); } chansetup(hc, ep); chanio(ep, hc, Epout, SETUP, req, Rsetuplen); if(req[Rtype] & Rd2h){ if(ep->dev->hub <= 1){ ep->toggle[Read] = DATA1; b->wp += multitrans(ep, hc, Read, data, datalen); }else b->wp += chanio(ep, hc, Epin, DATA1, data, datalen); chanio(ep, hc, Epout, DATA1, nil, 0); n = Rsetuplen; }else{ if(datalen > 0) chanio(ep, hc, Epout, DATA1, data, datalen); chanio(ep, hc, Epin, DATA1, nil, 0); n = Rsetuplen + datalen; } chanrelease(ep, hc); poperror(); return n; }
PCRE_EXP_DEFN int PCRE_CALL_CONVENTION pcre32_get_stringnumber(const pcre32 *code, PCRE_SPTR32 stringname) #endif { int rc; int entrysize; int top, bot; pcre_uchar *nametable; #ifdef COMPILE_PCRE8 if ((rc = pcre_fullinfo(code, NULL, PCRE_INFO_NAMECOUNT, &top)) != 0) return rc; if (top <= 0) return PCRE_ERROR_NOSUBSTRING; if ((rc = pcre_fullinfo(code, NULL, PCRE_INFO_NAMEENTRYSIZE, &entrysize)) != 0) return rc; if ((rc = pcre_fullinfo(code, NULL, PCRE_INFO_NAMETABLE, &nametable)) != 0) return rc; #endif #ifdef COMPILE_PCRE16 if ((rc = pcre16_fullinfo(code, NULL, PCRE_INFO_NAMECOUNT, &top)) != 0) return rc; if (top <= 0) return PCRE_ERROR_NOSUBSTRING; if ((rc = pcre16_fullinfo(code, NULL, PCRE_INFO_NAMEENTRYSIZE, &entrysize)) != 0) return rc; if ((rc = pcre16_fullinfo(code, NULL, PCRE_INFO_NAMETABLE, &nametable)) != 0) return rc; #endif #ifdef COMPILE_PCRE32 if ((rc = pcre32_fullinfo(code, NULL, PCRE_INFO_NAMECOUNT, &top)) != 0) return rc; if (top <= 0) return PCRE_ERROR_NOSUBSTRING; if ((rc = pcre32_fullinfo(code, NULL, PCRE_INFO_NAMEENTRYSIZE, &entrysize)) != 0) return rc; if ((rc = pcre32_fullinfo(code, NULL, PCRE_INFO_NAMETABLE, &nametable)) != 0) return rc; #endif bot = 0; while (top > bot) { int mid = (top + bot) / 2; pcre_uchar *entry = nametable + entrysize*mid; int c = STRCMP_UC_UC((pcre_uchar *)stringname, (pcre_uchar *)(entry + IMM2_SIZE)); if (c == 0) return GET2(entry, 0); if (c > 0) bot = mid + 1; else top = mid; } return PCRE_ERROR_NOSUBSTRING; }
static void buildixvector(int *ix, mat_t mstar, int nrows, int ncols) { int row, col; for (row = 0; row < nrows; row++) { for (col = 0; col < ncols; col++) { if (GET2(mstar, row, col)) { ix[row] = col; break; } } } }
static int getrxctl(Dev *d) { uchar buf[2]; int r; memset(buf, 0, sizeof(buf)); if(asixget(d, Crrxctl, buf, sizeof(buf)) < 0) return -1; r = GET2(buf); deprint(2, "%s: rxctl %#x\n", argv0, r); return r; }
char *parse_linked_vector_header(char *buf, NIDS_linked_vectors *v) { int i; char *p; int x_start; int y_start; v->length = GET2(buf); v->num_vectors = (v->length - 4) / 4; x_start = GET2(buf + 2); y_start = GET2(buf + 4); if (!(v->vectors = malloc(v->num_vectors * sizeof(NIDS_vector)))) ERROR("parse_linked_vector_header"); p = buf + 6; for (i = 0 ; i < v->num_vectors ; i++) { p = parse_linked_vector(p, v->vectors + i, x_start, y_start); } return p; }
void ProxyConfPrivate::readProxyData() { /* Read the proxy settings from /system/proxy* */ GET2(http_proxy, host, String); GET2(http_port, port, Int); GET2(ignore_hosts, ignore_hosts, List); GET(mode, String); GET(autoconfig_url, String); GET(secure_host, String); GET(secure_port, Int); GET(ftp_host, String); GET(ftp_port, Int); GET(socks_host, String); GET(socks_port, Int); GET(rtsp_host, String); GET(rtsp_port, Int); if (http_proxy.isEmpty()) use_http_host = false; else use_http_host = true; }
/* * This may be used to detect overcurrent on the hub */ static void checkhubstatus(Hub *h) { uint8_t buf[4]; int sts; if(h->isroot) /* not for root hubs */ return; if(usbcmd(h->dev, Rd2h|Rclass|Rdev, Rgetstatus, 0, 0, buf, 4) < 0){ dprint(2, "%s: get hub status: %r\n", h->dev->dir); return; } sts = GET2(buf); dprint(2, "hub %s: status %#x\n", h->dev->dir, sts); }
static void step3(int *ix, int *mdist, mat_t mstar, mat_t nmstar, mat_t mprime, col_t ccol, col_t crow, int nrows, int ncols, int dmin) { int zerosFound; int row, col, cstar; zerosFound = 1; while (zerosFound) { zerosFound = 0; for (col = 0; col < ncols; col++) { if (GET1(ccol, col)) continue; for (row = 0; row < nrows; row++) { if (mdist[row + nrows * col] != 0) continue; if (GET1(crow, row)) continue; /* prime zero */ SET2(mprime, row, col); /* find starred zero in current row */ for (cstar = 0; cstar < ncols; cstar++) if (GET2(mstar, row, cstar)) break; if (cstar == ncols) { /* no starred zero */ /* move to step 4 */ step4(ix, mdist, mstar, nmstar, mprime, ccol, crow, nrows, ncols, dmin, row, col); return; } else { SET1(crow, row); CLEAR1(ccol, cstar); zerosFound = 1; break; } } } } /* move to step 5 */ step5(ix, mdist, mstar, nmstar, mprime, ccol, crow, nrows, ncols, dmin); }
static int miiread(Dev *d, int phy, int reg) { int r; uchar v[2]; r = Rd2h|Rvendor|Rdev; if(usbcmd(d, r, Crmii, phy, reg, v, 2) < 0){ dprint(2, "%s: miiwrite: %r\n", argv0); return -1; } r = GET2(v); if(r == 0xFFFF) return -1; return r; }
static int eepromread(Dev *d, int i) { int r; int ec; uchar buf[2]; r = Rd2h|Rvendor|Rdev; ec = usbcmd(d, r, Creeprom, i, 0, buf, sizeof(buf)); if(ec < 0) deprint(2, "%s: eepromread %d: %r\n", argv0, i); ec = GET2(buf); deprint(2, "%s: eeprom %#x = %#x\n", argv0, i, ec); if(ec == 0xFFFF) ec = -1; return ec; }
char *parse_mesocyclone_header(char *buf, NIDS_mesocyclones *c) { int i; char *p; c->length = GET2(buf); c->num_mesocyclones = c->length / 6; if (!(c->mesocyclones = malloc(c->num_mesocyclones * sizeof(NIDS_mesocyclone)))) ERROR("parse_mesocyclone_header"); p = buf + 2; for (i = 0 ; i < c->num_mesocyclones ; i++) { p = parse_mesocyclone(p, c->mesocyclones + i); } return p; }
char *parse_etvs_header(char *buf, NIDS_etvss *p) { int i; char *ptr; p->length = GET2(buf); p->num_points = p->length / 4; if (!(p->points = malloc(p->num_points * sizeof(NIDS_point)))) ERROR("parse_etvs_header"); ptr = buf + 2; for (i = 0 ; i < p->num_points ; i++) { ptr = parse_point(ptr, p->points + i); } return ptr; }
char *parse_hail_header(char *buf, NIDS_hails *h) { int i; char *p; h->length = GET2(buf); h->num_hails = h->length / 10; if (!(h->hails = malloc(h->num_hails * sizeof(NIDS_hail)))) ERROR("parse_hail_header"); p = buf + 2; for (i = 0 ; i < h->num_hails ; i++) { p = parse_hail(p, h->hails + i); } return p; }
PCRE2_EXP_DEFN int PCRE2_CALL_CONVENTION pcre2_substring_nametable_scan(const pcre2_code *code, PCRE2_SPTR stringname, PCRE2_SPTR *firstptr, PCRE2_SPTR *lastptr) { uint16_t bot = 0; uint16_t top = code->name_count; uint16_t entrysize = code->name_entry_size; PCRE2_SPTR nametable = (PCRE2_SPTR)((char *)code + sizeof(pcre2_real_code)); while (top > bot) { uint16_t mid = (top + bot) / 2; PCRE2_SPTR entry = nametable + entrysize*mid; int c = PRIV(strcmp)(stringname, entry + IMM2_SIZE); if (c == 0) { PCRE2_SPTR first; PCRE2_SPTR last; PCRE2_SPTR lastentry; lastentry = nametable + entrysize * (code->name_count - 1); first = last = entry; while (first > nametable) { if (PRIV(strcmp)(stringname, (first - entrysize + IMM2_SIZE)) != 0) break; first -= entrysize; } while (last < lastentry) { if (PRIV(strcmp)(stringname, (last + entrysize + IMM2_SIZE)) != 0) break; last += entrysize; } if (firstptr == NULL) return (first == last)? (int)GET2(entry, 0) : PCRE2_ERROR_NOUNIQUESUBSTRING; *firstptr = first; *lastptr = last; return entrysize; } if (c > 0) bot = mid + 1; else top = mid; } return PCRE2_ERROR_NOSUBSTRING; }
int local_sieve(int a, int b) { int sqr = (int) sqrt(b), gap = b - a; int *mark2 = (int *) calloc(MAXN, sizeof(int)); for (int i = 0; i < Pt && P[i] <= sqr; i++) { unsigned p = P[i], base = a / p * p; while (base < a) base += p; if (base == p) base += p; for (unsigned j = base; j <= b; j += p) SET2(j - a); } if (a == 1) SET2(0); int ret = 0; for (int i = 0; i <= gap; i++) { if (!GET2(i)) ret++; } free(mark2); return ret; }
static char* mkstr(uchar *b, int n) { Rune r; char *us; char *s; char *e; if(n <= 2 || (n & 1) != 0) return strdup("none"); n = (n - 2)/2; b += 2; us = s = emallocz(n*UTFmax+1, 0); e = s + n*UTFmax+1; for(; --n >= 0; b += 2){ r = GET2(b); s = seprint(s, e, "%C", r); } return us; }
char *parse_raster_row(char *buf, NIDS_raster_row *r) { char *p; int i; r->num_rle = GET2(buf); if (!(r->run = malloc(r->num_rle * 2))) ERROR("parse_raster_row"); if (!(r->code = malloc(r->num_rle * 2))) ERROR("parse_raster_row"); p = buf + 2; for (i = 0 ; i < r->num_rle ; i++) { r->run[i] = (p[i] >> 4) & 0x0f; r->code[i] = p[i] & 0x0f; } return p + i; }
static int portstatus(Hub *h, int p) { Dev *d; uint8_t buf[4]; int t; int sts; int dbg; dbg = usbdebug; if(dbg != 0 && dbg < 4) usbdebug = 1; /* do not be too chatty */ d = h->dev; t = Rd2h|Rclass|Rother; if(usbcmd(d, t, Rgetstatus, 0, p, buf, sizeof(buf)) < 0) sts = -1; else sts = GET2(buf); usbdebug = dbg; return sts; }
static void step2a(int *ix, int *mdist, mat_t mstar, mat_t nmstar, mat_t mprime, col_t ccol, col_t crow, int nrows, int ncols, int dmin) { int col, row; /* cover every column containing a starred zero */ for (col = 0; col < ncols; col++) { for (row = 0; row < nrows; row++) { if (!GET2(mstar, row, col)) continue; SET1(ccol, col); break; } } /* move to step 3 */ step2b(ix, mdist, mstar, nmstar, mprime, ccol, crow, nrows, ncols, dmin); }
int smscinit(Dev *d) { if(!doreset(d, Hwcfg, Lrst) || !doreset(d, Pmctrl, Phyrst)) return -1; if(!setmac) if(eepromr(d, MACoffset, macaddr, 6) < 0) return -1; wr(d, Addrl, GET4(macaddr)); wr(d, Addrh, GET2(macaddr+4)); if(Doburst){ wr(d, Hwcfg, (rr(d,Hwcfg)&~Rxdoff)|Bir|Mef|Bce); wr(d, Burstcap, Hsburst); }else{ wr(d, Hwcfg, (rr(d,Hwcfg)&~(Rxdoff|Mef|Bce))|Bir); wr(d, Burstcap, 0); } wr(d, Bulkdelay, Defbulkdly); wr(d, Intsts, ~0); wr(d, Ledgpio, Ledspd|Ledlnk|Ledfdx); wr(d, Flow, 0); wr(d, Afccfg, Afcdefault); wr(d, Vlan1, Ethp8021q); wr(d, Coecr, rr(d,Coecr)&~(Txcoe|Rxcoe)); /* TODO could offload checksums? */ wr(d, Hashh, 0); wr(d, Hashl, 0); wr(d, Maccr, rr(d,Maccr)&~(Prms|Mcpas|Hpfilt)); phyinit(d); wr(d, Intepctl, rr(d, Intepctl)|Phyint); wr(d, Maccr, rr(d, Maccr)|Txen|Rxen); wr(d, Txcfg, Txon); eptransmit = smsctransmit; epreceive = smscreceive; return 0; }
PCRE2_EXP_DEFN int PCRE2_CALL_CONVENTION pcre2_substring_copy_byname(pcre2_match_data *match_data, PCRE2_SPTR stringname, PCRE2_UCHAR *buffer, PCRE2_SIZE *sizeptr) { PCRE2_SPTR first, last, entry; int failrc, entrysize; if (match_data->matchedby == PCRE2_MATCHEDBY_DFA_INTERPRETER) return PCRE2_ERROR_DFA_UFUNC; entrysize = pcre2_substring_nametable_scan(match_data->code, stringname, &first, &last); if (entrysize < 0) return entrysize; failrc = PCRE2_ERROR_UNAVAILABLE; for (entry = first; entry <= last; entry += entrysize) { uint32_t n = GET2(entry, 0); if (n < match_data->oveccount) { if (match_data->ovector[n*2] != PCRE2_UNSET) return pcre2_substring_copy_bynumber(match_data, n, buffer, sizeptr); failrc = PCRE2_ERROR_UNSET; } } return failrc; }
static void store_route(struct rt_msghdr *rtm) { u_int i; struct natm_route *r; char *cp; struct sockaddr *sa; struct sockaddr_in *sain; struct sockaddr_dl *sdl; struct diagif *aif; u_int n; r = malloc(sizeof(*r)); if (r == NULL) err(1, "allocate route"); r->flags = rtm->rtm_flags; cp = (char *)(rtm + 1); for (i = 1; i != 0; i <<= 1) { if (rtm->rtm_addrs & i) { sa = (struct sockaddr *)cp; cp += roundup(sa->sa_len, sizeof(long)); switch (i) { case RTA_DST: if (sa->sa_family != AF_INET) { warnx("RTA_DST not AF_INET %u", sa->sa_family); goto fail; } sain = (struct sockaddr_in *)(void *)sa; if (sain->sin_len < 4) r->host.s_addr = INADDR_ANY; else r->host = sain->sin_addr; break; case RTA_GATEWAY: if (sa->sa_family != AF_LINK) { warnx("RTA_GATEWAY not AF_LINK"); goto fail; } sdl = (struct sockaddr_dl *)(void *)sa; TAILQ_FOREACH(aif, &diagif_list, link) if (strlen(aif->ifname) == sdl->sdl_nlen && strncmp(aif->ifname, sdl->sdl_data, sdl->sdl_nlen) == 0) break; if (aif == NULL) { warnx("interface '%.*s' not found", sdl->sdl_nlen, sdl->sdl_data); goto fail; } r->aif = aif; /* parse ATM stuff */ #define GET3() (((sdl->sdl_data[n] & 0xff) << 16) | \ ((sdl->sdl_data[n + 1] & 0xff) << 8) | \ ((sdl->sdl_data[n + 2] & 0xff) << 0)) #define GET2() (((sdl->sdl_data[n] & 0xff) << 8) | \ ((sdl->sdl_data[n + 1] & 0xff) << 0)) #define GET1() (((sdl->sdl_data[n] & 0xff) << 0)) n = sdl->sdl_nlen; if (sdl->sdl_alen < 4) { warnx("RTA_GATEWAY alen too short"); goto fail; } r->llcsnap = GET1() & ATM_PH_LLCSNAP; n++; r->vpi = GET1(); n++; r->vci = GET2(); n += 2; if (sdl->sdl_alen == 4) { /* old address */ r->traffic = ATMIO_TRAFFIC_UBR; r->pcr = 0; break; } /* new address */ r->traffic = GET1(); n++; switch (r->traffic) { case ATMIO_TRAFFIC_UBR: if (sdl->sdl_alen >= 5 + 3) { r->pcr = GET3(); n += 3; } else r->pcr = 0; break; case ATMIO_TRAFFIC_CBR: if (sdl->sdl_alen < 5 + 3) { warnx("CBR address too short"); goto fail; } r->pcr = GET3(); n += 3; break; case ATMIO_TRAFFIC_VBR: if (sdl->sdl_alen < 5 + 3 * 3) { warnx("VBR address too short"); goto fail; } r->pcr = GET3(); n += 3; r->scr = GET3(); n += 3; r->mbs = GET3(); n += 3; break; case ATMIO_TRAFFIC_ABR: if (sdl->sdl_alen < 5 + 4 * 3 + 2 + 1 * 2 + 3) { warnx("ABR address too short"); goto fail; } r->pcr = GET3(); n += 3; r->mcr = GET3(); n += 3; r->icr = GET3(); n += 3; r->tbe = GET3(); n += 3; r->nrm = GET1(); n++; r->trm = GET1(); n++; r->adtf = GET2(); n += 2; r->rif = GET1(); n++; r->rdf = GET1(); n++; r->cdf = GET1(); n++; break; default: goto fail; } break; } } }
static int set_start_bits(const pcre_uchar *code, pcre_uint8 *start_bits, BOOL utf, compile_data *cd) { register pcre_uint32 c; int yield = SSB_DONE; #if defined SUPPORT_UTF && defined COMPILE_PCRE8 int table_limit = utf? 16:32; #else int table_limit = 32; #endif #if 0 /* ========================================================================= */ /* The following comment and code was inserted in January 1999. In May 2006, when it was observed to cause compiler warnings about unused values, I took it out again. If anybody is still using OS/2, they will have to put it back manually. */ /* This next statement and the later reference to dummy are here in order to trick the optimizer of the IBM C compiler for OS/2 into generating correct code. Apparently IBM isn't going to fix the problem, and we would rather not disable optimization (in this module it actually makes a big difference, and the pcre module can use all the optimization it can get). */ volatile int dummy; /* ========================================================================= */ #endif do { BOOL try_next = TRUE; const pcre_uchar *tcode = code + 1 + LINK_SIZE; if (*code == OP_CBRA || *code == OP_SCBRA || *code == OP_CBRAPOS || *code == OP_SCBRAPOS) tcode += IMM2_SIZE; while (try_next) /* Loop for items in this branch */ { int rc; switch(*tcode) { /* If we reach something we don't understand, it means a new opcode has been created that hasn't been added to this code. Hopefully this problem will be discovered during testing. */ default: return SSB_UNKNOWN; /* Fail for a valid opcode that implies no starting bits. */ case OP_ACCEPT: case OP_ASSERT_ACCEPT: case OP_ALLANY: case OP_ANY: case OP_ANYBYTE: case OP_CIRC: case OP_CIRCM: case OP_CLOSE: case OP_COMMIT: case OP_COND: case OP_CREF: case OP_DEF: case OP_DNCREF: case OP_DNREF: case OP_DNREFI: case OP_DNRREF: case OP_DOLL: case OP_DOLLM: case OP_END: case OP_EOD: case OP_EODN: case OP_EXTUNI: case OP_FAIL: case OP_MARK: case OP_NOT: case OP_NOTEXACT: case OP_NOTEXACTI: case OP_NOTI: case OP_NOTMINPLUS: case OP_NOTMINPLUSI: case OP_NOTMINQUERY: case OP_NOTMINQUERYI: case OP_NOTMINSTAR: case OP_NOTMINSTARI: case OP_NOTMINUPTO: case OP_NOTMINUPTOI: case OP_NOTPLUS: case OP_NOTPLUSI: case OP_NOTPOSPLUS: case OP_NOTPOSPLUSI: case OP_NOTPOSQUERY: case OP_NOTPOSQUERYI: case OP_NOTPOSSTAR: case OP_NOTPOSSTARI: case OP_NOTPOSUPTO: case OP_NOTPOSUPTOI: case OP_NOTPROP: case OP_NOTQUERY: case OP_NOTQUERYI: case OP_NOTSTAR: case OP_NOTSTARI: case OP_NOTUPTO: case OP_NOTUPTOI: case OP_NOT_HSPACE: case OP_NOT_VSPACE: case OP_PRUNE: case OP_PRUNE_ARG: case OP_RECURSE: case OP_REF: case OP_REFI: case OP_REVERSE: case OP_RREF: case OP_SCOND: case OP_SET_SOM: case OP_SKIP: case OP_SKIP_ARG: case OP_SOD: case OP_SOM: case OP_THEN: case OP_THEN_ARG: return SSB_FAIL; /* A "real" property test implies no starting bits, but the fake property PT_CLIST identifies a list of characters. These lists are short, as they are used for characters with more than one "other case", so there is no point in recognizing them for OP_NOTPROP. */ case OP_PROP: if (tcode[1] != PT_CLIST) return SSB_FAIL; { const pcre_uint32 *p = PRIV(ucd_caseless_sets) + tcode[2]; while ((c = *p++) < NOTACHAR) { #if defined SUPPORT_UTF && defined COMPILE_PCRE8 if (utf) { pcre_uchar buff[6]; (void)PRIV(ord2utf)(c, buff); c = buff[0]; } #endif if (c > 0xff) SET_BIT(0xff); else SET_BIT(c); } } try_next = FALSE; break; /* We can ignore word boundary tests. */ case OP_WORD_BOUNDARY: case OP_NOT_WORD_BOUNDARY: tcode++; break; /* If we hit a bracket or a positive lookahead assertion, recurse to set bits from within the subpattern. If it can't find anything, we have to give up. If it finds some mandatory character(s), we are done for this branch. Otherwise, carry on scanning after the subpattern. */ case OP_BRA: case OP_SBRA: case OP_CBRA: case OP_SCBRA: case OP_BRAPOS: case OP_SBRAPOS: case OP_CBRAPOS: case OP_SCBRAPOS: case OP_ONCE: case OP_ONCE_NC: case OP_ASSERT: rc = set_start_bits(tcode, start_bits, utf, cd); if (rc == SSB_FAIL || rc == SSB_UNKNOWN) return rc; if (rc == SSB_DONE) try_next = FALSE; else { do tcode += GET(tcode, 1); while (*tcode == OP_ALT); tcode += 1 + LINK_SIZE; } break; /* If we hit ALT or KET, it means we haven't found anything mandatory in this branch, though we might have found something optional. For ALT, we continue with the next alternative, but we have to arrange that the final result from subpattern is SSB_CONTINUE rather than SSB_DONE. For KET, return SSB_CONTINUE: if this is the top level, that indicates failure, but after a nested subpattern, it causes scanning to continue. */ case OP_ALT: yield = SSB_CONTINUE; try_next = FALSE; break; case OP_KET: case OP_KETRMAX: case OP_KETRMIN: case OP_KETRPOS: return SSB_CONTINUE; /* Skip over callout */ case OP_CALLOUT: tcode += 2 + 2*LINK_SIZE; break; /* Skip over lookbehind and negative lookahead assertions */ case OP_ASSERT_NOT: case OP_ASSERTBACK: case OP_ASSERTBACK_NOT: do tcode += GET(tcode, 1); while (*tcode == OP_ALT); tcode += 1 + LINK_SIZE; break; /* BRAZERO does the bracket, but carries on. */ case OP_BRAZERO: case OP_BRAMINZERO: case OP_BRAPOSZERO: rc = set_start_bits(++tcode, start_bits, utf, cd); if (rc == SSB_FAIL || rc == SSB_UNKNOWN) return rc; /* ========================================================================= See the comment at the head of this function concerning the next line, which was an old fudge for the benefit of OS/2. dummy = 1; ========================================================================= */ do tcode += GET(tcode,1); while (*tcode == OP_ALT); tcode += 1 + LINK_SIZE; break; /* SKIPZERO skips the bracket. */ case OP_SKIPZERO: tcode++; do tcode += GET(tcode,1); while (*tcode == OP_ALT); tcode += 1 + LINK_SIZE; break; /* Single-char * or ? sets the bit and tries the next item */ case OP_STAR: case OP_MINSTAR: case OP_POSSTAR: case OP_QUERY: case OP_MINQUERY: case OP_POSQUERY: tcode = set_table_bit(start_bits, tcode + 1, FALSE, cd, utf); break; case OP_STARI: case OP_MINSTARI: case OP_POSSTARI: case OP_QUERYI: case OP_MINQUERYI: case OP_POSQUERYI: tcode = set_table_bit(start_bits, tcode + 1, TRUE, cd, utf); break; /* Single-char upto sets the bit and tries the next */ case OP_UPTO: case OP_MINUPTO: case OP_POSUPTO: tcode = set_table_bit(start_bits, tcode + 1 + IMM2_SIZE, FALSE, cd, utf); break; case OP_UPTOI: case OP_MINUPTOI: case OP_POSUPTOI: tcode = set_table_bit(start_bits, tcode + 1 + IMM2_SIZE, TRUE, cd, utf); break; /* At least one single char sets the bit and stops */ case OP_EXACT: tcode += IMM2_SIZE; /* Fall through */ case OP_CHAR: case OP_PLUS: case OP_MINPLUS: case OP_POSPLUS: (void)set_table_bit(start_bits, tcode + 1, FALSE, cd, utf); try_next = FALSE; break; case OP_EXACTI: tcode += IMM2_SIZE; /* Fall through */ case OP_CHARI: case OP_PLUSI: case OP_MINPLUSI: case OP_POSPLUSI: (void)set_table_bit(start_bits, tcode + 1, TRUE, cd, utf); try_next = FALSE; break; /* Special spacing and line-terminating items. These recognize specific lists of characters. The difference between VSPACE and ANYNL is that the latter can match the two-character CRLF sequence, but that is not relevant for finding the first character, so their code here is identical. */ case OP_HSPACE: SET_BIT(CHAR_HT); SET_BIT(CHAR_SPACE); #ifdef SUPPORT_UTF if (utf) { #ifdef COMPILE_PCRE8 SET_BIT(0xC2); /* For U+00A0 */ SET_BIT(0xE1); /* For U+1680, U+180E */ SET_BIT(0xE2); /* For U+2000 - U+200A, U+202F, U+205F */ SET_BIT(0xE3); /* For U+3000 */ #elif defined COMPILE_PCRE16 || defined COMPILE_PCRE32 SET_BIT(0xA0); SET_BIT(0xFF); /* For characters > 255 */ #endif /* COMPILE_PCRE[8|16|32] */ } else #endif /* SUPPORT_UTF */ { #ifndef EBCDIC SET_BIT(0xA0); #endif /* Not EBCDIC */ #if defined COMPILE_PCRE16 || defined COMPILE_PCRE32 SET_BIT(0xFF); /* For characters > 255 */ #endif /* COMPILE_PCRE[16|32] */ } try_next = FALSE; break; case OP_ANYNL: case OP_VSPACE: SET_BIT(CHAR_LF); SET_BIT(CHAR_VT); SET_BIT(CHAR_FF); SET_BIT(CHAR_CR); #ifdef SUPPORT_UTF if (utf) { #ifdef COMPILE_PCRE8 SET_BIT(0xC2); /* For U+0085 */ SET_BIT(0xE2); /* For U+2028, U+2029 */ #elif defined COMPILE_PCRE16 || defined COMPILE_PCRE32 SET_BIT(CHAR_NEL); SET_BIT(0xFF); /* For characters > 255 */ #endif /* COMPILE_PCRE[8|16|32] */ } else #endif /* SUPPORT_UTF */ { SET_BIT(CHAR_NEL); #if defined COMPILE_PCRE16 || defined COMPILE_PCRE32 SET_BIT(0xFF); /* For characters > 255 */ #endif } try_next = FALSE; break; /* Single character types set the bits and stop. Note that if PCRE_UCP is set, we do not see these op codes because \d etc are converted to properties. Therefore, these apply in the case when only characters less than 256 are recognized to match the types. */ case OP_NOT_DIGIT: set_nottype_bits(start_bits, cbit_digit, table_limit, cd); try_next = FALSE; break; case OP_DIGIT: set_type_bits(start_bits, cbit_digit, table_limit, cd); try_next = FALSE; break; /* The cbit_space table has vertical tab as whitespace; we no longer have to play fancy tricks because Perl added VT to its whitespace at release 5.18. PCRE added it at release 8.34. */ case OP_NOT_WHITESPACE: set_nottype_bits(start_bits, cbit_space, table_limit, cd); try_next = FALSE; break; case OP_WHITESPACE: set_type_bits(start_bits, cbit_space, table_limit, cd); try_next = FALSE; break; case OP_NOT_WORDCHAR: set_nottype_bits(start_bits, cbit_word, table_limit, cd); try_next = FALSE; break; case OP_WORDCHAR: set_type_bits(start_bits, cbit_word, table_limit, cd); try_next = FALSE; break; /* One or more character type fudges the pointer and restarts, knowing it will hit a single character type and stop there. */ case OP_TYPEPLUS: case OP_TYPEMINPLUS: case OP_TYPEPOSPLUS: tcode++; break; case OP_TYPEEXACT: tcode += 1 + IMM2_SIZE; break; /* Zero or more repeats of character types set the bits and then try again. */ case OP_TYPEUPTO: case OP_TYPEMINUPTO: case OP_TYPEPOSUPTO: tcode += IMM2_SIZE; /* Fall through */ case OP_TYPESTAR: case OP_TYPEMINSTAR: case OP_TYPEPOSSTAR: case OP_TYPEQUERY: case OP_TYPEMINQUERY: case OP_TYPEPOSQUERY: switch(tcode[1]) { default: case OP_ANY: case OP_ALLANY: return SSB_FAIL; case OP_HSPACE: SET_BIT(CHAR_HT); SET_BIT(CHAR_SPACE); #ifdef SUPPORT_UTF if (utf) { #ifdef COMPILE_PCRE8 SET_BIT(0xC2); /* For U+00A0 */ SET_BIT(0xE1); /* For U+1680, U+180E */ SET_BIT(0xE2); /* For U+2000 - U+200A, U+202F, U+205F */ SET_BIT(0xE3); /* For U+3000 */ #elif defined COMPILE_PCRE16 || defined COMPILE_PCRE32 SET_BIT(0xA0); SET_BIT(0xFF); /* For characters > 255 */ #endif /* COMPILE_PCRE[8|16|32] */ } else #endif /* SUPPORT_UTF */ #ifndef EBCDIC SET_BIT(0xA0); #endif /* Not EBCDIC */ break; case OP_ANYNL: case OP_VSPACE: SET_BIT(CHAR_LF); SET_BIT(CHAR_VT); SET_BIT(CHAR_FF); SET_BIT(CHAR_CR); #ifdef SUPPORT_UTF if (utf) { #ifdef COMPILE_PCRE8 SET_BIT(0xC2); /* For U+0085 */ SET_BIT(0xE2); /* For U+2028, U+2029 */ #elif defined COMPILE_PCRE16 || defined COMPILE_PCRE32 SET_BIT(CHAR_NEL); SET_BIT(0xFF); /* For characters > 255 */ #endif /* COMPILE_PCRE16 */ } else #endif /* SUPPORT_UTF */ SET_BIT(CHAR_NEL); break; case OP_NOT_DIGIT: set_nottype_bits(start_bits, cbit_digit, table_limit, cd); break; case OP_DIGIT: set_type_bits(start_bits, cbit_digit, table_limit, cd); break; /* The cbit_space table has vertical tab as whitespace; we no longer have to play fancy tricks because Perl added VT to its whitespace at release 5.18. PCRE added it at release 8.34. */ case OP_NOT_WHITESPACE: set_nottype_bits(start_bits, cbit_space, table_limit, cd); break; case OP_WHITESPACE: set_type_bits(start_bits, cbit_space, table_limit, cd); break; case OP_NOT_WORDCHAR: set_nottype_bits(start_bits, cbit_word, table_limit, cd); break; case OP_WORDCHAR: set_type_bits(start_bits, cbit_word, table_limit, cd); break; } tcode += 2; break; /* Character class where all the information is in a bit map: set the bits and either carry on or not, according to the repeat count. If it was a negative class, and we are operating with UTF-8 characters, any byte with a value >= 0xc4 is a potentially valid starter because it starts a character with a value > 255. */ #if defined SUPPORT_UTF || !defined COMPILE_PCRE8 case OP_XCLASS: if ((tcode[1 + LINK_SIZE] & XCL_HASPROP) != 0) return SSB_FAIL; /* All bits are set. */ if ((tcode[1 + LINK_SIZE] & XCL_MAP) == 0 && (tcode[1 + LINK_SIZE] & XCL_NOT) != 0) return SSB_FAIL; #endif /* Fall through */ case OP_NCLASS: #if defined SUPPORT_UTF && defined COMPILE_PCRE8 if (utf) { start_bits[24] |= 0xf0; /* Bits for 0xc4 - 0xc8 */ memset(start_bits+25, 0xff, 7); /* Bits for 0xc9 - 0xff */ } #endif #if defined COMPILE_PCRE16 || defined COMPILE_PCRE32 SET_BIT(0xFF); /* For characters > 255 */ #endif /* Fall through */ case OP_CLASS: { pcre_uint8 *map; #if defined SUPPORT_UTF || !defined COMPILE_PCRE8 map = NULL; if (*tcode == OP_XCLASS) { if ((tcode[1 + LINK_SIZE] & XCL_MAP) != 0) map = (pcre_uint8 *)(tcode + 1 + LINK_SIZE + 1); tcode += GET(tcode, 1); } else #endif { tcode++; map = (pcre_uint8 *)tcode; tcode += 32 / sizeof(pcre_uchar); } /* In UTF-8 mode, the bits in a bit map correspond to character values, not to byte values. However, the bit map we are constructing is for byte values. So we have to do a conversion for characters whose value is > 127. In fact, there are only two possible starting bytes for characters in the range 128 - 255. */ #if defined SUPPORT_UTF || !defined COMPILE_PCRE8 if (map != NULL) #endif { #if defined SUPPORT_UTF && defined COMPILE_PCRE8 if (utf) { for (c = 0; c < 16; c++) start_bits[c] |= map[c]; for (c = 128; c < 256; c++) { if ((map[c/8] & (1 << (c&7))) != 0) { int d = (c >> 6) | 0xc0; /* Set bit for this starter */ start_bits[d/8] |= (1 << (d&7)); /* and then skip on to the */ c = (c & 0xc0) + 0x40 - 1; /* next relevant character. */ } } } else #endif { /* In non-UTF-8 mode, the two bit maps are completely compatible. */ for (c = 0; c < 32; c++) start_bits[c] |= map[c]; } } /* Advance past the bit map, and act on what follows. For a zero minimum repeat, continue; otherwise stop processing. */ switch (*tcode) { case OP_CRSTAR: case OP_CRMINSTAR: case OP_CRQUERY: case OP_CRMINQUERY: case OP_CRPOSSTAR: case OP_CRPOSQUERY: tcode++; break; case OP_CRRANGE: case OP_CRMINRANGE: case OP_CRPOSRANGE: if (GET2(tcode, 1) == 0) tcode += 1 + 2 * IMM2_SIZE; else try_next = FALSE; break; default: try_next = FALSE; break; } } break; /* End of bitmap class handling */ } /* End of switch */ } /* End of try_next loop */