01cf05bc75
Follow-up to 99ceb03a1c
175 lines
6.2 KiB
C++
175 lines
6.2 KiB
C++
// SPDX-FileCopyrightText: 2014 Tony Wasserka
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// SPDX-FileCopyrightText: 2014 Dolphin Emulator Project
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// SPDX-License-Identifier: BSD-3-Clause AND GPL-2.0-or-later
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#pragma once
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#include <cstddef>
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#include <limits>
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#include <type_traits>
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#include "common/swap.h"
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/*
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* Abstract bitfield class
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*
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* Allows endianness-independent access to individual bitfields within some raw
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* integer value. The assembly generated by this class is identical to the
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* usage of raw bitfields, so it's a perfectly fine replacement.
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*
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* For BitField<X,Y,Z>, X is the distance of the bitfield to the LSB of the
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* raw value, Y is the length in bits of the bitfield. Z is an integer type
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* which determines the sign of the bitfield. Z must have the same size as the
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* raw integer.
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*
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*
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* General usage:
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*
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* Create a new union with the raw integer value as a member.
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* Then for each bitfield you want to expose, add a BitField member
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* in the union. The template parameters are the bit offset and the number
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* of desired bits.
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*
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* Changes in the bitfield members will then get reflected in the raw integer
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* value and vice-versa.
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*
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*
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* Sample usage:
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*
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* union SomeRegister
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* {
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* u32 hex;
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*
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* BitField<0,7,u32> first_seven_bits; // unsigned
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* BitField<7,8,u32> next_eight_bits; // unsigned
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* BitField<3,15,s32> some_signed_fields; // signed
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* };
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*
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* This is equivalent to the little-endian specific code:
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*
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* union SomeRegister
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* {
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* u32 hex;
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*
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* struct
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* {
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* u32 first_seven_bits : 7;
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* u32 next_eight_bits : 8;
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* };
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* struct
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* {
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* u32 : 3; // padding
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* s32 some_signed_fields : 15;
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* };
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* };
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*
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*
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* Caveats:
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*
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* 1)
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* BitField provides automatic casting from and to the storage type where
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* appropriate. However, when using non-typesafe functions like printf, an
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* explicit cast must be performed on the BitField object to make sure it gets
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* passed correctly, e.g.:
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* printf("Value: %d", (s32)some_register.some_signed_fields);
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*
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* 2)
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* Not really a caveat, but potentially irritating: This class is used in some
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* packed structures that do not guarantee proper alignment. Therefore we have
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* to use #pragma pack here not to pack the members of the class, but instead
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* to break GCC's assumption that the members of the class are aligned on
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* sizeof(StorageType).
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* TODO(neobrain): Confirm that this is a proper fix and not just masking
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* symptoms.
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*/
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#pragma pack(1)
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template <std::size_t Position, std::size_t Bits, typename T, typename EndianTag = LETag>
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struct BitField {
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private:
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// UnderlyingType is T for non-enum types and the underlying type of T if
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// T is an enumeration. Note that T is wrapped within an enable_if in the
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// former case to workaround compile errors which arise when using
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// std::underlying_type<T>::type directly.
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using UnderlyingType = typename std::conditional_t<std::is_enum_v<T>, std::underlying_type<T>,
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std::enable_if<true, T>>::type;
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// We store the value as the unsigned type to avoid undefined behaviour on value shifting
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using StorageType = std::make_unsigned_t<UnderlyingType>;
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using StorageTypeWithEndian = typename AddEndian<StorageType, EndianTag>::type;
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public:
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/// Constants to allow limited introspection of fields if needed
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static constexpr std::size_t position = Position;
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static constexpr std::size_t bits = Bits;
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static constexpr StorageType mask = (((StorageType)~0) >> (8 * sizeof(T) - bits)) << position;
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/**
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* Formats a value by masking and shifting it according to the field parameters. A value
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* containing several bitfields can be assembled by formatting each of their values and ORing
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* the results together.
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*/
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[[nodiscard]] static constexpr StorageType FormatValue(const T& value) {
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return (static_cast<StorageType>(value) << position) & mask;
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}
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/**
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* Extracts a value from the passed storage. In most situations prefer use the member functions
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* (such as Value() or operator T), but this can be used to extract a value from a bitfield
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* union in a constexpr context.
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*/
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[[nodiscard]] static constexpr T ExtractValue(const StorageType& storage) {
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if constexpr (std::numeric_limits<UnderlyingType>::is_signed) {
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std::size_t shift = 8 * sizeof(T) - bits;
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return static_cast<T>(static_cast<UnderlyingType>(storage << (shift - position)) >>
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shift);
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} else {
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return static_cast<T>((storage & mask) >> position);
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}
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}
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// This constructor and assignment operator might be considered ambiguous:
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// Would they initialize the storage or just the bitfield?
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// Hence, delete them. Use the Assign method to set bitfield values!
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BitField(T val) = delete;
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BitField& operator=(T val) = delete;
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constexpr BitField() noexcept = default;
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constexpr BitField(const BitField&) noexcept = default;
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constexpr BitField& operator=(const BitField&) noexcept = default;
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constexpr BitField(BitField&&) noexcept = default;
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constexpr BitField& operator=(BitField&&) noexcept = default;
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[[nodiscard]] constexpr operator T() const {
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return Value();
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}
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constexpr void Assign(const T& value) {
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storage = static_cast<StorageType>((storage & ~mask) | FormatValue(value));
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}
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[[nodiscard]] constexpr T Value() const {
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return ExtractValue(storage);
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}
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[[nodiscard]] constexpr explicit operator bool() const {
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return Value() != 0;
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}
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private:
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StorageTypeWithEndian storage;
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static_assert(bits + position <= 8 * sizeof(T), "Bitfield out of range");
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// And, you know, just in case people specify something stupid like bits=position=0x80000000
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static_assert(position < 8 * sizeof(T), "Invalid position");
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static_assert(bits <= 8 * sizeof(T), "Invalid number of bits");
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static_assert(bits > 0, "Invalid number of bits");
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static_assert(std::is_trivially_copyable_v<T>, "T must be trivially copyable in a BitField");
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};
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#pragma pack()
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template <std::size_t Position, std::size_t Bits, typename T>
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using BitFieldBE = BitField<Position, Bits, T, BETag>;
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