src/lib/asn1/ASN1Writer.cpp - third_party/github/project-chip/connectedhomeip - Git at Google

 /*
  *
  *    Copyright (c) 2020-2021 Project CHIP Authors
  *    Copyright (c) 2013-2017 Nest Labs, Inc.
  *    All rights reserved.
  *
  *    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 implements an object for writing Abstract Syntax
  *      Notation One (ASN.1) encoded data.
  *
  */

 #ifndef __STDC_LIMIT_MACROS
 #define __STDC_LIMIT_MACROS
 #endif
 #include <ctype.h>
 #include <stdint.h>
 #include <stdio.h>
 #include <stdlib.h>
 #include <string.h>

 #include <lib/asn1/ASN1.h>
 #include <lib/core/CHIPCore.h>
 #include <lib/core/CHIPEncoding.h>
 #include <lib/core/CHIPTLV.h>
 #include <lib/support/CodeUtils.h>
 #include <lib/support/SafeInt.h>

 namespace chip {
 namespace ASN1 {

 using namespace chip::Encoding;

 enum
 {
     kLengthFieldReserveSize = 1,
     kUnknownLength          = -1,
     kUnknownLengthMarker    = 0xFF
 };

 void ASN1Writer::Init(uint8_t * buf, size_t maxLen)
 {
     mBuf                 = buf;
     mWritePoint          = buf;
     mBufEnd              = buf + maxLen;
     mDeferredLengthCount = 0;
 }

 void ASN1Writer::InitNullWriter()
 {
     mBuf                 = nullptr;
     mWritePoint          = nullptr;
     mBufEnd              = nullptr;
     mDeferredLengthCount = 0;
 }

 size_t ASN1Writer::GetLengthWritten() const
 {
     return (mBuf != nullptr) ? static_cast<size_t>(mWritePoint - mBuf) : 0;
 }

 CHIP_ERROR ASN1Writer::PutInteger(int64_t val)
 {
     uint8_t encodedVal[sizeof(int64_t)];
     uint8_t valStart, valLen;

     BigEndian::Put64(encodedVal, static_cast<uint64_t>(val));

     for (valStart = 0; valStart < 7; valStart++)
     {
         if (encodedVal[valStart] == 0x00 && (encodedVal[valStart + 1] & 0x80) == 0)
             continue;
         if (encodedVal[valStart] == 0xFF && (encodedVal[valStart + 1] & 0x80) == 0x80)
             continue;
         break;
     }
     valLen = static_cast<uint8_t>(8 - valStart);

     return PutValue(kASN1TagClass_Universal, kASN1UniversalTag_Integer, false, encodedVal + valStart, valLen);
 }

 CHIP_ERROR ASN1Writer::PutBoolean(bool val)
 {
     // Do nothing for a null writer.
     VerifyOrReturnError(mBuf != nullptr, CHIP_NO_ERROR);

     ReturnErrorOnFailure(EncodeHead(kASN1TagClass_Universal, kASN1UniversalTag_Boolean, false, 1));

     *mWritePoint++ = (val) ? 0xFF : 0;

     return CHIP_NO_ERROR;
 }

 CHIP_ERROR ASN1Writer::PutObjectId(const uint8_t * val, uint16_t valLen)
 {
     return PutValue(kASN1TagClass_Universal, kASN1UniversalTag_ObjectId, false, val, valLen);
 }

 CHIP_ERROR ASN1Writer::PutString(uint8_t tag, const char * val, uint16_t valLen)
 {
     return PutValue(kASN1TagClass_Universal, tag, false, (const uint8_t *) val, valLen);
 }

 CHIP_ERROR ASN1Writer::PutOctetString(const uint8_t * val, uint16_t valLen)
 {
     return PutValue(kASN1TagClass_Universal, kASN1UniversalTag_OctetString, false, val, valLen);
 }

 CHIP_ERROR ASN1Writer::PutOctetString(uint8_t cls, uint8_t tag, const uint8_t * val, uint16_t valLen)
 {
     return PutValue(cls, tag, false, val, valLen);
 }

 CHIP_ERROR ASN1Writer::PutOctetString(uint8_t cls, uint8_t tag, chip::TLV::TLVReader & tlvReader)
 {
     return PutValue(cls, tag, false, tlvReader);
 }

 static uint8_t ReverseBits(uint8_t v)
 {
     // swap adjacent bits
     v = static_cast<uint8_t>((v >> 1) & 0x55) | static_cast<uint8_t>((v & 0x55) << 1);
     // swap adjacent bit pairs
     v = static_cast<uint8_t>((v >> 2) & 0x33) | static_cast<uint8_t>((v & 0x33) << 2);
     // swap nibbles
     v = static_cast<uint8_t>(v >> 4) | static_cast<uint8_t>(v << 4);
     return v;
 }

 static uint8_t HighestBit(uint32_t v)
 {
     uint32_t highestBit = 0;

     if (v > 0xFFFF)
     {
         highestBit = 16;
         v >>= 16;
     }
     if (v > 0xFF)
     {
         highestBit |= 8;
         v >>= 8;
     }
     if (v > 0xF)
     {
         highestBit |= 4;
         v >>= 4;
     }
     if (v > 0x3)
     {
         highestBit |= 2;
         v >>= 2;
     }
     highestBit |= (v >> 1);

     return static_cast<uint8_t>(highestBit);
 }

 CHIP_ERROR ASN1Writer::PutBitString(uint32_t val)
 {
     uint8_t len;

     // Do nothing for a null writer.
     VerifyOrReturnError(mBuf != nullptr, CHIP_NO_ERROR);

     if (val == 0)
         len = 1;
     else if (val < 256)
         len = 2;
     else if (val < 65536)
         len = 3;
     else if (val < (1 << 24))
         len = 4;
     else
         len = 5;

     ReturnErrorOnFailure(EncodeHead(kASN1TagClass_Universal, kASN1UniversalTag_BitString, false, len));

     if (val == 0)
     {
         mWritePoint[0] = 0;
     }
     else
     {
         mWritePoint[1] = ReverseBits(static_cast<uint8_t>(val));
         if (len >= 3)
         {
             val >>= 8;
             mWritePoint[2] = ReverseBits(static_cast<uint8_t>(val));
             if (len >= 4)
             {
                 val >>= 8;
                 mWritePoint[3] = ReverseBits(static_cast<uint8_t>(val));
                 if (len == 5)
                 {
                     val >>= 8;
                     mWritePoint[4] = ReverseBits(static_cast<uint8_t>(val));
                 }
             }
         }
         mWritePoint[0] = static_cast<uint8_t>(7 - HighestBit(val));
     }

     mWritePoint += len;

     return CHIP_NO_ERROR;
 }

 CHIP_ERROR ASN1Writer::PutBitString(uint8_t unusedBitCount, const uint8_t * encodedBits, uint16_t encodedBitsLen)
 {
     // Do nothing for a null writer.
     VerifyOrReturnError(mBuf != nullptr, CHIP_NO_ERROR);

     ReturnErrorOnFailure(EncodeHead(kASN1TagClass_Universal, kASN1UniversalTag_BitString, false, encodedBitsLen + 1));

     *mWritePoint++ = unusedBitCount;

     WriteData(encodedBits, encodedBitsLen);

     return CHIP_NO_ERROR;
 }

 CHIP_ERROR ASN1Writer::PutBitString(uint8_t unusedBitCount, chip::TLV::TLVReader & tlvReader)
 {
     ByteSpan encodedBits;

     // Do nothing for a null writer.
     VerifyOrReturnError(mBuf != nullptr, CHIP_NO_ERROR);

     ReturnErrorOnFailure(tlvReader.Get(encodedBits));

     VerifyOrReturnError(CanCastTo<int32_t>(encodedBits.size() + 1), ASN1_ERROR_LENGTH_OVERFLOW);

     ReturnErrorOnFailure(
         EncodeHead(kASN1TagClass_Universal, kASN1UniversalTag_BitString, false, static_cast<int32_t>(encodedBits.size() + 1)));

     *mWritePoint++ = unusedBitCount;

     WriteData(encodedBits.data(), encodedBits.size());

     return CHIP_NO_ERROR;
 }

 CHIP_ERROR ASN1Writer::PutTime(const ASN1UniversalTime & val)
 {
     char buf[ASN1UniversalTime::kASN1TimeStringMaxLength];
     MutableCharSpan bufSpan(buf);
     uint8_t tag;

     ReturnErrorOnFailure(val.ExportTo_ASN1_TIME_string(bufSpan));

     if (val.Year >= 2050)
     {
         tag = kASN1UniversalTag_GeneralizedTime;
     }
     else
     {
         tag = kASN1UniversalTag_UTCTime;
     }
     return PutValue(kASN1TagClass_Universal, tag, false, reinterpret_cast<uint8_t *>(buf), static_cast<uint16_t>(bufSpan.size()));
 }

 CHIP_ERROR ASN1Writer::PutNull()
 {
     return EncodeHead(kASN1TagClass_Universal, kASN1UniversalTag_Null, false, 0);
 }

 CHIP_ERROR ASN1Writer::PutConstructedType(const uint8_t * val, uint16_t valLen)
 {
     // Do nothing for a null writer.
     VerifyOrReturnError(mBuf != nullptr, CHIP_NO_ERROR);

     // Make sure we have enough space to write
     VerifyOrReturnError((mWritePoint + valLen) <= mBufEnd, ASN1_ERROR_OVERFLOW);

     WriteData(val, valLen);

     return CHIP_NO_ERROR;
 }

 CHIP_ERROR ASN1Writer::StartConstructedType(uint8_t cls, uint8_t tag)
 {
     return EncodeHead(cls, tag, true, kUnknownLength);
 }

 CHIP_ERROR ASN1Writer::EndConstructedType()
 {
     return WriteDeferredLength();
 }

 CHIP_ERROR ASN1Writer::StartEncapsulatedType(uint8_t cls, uint8_t tag, bool bitStringEncoding)
 {
     // Do nothing for a null writer.
     VerifyOrReturnError(mBuf != nullptr, CHIP_NO_ERROR);

     ReturnErrorOnFailure(EncodeHead(cls, tag, false, kUnknownLength));

     // If the encapsulating type is BIT STRING, encode the unused bit count field.  Since the BIT
     // STRING contains an ASN.1 DER encoding, and ASN.1 DER encodings are always multiples of 8 bits,
     // the unused bit count is always 0.
     if (bitStringEncoding)
     {
         VerifyOrReturnError(mWritePoint < mBufEnd, ASN1_ERROR_OVERFLOW);
         *mWritePoint++ = 0;
     }

     return CHIP_NO_ERROR;
 }

 CHIP_ERROR ASN1Writer::EndEncapsulatedType()
 {
     return WriteDeferredLength();
 }

 CHIP_ERROR ASN1Writer::PutValue(uint8_t cls, uint8_t tag, bool isConstructed, const uint8_t * val, uint16_t valLen)
 {
     // Do nothing for a null writer.
     VerifyOrReturnError(mBuf != nullptr, CHIP_NO_ERROR);

     ReturnErrorOnFailure(EncodeHead(cls, tag, isConstructed, valLen));

     WriteData(val, valLen);

     return CHIP_NO_ERROR;
 }

 CHIP_ERROR ASN1Writer::PutValue(uint8_t cls, uint8_t tag, bool isConstructed, chip::TLV::TLVReader & tlvReader)
 {
     ByteSpan val;

     // Do nothing for a null writer.
     VerifyOrReturnError(mBuf != nullptr, CHIP_NO_ERROR);

     ReturnErrorOnFailure(tlvReader.Get(val));

     VerifyOrReturnError(CanCastTo<int32_t>(val.size()), ASN1_ERROR_LENGTH_OVERFLOW);

     ReturnErrorOnFailure(EncodeHead(cls, tag, isConstructed, static_cast<int32_t>(val.size())));

     WriteData(val.data(), val.size());

     return CHIP_NO_ERROR;
 }

 CHIP_ERROR ASN1Writer::EncodeHead(uint8_t cls, uint8_t tag, bool isConstructed, int32_t len)
 {
     uint8_t bytesForLen;
     uint32_t totalLen;

     // Do nothing for a null writer.
     VerifyOrReturnError(mBuf != nullptr, CHIP_NO_ERROR);

     // Only tags < 31 supported. The implication of this is that encoded tags are exactly 1 byte long.
     VerifyOrReturnError(tag < 0x1F, ASN1_ERROR_UNSUPPORTED_ENCODING);

     // Only positive and kUnknownLength values are supported for len input.
     VerifyOrReturnError(len >= 0 || len == kUnknownLength, ASN1_ERROR_UNSUPPORTED_ENCODING);

     // Compute the number of bytes required to encode the length.
     bytesForLen = BytesForLength(len);

     // Make sure there's enough space to encode the entire value.
     // Note that the calculated total length doesn't overflow because `len` is a signed value (int32_t).
     // Note that if `len` is not kUnknownLength then it is non-negative (`len` >= 0).
     totalLen = 1 + bytesForLen + static_cast<uint32_t>(len != kUnknownLength ? len : 0);
     VerifyOrReturnError((mWritePoint + totalLen) <= mBufEnd, ASN1_ERROR_OVERFLOW);

     // Write the tag byte.
     *mWritePoint++ = cls | static_cast<uint8_t>(isConstructed ? 0x20 : 0) | tag;

     // Encode the length if it is known.
     if (len != kUnknownLength)
     {
         EncodeLength(mWritePoint, bytesForLen, len);
     }
     // ... otherwise place a marker in the first byte of the length to indicate that the length is unknown
     // and save a pointer to the length field in the deferred-length array.
     //
     // The deferred-length is an array of "pointers" to length fields for which the length of the
     // element was unknown at the time the element head was written. Examples include constructed
     // types such as SEQUENCE and SET, as well non-constructed types that encapsulate other ASN.1 types
     // (e.g. OCTET STRINGS that contain BER/DER encodings). The final lengths are filled in later,
     // at the time the encoding of the element is complete (e.g. when EndConstructed() is called).
     else
     {
         VerifyOrReturnError(mDeferredLengthCount < kMaxDeferredLengthDepth, ASN1_ERROR_INVALID_STATE);

         *mWritePoint                                     = kUnknownLengthMarker;
         mDeferredLengthLocations[mDeferredLengthCount++] = mWritePoint;
     }

     mWritePoint += bytesForLen;

     return CHIP_NO_ERROR;
 }

 CHIP_ERROR ASN1Writer::WriteDeferredLength()
 {
     // Do nothing for a null writer.
     VerifyOrReturnError(mBuf != nullptr, CHIP_NO_ERROR);

     VerifyOrReturnError(mDeferredLengthCount > 0, ASN1_ERROR_INVALID_STATE);

     uint8_t * lenField = mDeferredLengthLocations[mDeferredLengthCount - 1];

     VerifyOrReturnError(*lenField == kUnknownLengthMarker, ASN1_ERROR_INVALID_STATE);

     // Compute the length of the element's value.
     size_t elemLen = static_cast<size_t>((mWritePoint - lenField) - kLengthFieldReserveSize);

     VerifyOrReturnError(CanCastTo<int32_t>(elemLen), ASN1_ERROR_LENGTH_OVERFLOW);

     uint8_t bytesForLen = BytesForLength(static_cast<int32_t>(elemLen));

     // Move the element data if the number of bytes consumed by the final length field
     // is different than the space that was reserved for the field.
     if (bytesForLen != kLengthFieldReserveSize)
     {
         mWritePoint += (bytesForLen - kLengthFieldReserveSize);

         VerifyOrReturnError(mWritePoint <= mBufEnd, ASN1_ERROR_OVERFLOW);

         memmove(lenField + bytesForLen, lenField + kLengthFieldReserveSize, elemLen);
     }

     // Encode the final length of the element, overwriting the unknown length marker
     // in the process.
     EncodeLength(lenField, bytesForLen, static_cast<int32_t>(elemLen));

     mDeferredLengthCount--;

     return CHIP_NO_ERROR;
 }

 /**
  * Returns the number of bytes required to encode the length value.
  *
  * @param[in]   len     Parameter, which encoding length to be calculated.
  *
  * @return number of bytes required to encode the length value.
  */
 uint8_t ASN1Writer::BytesForLength(int32_t len)
 {
     if (len == kUnknownLength)
         return kLengthFieldReserveSize;
     if (len < 128)
         return 1;
     if (len < 256)
         return 2;
     if (len < 65536)
         return 3;
     if (len < (1 << 24))
         return 4;
     return 5;
 }

 void ASN1Writer::EncodeLength(uint8_t * buf, uint8_t bytesForLen, int32_t lenToEncode)
 {
     if (bytesForLen == 1)
     {
         buf[0] = static_cast<uint8_t>(lenToEncode);
     }
     else
     {
         --bytesForLen;
         buf[0] = 0x80 | bytesForLen;
         do
         {
             buf[bytesForLen] = static_cast<uint8_t>(lenToEncode);
             lenToEncode >>= 8;
         } while (--bytesForLen);
     }
 }

 void ASN1Writer::WriteData(const uint8_t * p, size_t len)
 {
     memcpy(mWritePoint, p, len);
     mWritePoint += len;
 }

 } // namespace ASN1
 } // namespace chip
	/*
	*
	* Copyright (c) 2020-2021 Project CHIP Authors
	* Copyright (c) 2013-2017 Nest Labs, Inc.
	* All rights reserved.
	*
	* 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 implements an object for writing Abstract Syntax
	* Notation One (ASN.1) encoded data.
	*
	*/

	#ifndef __STDC_LIMIT_MACROS
	#define __STDC_LIMIT_MACROS
	#endif
	#include <ctype.h>
	#include <stdint.h>
	#include <stdio.h>
	#include <stdlib.h>
	#include <string.h>

	#include <lib/asn1/ASN1.h>
	#include <lib/core/CHIPCore.h>
	#include <lib/core/CHIPEncoding.h>
	#include <lib/core/CHIPTLV.h>
	#include <lib/support/CodeUtils.h>
	#include <lib/support/SafeInt.h>

	namespace chip {
	namespace ASN1 {

	using namespace chip::Encoding;

	enum
	{
	kLengthFieldReserveSize = 1,
	kUnknownLength = -1,
	kUnknownLengthMarker = 0xFF
	};

	void ASN1Writer::Init(uint8_t * buf, size_t maxLen)
	{
	mBuf = buf;
	mWritePoint = buf;
	mBufEnd = buf + maxLen;
	mDeferredLengthCount = 0;
	}

	void ASN1Writer::InitNullWriter()
	{
	mBuf = nullptr;
	mWritePoint = nullptr;
	mBufEnd = nullptr;
	mDeferredLengthCount = 0;
	}

	size_t ASN1Writer::GetLengthWritten() const
	{
	return (mBuf != nullptr) ? static_cast<size_t>(mWritePoint - mBuf) : 0;
	}

	CHIP_ERROR ASN1Writer::PutInteger(int64_t val)
	{
	uint8_t encodedVal[sizeof(int64_t)];
	uint8_t valStart, valLen;

	BigEndian::Put64(encodedVal, static_cast<uint64_t>(val));

	for (valStart = 0; valStart < 7; valStart++)
	{
	if (encodedVal[valStart] == 0x00 && (encodedVal[valStart + 1] & 0x80) == 0)
	continue;
	if (encodedVal[valStart] == 0xFF && (encodedVal[valStart + 1] & 0x80) == 0x80)
	continue;
	break;
	}
	valLen = static_cast<uint8_t>(8 - valStart);

	return PutValue(kASN1TagClass_Universal, kASN1UniversalTag_Integer, false, encodedVal + valStart, valLen);
	}

	CHIP_ERROR ASN1Writer::PutBoolean(bool val)
	{
	// Do nothing for a null writer.
	VerifyOrReturnError(mBuf != nullptr, CHIP_NO_ERROR);

	ReturnErrorOnFailure(EncodeHead(kASN1TagClass_Universal, kASN1UniversalTag_Boolean, false, 1));

	*mWritePoint++ = (val) ? 0xFF : 0;

	return CHIP_NO_ERROR;
	}

	CHIP_ERROR ASN1Writer::PutObjectId(const uint8_t * val, uint16_t valLen)
	{
	return PutValue(kASN1TagClass_Universal, kASN1UniversalTag_ObjectId, false, val, valLen);
	}

	CHIP_ERROR ASN1Writer::PutString(uint8_t tag, const char * val, uint16_t valLen)
	{
	return PutValue(kASN1TagClass_Universal, tag, false, (const uint8_t *) val, valLen);
	}

	CHIP_ERROR ASN1Writer::PutOctetString(const uint8_t * val, uint16_t valLen)
	{
	return PutValue(kASN1TagClass_Universal, kASN1UniversalTag_OctetString, false, val, valLen);
	}

	CHIP_ERROR ASN1Writer::PutOctetString(uint8_t cls, uint8_t tag, const uint8_t * val, uint16_t valLen)
	{
	return PutValue(cls, tag, false, val, valLen);
	}

	CHIP_ERROR ASN1Writer::PutOctetString(uint8_t cls, uint8_t tag, chip::TLV::TLVReader & tlvReader)
	{
	return PutValue(cls, tag, false, tlvReader);
	}

	static uint8_t ReverseBits(uint8_t v)
	{
	// swap adjacent bits
	v = static_cast<uint8_t>((v >> 1) & 0x55) \| static_cast<uint8_t>((v & 0x55) << 1);
	// swap adjacent bit pairs
	v = static_cast<uint8_t>((v >> 2) & 0x33) \| static_cast<uint8_t>((v & 0x33) << 2);
	// swap nibbles
	v = static_cast<uint8_t>(v >> 4) \| static_cast<uint8_t>(v << 4);
	return v;
	}

	static uint8_t HighestBit(uint32_t v)
	{
	uint32_t highestBit = 0;

	if (v > 0xFFFF)
	{
	highestBit = 16;
	v >>= 16;
	}
	if (v > 0xFF)
	{
	highestBit \|= 8;
	v >>= 8;
	}
	if (v > 0xF)
	{
	highestBit \|= 4;
	v >>= 4;
	}
	if (v > 0x3)
	{
	highestBit \|= 2;
	v >>= 2;
	}
	highestBit \|= (v >> 1);

	return static_cast<uint8_t>(highestBit);
	}

	CHIP_ERROR ASN1Writer::PutBitString(uint32_t val)
	{
	uint8_t len;

	// Do nothing for a null writer.
	VerifyOrReturnError(mBuf != nullptr, CHIP_NO_ERROR);

	if (val == 0)
	len = 1;
	else if (val < 256)
	len = 2;
	else if (val < 65536)
	len = 3;
	else if (val < (1 << 24))
	len = 4;
	else
	len = 5;

	ReturnErrorOnFailure(EncodeHead(kASN1TagClass_Universal, kASN1UniversalTag_BitString, false, len));

	if (val == 0)
	{
	mWritePoint[0] = 0;
	}
	else
	{
	mWritePoint[1] = ReverseBits(static_cast<uint8_t>(val));
	if (len >= 3)
	{
	val >>= 8;
	mWritePoint[2] = ReverseBits(static_cast<uint8_t>(val));
	if (len >= 4)
	{
	val >>= 8;
	mWritePoint[3] = ReverseBits(static_cast<uint8_t>(val));
	if (len == 5)
	{
	val >>= 8;
	mWritePoint[4] = ReverseBits(static_cast<uint8_t>(val));
	}
	}
	}
	mWritePoint[0] = static_cast<uint8_t>(7 - HighestBit(val));
	}

	mWritePoint += len;

	return CHIP_NO_ERROR;
	}

	CHIP_ERROR ASN1Writer::PutBitString(uint8_t unusedBitCount, const uint8_t * encodedBits, uint16_t encodedBitsLen)
	{
	// Do nothing for a null writer.
	VerifyOrReturnError(mBuf != nullptr, CHIP_NO_ERROR);

	ReturnErrorOnFailure(EncodeHead(kASN1TagClass_Universal, kASN1UniversalTag_BitString, false, encodedBitsLen + 1));

	*mWritePoint++ = unusedBitCount;

	WriteData(encodedBits, encodedBitsLen);

	return CHIP_NO_ERROR;
	}

	CHIP_ERROR ASN1Writer::PutBitString(uint8_t unusedBitCount, chip::TLV::TLVReader & tlvReader)
	{
	ByteSpan encodedBits;

	// Do nothing for a null writer.
	VerifyOrReturnError(mBuf != nullptr, CHIP_NO_ERROR);

	ReturnErrorOnFailure(tlvReader.Get(encodedBits));

	VerifyOrReturnError(CanCastTo<int32_t>(encodedBits.size() + 1), ASN1_ERROR_LENGTH_OVERFLOW);

	ReturnErrorOnFailure(
	EncodeHead(kASN1TagClass_Universal, kASN1UniversalTag_BitString, false, static_cast<int32_t>(encodedBits.size() + 1)));

	*mWritePoint++ = unusedBitCount;

	WriteData(encodedBits.data(), encodedBits.size());

	return CHIP_NO_ERROR;
	}

	CHIP_ERROR ASN1Writer::PutTime(const ASN1UniversalTime & val)
	{
	char buf[ASN1UniversalTime::kASN1TimeStringMaxLength];
	MutableCharSpan bufSpan(buf);
	uint8_t tag;

	ReturnErrorOnFailure(val.ExportTo_ASN1_TIME_string(bufSpan));

	if (val.Year >= 2050)
	{
	tag = kASN1UniversalTag_GeneralizedTime;
	}
	else
	{
	tag = kASN1UniversalTag_UTCTime;
	}
	return PutValue(kASN1TagClass_Universal, tag, false, reinterpret_cast<uint8_t *>(buf), static_cast<uint16_t>(bufSpan.size()));
	}

	CHIP_ERROR ASN1Writer::PutNull()
	{
	return EncodeHead(kASN1TagClass_Universal, kASN1UniversalTag_Null, false, 0);
	}

	CHIP_ERROR ASN1Writer::PutConstructedType(const uint8_t * val, uint16_t valLen)
	{
	// Do nothing for a null writer.
	VerifyOrReturnError(mBuf != nullptr, CHIP_NO_ERROR);

	// Make sure we have enough space to write
	VerifyOrReturnError((mWritePoint + valLen) <= mBufEnd, ASN1_ERROR_OVERFLOW);

	WriteData(val, valLen);

	return CHIP_NO_ERROR;
	}

	CHIP_ERROR ASN1Writer::StartConstructedType(uint8_t cls, uint8_t tag)
	{
	return EncodeHead(cls, tag, true, kUnknownLength);
	}

	CHIP_ERROR ASN1Writer::EndConstructedType()
	{
	return WriteDeferredLength();
	}

	CHIP_ERROR ASN1Writer::StartEncapsulatedType(uint8_t cls, uint8_t tag, bool bitStringEncoding)
	{
	// Do nothing for a null writer.
	VerifyOrReturnError(mBuf != nullptr, CHIP_NO_ERROR);

	ReturnErrorOnFailure(EncodeHead(cls, tag, false, kUnknownLength));

	// If the encapsulating type is BIT STRING, encode the unused bit count field. Since the BIT
	// STRING contains an ASN.1 DER encoding, and ASN.1 DER encodings are always multiples of 8 bits,
	// the unused bit count is always 0.
	if (bitStringEncoding)
	{
	VerifyOrReturnError(mWritePoint < mBufEnd, ASN1_ERROR_OVERFLOW);
	*mWritePoint++ = 0;
	}

	return CHIP_NO_ERROR;
	}

	CHIP_ERROR ASN1Writer::EndEncapsulatedType()
	{
	return WriteDeferredLength();
	}

	CHIP_ERROR ASN1Writer::PutValue(uint8_t cls, uint8_t tag, bool isConstructed, const uint8_t * val, uint16_t valLen)
	{
	// Do nothing for a null writer.
	VerifyOrReturnError(mBuf != nullptr, CHIP_NO_ERROR);

	ReturnErrorOnFailure(EncodeHead(cls, tag, isConstructed, valLen));

	WriteData(val, valLen);

	return CHIP_NO_ERROR;
	}

	CHIP_ERROR ASN1Writer::PutValue(uint8_t cls, uint8_t tag, bool isConstructed, chip::TLV::TLVReader & tlvReader)
	{
	ByteSpan val;

	// Do nothing for a null writer.
	VerifyOrReturnError(mBuf != nullptr, CHIP_NO_ERROR);

	ReturnErrorOnFailure(tlvReader.Get(val));

	VerifyOrReturnError(CanCastTo<int32_t>(val.size()), ASN1_ERROR_LENGTH_OVERFLOW);

	ReturnErrorOnFailure(EncodeHead(cls, tag, isConstructed, static_cast<int32_t>(val.size())));

	WriteData(val.data(), val.size());

	return CHIP_NO_ERROR;
	}

	CHIP_ERROR ASN1Writer::EncodeHead(uint8_t cls, uint8_t tag, bool isConstructed, int32_t len)
	{
	uint8_t bytesForLen;
	uint32_t totalLen;

	// Do nothing for a null writer.
	VerifyOrReturnError(mBuf != nullptr, CHIP_NO_ERROR);

	// Only tags < 31 supported. The implication of this is that encoded tags are exactly 1 byte long.
	VerifyOrReturnError(tag < 0x1F, ASN1_ERROR_UNSUPPORTED_ENCODING);

	// Only positive and kUnknownLength values are supported for len input.
	VerifyOrReturnError(len >= 0 \|\| len == kUnknownLength, ASN1_ERROR_UNSUPPORTED_ENCODING);

	// Compute the number of bytes required to encode the length.
	bytesForLen = BytesForLength(len);

	// Make sure there's enough space to encode the entire value.
	// Note that the calculated total length doesn't overflow because `len` is a signed value (int32_t).
	// Note that if `len` is not kUnknownLength then it is non-negative (`len` >= 0).
	totalLen = 1 + bytesForLen + static_cast<uint32_t>(len != kUnknownLength ? len : 0);
	VerifyOrReturnError((mWritePoint + totalLen) <= mBufEnd, ASN1_ERROR_OVERFLOW);

	// Write the tag byte.
	*mWritePoint++ = cls \| static_cast<uint8_t>(isConstructed ? 0x20 : 0) \| tag;

	// Encode the length if it is known.
	if (len != kUnknownLength)
	{
	EncodeLength(mWritePoint, bytesForLen, len);
	}
	// ... otherwise place a marker in the first byte of the length to indicate that the length is unknown
	// and save a pointer to the length field in the deferred-length array.
	//
	// The deferred-length is an array of "pointers" to length fields for which the length of the
	// element was unknown at the time the element head was written. Examples include constructed
	// types such as SEQUENCE and SET, as well non-constructed types that encapsulate other ASN.1 types
	// (e.g. OCTET STRINGS that contain BER/DER encodings). The final lengths are filled in later,
	// at the time the encoding of the element is complete (e.g. when EndConstructed() is called).
	else
	{
	VerifyOrReturnError(mDeferredLengthCount < kMaxDeferredLengthDepth, ASN1_ERROR_INVALID_STATE);

	*mWritePoint = kUnknownLengthMarker;
	mDeferredLengthLocations[mDeferredLengthCount++] = mWritePoint;
	}

	mWritePoint += bytesForLen;

	return CHIP_NO_ERROR;
	}

	CHIP_ERROR ASN1Writer::WriteDeferredLength()
	{
	// Do nothing for a null writer.
	VerifyOrReturnError(mBuf != nullptr, CHIP_NO_ERROR);

	VerifyOrReturnError(mDeferredLengthCount > 0, ASN1_ERROR_INVALID_STATE);

	uint8_t * lenField = mDeferredLengthLocations[mDeferredLengthCount - 1];

	VerifyOrReturnError(*lenField == kUnknownLengthMarker, ASN1_ERROR_INVALID_STATE);

	// Compute the length of the element's value.
	size_t elemLen = static_cast<size_t>((mWritePoint - lenField) - kLengthFieldReserveSize);

	VerifyOrReturnError(CanCastTo<int32_t>(elemLen), ASN1_ERROR_LENGTH_OVERFLOW);

	uint8_t bytesForLen = BytesForLength(static_cast<int32_t>(elemLen));

	// Move the element data if the number of bytes consumed by the final length field
	// is different than the space that was reserved for the field.
	if (bytesForLen != kLengthFieldReserveSize)
	{
	mWritePoint += (bytesForLen - kLengthFieldReserveSize);

	VerifyOrReturnError(mWritePoint <= mBufEnd, ASN1_ERROR_OVERFLOW);

	memmove(lenField + bytesForLen, lenField + kLengthFieldReserveSize, elemLen);
	}

	// Encode the final length of the element, overwriting the unknown length marker
	// in the process.
	EncodeLength(lenField, bytesForLen, static_cast<int32_t>(elemLen));

	mDeferredLengthCount--;

	return CHIP_NO_ERROR;
	}

	/**
	* Returns the number of bytes required to encode the length value.
	*
	* @param[in] len Parameter, which encoding length to be calculated.
	*
	* @return number of bytes required to encode the length value.
	*/
	uint8_t ASN1Writer::BytesForLength(int32_t len)
	{
	if (len == kUnknownLength)
	return kLengthFieldReserveSize;
	if (len < 128)
	return 1;
	if (len < 256)
	return 2;
	if (len < 65536)
	return 3;
	if (len < (1 << 24))
	return 4;
	return 5;
	}

	void ASN1Writer::EncodeLength(uint8_t * buf, uint8_t bytesForLen, int32_t lenToEncode)
	{
	if (bytesForLen == 1)
	{
	buf[0] = static_cast<uint8_t>(lenToEncode);
	}
	else
	{
	--bytesForLen;
	buf[0] = 0x80 \| bytesForLen;
	do
	{
	buf[bytesForLen] = static_cast<uint8_t>(lenToEncode);
	lenToEncode >>= 8;
	} while (--bytesForLen);
	}
	}

	void ASN1Writer::WriteData(const uint8_t * p, size_t len)
	{
	memcpy(mWritePoint, p, len);
	mWritePoint += len;
	}

	} // namespace ASN1
	} // namespace chip