// // PDF value functions for PDFio. // // Copyright © 2021 by Michael R Sweet. // // Licensed under Apache License v2.0. See the file "LICENSE" for more // information. // // // Include necessary headers... // #include "pdfio-private.h" // // '_pdfioValueCopy()' - Copy a value to a PDF file. // _pdfio_value_t * _pdfioValueCopy(pdfio_file_t *pdfdst, // I - Destination PDF file _pdfio_value_t *vdst, // I - Destination value pdfio_file_t *pdfsrc, // I - Source PDF file _pdfio_value_t *vsrc) // I - Source value { pdfio_obj_t *obj; // Object reference #ifdef DEBUG static const char * const types[] = // Type strings for debug { "PDFIO_VALTYPE_NONE", "PDFIO_VALTYPE_ARRAY", "PDFIO_VALTYPE_BINARY", "PDFIO_VALTYPE_BOOLEAN", "PDFIO_VALTYPE_DATE", "PDFIO_VALTYPE_DICT", "PDFIO_VALTYPE_INDIRECT", "PDFIO_VALTYPE_NAME", "PDFIO_VALTYPE_NULL", "PDFIO_VALTYPE_NUMBER", "PDFIO_VALTYPE_STRING" }; #endif // DEBUG PDFIO_DEBUG("_pdfioValueCopy(pdfdst=%p, vdst=%p, pdfsrc=%p, vsrc=%p(%s))\n", pdfdst, vdst, pdfsrc, vsrc, types[vsrc->type]); if (pdfdst == pdfsrc && vsrc->type != PDFIO_VALTYPE_BINARY) { // For the same document we can copy the values without any other effort // unless there is a binary (hex string) value... *vdst = *vsrc; return (vdst); } // Not the same document or a binary value, do a deep copy... switch (vsrc->type) { case PDFIO_VALTYPE_INDIRECT : if ((obj = _pdfioFileFindMappedObj(pdfdst, pdfsrc, vsrc->value.indirect.number)) == NULL) { obj = pdfioObjCopy(pdfdst, pdfioFileFindObj(pdfsrc, vsrc->value.indirect.number)); } if (!obj) return (NULL); vdst->value.indirect.number = obj->number; vdst->value.indirect.generation = obj->generation; break; default : return (NULL); case PDFIO_VALTYPE_ARRAY : vdst->value.array = pdfioArrayCopy(pdfdst, vsrc->value.array); break; case PDFIO_VALTYPE_BINARY : if ((vdst->value.binary.data = (unsigned char *)malloc(vsrc->value.binary.datalen)) == NULL) { _pdfioFileError(pdfdst, "Unable to allocate memory for a binary string - %s", strerror(errno)); return (NULL); } vdst->value.binary.datalen = vsrc->value.binary.datalen; memcpy(vdst->value.binary.data, vsrc->value.binary.data, vdst->value.binary.datalen); break; case PDFIO_VALTYPE_BOOLEAN : case PDFIO_VALTYPE_DATE : case PDFIO_VALTYPE_NUMBER : *vdst = *vsrc; return (vdst); case PDFIO_VALTYPE_DICT : vdst->value.dict = pdfioDictCopy(pdfdst, vsrc->value.dict); break; case PDFIO_VALTYPE_NAME : case PDFIO_VALTYPE_STRING : vdst->value.name = pdfioStringCreate(pdfdst, vsrc->value.name); break; } vdst->type = vsrc->type; return (vdst); } // // '_pdfioValueDebug()' - Print the contents of a value. // void _pdfioValueDebug(_pdfio_value_t *v, // I - Value FILE *fp) // I - Output file { switch (v->type) { case PDFIO_VALTYPE_ARRAY : _pdfioArrayDebug(v->value.array, fp); break; case PDFIO_VALTYPE_BINARY : { size_t i; // Looping var unsigned char *ptr; // Pointer into data putc('<', fp); for (i = v->value.binary.datalen, ptr = v->value.binary.data; i > 0; i --, ptr ++) fprintf(fp, "%02X", *ptr); putc('>', fp); } break; case PDFIO_VALTYPE_BOOLEAN : fputs(v->value.boolean ? " true" : " false", fp); break; case PDFIO_VALTYPE_DATE : { struct tm dateval; // Date value #ifdef _WIN32 gmtime_s(&dateval, &v->value.date); #else gmtime_r(&v->value.date, &dateval); #endif // _WIN32 fprintf(fp, "(D:%04d%02d%02d%02d%02d%02dZ)", dateval.tm_year + 1900, dateval.tm_mon + 1, dateval.tm_mday, dateval.tm_hour, dateval.tm_min, dateval.tm_sec); } break; case PDFIO_VALTYPE_DICT : fputs("<<", fp); _pdfioDictDebug(v->value.dict, fp); fputs(">>", fp); break; case PDFIO_VALTYPE_INDIRECT : fprintf(fp, " %lu %u R", (unsigned long)v->value.indirect.number, v->value.indirect.generation); break; case PDFIO_VALTYPE_NAME : fprintf(fp, "/%s", v->value.name); break; case PDFIO_VALTYPE_NULL : fputs(" null", fp); break; case PDFIO_VALTYPE_NUMBER : fprintf(fp, " %g", v->value.number); break; case PDFIO_VALTYPE_STRING : fprintf(fp, "(%s)", v->value.string); break; default : break; } } // // '_pdfioValueDelete()' - Free the memory used by a value. // void _pdfioValueDelete(_pdfio_value_t *v) // I - Value { if (v->type == PDFIO_VALTYPE_BINARY) free(v->value.binary.data); } // // '_pdfioValueRead()' - Read a value from a file. // _pdfio_value_t * // O - Value or `NULL` on error/EOF _pdfioValueRead(pdfio_file_t *pdf, // I - PDF file pdfio_obj_t *obj, // I - Object, if any _pdfio_token_t *tb, // I - Token buffer/stack _pdfio_value_t *v, // I - Value size_t depth) // I - Depth of value { char token[32768]; // Token buffer #ifdef DEBUG static const char * const valtypes[] = { "<>", // No value, not set "array", // Array "hex-string", // Binary data "boolean", // Boolean "date", // Date/time "dict", // Dictionary "indirect", // Indirect object (N G obj) "name", // Name "null", // Null object "number", // Number (integer or real) "string" // String }; #endif // DEBUG PDFIO_DEBUG("_pdfioValueRead(pdf=%p, obj=%p, v=%p)\n", pdf, obj, v); (void)obj; // TODO: Implement decryption if (!_pdfioTokenGet(tb, token, sizeof(token))) return (NULL); if (!strcmp(token, "[")) { // Start of array if (depth >= PDFIO_MAX_DEPTH) { _pdfioFileError(pdf, "Too many nested arrays."); return (NULL); } v->type = PDFIO_VALTYPE_ARRAY; if ((v->value.array = _pdfioArrayRead(pdf, obj, tb, depth + 1)) == NULL) return (NULL); } else if (!strcmp(token, "<<")) { // Start of dictionary if (depth >= PDFIO_MAX_DEPTH) { _pdfioFileError(pdf, "Too many nested dictionaries."); return (NULL); } v->type = PDFIO_VALTYPE_DICT; if ((v->value.dict = _pdfioDictRead(pdf, obj, tb, depth + 1)) == NULL) return (NULL); } else if (!strncmp(token, "(D:", 3)) { // Possible date value of the form: // // (D:YYYYMMDDhhmmssZ) // (D:YYYYMMDDhhmmss+HH'mm) // (D:YYYYMMDDhhmmss-HH'mm) // int i; // Looping var struct tm dateval; // Date value int offset; // Date offset for (i = 3; i < 17; i ++) { if (!isdigit(token[i] & 255)) break; } if (i >= 17) { if (token[i] == 'Z') { i ++; } else if (token[i] == '-' || token[i] == '+') { if (isdigit(token[i + 1] & 255) && isdigit(token[i + 2] & 255) && token[i + 3] == '\'' && isdigit(token[i + 4] & 255) && isdigit(token[i + 5] & 255)) { i += 6; if (token[i] == '\'') i ++; } } } if (token[i]) { // Just a string... v->type = PDFIO_VALTYPE_STRING; v->value.string = pdfioStringCreate(pdf, token + 1); } else { // Date value... memset(&dateval, 0, sizeof(dateval)); dateval.tm_year = (token[3] - '0') * 1000 + (token[4] - '0') * 100 + (token[5] - '0') * 10 + token[6] - '0' - 1900; dateval.tm_mon = (token[7] - '0') * 10 + token[8] - '0' - 1; dateval.tm_mday = (token[9] - '0') * 10 + token[10] - '0'; dateval.tm_hour = (token[11] - '0') * 10 + token[12] - '0'; dateval.tm_min = (token[13] - '0') * 10 + token[14] - '0'; dateval.tm_sec = (token[15] - '0') * 10 + token[16] - '0'; if (token[17] == 'Z') { offset = 0; } else { offset = (token[18] - '0') * 600 + (token[19] - '0') * 60 + (token[20] - '0') * 10 + token[21] - '0'; if (token[17] == '-') offset = -offset; } v->type = PDFIO_VALTYPE_DATE; v->value.date = mktime(&dateval) + offset; } } else if (token[0] == '(') { // String v->type = PDFIO_VALTYPE_STRING; v->value.string = pdfioStringCreate(pdf, token + 1); } else if (token[0] == '/') { // Name v->type = PDFIO_VALTYPE_NAME; v->value.name = pdfioStringCreate(pdf, token + 1); } else if (token[0] == '<') { // Hex string const char *tokptr; // Pointer into token unsigned char *dataptr; // Pointer into data v->type = PDFIO_VALTYPE_BINARY; v->value.binary.datalen = strlen(token) / 2; if ((v->value.binary.data = (unsigned char *)malloc(v->value.binary.datalen)) == NULL) { _pdfioFileError(pdf, "Out of memory for hex string."); return (NULL); } // Convert hex to binary... tokptr = token + 1; dataptr = v->value.binary.data; while (*tokptr) { int d; // Data value if (isdigit(*tokptr)) d = (*tokptr++ - '0') << 4; else d = (tolower(*tokptr++) - 'a' + 10) << 4; if (*tokptr) { // PDF allows writers to drop a trailing 0... if (isdigit(*tokptr)) d |= *tokptr++ - '0'; else d |= tolower(*tokptr++) - 'a' + 10; } *dataptr++ = (unsigned char)d; } } else if (strchr("0123456789-+.", token[0]) != NULL) { // Number or indirect object reference if (isdigit(token[0]) && !strchr(token, '.')) { // Integer or object ref... unsigned char *tempptr; // Pointer into buffer #ifdef DEBUG PDFIO_DEBUG("_pdfioValueRead: %d bytes left in buffer: '", (int)(tb->bufend - tb->bufptr)); for (tempptr = tb->bufptr; tempptr < tb->bufend; tempptr ++) { if (*tempptr < ' ' || *tempptr == 0x7f) PDFIO_DEBUG("\\%03o", *tempptr); else PDFIO_DEBUG("%c", *tempptr); } PDFIO_DEBUG("'.\n"); #endif // DEBUG if ((tb->bufend - tb->bufptr) < 10) { // Fill up buffer... ssize_t bytes; // Bytes peeked _pdfioTokenFlush(tb); if ((bytes = (tb->peek_cb)(tb->cb_data, tb->buffer, sizeof(tb->buffer))) > 0) tb->bufend = tb->buffer + bytes; #ifdef DEBUG PDFIO_DEBUG("_pdfioValueRead: %d bytes now in buffer: '", (int)(tb->bufend - tb->bufptr)); for (tempptr = tb->bufptr; tempptr < tb->bufend; tempptr ++) { if (*tempptr < ' ' || *tempptr == 0x7f) PDFIO_DEBUG("\\%03o", *tempptr); else PDFIO_DEBUG("%c", *tempptr); } PDFIO_DEBUG("'.\n"); #endif // DEBUG } tempptr = tb->bufptr; while (tempptr < tb->bufend && isspace(*tempptr & 255)) tempptr ++; // Skip whitespace as needed... if (tempptr < tb->bufend && isdigit(*tempptr & 255)) { // Integer... long generation = 0; // Generation number while (tempptr < tb->bufend && isdigit(*tempptr & 255)) { generation = generation * 10 + *tempptr - '0'; tempptr ++; } while (tempptr < tb->bufend && isspace(*tempptr & 255)) tempptr ++; // Skip whitespace if (tempptr < tb->bufend && *tempptr == 'R') { // Reference! PDFIO_DEBUG("_pdfioValueRead: Consuming %d bytes.\n", (int)(tempptr - tb->bufptr + 1)); tb->bufptr = tempptr + 1; #ifdef DEBUG PDFIO_DEBUG("_pdfioValueRead: Next bytes are '"); for (tempptr = tb->bufptr; tempptr < tb->bufend; tempptr ++) { if (*tempptr < ' ' || *tempptr == 0x7f) PDFIO_DEBUG("\\%03o", *tempptr); else PDFIO_DEBUG("%c", *tempptr); } PDFIO_DEBUG("'.\n"); #endif // DEBUG v->type = PDFIO_VALTYPE_INDIRECT; v->value.indirect.number = (size_t)strtoimax(token, NULL, 10); v->value.indirect.generation = (unsigned short)generation; PDFIO_DEBUG("_pdfioValueRead: Returning indirect value %lu %u R.\n", (unsigned long)v->value.indirect.number, v->value.indirect.generation); return (v); } } } // If we get here, we have a number... v->type = PDFIO_VALTYPE_NUMBER; v->value.number = (double)strtod(token, NULL); } else if (!strcmp(token, "true") || !strcmp(token, "false")) { // Boolean value v->type = PDFIO_VALTYPE_BOOLEAN; v->value.boolean = !strcmp(token, "true"); } else if (!strcmp(token, "null")) { // null value v->type = PDFIO_VALTYPE_NULL; } else { _pdfioFileError(pdf, "Unexpected '%s' token seen.", token); return (NULL); } PDFIO_DEBUG("_pdfioValueRead: Returning %s value.\n", valtypes[v->type]); return (v); } // // '_pdfioValueWrite()' - Write a value to a PDF file. // bool // O - `true` on success, `false` on failure _pdfioValueWrite(pdfio_file_t *pdf, // I - PDF file pdfio_obj_t *obj, // I - Object, if any _pdfio_value_t *v, // I - Value off_t *length)// O - Offset to /Length value, if any { switch (v->type) { default : return (false); case PDFIO_VALTYPE_ARRAY : return (_pdfioArrayWrite(v->value.array, obj)); case PDFIO_VALTYPE_BINARY : { size_t databytes; // Bytes to write uint8_t temp[32768], // Temporary buffer for encryption *dataptr; // Pointer into data if (obj && pdf->encryption) { // Write encrypted string... _pdfio_crypto_ctx_t ctx; // Encryption context _pdfio_crypto_cb_t cb; // Encryption callback size_t ivlen; // Number of initialization vector bytes if (v->value.binary.datalen > (sizeof(temp) - 32)) { _pdfioFileError(pdf, "Unable to write encrypted binary string - too long."); return (false); } cb = _pdfioCryptoMakeWriter(pdf, obj, &ctx, temp, &ivlen); databytes = (cb)(&ctx, temp + ivlen, v->value.binary.data, v->value.binary.datalen) + ivlen; dataptr = temp; } else { dataptr = v->value.binary.data; databytes = v->value.binary.datalen; } if (!_pdfioFilePuts(pdf, "<")) return (false); for (; databytes > 1; databytes -= 2, dataptr += 2) { if (!_pdfioFilePrintf(pdf, "%02X%02X", dataptr[0], dataptr[1])) return (false); } if (databytes > 0) return (_pdfioFilePrintf(pdf, "%02X>", dataptr[0])); else return (_pdfioFilePuts(pdf, ">")); } case PDFIO_VALTYPE_BOOLEAN : if (v->value.boolean) return (_pdfioFilePuts(pdf, " true")); else return (_pdfioFilePuts(pdf, " false")); case PDFIO_VALTYPE_DATE : { struct tm date; // Date values char datestr[32]; // Formatted date value #ifdef _WIN32 gmtime_s(&date, &v->value.date); #else gmtime_r(&v->value.date, &date); #endif // _WIN32 snprintf(datestr, sizeof(datestr), "D:%04d%02d%02d%02d%02d%02dZ", date.tm_year + 1900, date.tm_mon + 1, date.tm_mday, date.tm_hour, date.tm_min, date.tm_sec); if (obj && pdf->encryption) { // Write encrypted string... uint8_t temp[32768], // Encrypted bytes *tempptr; // Pointer into encrypted bytes _pdfio_crypto_ctx_t ctx; // Encryption context _pdfio_crypto_cb_t cb; // Encryption callback size_t len = strlen(datestr), // Length of value ivlen, // Number of initialization vector bytes tempbytes; // Number of output bytes cb = _pdfioCryptoMakeWriter(pdf, obj, &ctx, temp, &ivlen); tempbytes = (cb)(&ctx, temp + ivlen, (const uint8_t *)datestr, len) + ivlen; if (!_pdfioFilePuts(pdf, "<")) return (false); for (tempptr = temp; tempbytes > 1; tempbytes -= 2, tempptr += 2) { if (!_pdfioFilePrintf(pdf, "%02X%02X", tempptr[0], tempptr[1])) return (false); } if (tempbytes > 0) return (_pdfioFilePrintf(pdf, "%02X>", *tempptr)); else return (_pdfioFilePuts(pdf, ">")); } else { return (_pdfioFilePrintf(pdf, "(%s)", datestr)); } } case PDFIO_VALTYPE_DICT : return (_pdfioDictWrite(v->value.dict, obj, length)); case PDFIO_VALTYPE_INDIRECT : return (_pdfioFilePrintf(pdf, " %lu %u R", (unsigned long)v->value.indirect.number, v->value.indirect.generation)); case PDFIO_VALTYPE_NAME : return (_pdfioFilePrintf(pdf, "/%s", v->value.name)); case PDFIO_VALTYPE_NULL : return (_pdfioFilePuts(pdf, " null")); case PDFIO_VALTYPE_NUMBER : return (_pdfioFilePrintf(pdf, " %g", v->value.number)); case PDFIO_VALTYPE_STRING : if (obj && pdf->encryption) { // Write encrypted string... uint8_t temp[32768], // Encrypted bytes *tempptr; // Pointer into encrypted bytes _pdfio_crypto_ctx_t ctx; // Encryption context _pdfio_crypto_cb_t cb; // Encryption callback size_t len = strlen(v->value.string), // Length of value ivlen, // Number of initialization vector bytes tempbytes; // Number of output bytes if (len > (sizeof(temp) - 32)) { _pdfioFileError(pdf, "Unable to write encrypted string - too long."); return (false); } cb = _pdfioCryptoMakeWriter(pdf, obj, &ctx, temp, &ivlen); tempbytes = (cb)(&ctx, temp + ivlen, (const uint8_t *)v->value.string, len) + ivlen; if (!_pdfioFilePuts(pdf, "<")) return (false); for (tempptr = temp; tempbytes > 1; tempbytes -= 2, tempptr += 2) { if (!_pdfioFilePrintf(pdf, "%02X%02X", tempptr[0], tempptr[1])) return (false); } if (tempbytes > 0) return (_pdfioFilePrintf(pdf, "%02X>", *tempptr)); else return (_pdfioFilePuts(pdf, ">")); } else { // Write unencrypted string... const char *start, // Start of fragment *end; // End of fragment if (!_pdfioFilePuts(pdf, "(")) return (false); // Write a quoted string value... for (start = v->value.string; *start; start = end) { // Find the next character that needs to be quoted... for (end = start; *end; end ++) { if (*end == '\\' || *end == ')' || (*end & 255) < ' ') break; } if (end > start) { // Write unquoted (safe) characters... if (!_pdfioFileWrite(pdf, start, (size_t)(end - start))) return (false); } if (*end) { // Quote this character... bool success; // Did the write work? if (*end == '\\' || *end == ')') success = _pdfioFilePrintf(pdf, "\\%c", *end); else success = _pdfioFilePrintf(pdf, "\\%03o", *end); if (!success) return (false); end ++; } } return (_pdfioFilePuts(pdf, ")")); } } return (false); }