void Name::set(const NameLite& nameLite) { clear(); for (size_t i = 0; i < nameLite.size(); ++i) append(Component(nameLite.get(i))); }
void Name::get(NameLite& nameLite) const { nameLite.clear(); for (size_t i = 0; i < components_.size(); ++i) { ndn_Error error; NameLite::Component component; components_[i].get(component); if ((error = nameLite.append(component))) throw runtime_error(ndn_getErrorString(error)); } }
// Imitate Name::set(const NameLite& nameLite). static void setName(PyObject* name, const NameLite& nameLite) { PyObjectRef ignoreResult1(PyObject_CallMethodObjArgs(name, str.clear, NULL)); for (size_t i = 0; i < nameLite.size(); ++i) { PyObjectRef blob(makeBlob(nameLite.get(i).getValue())); PyObjectRef type(PyLong_FromLong((int)nameLite.get(i).getType())); PyObjectRef otherTypeCode(PyLong_FromLong(nameLite.get(i).getOtherTypeCode())); PyObjectRef ignoreResult3(PyObject_CallMethodObjArgs (name, str.append, blob.obj, type.obj, otherTypeCode.obj, NULL)); } }
// Imitate Name::get(NameLite& nameLite). static void toNameLite(PyObject* name, NameLite& nameLite) { nameLite.clear(); PyObjectRef components(PyObject_GetAttr(name, str._components)); for (size_t i = 0; i < PyList_GET_SIZE(components.obj); ++i) { ndn_Error error; NameLite::Component componentLite; toNameComponentLite(PyList_GET_ITEM(components.obj, i), componentLite); if ((error = nameLite.append(componentLite))) // TODO: Handle the error! return; } }
// Imitate Name::set(const NameLite& nameLite). static void setName(PyObject* name, const NameLite& nameLite) { PyObjectRef ignoreResult1(PyObject_CallMethodObjArgs(name, str.clear, NULL)); for (size_t i = 0; i < nameLite.size(); ++i) { PyObjectRef blob(makeBlob(nameLite.get(i).getValue())); // Imitate Name::Component::set(const NameLite::Component& componentLite). if (nameLite.get(i).isImplicitSha256Digest()) PyObjectRef ignoreResult2(PyObject_CallMethodObjArgs (name, str.appendImplicitSha256Digest, blob.obj, NULL)); else PyObjectRef ignoreResult3(PyObject_CallMethodObjArgs (name, str.append, blob.obj, NULL)); } }
/** * Loop to encode a data packet nIterations times using C. * @param nIterations The number of iterations. * @param useComplex If true, use a large name, large content and all fields. If false, use a small name, small content * and only required fields. * @param useCrypto If true, sign the data packet. If false, use a blank signature. * @param encoding Output buffer for the wire encoding. * @param maxEncodingLength The size of the encoding buffer. * @param encodingLength Return the number of output bytes in encoding. * @return The number of seconds for all iterations. */ static double benchmarkEncodeDataSecondsC (int nIterations, bool useComplex, bool useCrypto, uint8_t* encoding, size_t maxEncodingLength, size_t *encodingLength) { ndn_Error error; NameLite::Component finalBlockId((uint8_t*)"\x00", 1); ndn_NameComponent nameComponents[7]; NameLite name(nameComponents, sizeof(nameComponents) / sizeof(nameComponents[0])); const size_t complexContentSize = 1115; char contentString[complexContentSize + 10]; BlobLite content; if (useComplex) { // Use a large name and content. name.append("ndn"); name.append("ucla.edu"); name.append("apps"); name.append("lwndn-test"); name.append("numbers.txt"); name.append("\xFD\x05\x05\xE8\x0C\xCE\x1D"); if ((error = name.append(finalBlockId))) { cout << "Error in name.append: " << ndn_getErrorString(error) << endl; return 0; } int count = 1; sprintf(contentString, "%d", count++); while (strlen(contentString) < complexContentSize) sprintf(contentString + strlen(contentString), " %d", count++); content = BlobLite((uint8_t*)contentString, strlen(contentString)); } else { // Use a small name and content. name.append("test"); content = BlobLite((uint8_t*)"abc", 3); } ndn_NameComponent certificateNameComponents[5]; NameLite certificateName (certificateNameComponents, sizeof(certificateNameComponents) / sizeof(certificateNameComponents[0])); certificateName.append("testname"); certificateName.append("KEY"); certificateName.append("DSK-123"); certificateName.append("ID-CERT"); if ((error = certificateName.append("0"))) { cout << "Error in certificateName.append: " << ndn_getErrorString(error) << endl; return 0; } uint8_t signatureBitsArray[256]; memset(signatureBitsArray, 0, sizeof(signatureBitsArray)); // Set up the private key now in case useCrypto is true. // Use a temporary pointer since d2i updates it. const uint8_t *privateKeyDerPointer = DEFAULT_RSA_PRIVATE_KEY_DER; RSA *privateKey = d2i_RSAPrivateKey(NULL, &privateKeyDerPointer, sizeof(DEFAULT_RSA_PRIVATE_KEY_DER)); if (!privateKey) { // Don't expect this to happen. cout << "Error decoding private key DER" << endl; return 0; } double start = getNowSeconds(); for (int i = 0; i < nIterations; ++i) { // Since we aren't going to change the names, we can re-use the arrays. DataLite data (nameComponents, sizeof(nameComponents) / sizeof(nameComponents[0]), certificateNameComponents, sizeof(certificateNameComponents) / sizeof(certificateNameComponents[0])); if ((error = data.setName(name))) { cout << "Error in data.setName: " << ndn_getErrorString(error) << endl; return 0; } data.setContent(content); if (useComplex) { data.getMetaInfo().setFreshnessPeriod(1000); data.getMetaInfo().setFinalBlockId(finalBlockId); } // Assume the encoding buffer is big enough so we don't need to dynamically reallocate. DynamicUInt8ArrayLite output(encoding, maxEncodingLength, 0); size_t signedPortionBeginOffset, signedPortionEndOffset; data.getSignature().getKeyLocator().setType(ndn_KeyLocatorType_KEYNAME); if ((error = data.getSignature().getKeyLocator().setKeyName(certificateName))) { cout << "Error in data.setKeyName: " << ndn_getErrorString(error) << endl; return 0; } if (useCrypto) { data.getSignature().setType(ndn_SignatureType_Sha256WithRsaSignature); // Encode once to get the signed portion. size_t dummyEncodingLength; if ((error = Tlv0_1_1WireFormatLite::encodeData (data, &signedPortionBeginOffset, &signedPortionEndOffset, output, &dummyEncodingLength))) { cout << "Error in ndn_encodeTlvData: " << ndn_getErrorString(error) << endl; return 0; } // Imitate MemoryPrivateKeyStorage::sign. uint8_t digest[SHA256_DIGEST_LENGTH]; ndn_digestSha256(encoding + signedPortionBeginOffset, signedPortionEndOffset - signedPortionBeginOffset, digest); unsigned int signatureBitsLength; if (!RSA_sign(NID_sha256, digest, sizeof(digest), signatureBitsArray, &signatureBitsLength, privateKey)) { // Don't expect this to happen. cout << "Error in RSA_sign" << endl; return 0; } data.getSignature().setSignature(BlobLite(signatureBitsArray, signatureBitsLength)); } else { // Set up the signature, but don't sign. data.getSignature().setSignature(BlobLite(signatureBitsArray, sizeof(signatureBitsArray))); data.getSignature().setType(ndn_SignatureType_Sha256WithRsaSignature); } if ((error = Tlv0_1_1WireFormatLite::encodeData (data, &signedPortionBeginOffset, &signedPortionEndOffset, output, encodingLength))) { cout << "Error in ndn_encodeTlvData: " << ndn_getErrorString(error) << endl; return 0; } } double finish = getNowSeconds(); if (privateKey) RSA_free(privateKey); return finish - start; }