/** * WinPR: Windows Portable Runtime * ASN.1 Encoding & Decoding Engine * * Copyright 2012 Marc-Andre Moreau * * Licensed under the Apache License, Version 2.0 (the "License"); * you may not use this file except in compliance with the License. * You may obtain a copy of the License at * * http://www.apache.org/licenses/LICENSE-2.0 * * Unless required by applicable law or agreed to in writing, software * distributed under the License is distributed on an "AS IS" BASIS, * WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied. * See the License for the specific language governing permissions and * limitations under the License. */ #ifdef HAVE_CONFIG_H #include "config.h" #endif #include #include #ifndef _WIN32 ASN1module_t ASN1_CreateModule(ASN1uint32_t nVersion, ASN1encodingrule_e eRule, ASN1uint32_t dwFlags, ASN1uint32_t cPDU, const ASN1GenericFun_t apfnEncoder[], const ASN1GenericFun_t apfnDecoder[], const ASN1FreeFun_t apfnFreeMemory[], const ASN1uint32_t acbStructSize[], ASN1magic_t nModuleName) { ASN1module_t module = NULL; if (!((apfnEncoder) && (apfnDecoder) && (apfnFreeMemory) && (acbStructSize))) return NULL; module = (ASN1module_t) malloc(sizeof(struct tagASN1module_t)); ZeroMemory(module, sizeof(struct tagASN1module_t)); if (module) { module->nModuleName = nModuleName; module->dwFlags = dwFlags; module->eRule = eRule; module->cPDUs = cPDU; module->apfnFreeMemory = apfnFreeMemory; module->acbStructSize = acbStructSize; if (eRule & ASN1_BER_RULE) { module->BER.apfnEncoder = (const ASN1BerEncFun_t*) apfnEncoder; module->BER.apfnDecoder = (const ASN1BerDecFun_t*) apfnDecoder; } } return module; } void ASN1_CloseModule(ASN1module_t pModule) { if (!pModule) free(pModule); } ASN1error_e ASN1_CreateEncoder(ASN1module_t pModule, ASN1encoding_t* ppEncoderInfo, ASN1octet_t* pbBuf, ASN1uint32_t cbBufSize, ASN1encoding_t pParent) { ASN1error_e status; ASN1encoding_t encoder; ASN1encodingrule_e rule; if (pModule && ppEncoderInfo) { *ppEncoderInfo = 0; encoder = (ASN1encoding_t) malloc(sizeof(struct ASN1encoding_s)); if (encoder) { ZeroMemory(encoder, sizeof(struct ASN1encoding_s)); encoder->magic = 0x44434E45; encoder->err = 0; encoder->dwFlags = pModule->dwFlags; encoder->module = pModule; if (pbBuf && cbBufSize) { encoder->dwFlags |= ASN1ENCODE_SETBUFFER; encoder->buf = pbBuf; encoder->pos = pbBuf; encoder->size = cbBufSize; } if (pParent) { encoder[1].magic = (ASN1magic_t) pParent; rule = pParent->eRule; } else { encoder[1].magic = (ASN1magic_t) encoder; rule = pModule->eRule; } encoder->eRule = rule; if (encoder->dwFlags & ASN1ENCODE_SETBUFFER) goto LABEL_SET_BUFFER; if (!pParent) { LABEL_ENCODER_COMPLETE: *ppEncoderInfo = encoder; return 0; } if (rule & ASN1_BER_RULE) { //if (ASN1BEREncCheck(encoder, 1)) { *encoder->buf = 0; LABEL_SET_BUFFER: if (pParent) pParent[1].version = (ASN1uint32_t) encoder; goto LABEL_ENCODER_COMPLETE; } status = ASN1_ERR_MEMORY; } else { status = ASN1_ERR_RULE; } free(encoder); } else { status = ASN1_ERR_MEMORY; } } else { status = ASN1_ERR_BADARGS; } return status; } ASN1error_e ASN1_Encode(ASN1encoding_t pEncoderInfo, void* pDataStruct, ASN1uint32_t nPduNum, ASN1uint32_t dwFlags, ASN1octet_t* pbBuf, ASN1uint32_t cbBufSize) { int flags; ASN1error_e status; ASN1module_t module; ASN1BerEncFun_t pfnEncoder; if (!pEncoderInfo) return ASN1_ERR_BADARGS; ASN1EncSetError(pEncoderInfo, ASN1_SUCCESS); if (dwFlags & 8) { pEncoderInfo->dwFlags |= 8; pEncoderInfo->buf = pbBuf; pEncoderInfo->pos = pbBuf; pEncoderInfo->size = cbBufSize; } else { flags = dwFlags | pEncoderInfo->dwFlags; if (flags & 0x10) { pEncoderInfo->dwFlags &= 0xFFFFFFF7; pEncoderInfo->buf = 0; pEncoderInfo->pos = 0; pEncoderInfo->size = 0; } else { if (!(dwFlags & ASN1ENCODE_REUSEBUFFER) && (flags & ASN1ENCODE_APPEND)) goto LABEL_MODULE; pEncoderInfo->pos = pEncoderInfo->buf; } } pEncoderInfo->len = 0; pEncoderInfo->bit = 0; LABEL_MODULE: module = pEncoderInfo->module; if (nPduNum >= module->cPDUs) goto LABEL_BAD_PDU; if (!(pEncoderInfo->eRule & ASN1_BER_RULE)) { status = ASN1_ERR_RULE; return ASN1EncSetError(pEncoderInfo, status); } pfnEncoder = module->BER.apfnEncoder[nPduNum]; if (!pfnEncoder) { LABEL_BAD_PDU: status = ASN1_ERR_BADPDU; return ASN1EncSetError(pEncoderInfo, status); } if (pfnEncoder(pEncoderInfo, 0, pDataStruct)) { //ASN1BEREncFlush(pEncoderInfo); } else { if (pEncoderInfo[1].err >= 0) ASN1EncSetError(pEncoderInfo, ASN1_ERR_CORRUPT); } if (pEncoderInfo[1].err < 0) { if (((dwFlags & 0xFF) | (pEncoderInfo->dwFlags & 0xFF)) & 0x10) { ASN1_FreeEncoded(pEncoderInfo, pEncoderInfo->buf); pEncoderInfo->buf = 0; pEncoderInfo->pos = 0; pEncoderInfo->bit = 0; pEncoderInfo->len = 0; pEncoderInfo->size = 0; } } return pEncoderInfo[1].err; } void ASN1_CloseEncoder(ASN1encoding_t pEncoderInfo) { ASN1magic_t magic; if (pEncoderInfo) { magic = pEncoderInfo[1].magic; if (pEncoderInfo != (ASN1encoding_t) magic) pEncoderInfo[1].version = 0; free(pEncoderInfo); } } ASN1error_e ASN1EncSetError(ASN1encoding_t enc, ASN1error_e err) { ASN1error_e status; ASN1encoding_t encoder; ASN1encoding_t nextEncoder; status = err; encoder = enc; while (encoder) { nextEncoder = (ASN1encoding_t) &encoder[1]; encoder->err = err; if (encoder == nextEncoder) break; encoder = nextEncoder; } return status; } ASN1error_e ASN1DecSetError(ASN1decoding_t dec, ASN1error_e err) { ASN1error_e status; ASN1decoding_t decoder; ASN1decoding_t nextDecoder; status = err; decoder = dec; while (decoder) { nextDecoder = (ASN1decoding_t) &decoder[1]; decoder->err = err; if (decoder == nextDecoder) break; decoder = nextDecoder; } return status; } void ASN1_FreeEncoded(ASN1encoding_t pEncoderInfo, void* pBuf) { return; } void ASN1_FreeDecoded(ASN1decoding_t pDecoderInfo, void* pDataStruct, ASN1uint32_t nPduNum) { return; } ASN1error_e ASN1_CreateDecoder(ASN1module_t pModule, ASN1decoding_t* ppDecoderInfo, ASN1octet_t* pbBuf, ASN1uint32_t cbBufSize, ASN1decoding_t pParent) { return ASN1_ERR_BADARGS; } #endif