void OpcodeFixBadPixelsList::apply( RawImage &in, RawImage &out, int startY, int endY ) { iPoint2D crop = in->getCropOffset(); uint32 offset = crop.x | (crop.y << 16); for (vector<uint32>::iterator i=bad_pos.begin(); i != bad_pos.end(); i++) { uint32 pos = offset + (*i); out->mBadPixelPositions.push_back(pos); } }
void OpcodeFixBadPixelsConstant::apply( RawImage &in, RawImage &out, int startY, int endY ) { iPoint2D crop = in->getCropOffset(); uint32 offset = crop.x | (crop.y << 16); vector<uint32> bad_pos; for (int y = startY; y < endY; y ++) { ushort16* src = (ushort16*)out->getData(0, y); for (int x = 0; x < in->dim.x; x++) { if (src[x]== mValue) { bad_pos.push_back(offset + ((uint32)x | (uint32)y<<16)); } } } if (!bad_pos.empty()) { //mutex::lock(&out->mBadPixelMutex); out->mBadPixelMutex.lock(); out->mBadPixelPositions.insert(out->mBadPixelPositions.end(), bad_pos.begin(), bad_pos.end()); // pthread_mutex_unlock(&out->mBadPixelMutex); out->mBadPixelMutex.unlock(); } }
int main(int argc, const char* argv[]) { if(argc != 2) { fprintf(stderr, "Usage: darktable-rs-identify <file>\n"); return 2; } char *camfile = find_cameras_xml(argv[0]); if (!camfile) { //fprintf(stderr, "ERROR: Couldn't find cameras.xml\n"); return 2; } //fprintf(stderr, "Using cameras.xml from '%s'\n", camfile); try { std::unique_ptr<CameraMetaData> meta(new CameraMetaData(camfile)); if(!meta.get()) { fprintf(stderr, "ERROR: Couldn't get a CameraMetaData instance\n"); return 2; } #ifdef __AFL_HAVE_MANUAL_CONTROL __AFL_INIT(); #endif FileReader f((char *) argv[1]); std::unique_ptr<FileMap> m(f.readFile()); RawParser t(m.get()); std::unique_ptr<RawDecoder> d(t.getDecoder(meta.get())); if(!d.get()) { fprintf(stderr, "ERROR: Couldn't get a RawDecoder instance\n"); return 2; } d->applyCrop = false; d->failOnUnknown = true; RawImage r = d->mRaw; d->decodeMetaData(meta.get()); fprintf(stdout, "make: %s\n", r->metadata.make.c_str()); fprintf(stdout, "model: %s\n", r->metadata.model.c_str()); fprintf(stdout, "canonical_make: %s\n", r->metadata.canonical_make.c_str()); fprintf(stdout, "canonical_model: %s\n", r->metadata.canonical_model.c_str()); fprintf(stdout, "canonical_alias: %s\n", r->metadata.canonical_alias.c_str()); d->checkSupport(meta.get()); d->decodeRaw(); d->decodeMetaData(meta.get()); r = d->mRaw; for (uint32 i=0; i<r->errors.size(); i++) fprintf(stderr, "WARNING: [rawspeed] %s\n", r->errors[i]); fprintf(stdout, "blackLevel: %d\n", r->blackLevel); fprintf(stdout, "whitePoint: %d\n", r->whitePoint); fprintf(stdout, "blackLevelSeparate: %d %d %d %d\n", r->blackLevelSeparate[0], r->blackLevelSeparate[1], r->blackLevelSeparate[2], r->blackLevelSeparate[3]); fprintf(stdout, "wbCoeffs: %f %f %f %f\n", r->metadata.wbCoeffs[0], r->metadata.wbCoeffs[1], r->metadata.wbCoeffs[2], r->metadata.wbCoeffs[3]); fprintf(stdout, "isCFA: %d\n", r->isCFA); uint32 filters = r->cfa.getDcrawFilter(); fprintf(stdout, "filters: %d (0x%x)\n", filters, filters); uint32 bpp = r->getBpp(); fprintf(stdout, "bpp: %d\n", bpp); uint32 cpp = r->getCpp(); fprintf(stdout, "cpp: %d\n", cpp); fprintf(stdout, "dataType: %d\n", r->getDataType()); // dimensions of uncropped image iPoint2D dimUncropped = r->getUncroppedDim(); fprintf(stdout, "dimUncropped: %dx%d\n", dimUncropped.x, dimUncropped.y); // dimensions of cropped image iPoint2D dimCropped = r->dim; fprintf(stdout, "dimCropped: %dx%d\n", dimCropped.x, dimCropped.y); // crop - Top,Left corner iPoint2D cropTL = r->getCropOffset(); fprintf(stdout, "cropOffset: %dx%d\n", cropTL.x, cropTL.y); fprintf(stdout, "fuji_rotation_pos: %d\n", r->metadata.fujiRotationPos); fprintf(stdout, "pixel_aspect_ratio: %f\n", r->metadata.pixelAspectRatio); double sum = 0.0f; for(uint32 row = 0; row < ((uint32) dimUncropped.y); row++) { uchar8 *data = r->getDataUncropped(0, row); for(uint32 byte = 0; byte < ((uint32) dimUncropped.x*bpp) ; byte++) sum += (double) data[byte]; } fprintf(stdout, "Image byte sum: %lf\n", sum); fprintf(stdout, "Image byte avg: %lf\n", sum/(dimUncropped.y*dimUncropped.x*bpp)); } catch(const std::exception &exc) { printf("ERROR: [rawspeed] %s\n", exc.what()); /* if an exception is raised lets not retry or handle the specific ones, consider the file as corrupted */ return 2; } catch(...) { printf("Unhandled exception in rawspeed-identify\n"); return 3; } return 0; }
int main(int argc, const char* argv[]) { if(argc != 2) { fprintf(stderr, "Usage: darktable-rs-identify <file>\n"); return 2; } FileReader f((char *) argv[1]); #ifdef __APPLE__ std::auto_ptr<RawDecoder> d; std::auto_ptr<FileMap> m; #else std::unique_ptr<RawDecoder> d; std::unique_ptr<FileMap> m; #endif char camfile[PATH_MAX] = { 0 }; #if defined(__MACH__) || defined(__APPLE__) char *directory = dt_loc_find_install_dir("/share/darktable", argv[0]); if(!directory) { fprintf(stderr, "Couldn't find share/darktable folder\n"); return 2; } snprintf(camfile, sizeof(camfile), "%s/rawspeed/cameras.xml", directory); #else snprintf(camfile, sizeof(camfile), "%s/rawspeed/cameras.xml", DARKTABLE_DATADIR); #endif //fprintf(stderr, "Looking for cameras.xml in '%s'\n", camfile); try { CameraMetaData *meta = new CameraMetaData(camfile); #ifdef __APPLE__ m = auto_ptr<FileMap>(f.readFile()); #else m = unique_ptr<FileMap>(f.readFile()); #endif RawParser t(m.get()); #ifdef __APPLE__ d = auto_ptr<RawDecoder>(t.getDecoder(meta)); #else d = unique_ptr<RawDecoder>(t.getDecoder(meta)); #endif if(!d.get()) { fprintf(stderr, "ERROR: Couldn't get a RawDecoder instance\n"); return 2; } d->failOnUnknown = true; d->checkSupport(meta); d->decodeRaw(); d->decodeMetaData(meta); RawImage r = d->mRaw; for (uint32 i=0; i<r->errors.size(); i++) fprintf(stderr, "WARNING: [rawspeed] %s\n", r->errors[i]); fprintf(stdout, "make: %s\n", r->metadata.make.c_str()); fprintf(stdout, "model: %s\n", r->metadata.model.c_str()); fprintf(stdout, "canonical_make: %s\n", r->metadata.canonical_make.c_str()); fprintf(stdout, "canonical_model: %s\n", r->metadata.canonical_model.c_str()); fprintf(stdout, "canonical_alias: %s\n", r->metadata.canonical_alias.c_str()); fprintf(stdout, "blackLevel: %d\n", r->blackLevel); fprintf(stdout, "whitePoint: %d\n", r->whitePoint); fprintf(stdout, "blackLevelSeparate: %d %d %d %d\n", r->blackLevelSeparate[0], r->blackLevelSeparate[1], r->blackLevelSeparate[2], r->blackLevelSeparate[3]); fprintf(stdout, "wbCoeffs: %f %f %f %f\n", r->metadata.wbCoeffs[0], r->metadata.wbCoeffs[1], r->metadata.wbCoeffs[2], r->metadata.wbCoeffs[3]); fprintf(stdout, "isCFA: %d\n", r->isCFA); uint32_t filters = r->cfa.getDcrawFilter(); fprintf(stdout, "filters: %d (0x%x)\n", filters, filters); uint32_t bpp = r->getBpp(); fprintf(stdout, "bpp: %d\n", bpp); uint32_t cpp = r->getCpp(); fprintf(stdout, "cpp: %d\n", cpp); fprintf(stdout, "dataType: %d\n", r->getDataType()); // dimensions of uncropped image iPoint2D dimUncropped = r->getUncroppedDim(); fprintf(stdout, "dimUncropped: %dx%d\n", dimUncropped.x, dimUncropped.y); // dimensions of cropped image iPoint2D dimCropped = r->dim; fprintf(stdout, "dimCropped: %dx%d\n", dimCropped.x, dimCropped.y); // crop - Top,Left corner iPoint2D cropTL = r->getCropOffset(); fprintf(stdout, "cropOffset: %dx%d\n", cropTL.x, cropTL.y); fprintf(stdout, "fuji_rotation_pos: %d\n", r->metadata.fujiRotationPos); fprintf(stdout, "pixel_aspect_ratio: %f\n", r->metadata.pixelAspectRatio); double sum = 0.0f; for(uint32_t row = 0; row < ((uint32_t) dimUncropped.y); row++) { uint8_t *data = r->getDataUncropped(0, 0); for(uint32_t byte = 0; byte < ((uint32_t) dimUncropped.x*cpp*bpp) ; byte++) sum += (double) data[byte]; } fprintf(stdout, "Image byte sum: %lf\n", sum); fprintf(stdout, "Image byte avg: %lf\n", sum/(dimUncropped.y*dimUncropped.x*cpp*bpp)); } catch(const std::exception &exc) { printf("ERROR: [rawspeed] %s\n", exc.what()); /* if an exception is raised lets not retry or handle the specific ones, consider the file as corrupted */ return 2; } catch(...) { printf("Unhandled exception in rawspeed-identify\n"); return 3; } return 0; }