/* $Id: ImageBase.cpp 29254 2010-06-06 00:35:48Z jesterking $ ----------------------------------------------------------------------------- This source file is part of VideoTexture library Copyright (c) 2007 The Zdeno Ash Miklas This program is free software; you can redistribute it and/or modify it under the terms of the GNU Lesser General Public License as published by the Free Software Foundation; either version 2 of the License, or (at your option) any later version. This program is distributed in the hope that it will be useful, but WITHOUT ANY WARRANTY; without even the implied warranty of MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the GNU Lesser General Public License for more details. You should have received a copy of the GNU Lesser General Public License along with this program; if not, write to the Free Software Foundation, Inc., 59 Temple Place - Suite 330, Boston, MA 02111-1307, USA, or go to http://www.gnu.org/copyleft/lesser.txt. ----------------------------------------------------------------------------- */ #include "ImageBase.h" extern "C" { #include "bgl.h" } #include "GL/glew.h" #include #include #include #include #include "FilterBase.h" #include "Exception.h" #if (defined(WIN32) || defined(WIN64)) && !defined(FREE_WINDOWS) #define strcasecmp _stricmp #endif // ImageBase class implementation // constructor ImageBase::ImageBase (bool staticSrc) : m_image(NULL), m_imgSize(0), m_avail(false), m_scale(false), m_scaleChange(false), m_flip(false), m_staticSources(staticSrc), m_pyfilter(NULL) { m_size[0] = m_size[1] = 0; m_exports = 0; } // destructor ImageBase::~ImageBase (void) { // release image delete [] m_image; } // release python objects bool ImageBase::release (void) { // iterate sources for (ImageSourceList::iterator it = m_sources.begin(); it != m_sources.end(); ++it) { // release source object delete *it; *it = NULL; } // release filter object Py_XDECREF(m_pyfilter); m_pyfilter = NULL; return true; } // get image unsigned int * ImageBase::getImage (unsigned int texId, double ts) { // if image is not available if (!m_avail) { // if there are any sources if (!m_sources.empty()) { // get images from sources for (ImageSourceList::iterator it = m_sources.begin(); it != m_sources.end(); ++it) // get source image (*it)->getImage(ts); // init image init(m_sources[0]->getSize()[0], m_sources[0]->getSize()[1]); } // calculate new image calcImage(texId, ts); } // if image is available, return it, otherwise NULL return m_avail ? m_image : NULL; } // refresh image source void ImageBase::refresh (void) { // invalidate this image m_avail = false; // refresh all sources for (ImageSourceList::iterator it = m_sources.begin(); it != m_sources.end(); ++it) (*it)->refresh(); } // get source object PyImage * ImageBase::getSource (const char * id) { // find source ImageSourceList::iterator src = findSource(id); // return it, if found return src != m_sources.end() ? (*src)->getSource() : NULL; } // set source object bool ImageBase::setSource (const char * id, PyImage * source) { // find source ImageSourceList::iterator src = findSource(id); // check source loop if (source != NULL && source->m_image->loopDetect(this)) return false; // if found, set new object if (src != m_sources.end()) // if new object is not empty or sources are static if (source != NULL || m_staticSources) // replace previous source (*src)->setSource(source); // otherwise delete source else m_sources.erase(src); // if source is not found and adding is allowed else if (!m_staticSources) { // create new source ImageSource * newSrc = newSource(id); newSrc->setSource(source); // if source was created, add it to source list if (newSrc != NULL) m_sources.push_back(newSrc); } // otherwise source wasn't set else return false; // source was set return true; } // set pixel filter void ImageBase::setFilter (PyFilter * filt) { // reference new filter if (filt != NULL) Py_INCREF(filt); // release previous filter Py_XDECREF(m_pyfilter); // set new filter m_pyfilter = filt; } ExceptionID ImageHasExports; ExceptionID InvalidColorChannel; ExpDesc ImageHasExportsDesc (ImageHasExports, "Image has exported buffers, cannot resize"); ExpDesc InvalidColorChannelDesc (InvalidColorChannel, "Invalid or too many color channels specified. At most 4 values within R, G, B, A, 0, 1"); // initialize image data void ImageBase::init (short width, short height) { // if image has to be scaled if (m_scale) { // recalc sizes of image width = calcSize(width); height = calcSize(height); } // if sizes differ if (width != m_size[0] || height != m_size[1]) { if (m_exports > 0) THRWEXCP(ImageHasExports,S_OK); // new buffer size unsigned int newSize = width * height; // if new buffer is larger than previous if (newSize > m_imgSize) { // set new buffer size m_imgSize = newSize; // release previous and create new buffer delete [] m_image; m_image = new unsigned int[m_imgSize]; } // new image size m_size[0] = width; m_size[1] = height; // scale was processed m_scaleChange = false; } } // find source ImageSourceList::iterator ImageBase::findSource (const char * id) { // iterate sources ImageSourceList::iterator it; for (it = m_sources.begin(); it != m_sources.end(); ++it) // if id matches, return iterator if ((*it)->is(id)) return it; // source not found return it; } // check sources sizes bool ImageBase::checkSourceSizes (void) { // reference size short * refSize = NULL; // iterate sources for (ImageSourceList::iterator it = m_sources.begin(); it != m_sources.end(); ++it) { // get size of current source short * curSize = (*it)->getSize(); // if size is available and is not empty if (curSize[0] != 0 && curSize[1] != 0) { // if reference size is not set if (refSize == NULL) { // set current size as reference refSize = curSize; // otherwise check with current size } else if (curSize[0] != refSize[0] || curSize[1] != refSize[1]) { // if they don't match, report it return false; } } } // all sizes match return true; } // compute nearest power of 2 value short ImageBase::calcSize (short size) { // while there is more than 1 bit in size value while ((size & (size - 1)) != 0) // clear last bit size = size & (size - 1); // return result return size; } // perform loop detection bool ImageBase::loopDetect (ImageBase * img) { // if this object is the same as parameter, loop is detected if (this == img) return true; // check all sources for (ImageSourceList::iterator it = m_sources.begin(); it != m_sources.end(); ++it) // if source detected loop, return this result if ((*it)->getSource() != NULL && (*it)->getSource()->m_image->loopDetect(img)) return true; // no loop detected return false; } // ImageSource class implementation // constructor ImageSource::ImageSource (const char * id) : m_source(NULL), m_image(NULL) { // copy id int idx; for (idx = 0; id[idx] != '\0' && idx < SourceIdSize - 1; ++idx) m_id[idx] = id[idx]; m_id[idx] = '\0'; } // destructor ImageSource::~ImageSource (void) { // release source setSource(NULL); } // compare id bool ImageSource::is (const char * id) { for (char * myId = m_id; *myId != '\0'; ++myId, ++id) if (*myId != *id) return false; return *id == '\0'; } // set source object void ImageSource::setSource (PyImage * source) { // reference new source if (source != NULL) Py_INCREF(source); // release previous source Py_XDECREF(m_source); // set new source m_source = source; } // get image from source unsigned int * ImageSource::getImage (double ts) { // if source is available if (m_source != NULL) // get image from source m_image = m_source->m_image->getImage(0, ts); // otherwise reset buffer else m_image = NULL; // return image return m_image; } // refresh source void ImageSource::refresh (void) { // if source is available, refresh it if (m_source != NULL) m_source->m_image->refresh(); } // list of image types PyTypeList pyImageTypes; // functions for python interface // object allocation PyObject * Image_allocNew (PyTypeObject * type, PyObject * args, PyObject * kwds) { // allocate object PyImage * self = reinterpret_cast(type->tp_alloc(type, 0)); // initialize object structure self->m_image = NULL; // return allocated object return reinterpret_cast(self); } // object deallocation void Image_dealloc (PyImage * self) { // release object attributes if (self->m_image != NULL) { if (self->m_image->m_exports > 0) { PyErr_SetString(PyExc_SystemError, "deallocated Image object has exported buffers"); PyErr_Print(); } // if release requires deleting of object, do it if (self->m_image->release()) delete self->m_image; self->m_image = NULL; } } // get image data PyObject * Image_getImage (PyImage * self, char * mode) { try { unsigned int * image = self->m_image->getImage(); if (image) { // build BGL buffer int dimensions = self->m_image->getBuffSize(); Buffer * buffer; if (mode == NULL || !strcasecmp(mode, "RGBA")) { buffer = BGL_MakeBuffer( GL_BYTE, 1, &dimensions, image); } else { int i, c, ncolor, pixels; int offset[4]; unsigned char *s, *d; // scan the mode to get the channels requested, no more than 4 for (i=ncolor=0; mode[i] != 0 && ncolor < 4; i++) { switch (toupper(mode[i])) { case 'R': offset[ncolor++] = 0; break; case 'G': offset[ncolor++] = 1; break; case 'B': offset[ncolor++] = 2; break; case 'A': offset[ncolor++] = 3; break; case '0': offset[ncolor++] = -1; break; case '1': offset[ncolor++] = -2; break; // if you add more color code, change the switch further down default: THRWEXCP(InvalidColorChannel,S_OK); } } if (mode[i] != 0) { THRWEXCP(InvalidColorChannel,S_OK); } // first get the number of pixels pixels = dimensions / 4; // multiple by the number of channels, each is one byte dimensions = pixels * ncolor; // get an empty buffer buffer = BGL_MakeBuffer( GL_BYTE, 1, &dimensions, NULL); // and fill it for (i=0, d=(unsigned char*)buffer->buf.asbyte, s=(unsigned char*)image; im_image->getSize()[0], self->m_image->getSize()[1]); } // refresh image PyObject * Image_refresh (PyImage * self) { self->m_image->refresh(); Py_RETURN_NONE; } // get scale PyObject * Image_getScale (PyImage * self, void * closure) { if (self->m_image != NULL && self->m_image->getScale()) Py_RETURN_TRUE; else Py_RETURN_FALSE; } // set scale int Image_setScale (PyImage * self, PyObject * value, void * closure) { // check parameter, report failure if (value == NULL || !PyBool_Check(value)) { PyErr_SetString(PyExc_TypeError, "The value must be a bool"); return -1; } // set scale if (self->m_image != NULL) self->m_image->setScale(value == Py_True); // success return 0; } // get flip PyObject * Image_getFlip (PyImage * self, void * closure) { if (self->m_image != NULL && self->m_image->getFlip()) Py_RETURN_TRUE; else Py_RETURN_FALSE; } // set flip int Image_setFlip (PyImage * self, PyObject * value, void * closure) { // check parameter, report failure if (value == NULL || !PyBool_Check(value)) { PyErr_SetString(PyExc_TypeError, "The value must be a bool"); return -1; } // set scale if (self->m_image != NULL) self->m_image->setFlip(value == Py_True); // success return 0; } // get filter source object PyObject * Image_getSource (PyImage * self, PyObject * args) { // get arguments char * id; if (!PyArg_ParseTuple(args, "s:getSource", &id)) return NULL; if (self->m_image != NULL) { // get source object PyObject * src = reinterpret_cast(self->m_image->getSource(id)); // if source is available if (src != NULL) { // return source Py_INCREF(src); return src; } } // source was not found Py_RETURN_NONE; } // set filter source object PyObject * Image_setSource (PyImage * self, PyObject * args) { // get arguments char * id; PyObject * obj; if (!PyArg_ParseTuple(args, "sO:setSource", &id, &obj)) return NULL; if (self->m_image != NULL) { // check type of object if (pyImageTypes.in(obj->ob_type)) { // convert to image struct PyImage * img = reinterpret_cast(obj); // set source if (!self->m_image->setSource(id, img)) { // if not set, retport error PyErr_SetString(PyExc_RuntimeError, "Invalid source or id"); return NULL; } } // else report error else { PyErr_SetString(PyExc_RuntimeError, "Invalid type of object"); return NULL; } } // return none Py_RETURN_NONE; } // get pixel filter object PyObject * Image_getFilter (PyImage * self, void * closure) { // if image object is available if (self->m_image != NULL) { // pixel filter object PyObject * filt = reinterpret_cast(self->m_image->getFilter()); // if filter is present if (filt != NULL) { // return it Py_INCREF(filt); return filt; } } // otherwise return none Py_RETURN_NONE; } // set pixel filter object int Image_setFilter (PyImage * self, PyObject * value, void * closure) { // if image object is available if (self->m_image != NULL) { // check new value if (value == NULL || !pyFilterTypes.in(value->ob_type)) { // report value error PyErr_SetString(PyExc_TypeError, "Invalid type of value"); return -1; } // set new value self->m_image->setFilter(reinterpret_cast(value)); } // return success return 0; } PyObject * Image_valid(PyImage * self, void * closure) { if (self->m_image->isImageAvailable()) { Py_RETURN_TRUE; } else { Py_RETURN_FALSE; } } int Image_getbuffer(PyImage *self, Py_buffer *view, int flags) { unsigned int * image; int ret; try { // can throw in case of resize image = self->m_image->getImage(); } catch (Exception & exp) { // cannot return -1, this creates a crash in Python, for now we will just return an empty buffer exp.report(); //return -1; goto error; } if (!image) { // same remark, see above //PyErr_SetString(PyExc_BufferError, "Image buffer is not available"); //return -1; goto error; } if (view == NULL) { self->m_image->m_exports++; return 0; } ret = PyBuffer_FillInfo(view, (PyObject*)self, image, self->m_image->getBuffSize(), 0, flags); if (ret >= 0) self->m_image->m_exports++; return ret; error: // Return a empty buffer to avoid a crash in Python 3.1 // The bug is fixed in Python SVN 77916, as soon as the python revision used by Blender is // updated, you can simply return -1 and set the error static char* buf = (char *)""; ret = PyBuffer_FillInfo(view, (PyObject*)self, buf, 0, 0, flags); if (ret >= 0) self->m_image->m_exports++; return ret; } void Image_releaseBuffer(PyImage *self, Py_buffer *buffer) { self->m_image->m_exports--; } PyBufferProcs imageBufferProcs = { (getbufferproc)Image_getbuffer, (releasebufferproc)Image_releaseBuffer };