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/*************************************************************************** |
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* * |
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* libgig - C++ cross-platform Gigasampler format file access library * |
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* * |
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* Copyright (C) 2003-2021 by Christian Schoenebeck * |
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* <cuse@users.sourceforge.net> * |
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* * |
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* This library is free software; you can redistribute it and/or modify * |
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* it under the terms of the GNU General Public License as published by * |
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* the Free Software Foundation; either version 2 of the License, or * |
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* (at your option) any later version. * |
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* * |
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* This library is distributed in the hope that it will be useful, * |
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* but WITHOUT ANY WARRANTY; without even the implied warranty of * |
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* MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the * |
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* GNU General Public License for more details. * |
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* * |
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* You should have received a copy of the GNU General Public License * |
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* along with this library; if not, write to the Free Software * |
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* Foundation, Inc., 59 Temple Place, Suite 330, Boston, * |
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* MA 02111-1307 USA * |
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***************************************************************************/ |
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|
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#include <algorithm> |
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#include <set> |
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#include <string.h> |
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|
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#include "RIFF.h" |
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|
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#include "helper.h" |
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|
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#if POSIX |
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# include <errno.h> |
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#endif |
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|
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namespace RIFF { |
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|
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// *************** Internal functions ************** |
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// * |
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|
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/// Returns a human readable path of the given chunk. |
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static String __resolveChunkPath(Chunk* pCk) { |
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String sPath; |
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for (Chunk* pChunk = pCk; pChunk; pChunk = pChunk->GetParent()) { |
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if (pChunk->GetChunkID() == CHUNK_ID_LIST) { |
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List* pList = (List*) pChunk; |
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sPath = "->'" + pList->GetListTypeString() + "'" + sPath; |
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} else { |
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sPath = "->'" + pChunk->GetChunkIDString() + "'" + sPath; |
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} |
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} |
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return sPath; |
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} |
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|
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|
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|
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// *************** progress_t *************** |
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// * |
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|
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progress_t::progress_t() { |
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callback = NULL; |
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custom = NULL; |
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__range_min = 0.0f; |
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__range_max = 1.0f; |
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} |
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|
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/** |
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* Divides this progress task into the requested amount of equal weighted |
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* sub-progress tasks and returns a vector with those subprogress tasks. |
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* |
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* @param iSubtasks - total amount sub tasks this task should be subdivided |
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* @returns subtasks |
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*/ |
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std::vector<progress_t> progress_t::subdivide(int iSubtasks) { |
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std::vector<progress_t> v; |
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for (int i = 0; i < iSubtasks; ++i) { |
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progress_t p; |
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__divide_progress(this, &p, iSubtasks, i); |
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v.push_back(p); |
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} |
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return v; |
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} |
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|
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/** |
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* Divides this progress task into the requested amount of sub-progress |
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* tasks, where each one of those new sub-progress tasks is created with its |
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* requested individual weight / portion, and finally returns a vector |
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* with those new subprogress tasks. |
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* |
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* The amount of subprogresses to be created is determined by this method |
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* by calling @c vSubTaskPortions.size() . |
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* |
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* Example: consider you wanted to create 3 subprogresses where the 1st |
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* subtask should be assigned 10% of the new 3 subprogresses' overall |
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* progress, the 2nd subtask should be assigned 50% of the new 3 |
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* subprogresses' overall progress, and the 3rd subtask should be assigned |
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* 40%, then you might call this method like this: |
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* @code |
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* std::vector<progress_t> subprogresses = progress.subdivide({0.1, 0.5, 0.4}); |
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* @endcode |
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* |
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* @param vSubTaskPortions - amount and individual weight of subtasks to be |
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* created |
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* @returns subtasks |
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*/ |
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std::vector<progress_t> progress_t::subdivide(std::vector<float> vSubTaskPortions) { |
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float fTotal = 0.f; // usually 1.0, but we sum the portions up below to be sure |
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for (int i = 0; i < vSubTaskPortions.size(); ++i) |
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fTotal += vSubTaskPortions[i]; |
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|
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float fLow = 0.f, fHigh = 0.f; |
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std::vector<progress_t> v; |
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for (int i = 0; i < vSubTaskPortions.size(); ++i) { |
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fLow = fHigh; |
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fHigh = vSubTaskPortions[i]; |
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progress_t p; |
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__divide_progress(this, &p, fTotal, fLow, fHigh); |
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v.push_back(p); |
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} |
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return v; |
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} |
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|
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|
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|
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// *************** Chunk ************** |
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// * |
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|
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Chunk::Chunk(File* pFile) { |
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#if DEBUG_RIFF |
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std::cout << "Chunk::Chunk(File* pFile)" << std::endl; |
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#endif // DEBUG_RIFF |
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ullPos = 0; |
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pParent = NULL; |
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pChunkData = NULL; |
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ullCurrentChunkSize = 0; |
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ullNewChunkSize = 0; |
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ullChunkDataSize = 0; |
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ChunkID = CHUNK_ID_RIFF; |
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this->pFile = pFile; |
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} |
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|
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Chunk::Chunk(File* pFile, file_offset_t StartPos, List* Parent) { |
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#if DEBUG_RIFF |
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std::cout << "Chunk::Chunk(File*,file_offset_t,List*),StartPos=" << StartPos << std::endl; |
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#endif // DEBUG_RIFF |
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this->pFile = pFile; |
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ullStartPos = StartPos + CHUNK_HEADER_SIZE(pFile->FileOffsetSize); |
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pParent = Parent; |
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ullPos = 0; |
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pChunkData = NULL; |
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ullCurrentChunkSize = 0; |
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ullNewChunkSize = 0; |
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ullChunkDataSize = 0; |
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ReadHeader(StartPos); |
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} |
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|
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Chunk::Chunk(File* pFile, List* pParent, uint32_t uiChunkID, file_offset_t ullBodySize) { |
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this->pFile = pFile; |
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ullStartPos = 0; // arbitrary usually, since it will be updated when we write the chunk |
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this->pParent = pParent; |
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ullPos = 0; |
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pChunkData = NULL; |
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ChunkID = uiChunkID; |
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ullChunkDataSize = 0; |
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ullCurrentChunkSize = 0; |
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ullNewChunkSize = ullBodySize; |
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} |
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|
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Chunk::~Chunk() { |
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if (pChunkData) delete[] pChunkData; |
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} |
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|
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void Chunk::ReadHeader(file_offset_t filePos) { |
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#if DEBUG_RIFF |
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std::cout << "Chunk::Readheader(" << filePos << ") "; |
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#endif // DEBUG_RIFF |
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ChunkID = 0; |
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ullNewChunkSize = ullCurrentChunkSize = 0; |
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#if POSIX |
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if (lseek(pFile->hFileRead, filePos, SEEK_SET) != -1) { |
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read(pFile->hFileRead, &ChunkID, 4); |
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read(pFile->hFileRead, &ullCurrentChunkSize, pFile->FileOffsetSize); |
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#elif defined(WIN32) |
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LARGE_INTEGER liFilePos; |
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liFilePos.QuadPart = filePos; |
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if (SetFilePointerEx(pFile->hFileRead, liFilePos, NULL/*new pos pointer*/, FILE_BEGIN)) { |
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DWORD dwBytesRead; |
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ReadFile(pFile->hFileRead, &ChunkID, 4, &dwBytesRead, NULL); |
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ReadFile(pFile->hFileRead, &ullCurrentChunkSize, pFile->FileOffsetSize, &dwBytesRead, NULL); |
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#else |
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if (!fseeko(pFile->hFileRead, filePos, SEEK_SET)) { |
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fread(&ChunkID, 4, 1, pFile->hFileRead); |
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fread(&ullCurrentChunkSize, pFile->FileOffsetSize, 1, pFile->hFileRead); |
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#endif // POSIX |
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#if WORDS_BIGENDIAN |
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if (ChunkID == CHUNK_ID_RIFF) { |
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pFile->bEndianNative = false; |
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} |
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#else // little endian |
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if (ChunkID == CHUNK_ID_RIFX) { |
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pFile->bEndianNative = false; |
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ChunkID = CHUNK_ID_RIFF; |
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} |
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#endif // WORDS_BIGENDIAN |
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if (!pFile->bEndianNative) { |
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//swapBytes_32(&ChunkID); |
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if (pFile->FileOffsetSize == 4) |
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swapBytes_32(&ullCurrentChunkSize); |
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else |
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swapBytes_64(&ullCurrentChunkSize); |
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} |
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#if DEBUG_RIFF |
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std::cout << "ckID=" << convertToString(ChunkID) << " "; |
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std::cout << "ckSize=" << ullCurrentChunkSize << " "; |
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std::cout << "bEndianNative=" << pFile->bEndianNative << std::endl; |
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#endif // DEBUG_RIFF |
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ullNewChunkSize = ullCurrentChunkSize; |
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} |
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} |
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|
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void Chunk::WriteHeader(file_offset_t filePos) { |
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uint32_t uiNewChunkID = ChunkID; |
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if (ChunkID == CHUNK_ID_RIFF) { |
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#if WORDS_BIGENDIAN |
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if (pFile->bEndianNative) uiNewChunkID = CHUNK_ID_RIFX; |
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#else // little endian |
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if (!pFile->bEndianNative) uiNewChunkID = CHUNK_ID_RIFX; |
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#endif // WORDS_BIGENDIAN |
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} |
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|
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uint64_t ullNewChunkSize = this->ullNewChunkSize; |
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if (!pFile->bEndianNative) { |
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if (pFile->FileOffsetSize == 4) |
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swapBytes_32(&ullNewChunkSize); |
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else |
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swapBytes_64(&ullNewChunkSize); |
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} |
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|
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#if POSIX |
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if (lseek(pFile->hFileWrite, filePos, SEEK_SET) != -1) { |
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write(pFile->hFileWrite, &uiNewChunkID, 4); |
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write(pFile->hFileWrite, &ullNewChunkSize, pFile->FileOffsetSize); |
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} |
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#elif defined(WIN32) |
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LARGE_INTEGER liFilePos; |
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liFilePos.QuadPart = filePos; |
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if (SetFilePointerEx(pFile->hFileWrite, liFilePos, NULL/*new pos pointer*/, FILE_BEGIN)) { |
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DWORD dwBytesWritten; |
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WriteFile(pFile->hFileWrite, &uiNewChunkID, 4, &dwBytesWritten, NULL); |
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WriteFile(pFile->hFileWrite, &ullNewChunkSize, pFile->FileOffsetSize, &dwBytesWritten, NULL); |
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} |
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#else |
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if (!fseeko(pFile->hFileWrite, filePos, SEEK_SET)) { |
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fwrite(&uiNewChunkID, 4, 1, pFile->hFileWrite); |
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fwrite(&ullNewChunkSize, pFile->FileOffsetSize, 1, pFile->hFileWrite); |
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} |
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#endif // POSIX |
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} |
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|
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/** |
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* Returns the String representation of the chunk's ID (e.g. "RIFF", |
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* "LIST"). |
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*/ |
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String Chunk::GetChunkIDString() const { |
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return convertToString(ChunkID); |
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} |
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|
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/** |
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* Sets the position within the chunk body, thus within the data portion |
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* of the chunk (in bytes). |
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* |
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* <b>Caution:</b> the position will be reset to zero whenever |
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* File::Save() was called. |
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* |
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* @param Where - position offset (in bytes) |
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* @param Whence - optional: defines to what <i>\a Where</i> relates to, |
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* if omitted \a Where relates to beginning of the chunk |
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* data |
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*/ |
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file_offset_t Chunk::SetPos(file_offset_t Where, stream_whence_t Whence) { |
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#if DEBUG_RIFF |
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std::cout << "Chunk::SetPos(file_offset_t,stream_whence_t)" << std::endl; |
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#endif // DEBUG_RIFF |
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switch (Whence) { |
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case stream_curpos: |
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ullPos += Where; |
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break; |
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case stream_end: |
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ullPos = ullCurrentChunkSize - 1 - Where; |
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break; |
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case stream_backward: |
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ullPos -= Where; |
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break; |
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case stream_start: default: |
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ullPos = Where; |
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break; |
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} |
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if (ullPos > ullCurrentChunkSize) ullPos = ullCurrentChunkSize; |
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return ullPos; |
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} |
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|
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/** |
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* Returns the number of bytes left to read in the chunk body. |
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* When reading data from the chunk using the Read*() Methods, the |
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* position within the chunk data (that is the chunk body) will be |
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* incremented by the number of read bytes and RemainingBytes() returns |
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* how much data is left to read from the current position to the end |
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* of the chunk data. |
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* |
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* @returns number of bytes left to read |
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*/ |
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file_offset_t Chunk::RemainingBytes() const { |
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#if DEBUG_RIFF |
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std::cout << "Chunk::Remainingbytes()=" << ullCurrentChunkSize - ullPos << std::endl; |
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#endif // DEBUG_RIFF |
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return (ullCurrentChunkSize > ullPos) ? ullCurrentChunkSize - ullPos : 0; |
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} |
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|
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/** |
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* Returns the actual total size in bytes (including header) of this Chunk |
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* if being stored to a file. |
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* |
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* @param fileOffsetSize - RIFF file offset size (in bytes) assumed when |
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* being saved to a file |
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*/ |
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file_offset_t Chunk::RequiredPhysicalSize(int fileOffsetSize) { |
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return CHUNK_HEADER_SIZE(fileOffsetSize) + // RIFF chunk header |
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ullNewChunkSize + // chunks's actual data body |
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ullNewChunkSize % 2; // optional pad byte |
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} |
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|
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/** |
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* Returns the current state of the chunk object. |
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* Following values are possible: |
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* - RIFF::stream_ready : |
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* chunk data can be read (this is the usual case) |
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* - RIFF::stream_closed : |
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* the data stream was closed somehow, no more reading possible |
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* - RIFF::stream_end_reached : |
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* already reached the end of the chunk data, no more reading |
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* possible without SetPos() |
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*/ |
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stream_state_t Chunk::GetState() const { |
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#if DEBUG_RIFF |
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std::cout << "Chunk::GetState()" << std::endl; |
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#endif // DEBUG_RIFF |
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#if POSIX |
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if (pFile->hFileRead == 0) return stream_closed; |
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#elif defined (WIN32) |
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if (pFile->hFileRead == INVALID_HANDLE_VALUE) |
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return stream_closed; |
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#else |
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if (pFile->hFileRead == NULL) return stream_closed; |
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#endif // POSIX |
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if (ullPos < ullCurrentChunkSize) return stream_ready; |
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else return stream_end_reached; |
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} |
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|
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/** |
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* Reads \a WordCount number of data words with given \a WordSize and |
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* copies it into a buffer pointed by \a pData. The buffer has to be |
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* allocated and be sure to provide the correct \a WordSize, as this |
363 |
* will be important and taken into account for eventual endian |
364 |
* correction (swapping of bytes due to different native byte order of |
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* a system). The position within the chunk will automatically be |
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* incremented. |
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* |
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* @param pData destination buffer |
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* @param WordCount number of data words to read |
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* @param WordSize size of each data word to read |
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* @returns number of successfully read data words or 0 if end |
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* of file reached or error occurred |
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*/ |
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file_offset_t Chunk::Read(void* pData, file_offset_t WordCount, file_offset_t WordSize) { |
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#if DEBUG_RIFF |
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std::cout << "Chunk::Read(void*,file_offset_t,file_offset_t)" << std::endl; |
377 |
#endif // DEBUG_RIFF |
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//if (ulStartPos == 0) return 0; // is only 0 if this is a new chunk, so nothing to read (yet) |
379 |
if (ullPos >= ullCurrentChunkSize) return 0; |
380 |
if (ullPos + WordCount * WordSize >= ullCurrentChunkSize) WordCount = (ullCurrentChunkSize - ullPos) / WordSize; |
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#if POSIX |
382 |
if (lseek(pFile->hFileRead, ullStartPos + ullPos, SEEK_SET) < 0) return 0; |
383 |
ssize_t readWords = read(pFile->hFileRead, pData, WordCount * WordSize); |
384 |
if (readWords < 1) { |
385 |
#if DEBUG_RIFF |
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std::cerr << "POSIX read() failed: " << strerror(errno) << std::endl << std::flush; |
387 |
#endif // DEBUG_RIFF |
388 |
return 0; |
389 |
} |
390 |
readWords /= WordSize; |
391 |
#elif defined(WIN32) |
392 |
LARGE_INTEGER liFilePos; |
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liFilePos.QuadPart = ullStartPos + ullPos; |
394 |
if (!SetFilePointerEx(pFile->hFileRead, liFilePos, NULL/*new pos pointer*/, FILE_BEGIN)) |
395 |
return 0; |
396 |
DWORD readWords; |
397 |
ReadFile(pFile->hFileRead, pData, WordCount * WordSize, &readWords, NULL); //FIXME: does not work for reading buffers larger than 2GB (even though this should rarely be the case in practice) |
398 |
if (readWords < 1) return 0; |
399 |
readWords /= WordSize; |
400 |
#else // standard C functions |
401 |
if (fseeko(pFile->hFileRead, ullStartPos + ullPos, SEEK_SET)) return 0; |
402 |
file_offset_t readWords = fread(pData, WordSize, WordCount, pFile->hFileRead); |
403 |
#endif // POSIX |
404 |
if (!pFile->bEndianNative && WordSize != 1) { |
405 |
switch (WordSize) { |
406 |
case 2: |
407 |
for (file_offset_t iWord = 0; iWord < readWords; iWord++) |
408 |
swapBytes_16((uint16_t*) pData + iWord); |
409 |
break; |
410 |
case 4: |
411 |
for (file_offset_t iWord = 0; iWord < readWords; iWord++) |
412 |
swapBytes_32((uint32_t*) pData + iWord); |
413 |
break; |
414 |
case 8: |
415 |
for (file_offset_t iWord = 0; iWord < readWords; iWord++) |
416 |
swapBytes_64((uint64_t*) pData + iWord); |
417 |
break; |
418 |
default: |
419 |
for (file_offset_t iWord = 0; iWord < readWords; iWord++) |
420 |
swapBytes((uint8_t*) pData + iWord * WordSize, WordSize); |
421 |
break; |
422 |
} |
423 |
} |
424 |
SetPos(readWords * WordSize, stream_curpos); |
425 |
return readWords; |
426 |
} |
427 |
|
428 |
/** |
429 |
* Writes \a WordCount number of data words with given \a WordSize from |
430 |
* the buffer pointed by \a pData. Be sure to provide the correct |
431 |
* \a WordSize, as this will be important and taken into account for |
432 |
* eventual endian correction (swapping of bytes due to different |
433 |
* native byte order of a system). The position within the chunk will |
434 |
* automatically be incremented. |
435 |
* |
436 |
* @param pData source buffer (containing the data) |
437 |
* @param WordCount number of data words to write |
438 |
* @param WordSize size of each data word to write |
439 |
* @returns number of successfully written data words |
440 |
* @throws RIFF::Exception if write operation would exceed current |
441 |
* chunk size or any IO error occurred |
442 |
* @see Resize() |
443 |
*/ |
444 |
file_offset_t Chunk::Write(void* pData, file_offset_t WordCount, file_offset_t WordSize) { |
445 |
if (pFile->Mode != stream_mode_read_write) |
446 |
throw Exception("Cannot write data to chunk, file has to be opened in read+write mode first"); |
447 |
if (ullPos >= ullCurrentChunkSize || ullPos + WordCount * WordSize > ullCurrentChunkSize) |
448 |
throw Exception("End of chunk reached while trying to write data"); |
449 |
if (!pFile->bEndianNative && WordSize != 1) { |
450 |
switch (WordSize) { |
451 |
case 2: |
452 |
for (file_offset_t iWord = 0; iWord < WordCount; iWord++) |
453 |
swapBytes_16((uint16_t*) pData + iWord); |
454 |
break; |
455 |
case 4: |
456 |
for (file_offset_t iWord = 0; iWord < WordCount; iWord++) |
457 |
swapBytes_32((uint32_t*) pData + iWord); |
458 |
break; |
459 |
case 8: |
460 |
for (file_offset_t iWord = 0; iWord < WordCount; iWord++) |
461 |
swapBytes_64((uint64_t*) pData + iWord); |
462 |
break; |
463 |
default: |
464 |
for (file_offset_t iWord = 0; iWord < WordCount; iWord++) |
465 |
swapBytes((uint8_t*) pData + iWord * WordSize, WordSize); |
466 |
break; |
467 |
} |
468 |
} |
469 |
#if POSIX |
470 |
if (lseek(pFile->hFileWrite, ullStartPos + ullPos, SEEK_SET) < 0) { |
471 |
throw Exception("Could not seek to position " + ToString(ullPos) + |
472 |
" in chunk (" + ToString(ullStartPos + ullPos) + " in file)"); |
473 |
} |
474 |
ssize_t writtenWords = write(pFile->hFileWrite, pData, WordCount * WordSize); |
475 |
if (writtenWords < 1) throw Exception("POSIX IO Error while trying to write chunk data"); |
476 |
writtenWords /= WordSize; |
477 |
#elif defined(WIN32) |
478 |
LARGE_INTEGER liFilePos; |
479 |
liFilePos.QuadPart = ullStartPos + ullPos; |
480 |
if (!SetFilePointerEx(pFile->hFileWrite, liFilePos, NULL/*new pos pointer*/, FILE_BEGIN)) { |
481 |
throw Exception("Could not seek to position " + ToString(ullPos) + |
482 |
" in chunk (" + ToString(ullStartPos + ullPos) + " in file)"); |
483 |
} |
484 |
DWORD writtenWords; |
485 |
WriteFile(pFile->hFileWrite, pData, WordCount * WordSize, &writtenWords, NULL); //FIXME: does not work for writing buffers larger than 2GB (even though this should rarely be the case in practice) |
486 |
if (writtenWords < 1) throw Exception("Windows IO Error while trying to write chunk data"); |
487 |
writtenWords /= WordSize; |
488 |
#else // standard C functions |
489 |
if (fseeko(pFile->hFileWrite, ullStartPos + ullPos, SEEK_SET)) { |
490 |
throw Exception("Could not seek to position " + ToString(ullPos) + |
491 |
" in chunk (" + ToString(ullStartPos + ullPos) + " in file)"); |
492 |
} |
493 |
file_offset_t writtenWords = fwrite(pData, WordSize, WordCount, pFile->hFileWrite); |
494 |
#endif // POSIX |
495 |
SetPos(writtenWords * WordSize, stream_curpos); |
496 |
return writtenWords; |
497 |
} |
498 |
|
499 |
/** Just an internal wrapper for the main <i>Read()</i> method with additional Exception throwing on errors. */ |
500 |
file_offset_t Chunk::ReadSceptical(void* pData, file_offset_t WordCount, file_offset_t WordSize) { |
501 |
file_offset_t readWords = Read(pData, WordCount, WordSize); |
502 |
if (readWords != WordCount) throw RIFF::Exception("End of chunk data reached."); |
503 |
return readWords; |
504 |
} |
505 |
|
506 |
/** |
507 |
* Reads \a WordCount number of 8 Bit signed integer words and copies it |
508 |
* into the buffer pointed by \a pData. The buffer has to be allocated. |
509 |
* The position within the chunk will automatically be incremented. |
510 |
* |
511 |
* @param pData destination buffer |
512 |
* @param WordCount number of 8 Bit signed integers to read |
513 |
* @returns number of read integers |
514 |
* @throws RIFF::Exception if an error occurred or less than |
515 |
* \a WordCount integers could be read! |
516 |
*/ |
517 |
file_offset_t Chunk::ReadInt8(int8_t* pData, file_offset_t WordCount) { |
518 |
#if DEBUG_RIFF |
519 |
std::cout << "Chunk::ReadInt8(int8_t*,file_offset_t)" << std::endl; |
520 |
#endif // DEBUG_RIFF |
521 |
return ReadSceptical(pData, WordCount, 1); |
522 |
} |
523 |
|
524 |
/** |
525 |
* Writes \a WordCount number of 8 Bit signed integer words from the |
526 |
* buffer pointed by \a pData to the chunk's body, directly to the |
527 |
* actual "physical" file. The position within the chunk will |
528 |
* automatically be incremented. Note: you cannot write beyond the |
529 |
* boundaries of the chunk, to append data to the chunk call Resize() |
530 |
* before. |
531 |
* |
532 |
* @param pData source buffer (containing the data) |
533 |
* @param WordCount number of 8 Bit signed integers to write |
534 |
* @returns number of written integers |
535 |
* @throws RIFF::Exception if an IO error occurred |
536 |
* @see Resize() |
537 |
*/ |
538 |
file_offset_t Chunk::WriteInt8(int8_t* pData, file_offset_t WordCount) { |
539 |
return Write(pData, WordCount, 1); |
540 |
} |
541 |
|
542 |
/** |
543 |
* Reads \a WordCount number of 8 Bit unsigned integer words and copies |
544 |
* it into the buffer pointed by \a pData. The buffer has to be |
545 |
* allocated. The position within the chunk will automatically be |
546 |
* incremented. |
547 |
* |
548 |
* @param pData destination buffer |
549 |
* @param WordCount number of 8 Bit unsigned integers to read |
550 |
* @returns number of read integers |
551 |
* @throws RIFF::Exception if an error occurred or less than |
552 |
* \a WordCount integers could be read! |
553 |
*/ |
554 |
file_offset_t Chunk::ReadUint8(uint8_t* pData, file_offset_t WordCount) { |
555 |
#if DEBUG_RIFF |
556 |
std::cout << "Chunk::ReadUint8(uint8_t*,file_offset_t)" << std::endl; |
557 |
#endif // DEBUG_RIFF |
558 |
return ReadSceptical(pData, WordCount, 1); |
559 |
} |
560 |
|
561 |
/** |
562 |
* Writes \a WordCount number of 8 Bit unsigned integer words from the |
563 |
* buffer pointed by \a pData to the chunk's body, directly to the |
564 |
* actual "physical" file. The position within the chunk will |
565 |
* automatically be incremented. Note: you cannot write beyond the |
566 |
* boundaries of the chunk, to append data to the chunk call Resize() |
567 |
* before. |
568 |
* |
569 |
* @param pData source buffer (containing the data) |
570 |
* @param WordCount number of 8 Bit unsigned integers to write |
571 |
* @returns number of written integers |
572 |
* @throws RIFF::Exception if an IO error occurred |
573 |
* @see Resize() |
574 |
*/ |
575 |
file_offset_t Chunk::WriteUint8(uint8_t* pData, file_offset_t WordCount) { |
576 |
return Write(pData, WordCount, 1); |
577 |
} |
578 |
|
579 |
/** |
580 |
* Reads \a WordCount number of 16 Bit signed integer words and copies |
581 |
* it into the buffer pointed by \a pData. The buffer has to be |
582 |
* allocated. Endian correction will automatically be done if needed. |
583 |
* The position within the chunk will automatically be incremented. |
584 |
* |
585 |
* @param pData destination buffer |
586 |
* @param WordCount number of 16 Bit signed integers to read |
587 |
* @returns number of read integers |
588 |
* @throws RIFF::Exception if an error occurred or less than |
589 |
* \a WordCount integers could be read! |
590 |
*/ |
591 |
file_offset_t Chunk::ReadInt16(int16_t* pData, file_offset_t WordCount) { |
592 |
#if DEBUG_RIFF |
593 |
std::cout << "Chunk::ReadInt16(int16_t*,file_offset_t)" << std::endl; |
594 |
#endif // DEBUG_RIFF |
595 |
return ReadSceptical(pData, WordCount, 2); |
596 |
} |
597 |
|
598 |
/** |
599 |
* Writes \a WordCount number of 16 Bit signed integer words from the |
600 |
* buffer pointed by \a pData to the chunk's body, directly to the |
601 |
* actual "physical" file. The position within the chunk will |
602 |
* automatically be incremented. Note: you cannot write beyond the |
603 |
* boundaries of the chunk, to append data to the chunk call Resize() |
604 |
* before. |
605 |
* |
606 |
* @param pData source buffer (containing the data) |
607 |
* @param WordCount number of 16 Bit signed integers to write |
608 |
* @returns number of written integers |
609 |
* @throws RIFF::Exception if an IO error occurred |
610 |
* @see Resize() |
611 |
*/ |
612 |
file_offset_t Chunk::WriteInt16(int16_t* pData, file_offset_t WordCount) { |
613 |
return Write(pData, WordCount, 2); |
614 |
} |
615 |
|
616 |
/** |
617 |
* Reads \a WordCount number of 16 Bit unsigned integer words and copies |
618 |
* it into the buffer pointed by \a pData. The buffer has to be |
619 |
* allocated. Endian correction will automatically be done if needed. |
620 |
* The position within the chunk will automatically be incremented. |
621 |
* |
622 |
* @param pData destination buffer |
623 |
* @param WordCount number of 8 Bit unsigned integers to read |
624 |
* @returns number of read integers |
625 |
* @throws RIFF::Exception if an error occurred or less than |
626 |
* \a WordCount integers could be read! |
627 |
*/ |
628 |
file_offset_t Chunk::ReadUint16(uint16_t* pData, file_offset_t WordCount) { |
629 |
#if DEBUG_RIFF |
630 |
std::cout << "Chunk::ReadUint16(uint16_t*,file_offset_t)" << std::endl; |
631 |
#endif // DEBUG_RIFF |
632 |
return ReadSceptical(pData, WordCount, 2); |
633 |
} |
634 |
|
635 |
/** |
636 |
* Writes \a WordCount number of 16 Bit unsigned integer words from the |
637 |
* buffer pointed by \a pData to the chunk's body, directly to the |
638 |
* actual "physical" file. The position within the chunk will |
639 |
* automatically be incremented. Note: you cannot write beyond the |
640 |
* boundaries of the chunk, to append data to the chunk call Resize() |
641 |
* before. |
642 |
* |
643 |
* @param pData source buffer (containing the data) |
644 |
* @param WordCount number of 16 Bit unsigned integers to write |
645 |
* @returns number of written integers |
646 |
* @throws RIFF::Exception if an IO error occurred |
647 |
* @see Resize() |
648 |
*/ |
649 |
file_offset_t Chunk::WriteUint16(uint16_t* pData, file_offset_t WordCount) { |
650 |
return Write(pData, WordCount, 2); |
651 |
} |
652 |
|
653 |
/** |
654 |
* Reads \a WordCount number of 32 Bit signed integer words and copies |
655 |
* it into the buffer pointed by \a pData. The buffer has to be |
656 |
* allocated. Endian correction will automatically be done if needed. |
657 |
* The position within the chunk will automatically be incremented. |
658 |
* |
659 |
* @param pData destination buffer |
660 |
* @param WordCount number of 32 Bit signed integers to read |
661 |
* @returns number of read integers |
662 |
* @throws RIFF::Exception if an error occurred or less than |
663 |
* \a WordCount integers could be read! |
664 |
*/ |
665 |
file_offset_t Chunk::ReadInt32(int32_t* pData, file_offset_t WordCount) { |
666 |
#if DEBUG_RIFF |
667 |
std::cout << "Chunk::ReadInt32(int32_t*,file_offset_t)" << std::endl; |
668 |
#endif // DEBUG_RIFF |
669 |
return ReadSceptical(pData, WordCount, 4); |
670 |
} |
671 |
|
672 |
/** |
673 |
* Writes \a WordCount number of 32 Bit signed integer words from the |
674 |
* buffer pointed by \a pData to the chunk's body, directly to the |
675 |
* actual "physical" file. The position within the chunk will |
676 |
* automatically be incremented. Note: you cannot write beyond the |
677 |
* boundaries of the chunk, to append data to the chunk call Resize() |
678 |
* before. |
679 |
* |
680 |
* @param pData source buffer (containing the data) |
681 |
* @param WordCount number of 32 Bit signed integers to write |
682 |
* @returns number of written integers |
683 |
* @throws RIFF::Exception if an IO error occurred |
684 |
* @see Resize() |
685 |
*/ |
686 |
file_offset_t Chunk::WriteInt32(int32_t* pData, file_offset_t WordCount) { |
687 |
return Write(pData, WordCount, 4); |
688 |
} |
689 |
|
690 |
/** |
691 |
* Reads \a WordCount number of 32 Bit unsigned integer words and copies |
692 |
* it into the buffer pointed by \a pData. The buffer has to be |
693 |
* allocated. Endian correction will automatically be done if needed. |
694 |
* The position within the chunk will automatically be incremented. |
695 |
* |
696 |
* @param pData destination buffer |
697 |
* @param WordCount number of 32 Bit unsigned integers to read |
698 |
* @returns number of read integers |
699 |
* @throws RIFF::Exception if an error occurred or less than |
700 |
* \a WordCount integers could be read! |
701 |
*/ |
702 |
file_offset_t Chunk::ReadUint32(uint32_t* pData, file_offset_t WordCount) { |
703 |
#if DEBUG_RIFF |
704 |
std::cout << "Chunk::ReadUint32(uint32_t*,file_offset_t)" << std::endl; |
705 |
#endif // DEBUG_RIFF |
706 |
return ReadSceptical(pData, WordCount, 4); |
707 |
} |
708 |
|
709 |
/** |
710 |
* Reads a null-padded string of size characters and copies it |
711 |
* into the string \a s. The position within the chunk will |
712 |
* automatically be incremented. |
713 |
* |
714 |
* @param s destination string |
715 |
* @param size number of characters to read |
716 |
* @throws RIFF::Exception if an error occurred or less than |
717 |
* \a size characters could be read! |
718 |
*/ |
719 |
void Chunk::ReadString(String& s, int size) { |
720 |
char* buf = new char[size]; |
721 |
ReadSceptical(buf, 1, size); |
722 |
s.assign(buf, std::find(buf, buf + size, '\0')); |
723 |
delete[] buf; |
724 |
} |
725 |
|
726 |
/** |
727 |
* Writes \a WordCount number of 32 Bit unsigned integer words from the |
728 |
* buffer pointed by \a pData to the chunk's body, directly to the |
729 |
* actual "physical" file. The position within the chunk will |
730 |
* automatically be incremented. Note: you cannot write beyond the |
731 |
* boundaries of the chunk, to append data to the chunk call Resize() |
732 |
* before. |
733 |
* |
734 |
* @param pData source buffer (containing the data) |
735 |
* @param WordCount number of 32 Bit unsigned integers to write |
736 |
* @returns number of written integers |
737 |
* @throws RIFF::Exception if an IO error occurred |
738 |
* @see Resize() |
739 |
*/ |
740 |
file_offset_t Chunk::WriteUint32(uint32_t* pData, file_offset_t WordCount) { |
741 |
return Write(pData, WordCount, 4); |
742 |
} |
743 |
|
744 |
/** |
745 |
* Reads one 8 Bit signed integer word and increments the position within |
746 |
* the chunk. |
747 |
* |
748 |
* @returns read integer word |
749 |
* @throws RIFF::Exception if an error occurred |
750 |
*/ |
751 |
int8_t Chunk::ReadInt8() { |
752 |
#if DEBUG_RIFF |
753 |
std::cout << "Chunk::ReadInt8()" << std::endl; |
754 |
#endif // DEBUG_RIFF |
755 |
int8_t word; |
756 |
ReadSceptical(&word,1,1); |
757 |
return word; |
758 |
} |
759 |
|
760 |
/** |
761 |
* Reads one 8 Bit unsigned integer word and increments the position |
762 |
* within the chunk. |
763 |
* |
764 |
* @returns read integer word |
765 |
* @throws RIFF::Exception if an error occurred |
766 |
*/ |
767 |
uint8_t Chunk::ReadUint8() { |
768 |
#if DEBUG_RIFF |
769 |
std::cout << "Chunk::ReadUint8()" << std::endl; |
770 |
#endif // DEBUG_RIFF |
771 |
uint8_t word; |
772 |
ReadSceptical(&word,1,1); |
773 |
return word; |
774 |
} |
775 |
|
776 |
/** |
777 |
* Reads one 16 Bit signed integer word and increments the position |
778 |
* within the chunk. Endian correction will automatically be done if |
779 |
* needed. |
780 |
* |
781 |
* @returns read integer word |
782 |
* @throws RIFF::Exception if an error occurred |
783 |
*/ |
784 |
int16_t Chunk::ReadInt16() { |
785 |
#if DEBUG_RIFF |
786 |
std::cout << "Chunk::ReadInt16()" << std::endl; |
787 |
#endif // DEBUG_RIFF |
788 |
int16_t word; |
789 |
ReadSceptical(&word,1,2); |
790 |
return word; |
791 |
} |
792 |
|
793 |
/** |
794 |
* Reads one 16 Bit unsigned integer word and increments the position |
795 |
* within the chunk. Endian correction will automatically be done if |
796 |
* needed. |
797 |
* |
798 |
* @returns read integer word |
799 |
* @throws RIFF::Exception if an error occurred |
800 |
*/ |
801 |
uint16_t Chunk::ReadUint16() { |
802 |
#if DEBUG_RIFF |
803 |
std::cout << "Chunk::ReadUint16()" << std::endl; |
804 |
#endif // DEBUG_RIFF |
805 |
uint16_t word; |
806 |
ReadSceptical(&word,1,2); |
807 |
return word; |
808 |
} |
809 |
|
810 |
/** |
811 |
* Reads one 32 Bit signed integer word and increments the position |
812 |
* within the chunk. Endian correction will automatically be done if |
813 |
* needed. |
814 |
* |
815 |
* @returns read integer word |
816 |
* @throws RIFF::Exception if an error occurred |
817 |
*/ |
818 |
int32_t Chunk::ReadInt32() { |
819 |
#if DEBUG_RIFF |
820 |
std::cout << "Chunk::ReadInt32()" << std::endl; |
821 |
#endif // DEBUG_RIFF |
822 |
int32_t word; |
823 |
ReadSceptical(&word,1,4); |
824 |
return word; |
825 |
} |
826 |
|
827 |
/** |
828 |
* Reads one 32 Bit unsigned integer word and increments the position |
829 |
* within the chunk. Endian correction will automatically be done if |
830 |
* needed. |
831 |
* |
832 |
* @returns read integer word |
833 |
* @throws RIFF::Exception if an error occurred |
834 |
*/ |
835 |
uint32_t Chunk::ReadUint32() { |
836 |
#if DEBUG_RIFF |
837 |
std::cout << "Chunk::ReadUint32()" << std::endl; |
838 |
#endif // DEBUG_RIFF |
839 |
uint32_t word; |
840 |
ReadSceptical(&word,1,4); |
841 |
return word; |
842 |
} |
843 |
|
844 |
/** @brief Load chunk body into RAM. |
845 |
* |
846 |
* Loads the whole chunk body into memory. You can modify the data in |
847 |
* RAM and save the data by calling File::Save() afterwards. |
848 |
* |
849 |
* <b>Caution:</b> the buffer pointer will be invalidated once |
850 |
* File::Save() was called. You have to call LoadChunkData() again to |
851 |
* get a new, valid pointer whenever File::Save() was called. |
852 |
* |
853 |
* You can call LoadChunkData() again if you previously scheduled to |
854 |
* enlarge this chunk with a Resize() call. In that case the buffer will |
855 |
* be enlarged to the new, scheduled chunk size and you can already |
856 |
* place the new chunk data to the buffer and finally call File::Save() |
857 |
* to enlarge the chunk physically and write the new data in one rush. |
858 |
* This approach is definitely recommended if you have to enlarge and |
859 |
* write new data to a lot of chunks. |
860 |
* |
861 |
* @returns a pointer to the data in RAM on success, NULL otherwise |
862 |
* @throws Exception if data buffer could not be enlarged |
863 |
* @see ReleaseChunkData() |
864 |
*/ |
865 |
void* Chunk::LoadChunkData() { |
866 |
if (!pChunkData && pFile->Filename != "" /*&& ulStartPos != 0*/) { |
867 |
#if POSIX |
868 |
if (lseek(pFile->hFileRead, ullStartPos, SEEK_SET) == -1) return NULL; |
869 |
#elif defined(WIN32) |
870 |
LARGE_INTEGER liFilePos; |
871 |
liFilePos.QuadPart = ullStartPos; |
872 |
if (!SetFilePointerEx(pFile->hFileRead, liFilePos, NULL/*new pos pointer*/, FILE_BEGIN)) return NULL; |
873 |
#else |
874 |
if (fseeko(pFile->hFileRead, ullStartPos, SEEK_SET)) return NULL; |
875 |
#endif // POSIX |
876 |
file_offset_t ullBufferSize = (ullCurrentChunkSize > ullNewChunkSize) ? ullCurrentChunkSize : ullNewChunkSize; |
877 |
pChunkData = new uint8_t[ullBufferSize]; |
878 |
if (!pChunkData) return NULL; |
879 |
memset(pChunkData, 0, ullBufferSize); |
880 |
#if POSIX |
881 |
file_offset_t readWords = read(pFile->hFileRead, pChunkData, GetSize()); |
882 |
#elif defined(WIN32) |
883 |
DWORD readWords; |
884 |
ReadFile(pFile->hFileRead, pChunkData, GetSize(), &readWords, NULL); //FIXME: won't load chunks larger than 2GB ! |
885 |
#else |
886 |
file_offset_t readWords = fread(pChunkData, 1, GetSize(), pFile->hFileRead); |
887 |
#endif // POSIX |
888 |
if (readWords != GetSize()) { |
889 |
delete[] pChunkData; |
890 |
return (pChunkData = NULL); |
891 |
} |
892 |
ullChunkDataSize = ullBufferSize; |
893 |
} else if (ullNewChunkSize > ullChunkDataSize) { |
894 |
uint8_t* pNewBuffer = new uint8_t[ullNewChunkSize]; |
895 |
if (!pNewBuffer) throw Exception("Could not enlarge chunk data buffer to " + ToString(ullNewChunkSize) + " bytes"); |
896 |
memset(pNewBuffer, 0 , ullNewChunkSize); |
897 |
if (pChunkData) { |
898 |
memcpy(pNewBuffer, pChunkData, ullChunkDataSize); |
899 |
delete[] pChunkData; |
900 |
} |
901 |
pChunkData = pNewBuffer; |
902 |
ullChunkDataSize = ullNewChunkSize; |
903 |
} |
904 |
return pChunkData; |
905 |
} |
906 |
|
907 |
/** @brief Free loaded chunk body from RAM. |
908 |
* |
909 |
* Frees loaded chunk body data from memory (RAM). You should call |
910 |
* File::Save() before calling this method if you modified the data to |
911 |
* make the changes persistent. |
912 |
*/ |
913 |
void Chunk::ReleaseChunkData() { |
914 |
if (pChunkData) { |
915 |
delete[] pChunkData; |
916 |
pChunkData = NULL; |
917 |
} |
918 |
} |
919 |
|
920 |
/** @brief Resize chunk. |
921 |
* |
922 |
* Resizes this chunk's body, that is the actual size of data possible |
923 |
* to be written to this chunk. This call will return immediately and |
924 |
* just schedule the resize operation. You should call File::Save() to |
925 |
* actually perform the resize operation(s) "physically" to the file. |
926 |
* As this can take a while on large files, it is recommended to call |
927 |
* Resize() first on all chunks which have to be resized and finally to |
928 |
* call File::Save() to perform all those resize operations in one rush. |
929 |
* |
930 |
* <b>Caution:</b> You cannot directly write to enlarged chunks before |
931 |
* calling File::Save() as this might exceed the current chunk's body |
932 |
* boundary! |
933 |
* |
934 |
* @param NewSize - new chunk body size in bytes (must be greater than zero) |
935 |
* @throws RIFF::Exception if \a NewSize is less than 1 or unrealistic large |
936 |
* @see File::Save() |
937 |
*/ |
938 |
void Chunk::Resize(file_offset_t NewSize) { |
939 |
if (NewSize == 0) |
940 |
throw Exception("There is at least one empty chunk (zero size): " + __resolveChunkPath(this)); |
941 |
if ((NewSize >> 48) != 0) |
942 |
throw Exception("Unrealistic high chunk size detected: " + __resolveChunkPath(this)); |
943 |
if (ullNewChunkSize == NewSize) return; |
944 |
ullNewChunkSize = NewSize; |
945 |
} |
946 |
|
947 |
/** @brief Write chunk persistently e.g. to disk. |
948 |
* |
949 |
* Stores the chunk persistently to its actual "physical" file. |
950 |
* |
951 |
* @param ullWritePos - position within the "physical" file where this |
952 |
* chunk should be written to |
953 |
* @param ullCurrentDataOffset - offset of current (old) data within |
954 |
* the file |
955 |
* @param pProgress - optional: callback function for progress notification |
956 |
* @returns new write position in the "physical" file, that is |
957 |
* \a ullWritePos incremented by this chunk's new size |
958 |
* (including its header size of course) |
959 |
*/ |
960 |
file_offset_t Chunk::WriteChunk(file_offset_t ullWritePos, file_offset_t ullCurrentDataOffset, progress_t* pProgress) { |
961 |
const file_offset_t ullOriginalPos = ullWritePos; |
962 |
ullWritePos += CHUNK_HEADER_SIZE(pFile->FileOffsetSize); |
963 |
|
964 |
if (pFile->Mode != stream_mode_read_write) |
965 |
throw Exception("Cannot write list chunk, file has to be opened in read+write mode"); |
966 |
|
967 |
// if the whole chunk body was loaded into RAM |
968 |
if (pChunkData) { |
969 |
// make sure chunk data buffer in RAM is at least as large as the new chunk size |
970 |
LoadChunkData(); |
971 |
// write chunk data from RAM persistently to the file |
972 |
#if POSIX |
973 |
lseek(pFile->hFileWrite, ullWritePos, SEEK_SET); |
974 |
if (write(pFile->hFileWrite, pChunkData, ullNewChunkSize) != ullNewChunkSize) { |
975 |
throw Exception("Writing Chunk data (from RAM) failed"); |
976 |
} |
977 |
#elif defined(WIN32) |
978 |
LARGE_INTEGER liFilePos; |
979 |
liFilePos.QuadPart = ullWritePos; |
980 |
SetFilePointerEx(pFile->hFileWrite, liFilePos, NULL/*new pos pointer*/, FILE_BEGIN); |
981 |
DWORD dwBytesWritten; |
982 |
WriteFile(pFile->hFileWrite, pChunkData, ullNewChunkSize, &dwBytesWritten, NULL); //FIXME: won't save chunks larger than 2GB ! |
983 |
if (dwBytesWritten != ullNewChunkSize) { |
984 |
throw Exception("Writing Chunk data (from RAM) failed"); |
985 |
} |
986 |
#else |
987 |
fseeko(pFile->hFileWrite, ullWritePos, SEEK_SET); |
988 |
if (fwrite(pChunkData, 1, ullNewChunkSize, pFile->hFileWrite) != ullNewChunkSize) { |
989 |
throw Exception("Writing Chunk data (from RAM) failed"); |
990 |
} |
991 |
#endif // POSIX |
992 |
} else { |
993 |
// move chunk data from the end of the file to the appropriate position |
994 |
int8_t* pCopyBuffer = new int8_t[4096]; |
995 |
file_offset_t ullToMove = (ullNewChunkSize < ullCurrentChunkSize) ? ullNewChunkSize : ullCurrentChunkSize; |
996 |
#if defined(WIN32) |
997 |
DWORD iBytesMoved = 1; // we have to pass it via pointer to the Windows API, thus the correct size must be ensured |
998 |
#else |
999 |
int iBytesMoved = 1; |
1000 |
#endif |
1001 |
for (file_offset_t ullOffset = 0; ullToMove > 0 && iBytesMoved > 0; ullOffset += iBytesMoved, ullToMove -= iBytesMoved) { |
1002 |
iBytesMoved = (ullToMove < 4096) ? int(ullToMove) : 4096; |
1003 |
#if POSIX |
1004 |
lseek(pFile->hFileRead, ullStartPos + ullCurrentDataOffset + ullOffset, SEEK_SET); |
1005 |
iBytesMoved = (int) read(pFile->hFileRead, pCopyBuffer, (size_t) iBytesMoved); |
1006 |
lseek(pFile->hFileWrite, ullWritePos + ullOffset, SEEK_SET); |
1007 |
iBytesMoved = (int) write(pFile->hFileWrite, pCopyBuffer, (size_t) iBytesMoved); |
1008 |
#elif defined(WIN32) |
1009 |
LARGE_INTEGER liFilePos; |
1010 |
liFilePos.QuadPart = ullStartPos + ullCurrentDataOffset + ullOffset; |
1011 |
SetFilePointerEx(pFile->hFileRead, liFilePos, NULL/*new pos pointer*/, FILE_BEGIN); |
1012 |
ReadFile(pFile->hFileRead, pCopyBuffer, iBytesMoved, &iBytesMoved, NULL); |
1013 |
liFilePos.QuadPart = ullWritePos + ullOffset; |
1014 |
SetFilePointerEx(pFile->hFileWrite, liFilePos, NULL/*new pos pointer*/, FILE_BEGIN); |
1015 |
WriteFile(pFile->hFileWrite, pCopyBuffer, iBytesMoved, &iBytesMoved, NULL); |
1016 |
#else |
1017 |
fseeko(pFile->hFileRead, ullStartPos + ullCurrentDataOffset + ullOffset, SEEK_SET); |
1018 |
iBytesMoved = fread(pCopyBuffer, 1, iBytesMoved, pFile->hFileRead); |
1019 |
fseeko(pFile->hFileWrite, ullWritePos + ullOffset, SEEK_SET); |
1020 |
iBytesMoved = fwrite(pCopyBuffer, 1, iBytesMoved, pFile->hFileWrite); |
1021 |
#endif |
1022 |
} |
1023 |
delete[] pCopyBuffer; |
1024 |
if (iBytesMoved < 0) throw Exception("Writing Chunk data (from file) failed"); |
1025 |
} |
1026 |
|
1027 |
// update this chunk's header |
1028 |
ullCurrentChunkSize = ullNewChunkSize; |
1029 |
WriteHeader(ullOriginalPos); |
1030 |
|
1031 |
if (pProgress) |
1032 |
__notify_progress(pProgress, 1.0); // notify done |
1033 |
|
1034 |
// update chunk's position pointers |
1035 |
ullStartPos = ullOriginalPos + CHUNK_HEADER_SIZE(pFile->FileOffsetSize); |
1036 |
ullPos = 0; |
1037 |
|
1038 |
// add pad byte if needed |
1039 |
if ((ullStartPos + ullNewChunkSize) % 2 != 0) { |
1040 |
const char cPadByte = 0; |
1041 |
#if POSIX |
1042 |
lseek(pFile->hFileWrite, ullStartPos + ullNewChunkSize, SEEK_SET); |
1043 |
write(pFile->hFileWrite, &cPadByte, 1); |
1044 |
#elif defined(WIN32) |
1045 |
LARGE_INTEGER liFilePos; |
1046 |
liFilePos.QuadPart = ullStartPos + ullNewChunkSize; |
1047 |
SetFilePointerEx(pFile->hFileWrite, liFilePos, NULL/*new pos pointer*/, FILE_BEGIN); |
1048 |
DWORD dwBytesWritten; |
1049 |
WriteFile(pFile->hFileWrite, &cPadByte, 1, &dwBytesWritten, NULL); |
1050 |
#else |
1051 |
fseeko(pFile->hFileWrite, ullStartPos + ullNewChunkSize, SEEK_SET); |
1052 |
fwrite(&cPadByte, 1, 1, pFile->hFileWrite); |
1053 |
#endif |
1054 |
return ullStartPos + ullNewChunkSize + 1; |
1055 |
} |
1056 |
|
1057 |
return ullStartPos + ullNewChunkSize; |
1058 |
} |
1059 |
|
1060 |
void Chunk::__resetPos() { |
1061 |
ullPos = 0; |
1062 |
} |
1063 |
|
1064 |
|
1065 |
|
1066 |
// *************** List *************** |
1067 |
// * |
1068 |
|
1069 |
List::List(File* pFile) : Chunk(pFile) { |
1070 |
#if DEBUG_RIFF |
1071 |
std::cout << "List::List(File* pFile)" << std::endl; |
1072 |
#endif // DEBUG_RIFF |
1073 |
pSubChunks = NULL; |
1074 |
pSubChunksMap = NULL; |
1075 |
} |
1076 |
|
1077 |
List::List(File* pFile, file_offset_t StartPos, List* Parent) |
1078 |
: Chunk(pFile, StartPos, Parent) { |
1079 |
#if DEBUG_RIFF |
1080 |
std::cout << "List::List(File*,file_offset_t,List*)" << std::endl; |
1081 |
#endif // DEBUG_RIFF |
1082 |
pSubChunks = NULL; |
1083 |
pSubChunksMap = NULL; |
1084 |
ReadHeader(StartPos); |
1085 |
ullStartPos = StartPos + LIST_HEADER_SIZE(pFile->FileOffsetSize); |
1086 |
} |
1087 |
|
1088 |
List::List(File* pFile, List* pParent, uint32_t uiListID) |
1089 |
: Chunk(pFile, pParent, CHUNK_ID_LIST, 0) { |
1090 |
pSubChunks = NULL; |
1091 |
pSubChunksMap = NULL; |
1092 |
ListType = uiListID; |
1093 |
} |
1094 |
|
1095 |
List::~List() { |
1096 |
#if DEBUG_RIFF |
1097 |
std::cout << "List::~List()" << std::endl; |
1098 |
#endif // DEBUG_RIFF |
1099 |
DeleteChunkList(); |
1100 |
} |
1101 |
|
1102 |
void List::DeleteChunkList() { |
1103 |
if (pSubChunks) { |
1104 |
ChunkList::iterator iter = pSubChunks->begin(); |
1105 |
ChunkList::iterator end = pSubChunks->end(); |
1106 |
while (iter != end) { |
1107 |
delete *iter; |
1108 |
iter++; |
1109 |
} |
1110 |
delete pSubChunks; |
1111 |
pSubChunks = NULL; |
1112 |
} |
1113 |
if (pSubChunksMap) { |
1114 |
delete pSubChunksMap; |
1115 |
pSubChunksMap = NULL; |
1116 |
} |
1117 |
} |
1118 |
|
1119 |
/** |
1120 |
* Returns subchunk with chunk ID <i>\a ChunkID</i> within this chunk |
1121 |
* list. Use this method if you expect only one subchunk of that type in |
1122 |
* the list. It there are more than one, it's undetermined which one of |
1123 |
* them will be returned! If there are no subchunks with that desired |
1124 |
* chunk ID, NULL will be returned. |
1125 |
* |
1126 |
* @param ChunkID - chunk ID of the sought subchunk |
1127 |
* @returns pointer to the subchunk or NULL if there is none of |
1128 |
* that ID |
1129 |
*/ |
1130 |
Chunk* List::GetSubChunk(uint32_t ChunkID) { |
1131 |
#if DEBUG_RIFF |
1132 |
std::cout << "List::GetSubChunk(uint32_t)" << std::endl; |
1133 |
#endif // DEBUG_RIFF |
1134 |
if (!pSubChunksMap) LoadSubChunks(); |
1135 |
return (*pSubChunksMap)[ChunkID]; |
1136 |
} |
1137 |
|
1138 |
/** |
1139 |
* Returns sublist chunk with list type <i>\a ListType</i> within this |
1140 |
* chunk list. Use this method if you expect only one sublist chunk of |
1141 |
* that type in the list. If there are more than one, it's undetermined |
1142 |
* which one of them will be returned! If there are no sublists with |
1143 |
* that desired list type, NULL will be returned. |
1144 |
* |
1145 |
* @param ListType - list type of the sought sublist |
1146 |
* @returns pointer to the sublist or NULL if there is none of |
1147 |
* that type |
1148 |
*/ |
1149 |
List* List::GetSubList(uint32_t ListType) { |
1150 |
#if DEBUG_RIFF |
1151 |
std::cout << "List::GetSubList(uint32_t)" << std::endl; |
1152 |
#endif // DEBUG_RIFF |
1153 |
if (!pSubChunks) LoadSubChunks(); |
1154 |
ChunkList::iterator iter = pSubChunks->begin(); |
1155 |
ChunkList::iterator end = pSubChunks->end(); |
1156 |
while (iter != end) { |
1157 |
if ((*iter)->GetChunkID() == CHUNK_ID_LIST) { |
1158 |
List* l = (List*) *iter; |
1159 |
if (l->GetListType() == ListType) return l; |
1160 |
} |
1161 |
iter++; |
1162 |
} |
1163 |
return NULL; |
1164 |
} |
1165 |
|
1166 |
/** |
1167 |
* Returns the first subchunk within the list (which may be an ordinary |
1168 |
* chunk as well as a list chunk). You have to call this |
1169 |
* method before you can call GetNextSubChunk(). Recall it when you want |
1170 |
* to start from the beginning of the list again. |
1171 |
* |
1172 |
* @returns pointer to the first subchunk within the list, NULL |
1173 |
* otherwise |
1174 |
*/ |
1175 |
Chunk* List::GetFirstSubChunk() { |
1176 |
#if DEBUG_RIFF |
1177 |
std::cout << "List::GetFirstSubChunk()" << std::endl; |
1178 |
#endif // DEBUG_RIFF |
1179 |
if (!pSubChunks) LoadSubChunks(); |
1180 |
ChunksIterator = pSubChunks->begin(); |
1181 |
return (ChunksIterator != pSubChunks->end()) ? *ChunksIterator : NULL; |
1182 |
} |
1183 |
|
1184 |
/** |
1185 |
* Returns the next subchunk within the list (which may be an ordinary |
1186 |
* chunk as well as a list chunk). You have to call |
1187 |
* GetFirstSubChunk() before you can use this method! |
1188 |
* |
1189 |
* @returns pointer to the next subchunk within the list or NULL if |
1190 |
* end of list is reached |
1191 |
*/ |
1192 |
Chunk* List::GetNextSubChunk() { |
1193 |
#if DEBUG_RIFF |
1194 |
std::cout << "List::GetNextSubChunk()" << std::endl; |
1195 |
#endif // DEBUG_RIFF |
1196 |
if (!pSubChunks) return NULL; |
1197 |
ChunksIterator++; |
1198 |
return (ChunksIterator != pSubChunks->end()) ? *ChunksIterator : NULL; |
1199 |
} |
1200 |
|
1201 |
/** |
1202 |
* Returns the first sublist within the list (that is a subchunk with |
1203 |
* chunk ID "LIST"). You have to call this method before you can call |
1204 |
* GetNextSubList(). Recall it when you want to start from the beginning |
1205 |
* of the list again. |
1206 |
* |
1207 |
* @returns pointer to the first sublist within the list, NULL |
1208 |
* otherwise |
1209 |
*/ |
1210 |
List* List::GetFirstSubList() { |
1211 |
#if DEBUG_RIFF |
1212 |
std::cout << "List::GetFirstSubList()" << std::endl; |
1213 |
#endif // DEBUG_RIFF |
1214 |
if (!pSubChunks) LoadSubChunks(); |
1215 |
ListIterator = pSubChunks->begin(); |
1216 |
ChunkList::iterator end = pSubChunks->end(); |
1217 |
while (ListIterator != end) { |
1218 |
if ((*ListIterator)->GetChunkID() == CHUNK_ID_LIST) return (List*) *ListIterator; |
1219 |
ListIterator++; |
1220 |
} |
1221 |
return NULL; |
1222 |
} |
1223 |
|
1224 |
/** |
1225 |
* Returns the next sublist (that is a subchunk with chunk ID "LIST") |
1226 |
* within the list. You have to call GetFirstSubList() before you can |
1227 |
* use this method! |
1228 |
* |
1229 |
* @returns pointer to the next sublist within the list, NULL if |
1230 |
* end of list is reached |
1231 |
*/ |
1232 |
List* List::GetNextSubList() { |
1233 |
#if DEBUG_RIFF |
1234 |
std::cout << "List::GetNextSubList()" << std::endl; |
1235 |
#endif // DEBUG_RIFF |
1236 |
if (!pSubChunks) return NULL; |
1237 |
if (ListIterator == pSubChunks->end()) return NULL; |
1238 |
ListIterator++; |
1239 |
ChunkList::iterator end = pSubChunks->end(); |
1240 |
while (ListIterator != end) { |
1241 |
if ((*ListIterator)->GetChunkID() == CHUNK_ID_LIST) return (List*) *ListIterator; |
1242 |
ListIterator++; |
1243 |
} |
1244 |
return NULL; |
1245 |
} |
1246 |
|
1247 |
/** |
1248 |
* Returns number of subchunks within the list (including list chunks). |
1249 |
*/ |
1250 |
size_t List::CountSubChunks() { |
1251 |
if (!pSubChunks) LoadSubChunks(); |
1252 |
return pSubChunks->size(); |
1253 |
} |
1254 |
|
1255 |
/** |
1256 |
* Returns number of subchunks within the list with chunk ID |
1257 |
* <i>\a ChunkId</i>. |
1258 |
*/ |
1259 |
size_t List::CountSubChunks(uint32_t ChunkID) { |
1260 |
size_t result = 0; |
1261 |
if (!pSubChunks) LoadSubChunks(); |
1262 |
ChunkList::iterator iter = pSubChunks->begin(); |
1263 |
ChunkList::iterator end = pSubChunks->end(); |
1264 |
while (iter != end) { |
1265 |
if ((*iter)->GetChunkID() == ChunkID) { |
1266 |
result++; |
1267 |
} |
1268 |
iter++; |
1269 |
} |
1270 |
return result; |
1271 |
} |
1272 |
|
1273 |
/** |
1274 |
* Returns number of sublists within the list. |
1275 |
*/ |
1276 |
size_t List::CountSubLists() { |
1277 |
return CountSubChunks(CHUNK_ID_LIST); |
1278 |
} |
1279 |
|
1280 |
/** |
1281 |
* Returns number of sublists within the list with list type |
1282 |
* <i>\a ListType</i> |
1283 |
*/ |
1284 |
size_t List::CountSubLists(uint32_t ListType) { |
1285 |
size_t result = 0; |
1286 |
if (!pSubChunks) LoadSubChunks(); |
1287 |
ChunkList::iterator iter = pSubChunks->begin(); |
1288 |
ChunkList::iterator end = pSubChunks->end(); |
1289 |
while (iter != end) { |
1290 |
if ((*iter)->GetChunkID() == CHUNK_ID_LIST) { |
1291 |
List* l = (List*) *iter; |
1292 |
if (l->GetListType() == ListType) result++; |
1293 |
} |
1294 |
iter++; |
1295 |
} |
1296 |
return result; |
1297 |
} |
1298 |
|
1299 |
/** @brief Creates a new sub chunk. |
1300 |
* |
1301 |
* Creates and adds a new sub chunk to this list chunk. Note that the |
1302 |
* chunk's body size given by \a ullBodySize must be greater than zero. |
1303 |
* You have to call File::Save() to make this change persistent to the |
1304 |
* actual file and <b>before</b> performing any data write operations |
1305 |
* on the new chunk! |
1306 |
* |
1307 |
* @param uiChunkID - chunk ID of the new chunk |
1308 |
* @param ullBodySize - size of the new chunk's body, that is its actual |
1309 |
* data size (without header) |
1310 |
* @throws RIFF::Exception if \a ullBodySize equals zero |
1311 |
*/ |
1312 |
Chunk* List::AddSubChunk(uint32_t uiChunkID, file_offset_t ullBodySize) { |
1313 |
if (ullBodySize == 0) throw Exception("Chunk body size must be at least 1 byte"); |
1314 |
if (!pSubChunks) LoadSubChunks(); |
1315 |
Chunk* pNewChunk = new Chunk(pFile, this, uiChunkID, 0); |
1316 |
pSubChunks->push_back(pNewChunk); |
1317 |
(*pSubChunksMap)[uiChunkID] = pNewChunk; |
1318 |
pNewChunk->Resize(ullBodySize); |
1319 |
ullNewChunkSize += CHUNK_HEADER_SIZE(pFile->FileOffsetSize); |
1320 |
return pNewChunk; |
1321 |
} |
1322 |
|
1323 |
/** @brief Moves a sub chunk witin this list. |
1324 |
* |
1325 |
* Moves a sub chunk from one position in this list to another |
1326 |
* position in the same list. The pSrc chunk is placed before the |
1327 |
* pDst chunk. |
1328 |
* |
1329 |
* @param pSrc - sub chunk to be moved |
1330 |
* @param pDst - the position to move to. pSrc will be placed |
1331 |
* before pDst. If pDst is 0, pSrc will be placed |
1332 |
* last in list. |
1333 |
*/ |
1334 |
void List::MoveSubChunk(Chunk* pSrc, Chunk* pDst) { |
1335 |
if (!pSubChunks) LoadSubChunks(); |
1336 |
pSubChunks->remove(pSrc); |
1337 |
ChunkList::iterator iter = find(pSubChunks->begin(), pSubChunks->end(), pDst); |
1338 |
pSubChunks->insert(iter, pSrc); |
1339 |
} |
1340 |
|
1341 |
/** @brief Moves a sub chunk from this list to another list. |
1342 |
* |
1343 |
* Moves a sub chunk from this list list to the end of another |
1344 |
* list. |
1345 |
* |
1346 |
* @param pSrc - sub chunk to be moved |
1347 |
* @param pDst - destination list where the chunk shall be moved to |
1348 |
*/ |
1349 |
void List::MoveSubChunk(Chunk* pSrc, List* pNewParent) { |
1350 |
if (pNewParent == this || !pNewParent) return; |
1351 |
if (!pSubChunks) LoadSubChunks(); |
1352 |
if (!pNewParent->pSubChunks) pNewParent->LoadSubChunks(); |
1353 |
pSubChunks->remove(pSrc); |
1354 |
pNewParent->pSubChunks->push_back(pSrc); |
1355 |
// update chunk id map of this List |
1356 |
if ((*pSubChunksMap)[pSrc->GetChunkID()] == pSrc) { |
1357 |
pSubChunksMap->erase(pSrc->GetChunkID()); |
1358 |
// try to find another chunk of the same chunk ID |
1359 |
ChunkList::iterator iter = pSubChunks->begin(); |
1360 |
ChunkList::iterator end = pSubChunks->end(); |
1361 |
for (; iter != end; ++iter) { |
1362 |
if ((*iter)->GetChunkID() == pSrc->GetChunkID()) { |
1363 |
(*pSubChunksMap)[pSrc->GetChunkID()] = *iter; |
1364 |
break; // we're done, stop search |
1365 |
} |
1366 |
} |
1367 |
} |
1368 |
// update chunk id map of other list |
1369 |
if (!(*pNewParent->pSubChunksMap)[pSrc->GetChunkID()]) |
1370 |
(*pNewParent->pSubChunksMap)[pSrc->GetChunkID()] = pSrc; |
1371 |
} |
1372 |
|
1373 |
/** @brief Creates a new list sub chunk. |
1374 |
* |
1375 |
* Creates and adds a new list sub chunk to this list chunk. Note that |
1376 |
* you have to add sub chunks / sub list chunks to the new created chunk |
1377 |
* <b>before</b> trying to make this change persisten to the actual |
1378 |
* file with File::Save()! |
1379 |
* |
1380 |
* @param uiListType - list ID of the new list chunk |
1381 |
*/ |
1382 |
List* List::AddSubList(uint32_t uiListType) { |
1383 |
if (!pSubChunks) LoadSubChunks(); |
1384 |
List* pNewListChunk = new List(pFile, this, uiListType); |
1385 |
pSubChunks->push_back(pNewListChunk); |
1386 |
(*pSubChunksMap)[CHUNK_ID_LIST] = pNewListChunk; |
1387 |
ullNewChunkSize += LIST_HEADER_SIZE(pFile->FileOffsetSize); |
1388 |
return pNewListChunk; |
1389 |
} |
1390 |
|
1391 |
/** @brief Removes a sub chunk. |
1392 |
* |
1393 |
* Removes the sub chunk given by \a pSubChunk from this list and frees |
1394 |
* it completely from RAM. The given chunk can either be a normal sub |
1395 |
* chunk or a list sub chunk. In case the given chunk is a list chunk, |
1396 |
* all its subchunks (if any) will be removed recursively as well. You |
1397 |
* should call File::Save() to make this change persistent at any time. |
1398 |
* |
1399 |
* @param pSubChunk - sub chunk or sub list chunk to be removed |
1400 |
*/ |
1401 |
void List::DeleteSubChunk(Chunk* pSubChunk) { |
1402 |
if (!pSubChunks) LoadSubChunks(); |
1403 |
pSubChunks->remove(pSubChunk); |
1404 |
if ((*pSubChunksMap)[pSubChunk->GetChunkID()] == pSubChunk) { |
1405 |
pSubChunksMap->erase(pSubChunk->GetChunkID()); |
1406 |
// try to find another chunk of the same chunk ID |
1407 |
ChunkList::iterator iter = pSubChunks->begin(); |
1408 |
ChunkList::iterator end = pSubChunks->end(); |
1409 |
for (; iter != end; ++iter) { |
1410 |
if ((*iter)->GetChunkID() == pSubChunk->GetChunkID()) { |
1411 |
(*pSubChunksMap)[pSubChunk->GetChunkID()] = *iter; |
1412 |
break; // we're done, stop search |
1413 |
} |
1414 |
} |
1415 |
} |
1416 |
delete pSubChunk; |
1417 |
} |
1418 |
|
1419 |
/** |
1420 |
* Returns the actual total size in bytes (including List chunk header and |
1421 |
* all subchunks) of this List Chunk if being stored to a file. |
1422 |
* |
1423 |
* @param fileOffsetSize - RIFF file offset size (in bytes) assumed when |
1424 |
* being saved to a file |
1425 |
*/ |
1426 |
file_offset_t List::RequiredPhysicalSize(int fileOffsetSize) { |
1427 |
if (!pSubChunks) LoadSubChunks(); |
1428 |
file_offset_t size = LIST_HEADER_SIZE(fileOffsetSize); |
1429 |
ChunkList::iterator iter = pSubChunks->begin(); |
1430 |
ChunkList::iterator end = pSubChunks->end(); |
1431 |
for (; iter != end; ++iter) |
1432 |
size += (*iter)->RequiredPhysicalSize(fileOffsetSize); |
1433 |
return size; |
1434 |
} |
1435 |
|
1436 |
void List::ReadHeader(file_offset_t filePos) { |
1437 |
#if DEBUG_RIFF |
1438 |
std::cout << "List::Readheader(file_offset_t) "; |
1439 |
#endif // DEBUG_RIFF |
1440 |
Chunk::ReadHeader(filePos); |
1441 |
if (ullCurrentChunkSize < 4) return; |
1442 |
ullNewChunkSize = ullCurrentChunkSize -= 4; |
1443 |
#if POSIX |
1444 |
lseek(pFile->hFileRead, filePos + CHUNK_HEADER_SIZE(pFile->FileOffsetSize), SEEK_SET); |
1445 |
read(pFile->hFileRead, &ListType, 4); |
1446 |
#elif defined(WIN32) |
1447 |
LARGE_INTEGER liFilePos; |
1448 |
liFilePos.QuadPart = filePos + CHUNK_HEADER_SIZE(pFile->FileOffsetSize); |
1449 |
SetFilePointerEx(pFile->hFileRead, liFilePos, NULL/*new pos pointer*/, FILE_BEGIN); |
1450 |
DWORD dwBytesRead; |
1451 |
ReadFile(pFile->hFileRead, &ListType, 4, &dwBytesRead, NULL); |
1452 |
#else |
1453 |
fseeko(pFile->hFileRead, filePos + CHUNK_HEADER_SIZE(pFile->FileOffsetSize), SEEK_SET); |
1454 |
fread(&ListType, 4, 1, pFile->hFileRead); |
1455 |
#endif // POSIX |
1456 |
#if DEBUG_RIFF |
1457 |
std::cout << "listType=" << convertToString(ListType) << std::endl; |
1458 |
#endif // DEBUG_RIFF |
1459 |
if (!pFile->bEndianNative) { |
1460 |
//swapBytes_32(&ListType); |
1461 |
} |
1462 |
} |
1463 |
|
1464 |
void List::WriteHeader(file_offset_t filePos) { |
1465 |
// the four list type bytes officially belong the chunk's body in the RIFF format |
1466 |
ullNewChunkSize += 4; |
1467 |
Chunk::WriteHeader(filePos); |
1468 |
ullNewChunkSize -= 4; // just revert the +4 incrementation |
1469 |
#if POSIX |
1470 |
lseek(pFile->hFileWrite, filePos + CHUNK_HEADER_SIZE(pFile->FileOffsetSize), SEEK_SET); |
1471 |
write(pFile->hFileWrite, &ListType, 4); |
1472 |
#elif defined(WIN32) |
1473 |
LARGE_INTEGER liFilePos; |
1474 |
liFilePos.QuadPart = filePos + CHUNK_HEADER_SIZE(pFile->FileOffsetSize); |
1475 |
SetFilePointerEx(pFile->hFileWrite, liFilePos, NULL/*new pos pointer*/, FILE_BEGIN); |
1476 |
DWORD dwBytesWritten; |
1477 |
WriteFile(pFile->hFileWrite, &ListType, 4, &dwBytesWritten, NULL); |
1478 |
#else |
1479 |
fseeko(pFile->hFileWrite, filePos + CHUNK_HEADER_SIZE(pFile->FileOffsetSize), SEEK_SET); |
1480 |
fwrite(&ListType, 4, 1, pFile->hFileWrite); |
1481 |
#endif // POSIX |
1482 |
} |
1483 |
|
1484 |
void List::LoadSubChunks(progress_t* pProgress) { |
1485 |
#if DEBUG_RIFF |
1486 |
std::cout << "List::LoadSubChunks()"; |
1487 |
#endif // DEBUG_RIFF |
1488 |
if (!pSubChunks) { |
1489 |
pSubChunks = new ChunkList(); |
1490 |
pSubChunksMap = new ChunkMap(); |
1491 |
#if defined(WIN32) |
1492 |
if (pFile->hFileRead == INVALID_HANDLE_VALUE) return; |
1493 |
#else |
1494 |
if (!pFile->hFileRead) return; |
1495 |
#endif |
1496 |
file_offset_t ullOriginalPos = GetPos(); |
1497 |
SetPos(0); // jump to beginning of list chunk body |
1498 |
while (RemainingBytes() >= CHUNK_HEADER_SIZE(pFile->FileOffsetSize)) { |
1499 |
Chunk* ck; |
1500 |
uint32_t ckid; |
1501 |
// return value check is required here to prevent a potential |
1502 |
// garbage data use of 'ckid' below in case Read() failed |
1503 |
if (Read(&ckid, 4, 1) != 4) |
1504 |
throw Exception("LoadSubChunks(): Failed reading RIFF chunk ID"); |
1505 |
#if DEBUG_RIFF |
1506 |
std::cout << " ckid=" << convertToString(ckid) << std::endl; |
1507 |
#endif // DEBUG_RIFF |
1508 |
if (ckid == CHUNK_ID_LIST) { |
1509 |
ck = new RIFF::List(pFile, ullStartPos + ullPos - 4, this); |
1510 |
SetPos(ck->GetSize() + LIST_HEADER_SIZE(pFile->FileOffsetSize) - 4, RIFF::stream_curpos); |
1511 |
} |
1512 |
else { // simple chunk |
1513 |
ck = new RIFF::Chunk(pFile, ullStartPos + ullPos - 4, this); |
1514 |
SetPos(ck->GetSize() + CHUNK_HEADER_SIZE(pFile->FileOffsetSize) - 4, RIFF::stream_curpos); |
1515 |
} |
1516 |
pSubChunks->push_back(ck); |
1517 |
(*pSubChunksMap)[ckid] = ck; |
1518 |
if (GetPos() % 2 != 0) SetPos(1, RIFF::stream_curpos); // jump over pad byte |
1519 |
} |
1520 |
SetPos(ullOriginalPos); // restore position before this call |
1521 |
} |
1522 |
if (pProgress) |
1523 |
__notify_progress(pProgress, 1.0); // notify done |
1524 |
} |
1525 |
|
1526 |
void List::LoadSubChunksRecursively(progress_t* pProgress) { |
1527 |
const int n = (int) CountSubLists(); |
1528 |
int i = 0; |
1529 |
for (List* pList = GetFirstSubList(); pList; pList = GetNextSubList(), ++i) { |
1530 |
if (pProgress) { |
1531 |
// divide local progress into subprogress |
1532 |
progress_t subprogress; |
1533 |
__divide_progress(pProgress, &subprogress, n, i); |
1534 |
// do the actual work |
1535 |
pList->LoadSubChunksRecursively(&subprogress); |
1536 |
} else |
1537 |
pList->LoadSubChunksRecursively(NULL); |
1538 |
} |
1539 |
if (pProgress) |
1540 |
__notify_progress(pProgress, 1.0); // notify done |
1541 |
} |
1542 |
|
1543 |
/** @brief Write list chunk persistently e.g. to disk. |
1544 |
* |
1545 |
* Stores the list chunk persistently to its actual "physical" file. All |
1546 |
* subchunks (including sub list chunks) will be stored recursively as |
1547 |
* well. |
1548 |
* |
1549 |
* @param ullWritePos - position within the "physical" file where this |
1550 |
* list chunk should be written to |
1551 |
* @param ullCurrentDataOffset - offset of current (old) data within |
1552 |
* the file |
1553 |
* @param pProgress - optional: callback function for progress notification |
1554 |
* @returns new write position in the "physical" file, that is |
1555 |
* \a ullWritePos incremented by this list chunk's new size |
1556 |
* (including its header size of course) |
1557 |
*/ |
1558 |
file_offset_t List::WriteChunk(file_offset_t ullWritePos, file_offset_t ullCurrentDataOffset, progress_t* pProgress) { |
1559 |
const file_offset_t ullOriginalPos = ullWritePos; |
1560 |
ullWritePos += LIST_HEADER_SIZE(pFile->FileOffsetSize); |
1561 |
|
1562 |
if (pFile->Mode != stream_mode_read_write) |
1563 |
throw Exception("Cannot write list chunk, file has to be opened in read+write mode"); |
1564 |
|
1565 |
// write all subchunks (including sub list chunks) recursively |
1566 |
if (pSubChunks) { |
1567 |
size_t i = 0; |
1568 |
const size_t n = pSubChunks->size(); |
1569 |
for (ChunkList::iterator iter = pSubChunks->begin(), end = pSubChunks->end(); iter != end; ++iter, ++i) { |
1570 |
if (pProgress) { |
1571 |
// divide local progress into subprogress for loading current Instrument |
1572 |
progress_t subprogress; |
1573 |
__divide_progress(pProgress, &subprogress, n, i); |
1574 |
// do the actual work |
1575 |
ullWritePos = (*iter)->WriteChunk(ullWritePos, ullCurrentDataOffset, &subprogress); |
1576 |
} else |
1577 |
ullWritePos = (*iter)->WriteChunk(ullWritePos, ullCurrentDataOffset, NULL); |
1578 |
} |
1579 |
} |
1580 |
|
1581 |
// update this list chunk's header |
1582 |
ullCurrentChunkSize = ullNewChunkSize = ullWritePos - ullOriginalPos - LIST_HEADER_SIZE(pFile->FileOffsetSize); |
1583 |
WriteHeader(ullOriginalPos); |
1584 |
|
1585 |
// offset of this list chunk in new written file may have changed |
1586 |
ullStartPos = ullOriginalPos + LIST_HEADER_SIZE(pFile->FileOffsetSize); |
1587 |
|
1588 |
if (pProgress) |
1589 |
__notify_progress(pProgress, 1.0); // notify done |
1590 |
|
1591 |
return ullWritePos; |
1592 |
} |
1593 |
|
1594 |
void List::__resetPos() { |
1595 |
Chunk::__resetPos(); |
1596 |
if (pSubChunks) { |
1597 |
for (ChunkList::iterator iter = pSubChunks->begin(), end = pSubChunks->end(); iter != end; ++iter) { |
1598 |
(*iter)->__resetPos(); |
1599 |
} |
1600 |
} |
1601 |
} |
1602 |
|
1603 |
/** |
1604 |
* Returns string representation of the lists's id |
1605 |
*/ |
1606 |
String List::GetListTypeString() const { |
1607 |
return convertToString(ListType); |
1608 |
} |
1609 |
|
1610 |
|
1611 |
|
1612 |
// *************** File *************** |
1613 |
// * |
1614 |
|
1615 |
/** @brief Create new RIFF file. |
1616 |
* |
1617 |
* Use this constructor if you want to create a new RIFF file completely |
1618 |
* "from scratch". Note: there must be no empty chunks or empty list |
1619 |
* chunks when trying to make the new RIFF file persistent with Save()! |
1620 |
* |
1621 |
* Note: by default, the RIFF file will be saved in native endian |
1622 |
* format; that is, as a RIFF file on little-endian machines and |
1623 |
* as a RIFX file on big-endian. To change this behaviour, call |
1624 |
* SetByteOrder() before calling Save(). |
1625 |
* |
1626 |
* @param FileType - four-byte identifier of the RIFF file type |
1627 |
* @see AddSubChunk(), AddSubList(), SetByteOrder() |
1628 |
*/ |
1629 |
File::File(uint32_t FileType) |
1630 |
: List(this), bIsNewFile(true), Layout(layout_standard), |
1631 |
FileOffsetPreference(offset_size_auto) |
1632 |
{ |
1633 |
#if defined(WIN32) |
1634 |
hFileRead = hFileWrite = INVALID_HANDLE_VALUE; |
1635 |
#else |
1636 |
hFileRead = hFileWrite = 0; |
1637 |
#endif |
1638 |
Mode = stream_mode_closed; |
1639 |
bEndianNative = true; |
1640 |
ListType = FileType; |
1641 |
FileOffsetSize = 4; |
1642 |
ullStartPos = RIFF_HEADER_SIZE(FileOffsetSize); |
1643 |
} |
1644 |
|
1645 |
/** @brief Load existing RIFF file. |
1646 |
* |
1647 |
* Loads an existing RIFF file with all its chunks. |
1648 |
* |
1649 |
* @param path - path and file name of the RIFF file to open |
1650 |
* @throws RIFF::Exception if error occurred while trying to load the |
1651 |
* given RIFF file |
1652 |
*/ |
1653 |
File::File(const String& path) |
1654 |
: List(this), Filename(path), bIsNewFile(false), Layout(layout_standard), |
1655 |
FileOffsetPreference(offset_size_auto) |
1656 |
{ |
1657 |
#if DEBUG_RIFF |
1658 |
std::cout << "File::File("<<path<<")" << std::endl; |
1659 |
#endif // DEBUG_RIFF |
1660 |
bEndianNative = true; |
1661 |
FileOffsetSize = 4; |
1662 |
try { |
1663 |
__openExistingFile(path); |
1664 |
if (ChunkID != CHUNK_ID_RIFF && ChunkID != CHUNK_ID_RIFX) { |
1665 |
throw RIFF::Exception("Not a RIFF file"); |
1666 |
} |
1667 |
} |
1668 |
catch (...) { |
1669 |
Cleanup(); |
1670 |
throw; |
1671 |
} |
1672 |
} |
1673 |
|
1674 |
/** @brief Load existing RIFF-like file. |
1675 |
* |
1676 |
* Loads an existing file, which is not a "real" RIFF file, but similar to |
1677 |
* an ordinary RIFF file. |
1678 |
* |
1679 |
* A "real" RIFF file contains at top level a List chunk either with chunk |
1680 |
* ID "RIFF" or "RIFX". The simple constructor above expects this to be |
1681 |
* case, and if it finds the toplevel List chunk to have another chunk ID |
1682 |
* than one of those two expected ones, it would throw an Exception and |
1683 |
* would refuse to load the file accordingly. |
1684 |
* |
1685 |
* Since there are however a lot of file formats which use the same simple |
1686 |
* principles of the RIFF format, with another toplevel List chunk ID |
1687 |
* though, you can use this alternative constructor here to be able to load |
1688 |
* and handle those files in the same way as you would do with "real" RIFF |
1689 |
* files. |
1690 |
* |
1691 |
* @param path - path and file name of the RIFF-alike file to be opened |
1692 |
* @param FileType - expected toplevel List chunk ID (this is the very |
1693 |
* first chunk found in the file) |
1694 |
* @param Endian - whether the file uses little endian or big endian layout |
1695 |
* @param layout - general file structure type |
1696 |
* @param fileOffsetSize - (optional) preference how to deal with large files |
1697 |
* @throws RIFF::Exception if error occurred while trying to load the |
1698 |
* given RIFF-alike file |
1699 |
*/ |
1700 |
File::File(const String& path, uint32_t FileType, endian_t Endian, layout_t layout, offset_size_t fileOffsetSize) |
1701 |
: List(this), Filename(path), bIsNewFile(false), Layout(layout), |
1702 |
FileOffsetPreference(fileOffsetSize) |
1703 |
{ |
1704 |
SetByteOrder(Endian); |
1705 |
if (fileOffsetSize < offset_size_auto || fileOffsetSize > offset_size_64bit) |
1706 |
throw Exception("Invalid RIFF::offset_size_t"); |
1707 |
FileOffsetSize = 4; |
1708 |
try { |
1709 |
__openExistingFile(path, &FileType); |
1710 |
} |
1711 |
catch (...) { |
1712 |
Cleanup(); |
1713 |
throw; |
1714 |
} |
1715 |
} |
1716 |
|
1717 |
/** |
1718 |
* Opens an already existing RIFF file or RIFF-alike file. This method |
1719 |
* shall only be called once (in a File class constructor). |
1720 |
* |
1721 |
* @param path - path and file name of the RIFF file or RIFF-alike file to |
1722 |
* be opened |
1723 |
* @param FileType - (optional) expected chunk ID of first chunk in file |
1724 |
* @throws RIFF::Exception if error occurred while trying to load the |
1725 |
* given RIFF file or RIFF-alike file |
1726 |
*/ |
1727 |
void File::__openExistingFile(const String& path, uint32_t* FileType) { |
1728 |
#if POSIX |
1729 |
hFileRead = hFileWrite = open(path.c_str(), O_RDONLY | O_NONBLOCK); |
1730 |
if (hFileRead == -1) { |
1731 |
hFileRead = hFileWrite = 0; |
1732 |
String sError = strerror(errno); |
1733 |
throw RIFF::Exception("Can't open \"" + path + "\": " + sError); |
1734 |
} |
1735 |
#elif defined(WIN32) |
1736 |
hFileRead = hFileWrite = CreateFile( |
1737 |
path.c_str(), GENERIC_READ, |
1738 |
FILE_SHARE_READ | FILE_SHARE_WRITE, |
1739 |
NULL, OPEN_EXISTING, |
1740 |
FILE_ATTRIBUTE_NORMAL | |
1741 |
FILE_FLAG_RANDOM_ACCESS, NULL |
1742 |
); |
1743 |
if (hFileRead == INVALID_HANDLE_VALUE) { |
1744 |
hFileRead = hFileWrite = INVALID_HANDLE_VALUE; |
1745 |
throw RIFF::Exception("Can't open \"" + path + "\""); |
1746 |
} |
1747 |
#else |
1748 |
hFileRead = hFileWrite = fopen(path.c_str(), "rb"); |
1749 |
if (!hFileRead) throw RIFF::Exception("Can't open \"" + path + "\""); |
1750 |
#endif // POSIX |
1751 |
Mode = stream_mode_read; |
1752 |
|
1753 |
// determine RIFF file offset size to be used (in RIFF chunk headers) |
1754 |
// according to the current file offset preference |
1755 |
FileOffsetSize = FileOffsetSizeFor(GetCurrentFileSize()); |
1756 |
|
1757 |
switch (Layout) { |
1758 |
case layout_standard: // this is a normal RIFF file |
1759 |
ullStartPos = RIFF_HEADER_SIZE(FileOffsetSize); |
1760 |
ReadHeader(0); |
1761 |
if (FileType && ChunkID != *FileType) |
1762 |
throw RIFF::Exception("Invalid file container ID"); |
1763 |
break; |
1764 |
case layout_flat: // non-standard RIFF-alike file |
1765 |
ullStartPos = 0; |
1766 |
ullNewChunkSize = ullCurrentChunkSize = GetCurrentFileSize(); |
1767 |
if (FileType) { |
1768 |
uint32_t ckid; |
1769 |
if (Read(&ckid, 4, 1) != 4) { |
1770 |
throw RIFF::Exception("Invalid file header ID (premature end of header)"); |
1771 |
} else if (ckid != *FileType) { |
1772 |
String s = " (expected '" + convertToString(*FileType) + "' but got '" + convertToString(ckid) + "')"; |
1773 |
throw RIFF::Exception("Invalid file header ID" + s); |
1774 |
} |
1775 |
SetPos(0); // reset to first byte of file |
1776 |
} |
1777 |
LoadSubChunks(); |
1778 |
break; |
1779 |
} |
1780 |
} |
1781 |
|
1782 |
String File::GetFileName() const { |
1783 |
return Filename; |
1784 |
} |
1785 |
|
1786 |
void File::SetFileName(const String& path) { |
1787 |
Filename = path; |
1788 |
} |
1789 |
|
1790 |
stream_mode_t File::GetMode() const { |
1791 |
return Mode; |
1792 |
} |
1793 |
|
1794 |
layout_t File::GetLayout() const { |
1795 |
return Layout; |
1796 |
} |
1797 |
|
1798 |
/** @brief Change file access mode. |
1799 |
* |
1800 |
* Changes files access mode either to read-only mode or to read/write |
1801 |
* mode. |
1802 |
* |
1803 |
* @param NewMode - new file access mode |
1804 |
* @returns true if mode was changed, false if current mode already |
1805 |
* equals new mode |
1806 |
* @throws RIFF::Exception if file could not be opened in requested file |
1807 |
* access mode or if passed access mode is unknown |
1808 |
*/ |
1809 |
bool File::SetMode(stream_mode_t NewMode) { |
1810 |
if (NewMode != Mode) { |
1811 |
switch (NewMode) { |
1812 |
case stream_mode_read: |
1813 |
#if POSIX |
1814 |
if (hFileRead) close(hFileRead); |
1815 |
hFileRead = hFileWrite = open(Filename.c_str(), O_RDONLY | O_NONBLOCK); |
1816 |
if (hFileRead == -1) { |
1817 |
hFileRead = hFileWrite = 0; |
1818 |
String sError = strerror(errno); |
1819 |
throw Exception("Could not (re)open file \"" + Filename + "\" in read mode: " + sError); |
1820 |
} |
1821 |
#elif defined(WIN32) |
1822 |
if (hFileRead != INVALID_HANDLE_VALUE) CloseHandle(hFileRead); |
1823 |
hFileRead = hFileWrite = CreateFile( |
1824 |
Filename.c_str(), GENERIC_READ, |
1825 |
FILE_SHARE_READ | FILE_SHARE_WRITE, |
1826 |
NULL, OPEN_EXISTING, |
1827 |
FILE_ATTRIBUTE_NORMAL | |
1828 |
FILE_FLAG_RANDOM_ACCESS, |
1829 |
NULL |
1830 |
); |
1831 |
if (hFileRead == INVALID_HANDLE_VALUE) { |
1832 |
hFileRead = hFileWrite = INVALID_HANDLE_VALUE; |
1833 |
throw Exception("Could not (re)open file \"" + Filename + "\" in read mode"); |
1834 |
} |
1835 |
#else |
1836 |
if (hFileRead) fclose(hFileRead); |
1837 |
hFileRead = hFileWrite = fopen(Filename.c_str(), "rb"); |
1838 |
if (!hFileRead) throw Exception("Could not (re)open file \"" + Filename + "\" in read mode"); |
1839 |
#endif |
1840 |
__resetPos(); // reset read/write position of ALL 'Chunk' objects |
1841 |
break; |
1842 |
case stream_mode_read_write: |
1843 |
#if POSIX |
1844 |
if (hFileRead) close(hFileRead); |
1845 |
hFileRead = hFileWrite = open(Filename.c_str(), O_RDWR | O_NONBLOCK); |
1846 |
if (hFileRead == -1) { |
1847 |
hFileRead = hFileWrite = open(Filename.c_str(), O_RDONLY | O_NONBLOCK); |
1848 |
String sError = strerror(errno); |
1849 |
throw Exception("Could not open file \"" + Filename + "\" in read+write mode: " + sError); |
1850 |
} |
1851 |
#elif defined(WIN32) |
1852 |
if (hFileRead != INVALID_HANDLE_VALUE) CloseHandle(hFileRead); |
1853 |
hFileRead = hFileWrite = CreateFile( |
1854 |
Filename.c_str(), |
1855 |
GENERIC_READ | GENERIC_WRITE, |
1856 |
FILE_SHARE_READ, |
1857 |
NULL, OPEN_ALWAYS, |
1858 |
FILE_ATTRIBUTE_NORMAL | |
1859 |
FILE_FLAG_RANDOM_ACCESS, |
1860 |
NULL |
1861 |
); |
1862 |
if (hFileRead == INVALID_HANDLE_VALUE) { |
1863 |
hFileRead = hFileWrite = CreateFile( |
1864 |
Filename.c_str(), GENERIC_READ, |
1865 |
FILE_SHARE_READ | FILE_SHARE_WRITE, |
1866 |
NULL, OPEN_EXISTING, |
1867 |
FILE_ATTRIBUTE_NORMAL | |
1868 |
FILE_FLAG_RANDOM_ACCESS, |
1869 |
NULL |
1870 |
); |
1871 |
throw Exception("Could not (re)open file \"" + Filename + "\" in read+write mode"); |
1872 |
} |
1873 |
#else |
1874 |
if (hFileRead) fclose(hFileRead); |
1875 |
hFileRead = hFileWrite = fopen(Filename.c_str(), "r+b"); |
1876 |
if (!hFileRead) { |
1877 |
hFileRead = hFileWrite = fopen(Filename.c_str(), "rb"); |
1878 |
throw Exception("Could not open file \"" + Filename + "\" in read+write mode"); |
1879 |
} |
1880 |
#endif |
1881 |
__resetPos(); // reset read/write position of ALL 'Chunk' objects |
1882 |
break; |
1883 |
case stream_mode_closed: |
1884 |
#if POSIX |
1885 |
if (hFileRead) close(hFileRead); |
1886 |
if (hFileWrite) close(hFileWrite); |
1887 |
hFileRead = hFileWrite = 0; |
1888 |
#elif defined(WIN32) |
1889 |
if (hFileRead != INVALID_HANDLE_VALUE) CloseHandle(hFileRead); |
1890 |
if (hFileWrite != INVALID_HANDLE_VALUE) CloseHandle(hFileWrite); |
1891 |
hFileRead = hFileWrite = INVALID_HANDLE_VALUE; |
1892 |
#else |
1893 |
if (hFileRead) fclose(hFileRead); |
1894 |
if (hFileWrite) fclose(hFileWrite); |
1895 |
hFileRead = hFileWrite = NULL; |
1896 |
#endif |
1897 |
break; |
1898 |
default: |
1899 |
throw Exception("Unknown file access mode"); |
1900 |
} |
1901 |
Mode = NewMode; |
1902 |
return true; |
1903 |
} |
1904 |
return false; |
1905 |
} |
1906 |
|
1907 |
/** @brief Set the byte order to be used when saving. |
1908 |
* |
1909 |
* Set the byte order to be used in the file. A value of |
1910 |
* endian_little will create a RIFF file, endian_big a RIFX file |
1911 |
* and endian_native will create a RIFF file on little-endian |
1912 |
* machines and RIFX on big-endian machines. |
1913 |
* |
1914 |
* @param Endian - endianess to use when file is saved. |
1915 |
*/ |
1916 |
void File::SetByteOrder(endian_t Endian) { |
1917 |
#if WORDS_BIGENDIAN |
1918 |
bEndianNative = Endian != endian_little; |
1919 |
#else |
1920 |
bEndianNative = Endian != endian_big; |
1921 |
#endif |
1922 |
} |
1923 |
|
1924 |
/** @brief Save changes to same file. |
1925 |
* |
1926 |
* Make all changes of all chunks persistent by writing them to the |
1927 |
* actual (same) file. |
1928 |
* |
1929 |
* @param pProgress - optional: callback function for progress notification |
1930 |
* @throws RIFF::Exception if there is an empty chunk or empty list |
1931 |
* chunk or any kind of IO error occurred |
1932 |
*/ |
1933 |
void File::Save(progress_t* pProgress) { |
1934 |
//TODO: implementation for the case where first chunk is not a global container (List chunk) is not implemented yet (i.e. Korg files) |
1935 |
if (Layout == layout_flat) |
1936 |
throw Exception("Saving a RIFF file with layout_flat is not implemented yet"); |
1937 |
|
1938 |
// make sure the RIFF tree is built (from the original file) |
1939 |
if (pProgress) { |
1940 |
// divide progress into subprogress |
1941 |
progress_t subprogress; |
1942 |
__divide_progress(pProgress, &subprogress, 3.f, 0.f); // arbitrarily subdivided into 1/3 of total progress |
1943 |
// do the actual work |
1944 |
LoadSubChunksRecursively(&subprogress); |
1945 |
// notify subprogress done |
1946 |
__notify_progress(&subprogress, 1.f); |
1947 |
} else |
1948 |
LoadSubChunksRecursively(NULL); |
1949 |
|
1950 |
// reopen file in write mode |
1951 |
SetMode(stream_mode_read_write); |
1952 |
|
1953 |
// get the current file size as it is now still physically stored on disk |
1954 |
const file_offset_t workingFileSize = GetCurrentFileSize(); |
1955 |
|
1956 |
// get the overall file size required to save this file |
1957 |
const file_offset_t newFileSize = GetRequiredFileSize(FileOffsetPreference); |
1958 |
|
1959 |
// determine whether this file will yield in a large file (>=4GB) and |
1960 |
// the RIFF file offset size to be used accordingly for all chunks |
1961 |
FileOffsetSize = FileOffsetSizeFor(newFileSize); |
1962 |
|
1963 |
// to be able to save the whole file without loading everything into |
1964 |
// RAM and without having to store the data in a temporary file, we |
1965 |
// enlarge the file with the overall positive file size change, |
1966 |
// then move current data towards the end of the file by the calculated |
1967 |
// positive file size difference and finally update / rewrite the file |
1968 |
// by copying the old data back to the right position at the beginning |
1969 |
// of the file |
1970 |
|
1971 |
// if there are positive size changes... |
1972 |
file_offset_t positiveSizeDiff = 0; |
1973 |
if (newFileSize > workingFileSize) { |
1974 |
positiveSizeDiff = newFileSize - workingFileSize; |
1975 |
|
1976 |
// divide progress into subprogress |
1977 |
progress_t subprogress; |
1978 |
if (pProgress) |
1979 |
__divide_progress(pProgress, &subprogress, 3.f, 1.f); // arbitrarily subdivided into 1/3 of total progress |
1980 |
|
1981 |
// ... we enlarge this file first ... |
1982 |
ResizeFile(newFileSize); |
1983 |
|
1984 |
// ... and move current data by the same amount towards end of file. |
1985 |
int8_t* pCopyBuffer = new int8_t[4096]; |
1986 |
#if defined(WIN32) |
1987 |
DWORD iBytesMoved = 1; // we have to pass it via pointer to the Windows API, thus the correct size must be ensured |
1988 |
#else |
1989 |
ssize_t iBytesMoved = 1; |
1990 |
#endif |
1991 |
for (file_offset_t ullPos = workingFileSize, iNotif = 0; iBytesMoved > 0; ++iNotif) { |
1992 |
iBytesMoved = (ullPos < 4096) ? ullPos : 4096; |
1993 |
ullPos -= iBytesMoved; |
1994 |
#if POSIX |
1995 |
lseek(hFileRead, ullPos, SEEK_SET); |
1996 |
iBytesMoved = read(hFileRead, pCopyBuffer, iBytesMoved); |
1997 |
lseek(hFileWrite, ullPos + positiveSizeDiff, SEEK_SET); |
1998 |
iBytesMoved = write(hFileWrite, pCopyBuffer, iBytesMoved); |
1999 |
#elif defined(WIN32) |
2000 |
LARGE_INTEGER liFilePos; |
2001 |
liFilePos.QuadPart = ullPos; |
2002 |
SetFilePointerEx(hFileRead, liFilePos, NULL/*new pos pointer*/, FILE_BEGIN); |
2003 |
ReadFile(hFileRead, pCopyBuffer, iBytesMoved, &iBytesMoved, NULL); |
2004 |
liFilePos.QuadPart = ullPos + positiveSizeDiff; |
2005 |
SetFilePointerEx(hFileWrite, liFilePos, NULL/*new pos pointer*/, FILE_BEGIN); |
2006 |
WriteFile(hFileWrite, pCopyBuffer, iBytesMoved, &iBytesMoved, NULL); |
2007 |
#else |
2008 |
fseeko(hFileRead, ullPos, SEEK_SET); |
2009 |
iBytesMoved = fread(pCopyBuffer, 1, iBytesMoved, hFileRead); |
2010 |
fseeko(hFileWrite, ullPos + positiveSizeDiff, SEEK_SET); |
2011 |
iBytesMoved = fwrite(pCopyBuffer, 1, iBytesMoved, hFileWrite); |
2012 |
#endif |
2013 |
if (pProgress && !(iNotif % 8) && iBytesMoved > 0) |
2014 |
__notify_progress(&subprogress, float(workingFileSize - ullPos) / float(workingFileSize)); |
2015 |
} |
2016 |
delete[] pCopyBuffer; |
2017 |
if (iBytesMoved < 0) throw Exception("Could not modify file while trying to enlarge it"); |
2018 |
|
2019 |
if (pProgress) |
2020 |
__notify_progress(&subprogress, 1.f); // notify subprogress done |
2021 |
} |
2022 |
|
2023 |
// rebuild / rewrite complete RIFF tree ... |
2024 |
|
2025 |
// divide progress into subprogress |
2026 |
progress_t subprogress; |
2027 |
if (pProgress) |
2028 |
__divide_progress(pProgress, &subprogress, 3.f, 2.f); // arbitrarily subdivided into 1/3 of total progress |
2029 |
// do the actual work |
2030 |
const file_offset_t finalSize = WriteChunk(0, positiveSizeDiff, pProgress ? &subprogress : NULL); |
2031 |
const file_offset_t finalActualSize = __GetFileSize(hFileWrite); |
2032 |
// notify subprogress done |
2033 |
if (pProgress) |
2034 |
__notify_progress(&subprogress, 1.f); |
2035 |
|
2036 |
// resize file to the final size |
2037 |
if (finalSize < finalActualSize) ResizeFile(finalSize); |
2038 |
|
2039 |
if (pProgress) |
2040 |
__notify_progress(pProgress, 1.0); // notify done |
2041 |
} |
2042 |
|
2043 |
/** @brief Save changes to another file. |
2044 |
* |
2045 |
* Make all changes of all chunks persistent by writing them to another |
2046 |
* file. <b>Caution:</b> this method is optimized for writing to |
2047 |
* <b>another</b> file, do not use it to save the changes to the same |
2048 |
* file! Use File::Save() in that case instead! Ignoring this might |
2049 |
* result in a corrupted file, especially in case chunks were resized! |
2050 |
* |
2051 |
* After calling this method, this File object will be associated with |
2052 |
* the new file (given by \a path) afterwards. |
2053 |
* |
2054 |
* @param path - path and file name where everything should be written to |
2055 |
* @param pProgress - optional: callback function for progress notification |
2056 |
*/ |
2057 |
void File::Save(const String& path, progress_t* pProgress) { |
2058 |
//TODO: we should make a check here if somebody tries to write to the same file and automatically call the other Save() method in that case |
2059 |
|
2060 |
//TODO: implementation for the case where first chunk is not a global container (List chunk) is not implemented yet (i.e. Korg files) |
2061 |
if (Layout == layout_flat) |
2062 |
throw Exception("Saving a RIFF file with layout_flat is not implemented yet"); |
2063 |
|
2064 |
// make sure the RIFF tree is built (from the original file) |
2065 |
if (pProgress) { |
2066 |
// divide progress into subprogress |
2067 |
progress_t subprogress; |
2068 |
__divide_progress(pProgress, &subprogress, 2.f, 0.f); // arbitrarily subdivided into 1/2 of total progress |
2069 |
// do the actual work |
2070 |
LoadSubChunksRecursively(&subprogress); |
2071 |
// notify subprogress done |
2072 |
__notify_progress(&subprogress, 1.f); |
2073 |
} else |
2074 |
LoadSubChunksRecursively(NULL); |
2075 |
|
2076 |
if (!bIsNewFile) SetMode(stream_mode_read); |
2077 |
// open the other (new) file for writing and truncate it to zero size |
2078 |
#if POSIX |
2079 |
hFileWrite = open(path.c_str(), O_RDWR | O_CREAT, S_IRUSR | S_IWUSR | S_IRGRP); |
2080 |
if (hFileWrite == -1) { |
2081 |
hFileWrite = hFileRead; |
2082 |
String sError = strerror(errno); |
2083 |
throw Exception("Could not open file \"" + path + "\" for writing: " + sError); |
2084 |
} |
2085 |
#elif defined(WIN32) |
2086 |
hFileWrite = CreateFile( |
2087 |
path.c_str(), GENERIC_WRITE, FILE_SHARE_READ, |
2088 |
NULL, OPEN_ALWAYS, FILE_ATTRIBUTE_NORMAL | |
2089 |
FILE_FLAG_RANDOM_ACCESS, NULL |
2090 |
); |
2091 |
if (hFileWrite == INVALID_HANDLE_VALUE) { |
2092 |
hFileWrite = hFileRead; |
2093 |
throw Exception("Could not open file \"" + path + "\" for writing"); |
2094 |
} |
2095 |
#else |
2096 |
hFileWrite = fopen(path.c_str(), "w+b"); |
2097 |
if (!hFileWrite) { |
2098 |
hFileWrite = hFileRead; |
2099 |
throw Exception("Could not open file \"" + path + "\" for writing"); |
2100 |
} |
2101 |
#endif // POSIX |
2102 |
Mode = stream_mode_read_write; |
2103 |
|
2104 |
// get the overall file size required to save this file |
2105 |
const file_offset_t newFileSize = GetRequiredFileSize(FileOffsetPreference); |
2106 |
|
2107 |
// determine whether this file will yield in a large file (>=4GB) and |
2108 |
// the RIFF file offset size to be used accordingly for all chunks |
2109 |
FileOffsetSize = FileOffsetSizeFor(newFileSize); |
2110 |
|
2111 |
// write complete RIFF tree to the other (new) file |
2112 |
file_offset_t ullTotalSize; |
2113 |
if (pProgress) { |
2114 |
// divide progress into subprogress |
2115 |
progress_t subprogress; |
2116 |
__divide_progress(pProgress, &subprogress, 2.f, 1.f); // arbitrarily subdivided into 1/2 of total progress |
2117 |
// do the actual work |
2118 |
ullTotalSize = WriteChunk(0, 0, &subprogress); |
2119 |
// notify subprogress done |
2120 |
__notify_progress(&subprogress, 1.f); |
2121 |
} else |
2122 |
ullTotalSize = WriteChunk(0, 0, NULL); |
2123 |
|
2124 |
file_offset_t ullActualSize = __GetFileSize(hFileWrite); |
2125 |
|
2126 |
// resize file to the final size (if the file was originally larger) |
2127 |
if (ullActualSize > ullTotalSize) ResizeFile(ullTotalSize); |
2128 |
|
2129 |
#if POSIX |
2130 |
if (hFileWrite) close(hFileWrite); |
2131 |
#elif defined(WIN32) |
2132 |
if (hFileWrite != INVALID_HANDLE_VALUE) CloseHandle(hFileWrite); |
2133 |
#else |
2134 |
if (hFileWrite) fclose(hFileWrite); |
2135 |
#endif |
2136 |
hFileWrite = hFileRead; |
2137 |
|
2138 |
// associate new file with this File object from now on |
2139 |
Filename = path; |
2140 |
bIsNewFile = false; |
2141 |
Mode = (stream_mode_t) -1; // Just set it to an undefined mode ... |
2142 |
SetMode(stream_mode_read_write); // ... so SetMode() has to reopen the file handles. |
2143 |
|
2144 |
if (pProgress) |
2145 |
__notify_progress(pProgress, 1.0); // notify done |
2146 |
} |
2147 |
|
2148 |
void File::ResizeFile(file_offset_t ullNewSize) { |
2149 |
#if POSIX |
2150 |
if (ftruncate(hFileWrite, ullNewSize) < 0) |
2151 |
throw Exception("Could not resize file \"" + Filename + "\""); |
2152 |
#elif defined(WIN32) |
2153 |
LARGE_INTEGER liFilePos; |
2154 |
liFilePos.QuadPart = ullNewSize; |
2155 |
if ( |
2156 |
!SetFilePointerEx(hFileWrite, liFilePos, NULL/*new pos pointer*/, FILE_BEGIN) || |
2157 |
!SetEndOfFile(hFileWrite) |
2158 |
) throw Exception("Could not resize file \"" + Filename + "\""); |
2159 |
#else |
2160 |
# error Sorry, this version of libgig only supports POSIX and Windows systems yet. |
2161 |
# error Reason: portable implementation of RIFF::File::ResizeFile() is missing (yet)! |
2162 |
#endif |
2163 |
} |
2164 |
|
2165 |
File::~File() { |
2166 |
#if DEBUG_RIFF |
2167 |
std::cout << "File::~File()" << std::endl; |
2168 |
#endif // DEBUG_RIFF |
2169 |
Cleanup(); |
2170 |
} |
2171 |
|
2172 |
/** |
2173 |
* Returns @c true if this file has been created new from scratch and |
2174 |
* has not been stored to disk yet. |
2175 |
*/ |
2176 |
bool File::IsNew() const { |
2177 |
return bIsNewFile; |
2178 |
} |
2179 |
|
2180 |
void File::Cleanup() { |
2181 |
#if POSIX |
2182 |
if (hFileRead) close(hFileRead); |
2183 |
#elif defined(WIN32) |
2184 |
if (hFileRead != INVALID_HANDLE_VALUE) CloseHandle(hFileRead); |
2185 |
#else |
2186 |
if (hFileRead) fclose(hFileRead); |
2187 |
#endif // POSIX |
2188 |
DeleteChunkList(); |
2189 |
pFile = NULL; |
2190 |
} |
2191 |
|
2192 |
/** |
2193 |
* Returns the current size of this file (in bytes) as it is currently |
2194 |
* yet stored on disk. If this file does not yet exist on disk (i.e. when |
2195 |
* this RIFF File has just been created from scratch and Save() has not |
2196 |
* been called yet) then this method returns 0. |
2197 |
*/ |
2198 |
file_offset_t File::GetCurrentFileSize() const { |
2199 |
file_offset_t size = 0; |
2200 |
try { |
2201 |
size = __GetFileSize(hFileRead); |
2202 |
} catch (...) { |
2203 |
size = 0; |
2204 |
} |
2205 |
return size; |
2206 |
} |
2207 |
|
2208 |
/** |
2209 |
* Returns the required size (in bytes) for this RIFF File to be saved to |
2210 |
* disk. The precise size of the final file on disk depends on the RIFF |
2211 |
* file offset size actually used internally in all headers of the RIFF |
2212 |
* chunks. By default libgig handles the required file offset size |
2213 |
* automatically for you; that means it is using 32 bit offsets for files |
2214 |
* smaller than 4 GB and 64 bit offsets for files equal or larger than |
2215 |
* 4 GB. You may however also override this default behavior by passing the |
2216 |
* respective option to the RIFF File constructor to force one particular |
2217 |
* offset size. In the latter case this method will return the file size |
2218 |
* for the requested forced file offset size that will be used when calling |
2219 |
* Save() later on. |
2220 |
* |
2221 |
* You may also use the overridden method below to get the file size for |
2222 |
* an arbitrary other file offset size instead. |
2223 |
* |
2224 |
* @see offset_size_t |
2225 |
* @see GetFileOffsetSize() |
2226 |
*/ |
2227 |
file_offset_t File::GetRequiredFileSize() { |
2228 |
return GetRequiredFileSize(FileOffsetPreference); |
2229 |
} |
2230 |
|
2231 |
/** |
2232 |
* Returns the rquired size (in bytes) for this RIFF file to be saved to |
2233 |
* disk, assuming the passed @a fileOffsestSize would be used for the |
2234 |
* Save() operation. |
2235 |
* |
2236 |
* This overridden method essentialy behaves like the above method, with |
2237 |
* the difference that you must provide a specific RIFF @a fileOffsetSize |
2238 |
* for calculating the theoretical final file size. |
2239 |
* |
2240 |
* @see GetFileOffsetSize() |
2241 |
*/ |
2242 |
file_offset_t File::GetRequiredFileSize(offset_size_t fileOffsetSize) { |
2243 |
switch (fileOffsetSize) { |
2244 |
case offset_size_auto: { |
2245 |
file_offset_t fileSize = GetRequiredFileSize(offset_size_32bit); |
2246 |
if (fileSize >> 32) |
2247 |
return GetRequiredFileSize(offset_size_64bit); |
2248 |
else |
2249 |
return fileSize; |
2250 |
} |
2251 |
case offset_size_32bit: break; |
2252 |
case offset_size_64bit: break; |
2253 |
default: throw Exception("Internal error: Invalid RIFF::offset_size_t"); |
2254 |
} |
2255 |
return RequiredPhysicalSize(FileOffsetSize); |
2256 |
} |
2257 |
|
2258 |
int File::FileOffsetSizeFor(file_offset_t fileSize) const { |
2259 |
switch (FileOffsetPreference) { |
2260 |
case offset_size_auto: |
2261 |
return (fileSize >> 32) ? 8 : 4; |
2262 |
case offset_size_32bit: |
2263 |
return 4; |
2264 |
case offset_size_64bit: |
2265 |
return 8; |
2266 |
default: |
2267 |
throw Exception("Internal error: Invalid RIFF::offset_size_t"); |
2268 |
} |
2269 |
} |
2270 |
|
2271 |
/** |
2272 |
* Returns the current size (in bytes) of file offsets stored in the |
2273 |
* headers of all chunks of this file. |
2274 |
* |
2275 |
* Most RIFF files are using 32 bit file offsets internally, which limits |
2276 |
* them to a maximum file size of less than 4 GB though. In contrast to the |
2277 |
* common standard, this RIFF File class implementation supports handling of |
2278 |
* RIFF files equal or larger than 4 GB. In such cases 64 bit file offsets |
2279 |
* have to be used in all headers of all RIFF Chunks when being stored to a |
2280 |
* physical file. libgig by default automatically selects the correct file |
2281 |
* offset size for you. You may however also force one particular file |
2282 |
* offset size by supplying the respective option to the RIFF::File |
2283 |
* constructor. |
2284 |
* |
2285 |
* This method can be used to check which RIFF file offset size is currently |
2286 |
* being used for this RIFF File. |
2287 |
* |
2288 |
* @returns current RIFF file offset size used (in bytes) |
2289 |
* @see offset_size_t |
2290 |
*/ |
2291 |
int File::GetFileOffsetSize() const { |
2292 |
return FileOffsetSize; |
2293 |
} |
2294 |
|
2295 |
/** |
2296 |
* Returns the required size (in bytes) of file offsets stored in the |
2297 |
* headers of all chunks of this file if the current RIFF tree would be |
2298 |
* saved to disk by calling Save(). |
2299 |
* |
2300 |
* See GetFileOffsetSize() for mor details about RIFF file offsets. |
2301 |
* |
2302 |
* @returns RIFF file offset size required (in bytes) if being saved |
2303 |
* @see offset_size_t |
2304 |
*/ |
2305 |
int File::GetRequiredFileOffsetSize() { |
2306 |
return FileOffsetSizeFor(GetCurrentFileSize()); |
2307 |
} |
2308 |
|
2309 |
#if POSIX |
2310 |
file_offset_t File::__GetFileSize(int hFile) const { |
2311 |
struct stat filestat; |
2312 |
if (fstat(hFile, &filestat) == -1) |
2313 |
throw Exception("POSIX FS error: could not determine file size"); |
2314 |
return filestat.st_size; |
2315 |
} |
2316 |
#elif defined(WIN32) |
2317 |
file_offset_t File::__GetFileSize(HANDLE hFile) const { |
2318 |
LARGE_INTEGER size; |
2319 |
if (!GetFileSizeEx(hFile, &size)) |
2320 |
throw Exception("Windows FS error: could not determine file size"); |
2321 |
return size.QuadPart; |
2322 |
} |
2323 |
#else // standard C functions |
2324 |
file_offset_t File::__GetFileSize(FILE* hFile) const { |
2325 |
off_t curpos = ftello(hFile); |
2326 |
if (fseeko(hFile, 0, SEEK_END) == -1) |
2327 |
throw Exception("FS error: could not determine file size"); |
2328 |
off_t size = ftello(hFile); |
2329 |
fseeko(hFile, curpos, SEEK_SET); |
2330 |
return size; |
2331 |
} |
2332 |
#endif |
2333 |
|
2334 |
|
2335 |
// *************** Exception *************** |
2336 |
// * |
2337 |
|
2338 |
Exception::Exception() { |
2339 |
} |
2340 |
|
2341 |
Exception::Exception(String format, ...) { |
2342 |
va_list arg; |
2343 |
va_start(arg, format); |
2344 |
Message = assemble(format, arg); |
2345 |
va_end(arg); |
2346 |
} |
2347 |
|
2348 |
Exception::Exception(String format, va_list arg) { |
2349 |
Message = assemble(format, arg); |
2350 |
} |
2351 |
|
2352 |
void Exception::PrintMessage() { |
2353 |
std::cout << "RIFF::Exception: " << Message << std::endl; |
2354 |
} |
2355 |
|
2356 |
String Exception::assemble(String format, va_list arg) { |
2357 |
char* buf = NULL; |
2358 |
vasprintf(&buf, format.c_str(), arg); |
2359 |
String s = buf; |
2360 |
free(buf); |
2361 |
return s; |
2362 |
} |
2363 |
|
2364 |
|
2365 |
// *************** functions *************** |
2366 |
// * |
2367 |
|
2368 |
/** |
2369 |
* Returns the name of this C++ library. This is usually "libgig" of |
2370 |
* course. This call is equivalent to DLS::libraryName() and |
2371 |
* gig::libraryName(). |
2372 |
*/ |
2373 |
String libraryName() { |
2374 |
return PACKAGE; |
2375 |
} |
2376 |
|
2377 |
/** |
2378 |
* Returns version of this C++ library. This call is equivalent to |
2379 |
* DLS::libraryVersion() and gig::libraryVersion(). |
2380 |
*/ |
2381 |
String libraryVersion() { |
2382 |
return VERSION; |
2383 |
} |
2384 |
|
2385 |
} // namespace RIFF |