/* * Copyright 2011 Google Inc. * * Use of this source code is governed by a BSD-style license that can be * found in the LICENSE file. */ #include "SkPDFConvertType1FontStream.h" #include "SkTemplates.h" #include "SkTo.h" #include static bool parsePFBSection(const uint8_t** src, size_t* len, int sectionType, size_t* size) { // PFB sections have a two or six bytes header. 0x80 and a one byte // section type followed by a four byte section length. Type one is // an ASCII section (includes a length), type two is a binary section // (includes a length) and type three is an EOF marker with no length. const uint8_t* buf = *src; if (*len < 2 || buf[0] != 0x80 || buf[1] != sectionType) { return false; } else if (buf[1] == 3) { return true; } else if (*len < 6) { return false; } *size = (size_t)buf[2] | ((size_t)buf[3] << 8) | ((size_t)buf[4] << 16) | ((size_t)buf[5] << 24); size_t consumed = *size + 6; if (consumed > *len) { return false; } *src = *src + consumed; *len = *len - consumed; return true; } static bool parsePFB(const uint8_t* src, size_t size, size_t* headerLen, size_t* dataLen, size_t* trailerLen) { const uint8_t* srcPtr = src; size_t remaining = size; return parsePFBSection(&srcPtr, &remaining, 1, headerLen) && parsePFBSection(&srcPtr, &remaining, 2, dataLen) && parsePFBSection(&srcPtr, &remaining, 1, trailerLen) && parsePFBSection(&srcPtr, &remaining, 3, nullptr); } /* The sections of a PFA file are implicitly defined. The body starts * after the line containing "eexec," and the trailer starts with 512 * literal 0's followed by "cleartomark" (plus arbitrary white space). * * This function assumes that src is NUL terminated, but the NUL * termination is not included in size. * */ static bool parsePFA(const char* src, size_t size, size_t* headerLen, size_t* hexDataLen, size_t* dataLen, size_t* trailerLen) { const char* end = src + size; const char* dataPos = strstr(src, "eexec"); if (!dataPos) { return false; } dataPos += strlen("eexec"); while ((*dataPos == '\n' || *dataPos == '\r' || *dataPos == ' ') && dataPos < end) { dataPos++; } *headerLen = dataPos - src; const char* trailerPos = strstr(dataPos, "cleartomark"); if (!trailerPos) { return false; } int zeroCount = 0; for (trailerPos--; trailerPos > dataPos && zeroCount < 512; trailerPos--) { if (*trailerPos == '\n' || *trailerPos == '\r' || *trailerPos == ' ') { continue; } else if (*trailerPos == '0') { zeroCount++; } else { return false; } } if (zeroCount != 512) { return false; } *hexDataLen = trailerPos - src - *headerLen; *trailerLen = size - *headerLen - *hexDataLen; // Verify that the data section is hex encoded and count the bytes. int nibbles = 0; for (; dataPos < trailerPos; dataPos++) { if (isspace(*dataPos)) { continue; } if (!isxdigit(*dataPos)) { return false; } nibbles++; } *dataLen = (nibbles + 1) / 2; return true; } static int8_t hexToBin(uint8_t c) { if (!isxdigit(c)) { return -1; } else if (c <= '9') { return c - '0'; } else if (c <= 'F') { return c - 'A' + 10; } else if (c <= 'f') { return c - 'a' + 10; } return -1; } sk_sp SkPDFConvertType1FontStream( std::unique_ptr srcStream, size_t* headerLen, size_t* dataLen, size_t* trailerLen) { size_t srcLen = srcStream ? srcStream->getLength() : 0; SkASSERT(srcLen); if (!srcLen) { return nullptr; } // Flatten and Nul-terminate the source stream so that we can use // strstr() to search it. SkAutoTMalloc sourceBuffer(SkToInt(srcLen + 1)); (void)srcStream->read(sourceBuffer.get(), srcLen); sourceBuffer[SkToInt(srcLen)] = 0; const uint8_t* src = sourceBuffer.get(); if (parsePFB(src, srcLen, headerLen, dataLen, trailerLen)) { static const int kPFBSectionHeaderLength = 6; const size_t length = *headerLen + *dataLen + *trailerLen; SkASSERT(length > 0); SkASSERT(length + (2 * kPFBSectionHeaderLength) <= srcLen); sk_sp data(SkData::MakeUninitialized(length)); const uint8_t* const srcHeader = src + kPFBSectionHeaderLength; // There is a six-byte section header before header and data // (but not trailer) that we're not going to copy. const uint8_t* const srcData = srcHeader + *headerLen + kPFBSectionHeaderLength; const uint8_t* const srcTrailer = srcData + *headerLen; uint8_t* const resultHeader = (uint8_t*)data->writable_data(); uint8_t* const resultData = resultHeader + *headerLen; uint8_t* const resultTrailer = resultData + *dataLen; SkASSERT(resultTrailer + *trailerLen == resultHeader + length); memcpy(resultHeader, srcHeader, *headerLen); memcpy(resultData, srcData, *dataLen); memcpy(resultTrailer, srcTrailer, *trailerLen); return data; } // A PFA has to be converted for PDF. size_t hexDataLen; if (!parsePFA((const char*)src, srcLen, headerLen, &hexDataLen, dataLen, trailerLen)) { return nullptr; } const size_t length = *headerLen + *dataLen + *trailerLen; SkASSERT(length > 0); auto data = SkData::MakeUninitialized(length); uint8_t* buffer = (uint8_t*)data->writable_data(); memcpy(buffer, src, *headerLen); uint8_t* const resultData = &(buffer[*headerLen]); const uint8_t* hexData = src + *headerLen; const uint8_t* trailer = hexData + hexDataLen; size_t outputOffset = 0; uint8_t dataByte = 0; // To hush compiler. bool highNibble = true; for (; hexData < trailer; hexData++) { int8_t curNibble = hexToBin(*hexData); if (curNibble < 0) { continue; } if (highNibble) { dataByte = curNibble << 4; highNibble = false; } else { dataByte |= curNibble; highNibble = true; resultData[outputOffset++] = dataByte; } } if (!highNibble) { resultData[outputOffset++] = dataByte; } SkASSERT(outputOffset == *dataLen); uint8_t* const resultTrailer = &(buffer[SkToInt(*headerLen + outputOffset)]); memcpy(resultTrailer, src + *headerLen + hexDataLen, *trailerLen); return data; }