TiedFields.h - mozsearch

Enable keyboard shortcuts

/* This Source Code Form is subject to the terms of the Mozilla Public

 * License, v. 2.0. If a copy of the MPL was not distributed with this

 * file, You can obtain one at http://mozilla.org/MPL/2.0/. */

#ifndef DOM_CANVAS_TIED_FIELDS_H

#define DOM_CANVAS_TIED_FIELDS_H

#include "TupleUtils.h"

namespace mozilla {

// -

/**

 * TiedFields(T&) -> std::tuple<Fields&...>

 * TiedFields(const T&) -> std::tuple<const Fields&...>

 * You can also overload TiedFields without adding T::MutTiedFields:

 * template<>

 * inline auto TiedFields<gfx::IntSize>(gfx::IntSize& a) {

 *   return std::tie(a.width, a.height);

* }

*/

template <class T>

constexpr auto TiedFields(T& t) {

  const auto fields = t.MutTiedFields();

  return fields;

template <class T, class... Args, class Tup = std::tuple<Args&...>>

constexpr auto TiedFields(const T& t) {

  // Uncast const to get mutable-fields tuple, but reapply const to tuple args.

  // We should do better than this when C++ gets a solution other than macros.

  const auto mutFields = TiedFields(const_cast<T&>(t));

  return ToTupleOfConstRefs(mutFields);

/**

 * Returns true if all bytes in T are accounted for via size of all tied fields.

 * Returns false if there's bytes unaccounted for, which might indicate either

 * unaccounted-for padding or missing fields.

 * The goal is to check that TiedFields returns every field in T, and this

 * returns false if it suspects there are bytes that are not accounted for by

 * TiedFields.

 * `constexpr` effectively cannot do math on pointers, so it's not possible to

 * figure out via `constexpr` whether fields are consecutive or dense.

 * However, we can at least compare `sizeof(T)` to the sum of `sizeof(Args...)`

 * for `TiedFields(T) -> std::tuple<Args...>`.

 * See TiedFieldsExamples.

*/

template <class T>

constexpr bool AreAllBytesTiedFields() {

  using fieldsT = decltype(TiedFields(std::declval<T>()));

  const auto fields_size_sum = SizeofTupleArgs<fieldsT>::value;

  const auto t_size = sizeof(T);

  return fields_size_sum == t_size;

// It's also possible to determine AreAllBytesRecursiveTiedFields:

// https://hackmd.io/@jgilbert/B16qa0Fa9

// -

template <class StructT, size_t FieldId, size_t PrevFieldBeginOffset,

          class PrevFieldT, size_t PrevFieldEndOffset, class FieldT,

          size_t FieldAlignment = alignof(FieldT)>

struct FieldDebugInfoT {

  static constexpr bool IsTightlyPacked() {

    return PrevFieldEndOffset % FieldAlignment == 0;

};

template <class StructT, class TupleOfFields, size_t FieldId>

struct TightlyPackedFieldEndOffsetT {

  template <size_t I>

  using FieldTAt = std::remove_reference_t<

      typename std::tuple_element<I, TupleOfFields>::type>;

  static constexpr size_t Fn() {

    constexpr auto num_fields = std::tuple_size_v<TupleOfFields>;

    static_assert(FieldId < num_fields);

    using PrevFieldT = FieldTAt<FieldId - 1>;

    using FieldT = FieldTAt<FieldId>;

    constexpr auto prev_field_end_offset =

        TightlyPackedFieldEndOffsetT<StructT, TupleOfFields, FieldId - 1>::Fn();

    constexpr auto prev_field_begin_offset =

        prev_field_end_offset - sizeof(PrevFieldT);

    using FieldDebugInfoT =

        FieldDebugInfoT<StructT, FieldId, prev_field_begin_offset, PrevFieldT,

                        prev_field_end_offset, FieldT>;

    static_assert(FieldDebugInfoT::IsTightlyPacked(),

                  "This field was not tightly packed. Is there padding between "

                  "it and its predecessor?");

    return prev_field_end_offset + sizeof(FieldT);

};

template <class StructT, class TupleOfFields>

struct TightlyPackedFieldEndOffsetT<StructT, TupleOfFields, 0> {

  static constexpr size_t Fn() {

    using FieldT = typename std::tuple_element<0, TupleOfFields>::type;

    return sizeof(FieldT);

};

template <class StructT, class TupleOfFields>

struct TightlyPackedFieldEndOffsetT<StructT, TupleOfFields, size_t(-1)> {

  static constexpr size_t Fn() {

    // -1 means tuple_size_v<TupleOfFields> -> 0.

    static_assert(sizeof(StructT) == 0);

    return 0;

};

template <class StructT>

constexpr bool AssertTiedFieldsAreExhaustive() {

  using TupleOfFields = decltype(std::declval<StructT>().MutTiedFields());

  constexpr auto num_fields = std::tuple_size_v<TupleOfFields>;

  constexpr auto end_offset_of_last_field =

      TightlyPackedFieldEndOffsetT<StructT, TupleOfFields,

                                   num_fields - 1>::Fn();

  static_assert(

      end_offset_of_last_field == sizeof(StructT),

      "Incorrect field list in MutTiedFields()? (or not tightly-packed?)");

  return true;  // Support `static_assert(AssertTiedFieldsAreExhaustive())`.

// -

/**

 * PaddingField<T,N=1> can be used to pad out a struct so that it's not

 * implicitly padded by struct rules, but also can't be accidentally initialized

 * via Aggregate Initialization. (TiedFields serialization checks rely on object

 * fields leaving no implicit padding bytes, but explicit padding fields are

 * fine) While you can use e.g. `uint8_t _padding[3];`, consider instead

 * `PaddingField<uint8_t,3> _padding;` for clarity and to move the `3` nearer

 * to the `uint8_t`.

*/

template <class T, size_t N = 1>

struct PaddingField {

  static_assert(!std::is_array_v<T>, "Use PaddingField<T,N> not <T[N]>.");

  std::array<T, N> ignored = {};

  PaddingField() {}

  friend constexpr bool operator==(const PaddingField&, const PaddingField&) {

    return true;

  friend constexpr bool operator<(const PaddingField&, const PaddingField&) {

    return false;

  auto MutTiedFields() { return std::tie(ignored); }

};

static_assert(sizeof(PaddingField<bool>) == 1);

static_assert(sizeof(PaddingField<bool, 2>) == 2);

static_assert(sizeof(PaddingField<int>) == 4);

// -

namespace TiedFieldsExamples {

struct Cat {

  int i;

  bool b;

  constexpr auto MutTiedFields() { return std::tie(i, b); }

};

static_assert(sizeof(Cat) == 8);

static_assert(!AreAllBytesTiedFields<Cat>());

struct Dog {

  bool b;

  int i;

  constexpr auto MutTiedFields() { return std::tie(i, b); }

};

static_assert(sizeof(Dog) == 8);

static_assert(!AreAllBytesTiedFields<Dog>());

struct Fish {

  bool b;

  bool padding[3];

  int i;

  constexpr auto MutTiedFields() { return std::tie(i, b, padding); }

};

static_assert(sizeof(Fish) == 8);

static_assert(AreAllBytesTiedFields<Fish>());

struct Eel {  // Like a Fish, but you can skip serializing the padding.

  bool b;

  PaddingField<bool, 3> padding;

  int i;

  constexpr auto MutTiedFields() { return std::tie(i, b, padding); }

};

static_assert(sizeof(Eel) == 8);

static_assert(AreAllBytesTiedFields<Eel>());

// -

// #define LETS_USE_BIT_FIELDS

#ifdef LETS_USE_BIT_FIELDS

#  undef LETS_USE_BIT_FIELDS

struct Platypus {

  short s : 1;

  short s2 : 1;

  int i;

  constexpr auto MutTiedFields() {

    return std::tie(s, s2, i);  // Error: Can't take reference to bit-field.

};

#endif

// -

struct FishTank {

  Fish f;

  int i2;

  constexpr auto MutTiedFields() { return std::tie(f, i2); }

};

static_assert(sizeof(FishTank) == 12);

static_assert(AreAllBytesTiedFields<FishTank>());

struct CatCarrier {

  Cat c;

  int i2;

  constexpr auto MutTiedFields() { return std::tie(c, i2); }

};

static_assert(sizeof(CatCarrier) == 12);

static_assert(AreAllBytesTiedFields<CatCarrier>());

static_assert(

    !AreAllBytesTiedFields<decltype(CatCarrier::c)>());  // BUT BEWARE THIS!

// For example, if we had AreAllBytesRecursiveTiedFields:

// static_assert(!AreAllBytesRecursiveTiedFields<CatCarrier>());

}  // namespace TiedFieldsExamples

}  // namespace mozilla

#endif  // DOM_CANVAS_TIED_FIELDS_H