/* Copyright (C) 2012 Carl Hetherington 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., 675 Mass Ave, Cambridge, MA 02139, USA. */ /** @file src/util.cc * @brief Utility methods. */ #include #include #include #include #include #include #include "KM_util.h" #include "KM_fileio.h" #include "AS_DCP.h" #include "util.h" #include "exceptions.h" #include "types.h" #include "argb_frame.h" #include "lut.h" using std::string; using std::stringstream; using std::min; using std::max; using boost::shared_ptr; using namespace libdcp; string libdcp::make_uuid () { char buffer[64]; Kumu::UUID id; Kumu::GenRandomValue (id); id.EncodeHex (buffer, 64); return string (buffer); } string libdcp::make_digest (string filename, boost::signals2::signal* progress) { int const file_size = boost::filesystem::file_size (filename); Kumu::FileReader reader; if (ASDCP_FAILURE (reader.OpenRead (filename.c_str ()))) { throw FileError ("could not open file to compute digest", filename); } SHA_CTX sha; SHA1_Init (&sha); Kumu::ByteString read_buffer (65536); int done = 0; while (1) { ui32_t read = 0; Kumu::Result_t r = reader.Read (read_buffer.Data(), read_buffer.Capacity(), &read); if (r == Kumu::RESULT_ENDOFFILE) { break; } else if (ASDCP_FAILURE (r)) { throw FileError ("could not read file to compute digest", filename); } SHA1_Update (&sha, read_buffer.Data(), read); done += read; if (progress) { (*progress) (0.5 + (0.5 * done / file_size)); } } byte_t byte_buffer[20]; SHA1_Final (byte_buffer, &sha); stringstream s; char digest[64]; return Kumu::base64encode (byte_buffer, 20, digest, 64); } string libdcp::content_kind_to_string (ContentKind kind) { switch (kind) { case FEATURE: return "feature"; case SHORT: return "short"; case TRAILER: return "trailer"; case TEST: return "test"; case TRANSITIONAL: return "transitional"; case RATING: return "rating"; case TEASER: return "teaser"; case POLICY: return "policy"; case PUBLIC_SERVICE_ANNOUNCEMENT: return "psa"; case ADVERTISEMENT: return "advertisement"; } assert (false); } libdcp::ContentKind libdcp::content_kind_from_string (string type) { if (type == "feature") { return FEATURE; } else if (type == "short") { return SHORT; } else if (type == "trailer" || type == "Trailer") { return TRAILER; } else if (type == "test") { return TEST; } else if (type == "transitional") { return TRANSITIONAL; } else if (type == "rating") { return RATING; } else if (type == "teaser" || type == "Teaser") { return TEASER; } else if (type == "policy") { return POLICY; } else if (type == "psa") { return PUBLIC_SERVICE_ANNOUNCEMENT; } else if (type == "advertisement") { return ADVERTISEMENT; } assert (false); } bool libdcp::starts_with (string big, string little) { if (little.size() > big.size()) { return false; } return big.substr (0, little.length()) == little; } bool libdcp::ends_with (string big, string little) { if (little.size() > big.size()) { return false; } return big.compare (big.length() - little.length(), little.length(), little) == 0; } opj_image_t * libdcp::decompress_j2k (uint8_t* data, int64_t size, int reduce) { opj_dinfo_t* decoder = opj_create_decompress (CODEC_J2K); opj_dparameters_t parameters; opj_set_default_decoder_parameters (¶meters); parameters.cp_reduce = reduce; opj_setup_decoder (decoder, ¶meters); opj_cio_t* cio = opj_cio_open ((opj_common_ptr) decoder, data, size); opj_image_t* image = opj_decode (decoder, cio); if (!image) { opj_destroy_decompress (decoder); opj_cio_close (cio); throw DCPReadError ("could not decode JPEG2000 codestream"); } opj_cio_close (cio); image->x1 = rint (float(image->x1) / pow (2, reduce)); image->y1 = rint (float(image->y1) / pow (2, reduce)); return image; } shared_ptr libdcp::xyz_to_rgb (opj_image_t* xyz_frame) { struct { double x, y, z; } s; struct { double r, g, b; } d; int* xyz_x = xyz_frame->comps[0].data; int* xyz_y = xyz_frame->comps[1].data; int* xyz_z = xyz_frame->comps[2].data; shared_ptr argb_frame (new ARGBFrame (xyz_frame->x1, xyz_frame->y1)); uint8_t* argb = argb_frame->data (); for (int y = 0; y < xyz_frame->y1; ++y) { uint8_t* argb_line = argb; for (int x = 0; x < xyz_frame->x1; ++x) { assert (*xyz_x >= 0 && *xyz_y >= 0 && *xyz_z >= 0 && *xyz_x < 4096 && *xyz_x < 4096 && *xyz_z < 4096); /* In gamma LUT */ s.x = lut_in[*xyz_x++]; s.y = lut_in[*xyz_y++]; s.z = lut_in[*xyz_z++]; /* DCI companding */ s.x /= DCI_COEFFICIENT; s.y /= DCI_COEFFICIENT; s.z /= DCI_COEFFICIENT; /* XYZ to RGB */ d.r = ((s.x * color_matrix[0][0]) + (s.y * color_matrix[0][1]) + (s.z * color_matrix[0][2])); d.g = ((s.x * color_matrix[1][0]) + (s.y * color_matrix[1][1]) + (s.z * color_matrix[1][2])); d.b = ((s.x * color_matrix[2][0]) + (s.y * color_matrix[2][1]) + (s.z * color_matrix[2][2])); d.r = min (d.r, 1.0); d.r = max (d.r, 0.0); d.g = min (d.g, 1.0); d.g = max (d.g, 0.0); d.b = min (d.b, 1.0); d.b = max (d.b, 0.0); /* Out gamma LUT */ *argb_line++ = lut_out[(int) (d.b * COLOR_DEPTH)]; *argb_line++ = lut_out[(int) (d.g * COLOR_DEPTH)]; *argb_line++ = lut_out[(int) (d.r * COLOR_DEPTH)]; *argb_line++ = 0xff; } argb += argb_frame->stride (); } return argb_frame; } bool libdcp::empty_or_white_space (string s) { for (size_t i = 0; i < s.length(); ++i) { if (s[i] != ' ' && s[i] != '\n' && s[i] != '\t') { return false; } } return true; }