/*---------------------------------------------------------------------- | main +---------------------------------------------------------------------*/ int main(int argc, char** argv) { if (argc == 1) PrintUsageAndExit(); // parse options const char* kms_uri = NULL; enum Method method = METHOD_NONE; const char* input_filename = NULL; const char* output_filename = NULL; AP4_ProtectionKeyMap key_map; AP4_TrackPropertyMap property_map; bool show_progress = false; // parse the command line arguments char* arg; while ((arg = *++argv)) { if (!strcmp(arg, "--method")) { arg = *++argv; if (!strcmp(arg, "OMA-PDCF-CBC")) { method = METHOD_OMA_PDCF_CBC; } else if (!strcmp(arg, "OMA-PDCF-CTR")) { method = METHOD_OMA_PDCF_CTR; } else if (!strcmp(arg, "MARLIN-IPMP")) { method = METHOD_MARLIN_IPMP; } else if (!strcmp(arg, "ISMA-IAEC")) { method = METHOD_ISMA_AES; } else { fprintf(stderr, "ERROR: invalid value for --method argument\n"); return 1; } } else if (!strcmp(arg, "--kms-uri")) { if (method != METHOD_ISMA_AES) { fprintf(stderr, "ERROR: --kms-uri only applies to method ISMA-IAEC\n"); return 1; } kms_uri = *++argv; } else if (!strcmp(arg, "--show-progress")) { show_progress = true; } else if (!strcmp(arg, "--key")) { if (method == METHOD_NONE) { fprintf(stderr, "ERROR: --method argument must appear before --key\n"); return 1; } arg = *++argv; if (arg == NULL) { fprintf(stderr, "ERROR: missing argument for --key option\n"); return 1; } char* track_ascii = NULL; char* key_ascii = NULL; char* iv_ascii = NULL; if (AP4_FAILED(AP4_SplitArgs(arg, track_ascii, key_ascii, iv_ascii))) { fprintf(stderr, "ERROR: invalid argument for --key option\n"); return 1; } unsigned char key[16]; unsigned char iv[16]; unsigned int track = strtoul(track_ascii, NULL, 10); AP4_SetMemory(key, 0, sizeof(key)); AP4_SetMemory(iv, 0, sizeof(iv)); if (AP4_ParseHex(key_ascii, key, 16)) { fprintf(stderr, "ERROR: invalid hex format for key\n"); } if (AP4_ParseHex(iv_ascii, iv, 8)) { fprintf(stderr, "ERROR: invalid hex format for iv\n"); return 1; } // check that the key is not already there if (key_map.GetKey(track)) { fprintf(stderr, "ERROR: key already set for track %d\n", track); return 1; } // set the key in the map key_map.SetKey(track, key, iv); } else if (!strcmp(arg, "--property")) { char* track_ascii = NULL; char* name = NULL; char* value = NULL; if (method != METHOD_OMA_PDCF_CBC && method != METHOD_OMA_PDCF_CTR && method != METHOD_MARLIN_IPMP) { fprintf(stderr, "ERROR: this method does not use properties\n"); return 1; } arg = *++argv; if (arg == NULL) { fprintf(stderr, "ERROR: missing argument for --property option\n"); return 1; } if (AP4_FAILED(AP4_SplitArgs(arg, track_ascii, name, value))) { fprintf(stderr, "ERROR: invalid argument for --property option\n"); return 1; } unsigned int track = strtoul(track_ascii, NULL, 10); // check that the property is not already set if (property_map.GetProperty(track, name)) { fprintf(stderr, "ERROR: property %s already set for track %d\n", name, track); return 1; } // set the property in the map property_map.SetProperty(track, name, value); } else if (input_filename == NULL) { input_filename = arg; } else if (output_filename == NULL) { output_filename = arg; } else { fprintf(stderr, "ERROR: unexpected argument (%s)\n", arg); return 1; } } // check the arguments if (method == METHOD_NONE) { fprintf(stderr, "ERROR: missing --method argument\n"); return 1; } if (input_filename == NULL) { fprintf(stderr, "ERROR: missing input filename\n"); return 1; } if (output_filename == NULL) { fprintf(stderr, "ERROR: missing output filename\n"); return 1; } // create an encrypting processor AP4_Processor* processor; if (method == METHOD_ISMA_AES) { if (kms_uri == NULL) { fprintf(stderr, "ERROR: method ISMA-IAEC requires --kms-uri\n"); return 1; } AP4_IsmaEncryptingProcessor* isma_processor = new AP4_IsmaEncryptingProcessor(kms_uri); isma_processor->GetKeyMap().SetKeys(key_map); processor = isma_processor; } else if (method == METHOD_MARLIN_IPMP) { AP4_MarlinIpmpEncryptingProcessor* marlin_processor = new AP4_MarlinIpmpEncryptingProcessor(); marlin_processor->GetKeyMap().SetKeys(key_map); marlin_processor->GetPropertyMap().SetProperties(property_map); processor = marlin_processor; } else { AP4_OmaDcfEncryptingProcessor* oma_processor = new AP4_OmaDcfEncryptingProcessor(method == METHOD_OMA_PDCF_CTR? AP4_OMA_DCF_CIPHER_MODE_CTR : AP4_OMA_DCF_CIPHER_MODE_CBC); oma_processor->GetKeyMap().SetKeys(key_map); oma_processor->GetPropertyMap().SetProperties(property_map); processor = oma_processor; } // create the input stream AP4_ByteStream* input; try{ input = new AP4_FileByteStream(input_filename, AP4_FileByteStream::STREAM_MODE_READ); } catch (AP4_Exception) { fprintf(stderr, "ERROR: cannot open input file (%s)\n", input_filename); return 1; } // create the output stream AP4_ByteStream* output; try { output = new AP4_FileByteStream(output_filename, AP4_FileByteStream::STREAM_MODE_WRITE); } catch (AP4_Exception) { fprintf(stderr, "ERROR: cannot open output file (%s)\n", output_filename); return 1; } // process/decrypt the file ProgressListener listener; AP4_Result result = processor->Process(*input, *output, show_progress?&listener:NULL); if (AP4_FAILED(result)) { fprintf(stderr, "ERROR: failed to process the file (%d)\n", result); } // cleanup delete processor; input->Release(); output->Release(); return 0; }
/*---------------------------------------------------------------------- | main +---------------------------------------------------------------------*/ int main(int argc, char** argv) { if (argc == 1) PrintUsageAndExit(); // parse options AP4_UI08 encryption_method = 0; bool encryption_method_is_set = false; AP4_UI08 padding_scheme = 0; const char* input_filename = NULL; const char* output_filename = NULL; bool show_progress = false; bool key_is_set = false; unsigned char key[16]; unsigned char iv[16]; AP4_BlockCipher::CipherMode cipher_mode = AP4_BlockCipher::CBC; const char* content_type = ""; const char* content_id = ""; const char* rights_issuer_url = ""; AP4_LargeSize plaintext_length = 0; AP4_DataBuffer textual_headers_buffer; AP4_TrackPropertyMap textual_headers; AP4_SetMemory(key, 0, sizeof(key)); AP4_SetMemory(iv, 0, sizeof(iv)); // parse the command line arguments char* arg; while ((arg = *++argv)) { if (!strcmp(arg, "--method")) { arg = *++argv; if (!strcmp(arg, "CBC")) { encryption_method = AP4_OMA_DCF_ENCRYPTION_METHOD_AES_CBC; encryption_method_is_set = true; padding_scheme = AP4_OMA_DCF_PADDING_SCHEME_RFC_2630; cipher_mode = AP4_BlockCipher::CBC; } else if (!strcmp(arg, "CTR")) { encryption_method = AP4_OMA_DCF_ENCRYPTION_METHOD_AES_CTR; encryption_method_is_set = true; padding_scheme = AP4_OMA_DCF_PADDING_SCHEME_NONE; cipher_mode = AP4_BlockCipher::CTR; } else if (!strcmp(arg, "NULL")) { encryption_method = AP4_OMA_DCF_ENCRYPTION_METHOD_NULL; encryption_method_is_set = true; padding_scheme = AP4_OMA_DCF_PADDING_SCHEME_NONE; } else { fprintf(stderr, "ERROR: invalid value for --method argument\n"); return 1; } } else if (!strcmp(arg, "--show-progress")) { show_progress = true; } else if (!strcmp(arg, "--content-type")) { content_type = *++argv; if (content_type == NULL) { fprintf(stderr, "ERROR: missing argument for --content-type option\n"); return 1; } } else if (!strcmp(arg, "--content-id")) { content_id = *++argv; if (content_type == NULL) { fprintf(stderr, "ERROR: missing argument for --content-id option\n"); return 1; } } else if (!strcmp(arg, "--rights-issuer")) { rights_issuer_url = *++argv; if (rights_issuer_url == NULL) { fprintf(stderr, "ERROR: missing argument for --rights-issuer option\n"); return 1; } } else if (!strcmp(arg, "--key")) { if (!encryption_method_is_set) { fprintf(stderr, "ERROR: --method argument must appear before --key\n"); return 1; } else if (encryption_method_is_set == AP4_OMA_DCF_ENCRYPTION_METHOD_NULL) { fprintf(stderr, "ERROR: --key cannot be used with --method NULL\n"); return 1; } arg = *++argv; if (arg == NULL) { fprintf(stderr, "ERROR: missing argument for --key option\n"); return 1; } char* key_ascii = NULL; char* iv_ascii = NULL; if (AP4_FAILED(AP4_SplitArgs(arg, key_ascii, iv_ascii))) { fprintf(stderr, "ERROR: invalid argument for --key option\n"); return 1; } if (AP4_ParseHex(key_ascii, key, 16)) { fprintf(stderr, "ERROR: invalid hex format for key\n"); } if (AP4_ParseHex(iv_ascii, iv, 16)) { fprintf(stderr, "ERROR: invalid hex format for iv\n"); return 1; } // check that the key is not already there if (key_is_set) { fprintf(stderr, "ERROR: key already set\n"); return 1; } key_is_set = true; } else if (!strcmp(arg, "--textual-header")) { char* name = NULL; char* value = NULL; arg = *++argv; if (arg == NULL) { fprintf(stderr, "ERROR: missing argument for --textual-header option\n"); return 1; } if (AP4_FAILED(AP4_SplitArgs(arg, name, value))) { fprintf(stderr, "ERROR: invalid argument for --textual-header option\n"); return 1; } // check that the property is not already set if (textual_headers.GetProperty(0, name)) { fprintf(stderr, "ERROR: textual header %s already set\n", name); return 1; } // set the property in the map textual_headers.SetProperty(0, name, value); } else if (input_filename == NULL) { input_filename = arg; } else if (output_filename == NULL) { output_filename = arg; } else { fprintf(stderr, "ERROR: unexpected argument (%s)\n", arg); return 1; } } // check the arguments if (!encryption_method_is_set) { fprintf(stderr, "ERROR: missing --method argument\n"); return 1; } if (!key_is_set) { fprintf(stderr, "ERROR: encryption key not specified\n"); return 1; } if (input_filename == NULL) { fprintf(stderr, "ERROR: missing input filename\n"); return 1; } if (output_filename == NULL) { fprintf(stderr, "ERROR: missing output filename\n"); return 1; } (void)show_progress; // avoid warnings // convert to a textual headers buffer textual_headers.GetTextualHeaders(0, textual_headers_buffer); // create the input stream AP4_Result result; AP4_ByteStream* input = NULL; result = AP4_FileByteStream::Create(input_filename, AP4_FileByteStream::STREAM_MODE_READ, input); if (AP4_FAILED(result)) { fprintf(stderr, "ERROR: cannot open input file (%s) %d\n", input_filename, result); return 1; } // get the size of the input result = input->GetSize(plaintext_length); if (AP4_FAILED(result)) { fprintf(stderr, "ERROR: cannot get the size of the input\n"); return 1; } // create an encrypting stream for the input AP4_ByteStream* encrypted_stream; if (encryption_method == AP4_OMA_DCF_ENCRYPTION_METHOD_NULL) { encrypted_stream = input; } else { result = AP4_EncryptingStream::Create(cipher_mode, *input, iv, 16, key, 16, true, &AP4_DefaultBlockCipherFactory::Instance, encrypted_stream); if (AP4_FAILED(result)) { fprintf(stderr, "ERROR: failed to create cipher (%d)\n", result); return 1; } } // create the output stream AP4_ByteStream* output = NULL; result = AP4_FileByteStream::Create(output_filename, AP4_FileByteStream::STREAM_MODE_WRITE, output); if (AP4_FAILED(result)) { fprintf(stderr, "ERROR: cannot open output file (%s) %d\n", output_filename, result); return 1; } // create the file AP4_File file; // set the brand AP4_UI32 compatible_brands[1] = {AP4_OMA_DCF_BRAND_ODCF}; file.SetFileType(AP4_OMA_DCF_BRAND_ODCF, 2, compatible_brands, 1); // create the odrm atom (force a 64-bit size) AP4_ContainerAtom* odrm = new AP4_ContainerAtom(AP4_ATOM_TYPE_ODRM, AP4_FULL_ATOM_HEADER_SIZE_64, true, 0, 0); // create the ohdr atom AP4_OhdrAtom* ohdr = new AP4_OhdrAtom(encryption_method, padding_scheme, plaintext_length, content_id, rights_issuer_url, textual_headers_buffer.GetData(), textual_headers_buffer.GetDataSize()); // create the odhe atom (the ownership is transfered) AP4_OdheAtom* odhe = new AP4_OdheAtom(content_type, ohdr); odrm->AddChild(odhe); // create the odda atom AP4_OddaAtom* odda = new AP4_OddaAtom(*encrypted_stream); odrm->AddChild(odda); // add the odrm atom to the file (the owndership is transfered) file.GetTopLevelAtoms().Add(odrm); // write the file to the output AP4_FileWriter::Write(file, *output); // cleanup input->Release(); output->Release(); return 0; }
/*---------------------------------------------------------------------- | main +---------------------------------------------------------------------*/ int main(int argc, char** argv) { if (argc < 5) { PrintUsageAndExit(); } // parse options if (strcmp(*++argv, "--kms-uri")) { fprintf(stderr, "ERROR: the first option must be --kms-uri\n"); return 1; } const char* kms_uri = *++argv; // create an encrypting processor AP4_IsmaEncryptingProcessor processor(kms_uri); // setup default values const char* input_filename = NULL; const char* output_filename = NULL; char* arg; while ((arg = *++argv)) { if (!strcmp(arg, "--key")) { arg = *++argv; if (arg == NULL) { fprintf(stderr, "ERROR: missing argument for --key option\n"); return 1; } char* track_ascii = NULL; char* key_ascii = NULL; char* salt_ascii = NULL; if (AP4_FAILED(AP4_SplitArgs(arg, track_ascii, key_ascii, salt_ascii))) { fprintf(stderr, "ERROR: invalid argument for --key option\n"); return 1; } unsigned char key[16]; unsigned char salt[8]; unsigned int track = strtoul(track_ascii, NULL, 10); if (AP4_ParseHex(key_ascii, key, 16)) { fprintf(stderr, "ERROR: invalid hex format for key\n"); } if (AP4_ParseHex(salt_ascii, salt, 8)) { fprintf(stderr, "ERROR: invalid hex format for salt\n"); } // set the key in the map processor.GetKeyMap().SetKey(track, key, salt); } else if (input_filename == NULL) { input_filename = arg; } else if (output_filename == NULL) { output_filename = arg; } else { fprintf(stderr, "ERROR: unexpected argument (%s)\n", arg); return 1; } } // check the arguments if (input_filename == NULL) { fprintf(stderr, "ERROR: missing input filename\n"); return 1; } if (output_filename == NULL) { fprintf(stderr, "ERROR: missing output filename\n"); return 1; } if (kms_uri == NULL) { fprintf(stderr, "ERROR: missing kms uri\n"); return 1; } // create the input stream AP4_ByteStream* input; try{ input = new AP4_FileByteStream(input_filename, AP4_FileByteStream::STREAM_MODE_READ); } catch (AP4_Exception) { fprintf(stderr, "ERROR: cannot open input file (%s)\n", input_filename); return 1; } // create the output stream AP4_ByteStream* output; try { output = new AP4_FileByteStream(output_filename, AP4_FileByteStream::STREAM_MODE_WRITE); } catch (AP4_Exception) { fprintf(stderr, "ERROR: cannot open output file (%s)\n", output_filename); return 1; } // process/decrypt the file processor.Process(*input, *output); // cleanup input->Release(); output->Release(); return 0; }
/*---------------------------------------------------------------------- | main +---------------------------------------------------------------------*/ int main(int argc, char** argv) { if (argc == 1) PrintUsageAndExit(); // parse options const char* kms_uri = NULL; enum Method method = METHOD_NONE; const char* input_filename = NULL; const char* output_filename = NULL; const char* fragments_info_filename = NULL; AP4_ProtectionKeyMap key_map; AP4_TrackPropertyMap property_map; bool show_progress = false; bool strict = false; AP4_Array<AP4_PsshAtom*> pssh_atoms; AP4_DataBuffer kids; unsigned int kid_count = 0; AP4_Result result; // parse the command line arguments char* arg; while ((arg = *++argv)) { if (!strcmp(arg, "--method")) { arg = *++argv; if (arg == NULL) { fprintf(stderr, "ERROR: missing argument for --method option\n"); return 1; } if (!strcmp(arg, "OMA-PDCF-CBC")) { method = METHOD_OMA_PDCF_CBC; } else if (!strcmp(arg, "OMA-PDCF-CTR")) { method = METHOD_OMA_PDCF_CTR; } else if (!strcmp(arg, "MARLIN-IPMP-ACBC")) { method = METHOD_MARLIN_IPMP_ACBC; } else if (!strcmp(arg, "MARLIN-IPMP-ACGK")) { method = METHOD_MARLIN_IPMP_ACGK; } else if (!strcmp(arg, "PIFF-CBC")) { method = METHOD_PIFF_CBC; } else if (!strcmp(arg, "PIFF-CTR")) { method = METHOD_PIFF_CTR; } else if (!strcmp(arg, "MPEG-CENC")) { method = METHOD_MPEG_CENC; } else if (!strcmp(arg, "ISMA-IAEC")) { method = METHOD_ISMA_AES; } else { fprintf(stderr, "ERROR: invalid value for --method argument\n"); return 1; } } else if (!strcmp(arg, "--fragments-info")) { arg = *++argv; if (arg == NULL) { fprintf(stderr, "ERROR: missing argument for --fragments-info option\n"); return 1; } fragments_info_filename = arg; } else if (!strcmp(arg, "--pssh") || !strcmp(arg, "--pssh-v1")) { bool v1 = (strcmp(arg, "--pssh-v1") == 0); arg = *++argv; if (arg == NULL) { fprintf(stderr, "ERROR: missing argument for --pssh\n"); return 1; } if (AP4_StringLength(arg) < 32+1 || arg[32] != ':') { fprintf(stderr, "ERROR: invalid argument syntax for --pssh\n"); return 1; } unsigned char system_id[16]; arg[32] = '\0'; result = AP4_ParseHex(arg, system_id, 16); if (AP4_FAILED(result)) { fprintf(stderr, "ERROR: invalid argument syntax for --pssh\n"); return 1; } const char* pssh_filename = arg+33; // load the pssh payload AP4_DataBuffer pssh_payload; if (pssh_filename[0]) { AP4_ByteStream* pssh_input = NULL; result = AP4_FileByteStream::Create(pssh_filename, AP4_FileByteStream::STREAM_MODE_READ, pssh_input); if (AP4_FAILED(result)) { fprintf(stderr, "ERROR: cannot open pssh payload file (%d)\n", result); return 1; } AP4_LargeSize pssh_payload_size = 0; pssh_input->GetSize(pssh_payload_size); pssh_payload.SetDataSize((AP4_Size)pssh_payload_size); result = pssh_input->Read(pssh_payload.UseData(), (AP4_Size)pssh_payload_size); if (AP4_FAILED(result)) { fprintf(stderr, "ERROR: cannot read pssh payload from file (%d)\n", result); return 1; } } AP4_PsshAtom* pssh; if (v1) { if (kid_count) { pssh = new AP4_PsshAtom(system_id, kids.GetData(), kid_count); } else { pssh = new AP4_PsshAtom(system_id); } } else { pssh = new AP4_PsshAtom(system_id); } if (pssh_payload.GetDataSize()) { pssh->SetData(pssh_payload.GetData(), pssh_payload.GetDataSize()); } pssh_atoms.Append(pssh); } else if (!strcmp(arg, "--kms-uri")) { arg = *++argv; if (arg == NULL) { fprintf(stderr, "ERROR: missing argument for --kms-uri option\n"); return 1; } if (method != METHOD_ISMA_AES) { fprintf(stderr, "ERROR: --kms-uri only applies to method ISMA-IAEC\n"); return 1; } kms_uri = arg; } else if (!strcmp(arg, "--show-progress")) { show_progress = true; } else if (!strcmp(arg, "--strict")) { strict = true; } else if (!strcmp(arg, "--key")) { if (method == METHOD_NONE) { fprintf(stderr, "ERROR: --method argument must appear before --key\n"); return 1; } arg = *++argv; if (arg == NULL) { fprintf(stderr, "ERROR: missing argument for --key option\n"); return 1; } char* track_ascii = NULL; char* key_ascii = NULL; char* iv_ascii = NULL; if (AP4_FAILED(AP4_SplitArgs(arg, track_ascii, key_ascii, iv_ascii))) { fprintf(stderr, "ERROR: invalid argument for --key option\n"); return 1; } unsigned int track = strtoul(track_ascii, NULL, 10); // parse the key value unsigned char key[16]; AP4_SetMemory(key, 0, sizeof(key)); if (AP4_CompareStrings(key_ascii, "random") == 0) { result = AP4_System_GenerateRandomBytes(key, 16); if (AP4_FAILED(result)) { fprintf(stderr, "ERROR: failed to generate random key (%d)\n", result); return 1; } char key_hex[32+1]; key_hex[32] = '\0'; AP4_FormatHex(key, 16, key_hex); printf("KEY.%d=%s\n", track, key_hex); } else { if (AP4_ParseHex(key_ascii, key, 16)) { fprintf(stderr, "ERROR: invalid hex format for key\n"); return 1; } } // parse the iv unsigned char iv[16]; AP4_SetMemory(iv, 0, sizeof(iv)); if (AP4_CompareStrings(iv_ascii, "random") == 0) { result = AP4_System_GenerateRandomBytes(iv, 16); if (AP4_FAILED(result)) { fprintf(stderr, "ERROR: failed to generate random key (%d)\n", result); return 1; } iv[0] &= 0x7F; // always set the MSB to 0 so we don't have wraparounds } else { unsigned int iv_size = (unsigned int)AP4_StringLength(iv_ascii)/2; if (AP4_ParseHex(iv_ascii, iv, iv_size)) { fprintf(stderr, "ERROR: invalid hex format for iv\n"); return 1; } } switch (method) { case METHOD_OMA_PDCF_CTR: case METHOD_ISMA_AES: case METHOD_PIFF_CTR: case METHOD_MPEG_CENC: // truncate the IV AP4_SetMemory(&iv[8], 0, 8); break; default: break; } // check that the key is not already there if (key_map.GetKey(track)) { fprintf(stderr, "ERROR: key already set for track %d\n", track); return 1; } // set the key in the map key_map.SetKey(track, key, 16, iv, 16); } else if (!strcmp(arg, "--property")) { char* track_ascii = NULL; char* name = NULL; char* value = NULL; if (method != METHOD_OMA_PDCF_CBC && method != METHOD_OMA_PDCF_CTR && method != METHOD_MARLIN_IPMP_ACBC && method != METHOD_MARLIN_IPMP_ACGK && method != METHOD_PIFF_CBC && method != METHOD_PIFF_CTR && method != METHOD_MPEG_CENC) { fprintf(stderr, "ERROR: this method does not use properties\n"); return 1; } arg = *++argv; if (arg == NULL) { fprintf(stderr, "ERROR: missing argument for --property option\n"); return 1; } if (AP4_FAILED(AP4_SplitArgs(arg, track_ascii, name, value))) { fprintf(stderr, "ERROR: invalid argument for --property option\n"); return 1; } unsigned int track = strtoul(track_ascii, NULL, 10); // check that the property is not already set if (property_map.GetProperty(track, name)) { fprintf(stderr, "ERROR: property %s already set for track %d\n", name, track); return 1; } // set the property in the map property_map.SetProperty(track, name, value); // special treatment for KID properties if (!strcmp(name, "KID")) { if (AP4_StringLength(value) != 32) { fprintf(stderr, "ERROR: invalid size for KID property (must be 32 hex chars)\n"); return 1; } AP4_UI08 kid[16]; if (AP4_FAILED(AP4_ParseHex(value, kid, 16))) { fprintf(stderr, "ERROR: invalid syntax for KID property (must be 32 hex chars)\n"); return 1; } // check if we already have this KID bool kid_already_present = false; for (unsigned int i=0; i<kid_count; i++) { if (AP4_CompareMemory(kids.GetData()+(i*16), kid, 16) == 0) { kid_already_present = true; break; } } if (!kid_already_present) { ++kid_count; kids.AppendData(kid, 16); } } } else if (!strcmp(arg, "--global-option")) { arg = *++argv; char* name = NULL; char* value = NULL; if (arg == NULL) { fprintf(stderr, "ERROR: missing argument for --global-option option\n"); return 1; } if (AP4_FAILED(AP4_SplitArgs(arg, name, value))) { fprintf(stderr, "ERROR: invalid argument for --global-option option\n"); return 1; } AP4_GlobalOptions::SetString(name, value); } else if (input_filename == NULL) { input_filename = arg; } else if (output_filename == NULL) { output_filename = arg; } else { fprintf(stderr, "ERROR: unexpected argument (%s)\n", arg); return 1; } } // check the arguments if (method == METHOD_NONE) { fprintf(stderr, "ERROR: missing --method argument\n"); return 1; } if (input_filename == NULL) { fprintf(stderr, "ERROR: missing input filename\n"); return 1; } if (output_filename == NULL) { fprintf(stderr, "ERROR: missing output filename\n"); return 1; } // create an encrypting processor AP4_Processor* processor = NULL; if (method == METHOD_ISMA_AES) { if (kms_uri == NULL) { fprintf(stderr, "ERROR: method ISMA-IAEC requires --kms-uri\n"); return 1; } AP4_IsmaEncryptingProcessor* isma_processor = new AP4_IsmaEncryptingProcessor(kms_uri); isma_processor->GetKeyMap().SetKeys(key_map); processor = isma_processor; } else if (method == METHOD_MARLIN_IPMP_ACBC || method == METHOD_MARLIN_IPMP_ACGK) { bool use_group_key = (method == METHOD_MARLIN_IPMP_ACGK); if (use_group_key) { // check that the group key is set if (key_map.GetKey(0) == NULL) { fprintf(stderr, "ERROR: method MARLIN-IPMP-ACGK requires a group key\n"); return 1; } } AP4_MarlinIpmpEncryptingProcessor* marlin_processor = new AP4_MarlinIpmpEncryptingProcessor(use_group_key); marlin_processor->GetKeyMap().SetKeys(key_map); marlin_processor->GetPropertyMap().SetProperties(property_map); processor = marlin_processor; } else if (method == METHOD_OMA_PDCF_CTR || method == METHOD_OMA_PDCF_CBC) { AP4_OmaDcfEncryptingProcessor* oma_processor = new AP4_OmaDcfEncryptingProcessor(method == METHOD_OMA_PDCF_CTR? AP4_OMA_DCF_CIPHER_MODE_CTR : AP4_OMA_DCF_CIPHER_MODE_CBC); oma_processor->GetKeyMap().SetKeys(key_map); oma_processor->GetPropertyMap().SetProperties(property_map); processor = oma_processor; } else if (method == METHOD_PIFF_CTR || method == METHOD_PIFF_CBC || method == METHOD_MPEG_CENC) { AP4_CencVariant variant = AP4_CENC_VARIANT_MPEG; switch (method) { case METHOD_PIFF_CBC: variant = AP4_CENC_VARIANT_PIFF_CBC; break; case METHOD_PIFF_CTR: variant = AP4_CENC_VARIANT_PIFF_CTR; break; case METHOD_MPEG_CENC: variant = AP4_CENC_VARIANT_MPEG; break; default: break; } AP4_CencEncryptingProcessor* cenc_processor = new AP4_CencEncryptingProcessor(variant); cenc_processor->GetKeyMap().SetKeys(key_map); cenc_processor->GetPropertyMap().SetProperties(property_map); for (unsigned int i=0; i<pssh_atoms.ItemCount(); i++) { cenc_processor->GetPsshAtoms().Append(pssh_atoms[i]); } processor = cenc_processor; } // create the input stream AP4_ByteStream* input = NULL; result = AP4_FileByteStream::Create(input_filename, AP4_FileByteStream::STREAM_MODE_READ, input); if (AP4_FAILED(result)) { fprintf(stderr, "ERROR: cannot open input file (%s)\n", input_filename); return 1; } // create the output stream AP4_ByteStream* output = NULL; result = AP4_FileByteStream::Create(output_filename, AP4_FileByteStream::STREAM_MODE_WRITE, output); if (AP4_FAILED(result)) { fprintf(stderr, "ERROR: cannot open output file (%s)\n", output_filename); return 1; } // create the fragments info stream if needed AP4_ByteStream* fragments_info = NULL; if (fragments_info_filename) { result = AP4_FileByteStream::Create(fragments_info_filename, AP4_FileByteStream::STREAM_MODE_READ, fragments_info); if (AP4_FAILED(result)) { fprintf(stderr, "ERROR: cannot open fragments info file (%s)\n", fragments_info_filename); return 1; } } // process/decrypt the file ProgressListener listener; if (fragments_info) { bool check = CheckWarning(*fragments_info, key_map, method); if (strict && check) return 1; result = processor->Process(*input, *output, *fragments_info, show_progress?&listener:NULL); } else { bool check = CheckWarning(*input, key_map, method); if (strict && check) return 1; result = processor->Process(*input, *output, show_progress?&listener:NULL); } if (AP4_FAILED(result)) { fprintf(stderr, "ERROR: failed to process the file (%d)\n", result); } // cleanup delete processor; input->Release(); output->Release(); if (fragments_info) fragments_info->Release(); for (unsigned int i=0; i<pssh_atoms.ItemCount(); i++) { delete pssh_atoms[i]; } return 0; }