/* * ***** BEGIN GPL LICENSE 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. * * Contributor(s): Campbell Barton * * ***** END GPL LICENSE BLOCK ***** */ /** \file blender/imbuf/intern/jp2.c * \ingroup imbuf */ #include "MEM_guardedalloc.h" #include "BLI_math.h" #include "BLI_fileops.h" #include "imbuf.h" #include "IMB_imbuf_types.h" #include "IMB_imbuf.h" #include "IMB_allocimbuf.h" #include "IMB_filetype.h" #include "IMB_colormanagement.h" #include "IMB_colormanagement_intern.h" #include "openjpeg.h" // #define JP2_FILEHEADER_SIZE 14 /* UNUSED */ static char JP2_HEAD[] = {0x0, 0x0, 0x0, 0x0C, 0x6A, 0x50, 0x20, 0x20, 0x0D, 0x0A, 0x87, 0x0A}; static char J2K_HEAD[] = {0xFF, 0x4F, 0xFF, 0x51, 0x00}; /* We only need this because of how the presets are set */ /* this typedef is copied from 'openjpeg-1.5.0/applications/codec/image_to_j2k.c' */ typedef struct img_folder { /** The directory path of the folder containing input images*/ char *imgdirpath; /** Output format*/ char *out_format; /** Enable option*/ char set_imgdir; /** Enable Cod Format for output*/ char set_out_format; /** User specified rate stored in case of cinema option*/ float *rates; } img_fol_t; static int check_jp2(unsigned char *mem) /* J2K_CFMT */ { return memcmp(JP2_HEAD, mem, sizeof(JP2_HEAD)) ? 0 : 1; } static int check_j2k(unsigned char *mem) /* J2K_CFMT */ { return memcmp(J2K_HEAD, mem, sizeof(J2K_HEAD)) ? 0 : 1; } int imb_is_a_jp2(unsigned char *buf) { return check_jp2(buf); } /** * sample error callback expecting a FILE* client object */ static void error_callback(const char *msg, void *client_data) { FILE *stream = (FILE *)client_data; fprintf(stream, "[ERROR] %s", msg); } /** * sample warning callback expecting a FILE* client object */ static void warning_callback(const char *msg, void *client_data) { FILE *stream = (FILE *)client_data; fprintf(stream, "[WARNING] %s", msg); } /** * sample debug callback expecting no client object */ static void info_callback(const char *msg, void *client_data) { (void)client_data; fprintf(stdout, "[INFO] %s", msg); } # define PIXEL_LOOPER_BEGIN(_rect) \ for (y = h - 1; y != (unsigned int)(-1); y--) { \ for (i = y * w, i_next = (y + 1) * w; \ i < i_next; \ i++, _rect += 4) \ { \ # define PIXEL_LOOPER_BEGIN_CHANNELS(_rect, _channels) \ for (y = h - 1; y != (unsigned int)(-1); y--) { \ for (i = y * w, i_next = (y + 1) * w; \ i < i_next; \ i++, _rect += _channels) \ { \ # define PIXEL_LOOPER_END \ } \ } (void)0 \ struct ImBuf *imb_jp2_decode(unsigned char *mem, size_t size, int flags, char colorspace[IM_MAX_SPACE]) { struct ImBuf *ibuf = NULL; bool use_float = false; /* for precision higher then 8 use float */ bool use_alpha = false; long signed_offsets[4] = {0, 0, 0, 0}; int float_divs[4] = {1, 1, 1, 1}; unsigned int i, i_next, w, h, planes; unsigned int y; int *r, *g, *b, *a; /* matching 'opj_image_comp.data' type */ int is_jp2, is_j2k; opj_dparameters_t parameters; /* decompression parameters */ opj_event_mgr_t event_mgr; /* event manager */ opj_image_t *image = NULL; opj_dinfo_t *dinfo = NULL; /* handle to a decompressor */ opj_cio_t *cio = NULL; is_jp2 = check_jp2(mem); is_j2k = check_j2k(mem); if (!is_jp2 && !is_j2k) return(NULL); /* both 8, 12 and 16 bit JP2Ks are default to standard byte colorspace */ colorspace_set_default_role(colorspace, IM_MAX_SPACE, COLOR_ROLE_DEFAULT_BYTE); /* configure the event callbacks (not required) */ memset(&event_mgr, 0, sizeof(opj_event_mgr_t)); event_mgr.error_handler = error_callback; event_mgr.warning_handler = warning_callback; event_mgr.info_handler = info_callback; /* set decoding parameters to default values */ opj_set_default_decoder_parameters(¶meters); /* JPEG 2000 compressed image data */ /* get a decoder handle */ dinfo = opj_create_decompress(is_jp2 ? CODEC_JP2 : CODEC_J2K); /* catch events using our callbacks and give a local context */ opj_set_event_mgr((opj_common_ptr)dinfo, &event_mgr, stderr); /* setup the decoder decoding parameters using the current image and user parameters */ opj_setup_decoder(dinfo, ¶meters); /* open a byte stream */ cio = opj_cio_open((opj_common_ptr)dinfo, mem, size); /* decode the stream and fill the image structure */ image = opj_decode(dinfo, cio); if (!image) { fprintf(stderr, "ERROR -> j2k_to_image: failed to decode image!\n"); opj_destroy_decompress(dinfo); opj_cio_close(cio); return NULL; } /* close the byte stream */ opj_cio_close(cio); if ((image->numcomps * image->x1 * image->y1) == 0) { fprintf(stderr, "\nError: invalid raw image parameters\n"); return NULL; } w = image->comps[0].w; h = image->comps[0].h; switch (image->numcomps) { case 1: /* Grayscale */ case 3: /* Color */ planes = 24; use_alpha = false; break; default: /* 2 or 4 - Grayscale or Color + alpha */ planes = 32; /* grayscale + alpha */ use_alpha = true; break; } i = image->numcomps; if (i > 4) i = 4; while (i) { i--; if (image->comps[i].prec > 8) use_float = true; if (image->comps[i].sgnd) signed_offsets[i] = 1 << (image->comps[i].prec - 1); /* only needed for float images but dosnt hurt to calc this */ float_divs[i] = (1 << image->comps[i].prec) - 1; } ibuf = IMB_allocImBuf(w, h, planes, use_float ? IB_rectfloat : IB_rect); if (ibuf == NULL) { if (dinfo) opj_destroy_decompress(dinfo); return NULL; } ibuf->ftype = JP2; if (is_jp2) ibuf->ftype |= JP2_JP2; else ibuf->ftype |= JP2_J2K; if (use_float) { float *rect_float = ibuf->rect_float; if (image->numcomps < 3) { r = image->comps[0].data; a = (use_alpha) ? image->comps[1].data : NULL; /* grayscale 12bits+ */ if (use_alpha) { a = image->comps[1].data; PIXEL_LOOPER_BEGIN(rect_float) { rect_float[0] = rect_float[1] = rect_float[2] = (float)(r[i] + signed_offsets[0]) / float_divs[0]; rect_float[3] = (a[i] + signed_offsets[1]) / float_divs[1]; } PIXEL_LOOPER_END; } else { PIXEL_LOOPER_BEGIN(rect_float) { rect_float[0] = rect_float[1] = rect_float[2] = (float)(r[i] + signed_offsets[0]) / float_divs[0]; rect_float[3] = 1.0f; } PIXEL_LOOPER_END; } } else { r = image->comps[0].data; g = image->comps[1].data; b = image->comps[2].data; /* rgb or rgba 12bits+ */ if (use_alpha) { a = image->comps[3].data; PIXEL_LOOPER_BEGIN(rect_float) { rect_float[0] = (float)(r[i] + signed_offsets[0]) / float_divs[0]; rect_float[1] = (float)(g[i] + signed_offsets[1]) / float_divs[1]; rect_float[2] = (float)(b[i] + signed_offsets[2]) / float_divs[2]; rect_float[3] = (float)(a[i] + signed_offsets[3]) / float_divs[3]; } PIXEL_LOOPER_END; } else { PIXEL_LOOPER_BEGIN(rect_float) { rect_float[0] = (float)(r[i] + signed_offsets[0]) / float_divs[0]; rect_float[1] = (float)(g[i] + signed_offsets[1]) / float_divs[1]; rect_float[2] = (float)(b[i] + signed_offsets[2]) / float_divs[2]; rect_float[3] = 1.0f; } PIXEL_LOOPER_END; } } } else { unsigned char *rect_uchar = (unsigned char *)ibuf->rect; if (image->numcomps < 3) { r = image->comps[0].data; a = (use_alpha) ? image->comps[1].data : NULL; /* grayscale */ if (use_alpha) { a = image->comps[3].data; PIXEL_LOOPER_BEGIN(rect_uchar) { rect_uchar[0] = rect_uchar[1] = rect_uchar[2] = (r[i] + signed_offsets[0]); rect_uchar[3] = a[i] + signed_offsets[1]; } PIXEL_LOOPER_END; } else { PIXEL_LOOPER_BEGIN(rect_uchar) { rect_uchar[0] = rect_uchar[1] = rect_uchar[2] = (r[i] + signed_offsets[0]); rect_uchar[3] = 255; } PIXEL_LOOPER_END; } } else { r = image->comps[0].data; g = image->comps[1].data; b = image->comps[2].data; /* 8bit rgb or rgba */ if (use_alpha) { a = image->comps[3].data; PIXEL_LOOPER_BEGIN(rect_uchar) { rect_uchar[0] = r[i] + signed_offsets[0]; rect_uchar[1] = g[i] + signed_offsets[1]; rect_uchar[2] = b[i] + signed_offsets[2]; rect_uchar[3] = a[i] + signed_offsets[3]; } PIXEL_LOOPER_END; } else { PIXEL_LOOPER_BEGIN(rect_uchar) { rect_uchar[0] = r[i] + signed_offsets[0]; rect_uchar[1] = g[i] + signed_offsets[1]; rect_uchar[2] = b[i] + signed_offsets[2]; rect_uchar[3] = 255; } PIXEL_LOOPER_END; } } } /* free remaining structures */ if (dinfo) { opj_destroy_decompress(dinfo); } /* free image data structure */ opj_image_destroy(image); if (flags & IB_rect) { IMB_rect_from_float(ibuf); } return(ibuf); } //static opj_image_t* rawtoimage(const char *filename, opj_cparameters_t *parameters, raw_cparameters_t *raw_cp) /* prec can be 8, 12, 16 */ /* use inline because the float passed can be a function call that would end up being called many times */ #if 0 #define UPSAMPLE_8_TO_12(_val) ((_val << 4) | (_val & ((1 << 4) - 1))) #define UPSAMPLE_8_TO_16(_val) ((_val << 8) + _val) #define DOWNSAMPLE_FLOAT_TO_8BIT(_val) (_val) <= 0.0f ? 0 : ((_val) >= 1.0f ? 255 : (int)(255.0f * (_val))) #define DOWNSAMPLE_FLOAT_TO_12BIT(_val) (_val) <= 0.0f ? 0 : ((_val) >= 1.0f ? 4095 : (int)(4095.0f * (_val))) #define DOWNSAMPLE_FLOAT_TO_16BIT(_val) (_val) <= 0.0f ? 0 : ((_val) >= 1.0f ? 65535 : (int)(65535.0f * (_val))) #else BLI_INLINE int UPSAMPLE_8_TO_12(const unsigned char _val) { return (_val << 4) | (_val & ((1 << 4) - 1)); } BLI_INLINE int UPSAMPLE_8_TO_16(const unsigned char _val) { return (_val << 8) + _val; } BLI_INLINE int DOWNSAMPLE_FLOAT_TO_8BIT(const float _val) { return (_val) <= 0.0f ? 0 : ((_val) >= 1.0f ? 255 : (int)(255.0f * (_val))); } BLI_INLINE int DOWNSAMPLE_FLOAT_TO_12BIT(const float _val) { return (_val) <= 0.0f ? 0 : ((_val) >= 1.0f ? 4095 : (int)(4095.0f * (_val))); } BLI_INLINE int DOWNSAMPLE_FLOAT_TO_16BIT(const float _val) { return (_val) <= 0.0f ? 0 : ((_val) >= 1.0f ? 65535 : (int)(65535.0f * (_val))); } #endif /* * 2048x1080 (2K) at 24 fps or 48 fps, or 4096x2160 (4K) at 24 fps; 3x12 bits per pixel, XYZ color space * * - In 2K, for Scope (2.39:1) presentation 2048x858 pixels of the image is used * - In 2K, for Flat (1.85:1) presentation 1998x1080 pixels of the image is used */ /* ****************************** COPIED FROM image_to_j2k.c */ /* ----------------------------------------------------------------------- */ #define CINEMA_24_CS 1302083 /*Codestream length for 24fps*/ #define CINEMA_48_CS 651041 /*Codestream length for 48fps*/ #define COMP_24_CS 1041666 /*Maximum size per color component for 2K & 4K @ 24fps*/ #define COMP_48_CS 520833 /*Maximum size per color component for 2K @ 48fps*/ static int initialise_4K_poc(opj_poc_t *POC, int numres) { POC[0].tile = 1; POC[0].resno0 = 0; POC[0].compno0 = 0; POC[0].layno1 = 1; POC[0].resno1 = numres - 1; POC[0].compno1 = 3; POC[0].prg1 = CPRL; POC[1].tile = 1; POC[1].resno0 = numres - 1; POC[1].compno0 = 0; POC[1].layno1 = 1; POC[1].resno1 = numres; POC[1].compno1 = 3; POC[1].prg1 = CPRL; return 2; } static void cinema_parameters(opj_cparameters_t *parameters) { parameters->tile_size_on = 0; /* false */ parameters->cp_tdx = 1; parameters->cp_tdy = 1; /*Tile part*/ parameters->tp_flag = 'C'; parameters->tp_on = 1; /*Tile and Image shall be at (0, 0)*/ parameters->cp_tx0 = 0; parameters->cp_ty0 = 0; parameters->image_offset_x0 = 0; parameters->image_offset_y0 = 0; /*Codeblock size = 32 * 32*/ parameters->cblockw_init = 32; parameters->cblockh_init = 32; parameters->csty |= 0x01; /*The progression order shall be CPRL*/ parameters->prog_order = CPRL; /* No ROI */ parameters->roi_compno = -1; parameters->subsampling_dx = 1; parameters->subsampling_dy = 1; /* 9-7 transform */ parameters->irreversible = 1; } static void cinema_setup_encoder(opj_cparameters_t *parameters, opj_image_t *image, img_fol_t *img_fol) { int i; float temp_rate; switch (parameters->cp_cinema) { case CINEMA2K_24: case CINEMA2K_48: if (parameters->numresolution > 6) { parameters->numresolution = 6; } if (!((image->comps[0].w == 2048) || (image->comps[0].h == 1080))) { fprintf(stdout, "Image coordinates %d x %d is not 2K compliant.\nJPEG Digital Cinema Profile-3 " "(2K profile) compliance requires that at least one of coordinates match 2048 x 1080\n", image->comps[0].w, image->comps[0].h); parameters->cp_rsiz = STD_RSIZ; } break; case CINEMA4K_24: if (parameters->numresolution < 1) { parameters->numresolution = 1; } else if (parameters->numresolution > 7) { parameters->numresolution = 7; } if (!((image->comps[0].w == 4096) || (image->comps[0].h == 2160))) { fprintf(stdout, "Image coordinates %d x %d is not 4K compliant.\nJPEG Digital Cinema Profile-4" "(4K profile) compliance requires that at least one of coordinates match 4096 x 2160\n", image->comps[0].w, image->comps[0].h); parameters->cp_rsiz = STD_RSIZ; } parameters->numpocs = initialise_4K_poc(parameters->POC, parameters->numresolution); break; case OFF: /* do nothing */ break; } switch (parameters->cp_cinema) { case CINEMA2K_24: case CINEMA4K_24: for (i = 0; i < parameters->tcp_numlayers; i++) { temp_rate = 0; if (img_fol->rates[i] == 0) { parameters->tcp_rates[0] = ((float) (image->numcomps * image->comps[0].w * image->comps[0].h * image->comps[0].prec)) / (CINEMA_24_CS * 8 * image->comps[0].dx * image->comps[0].dy); } else { temp_rate = ((float) (image->numcomps * image->comps[0].w * image->comps[0].h * image->comps[0].prec)) / (img_fol->rates[i] * 8 * image->comps[0].dx * image->comps[0].dy); if (temp_rate > CINEMA_24_CS) { parameters->tcp_rates[i] = ((float) (image->numcomps * image->comps[0].w * image->comps[0].h * image->comps[0].prec)) / (CINEMA_24_CS * 8 * image->comps[0].dx * image->comps[0].dy); } else { parameters->tcp_rates[i] = img_fol->rates[i]; } } } parameters->max_comp_size = COMP_24_CS; break; case CINEMA2K_48: for (i = 0; i < parameters->tcp_numlayers; i++) { temp_rate = 0; if (img_fol->rates[i] == 0) { parameters->tcp_rates[0] = ((float) (image->numcomps * image->comps[0].w * image->comps[0].h * image->comps[0].prec)) / (CINEMA_48_CS * 8 * image->comps[0].dx * image->comps[0].dy); } else { temp_rate = ((float) (image->numcomps * image->comps[0].w * image->comps[0].h * image->comps[0].prec)) / (img_fol->rates[i] * 8 * image->comps[0].dx * image->comps[0].dy); if (temp_rate > CINEMA_48_CS) { parameters->tcp_rates[0] = ((float) (image->numcomps * image->comps[0].w * image->comps[0].h * image->comps[0].prec)) / (CINEMA_48_CS * 8 * image->comps[0].dx * image->comps[0].dy); } else { parameters->tcp_rates[i] = img_fol->rates[i]; } } } parameters->max_comp_size = COMP_48_CS; break; case OFF: /* do nothing */ break; } parameters->cp_disto_alloc = 1; } static float channel_colormanage_noop(float value) { return value; } static opj_image_t *ibuftoimage(ImBuf *ibuf, opj_cparameters_t *parameters) { unsigned char *rect_uchar; float *rect_float, from_straight[4]; unsigned int subsampling_dx = parameters->subsampling_dx; unsigned int subsampling_dy = parameters->subsampling_dy; unsigned int i, i_next, numcomps, w, h, prec; unsigned int y; int *r, *g, *b, *a; /* matching 'opj_image_comp.data' type */ OPJ_COLOR_SPACE color_space; opj_image_cmptparm_t cmptparm[4]; /* maximum of 4 components */ opj_image_t *image = NULL; float (*chanel_colormanage_cb)(float); img_fol_t img_fol; /* only needed for cinema presets */ memset(&img_fol, 0, sizeof(img_fol_t)); if (ibuf->float_colorspace) { /* float buffer was managed already, no need in color space conversion */ chanel_colormanage_cb = channel_colormanage_noop; } else { /* standard linear-to-srgb conversion if float buffer wasn't managed */ chanel_colormanage_cb = linearrgb_to_srgb; } if (ibuf->ftype & JP2_CINE) { if (ibuf->x == 4096 || ibuf->y == 2160) parameters->cp_cinema = CINEMA4K_24; else { if (ibuf->ftype & JP2_CINE_48FPS) { parameters->cp_cinema = CINEMA2K_48; } else { parameters->cp_cinema = CINEMA2K_24; } } if (parameters->cp_cinema) { img_fol.rates = (float *)MEM_mallocN(parameters->tcp_numlayers * sizeof(float), "jp2_rates"); for (i = 0; i < parameters->tcp_numlayers; i++) { img_fol.rates[i] = parameters->tcp_rates[i]; } cinema_parameters(parameters); } color_space = CLRSPC_SYCC; prec = 12; numcomps = 3; } else { /* Get settings from the imbuf */ color_space = (ibuf->ftype & JP2_YCC) ? CLRSPC_SYCC : CLRSPC_SRGB; if (ibuf->ftype & JP2_16BIT) prec = 16; else if (ibuf->ftype & JP2_12BIT) prec = 12; else prec = 8; /* 32bit images == alpha channel */ /* grayscale not supported yet */ numcomps = (ibuf->planes == 32) ? 4 : 3; } w = ibuf->x; h = ibuf->y; /* initialize image components */ memset(&cmptparm, 0, 4 * sizeof(opj_image_cmptparm_t)); for (i = 0; i < numcomps; i++) { cmptparm[i].prec = prec; cmptparm[i].bpp = prec; cmptparm[i].sgnd = 0; cmptparm[i].dx = subsampling_dx; cmptparm[i].dy = subsampling_dy; cmptparm[i].w = w; cmptparm[i].h = h; } /* create the image */ image = opj_image_create(numcomps, &cmptparm[0], color_space); if (!image) { printf("Error: opj_image_create() failed\n"); return NULL; } /* set image offset and reference grid */ image->x0 = parameters->image_offset_x0; image->y0 = parameters->image_offset_y0; image->x1 = image->x0 + (w - 1) * subsampling_dx + 1 + image->x0; image->y1 = image->y0 + (h - 1) * subsampling_dy + 1 + image->y0; /* set image data */ rect_uchar = (unsigned char *) ibuf->rect; rect_float = ibuf->rect_float; /* set the destination channels */ r = image->comps[0].data; g = image->comps[1].data; b = image->comps[2].data; a = (numcomps == 4) ? image->comps[3].data : NULL; if (rect_float && rect_uchar && prec == 8) { /* No need to use the floating point buffer, just write the 8 bits from the char buffer */ rect_float = NULL; } if (rect_float) { int channels_in_float = ibuf->channels ? ibuf->channels : 4; switch (prec) { case 8: /* Convert blenders float color channels to 8, 12 or 16bit ints */ if (numcomps == 4) { if (channels_in_float == 4) { PIXEL_LOOPER_BEGIN(rect_float) { premul_to_straight_v4_v4(from_straight, rect_float); r[i] = DOWNSAMPLE_FLOAT_TO_8BIT(chanel_colormanage_cb(from_straight[0])); g[i] = DOWNSAMPLE_FLOAT_TO_8BIT(chanel_colormanage_cb(from_straight[1])); b[i] = DOWNSAMPLE_FLOAT_TO_8BIT(chanel_colormanage_cb(from_straight[2])); a[i] = DOWNSAMPLE_FLOAT_TO_8BIT(from_straight[3]); } PIXEL_LOOPER_END; } else if (channels_in_float == 3) { PIXEL_LOOPER_BEGIN_CHANNELS(rect_float, 3) { r[i] = DOWNSAMPLE_FLOAT_TO_8BIT(chanel_colormanage_cb(rect_float[0])); g[i] = DOWNSAMPLE_FLOAT_TO_8BIT(chanel_colormanage_cb(rect_float[1])); b[i] = DOWNSAMPLE_FLOAT_TO_8BIT(chanel_colormanage_cb(rect_float[2])); a[i] = 255; } PIXEL_LOOPER_END; } else { PIXEL_LOOPER_BEGIN_CHANNELS(rect_float, 1) { r[i] = DOWNSAMPLE_FLOAT_TO_8BIT(chanel_colormanage_cb(rect_float[0])); g[i] = b[i] = r[i]; a[i] = 255; } PIXEL_LOOPER_END; } } else { if (channels_in_float == 4) { PIXEL_LOOPER_BEGIN(rect_float) { premul_to_straight_v4_v4(from_straight, rect_float); r[i] = DOWNSAMPLE_FLOAT_TO_8BIT(chanel_colormanage_cb(from_straight[0])); g[i] = DOWNSAMPLE_FLOAT_TO_8BIT(chanel_colormanage_cb(from_straight[1])); b[i] = DOWNSAMPLE_FLOAT_TO_8BIT(chanel_colormanage_cb(from_straight[2])); } PIXEL_LOOPER_END; } else if (channels_in_float == 3) { PIXEL_LOOPER_BEGIN_CHANNELS(rect_float, 3) { r[i] = DOWNSAMPLE_FLOAT_TO_8BIT(chanel_colormanage_cb(rect_float[0])); g[i] = DOWNSAMPLE_FLOAT_TO_8BIT(chanel_colormanage_cb(rect_float[1])); b[i] = DOWNSAMPLE_FLOAT_TO_8BIT(chanel_colormanage_cb(rect_float[2])); } PIXEL_LOOPER_END; } else { PIXEL_LOOPER_BEGIN_CHANNELS(rect_float, 1) { r[i] = DOWNSAMPLE_FLOAT_TO_8BIT(chanel_colormanage_cb(rect_float[0])); g[i] = b[i] = r[i]; } PIXEL_LOOPER_END; } } break; case 12: if (numcomps == 4) { if (channels_in_float == 4) { PIXEL_LOOPER_BEGIN(rect_float) { premul_to_straight_v4_v4(from_straight, rect_float); r[i] = DOWNSAMPLE_FLOAT_TO_12BIT(chanel_colormanage_cb(from_straight[0])); g[i] = DOWNSAMPLE_FLOAT_TO_12BIT(chanel_colormanage_cb(from_straight[1])); b[i] = DOWNSAMPLE_FLOAT_TO_12BIT(chanel_colormanage_cb(from_straight[2])); a[i] = DOWNSAMPLE_FLOAT_TO_12BIT(from_straight[3]); } PIXEL_LOOPER_END; } else if (channels_in_float == 3) { PIXEL_LOOPER_BEGIN_CHANNELS(rect_float, 3) { r[i] = DOWNSAMPLE_FLOAT_TO_12BIT(chanel_colormanage_cb(rect_float[0])); g[i] = DOWNSAMPLE_FLOAT_TO_12BIT(chanel_colormanage_cb(rect_float[1])); b[i] = DOWNSAMPLE_FLOAT_TO_12BIT(chanel_colormanage_cb(rect_float[2])); a[i] = 4095; } PIXEL_LOOPER_END; } else { PIXEL_LOOPER_BEGIN_CHANNELS(rect_float, 1) { r[i] = DOWNSAMPLE_FLOAT_TO_12BIT(chanel_colormanage_cb(rect_float[0])); g[i] = b[i] = r[i]; a[i] = 4095; } PIXEL_LOOPER_END; } } else { if (channels_in_float == 4) { PIXEL_LOOPER_BEGIN(rect_float) { premul_to_straight_v4_v4(from_straight, rect_float); r[i] = DOWNSAMPLE_FLOAT_TO_12BIT(chanel_colormanage_cb(from_straight[0])); g[i] = DOWNSAMPLE_FLOAT_TO_12BIT(chanel_colormanage_cb(from_straight[1])); b[i] = DOWNSAMPLE_FLOAT_TO_12BIT(chanel_colormanage_cb(from_straight[2])); } PIXEL_LOOPER_END; } else if (channels_in_float == 3) { PIXEL_LOOPER_BEGIN_CHANNELS(rect_float, 3) { r[i] = DOWNSAMPLE_FLOAT_TO_12BIT(chanel_colormanage_cb(rect_float[0])); g[i] = DOWNSAMPLE_FLOAT_TO_12BIT(chanel_colormanage_cb(rect_float[1])); b[i] = DOWNSAMPLE_FLOAT_TO_12BIT(chanel_colormanage_cb(rect_float[2])); } PIXEL_LOOPER_END; } else { PIXEL_LOOPER_BEGIN_CHANNELS(rect_float, 1) { r[i] = DOWNSAMPLE_FLOAT_TO_12BIT(chanel_colormanage_cb(rect_float[0])); g[i] = b[i] = r[i]; } PIXEL_LOOPER_END; } } break; case 16: if (numcomps == 4) { if (channels_in_float == 4) { PIXEL_LOOPER_BEGIN(rect_float) { premul_to_straight_v4_v4(from_straight, rect_float); r[i] = DOWNSAMPLE_FLOAT_TO_16BIT(chanel_colormanage_cb(from_straight[0])); g[i] = DOWNSAMPLE_FLOAT_TO_16BIT(chanel_colormanage_cb(from_straight[1])); b[i] = DOWNSAMPLE_FLOAT_TO_16BIT(chanel_colormanage_cb(from_straight[2])); a[i] = DOWNSAMPLE_FLOAT_TO_16BIT(from_straight[3]); } PIXEL_LOOPER_END; } else if (channels_in_float == 3) { PIXEL_LOOPER_BEGIN_CHANNELS(rect_float, 3) { r[i] = DOWNSAMPLE_FLOAT_TO_16BIT(chanel_colormanage_cb(rect_float[0])); g[i] = DOWNSAMPLE_FLOAT_TO_16BIT(chanel_colormanage_cb(rect_float[1])); b[i] = DOWNSAMPLE_FLOAT_TO_16BIT(chanel_colormanage_cb(rect_float[2])); a[i] = 65535; } PIXEL_LOOPER_END; } else { PIXEL_LOOPER_BEGIN_CHANNELS(rect_float, 1) { r[i] = DOWNSAMPLE_FLOAT_TO_16BIT(chanel_colormanage_cb(rect_float[0])); g[i] = b[i] = r[i]; a[i] = 65535; } PIXEL_LOOPER_END; } } else { if (channels_in_float == 4) { PIXEL_LOOPER_BEGIN(rect_float) { premul_to_straight_v4_v4(from_straight, rect_float); r[i] = DOWNSAMPLE_FLOAT_TO_16BIT(chanel_colormanage_cb(from_straight[0])); g[i] = DOWNSAMPLE_FLOAT_TO_16BIT(chanel_colormanage_cb(from_straight[1])); b[i] = DOWNSAMPLE_FLOAT_TO_16BIT(chanel_colormanage_cb(from_straight[2])); } PIXEL_LOOPER_END; } else if (channels_in_float == 3) { PIXEL_LOOPER_BEGIN_CHANNELS(rect_float, 3) { r[i] = DOWNSAMPLE_FLOAT_TO_16BIT(chanel_colormanage_cb(rect_float[0])); g[i] = DOWNSAMPLE_FLOAT_TO_16BIT(chanel_colormanage_cb(rect_float[1])); b[i] = DOWNSAMPLE_FLOAT_TO_16BIT(chanel_colormanage_cb(rect_float[2])); } PIXEL_LOOPER_END; } else { PIXEL_LOOPER_BEGIN_CHANNELS(rect_float, 1) { r[i] = DOWNSAMPLE_FLOAT_TO_16BIT(chanel_colormanage_cb(rect_float[0])); g[i] = b[i] = r[i]; } PIXEL_LOOPER_END; } } break; } } else { /* just use rect*/ switch (prec) { case 8: if (numcomps == 4) { PIXEL_LOOPER_BEGIN(rect_uchar) { r[i] = rect_uchar[0]; g[i] = rect_uchar[1]; b[i] = rect_uchar[2]; a[i] = rect_uchar[3]; } PIXEL_LOOPER_END; } else { PIXEL_LOOPER_BEGIN(rect_uchar) { r[i] = rect_uchar[0]; g[i] = rect_uchar[1]; b[i] = rect_uchar[2]; } PIXEL_LOOPER_END; } break; case 12: /* Up Sampling, a bit pointless but best write the bit depth requested */ if (numcomps == 4) { PIXEL_LOOPER_BEGIN(rect_uchar) { r[i] = UPSAMPLE_8_TO_12(rect_uchar[0]); g[i] = UPSAMPLE_8_TO_12(rect_uchar[1]); b[i] = UPSAMPLE_8_TO_12(rect_uchar[2]); a[i] = UPSAMPLE_8_TO_12(rect_uchar[3]); } PIXEL_LOOPER_END; } else { PIXEL_LOOPER_BEGIN(rect_uchar) { r[i] = UPSAMPLE_8_TO_12(rect_uchar[0]); g[i] = UPSAMPLE_8_TO_12(rect_uchar[1]); b[i] = UPSAMPLE_8_TO_12(rect_uchar[2]); } PIXEL_LOOPER_END; } break; case 16: if (numcomps == 4) { PIXEL_LOOPER_BEGIN(rect_uchar) { r[i] = UPSAMPLE_8_TO_16(rect_uchar[0]); g[i] = UPSAMPLE_8_TO_16(rect_uchar[1]); b[i] = UPSAMPLE_8_TO_16(rect_uchar[2]); a[i] = UPSAMPLE_8_TO_16(rect_uchar[3]); } PIXEL_LOOPER_END; } else { PIXEL_LOOPER_BEGIN(rect_uchar) { r[i] = UPSAMPLE_8_TO_16(rect_uchar[0]); g[i] = UPSAMPLE_8_TO_16(rect_uchar[1]); b[i] = UPSAMPLE_8_TO_16(rect_uchar[2]); } PIXEL_LOOPER_END; } break; } } /* Decide if MCT should be used */ parameters->tcp_mct = image->numcomps == 3 ? 1 : 0; if (parameters->cp_cinema) { cinema_setup_encoder(parameters, image, &img_fol); } if (img_fol.rates) MEM_freeN(img_fol.rates); return image; } /* Found write info at http://users.ece.gatech.edu/~slabaugh/personal/c/bitmapUnix.c */ int imb_savejp2(struct ImBuf *ibuf, const char *name, int flags) { int quality = ibuf->ftype & 0xff; int bSuccess; opj_cparameters_t parameters; /* compression parameters */ opj_event_mgr_t event_mgr; /* event manager */ opj_image_t *image = NULL; (void)flags; /* unused */ /* * configure the event callbacks (not required) * setting of each callback is optional */ memset(&event_mgr, 0, sizeof(opj_event_mgr_t)); event_mgr.error_handler = error_callback; event_mgr.warning_handler = warning_callback; event_mgr.info_handler = info_callback; /* set encoding parameters to default values */ opj_set_default_encoder_parameters(¶meters); /* compression ratio */ /* invert range, from 10-100, 100-1 * where jpeg see's 1 and highest quality (lossless) and 100 is very low quality*/ parameters.tcp_rates[0] = ((100 - quality) / 90.0f * 99.0f) + 1; parameters.tcp_numlayers = 1; /* only one resolution */ parameters.cp_disto_alloc = 1; image = ibuftoimage(ibuf, ¶meters); { /* JP2 format output */ int codestream_length; opj_cio_t *cio = NULL; FILE *f = NULL; opj_cinfo_t *cinfo = NULL; /* get a JP2 compressor handle */ if (ibuf->ftype & JP2_JP2) cinfo = opj_create_compress(CODEC_JP2); else if (ibuf->ftype & JP2_J2K) cinfo = opj_create_compress(CODEC_J2K); else BLI_assert(!"Unsupported codec was specified in save settings"); /* catch events using our callbacks and give a local context */ opj_set_event_mgr((opj_common_ptr)cinfo, &event_mgr, stderr); /* setup the encoder parameters using the current image and using user parameters */ opj_setup_encoder(cinfo, ¶meters, image); /* open a byte stream for writing */ /* allocate memory for all tiles */ cio = opj_cio_open((opj_common_ptr)cinfo, NULL, 0); /* encode the image */ bSuccess = opj_encode(cinfo, cio, image, NULL); /* last arg used to be parameters.index but this deprecated */ if (!bSuccess) { opj_cio_close(cio); fprintf(stderr, "failed to encode image\n"); return 0; } codestream_length = cio_tell(cio); /* write the buffer to disk */ f = BLI_fopen(name, "wb"); if (!f) { fprintf(stderr, "failed to open %s for writing\n", name); return 1; } fwrite(cio->buffer, 1, codestream_length, f); fclose(f); fprintf(stderr, "Generated outfile %s\n", name); /* close and free the byte stream */ opj_cio_close(cio); /* free remaining compression structures */ opj_destroy_compress(cinfo); } /* free image data */ opj_image_destroy(image); return 1; }