/* * The CMap data structure here is constructed on the fly by * adding simple range-to-range mappings. Then the data structure * is optimized to contain both range-to-range and range-to-table * lookups. * * Any one-to-many mappings are inserted as one-to-table * lookups in the beginning, and are not affected by the optimization * stage. * * There is a special function to add a 256-length range-to-table mapping. * The ranges do not have to be added in order. * * This code can be a lot simpler if we don't care about wasting memory, * or can trust the parser to give us optimal mappings. */ #include "fitz.h" #include "mupdf.h" /* Macros for accessing the combined extent_flags field */ #define pdf_range_high(r) ((r)->low + ((r)->extent_flags >> 2)) #define pdf_range_flags(r) ((r)->extent_flags & 3) #define pdf_range_set_high(r, h) ((r)->extent_flags = (((r)->extent_flags & 3) | ((h - (r)->low) << 2))) #define pdf_range_set_flags(r, f) ((r)->extent_flags = (((r)->extent_flags & ~3) | f)) /* * Allocate, destroy and simple parameters. */ pdf_cmap * pdf_new_cmap(void) { pdf_cmap *cmap; cmap = fz_malloc(sizeof(pdf_cmap)); cmap->refs = 1; strcpy(cmap->cmap_name, ""); strcpy(cmap->usecmap_name, ""); cmap->usecmap = NULL; cmap->wmode = 0; cmap->codespace_len = 0; cmap->rlen = 0; cmap->rcap = 0; cmap->ranges = NULL; cmap->tlen = 0; cmap->tcap = 0; cmap->table = NULL; return cmap; } pdf_cmap * pdf_keep_cmap(pdf_cmap *cmap) { if (cmap->refs >= 0) cmap->refs ++; return cmap; } void pdf_drop_cmap(pdf_cmap *cmap) { if (cmap->refs >= 0) { if (--cmap->refs == 0) { if (cmap->usecmap) pdf_drop_cmap(cmap->usecmap); fz_free(cmap->ranges); fz_free(cmap->table); fz_free(cmap); } } } void pdf_set_usecmap(pdf_cmap *cmap, pdf_cmap *usecmap) { int i; if (cmap->usecmap) pdf_drop_cmap(cmap->usecmap); cmap->usecmap = pdf_keep_cmap(usecmap); if (cmap->codespace_len == 0) { cmap->codespace_len = usecmap->codespace_len; for (i = 0; i < usecmap->codespace_len; i++) cmap->codespace[i] = usecmap->codespace[i]; } } int pdf_get_wmode(pdf_cmap *cmap) { return cmap->wmode; } void pdf_set_wmode(pdf_cmap *cmap, int wmode) { cmap->wmode = wmode; } void pdf_debug_cmap(pdf_cmap *cmap) { int i, k, n; printf("cmap $%p /%s {\n", (void *) cmap, cmap->cmap_name); if (cmap->usecmap_name[0]) printf("\tusecmap /%s\n", cmap->usecmap_name); if (cmap->usecmap) printf("\tusecmap $%p\n", (void *) cmap->usecmap); printf("\twmode %d\n", cmap->wmode); printf("\tcodespaces {\n"); for (i = 0; i < cmap->codespace_len; i++) { printf("\t\t<%x> <%x>\n", cmap->codespace[i].low, cmap->codespace[i].high); } printf("\t}\n"); printf("\tranges (%d,%d) {\n", cmap->rlen, cmap->tlen); for (i = 0; i < cmap->rlen; i++) { pdf_range *r = &cmap->ranges[i]; printf("\t\t<%04x> <%04x> ", r->low, pdf_range_high(r)); if (pdf_range_flags(r) == PDF_CMAP_TABLE) { printf("[ "); for (k = 0; k < pdf_range_high(r) - r->low + 1; k++) printf("%d ", cmap->table[r->offset + k]); printf("]\n"); } else if (pdf_range_flags(r) == PDF_CMAP_MULTI) { printf("< "); n = cmap->table[r->offset]; for (k = 0; k < n; k++) printf("%04x ", cmap->table[r->offset + 1 + k]); printf(">\n"); } else printf("%d\n", r->offset); } printf("\t}\n}\n"); } /* * Add a codespacerange section. * These ranges are used by pdf_decode_cmap to decode * multi-byte encoded strings. */ void pdf_add_codespace(pdf_cmap *cmap, int low, int high, int n) { if (cmap->codespace_len + 1 == nelem(cmap->codespace)) { fz_warn("assert: too many code space ranges"); return; } cmap->codespace[cmap->codespace_len].n = n; cmap->codespace[cmap->codespace_len].low = low; cmap->codespace[cmap->codespace_len].high = high; cmap->codespace_len ++; } /* * Add an integer to the table. */ static void add_table(pdf_cmap *cmap, int value) { if (cmap->tlen + 1 > cmap->tcap) { cmap->tcap = cmap->tcap > 1 ? (cmap->tcap * 3) / 2 : 256; cmap->table = fz_realloc(cmap->table, cmap->tcap, sizeof(unsigned short)); } cmap->table[cmap->tlen++] = value; } /* * Add a range. */ static void add_range(pdf_cmap *cmap, int low, int high, int flag, int offset) { /* If the range is too large to be represented, split it */ if (high - low > 0x3fff) { add_range(cmap, low, low+0x3fff, flag, offset); add_range(cmap, low+0x3fff, high, flag, offset+0x3fff); return; } if (cmap->rlen + 1 > cmap->rcap) { cmap->rcap = cmap->rcap > 1 ? (cmap->rcap * 3) / 2 : 256; cmap->ranges = fz_realloc(cmap->ranges, cmap->rcap, sizeof(pdf_range)); } cmap->ranges[cmap->rlen].low = low; pdf_range_set_high(&cmap->ranges[cmap->rlen], high); pdf_range_set_flags(&cmap->ranges[cmap->rlen], flag); cmap->ranges[cmap->rlen].offset = offset; cmap->rlen ++; } /* * Add a range-to-table mapping. */ void pdf_map_range_to_table(pdf_cmap *cmap, int low, int *table, int len) { int i; int high = low + len; int offset = cmap->tlen; for (i = 0; i < len; i++) add_table(cmap, table[i]); add_range(cmap, low, high, PDF_CMAP_TABLE, offset); } /* * Add a range of contiguous one-to-one mappings (ie 1..5 maps to 21..25) */ void pdf_map_range_to_range(pdf_cmap *cmap, int low, int high, int offset) { add_range(cmap, low, high, high - low == 0 ? PDF_CMAP_SINGLE : PDF_CMAP_RANGE, offset); } /* * Add a single one-to-many mapping. */ void pdf_map_one_to_many(pdf_cmap *cmap, int low, int *values, int len) { int offset, i; if (len == 1) { add_range(cmap, low, low, PDF_CMAP_SINGLE, values[0]); return; } if (len > 8) { fz_warn("one to many mapping is too large (%d); truncating", len); len = 8; } offset = cmap->tlen; add_table(cmap, len); for (i = 0; i < len; i++) add_table(cmap, values[i]); add_range(cmap, low, low, PDF_CMAP_MULTI, offset); } /* * Sort the input ranges. * Merge contiguous input ranges to range-to-range if the output is contiguous. * Merge contiguous input ranges to range-to-table if the output is random. */ static int cmprange(const void *va, const void *vb) { return ((const pdf_range*)va)->low - ((const pdf_range*)vb)->low; } void pdf_sort_cmap(pdf_cmap *cmap) { pdf_range *a; /* last written range on output */ pdf_range *b; /* current range examined on input */ if (cmap->rlen == 0) return; qsort(cmap->ranges, cmap->rlen, sizeof(pdf_range), cmprange); a = cmap->ranges; b = cmap->ranges + 1; while (b < cmap->ranges + cmap->rlen) { /* ignore one-to-many mappings */ if (pdf_range_flags(b) == PDF_CMAP_MULTI) { *(++a) = *b; } /* input contiguous */ else if (pdf_range_high(a) + 1 == b->low) { /* output contiguous */ if (pdf_range_high(a) - a->low + a->offset + 1 == b->offset) { /* SR -> R and SS -> R and RR -> R and RS -> R */ if (pdf_range_flags(a) == PDF_CMAP_SINGLE || pdf_range_flags(a) == PDF_CMAP_RANGE) { pdf_range_set_flags(a, PDF_CMAP_RANGE); pdf_range_set_high(a, pdf_range_high(b)); } /* LS -> L */ else if (pdf_range_flags(a) == PDF_CMAP_TABLE && pdf_range_flags(b) == PDF_CMAP_SINGLE) { pdf_range_set_high(a, pdf_range_high(b)); add_table(cmap, b->offset); } /* LR -> LR */ else if (pdf_range_flags(a) == PDF_CMAP_TABLE && pdf_range_flags(b) == PDF_CMAP_RANGE) { *(++a) = *b; } /* XX -> XX */ else { *(++a) = *b; } } /* output separated */ else { /* SS -> L */ if (pdf_range_flags(a) == PDF_CMAP_SINGLE && pdf_range_flags(b) == PDF_CMAP_SINGLE) { pdf_range_set_flags(a, PDF_CMAP_TABLE); pdf_range_set_high(a, pdf_range_high(b)); add_table(cmap, a->offset); add_table(cmap, b->offset); a->offset = cmap->tlen - 2; } /* LS -> L */ else if (pdf_range_flags(a) == PDF_CMAP_TABLE && pdf_range_flags(b) == PDF_CMAP_SINGLE) { pdf_range_set_high(a, pdf_range_high(b)); add_table(cmap, b->offset); } /* XX -> XX */ else { *(++a) = *b; } } } /* input separated: XX -> XX */ else { *(++a) = *b; } b ++; } } /* * Lookup the mapping of a codepoint. */ int pdf_lookup_cmap(pdf_cmap *cmap, int cpt) { int l = 0; int r = cmap->rlen - 1; int m; while (l <= r) { m = (l + r) >> 1; if (cpt < cmap->ranges[m].low) r = m - 1; else if (cpt > pdf_range_high(&cmap->ranges[m])) l = m + 1; else { int i = cpt - cmap->ranges[m].low + cmap->ranges[m].offset; if (pdf_range_flags(&cmap->ranges[m]) == PDF_CMAP_TABLE) return cmap->table[i]; if (pdf_range_flags(&cmap->ranges[m]) == PDF_CMAP_MULTI) return cmap->table[cmap->ranges[m].offset + 1]; /* first char */ return i; } } if (cmap->usecmap) return pdf_lookup_cmap(cmap->usecmap, cpt); return -1; } int pdf_lookup_cmap_full(pdf_cmap *cmap, int cpt, int *out) { int i, k, n; int l = 0; int r = cmap->rlen - 1; int m; while (l <= r) { m = (l + r) >> 1; if (cpt < cmap->ranges[m].low) r = m - 1; else if (cpt > pdf_range_high(&cmap->ranges[m])) l = m + 1; else { k = cpt - cmap->ranges[m].low + cmap->ranges[m].offset; if (pdf_range_flags(&cmap->ranges[m]) == PDF_CMAP_TABLE) { out[0] = cmap->table[k]; return 1; } else if (pdf_range_flags(&cmap->ranges[m]) == PDF_CMAP_MULTI) { n = cmap->ranges[m].offset; for (i = 0; i < cmap->table[n]; i++) out[i] = cmap->table[n + i + 1]; return cmap->table[n]; } else { out[0] = k; return 1; } } } if (cmap->usecmap) return pdf_lookup_cmap_full(cmap->usecmap, cpt, out); return 0; } /* * Use the codespace ranges to extract a codepoint from a * multi-byte encoded string. */ unsigned char * pdf_decode_cmap(pdf_cmap *cmap, unsigned char *buf, int *cpt) { int k, n, c; c = 0; for (n = 0; n < 4; n++) { c = (c << 8) | buf[n]; for (k = 0; k < cmap->codespace_len; k++) { if (cmap->codespace[k].n == n + 1) { if (c >= cmap->codespace[k].low && c <= cmap->codespace[k].high) { *cpt = c; return buf + n + 1; } } } } *cpt = 0; return buf + 1; }