Maxim Integrated
Device interface library for multiple platforms including Mbed.
Dependents: DeepCover Embedded Security in IoT MaximInterface MAXREFDES155#
Maxim Interface is a library framework focused on providing flexible and expressive hardware interfaces. Both communication interfaces such as I2C and 1-Wire and device interfaces such as DS18B20 are supported. Modern C++ concepts are used extensively while keeping compatibility with C++98/C++03 and requiring no external dependencies. The embedded-friendly design does not depend on exceptions or RTTI.
The full version of the project is hosted on GitLab: https://gitlab.com/iabenz/MaximInterface
MaximInterfaceDevices/DS28C36_DS2476.cpp
- Committer:
- IanBenzMaxim
- Date:
- 2019-07-22
- Revision:
- 7:9cd16581b578
- Child:
- 8:5ea891c7d1a1
File content as of revision 7:9cd16581b578:
/*******************************************************************************
* Copyright (C) 2017 Maxim Integrated Products, Inc., All Rights Reserved.
*
* Permission is hereby granted, free of charge, to any person obtaining a
* copy of this software and associated documentation files (the "Software"),
* to deal in the Software without restriction, including without limitation
* the rights to use, copy, modify, merge, publish, distribute, sublicense,
* and/or sell copies of the Software, and to permit persons to whom the
* Software is furnished to do so, subject to the following conditions:
*
* The above copyright notice and this permission notice shall be included
* in all copies or substantial portions of the Software.
*
* THE SOFTWARE IS PROVIDED "AS IS", WITHOUT WARRANTY OF ANY KIND, EXPRESS
* OR IMPLIED, INCLUDING BUT NOT LIMITED TO THE WARRANTIES OF
* MERCHANTABILITY, FITNESS FOR A PARTICULAR PURPOSE AND NONINFRINGEMENT.
* IN NO EVENT SHALL MAXIM INTEGRATED BE LIABLE FOR ANY CLAIM, DAMAGES
* OR OTHER LIABILITY, WHETHER IN AN ACTION OF CONTRACT, TORT OR OTHERWISE,
* ARISING FROM, OUT OF OR IN CONNECTION WITH THE SOFTWARE OR THE USE OR
* OTHER DEALINGS IN THE SOFTWARE.
*
* Except as contained in this notice, the name of Maxim Integrated
* Products, Inc. shall not be used except as stated in the Maxim Integrated
* Products, Inc. Branding Policy.
*
* The mere transfer of this software does not imply any licenses
* of trade secrets, proprietary technology, copyrights, patents,
* trademarks, maskwork rights, or any other form of intellectual
* property whatsoever. Maxim Integrated Products, Inc. retains all
* ownership rights.
*******************************************************************************/
#include <algorithm>
#include <MaximInterfaceCore/Error.hpp>
#include <MaximInterfaceCore/I2CMaster.hpp>
#include <MaximInterfaceCore/RomId.hpp>
#include "DS28C36_DS2476.hpp"
namespace MaximInterfaceDevices {
using namespace Core;
using namespace Ecc256;
using std::copy;
static error_code convertResultByte(uint_least8_t resultByte) {
error_code errorCode;
if (resultByte != 0xAA) {
errorCode.assign((resultByte == 0x00)
? static_cast<int>(DS28C36::AuthenticationError)
: resultByte,
DS28C36::errorCategory());
}
return errorCode;
}
const int DS28C36::publicKeyAxPage;
const int DS28C36::publicKeyAyPage;
const int DS28C36::publicKeyBxPage;
const int DS28C36::publicKeyByPage;
const int DS28C36::publicKeyCxPage;
const int DS28C36::publicKeyCyPage;
const int DS28C36::privateKeyAPage;
const int DS28C36::privateKeyBPage;
const int DS28C36::privateKeyCPage;
const int DS28C36::secretAPage;
const int DS28C36::secretBPage;
const int DS28C36::decrementCounterPage;
const int DS28C36::romOptionsPage;
const int DS28C36::gpioControlPage;
const int DS28C36::publicKeySxPage;
const int DS28C36::publicKeySyPage;
const int DS28C36::memoryPages;
error_code DS28C36::writeMemory(int pageNum, Page::const_span page) {
if (pageNum < 0 || pageNum >= memoryPages) {
return make_error_code(InvalidParameterError);
}
uint_least8_t buffer[1 + Page::size];
buffer[0] = pageNum;
copy(page.begin(), page.end(), buffer + 1);
error_code result = writeCommand(0x96, buffer);
if (!result) {
sleep(writeMemoryTimeMs);
result = readFixedLengthResponse(make_span(buffer, 1));
if (!result) {
result = convertResultByte(buffer[0]);
}
}
return result;
}
error_code DS28C36::readMemory(int pageNum, Page::span page) {
if (pageNum < 0 || pageNum >= memoryPages) {
return make_error_code(InvalidParameterError);
}
const uint_least8_t parameter = pageNum;
error_code result = writeCommand(0x69, make_span(¶meter, 1));
if (!result) {
sleep(readMemoryTimeMs);
array<uint_least8_t, 1 + Page::size> response;
result = readFixedLengthResponse(response);
if (!result) {
result = convertResultByte(response[0]);
copy(response.begin() + 1, response.end(), page.begin());
}
}
return result;
}
error_code DS28C36::writeBuffer(span<const uint_least8_t> data) {
return writeCommand(0x87, data);
}
error_code DS28C36::readBuffer(std::vector<uint_least8_t> & data) {
error_code result = writeCommand(0x5A);
if (!result) {
data.resize(80);
span<uint_least8_t> dataSpan(data);
result = readVariableLengthResponse(dataSpan);
if (result) {
data.clear();
} else {
data.resize(dataSpan.size());
}
}
return result;
}
error_code DS28C36::readPageProtection(int pageNum,
PageProtection & protection) {
if (pageNum < 0 || pageNum >= memoryPages) {
return make_error_code(InvalidParameterError);
}
uint_least8_t buffer = pageNum;
error_code result = writeCommand(0xAA, make_span(&buffer, 1));
if (!result) {
sleep(readMemoryTimeMs);
result = readFixedLengthResponse(make_span(&buffer, 1));
if (!result) {
protection = buffer;
}
}
return result;
}
error_code DS28C36::setPageProtection(int pageNum,
const PageProtection & protection) {
if (pageNum < 0 || pageNum >= memoryPages) {
return make_error_code(InvalidParameterError);
}
uint_least8_t buffer[] = {static_cast<uint_least8_t>(pageNum),
static_cast<uint_least8_t>(protection.to_ulong())};
error_code result = writeCommand(0xC3, buffer);
if (!result) {
sleep(writeMemoryTimeMs);
result = readFixedLengthResponse(make_span(buffer, 1));
if (!result) {
result = convertResultByte(buffer[0]);
}
}
return result;
}
error_code DS28C36::decrementCounter() {
error_code result = writeCommand(0xC9);
if (!result) {
sleep(writeMemoryTimeMs);
uint_least8_t response;
result = readFixedLengthResponse(make_span(&response, 1));
if (!result) {
result = convertResultByte(response);
}
}
return result;
}
error_code DS28C36::readRng(span<uint_least8_t> data) {
if ((data.size() < 1) || (data.size() > 64)) {
return make_error_code(InvalidParameterError);
}
data[0] = static_cast<uint_least8_t>(data.size() - 1);
error_code result = writeCommand(0xD2, data.first(1));
if (!result) {
sleep(sha256ComputationTimeMs);
result = readFixedLengthResponse(data);
}
return result;
}
error_code DS28C36::encryptedReadMemory(int pageNum, SecretNum secretNum,
EncryptionChallenge::span challenge,
Page::span data) {
if (pageNum < 0 || pageNum >= memoryPages) {
return make_error_code(InvalidParameterError);
}
const uint_least8_t parameter = (secretNum << 6) | pageNum;
error_code result = writeCommand(0x4B, make_span(¶meter, 1));
if (!result) {
sleep(readMemoryTimeMs + sha256ComputationTimeMs);
uint_least8_t response[1 + EncryptionChallenge::size + Page::size];
result = readFixedLengthResponse(response);
if (!result) {
result = convertResultByte(response[0]);
const uint_least8_t * begin = response + 1;
const uint_least8_t * end = begin + challenge.size();
copy(begin, end, challenge.begin());
begin = end;
end = begin + data.size();
copy(begin, end, data.begin());
}
}
return result;
}
error_code DS28C36::computeAndReadPageAuthentication(int pageNum,
AuthType authType) {
if (pageNum < 0 || pageNum >= memoryPages) {
return make_error_code(InvalidParameterError);
}
const uint_least8_t parameter = (authType << 5) | pageNum;
return writeCommand(0xA5, make_span(¶meter, 1));
}
error_code
DS28C36::computeAndReadPageAuthentication(int pageNum, KeyNum keyNum,
Signature::span signature) {
AuthType authType;
switch (keyNum) {
case KeyNumA:
authType = EcdsaWithKeyA;
break;
case KeyNumB:
authType = EcdsaWithKeyB;
break;
case KeyNumC:
authType = EcdsaWithKeyC;
break;
default:
return make_error_code(InvalidParameterError);
}
error_code result = computeAndReadPageAuthentication(pageNum, authType);
if (!result) {
sleep(readMemoryTimeMs + generateEcdsaSignatureTimeMs);
uint_least8_t response[1 + 2 * Scalar::size];
result = readFixedLengthResponse(response);
if (!result) {
result = convertResultByte(response[0]);
const uint_least8_t * begin = response + 1;
const uint_least8_t * end = begin + signature.s.size();
copy(begin, end, signature.s.begin());
begin = end;
end = begin + signature.r.size();
copy(begin, end, signature.r.begin());
}
}
return result;
}
error_code DS28C36::computeAndReadPageAuthentication(int pageNum,
SecretNum secretNum,
Page::span hmac) {
AuthType authType;
switch (secretNum) {
case SecretNumA:
authType = HmacWithSecretA;
break;
case SecretNumB:
authType = HmacWithSecretB;
break;
case SecretNumS:
authType = HmacWithSecretS;
break;
default:
return make_error_code(InvalidParameterError);
}
error_code result = computeAndReadPageAuthentication(pageNum, authType);
if (!result) {
sleep(readMemoryTimeMs + sha256ComputationTimeMs);
array<uint_least8_t, 1 + Page::size> response;
result = readFixedLengthResponse(response);
if (!result) {
result = convertResultByte(response[0]);
copy(response.begin() + 1, response.end(), hmac.begin());
}
}
return result;
}
error_code DS28C36::authenticatedSha2WriteMemory(int pageNum,
SecretNum secretNum,
Page::const_span page) {
if (pageNum < 0 || pageNum >= memoryPages) {
return make_error_code(InvalidParameterError);
}
uint_least8_t buffer[1 + Page::size];
buffer[0] = (secretNum << 6) | pageNum;
copy(page.begin(), page.end(), buffer + 1);
error_code result = writeCommand(0x99, buffer);
if (!result) {
sleep(writeMemoryTimeMs + (2 * sha256ComputationTimeMs));
result = readFixedLengthResponse(make_span(buffer, 1));
if (!result) {
result = convertResultByte(buffer[0]);
}
}
return result;
}
error_code DS28C36::computeAndLockSha2Secret(int pageNum, SecretNum msecretNum,
SecretNum dsecretNum,
bool writeProtectEnable) {
// User pages only
if (pageNum < 0 || pageNum > 15) {
return make_error_code(InvalidParameterError);
}
uint_least8_t buffer[] = {
static_cast<uint_least8_t>((dsecretNum << 6) | (msecretNum << 4) |
pageNum),
static_cast<uint_least8_t>(writeProtectEnable ? 0x80 : 0x00)};
error_code result = writeCommand(0x3C, buffer);
if (!result) {
sleep(sha256ComputationTimeMs +
((writeProtectEnable ? 2 : 1) * writeMemoryTimeMs));
result = readFixedLengthResponse(make_span(buffer, 1));
if (!result) {
result = convertResultByte(buffer[0]);
}
}
return result;
}
error_code DS28C36::generateEcc256KeyPair(KeyNum keyNum,
bool writeProtectEnable) {
if (keyNum == KeyNumS) {
return make_error_code(InvalidParameterError);
}
uint_least8_t buffer = keyNum;
if (writeProtectEnable) {
buffer |= 0x80;
}
error_code result = writeCommand(0xCB, make_span(&buffer, 1));
if (!result) {
sleep(generateEccKeyPairTimeMs);
result = readFixedLengthResponse(make_span(&buffer, 1));
if (!result) {
result = convertResultByte(buffer);
}
}
return result;
}
error_code DS28C36::computeMultiblockHash(bool firstBlock, bool lastBlock,
span<const uint_least8_t> data) {
const span<const uint_least8_t>::index_type maxDataSize = 64;
if (data.size() < 1 || data.size() > maxDataSize) {
return make_error_code(InvalidParameterError);
}
uint_least8_t buffer[1 + maxDataSize];
buffer[0] = 0;
if (firstBlock) {
buffer[0] |= 0x40;
}
if (lastBlock) {
buffer[0] |= 0x80;
}
copy(data.begin(), data.end(), buffer + 1);
error_code result = writeCommand(0x33, make_span(buffer, data.size() + 1));
if (!result) {
sleep(sha256ComputationTimeMs);
result = readFixedLengthResponse(make_span(buffer, 1));
if (!result) {
result = convertResultByte(buffer[0]);
}
}
return result;
}
error_code DS28C36::verifyEcdsaSignature(KeyNum keyNum, HashType hashType,
Signature::const_span signature,
PioState pioa, PioState piob) {
uint_least8_t buffer[1 + 2 * Scalar::size];
buffer[0] = keyNum | (hashType << 2);
if (pioa != Unchanged) {
buffer[0] |= 0x20;
}
if (pioa == Conducting) {
buffer[0] |= 0x10;
}
if (piob != Unchanged) {
buffer[0] |= 0x80;
}
if (piob == Conducting) {
buffer[0] |= 0x40;
}
uint_least8_t * bufferIt =
copy(signature.r.begin(), signature.r.end(), buffer + 1);
copy(signature.s.begin(), signature.s.end(), bufferIt);
error_code result = writeCommand(0x59, buffer);
if (!result) {
sleep(verifyEsdsaSignatureOrComputeEcdhTimeMs +
((hashType == DataInBuffer) ? sha256ComputationTimeMs : 0));
result = readFixedLengthResponse(make_span(buffer, 1));
if (!result) {
result = convertResultByte(buffer[0]);
}
}
return result;
}
error_code
DS28C36::authenticateEcdsaPublicKey(bool authWrites, bool ecdh, KeyNum keyNum,
int csOffset,
Signature::const_span signature) {
if (((keyNum != KeyNumA) && (keyNum != KeyNumB)) || (csOffset < 0) ||
(csOffset > 31)) {
return make_error_code(InvalidParameterError);
}
uint_least8_t buffer[1 + 2 * Scalar::size];
buffer[0] = (csOffset << 3) | (keyNum << 2);
if (ecdh) {
buffer[0] |= 0x02;
}
if (authWrites) {
buffer[0] |= 0x01;
}
uint_least8_t * bufferIt =
copy(signature.r.begin(), signature.r.end(), buffer + 1);
copy(signature.s.begin(), signature.s.end(), bufferIt);
error_code result = writeCommand(0xA8, buffer);
if (!result) {
sleep((ecdh ? 2 : 1) * verifyEsdsaSignatureOrComputeEcdhTimeMs);
result = readFixedLengthResponse(make_span(buffer, 1));
if (!result) {
result = convertResultByte(buffer[0]);
}
}
return result;
}
error_code DS28C36::authenticatedEcdsaWriteMemory(int pageNum,
Page::const_span page) {
if (pageNum < 0 || pageNum >= memoryPages) {
return make_error_code(InvalidParameterError);
}
uint_least8_t buffer[1 + Page::size];
buffer[0] = pageNum;
copy(page.begin(), page.end(), buffer + 1);
error_code result = writeCommand(0x89, buffer);
if (!result) {
sleep(verifyEsdsaSignatureOrComputeEcdhTimeMs + writeMemoryTimeMs +
sha256ComputationTimeMs);
result = readFixedLengthResponse(make_span(buffer, 1));
if (!result) {
result = convertResultByte(buffer[0]);
}
}
return result;
}
error_code DS28C36::writeCommand(uint_least8_t command,
span<const uint_least8_t> parameters) {
error_code result = master->start(address_);
if (result) {
master->stop();
return result;
}
result = master->writeByte(command);
if (result) {
master->stop();
return result;
}
if (!parameters.empty()) {
result = master->writeByte(static_cast<uint_least8_t>(parameters.size()));
if (result) {
master->stop();
return result;
}
result = master->writeBlock(parameters);
if (result) {
master->stop();
return result;
}
}
result = master->stop();
return result;
}
error_code DS28C36::readVariableLengthResponse(span<uint_least8_t> & response) {
error_code result = master->start(address_ | 1);
if (result) {
master->stop();
return result;
}
uint_least8_t length;
result = master->readByte(I2CMaster::Ack, length);
if (result) {
master->stop();
return result;
}
if (length > response.size()) {
master->stop();
return make_error_code(InvalidResponseError);
}
response = response.first(length);
if (!response.empty()) {
result = master->readBlock(I2CMaster::Nack, response);
if (result) {
master->stop();
return result;
}
}
result = master->stop();
return result;
}
error_code DS28C36::readFixedLengthResponse(span<uint_least8_t> response) {
const span<uint_least8_t>::index_type requestedResponseSize = response.size();
error_code result = readVariableLengthResponse(response);
if (!result && response.size() != requestedResponseSize) {
result = make_error_code(InvalidResponseError);
}
return result;
}
const error_category & DS28C36::errorCategory() {
static class : public error_category {
public:
virtual const char * name() const { return "DS28C36"; }
virtual std::string message(int condition) const {
switch (condition) {
case ProtectionError:
return "Protection Error";
case InvalidParameterError:
return "Invalid Parameter Error";
case InvalidSequenceError:
return "Invalid Sequence Error";
case InvalidEcdsaInputOrResultError:
return "Invalid ECDSA Input or Result Error";
case AuthenticationError:
return "Authentication Error";
case InvalidResponseError:
return "Invalid Response Error";
default:
return defaultErrorMessage(condition);
}
}
} instance;
return instance;
}
error_code DS2476::generateEcdsaSignature(KeyNum keyNum,
Signature::span signature) {
if (keyNum == KeyNumS) {
return make_error_code(InvalidParameterError);
}
const uint_least8_t parameter = keyNum;
error_code result = writeCommand(0x1E, make_span(¶meter, 1));
if (!result) {
sleep(generateEcdsaSignatureTimeMs);
uint_least8_t response[1 + 2 * Scalar::size];
result = readFixedLengthResponse(response);
if (!result) {
result = convertResultByte(response[0]);
const uint_least8_t * begin = response + 1;
const uint_least8_t * end = begin + signature.s.size();
copy(begin, end, signature.s.begin());
begin = end;
end = begin + signature.r.size();
copy(begin, end, signature.r.begin());
}
}
return result;
}
error_code DS2476::computeSha2UniqueSecret(SecretNum msecretNum) {
uint_least8_t buffer = msecretNum << 4;
error_code result = writeCommand(0x55, make_span(&buffer, 1));
if (!result) {
sleep(sha256ComputationTimeMs);
result = readFixedLengthResponse(make_span(&buffer, 1));
if (!result) {
convertResultByte(buffer);
}
}
return result;
}
error_code DS2476::computeSha2Hmac(Page::span hmac) {
error_code result = writeCommand(0x2D);
if (!result) {
sleep(sha256ComputationTimeMs);
array<uint_least8_t, 1 + Page::size> response;
result = readFixedLengthResponse(response);
if (!result) {
result = convertResultByte(response[0]);
copy(response.begin() + 1, response.end(), hmac.begin());
}
}
return result;
}
error_code computeMultiblockHash(DS28C36 & ds28c36,
span<const uint_least8_t> data) {
error_code result;
span<const uint_least8_t>::index_type dataIdx = 0;
while (dataIdx < data.size() && !result) {
const span<const uint_least8_t>::index_type remainingSize =
data.size() - dataIdx;
const span<const uint_least8_t>::index_type chunkSize =
std::min<span<const uint_least8_t>::index_type>(remainingSize, 64);
result =
ds28c36.computeMultiblockHash(dataIdx == 0, remainingSize == chunkSize,
data.subspan(dataIdx, chunkSize));
dataIdx += chunkSize;
}
return result;
}
error_code verifyEcdsaSignature(DS28C36 & ds28c36, DS28C36::KeyNum publicKey,
span<const uint_least8_t> data,
Signature::const_span signature,
DS28C36::PioState pioa,
DS28C36::PioState piob) {
error_code result = computeMultiblockHash(ds28c36, data);
if (!result) {
result = ds28c36.verifyEcdsaSignature(publicKey, DS28C36::THASH, signature,
pioa, piob);
}
return result;
}
error_code verifyEcdsaSignature(DS28C36 & ds28c36,
PublicKey::const_span publicKey,
span<const uint_least8_t> data,
Signature::const_span signature,
DS28C36::PioState pioa,
DS28C36::PioState piob) {
error_code result =
ds28c36.writeMemory(DS28C36::publicKeySxPage, publicKey.x);
if (!result) {
result = ds28c36.writeMemory(DS28C36::publicKeySyPage, publicKey.y);
}
if (!result) {
result = verifyEcdsaSignature(ds28c36, DS28C36::KeyNumS, data, signature,
pioa, piob);
}
return result;
}
error_code readRomIdAndManId(DS28C36 & ds28c36, RomId::span romId,
ManId::span manId) {
DS28C36::Page::array page;
error_code result = ds28c36.readMemory(DS28C36::romOptionsPage, page);
if (!result) {
const DS28C36::RomOptions romOptions(page);
copy(romOptions.romId(), romId);
copy(romOptions.manId(), manId);
}
return result;
}
error_code enableCoprocessor(DS2476 & ds2476) {
DS2476::Page::array page;
error_code result = ds2476.readMemory(DS2476::gpioControlPage, page);
if (!result) {
DS2476::GpioControl gpioControl(page);
if (!gpioControl.pioaConducting()) {
gpioControl.setPioaConducting(true);
result = ds2476.writeMemory(DS2476::gpioControlPage, page);
}
}
return result;
}
error_code enableRomId(DS2476 & ds2476) {
DS2476::Page::array page;
error_code result = ds2476.readMemory(DS2476::romOptionsPage, page);
if (!result) {
DS2476::RomOptions romOptions(page);
if (!romOptions.romBlockDisable()) {
romOptions.setRomBlockDisable(true);
result = ds2476.writeMemory(DS2476::romOptionsPage, page);
}
}
return result;
}
static void setAnonymous(RomId::span romId) {
std::fill(romId.begin(), romId.end(), 0xFF);
}
DS28C36::PageAuthenticationData &
DS28C36::PageAuthenticationData::setAnonymousRomId() {
setAnonymous(romId());
return *this;
}
DS28C36::EncryptionHmacData & DS28C36::EncryptionHmacData::setAnonymousRomId() {
setAnonymous(romId());
return *this;
}
} // namespace MaximInterfaceDevices