#include "fitz.h" /* Pretend we have a filter that just copies data forever */ fz_stream * fz_open_copy(fz_stream *chain) { return fz_keep_stream(chain); } /* Null filter copies a specified amount of data */ struct null_filter { fz_stream *chain; int remain; }; static int read_null(fz_stream *stm, unsigned char *buf, int len) { struct null_filter *state = stm->state; int amount = MIN(len, state->remain); int n = fz_read(state->chain, buf, amount); if (n < 0) return fz_rethrow(n, "read error in null filter"); state->remain -= n; return n; } static void close_null(fz_stream *stm) { struct null_filter *state = stm->state; fz_close(state->chain); fz_free(state); } fz_stream * fz_open_null(fz_stream *chain, int len) { struct null_filter *state; state = fz_malloc(sizeof(struct null_filter)); state->chain = chain; state->remain = len; return fz_new_stream(state, read_null, close_null); } /* ASCII Hex Decode */ typedef struct fz_ahxd_s fz_ahxd; struct fz_ahxd_s { fz_stream *chain; int eod; }; static inline int iswhite(int a) { switch (a) { case '\n': case '\r': case '\t': case ' ': case '\0': case '\f': case '\b': case 0177: return 1; } return 0; } static inline int ishex(int a) { return (a >= 'A' && a <= 'F') || (a >= 'a' && a <= 'f') || (a >= '0' && a <= '9'); } static inline int from_hex(int a) { if (a >= 'A' && a <= 'F') return a - 'A' + 0xA; if (a >= 'a' && a <= 'f') return a - 'a' + 0xA; if (a >= '0' && a <= '9') return a - '0'; return 0; } static int read_ahxd(fz_stream *stm, unsigned char *buf, int len) { fz_ahxd *state = stm->state; unsigned char *p = buf; unsigned char *ep = buf + len; int a, b, c, odd; odd = 0; while (p < ep) { if (state->eod) return p - buf; c = fz_read_byte(state->chain); if (c < 0) return p - buf; if (ishex(c)) { if (!odd) { a = from_hex(c); odd = 1; } else { b = from_hex(c); *p++ = (a << 4) | b; odd = 0; } } else if (c == '>') { if (odd) *p++ = (a << 4); state->eod = 1; } else if (!iswhite(c)) { return fz_throw("bad data in ahxd: '%c'", c); } } return p - buf; } static void close_ahxd(fz_stream *stm) { fz_ahxd *state = stm->state; fz_close(state->chain); fz_free(state); } fz_stream * fz_open_ahxd(fz_stream *chain) { fz_ahxd *state; state = fz_malloc(sizeof(fz_ahxd)); state->chain = chain; state->eod = 0; return fz_new_stream(state, read_ahxd, close_ahxd); } /* ASCII 85 Decode */ typedef struct fz_a85d_s fz_a85d; struct fz_a85d_s { fz_stream *chain; unsigned char bp[4]; unsigned char *rp, *wp; int eod; }; static int read_a85d(fz_stream *stm, unsigned char *buf, int len) { fz_a85d *state = stm->state; unsigned char *p = buf; unsigned char *ep = buf + len; int count = 0; int word = 0; int c; while (state->rp < state->wp && p < ep) *p++ = *state->rp++; while (p < ep) { if (state->eod) return p - buf; c = fz_read_byte(state->chain); if (c < 0) return p - buf; if (c >= '!' && c <= 'u') { if (count == 4) { word = word * 85 + (c - '!'); state->bp[0] = (word >> 24) & 0xff; state->bp[1] = (word >> 16) & 0xff; state->bp[2] = (word >> 8) & 0xff; state->bp[3] = (word) & 0xff; state->rp = state->bp; state->wp = state->bp + 4; word = 0; count = 0; } else { word = word * 85 + (c - '!'); count ++; } } else if (c == 'z' && count == 0) { state->bp[0] = 0; state->bp[1] = 0; state->bp[2] = 0; state->bp[3] = 0; state->rp = state->bp; state->wp = state->bp + 4; } else if (c == '~') { c = fz_read_byte(state->chain); if (c != '>') fz_warn("bad eod marker in a85d"); switch (count) { case 0: break; case 1: return fz_throw("partial final byte in a85d"); case 2: word = word * (85 * 85 * 85) + 0xffffff; state->bp[0] = word >> 24; state->rp = state->bp; state->wp = state->bp + 1; break; case 3: word = word * (85 * 85) + 0xffff; state->bp[0] = word >> 24; state->bp[1] = word >> 16; state->rp = state->bp; state->wp = state->bp + 2; break; case 4: word = word * 85 + 0xff; state->bp[0] = word >> 24; state->bp[1] = word >> 16; state->bp[2] = word >> 8; state->rp = state->bp; state->wp = state->bp + 3; break; } state->eod = 1; } else if (!iswhite(c)) { return fz_throw("bad data in a85d: '%c'", c); } while (state->rp < state->wp && p < ep) *p++ = *state->rp++; } return p - buf; } static void close_a85d(fz_stream *stm) { fz_a85d *state = stm->state; fz_close(state->chain); fz_free(state); } fz_stream * fz_open_a85d(fz_stream *chain) { fz_a85d *state; state = fz_malloc(sizeof(fz_a85d)); state->chain = chain; state->rp = state->bp; state->wp = state->bp; state->eod = 0; return fz_new_stream(state, read_a85d, close_a85d); } /* Run Length Decode */ typedef struct fz_rld_s fz_rld; struct fz_rld_s { fz_stream *chain; int run, n, c; }; static int read_rld(fz_stream *stm, unsigned char *buf, int len) { fz_rld *state = stm->state; unsigned char *p = buf; unsigned char *ep = buf + len; while (p < ep) { if (state->run == 128) return p - buf; if (state->n == 0) { state->run = fz_read_byte(state->chain); if (state->run < 0) state->run = 128; if (state->run < 128) state->n = state->run + 1; if (state->run > 128) { state->n = 257 - state->run; state->c = fz_read_byte(state->chain); if (state->c < 0) return fz_throw("premature end of data in run length decode"); } } if (state->run < 128) { while (p < ep && state->n) { int c = fz_read_byte(state->chain); if (c < 0) return fz_throw("premature end of data in run length decode"); *p++ = c; state->n--; } } if (state->run > 128) { while (p < ep && state->n) { *p++ = state->c; state->n--; } } } return p - buf; } static void close_rld(fz_stream *stm) { fz_rld *state = stm->state; fz_close(state->chain); fz_free(state); } fz_stream * fz_open_rld(fz_stream *chain) { fz_rld *state; state = fz_malloc(sizeof(fz_rld)); state->chain = chain; state->run = 0; state->n = 0; state->c = 0; return fz_new_stream(state, read_rld, close_rld); } /* RC4 Filter */ typedef struct fz_arc4c_s fz_arc4c; struct fz_arc4c_s { fz_stream *chain; fz_arc4 arc4; }; static int read_arc4(fz_stream *stm, unsigned char *buf, int len) { fz_arc4c *state = stm->state; int n; n = fz_read(state->chain, buf, len); if (n < 0) return fz_rethrow(n, "read error in arc4 filter"); fz_arc4_encrypt(&state->arc4, buf, buf, n); return n; } static void close_arc4(fz_stream *stm) { fz_arc4c *state = stm->state; fz_close(state->chain); fz_free(state); } fz_stream * fz_open_arc4(fz_stream *chain, unsigned char *key, unsigned keylen) { fz_arc4c *state; state = fz_malloc(sizeof(fz_arc4c)); state->chain = chain; fz_arc4_init(&state->arc4, key, keylen); return fz_new_stream(state, read_arc4, close_arc4); } /* AES Filter */ typedef struct fz_aesd_s fz_aesd; struct fz_aesd_s { fz_stream *chain; fz_aes aes; unsigned char iv[16]; int ivcount; unsigned char bp[16]; unsigned char *rp, *wp; }; static int read_aesd(fz_stream *stm, unsigned char *buf, int len) { fz_aesd *state = stm->state; unsigned char *p = buf; unsigned char *ep = buf + len; while (state->ivcount < 16) { int c = fz_read_byte(state->chain); if (c < 0) return fz_throw("premature end in aes filter"); state->iv[state->ivcount++] = c; } while (state->rp < state->wp && p < ep) *p++ = *state->rp++; while (p < ep) { int n = fz_read(state->chain, state->bp, 16); if (n < 0) return fz_rethrow(n, "read error in aes filter"); else if (n == 0) return p - buf; else if (n < 16) return fz_throw("partial block in aes filter"); aes_crypt_cbc(&state->aes, AES_DECRYPT, 16, state->iv, state->bp, state->bp); state->rp = state->bp; state->wp = state->bp + 16; /* strip padding at end of file */ if (fz_is_eof(state->chain)) { int pad = state->bp[15]; if (pad < 1 || pad > 16) return fz_throw("aes padding out of range: %d", pad); state->wp -= pad; } while (state->rp < state->wp && p < ep) *p++ = *state->rp++; } return p - buf; } static void close_aesd(fz_stream *stm) { fz_aesd *state = stm->state; fz_close(state->chain); fz_free(state); } fz_stream * fz_open_aesd(fz_stream *chain, unsigned char *key, unsigned keylen) { fz_aesd *state; state = fz_malloc(sizeof(fz_aesd)); state->chain = chain; aes_setkey_dec(&state->aes, key, keylen * 8); state->ivcount = 0; state->rp = state->bp; state->wp = state->bp; return fz_new_stream(state, read_aesd, close_aesd); }