include/ipmid/message/unpack.hpp - openbmc/phosphor-host-ipmid - Gitiles

 /**
  * Copyright © 2018 Intel Corporation
  *
  * 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.
  */
 #pragma once

 #include <array>
 #include <ipmid/message/types.hpp>
 #include <optional>
 #include <string>
 #include <tuple>
 #include <vector>

 namespace ipmi
 {

 namespace message
 {

 namespace details
 {

 /**************************************
  * ipmi return type helpers
  **************************************/

 template <typename NumericType, size_t byteIndex = 0>
 void UnpackBytes(uint8_t* pointer, NumericType& i)
 {
     if constexpr (byteIndex < sizeof(NumericType))
     {
         i |= static_cast<NumericType>(*pointer) << (CHAR_BIT * byteIndex);
         UnpackBytes<NumericType, byteIndex + 1>(pointer + 1, i);
     }
 }

 template <typename NumericType, size_t byteIndex = 0>
 void UnpackBytesUnaligned(Payload& p, NumericType& i)
 {
     if constexpr (byteIndex < sizeof(NumericType))
     {
         i |= static_cast<NumericType>(p.popBits(CHAR_BIT))
              << (CHAR_BIT * byteIndex);
         UnpackBytesUnaligned<NumericType, byteIndex + 1>(p, i);
     }
 }

 /** @struct UnpackSingle
  *  @brief Utility to unpack a single C++ element from a Payload
  *
  *  User-defined types are expected to specialize this template in order to
  *  get their functionality.
  *
  *  @tparam T - Type of element to unpack.
  */
 template <typename T>
 struct UnpackSingle
 {
     /** @brief Do the operation to unpack element.
      *
      *  @param[in] p - Payload to unpack from.
      *  @param[out] t - The reference to unpack item into.
      */
     static int op(Payload& p, T& t)
     {
         if constexpr (std::is_fundamental<T>::value)
         {
             t = 0;
             if (p.bitCount)
             {
                 if (p.fillBits(CHAR_BIT * sizeof(t)))
                 {
                     return 1;
                 }
                 UnpackBytesUnaligned<T>(p, t);
             }
             else
             {
                 // copy out bits from vector....
                 if (p.raw.size() < (p.rawIndex + sizeof(t)))
                 {
                     return 1;
                 }
                 auto iter = p.raw.data() + p.rawIndex;
                 t = 0;
                 UnpackBytes<T>(iter, t);
                 p.rawIndex += sizeof(t);
             }
             return 0;
         }
         else if constexpr (utility::is_tuple<T>::value)
         {
             bool priorError = p.unpackError;
             size_t priorIndex = p.rawIndex;
             // more stuff to unroll if partial bytes are out
             size_t priorBitCount = p.bitCount;
             fixed_uint_t<details::bitStreamSize> priorBits = p.bitStream;
             int ret = p.unpack(t);
             if (ret != 0)
             {
                 t = T();
                 p.rawIndex = priorIndex;
                 p.bitStream = priorBits;
                 p.bitCount = priorBitCount;
                 p.unpackError = priorError;
             }
             return ret;
         }
         else
         {
             static_assert(
                 utility::dependent_false<T>::value,
                 "Attempt to unpack a type that has no IPMI unpack operation");
         }
     }
 };

 /** @struct UnpackSingle
  *  @brief Utility to unpack a single C++ element from a Payload
  *
  *  Specialization to unpack std::string represented as a
  *  UCSD-Pascal style string
  */
 template <>
 struct UnpackSingle<std::string>
 {
     static int op(Payload& p, std::string& t)
     {
         // pop len first
         if (p.rawIndex > (p.raw.size() - sizeof(uint8_t)))
         {
             return 1;
         }
         uint8_t len = p.raw[p.rawIndex++];
         // check to see that there are n bytes left
         auto [first, last] = p.pop<char>(len);
         if (first == last)
         {
             return 1;
         }
         t.reserve(last - first);
         t.insert(0, first, (last - first));
         return 0;
     }
 };

 /** @brief Specialization of UnpackSingle for fixed_uint_t types
  */
 template <unsigned N>
 struct UnpackSingle<fixed_uint_t<N>>
 {
     static int op(Payload& p, fixed_uint_t<N>& t)
     {
         static_assert(N <= (details::bitStreamSize - CHAR_BIT));
         constexpr size_t count = N;
         // acquire enough bits in the stream to fulfill the Payload
         if (p.fillBits(count))
         {
             return -1;
         }
         fixed_uint_t<details::bitStreamSize> bitmask = ((1 << count) - 1);
         t = (p.bitStream & bitmask).convert_to<fixed_uint_t<N>>();
         p.bitStream >>= count;
         p.bitCount -= count;
         return 0;
     }
 };

 /** @brief Specialization of UnpackSingle for bool. */
 template <>
 struct UnpackSingle<bool>
 {
     static int op(Payload& p, bool& b)
     {
         // acquire enough bits in the stream to fulfill the Payload
         if (p.fillBits(1))
         {
             return -1;
         }
         b = static_cast<bool>(p.bitStream & 0x01);
         // clear bits from stream
         p.bitStream >>= 1;
         p.bitCount -= 1;
         return 0;
     }
 };

 /** @brief Specialization of UnpackSingle for std::bitset<N>
  */
 template <size_t N>
 struct UnpackSingle<std::bitset<N>>
 {
     static int op(Payload& p, std::bitset<N>& t)
     {
         static_assert(N <= (details::bitStreamSize - CHAR_BIT));
         size_t count = N;
         // acquire enough bits in the stream to fulfill the Payload
         if (p.fillBits(count))
         {
             return -1;
         }
         fixed_uint_t<details::bitStreamSize> bitmask =
             ~fixed_uint_t<details::bitStreamSize>(0) >>
             (details::bitStreamSize - count);
         t |= (p.bitStream & bitmask).convert_to<unsigned long long>();
         p.bitStream >>= count;
         p.bitCount -= count;
         return 0;
     }
 };

 /** @brief Specialization of UnpackSingle for std::optional<T> */
 template <typename T>
 struct UnpackSingle<std::optional<T>>
 {
     static int op(Payload& p, std::optional<T>& t)
     {
         bool priorError = p.unpackError;
         size_t priorIndex = p.rawIndex;
         // more stuff to unroll if partial bytes are out
         size_t priorBitCount = p.bitCount;
         fixed_uint_t<details::bitStreamSize> priorBits = p.bitStream;
         t.emplace();
         int ret = UnpackSingle<T>::op(p, *t);
         if (ret != 0)
         {
             t.reset();
             p.rawIndex = priorIndex;
             p.bitStream = priorBits;
             p.bitCount = priorBitCount;
             p.unpackError = priorError;
         }
         return 0;
     }
 };

 /** @brief Specialization of UnpackSingle for std::array<T, N> */
 template <typename T, size_t N>
 struct UnpackSingle<std::array<T, N>>
 {
     static int op(Payload& p, std::array<T, N>& t)
     {
         int ret = 0;
         size_t priorIndex = p.rawIndex;
         for (auto& v : t)
         {
             ret = UnpackSingle<T>::op(p, v);
             if (ret)
             {
                 p.rawIndex = priorIndex;
                 t = std::array<T, N>();
                 break;
             }
         }
         return ret;
     }
 };

 /** @brief Specialization of UnpackSingle for std::array<uint8_t> */
 template <size_t N>
 struct UnpackSingle<std::array<uint8_t, N>>
 {
     static int op(Payload& p, std::array<uint8_t, N>& t)
     {
         if (p.raw.size() - p.rawIndex < N)
         {
             t.fill(0);
             return -1;
         }
         // copy out the bytes
         std::copy(p.raw.begin() + p.rawIndex, p.raw.begin() + p.rawIndex + N,
                   t.begin());
         p.rawIndex += N;
         return 0;
     }
 };

 /** @brief Specialization of UnpackSingle for std::vector<T> */
 template <typename T>
 struct UnpackSingle<std::vector<T>>
 {
     static int op(Payload& p, std::vector<T>& t)
     {
         while (p.rawIndex < p.raw.size())
         {
             t.emplace_back();
             if (UnpackSingle<T>::op(p, t.back()))
             {
                 t.pop_back();
                 break;
             }
         }
         // unpacking a vector is always successful:
         // either stuff was unpacked successfully (return 0)
         // or stuff was not unpacked, but should still return
         // success because an empty vector or a not-fully-unpacked
         // payload is not a failure.
         return 0;
     }
 };

 /** @brief Specialization of UnpackSingle for std::vector<uint8_t> */
 template <>
 struct UnpackSingle<std::vector<uint8_t>>
 {
     static int op(Payload& p, std::vector<uint8_t>& t)
     {
         // copy out the remainder of the message
         t.reserve(p.raw.size() - p.rawIndex);
         t.insert(t.begin(), p.raw.begin() + p.rawIndex, p.raw.end());
         p.rawIndex = p.raw.size();
         return 0;
     }
 };

 /** @brief Specialization of UnpackSingle for SecureBuffer */
 template <>
 struct UnpackSingle<SecureBuffer>
 {
     static int op(Payload& p, SecureBuffer& t)
     {
         // copy out the remainder of the message
         t.reserve(p.raw.size() - p.rawIndex);
         t.insert(t.begin(), p.raw.begin() + p.rawIndex, p.raw.end());
         p.rawIndex = p.raw.size();
         return 0;
     }
 };

 /** @brief Specialization of UnpackSingle for Payload */
 template <>
 struct UnpackSingle<Payload>
 {
     static int op(Payload& p, Payload& t)
     {
         t = p;
         // mark that this payload is being included in the args
         p.trailingOk = true;
         return 0;
     }
 };

 } // namespace details

 } // namespace message

 } // namespace ipmi
	/**
	* Copyright © 2018 Intel Corporation
	*
	* 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.
	*/
	#pragma once

	#include <array>
	#include <ipmid/message/types.hpp>
	#include <optional>
	#include <string>
	#include <tuple>
	#include <vector>

	namespace ipmi
	{

	namespace message
	{

	namespace details
	{

	/**************************************
	* ipmi return type helpers
	**************************************/

	template <typename NumericType, size_t byteIndex = 0>
	void UnpackBytes(uint8_t* pointer, NumericType& i)
	{
	if constexpr (byteIndex < sizeof(NumericType))
	{
	i \|= static_cast<NumericType>(pointer) << (CHAR_BIT byteIndex);
	UnpackBytes<NumericType, byteIndex + 1>(pointer + 1, i);
	}
	}

	template <typename NumericType, size_t byteIndex = 0>
	void UnpackBytesUnaligned(Payload& p, NumericType& i)
	{
	if constexpr (byteIndex < sizeof(NumericType))
	{
	i \|= static_cast<NumericType>(p.popBits(CHAR_BIT))
	<< (CHAR_BIT * byteIndex);
	UnpackBytesUnaligned<NumericType, byteIndex + 1>(p, i);
	}
	}

	/** @struct UnpackSingle
	* @brief Utility to unpack a single C++ element from a Payload
	*
	* User-defined types are expected to specialize this template in order to
	* get their functionality.
	*
	* @tparam T - Type of element to unpack.
	*/
	template <typename T>
	struct UnpackSingle
	{
	/** @brief Do the operation to unpack element.
	*
	* @param[in] p - Payload to unpack from.
	* @param[out] t - The reference to unpack item into.
	*/
	static int op(Payload& p, T& t)
	{
	if constexpr (std::is_fundamental<T>::value)
	{
	t = 0;
	if (p.bitCount)
	{
	if (p.fillBits(CHAR_BIT * sizeof(t)))
	{
	return 1;
	}
	UnpackBytesUnaligned<T>(p, t);
	}
	else
	{
	// copy out bits from vector....
	if (p.raw.size() < (p.rawIndex + sizeof(t)))
	{
	return 1;
	}
	auto iter = p.raw.data() + p.rawIndex;
	t = 0;
	UnpackBytes<T>(iter, t);
	p.rawIndex += sizeof(t);
	}
	return 0;
	}
	else if constexpr (utility::is_tuple<T>::value)
	{
	bool priorError = p.unpackError;
	size_t priorIndex = p.rawIndex;
	// more stuff to unroll if partial bytes are out
	size_t priorBitCount = p.bitCount;
	fixed_uint_t<details::bitStreamSize> priorBits = p.bitStream;
	int ret = p.unpack(t);
	if (ret != 0)
	{
	t = T();
	p.rawIndex = priorIndex;
	p.bitStream = priorBits;
	p.bitCount = priorBitCount;
	p.unpackError = priorError;
	}
	return ret;
	}
	else
	{
	static_assert(
	utility::dependent_false<T>::value,
	"Attempt to unpack a type that has no IPMI unpack operation");
	}
	}
	};

	/** @struct UnpackSingle
	* @brief Utility to unpack a single C++ element from a Payload
	*
	* Specialization to unpack std::string represented as a
	* UCSD-Pascal style string
	*/
	template <>
	struct UnpackSingle<std::string>
	{
	static int op(Payload& p, std::string& t)
	{
	// pop len first
	if (p.rawIndex > (p.raw.size() - sizeof(uint8_t)))
	{
	return 1;
	}
	uint8_t len = p.raw[p.rawIndex++];
	// check to see that there are n bytes left
	auto [first, last] = p.pop<char>(len);
	if (first == last)
	{
	return 1;
	}
	t.reserve(last - first);
	t.insert(0, first, (last - first));
	return 0;
	}
	};

	/** @brief Specialization of UnpackSingle for fixed_uint_t types
	*/
	template <unsigned N>
	struct UnpackSingle<fixed_uint_t<N>>
	{
	static int op(Payload& p, fixed_uint_t<N>& t)
	{
	static_assert(N <= (details::bitStreamSize - CHAR_BIT));
	constexpr size_t count = N;
	// acquire enough bits in the stream to fulfill the Payload
	if (p.fillBits(count))
	{
	return -1;
	}
	fixed_uint_t<details::bitStreamSize> bitmask = ((1 << count) - 1);
	t = (p.bitStream & bitmask).convert_to<fixed_uint_t<N>>();
	p.bitStream >>= count;
	p.bitCount -= count;
	return 0;
	}
	};

	/** @brief Specialization of UnpackSingle for bool. */
	template <>
	struct UnpackSingle<bool>
	{
	static int op(Payload& p, bool& b)
	{
	// acquire enough bits in the stream to fulfill the Payload
	if (p.fillBits(1))
	{
	return -1;
	}
	b = static_cast<bool>(p.bitStream & 0x01);
	// clear bits from stream
	p.bitStream >>= 1;
	p.bitCount -= 1;
	return 0;
	}
	};

	/** @brief Specialization of UnpackSingle for std::bitset<N>
	*/
	template <size_t N>
	struct UnpackSingle<std::bitset<N>>
	{
	static int op(Payload& p, std::bitset<N>& t)
	{
	static_assert(N <= (details::bitStreamSize - CHAR_BIT));
	size_t count = N;
	// acquire enough bits in the stream to fulfill the Payload
	if (p.fillBits(count))
	{
	return -1;
	}
	fixed_uint_t<details::bitStreamSize> bitmask =
	~fixed_uint_t<details::bitStreamSize>(0) >>
	(details::bitStreamSize - count);
	t \|= (p.bitStream & bitmask).convert_to<unsigned long long>();
	p.bitStream >>= count;
	p.bitCount -= count;
	return 0;
	}
	};

	/** @brief Specialization of UnpackSingle for std::optional<T> */
	template <typename T>
	struct UnpackSingle<std::optional<T>>
	{
	static int op(Payload& p, std::optional<T>& t)
	{
	bool priorError = p.unpackError;
	size_t priorIndex = p.rawIndex;
	// more stuff to unroll if partial bytes are out
	size_t priorBitCount = p.bitCount;
	fixed_uint_t<details::bitStreamSize> priorBits = p.bitStream;
	t.emplace();
	int ret = UnpackSingle<T>::op(p, *t);
	if (ret != 0)
	{
	t.reset();
	p.rawIndex = priorIndex;
	p.bitStream = priorBits;
	p.bitCount = priorBitCount;
	p.unpackError = priorError;
	}
	return 0;
	}
	};

	/** @brief Specialization of UnpackSingle for std::array<T, N> */
	template <typename T, size_t N>
	struct UnpackSingle<std::array<T, N>>
	{
	static int op(Payload& p, std::array<T, N>& t)
	{
	int ret = 0;
	size_t priorIndex = p.rawIndex;
	for (auto& v : t)
	{
	ret = UnpackSingle<T>::op(p, v);
	if (ret)
	{
	p.rawIndex = priorIndex;
	t = std::array<T, N>();
	break;
	}
	}
	return ret;
	}
	};

	/** @brief Specialization of UnpackSingle for std::array<uint8_t> */
	template <size_t N>
	struct UnpackSingle<std::array<uint8_t, N>>
	{
	static int op(Payload& p, std::array<uint8_t, N>& t)
	{
	if (p.raw.size() - p.rawIndex < N)
	{
	t.fill(0);
	return -1;
	}
	// copy out the bytes
	std::copy(p.raw.begin() + p.rawIndex, p.raw.begin() + p.rawIndex + N,
	t.begin());
	p.rawIndex += N;
	return 0;
	}
	};

	/** @brief Specialization of UnpackSingle for std::vector<T> */
	template <typename T>
	struct UnpackSingle<std::vector<T>>
	{
	static int op(Payload& p, std::vector<T>& t)
	{
	while (p.rawIndex < p.raw.size())
	{
	t.emplace_back();
	if (UnpackSingle<T>::op(p, t.back()))
	{
	t.pop_back();
	break;
	}
	}
	// unpacking a vector is always successful:
	// either stuff was unpacked successfully (return 0)
	// or stuff was not unpacked, but should still return
	// success because an empty vector or a not-fully-unpacked
	// payload is not a failure.
	return 0;
	}
	};

	/** @brief Specialization of UnpackSingle for std::vector<uint8_t> */
	template <>
	struct UnpackSingle<std::vector<uint8_t>>
	{
	static int op(Payload& p, std::vector<uint8_t>& t)
	{
	// copy out the remainder of the message
	t.reserve(p.raw.size() - p.rawIndex);
	t.insert(t.begin(), p.raw.begin() + p.rawIndex, p.raw.end());
	p.rawIndex = p.raw.size();
	return 0;
	}
	};

	/** @brief Specialization of UnpackSingle for SecureBuffer */
	template <>
	struct UnpackSingle<SecureBuffer>
	{
	static int op(Payload& p, SecureBuffer& t)
	{
	// copy out the remainder of the message
	t.reserve(p.raw.size() - p.rawIndex);
	t.insert(t.begin(), p.raw.begin() + p.rawIndex, p.raw.end());
	p.rawIndex = p.raw.size();
	return 0;
	}
	};

	/** @brief Specialization of UnpackSingle for Payload */
	template <>
	struct UnpackSingle<Payload>
	{
	static int op(Payload& p, Payload& t)
	{
	t = p;
	// mark that this payload is being included in the args
	p.trailingOk = true;
	return 0;
	}
	};

	} // namespace details

	} // namespace message

	} // namespace ipmi