/* * ***** BEGIN GPLLICENSE BLOCK ***** * * This program is free software; you can redistribute it and/or * modify it under the terms of the GNU 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 General Public License for more details. * * You should have received a copy of the GNU General Public License * along with this program; if not, write to the Free Software Foundation, * Inc., 51 Franklin Street, Fifth Floor, Boston, MA 02110-1301, USA. * * Copyright by Gernot Ziegler . * All rights reserved. * * The Original Code is: all of this file. * * Contributor(s): Austin Benesh, Ton Roosendaal (float, half, speedup, cleanup...). * * ***** END GPL LICENSE BLOCK ***** */ /** \file blender/imbuf/intern/openexr/openexr_api.cpp * \ingroup openexr */ #include #include #include #include #include extern "C" { // The following prevents a linking error in debug mode for MSVC using the libs in CVS #if defined(WITH_OPENEXR) && defined(_WIN32) && defined(_DEBUG) && !defined(__MINGW32__) && !defined(__CYGWIN__) _CRTIMP void __cdecl _invalid_parameter_noinfo(void) { } #endif #include "MEM_guardedalloc.h" #include "BLI_blenlib.h" #include "BLI_math_color.h" #include "IMB_imbuf_types.h" #include "IMB_imbuf.h" #include "IMB_allocimbuf.h" #include "IMB_metadata.h" #include "openexr_multi.h" } #include #if defined (_WIN32) && !defined(FREE_WINDOWS) #include #include #include #include #include #include #include #include #include #include #include #include #else #include #include #include #include #include #include #include #include #include #include #include #include #endif using namespace Imf; using namespace Imath; class Mem_IStream: public IStream { public: Mem_IStream (unsigned char *exrbuf, size_t exrsize): IStream("dummy"), _exrpos (0), _exrsize(exrsize) { _exrbuf = exrbuf; } virtual bool read (char c[], int n); virtual Int64 tellg (); virtual void seekg (Int64 pos); virtual void clear (); //virtual ~Mem_IStream() {}; // unused private: Int64 _exrpos; Int64 _exrsize; unsigned char *_exrbuf; }; bool Mem_IStream::read (char c[], int n) { if (n + _exrpos <= _exrsize) { memcpy(c, (void *)(&_exrbuf[_exrpos]), n); _exrpos += n; return true; } else return false; } Int64 Mem_IStream::tellg () { return _exrpos; } void Mem_IStream::seekg (Int64 pos) { _exrpos = pos; } void Mem_IStream::clear () { } struct _RGBAZ { half r; half g; half b; half a; half z; }; typedef struct _RGBAZ RGBAZ; extern "C" { int imb_is_a_openexr(unsigned char *mem) { return Imf::isImfMagic ((const char *)mem); } static void openexr_header_compression(Header *header, int compression) { switch(compression) { case 0: header->compression() = NO_COMPRESSION; break; case 1: header->compression() = PXR24_COMPRESSION; break; case 2: header->compression() = ZIP_COMPRESSION; break; case 3: header->compression() = PIZ_COMPRESSION; break; case 4: header->compression() = RLE_COMPRESSION; break; default: header->compression() = ZIP_COMPRESSION; break; } } static void openexr_header_metadata(Header *header, struct ImBuf *ibuf) { ImMetaData* info; for (info= ibuf->metadata; info; info= info->next) header->insert(info->key, StringAttribute(info->value)); } static int imb_save_openexr_half(struct ImBuf *ibuf, const char *name, int flags) { int channels = ibuf->channels; int width = ibuf->x; int height = ibuf->y; int write_zbuf = (flags & IB_zbuffloat) && ibuf->zbuf_float != NULL; // summarize try { Header header (width, height); openexr_header_compression(&header, ibuf->ftype & OPENEXR_COMPRESS); openexr_header_metadata(&header, ibuf); header.channels().insert ("R", Channel (HALF)); header.channels().insert ("G", Channel (HALF)); header.channels().insert ("B", Channel (HALF)); if (ibuf->planes==32 && channels >= 4) header.channels().insert ("A", Channel (HALF)); if (write_zbuf) // z we do as float always header.channels().insert ("Z", Channel (FLOAT)); FrameBuffer frameBuffer; OutputFile *file = new OutputFile(name, header); /* we store first everything in half array */ RGBAZ *pixels = new RGBAZ[height * width]; RGBAZ *to = pixels; int xstride= sizeof (RGBAZ); int ystride= xstride*width; /* indicate used buffers */ frameBuffer.insert ("R", Slice (HALF, (char *) &pixels[0].r, xstride, ystride)); frameBuffer.insert ("G", Slice (HALF, (char *) &pixels[0].g, xstride, ystride)); frameBuffer.insert ("B", Slice (HALF, (char *) &pixels[0].b, xstride, ystride)); if (ibuf->planes==32 && channels >= 4) frameBuffer.insert ("A", Slice (HALF, (char *) &pixels[0].a, xstride, ystride)); if (write_zbuf) frameBuffer.insert ("Z", Slice (FLOAT, (char *)(ibuf->zbuf_float + (height-1)*width), sizeof(float), sizeof(float) * -width)); if (ibuf->rect_float) { float *from; for (int i = ibuf->y-1; i >= 0; i--) { from= ibuf->rect_float + channels*i*width; for (int j = ibuf->x; j > 0; j--) { to->r = from[0]; to->g = from[1]; to->b = from[2]; to->a = (channels >= 4)? from[3]: 1.0f; to++; from += 4; } } } else { unsigned char *from; if (ibuf->profile == IB_PROFILE_LINEAR_RGB) { for (int i = ibuf->y-1; i >= 0; i--) { from= (unsigned char *)ibuf->rect + channels*i*width; for (int j = ibuf->x; j > 0; j--) { to->r = (float)(from[0])/255.0; to->g = (float)(from[1])/255.0; to->b = (float)(from[2])/255.0; to->a = (float)(channels >= 4) ? from[3]/255.0 : 1.0f; to++; from += 4; } } } else { for (int i = ibuf->y-1; i >= 0; i--) { from= (unsigned char *)ibuf->rect + channels*i*width; for (int j = ibuf->x; j > 0; j--) { to->r = srgb_to_linearrgb((float)from[0] / 255.0); to->g = srgb_to_linearrgb((float)from[1] / 255.0); to->b = srgb_to_linearrgb((float)from[2] / 255.0); to->a = channels >= 4 ? (float)from[3]/255.0 : 1.0f; to++; from += 4; } } } } // printf("OpenEXR-save: Writing OpenEXR file of height %d.\n", height); file->setFrameBuffer (frameBuffer); file->writePixels (height); delete file; delete [] pixels; } catch (const std::exception &exc) { printf("OpenEXR-save: ERROR: %s\n", exc.what()); if (ibuf) IMB_freeImBuf(ibuf); return (0); } return (1); } static int imb_save_openexr_float(struct ImBuf *ibuf, const char *name, int flags) { int channels = ibuf->channels; int width = ibuf->x; int height = ibuf->y; int write_zbuf = (flags & IB_zbuffloat) && ibuf->zbuf_float != NULL; // summarize try { Header header (width, height); openexr_header_compression(&header, ibuf->ftype & OPENEXR_COMPRESS); openexr_header_metadata(&header, ibuf); header.channels().insert ("R", Channel (FLOAT)); header.channels().insert ("G", Channel (FLOAT)); header.channels().insert ("B", Channel (FLOAT)); if (ibuf->planes==32 && channels >= 4) header.channels().insert ("A", Channel (FLOAT)); if (write_zbuf) header.channels().insert ("Z", Channel (FLOAT)); FrameBuffer frameBuffer; OutputFile *file = new OutputFile(name, header); int xstride = sizeof(float) * channels; int ystride = - xstride*width; float *rect[4] = {NULL, NULL, NULL, NULL}; /* last scanline, stride negative */ rect[0]= ibuf->rect_float + channels*(height-1)*width; rect[1]= rect[0]+1; rect[2]= rect[0]+2; rect[3]= (channels >= 4)? rect[0]+3:rect[0]; /* red as alpha, is this needed since alpha isn't written? */ frameBuffer.insert ("R", Slice (FLOAT, (char *)rect[0], xstride, ystride)); frameBuffer.insert ("G", Slice (FLOAT, (char *)rect[1], xstride, ystride)); frameBuffer.insert ("B", Slice (FLOAT, (char *)rect[2], xstride, ystride)); if (ibuf->planes==32 && channels >= 4) frameBuffer.insert ("A", Slice (FLOAT, (char *)rect[3], xstride, ystride)); if (write_zbuf) frameBuffer.insert ("Z", Slice (FLOAT, (char *) (ibuf->zbuf_float + (height-1)*width), sizeof(float), sizeof(float) * -width)); file->setFrameBuffer (frameBuffer); file->writePixels (height); delete file; } catch (const std::exception &exc) { printf("OpenEXR-save: ERROR: %s\n", exc.what()); if (ibuf) IMB_freeImBuf(ibuf); return (0); } return (1); // printf("OpenEXR-save: Done.\n"); } int imb_save_openexr(struct ImBuf *ibuf, const char *name, int flags) { if (flags & IB_mem) { printf("OpenEXR-save: Create EXR in memory CURRENTLY NOT SUPPORTED !\n"); imb_addencodedbufferImBuf(ibuf); ibuf->encodedsize = 0; return(0); } if (ibuf->ftype & OPENEXR_HALF) return imb_save_openexr_half(ibuf, name, flags); else { /* when no float rect, we save as half (16 bits is sufficient) */ if (ibuf->rect_float==NULL) return imb_save_openexr_half(ibuf, name, flags); else return imb_save_openexr_float(ibuf, name, flags); } } /* ********************* Nicer API, MultiLayer and with Tile file support ************************************ */ /* naming rules: * - parse name from right to left * - last character is channel ID, 1 char like 'A' 'R' 'G' 'B' 'X' 'Y' 'Z' 'W' 'U' 'V' * - separated with a dot; the Pass name (like "Depth", "Color", "Diffuse" or "Combined") * - separated with a dot: the Layer name (like "Lamp1" or "Walls" or "Characters") */ static ListBase exrhandles= {NULL, NULL}; typedef struct ExrHandle { struct ExrHandle *next, *prev; InputFile *ifile; TiledOutputFile *tofile; OutputFile *ofile; int tilex, tiley; int width, height; int mipmap; ListBase channels; /* flattened out, ExrChannel */ ListBase layers; /* hierarchical, pointing in end to ExrChannel */ } ExrHandle; /* flattened out channel */ typedef struct ExrChannel { struct ExrChannel *next, *prev; char name[EXR_TOT_MAXNAME+1]; /* full name of layer+pass */ int xstride, ystride; /* step to next pixel, to next scanline */ float *rect; /* first pointer to write in */ char chan_id; /* quick lookup of channel char */ } ExrChannel; /* hierarchical; layers -> passes -> channels[] */ typedef struct ExrPass { struct ExrPass *next, *prev; char name[EXR_PASS_MAXNAME]; int totchan; float *rect; struct ExrChannel *chan[EXR_PASS_MAXCHAN]; char chan_id[EXR_PASS_MAXCHAN]; } ExrPass; typedef struct ExrLayer { struct ExrLayer *next, *prev; char name[EXR_LAY_MAXNAME+1]; ListBase passes; } ExrLayer; /* ********************** */ void *IMB_exr_get_handle(void) { ExrHandle *data= (ExrHandle *)MEM_callocN(sizeof(ExrHandle), "exr handle"); BLI_addtail(&exrhandles, data); return data; } /* adds flattened ExrChannels */ /* xstride, ystride and rect can be done in set_channel too, for tile writing */ void IMB_exr_add_channel(void *handle, const char *layname, const char *passname, int xstride, int ystride, float *rect) { ExrHandle *data= (ExrHandle *)handle; ExrChannel *echan; echan= (ExrChannel *)MEM_callocN(sizeof(ExrChannel), "exr tile channel"); if (layname) { char lay[EXR_LAY_MAXNAME+1], pass[EXR_PASS_MAXNAME+1]; BLI_strncpy(lay, layname, EXR_LAY_MAXNAME); BLI_strncpy(pass, passname, EXR_PASS_MAXNAME); sprintf(echan->name, "%s.%s", lay, pass); } else BLI_strncpy(echan->name, passname, EXR_TOT_MAXNAME-1); echan->xstride= xstride; echan->ystride= ystride; echan->rect= rect; // printf("added channel %s\n", echan->name); BLI_addtail(&data->channels, echan); } /* only used for writing temp. render results (not image files) */ int IMB_exr_begin_write(void *handle, const char *filename, int width, int height, int compress) { ExrHandle *data= (ExrHandle *)handle; Header header (width, height); ExrChannel *echan; data->width= width; data->height= height; for (echan= (ExrChannel *)data->channels.first; echan; echan= echan->next) header.channels().insert (echan->name, Channel (FLOAT)); openexr_header_compression(&header, compress); // openexr_header_metadata(&header, ibuf); // no imbuf. cant write /* header.lineOrder() = DECREASING_Y; this crashes in windows for file read! */ header.insert ("BlenderMultiChannel", StringAttribute ("Blender V2.55.1 and newer")); /* avoid crash/abort when we don't have permission to write here */ try { data->ofile = new OutputFile(filename, header); } catch (const std::exception &exc) { std::cerr << "IMB_exr_begin_write: ERROR: " << exc.what() << std::endl; data->ofile = NULL; } return (data->ofile != NULL); } void IMB_exrtile_begin_write(void *handle, const char *filename, int mipmap, int width, int height, int tilex, int tiley) { ExrHandle *data= (ExrHandle *)handle; Header header (width, height); ExrChannel *echan; data->tilex= tilex; data->tiley= tiley; data->width= width; data->height= height; data->mipmap= mipmap; for (echan= (ExrChannel *)data->channels.first; echan; echan= echan->next) header.channels().insert (echan->name, Channel (FLOAT)); header.setTileDescription (TileDescription (tilex, tiley, (mipmap)? MIPMAP_LEVELS: ONE_LEVEL)); header.lineOrder() = RANDOM_Y; header.compression() = RLE_COMPRESSION; header.insert ("BlenderMultiChannel", StringAttribute ("Blender V2.43")); data->tofile = new TiledOutputFile(filename, header); } /* read from file */ int IMB_exr_begin_read(void *handle, const char *filename, int *width, int *height) { ExrHandle *data= (ExrHandle *)handle; if (BLI_exists(filename) && BLI_file_size(filename)>32) { /* 32 is arbitrary, but zero length files crashes exr */ data->ifile = new InputFile(filename); if (data->ifile) { Box2i dw = data->ifile->header().dataWindow(); data->width= *width = dw.max.x - dw.min.x + 1; data->height= *height = dw.max.y - dw.min.y + 1; const ChannelList &channels = data->ifile->header().channels(); for (ChannelList::ConstIterator i = channels.begin(); i != channels.end(); ++i) IMB_exr_add_channel(data, NULL, i.name(), 0, 0, NULL); return 1; } } return 0; } /* still clumsy name handling, layers/channels can be ordered as list in list later */ void IMB_exr_set_channel(void *handle, const char *layname, const char *passname, int xstride, int ystride, float *rect) { ExrHandle *data= (ExrHandle *)handle; ExrChannel *echan; char name[EXR_TOT_MAXNAME + 1]; if (layname) { char lay[EXR_LAY_MAXNAME+1], pass[EXR_PASS_MAXNAME+1]; BLI_strncpy(lay, layname, EXR_LAY_MAXNAME); BLI_strncpy(pass, passname, EXR_PASS_MAXNAME); sprintf(name, "%s.%s", lay, pass); } else BLI_strncpy(name, passname, EXR_TOT_MAXNAME-1); echan= (ExrChannel *)BLI_findstring(&data->channels, name, offsetof(ExrChannel, name)); if (echan) { echan->xstride= xstride; echan->ystride= ystride; echan->rect= rect; } else printf("IMB_exrtile_set_channel error %s\n", name); } void IMB_exrtile_clear_channels(void *handle) { ExrHandle *data= (ExrHandle *)handle; BLI_freelistN(&data->channels); } void IMB_exrtile_write_channels(void *handle, int partx, int party, int level) { ExrHandle *data= (ExrHandle *)handle; FrameBuffer frameBuffer; ExrChannel *echan; for (echan= (ExrChannel *)data->channels.first; echan; echan= echan->next) { float *rect= echan->rect - echan->xstride*partx - echan->ystride*party; frameBuffer.insert (echan->name, Slice (FLOAT, (char *)rect, echan->xstride*sizeof(float), echan->ystride*sizeof(float))); } data->tofile->setFrameBuffer (frameBuffer); try { // printf("write tile %d %d\n", partx/data->tilex, party/data->tiley); data->tofile->writeTile (partx/data->tilex, party/data->tiley, level); } catch (const std::exception &exc) { std::cerr << "OpenEXR-writeTile: ERROR: " << exc.what() << std::endl; } } void IMB_exr_write_channels(void *handle) { ExrHandle *data= (ExrHandle *)handle; FrameBuffer frameBuffer; ExrChannel *echan; if (data->channels.first) { for (echan= (ExrChannel *)data->channels.first; echan; echan= echan->next) { /* last scanline, stride negative */ float *rect = echan->rect + echan->xstride*(data->height-1)*data->width; frameBuffer.insert (echan->name, Slice (FLOAT, (char *)rect, echan->xstride*sizeof(float), -echan->ystride*sizeof(float))); } data->ofile->setFrameBuffer (frameBuffer); try { data->ofile->writePixels (data->height); } catch (const std::exception &exc) { std::cerr << "OpenEXR-writePixels: ERROR: " << exc.what() << std::endl; } } else { printf("Error: attempt to save MultiLayer without layers.\n"); } } void IMB_exr_read_channels(void *handle) { ExrHandle *data= (ExrHandle *)handle; FrameBuffer frameBuffer; ExrChannel *echan; /* check if exr was saved with previous versions of blender which flipped images */ const StringAttribute *ta = data->ifile->header().findTypedAttribute ("BlenderMultiChannel"); short flip = (ta && strncmp(ta->value().c_str(), "Blender V2.43", 13)==0); /* 'previous multilayer attribute, flipped */ for (echan= (ExrChannel *)data->channels.first; echan; echan= echan->next) { if (echan->rect) { if (flip) frameBuffer.insert (echan->name, Slice (FLOAT, (char *)echan->rect, echan->xstride*sizeof(float), echan->ystride*sizeof(float))); else frameBuffer.insert (echan->name, Slice (FLOAT, (char *)(echan->rect + echan->xstride*(data->height-1)*data->width), echan->xstride*sizeof(float), -echan->ystride*sizeof(float))); } else printf("warning, channel with no rect set %s\n", echan->name); } data->ifile->setFrameBuffer (frameBuffer); try { data->ifile->readPixels (0, data->height-1); } catch (const std::exception &exc) { std::cerr << "OpenEXR-readPixels: ERROR: " << exc.what() << std::endl; } } void IMB_exr_multilayer_convert(void *handle, void *base, void * (*addlayer)(void *base, char *str), void (*addpass)(void *base, void *lay, char *str, float *rect, int totchan, char *chan_id)) { ExrHandle *data= (ExrHandle *)handle; ExrLayer *lay; ExrPass *pass; if (data->layers.first==NULL) { printf("cannot convert multilayer, no layers in handle\n"); return; } for (lay= (ExrLayer *)data->layers.first; lay; lay= lay->next) { void *laybase= addlayer(base, lay->name); if (laybase) { for (pass= (ExrPass *)lay->passes.first; pass; pass= pass->next) { addpass(base, laybase, pass->name, pass->rect, pass->totchan, pass->chan_id); pass->rect= NULL; } } } } void IMB_exr_close(void *handle) { ExrHandle *data= (ExrHandle *)handle; ExrLayer *lay; ExrPass *pass; if (data->ifile) delete data->ifile; else if (data->ofile) delete data->ofile; else if (data->tofile) delete data->tofile; data->ifile= NULL; data->ofile= NULL; data->tofile= NULL; BLI_freelistN(&data->channels); for (lay= (ExrLayer *)data->layers.first; lay; lay= lay->next) { for (pass= (ExrPass *)lay->passes.first; pass; pass= pass->next) if (pass->rect) MEM_freeN(pass->rect); BLI_freelistN(&lay->passes); } BLI_freelistN(&data->layers); BLI_remlink(&exrhandles, data); MEM_freeN(data); } /* ********* */ static int imb_exr_split_channel_name(ExrChannel *echan, char *layname, char *passname) { int plen, len= strlen(echan->name); if (len < 4) { printf("multilayer read: name too short: %s\n", echan->name); return 0; } if (echan->name[len-2]!='.') { printf("multilayer read: name has no Channel: %s\n", echan->name); return 0; } echan->chan_id= echan->name[len-1]; len-= 3; while(len>=0) { if (echan->name[len]=='.') break; len--; } BLI_strncpy(passname, echan->name+len+1, EXR_PASS_MAXNAME); plen= strlen(passname); if (plen < 3) { printf("multilayer read: should not happen: %s\n", echan->name); return 0; } passname[plen-2]= 0; if (len<1) layname[0]= 0; else { BLI_strncpy(layname, echan->name, EXR_LAY_MAXNAME); layname[len]= 0; } // printf("found lay %s pass %s chan %c\n", layname, passname, echan->chan_id); return 1; } static ExrLayer *imb_exr_get_layer(ListBase *lb, char *layname) { ExrLayer *lay= (ExrLayer *)BLI_findstring(lb, layname, offsetof(ExrLayer, name)); if (lay==NULL) { lay= (ExrLayer *)MEM_callocN(sizeof(ExrLayer), "exr layer"); BLI_addtail(lb, lay); BLI_strncpy(lay->name, layname, EXR_LAY_MAXNAME); } return lay; } static ExrPass *imb_exr_get_pass(ListBase *lb, char *passname) { ExrPass *pass= (ExrPass *)BLI_findstring(lb, passname, offsetof(ExrPass, name)); if (pass==NULL) { pass= (ExrPass *)MEM_callocN(sizeof(ExrPass), "exr pass"); if (strcmp(passname, "Combined")==0) BLI_addhead(lb, pass); else BLI_addtail(lb, pass); } BLI_strncpy(pass->name, passname, EXR_LAY_MAXNAME); return pass; } /* creates channels, makes a hierarchy and assigns memory to channels */ static ExrHandle *imb_exr_begin_read_mem(InputFile *file, int width, int height) { ExrLayer *lay; ExrPass *pass; ExrChannel *echan; ExrHandle *data= (ExrHandle *)IMB_exr_get_handle(); int a; char layname[EXR_TOT_MAXNAME], passname[EXR_TOT_MAXNAME]; data->ifile= file; data->width= width; data->height= height; const ChannelList &channels = data->ifile->header().channels(); for (ChannelList::ConstIterator i = channels.begin(); i != channels.end(); ++i) IMB_exr_add_channel(data, NULL, i.name(), 0, 0, NULL); /* now try to sort out how to assign memory to the channels */ /* first build hierarchical layer list */ for (echan= (ExrChannel *)data->channels.first; echan; echan= echan->next) { if ( imb_exr_split_channel_name(echan, layname, passname) ) { ExrLayer *lay= imb_exr_get_layer(&data->layers, layname); ExrPass *pass= imb_exr_get_pass(&lay->passes, passname); pass->chan[pass->totchan]= echan; pass->totchan++; if (pass->totchan>=EXR_PASS_MAXCHAN) break; } } if (echan) { printf("error, too many channels in one pass: %s\n", echan->name); IMB_exr_close(data); return NULL; } /* with some heuristics, try to merge the channels in buffers */ for (lay= (ExrLayer *)data->layers.first; lay; lay= lay->next) { for (pass= (ExrPass *)lay->passes.first; pass; pass= pass->next) { if (pass->totchan) { pass->rect= (float *)MEM_mapallocN(width*height*pass->totchan*sizeof(float), "pass rect"); if (pass->totchan==1) { echan= pass->chan[0]; echan->rect= pass->rect; echan->xstride= 1; echan->ystride= width; pass->chan_id[0]= echan->chan_id; } else { char lookup[256]; memset(lookup, 0, sizeof(lookup)); /* we can have RGB(A), XYZ(W), UVA */ if (pass->totchan==3 || pass->totchan==4) { if (pass->chan[0]->chan_id=='B' || pass->chan[1]->chan_id=='B' || pass->chan[2]->chan_id=='B') { lookup[(unsigned int)'R']= 0; lookup[(unsigned int)'G']= 1; lookup[(unsigned int)'B']= 2; lookup[(unsigned int)'A']= 3; } else if (pass->chan[0]->chan_id=='Y' || pass->chan[1]->chan_id=='Y' || pass->chan[2]->chan_id=='Y') { lookup[(unsigned int)'X']= 0; lookup[(unsigned int)'Y']= 1; lookup[(unsigned int)'Z']= 2; lookup[(unsigned int)'W']= 3; } else { lookup[(unsigned int)'U']= 0; lookup[(unsigned int)'V']= 1; lookup[(unsigned int)'A']= 2; } for (a=0; atotchan; a++) { echan= pass->chan[a]; echan->rect= pass->rect + lookup[(unsigned int)echan->chan_id]; echan->xstride= pass->totchan; echan->ystride= width*pass->totchan; pass->chan_id[ (unsigned int)lookup[(unsigned int)echan->chan_id] ]= echan->chan_id; } } else { /* unknown */ for (a=0; atotchan; a++) { echan= pass->chan[a]; echan->rect= pass->rect + a; echan->xstride= pass->totchan; echan->ystride= width*pass->totchan; pass->chan_id[a]= echan->chan_id; } } } } } } return data; } /* ********************************************************* */ typedef struct RGBA { float r; float g; float b; float a; } RGBA; /* debug only */ static void exr_print_filecontents(InputFile *file) { const ChannelList &channels = file->header().channels(); for (ChannelList::ConstIterator i = channels.begin(); i != channels.end(); ++i) { const Channel &channel = i.channel(); printf("OpenEXR-load: Found channel %s of type %d\n", i.name(), channel.type); } } /* for non-multilayer, map R G B A channel names to something that's in this file */ static const char *exr_rgba_channelname(InputFile *file, const char *chan) { const ChannelList &channels = file->header().channels(); for (ChannelList::ConstIterator i = channels.begin(); i != channels.end(); ++i) { /* const Channel &channel = i.channel(); */ /* Not used yet */ const char *str= i.name(); int len= strlen(str); if (len) { if (BLI_strcasecmp(chan, str+len-1)==0) { return str; } } } return chan; } static int exr_has_zbuffer(InputFile *file) { return !(file->header().channels().findChannel("Z") == NULL); } static int exr_is_renderresult(InputFile *file) { const StringAttribute *comments= file->header().findTypedAttribute("BlenderMultiChannel"); if (comments) // if (comments->value() == "Blender MultiChannel") return 1; return 0; } struct ImBuf *imb_load_openexr(unsigned char *mem, size_t size, int flags) { struct ImBuf *ibuf = NULL; InputFile *file = NULL; if (imb_is_a_openexr(mem) == 0) return(NULL); try { Mem_IStream *membuf = new Mem_IStream(mem, size); int is_multi; file = new InputFile(*membuf); Box2i dw = file->header().dataWindow(); int width = dw.max.x - dw.min.x + 1; int height = dw.max.y - dw.min.y + 1; //printf("OpenEXR-load: image data window %d %d %d %d\n", // dw.min.x, dw.min.y, dw.max.x, dw.max.y); if (0) // debug exr_print_filecontents(file); is_multi= exr_is_renderresult(file); /* do not make an ibuf when */ if (is_multi && !(flags & IB_test) && !(flags & IB_multilayer)) { printf("Error: can't process EXR multilayer file\n"); } else { ibuf = IMB_allocImBuf(width, height, 32, 0); ibuf->ftype = OPENEXR; /* openEXR is linear as per EXR spec */ ibuf->profile = IB_PROFILE_LINEAR_RGB; if (!(flags & IB_test)) { if (is_multi) /* only enters with IB_multilayer flag set */ { /* constructs channels for reading, allocates memory in channels */ ExrHandle *handle= imb_exr_begin_read_mem(file, width, height); if (handle) { IMB_exr_read_channels(handle); ibuf->userdata= handle; /* potential danger, the caller has to check for this! */ return ibuf; } } else { FrameBuffer frameBuffer; float *first; int xstride = sizeof(float) * 4; int ystride = - xstride*width; imb_addrectfloatImBuf(ibuf); /* inverse correct first pixel for datawindow coordinates (- dw.min.y because of y flip) */ first= ibuf->rect_float - 4*(dw.min.x - dw.min.y*width); /* but, since we read y-flipped (negative y stride) we move to last scanline */ first+= 4*(height-1)*width; frameBuffer.insert ( exr_rgba_channelname(file, "R"), Slice (FLOAT, (char *) first, xstride, ystride)); frameBuffer.insert ( exr_rgba_channelname(file, "G"), Slice (FLOAT, (char *) (first+1), xstride, ystride)); frameBuffer.insert ( exr_rgba_channelname(file, "B"), Slice (FLOAT, (char *) (first+2), xstride, ystride)); frameBuffer.insert ( exr_rgba_channelname(file, "A"), Slice (FLOAT, (char *) (first+3), xstride, ystride, 1, 1, 1.0f)); /* 1.0 is fill value */ if (exr_has_zbuffer(file)) { float *firstz; addzbuffloatImBuf(ibuf); firstz= ibuf->zbuf_float - (dw.min.x - dw.min.y*width); firstz+= (height-1)*width; frameBuffer.insert ("Z", Slice (FLOAT, (char *)firstz , sizeof(float), -width*sizeof(float))); } file->setFrameBuffer (frameBuffer); file->readPixels (dw.min.y, dw.max.y); // XXX, ImBuf has no nice way to deal with this. // ideally IM_rect would be used when the caller wants a rect BUT // at the moment all functions use IM_rect. // Disabling this is ok because all functions should check if a rect exists and create one on demand. // // Disabling this because the sequencer frees immediate. // // if (flag & IM_rect) // IMB_rect_from_float(ibuf); } } } delete file; return(ibuf); } catch (const std::exception &exc) { std::cerr << exc.what() << std::endl; if (ibuf) IMB_freeImBuf(ibuf); delete file; return (0); } } } // export "C"