src/setup_payload/ManualSetupPayloadGenerator.cpp - third_party/github/project-chip/connectedhomeip - Git at Google

 /**
  *
  *    Copyright (c) 2020 Project CHIP Authors
  *
  *    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.
  */

 /**
  *    @file
  *      This file describes a Manual Entry Code Generator.
  *
  */

 #include "ManualSetupPayloadGenerator.h"

 #include <inttypes.h>
 #include <limits>

 #include <lib/support/logging/CHIPLogging.h>
 #include <lib/support/verhoeff/Verhoeff.h>

 namespace chip {

 static uint32_t chunk1PayloadRepresentation(const PayloadContents & payload)
 {
     /* <1 digit> Represents:
      *     - <bits 1..0> Discriminator <bits 11.10>
      *     - <bit 2> VID/PID present flag
      */

     constexpr int kDiscriminatorShift = (kManualSetupDiscriminatorFieldLengthInBits - kManualSetupChunk1DiscriminatorMsbitsLength);
     constexpr uint32_t kDiscriminatorMask = (1 << kManualSetupChunk1DiscriminatorMsbitsLength) - 1;

     static_assert(kManualSetupChunk1VidPidPresentBitPos >=
                       kManualSetupChunk1DiscriminatorMsbitsPos + kManualSetupChunk1DiscriminatorMsbitsLength,
                   "Discriminator won't fit");

     uint32_t discriminatorChunk = (payload.discriminator.GetShortValue() >> kDiscriminatorShift) & kDiscriminatorMask;
     uint32_t vidPidPresentFlag  = payload.commissioningFlow != CommissioningFlow::kStandard ? 1 : 0;

     uint32_t result = (discriminatorChunk << kManualSetupChunk1DiscriminatorMsbitsPos) |
         (vidPidPresentFlag << kManualSetupChunk1VidPidPresentBitPos);

     return result;
 }

 static uint32_t chunk2PayloadRepresentation(const PayloadContents & payload)
 {
     /* <5 digits> Represents:
      *     - <bits 13..0> PIN Code <bits 13..0>
      *     - <bits 15..14> Discriminator <bits 9..8>
      */

     constexpr uint32_t kDiscriminatorMask = (1 << kManualSetupChunk2DiscriminatorLsbitsLength) - 1;
     constexpr uint32_t kPincodeMask       = (1 << kManualSetupChunk2PINCodeLsbitsLength) - 1;

     uint32_t discriminatorChunk = payload.discriminator.GetShortValue() & kDiscriminatorMask;

     uint32_t result = ((payload.setUpPINCode & kPincodeMask) << kManualSetupChunk2PINCodeLsbitsPos) |
         (discriminatorChunk << kManualSetupChunk2DiscriminatorLsbitsPos);

     return result;
 }

 static uint32_t chunk3PayloadRepresentation(const PayloadContents & payload)
 {
     /* <4 digits> Represents:
      *     - <bits 12..0> PIN Code <bits 26..14>
      */

     constexpr int kPincodeShift     = (kSetupPINCodeFieldLengthInBits - kManualSetupChunk3PINCodeMsbitsLength);
     constexpr uint32_t kPincodeMask = (1 << kManualSetupChunk3PINCodeMsbitsLength) - 1;

     uint32_t result = ((payload.setUpPINCode >> kPincodeShift) & kPincodeMask) << kManualSetupChunk3PINCodeMsbitsPos;

     return result;
 }

 static CHIP_ERROR decimalStringWithPadding(MutableCharSpan buffer, uint32_t number)
 {
     int len    = static_cast<int>(buffer.size() - 1);
     int retval = snprintf(buffer.data(), buffer.size(), "%0*" PRIu32, len, number);

     return (retval >= static_cast<int>(buffer.size())) ? CHIP_ERROR_BUFFER_TOO_SMALL : CHIP_NO_ERROR;
 }

 CHIP_ERROR ManualSetupPayloadGenerator::payloadDecimalStringRepresentation(MutableCharSpan & outBuffer)
 {
     static_assert(kManualSetupCodeChunk1CharLength + kManualSetupCodeChunk2CharLength + kManualSetupCodeChunk3CharLength ==
                       kManualSetupShortCodeCharLength,
                   "Manual code length mismatch (short)");
     static_assert(kManualSetupShortCodeCharLength + kManualSetupVendorIdCharLength + kManualSetupProductIdCharLength ==
                       kManualSetupLongCodeCharLength,
                   "Manual code length mismatch (long)");
     static_assert(kManualSetupChunk1DiscriminatorMsbitsLength + kManualSetupChunk2DiscriminatorLsbitsLength ==
                       kManualSetupDiscriminatorFieldLengthInBits,
                   "Discriminator won't fit");
     static_assert(kManualSetupChunk2PINCodeLsbitsLength + kManualSetupChunk3PINCodeMsbitsLength == kSetupPINCodeFieldLengthInBits,
                   "PIN code won't fit");

     if (!mAllowInvalidPayload && !mPayloadContents.isValidManualCode())
     {
         ChipLogError(SetupPayload, "Failed encoding invalid payload");
         return CHIP_ERROR_INVALID_ARGUMENT;
     }

     bool useLongCode = (mPayloadContents.commissioningFlow != CommissioningFlow::kStandard) && !mForceShortCode;

     // Add two for the check digit and null terminator.
     if ((useLongCode && outBuffer.size() < kManualSetupLongCodeCharLength + 2) ||
         (!useLongCode && outBuffer.size() < kManualSetupShortCodeCharLength + 2))
     {
         ChipLogError(SetupPayload, "Failed encoding payload to buffer");
         return CHIP_ERROR_BUFFER_TOO_SMALL;
     }

     uint32_t chunk1 = chunk1PayloadRepresentation(mPayloadContents);
     uint32_t chunk2 = chunk2PayloadRepresentation(mPayloadContents);
     uint32_t chunk3 = chunk3PayloadRepresentation(mPayloadContents);

     size_t offset = 0;

     // Add one to the length of each chunk, since snprintf writes a null terminator.
     ReturnErrorOnFailure(decimalStringWithPadding(outBuffer.SubSpan(offset, kManualSetupCodeChunk1CharLength + 1), chunk1));
     offset += kManualSetupCodeChunk1CharLength;
     ReturnErrorOnFailure(decimalStringWithPadding(outBuffer.SubSpan(offset, kManualSetupCodeChunk2CharLength + 1), chunk2));
     offset += kManualSetupCodeChunk2CharLength;
     ReturnErrorOnFailure(decimalStringWithPadding(outBuffer.SubSpan(offset, kManualSetupCodeChunk3CharLength + 1), chunk3));
     offset += kManualSetupCodeChunk3CharLength;

     if (useLongCode)
     {
         ReturnErrorOnFailure(
             decimalStringWithPadding(outBuffer.SubSpan(offset, kManualSetupVendorIdCharLength + 1), mPayloadContents.vendorID));
         offset += kManualSetupVendorIdCharLength;
         ReturnErrorOnFailure(
             decimalStringWithPadding(outBuffer.SubSpan(offset, kManualSetupProductIdCharLength + 1), mPayloadContents.productID));
         offset += kManualSetupProductIdCharLength;
     }

     int checkDigit = Verhoeff10::CharToVal(Verhoeff10::ComputeCheckChar(outBuffer.data()));
     ReturnErrorOnFailure(decimalStringWithPadding(outBuffer.SubSpan(offset, 2), static_cast<uint32_t>(checkDigit)));
     offset += 1;

     // Reduce outBuffer span size to be the size of written data and to not include null-terminator.
     outBuffer.reduce_size(offset);

     return CHIP_NO_ERROR;
 }

 CHIP_ERROR ManualSetupPayloadGenerator::payloadDecimalStringRepresentation(std::string & outDecimalString)
 {
     // One extra char for the check digit, another for the null terminator.
     char decimalString[kManualSetupLongCodeCharLength + 1 + 1] = "";
     MutableCharSpan outBuffer(decimalString);

     ReturnErrorOnFailure(payloadDecimalStringRepresentation(outBuffer));
     outDecimalString.assign(decimalString);

     return CHIP_NO_ERROR;
 }

 } // namespace chip
	/**
	*
	* Copyright (c) 2020 Project CHIP Authors
	*
	* 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.
	*/

	/**
	* @file
	* This file describes a Manual Entry Code Generator.
	*
	*/

	#include "ManualSetupPayloadGenerator.h"

	#include <inttypes.h>
	#include <limits>

	#include <lib/support/logging/CHIPLogging.h>
	#include <lib/support/verhoeff/Verhoeff.h>

	namespace chip {

	static uint32_t chunk1PayloadRepresentation(const PayloadContents & payload)
	{
	/* <1 digit> Represents:
	* - <bits 1..0> Discriminator <bits 11.10>
	* - <bit 2> VID/PID present flag
	*/

	constexpr int kDiscriminatorShift = (kManualSetupDiscriminatorFieldLengthInBits - kManualSetupChunk1DiscriminatorMsbitsLength);
	constexpr uint32_t kDiscriminatorMask = (1 << kManualSetupChunk1DiscriminatorMsbitsLength) - 1;

	static_assert(kManualSetupChunk1VidPidPresentBitPos >=
	kManualSetupChunk1DiscriminatorMsbitsPos + kManualSetupChunk1DiscriminatorMsbitsLength,
	"Discriminator won't fit");

	uint32_t discriminatorChunk = (payload.discriminator.GetShortValue() >> kDiscriminatorShift) & kDiscriminatorMask;
	uint32_t vidPidPresentFlag = payload.commissioningFlow != CommissioningFlow::kStandard ? 1 : 0;

	uint32_t result = (discriminatorChunk << kManualSetupChunk1DiscriminatorMsbitsPos) \|
	(vidPidPresentFlag << kManualSetupChunk1VidPidPresentBitPos);

	return result;
	}

	static uint32_t chunk2PayloadRepresentation(const PayloadContents & payload)
	{
	/* <5 digits> Represents:
	* - <bits 13..0> PIN Code <bits 13..0>
	* - <bits 15..14> Discriminator <bits 9..8>
	*/

	constexpr uint32_t kDiscriminatorMask = (1 << kManualSetupChunk2DiscriminatorLsbitsLength) - 1;
	constexpr uint32_t kPincodeMask = (1 << kManualSetupChunk2PINCodeLsbitsLength) - 1;

	uint32_t discriminatorChunk = payload.discriminator.GetShortValue() & kDiscriminatorMask;

	uint32_t result = ((payload.setUpPINCode & kPincodeMask) << kManualSetupChunk2PINCodeLsbitsPos) \|
	(discriminatorChunk << kManualSetupChunk2DiscriminatorLsbitsPos);

	return result;
	}

	static uint32_t chunk3PayloadRepresentation(const PayloadContents & payload)
	{
	/* <4 digits> Represents:
	* - <bits 12..0> PIN Code <bits 26..14>
	*/

	constexpr int kPincodeShift = (kSetupPINCodeFieldLengthInBits - kManualSetupChunk3PINCodeMsbitsLength);
	constexpr uint32_t kPincodeMask = (1 << kManualSetupChunk3PINCodeMsbitsLength) - 1;

	uint32_t result = ((payload.setUpPINCode >> kPincodeShift) & kPincodeMask) << kManualSetupChunk3PINCodeMsbitsPos;

	return result;
	}

	static CHIP_ERROR decimalStringWithPadding(MutableCharSpan buffer, uint32_t number)
	{
	int len = static_cast<int>(buffer.size() - 1);
	int retval = snprintf(buffer.data(), buffer.size(), "%0*" PRIu32, len, number);

	return (retval >= static_cast<int>(buffer.size())) ? CHIP_ERROR_BUFFER_TOO_SMALL : CHIP_NO_ERROR;
	}

	CHIP_ERROR ManualSetupPayloadGenerator::payloadDecimalStringRepresentation(MutableCharSpan & outBuffer)
	{
	static_assert(kManualSetupCodeChunk1CharLength + kManualSetupCodeChunk2CharLength + kManualSetupCodeChunk3CharLength ==
	kManualSetupShortCodeCharLength,
	"Manual code length mismatch (short)");
	static_assert(kManualSetupShortCodeCharLength + kManualSetupVendorIdCharLength + kManualSetupProductIdCharLength ==
	kManualSetupLongCodeCharLength,
	"Manual code length mismatch (long)");
	static_assert(kManualSetupChunk1DiscriminatorMsbitsLength + kManualSetupChunk2DiscriminatorLsbitsLength ==
	kManualSetupDiscriminatorFieldLengthInBits,
	"Discriminator won't fit");
	static_assert(kManualSetupChunk2PINCodeLsbitsLength + kManualSetupChunk3PINCodeMsbitsLength == kSetupPINCodeFieldLengthInBits,
	"PIN code won't fit");

	if (!mAllowInvalidPayload && !mPayloadContents.isValidManualCode())
	{
	ChipLogError(SetupPayload, "Failed encoding invalid payload");
	return CHIP_ERROR_INVALID_ARGUMENT;
	}

	bool useLongCode = (mPayloadContents.commissioningFlow != CommissioningFlow::kStandard) && !mForceShortCode;

	// Add two for the check digit and null terminator.
	if ((useLongCode && outBuffer.size() < kManualSetupLongCodeCharLength + 2) \|\|
	(!useLongCode && outBuffer.size() < kManualSetupShortCodeCharLength + 2))
	{
	ChipLogError(SetupPayload, "Failed encoding payload to buffer");
	return CHIP_ERROR_BUFFER_TOO_SMALL;
	}

	uint32_t chunk1 = chunk1PayloadRepresentation(mPayloadContents);
	uint32_t chunk2 = chunk2PayloadRepresentation(mPayloadContents);
	uint32_t chunk3 = chunk3PayloadRepresentation(mPayloadContents);

	size_t offset = 0;

	// Add one to the length of each chunk, since snprintf writes a null terminator.
	ReturnErrorOnFailure(decimalStringWithPadding(outBuffer.SubSpan(offset, kManualSetupCodeChunk1CharLength + 1), chunk1));
	offset += kManualSetupCodeChunk1CharLength;
	ReturnErrorOnFailure(decimalStringWithPadding(outBuffer.SubSpan(offset, kManualSetupCodeChunk2CharLength + 1), chunk2));
	offset += kManualSetupCodeChunk2CharLength;
	ReturnErrorOnFailure(decimalStringWithPadding(outBuffer.SubSpan(offset, kManualSetupCodeChunk3CharLength + 1), chunk3));
	offset += kManualSetupCodeChunk3CharLength;

	if (useLongCode)
	{
	ReturnErrorOnFailure(
	decimalStringWithPadding(outBuffer.SubSpan(offset, kManualSetupVendorIdCharLength + 1), mPayloadContents.vendorID));
	offset += kManualSetupVendorIdCharLength;
	ReturnErrorOnFailure(
	decimalStringWithPadding(outBuffer.SubSpan(offset, kManualSetupProductIdCharLength + 1), mPayloadContents.productID));
	offset += kManualSetupProductIdCharLength;
	}

	int checkDigit = Verhoeff10::CharToVal(Verhoeff10::ComputeCheckChar(outBuffer.data()));
	ReturnErrorOnFailure(decimalStringWithPadding(outBuffer.SubSpan(offset, 2), static_cast<uint32_t>(checkDigit)));
	offset += 1;

	// Reduce outBuffer span size to be the size of written data and to not include null-terminator.
	outBuffer.reduce_size(offset);

	return CHIP_NO_ERROR;
	}

	CHIP_ERROR ManualSetupPayloadGenerator::payloadDecimalStringRepresentation(std::string & outDecimalString)
	{
	// One extra char for the check digit, another for the null terminator.
	char decimalString[kManualSetupLongCodeCharLength + 1 + 1] = "";
	MutableCharSpan outBuffer(decimalString);

	ReturnErrorOnFailure(payloadDecimalStringRepresentation(outBuffer));
	outDecimalString.assign(decimalString);

	return CHIP_NO_ERROR;
	}

	} // namespace chip