opencv/3rdparty/openexr/IlmImf/ImfScanLineInputFile.cpp

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2012-08-24 22:31:49 +02:00
///////////////////////////////////////////////////////////////////////////
//
// Copyright (c) 2004, Industrial Light & Magic, a division of Lucas
// Digital Ltd. LLC
//
// All rights reserved.
//
// Redistribution and use in source and binary forms, with or without
// modification, are permitted provided that the following conditions are
// met:
// * Redistributions of source code must retain the above copyright
// notice, this list of conditions and the following disclaimer.
// * Redistributions in binary form must reproduce the above
// copyright notice, this list of conditions and the following disclaimer
// in the documentation and/or other materials provided with the
// distribution.
// * Neither the name of Industrial Light & Magic nor the names of
// its contributors may be used to endorse or promote products derived
// from this software without specific prior written permission.
//
// THIS SOFTWARE IS PROVIDED BY THE COPYRIGHT HOLDERS AND CONTRIBUTORS
// "AS IS" AND ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT
// LIMITED TO, THE IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR
// A PARTICULAR PURPOSE ARE DISCLAIMED. IN NO EVENT SHALL THE COPYRIGHT
// OWNER OR CONTRIBUTORS BE LIABLE FOR ANY DIRECT, INDIRECT, INCIDENTAL,
// SPECIAL, EXEMPLARY, OR CONSEQUENTIAL DAMAGES (INCLUDING, BUT NOT
// LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS OR SERVICES; LOSS OF USE,
// DATA, OR PROFITS; OR BUSINESS INTERRUPTION) HOWEVER CAUSED AND ON ANY
// THEORY OF LIABILITY, WHETHER IN CONTRACT, STRICT LIABILITY, OR TORT
// (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY OUT OF THE USE
// OF THIS SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF SUCH DAMAGE.
//
///////////////////////////////////////////////////////////////////////////
//-----------------------------------------------------------------------------
//
// class ScanLineInputFile
//
//-----------------------------------------------------------------------------
#include <ImfScanLineInputFile.h>
#include <ImfChannelList.h>
#include <ImfMisc.h>
#include <ImfStdIO.h>
#include <ImfCompressor.h>
#include "ImathBox.h"
#include "ImathFun.h"
#include <ImfXdr.h>
#include <ImfConvert.h>
#include <ImfThreading.h>
#include "IlmThreadPool.h"
#include "IlmThreadSemaphore.h"
#include "IlmThreadMutex.h"
#include "Iex.h"
#include <string>
#include <vector>
#include <assert.h>
namespace Imf {
using Imath::Box2i;
using Imath::divp;
using Imath::modp;
using std::string;
using std::vector;
using std::ifstream;
using std::min;
using std::max;
using IlmThread::Mutex;
using IlmThread::Lock;
using IlmThread::Semaphore;
using IlmThread::Task;
using IlmThread::TaskGroup;
using IlmThread::ThreadPool;
namespace {
struct InSliceInfo
{
PixelType typeInFrameBuffer;
PixelType typeInFile;
char * base;
size_t xStride;
size_t yStride;
int xSampling;
int ySampling;
bool fill;
bool skip;
double fillValue;
InSliceInfo (PixelType typeInFrameBuffer = HALF,
PixelType typeInFile = HALF,
char *base = 0,
size_t xStride = 0,
size_t yStride = 0,
int xSampling = 1,
int ySampling = 1,
bool fill = false,
bool skip = false,
double fillValue = 0.0);
};
InSliceInfo::InSliceInfo (PixelType tifb,
PixelType tifl,
char *b,
size_t xs, size_t ys,
int xsm, int ysm,
bool f, bool s,
double fv)
:
typeInFrameBuffer (tifb),
typeInFile (tifl),
base (b),
xStride (xs),
yStride (ys),
xSampling (xsm),
ySampling (ysm),
fill (f),
skip (s),
fillValue (fv)
{
// empty
}
struct LineBuffer
{
const char * uncompressedData;
char * buffer;
int dataSize;
int minY;
int maxY;
Compressor * compressor;
Compressor::Format format;
int number;
bool hasException;
string exception;
LineBuffer (Compressor * const comp);
~LineBuffer ();
inline void wait () {_sem.wait();}
inline void post () {_sem.post();}
private:
Semaphore _sem;
};
LineBuffer::LineBuffer (Compressor *comp):
uncompressedData (0),
buffer (0),
dataSize (0),
compressor (comp),
format (defaultFormat(compressor)),
number (-1),
hasException (false),
exception (),
_sem (1)
{
// empty
}
LineBuffer::~LineBuffer ()
{
delete compressor;
}
} // namespace
struct ScanLineInputFile::Data: public Mutex
{
Header header; // the image header
int version; // file's version
FrameBuffer frameBuffer; // framebuffer to write into
LineOrder lineOrder; // order of the scanlines in file
int minX; // data window's min x coord
int maxX; // data window's max x coord
int minY; // data window's min y coord
int maxY; // data window's max x coord
vector<Int64> lineOffsets; // stores offsets in file for
// each line
bool fileIsComplete; // True if no scanlines are missing
// in the file
int nextLineBufferMinY; // minimum y of the next linebuffer
vector<size_t> bytesPerLine; // combined size of a line over all
// channels
vector<size_t> offsetInLineBuffer; // offset for each scanline in its
// linebuffer
vector<InSliceInfo> slices; // info about channels in file
IStream * is; // file stream to read from
vector<LineBuffer*> lineBuffers; // each holds one line buffer
int linesInBuffer; // number of scanlines each buffer
// holds
size_t lineBufferSize; // size of the line buffer
Data (IStream *is, int numThreads);
~Data ();
inline LineBuffer * getLineBuffer (int number); // hash function from line
// buffer indices into our
// vector of line buffers
};
ScanLineInputFile::Data::Data (IStream *is, int numThreads):
is (is)
{
//
// We need at least one lineBuffer, but if threading is used,
// to keep n threads busy we need 2*n lineBuffers
//
lineBuffers.resize (max (1, 2 * numThreads));
}
ScanLineInputFile::Data::~Data ()
{
for (size_t i = 0; i < lineBuffers.size(); i++)
delete lineBuffers[i];
}
inline LineBuffer *
ScanLineInputFile::Data::getLineBuffer (int lineBufferNumber)
{
return lineBuffers[lineBufferNumber % lineBuffers.size()];
}
namespace {
void
reconstructLineOffsets (IStream &is,
LineOrder lineOrder,
vector<Int64> &lineOffsets)
{
Int64 position = is.tellg();
try
{
for (unsigned int i = 0; i < lineOffsets.size(); i++)
{
Int64 lineOffset = is.tellg();
int y;
Xdr::read <StreamIO> (is, y);
int dataSize;
Xdr::read <StreamIO> (is, dataSize);
Xdr::skip <StreamIO> (is, dataSize);
if (lineOrder == INCREASING_Y)
lineOffsets[i] = lineOffset;
else
lineOffsets[lineOffsets.size() - i - 1] = lineOffset;
}
}
catch (...)
{
//
// Suppress all exceptions. This functions is
// called only to reconstruct the line offset
// table for incomplete files, and exceptions
// are likely.
//
}
is.clear();
is.seekg (position);
}
void
readLineOffsets (IStream &is,
LineOrder lineOrder,
vector<Int64> &lineOffsets,
bool &complete)
{
for (unsigned int i = 0; i < lineOffsets.size(); i++)
{
Xdr::read <StreamIO> (is, lineOffsets[i]);
}
complete = true;
for (unsigned int i = 0; i < lineOffsets.size(); i++)
{
if (lineOffsets[i] <= 0)
{
//
// Invalid data in the line offset table mean that
// the file is probably incomplete (the table is
// the last thing written to the file). Either
// some process is still busy writing the file,
// or writing the file was aborted.
//
// We should still be able to read the existing
// parts of the file. In order to do this, we
// have to make a sequential scan over the scan
// line data to reconstruct the line offset table.
//
complete = false;
reconstructLineOffsets (is, lineOrder, lineOffsets);
break;
}
}
}
void
readPixelData (ScanLineInputFile::Data *ifd,
int minY,
char *&buffer,
int &dataSize)
{
//
// Read a single line buffer from the input file.
//
// If the input file is not memory-mapped, we copy the pixel data into
// into the array pointed to by buffer. If the file is memory-mapped,
// then we change where buffer points to instead of writing into the
// array (hence buffer needs to be a reference to a char *).
//
Int64 lineOffset =
ifd->lineOffsets[(minY - ifd->minY) / ifd->linesInBuffer];
if (lineOffset == 0)
THROW (Iex::InputExc, "Scan line " << minY << " is missing.");
//
// Seek to the start of the scan line in the file,
// if necessary.
//
if (ifd->nextLineBufferMinY != minY)
ifd->is->seekg (lineOffset);
//
// Read the data block's header.
//
int yInFile;
Xdr::read <StreamIO> (*ifd->is, yInFile);
Xdr::read <StreamIO> (*ifd->is, dataSize);
if (yInFile != minY)
throw Iex::InputExc ("Unexpected data block y coordinate.");
if (dataSize > (int) ifd->lineBufferSize)
throw Iex::InputExc ("Unexpected data block length.");
//
// Read the pixel data.
//
if (ifd->is->isMemoryMapped ())
buffer = ifd->is->readMemoryMapped (dataSize);
else
ifd->is->read (buffer, dataSize);
//
// Keep track of which scan line is the next one in
// the file, so that we can avoid redundant seekg()
// operations (seekg() can be fairly expensive).
//
if (ifd->lineOrder == INCREASING_Y)
ifd->nextLineBufferMinY = minY + ifd->linesInBuffer;
else
ifd->nextLineBufferMinY = minY - ifd->linesInBuffer;
}
//
// A LineBufferTask encapsulates the task uncompressing a set of
// scanlines (line buffer) and copying them into the frame buffer.
//
class LineBufferTask : public Task
{
public:
LineBufferTask (TaskGroup *group,
ScanLineInputFile::Data *ifd,
LineBuffer *lineBuffer,
int scanLineMin,
int scanLineMax);
virtual ~LineBufferTask ();
virtual void execute ();
private:
ScanLineInputFile::Data * _ifd;
LineBuffer * _lineBuffer;
int _scanLineMin;
int _scanLineMax;
};
LineBufferTask::LineBufferTask
(TaskGroup *group,
ScanLineInputFile::Data *ifd,
LineBuffer *lineBuffer,
int scanLineMin,
int scanLineMax)
:
Task (group),
_ifd (ifd),
_lineBuffer (lineBuffer),
_scanLineMin (scanLineMin),
_scanLineMax (scanLineMax)
{
// empty
}
LineBufferTask::~LineBufferTask ()
{
//
// Signal that the line buffer is now free
//
_lineBuffer->post ();
}
void
LineBufferTask::execute ()
{
try
{
//
// Uncompress the data, if necessary
//
if (_lineBuffer->uncompressedData == 0)
{
int uncompressedSize = 0;
int maxY = min (_lineBuffer->maxY, _ifd->maxY);
for (int i = _lineBuffer->minY - _ifd->minY;
i <= maxY - _ifd->minY;
++i)
{
uncompressedSize += (int) _ifd->bytesPerLine[i];
}
if (_lineBuffer->compressor &&
_lineBuffer->dataSize < uncompressedSize)
{
_lineBuffer->format = _lineBuffer->compressor->format();
_lineBuffer->dataSize = _lineBuffer->compressor->uncompress
(_lineBuffer->buffer, _lineBuffer->dataSize,
_lineBuffer->minY, _lineBuffer->uncompressedData);
}
else
{
//
// If the line is uncompressed, it's in XDR format,
// regardless of the compressor's output format.
//
_lineBuffer->format = Compressor::XDR;
_lineBuffer->uncompressedData = _lineBuffer->buffer;
}
}
int yStart, yStop, dy;
if (_ifd->lineOrder == INCREASING_Y)
{
yStart = _scanLineMin;
yStop = _scanLineMax + 1;
dy = 1;
}
else
{
yStart = _scanLineMax;
yStop = _scanLineMin - 1;
dy = -1;
}
for (int y = yStart; y != yStop; y += dy)
{
//
// Convert one scan line's worth of pixel data back
// from the machine-independent representation, and
// store the result in the frame buffer.
//
const char *readPtr = _lineBuffer->uncompressedData +
_ifd->offsetInLineBuffer[y - _ifd->minY];
//
// Iterate over all image channels.
//
for (unsigned int i = 0; i < _ifd->slices.size(); ++i)
{
//
// Test if scan line y of this channel contains any data
// (the scan line contains data only if y % ySampling == 0).
//
const InSliceInfo &slice = _ifd->slices[i];
if (modp (y, slice.ySampling) != 0)
continue;
//
// Find the x coordinates of the leftmost and rightmost
// sampled pixels (i.e. pixels within the data window
// for which x % xSampling == 0).
//
int dMinX = divp (_ifd->minX, slice.xSampling);
int dMaxX = divp (_ifd->maxX, slice.xSampling);
//
// Fill the frame buffer with pixel data.
//
if (slice.skip)
{
//
// The file contains data for this channel, but
// the frame buffer contains no slice for this channel.
//
skipChannel (readPtr, slice.typeInFile, dMaxX - dMinX + 1);
}
else
{
//
// The frame buffer contains a slice for this channel.
//
char *linePtr = slice.base +
divp (y, slice.ySampling) *
slice.yStride;
char *writePtr = linePtr + dMinX * slice.xStride;
char *endPtr = linePtr + dMaxX * slice.xStride;
copyIntoFrameBuffer (readPtr, writePtr, endPtr,
slice.xStride, slice.fill,
slice.fillValue, _lineBuffer->format,
slice.typeInFrameBuffer,
slice.typeInFile);
}
}
}
}
catch (std::exception &e)
{
if (!_lineBuffer->hasException)
{
_lineBuffer->exception = e.what();
_lineBuffer->hasException = true;
}
}
catch (...)
{
if (!_lineBuffer->hasException)
{
_lineBuffer->exception = "unrecognized exception";
_lineBuffer->hasException = true;
}
}
}
LineBufferTask *
newLineBufferTask
(TaskGroup *group,
ScanLineInputFile::Data *ifd,
int number,
int scanLineMin,
int scanLineMax)
{
//
// Wait for a line buffer to become available, fill the line
// buffer with raw data from the file if necessary, and create
// a new LineBufferTask whose execute() method will uncompress
// the contents of the buffer and copy the pixels into the
// frame buffer.
//
LineBuffer *lineBuffer = ifd->getLineBuffer (number);
try
{
lineBuffer->wait ();
if (lineBuffer->number != number)
{
lineBuffer->minY = ifd->minY + number * ifd->linesInBuffer;
lineBuffer->maxY = lineBuffer->minY + ifd->linesInBuffer - 1;
lineBuffer->number = number;
lineBuffer->uncompressedData = 0;
readPixelData (ifd, lineBuffer->minY,
lineBuffer->buffer,
lineBuffer->dataSize);
}
}
catch (std::exception &e)
{
if (!lineBuffer->hasException)
{
lineBuffer->exception = e.what();
lineBuffer->hasException = true;
}
lineBuffer->number = -1;
lineBuffer->post();\
throw;
}
catch (...)
{
//
// Reading from the file caused an exception.
// Signal that the line buffer is free, and
// re-throw the exception.
//
lineBuffer->exception = "unrecognized exception";
lineBuffer->hasException = true;
lineBuffer->number = -1;
lineBuffer->post();
throw;
}
scanLineMin = max (lineBuffer->minY, scanLineMin);
scanLineMax = min (lineBuffer->maxY, scanLineMax);
return new LineBufferTask (group, ifd, lineBuffer,
scanLineMin, scanLineMax);
}
} // namespace
ScanLineInputFile::ScanLineInputFile
(const Header &header,
IStream *is,
int numThreads)
:
_data (new Data (is, numThreads))
{
try
{
_data->header = header;
_data->lineOrder = _data->header.lineOrder();
const Box2i &dataWindow = _data->header.dataWindow();
_data->minX = dataWindow.min.x;
_data->maxX = dataWindow.max.x;
_data->minY = dataWindow.min.y;
_data->maxY = dataWindow.max.y;
size_t maxBytesPerLine = bytesPerLineTable (_data->header,
_data->bytesPerLine);
for (size_t i = 0; i < _data->lineBuffers.size(); i++)
{
_data->lineBuffers[i] = new LineBuffer (newCompressor
(_data->header.compression(),
maxBytesPerLine,
_data->header));
}
_data->linesInBuffer =
numLinesInBuffer (_data->lineBuffers[0]->compressor);
_data->lineBufferSize = maxBytesPerLine * _data->linesInBuffer;
if (!_data->is->isMemoryMapped())
for (size_t i = 0; i < _data->lineBuffers.size(); i++)
_data->lineBuffers[i]->buffer = new char[_data->lineBufferSize];
_data->nextLineBufferMinY = _data->minY - 1;
offsetInLineBufferTable (_data->bytesPerLine,
_data->linesInBuffer,
_data->offsetInLineBuffer);
int lineOffsetSize = (dataWindow.max.y - dataWindow.min.y +
_data->linesInBuffer) / _data->linesInBuffer;
_data->lineOffsets.resize (lineOffsetSize);
readLineOffsets (*_data->is,
_data->lineOrder,
_data->lineOffsets,
_data->fileIsComplete);
}
catch (...)
{
delete _data;
throw;
}
}
ScanLineInputFile::~ScanLineInputFile ()
{
if (!_data->is->isMemoryMapped())
for (size_t i = 0; i < _data->lineBuffers.size(); i++)
delete [] _data->lineBuffers[i]->buffer;
delete _data;
}
const char *
ScanLineInputFile::fileName () const
{
return _data->is->fileName();
}
const Header &
ScanLineInputFile::header () const
{
return _data->header;
}
int
ScanLineInputFile::version () const
{
return _data->version;
}
void
ScanLineInputFile::setFrameBuffer (const FrameBuffer &frameBuffer)
{
Lock lock (*_data);
//
// Check if the new frame buffer descriptor is
// compatible with the image file header.
//
const ChannelList &channels = _data->header.channels();
for (FrameBuffer::ConstIterator j = frameBuffer.begin();
j != frameBuffer.end();
++j)
{
ChannelList::ConstIterator i = channels.find (j.name());
if (i == channels.end())
continue;
if (i.channel().xSampling != j.slice().xSampling ||
i.channel().ySampling != j.slice().ySampling)
THROW (Iex::ArgExc, "X and/or y subsampling factors "
"of \"" << i.name() << "\" channel "
"of input file \"" << fileName() << "\" are "
"not compatible with the frame buffer's "
"subsampling factors.");
}
//
// Initialize the slice table for readPixels().
//
vector<InSliceInfo> slices;
ChannelList::ConstIterator i = channels.begin();
for (FrameBuffer::ConstIterator j = frameBuffer.begin();
j != frameBuffer.end();
++j)
{
while (i != channels.end() && strcmp (i.name(), j.name()) < 0)
{
//
// Channel i is present in the file but not
// in the frame buffer; data for channel i
// will be skipped during readPixels().
//
slices.push_back (InSliceInfo (i.channel().type,
i.channel().type,
0, // base
0, // xStride
0, // yStride
i.channel().xSampling,
i.channel().ySampling,
false, // fill
true, // skip
0.0)); // fillValue
++i;
}
bool fill = false;
if (i == channels.end() || strcmp (i.name(), j.name()) > 0)
{
//
// Channel i is present in the frame buffer, but not in the file.
// In the frame buffer, slice j will be filled with a default value.
//
fill = true;
}
slices.push_back (InSliceInfo (j.slice().type,
fill? j.slice().type:
i.channel().type,
j.slice().base,
j.slice().xStride,
j.slice().yStride,
j.slice().xSampling,
j.slice().ySampling,
fill,
false, // skip
j.slice().fillValue));
if (i != channels.end() && !fill)
++i;
}
//
// Store the new frame buffer.
//
_data->frameBuffer = frameBuffer;
_data->slices = slices;
}
const FrameBuffer &
ScanLineInputFile::frameBuffer () const
{
Lock lock (*_data);
return _data->frameBuffer;
}
bool
ScanLineInputFile::isComplete () const
{
return _data->fileIsComplete;
}
void
ScanLineInputFile::readPixels (int scanLine1, int scanLine2)
{
try
{
Lock lock (*_data);
if (_data->slices.size() == 0)
throw Iex::ArgExc ("No frame buffer specified "
"as pixel data destination.");
int scanLineMin = min (scanLine1, scanLine2);
int scanLineMax = max (scanLine1, scanLine2);
if (scanLineMin < _data->minY || scanLineMax > _data->maxY)
throw Iex::ArgExc ("Tried to read scan line outside "
"the image file's data window.");
//
// We impose a numbering scheme on the lineBuffers where the first
// scanline is contained in lineBuffer 1.
//
// Determine the first and last lineBuffer numbers in this scanline
// range. We always attempt to read the scanlines in the order that
// they are stored in the file.
//
int start, stop, dl;
if (_data->lineOrder == INCREASING_Y)
{
start = (scanLineMin - _data->minY) / _data->linesInBuffer;
stop = (scanLineMax - _data->minY) / _data->linesInBuffer + 1;
dl = 1;
}
else
{
start = (scanLineMax - _data->minY) / _data->linesInBuffer;
stop = (scanLineMin - _data->minY) / _data->linesInBuffer - 1;
dl = -1;
}
//
// Create a task group for all line buffer tasks. When the
// task group goes out of scope, the destructor waits until
// all tasks are complete.
//
{
TaskGroup taskGroup;
//
// Add the line buffer tasks.
//
// The tasks will execute in the order that they are created
// because we lock the line buffers during construction and the
// constructors are called by the main thread. Hence, in order
// for a successive task to execute the previous task which
// used that line buffer must have completed already.
//
for (int l = start; l != stop; l += dl)
{
ThreadPool::addGlobalTask (newLineBufferTask (&taskGroup,
_data, l,
scanLineMin,
scanLineMax));
}
//
// finish all tasks
//
}
//
// Exeption handling:
//
// LineBufferTask::execute() may have encountered exceptions, but
// those exceptions occurred in another thread, not in the thread
// that is executing this call to ScanLineInputFile::readPixels().
// LineBufferTask::execute() has caught all exceptions and stored
// the exceptions' what() strings in the line buffers.
// Now we check if any line buffer contains a stored exception; if
// this is the case then we re-throw the exception in this thread.
// (It is possible that multiple line buffers contain stored
// exceptions. We re-throw the first exception we find and
// ignore all others.)
//
const string *exception = 0;
for (int i = 0; i < _data->lineBuffers.size(); ++i)
{
LineBuffer *lineBuffer = _data->lineBuffers[i];
if (lineBuffer->hasException && !exception)
exception = &lineBuffer->exception;
lineBuffer->hasException = false;
}
if (exception)
throw Iex::IoExc (*exception);
}
catch (Iex::BaseExc &e)
{
REPLACE_EXC (e, "Error reading pixel data from image "
"file \"" << fileName() << "\". " << e);
throw;
}
}
void
ScanLineInputFile::readPixels (int scanLine)
{
readPixels (scanLine, scanLine);
}
void
ScanLineInputFile::rawPixelData (int firstScanLine,
const char *&pixelData,
int &pixelDataSize)
{
try
{
Lock lock (*_data);
if (firstScanLine < _data->minY || firstScanLine > _data->maxY)
{
throw Iex::ArgExc ("Tried to read scan line outside "
"the image file's data window.");
}
int minY = lineBufferMinY
(firstScanLine, _data->minY, _data->linesInBuffer);
readPixelData
(_data, minY, _data->lineBuffers[0]->buffer, pixelDataSize);
pixelData = _data->lineBuffers[0]->buffer;
}
catch (Iex::BaseExc &e)
{
REPLACE_EXC (e, "Error reading pixel data from image "
"file \"" << fileName() << "\". " << e);
throw;
}
}
} // namespace Imf