mirror of
https://github.com/mozilla/gecko-dev.git
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c9530ebe28
Differential Revision: https://phabricator.services.mozilla.com/D125504
805 lines
27 KiB
C++
805 lines
27 KiB
C++
/* -*- Mode: C++; tab-width: 8; indent-tabs-mode: nil; c-basic-offset: 2 -*-
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* vim: set ts=8 sts=2 et sw=2 tw=80:
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* This Source Code Form is subject to the terms of the Mozilla Public
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* License, v. 2.0. If a copy of the MPL was not distributed with this
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* file, You can obtain one at http://mozilla.org/MPL/2.0/. */
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/* A type suitable for returning either a value or an error from a function. */
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#ifndef mozilla_Result_h
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#define mozilla_Result_h
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#include <algorithm>
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#include <cstdint>
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#include <cstring>
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#include <type_traits>
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#include "mozilla/Assertions.h"
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#include "mozilla/Attributes.h"
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#include "mozilla/CompactPair.h"
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#include "mozilla/MaybeStorageBase.h"
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namespace mozilla {
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/**
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* Empty struct, indicating success for operations that have no return value.
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* For example, if you declare another empty struct `struct OutOfMemory {};`,
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* then `Result<Ok, OutOfMemory>` represents either success or OOM.
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*/
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struct Ok {};
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/**
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* A tag used to differentiate between GenericErrorResult created by the Err
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* function (completely new error) and GenericErrorResult created by the
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* Result::propagateErr function (propagated error). This can be used to track
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* error propagation and eventually produce error stacks for logging/debugging
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* purposes.
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*/
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struct ErrorPropagationTag {};
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template <typename E>
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class GenericErrorResult;
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template <typename V, typename E>
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class Result;
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namespace detail {
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enum class PackingStrategy {
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Variant,
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NullIsOk,
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LowBitTagIsError,
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PackedVariant,
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};
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template <typename T>
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struct UnusedZero;
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template <typename V, typename E, PackingStrategy Strategy>
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class ResultImplementation;
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template <typename V>
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struct EmptyWrapper : V {
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constexpr EmptyWrapper() = default;
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explicit constexpr EmptyWrapper(const V&) {}
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explicit constexpr EmptyWrapper(std::in_place_t) {}
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constexpr V* addr() { return this; }
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constexpr const V* addr() const { return this; }
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};
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// The purpose of AlignedStorageOrEmpty is to make an empty class look like
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// std::aligned_storage_t for the purposes of the PackingStrategy::NullIsOk
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// specializations of ResultImplementation below. We can't use
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// std::aligned_storage_t itself with an empty class, since it would no longer
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// be empty.
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template <typename V>
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using AlignedStorageOrEmpty =
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std::conditional_t<std::is_empty_v<V>, EmptyWrapper<V>,
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MaybeStorageBase<V>>;
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template <typename V, typename E>
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class ResultImplementationNullIsOkBase {
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protected:
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using ErrorStorageType = typename UnusedZero<E>::StorageType;
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static constexpr auto kNullValue = UnusedZero<E>::nullValue;
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static_assert(std::is_trivially_copyable_v<ErrorStorageType>);
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// XXX This can't be statically asserted in general, if ErrorStorageType is
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// not a basic type. With C++20 bit_cast, we could probably re-add such as
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// assertion. static_assert(kNullValue == decltype(kNullValue)(0));
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CompactPair<AlignedStorageOrEmpty<V>, ErrorStorageType> mValue;
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public:
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explicit constexpr ResultImplementationNullIsOkBase(const V& aSuccessValue)
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: mValue(aSuccessValue, kNullValue) {}
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explicit constexpr ResultImplementationNullIsOkBase(V&& aSuccessValue)
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: mValue(std::move(aSuccessValue), kNullValue) {}
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template <typename... Args>
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explicit constexpr ResultImplementationNullIsOkBase(std::in_place_t,
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Args&&... aArgs)
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: mValue(std::piecewise_construct,
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std::tuple(std::in_place, std::forward<Args>(aArgs)...),
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std::tuple(kNullValue)) {}
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explicit constexpr ResultImplementationNullIsOkBase(E aErrorValue)
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: mValue(std::piecewise_construct, std::tuple<>(),
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std::tuple(UnusedZero<E>::Store(std::move(aErrorValue)))) {
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MOZ_ASSERT(mValue.second() != kNullValue);
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}
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constexpr ResultImplementationNullIsOkBase(
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ResultImplementationNullIsOkBase&& aOther)
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: mValue(std::piecewise_construct, std::tuple<>(),
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std::tuple(aOther.mValue.second())) {
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if constexpr (!std::is_empty_v<V>) {
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if (isOk()) {
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new (mValue.first().addr()) V(std::move(*aOther.mValue.first().addr()));
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}
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}
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}
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ResultImplementationNullIsOkBase& operator=(
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ResultImplementationNullIsOkBase&& aOther) {
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if constexpr (!std::is_empty_v<V>) {
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if (isOk()) {
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mValue.first().addr()->~V();
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}
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}
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mValue.second() = std::move(aOther.mValue.second());
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if constexpr (!std::is_empty_v<V>) {
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if (isOk()) {
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new (mValue.first().addr()) V(std::move(*aOther.mValue.first().addr()));
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}
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}
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return *this;
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}
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constexpr bool isOk() const { return mValue.second() == kNullValue; }
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constexpr const V& inspect() const { return *mValue.first().addr(); }
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constexpr V unwrap() { return std::move(*mValue.first().addr()); }
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constexpr decltype(auto) inspectErr() const {
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return UnusedZero<E>::Inspect(mValue.second());
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}
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constexpr E unwrapErr() { return UnusedZero<E>::Unwrap(mValue.second()); }
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};
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template <typename V, typename E,
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bool IsVTriviallyDestructible = std::is_trivially_destructible_v<V>>
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class ResultImplementationNullIsOk;
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template <typename V, typename E>
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class ResultImplementationNullIsOk<V, E, true>
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: public ResultImplementationNullIsOkBase<V, E> {
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public:
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using ResultImplementationNullIsOkBase<V,
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E>::ResultImplementationNullIsOkBase;
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};
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template <typename V, typename E>
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class ResultImplementationNullIsOk<V, E, false>
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: public ResultImplementationNullIsOkBase<V, E> {
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public:
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using ResultImplementationNullIsOkBase<V,
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E>::ResultImplementationNullIsOkBase;
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ResultImplementationNullIsOk(ResultImplementationNullIsOk&&) = default;
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ResultImplementationNullIsOk& operator=(ResultImplementationNullIsOk&&) =
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default;
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~ResultImplementationNullIsOk() {
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if (this->isOk()) {
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this->mValue.first().addr()->~V();
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}
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}
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};
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/**
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* Specialization for when the success type is default-constructible and the
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* error type is a value type which can never have the value 0 (as determined by
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* UnusedZero<>).
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*/
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template <typename V, typename E>
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class ResultImplementation<V, E, PackingStrategy::NullIsOk>
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: public ResultImplementationNullIsOk<V, E> {
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public:
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using ResultImplementationNullIsOk<V, E>::ResultImplementationNullIsOk;
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};
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template <size_t S>
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using UnsignedIntType = std::conditional_t<
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S == 1, std::uint8_t,
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std::conditional_t<
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S == 2, std::uint16_t,
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std::conditional_t<S == 3 || S == 4, std::uint32_t,
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std::conditional_t<S <= 8, std::uint64_t, void>>>>;
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/**
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* Specialization for when alignment permits using the least significant bit
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* as a tag bit.
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*/
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template <typename V, typename E>
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class ResultImplementation<V, E, PackingStrategy::LowBitTagIsError> {
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static_assert(std::is_trivially_copyable_v<V> &&
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std::is_trivially_destructible_v<V>);
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static_assert(std::is_trivially_copyable_v<E> &&
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std::is_trivially_destructible_v<E>);
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static constexpr size_t kRequiredSize = std::max(sizeof(V), sizeof(E));
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using StorageType = UnsignedIntType<kRequiredSize>;
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#if defined(__clang__)
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alignas(std::max(alignof(V), alignof(E))) StorageType mBits;
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#else
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// Some gcc versions choke on using std::max with alignas, see
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// https://gcc.gnu.org/bugzilla/show_bug.cgi?id=94929 (and this seems to have
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// regressed in some gcc 9.x version before being fixed again) Keeping the
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// code above since we would eventually drop this when we no longer support
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// gcc versions with the bug.
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alignas(alignof(V) > alignof(E) ? alignof(V) : alignof(E)) StorageType mBits;
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#endif
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public:
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explicit constexpr ResultImplementation(V aValue) : mBits(0) {
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if constexpr (!std::is_empty_v<V>) {
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std::memcpy(&mBits, &aValue, sizeof(V));
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MOZ_ASSERT((mBits & 1) == 0);
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} else {
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(void)aValue;
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}
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}
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explicit constexpr ResultImplementation(E aErrorValue) : mBits(1) {
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if constexpr (!std::is_empty_v<E>) {
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std::memcpy(&mBits, &aErrorValue, sizeof(E));
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MOZ_ASSERT((mBits & 1) == 0);
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mBits |= 1;
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} else {
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(void)aErrorValue;
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}
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}
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constexpr bool isOk() const { return (mBits & 1) == 0; }
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constexpr V inspect() const {
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V res;
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std::memcpy(&res, &mBits, sizeof(V));
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return res;
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}
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constexpr V unwrap() { return inspect(); }
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constexpr E inspectErr() const {
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const auto bits = mBits ^ 1;
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E res;
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std::memcpy(&res, &bits, sizeof(E));
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return res;
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}
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constexpr E unwrapErr() { return inspectErr(); }
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};
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// Return true if any of the struct can fit in a word.
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template <typename V, typename E>
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struct IsPackableVariant {
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struct VEbool {
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V v;
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E e;
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bool ok;
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};
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struct EVbool {
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E e;
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V v;
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bool ok;
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};
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using Impl =
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std::conditional_t<sizeof(VEbool) <= sizeof(EVbool), VEbool, EVbool>;
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static const bool value = sizeof(Impl) <= sizeof(uintptr_t);
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};
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/**
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* Specialization for when both type are not using all the bytes, in order to
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* use one byte as a tag.
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*/
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template <typename V, typename E>
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class ResultImplementation<V, E, PackingStrategy::PackedVariant> {
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using Impl = typename IsPackableVariant<V, E>::Impl;
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Impl data;
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public:
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explicit constexpr ResultImplementation(V aValue) {
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data.v = std::move(aValue);
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data.ok = true;
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}
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explicit constexpr ResultImplementation(E aErrorValue) {
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data.e = std::move(aErrorValue);
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data.ok = false;
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}
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constexpr bool isOk() const { return data.ok; }
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constexpr const V& inspect() const { return data.v; }
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constexpr V unwrap() { return std::move(data.v); }
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constexpr const E& inspectErr() const { return data.e; }
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constexpr E unwrapErr() { return std::move(data.e); }
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};
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// To use nullptr as a special value, we need the counter part to exclude zero
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// from its range of valid representations.
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//
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// By default assume that zero can be represented.
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template <typename T>
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struct UnusedZero {
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static const bool value = false;
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};
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// This template can be used as a helper for specializing UnusedZero for scoped
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// enum types which never use 0 as an error value, e.g.
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//
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// namespace mozilla::detail {
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//
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// template <>
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// struct UnusedZero<MyEnumType> : UnusedZeroEnum<MyEnumType> {};
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//
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// } // namespace mozilla::detail
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//
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template <typename T>
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struct UnusedZeroEnum {
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using StorageType = std::underlying_type_t<T>;
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static constexpr bool value = true;
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static constexpr StorageType nullValue = 0;
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static constexpr T Inspect(const StorageType& aValue) {
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return static_cast<T>(aValue);
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}
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static constexpr T Unwrap(StorageType aValue) {
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return static_cast<T>(aValue);
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}
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static constexpr StorageType Store(T aValue) {
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return static_cast<StorageType>(aValue);
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}
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};
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// A bit of help figuring out which of the above specializations to use.
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//
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// We begin by safely assuming types don't have a spare bit, unless they are
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// empty.
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template <typename T>
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struct HasFreeLSB {
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static const bool value = std::is_empty_v<T>;
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};
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// As an incomplete type, void* does not have a spare bit.
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template <>
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struct HasFreeLSB<void*> {
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static const bool value = false;
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};
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// The lowest bit of a properly-aligned pointer is always zero if the pointee
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// type is greater than byte-aligned. That bit is free to use if it's masked
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// out of such pointers before they're dereferenced.
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template <typename T>
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struct HasFreeLSB<T*> {
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static const bool value = (alignof(T) & 1) == 0;
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};
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// Select one of the previous result implementation based on the properties of
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// the V and E types.
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template <typename V, typename E>
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struct SelectResultImpl {
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static const PackingStrategy value =
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(HasFreeLSB<V>::value && HasFreeLSB<E>::value)
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? PackingStrategy::LowBitTagIsError
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: (UnusedZero<E>::value && sizeof(E) <= sizeof(uintptr_t))
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? PackingStrategy::NullIsOk
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: (std::is_default_constructible_v<V> &&
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std::is_default_constructible_v<E> && IsPackableVariant<V, E>::value)
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? PackingStrategy::PackedVariant
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: PackingStrategy::Variant;
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using Type = ResultImplementation<V, E, value>;
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};
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template <typename T>
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struct IsResult : std::false_type {};
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template <typename V, typename E>
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struct IsResult<Result<V, E>> : std::true_type {};
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} // namespace detail
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template <typename V, typename E>
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constexpr auto ToResult(Result<V, E>&& aValue)
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-> decltype(std::forward<Result<V, E>>(aValue)) {
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return std::forward<Result<V, E>>(aValue);
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}
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/**
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* Result<V, E> represents the outcome of an operation that can either succeed
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* or fail. It contains either a success value of type V or an error value of
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* type E.
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*
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* All Result methods are const, so results are basically immutable.
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* This is just like Variant<V, E> but with a slightly different API, and the
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* following cases are optimized so Result can be stored more efficiently:
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*
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* - If both the success and error types do not use their least significant bit,
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* are trivially copyable and destructible, Result<V, E> is guaranteed to be as
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* large as the larger type. This is determined via the HasFreeLSB trait. By
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* default, empty classes (in particular Ok) and aligned pointer types are
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* assumed to have a free LSB, but you can specialize this trait for other
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* types. If the success type is empty, the representation is guaranteed to be
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* all zero bits on success. Do not change this representation! There is JIT
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* code that depends on it. (Implementation note: The lowest bit is used as a
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* tag bit: 0 to indicate the Result's bits are a success value, 1 to indicate
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* the Result's bits (with the 1 masked out) encode an error value)
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*
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* - Else, if the error type can't have a all-zero bits representation and is
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* not larger than a pointer, a CompactPair is used to represent this rather
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* than a Variant. This has shown to be better optimizable, and the template
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* code is much simpler than that of Variant, so it should also compile faster.
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* Whether an error type can't be all-zero bits, is determined via the
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* UnusedZero trait. MFBT doesn't declare any public type UnusedZero, but
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* nsresult is declared UnusedZero in XPCOM.
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*
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* The purpose of Result is to reduce the screwups caused by using `false` or
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* `nullptr` to indicate errors.
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* What screwups? See <https://bugzilla.mozilla.org/show_bug.cgi?id=912928> for
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* a partial list.
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*
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* Result<const V, E> or Result<V, const E> are not meaningful. The success or
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* error values in a Result instance are non-modifiable in-place anyway. This
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* guarantee must also be maintained when evolving Result. They can be
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* unwrap()ped, but this loses const qualification. However, Result<const V, E>
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* or Result<V, const E> may be misleading and prevent movability. Just use
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* Result<V, E>. (Result<const V*, E> may make sense though, just Result<const
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* V* const, E> is not possible.)
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*/
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template <typename V, typename E>
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class [[nodiscard]] Result final {
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// See class comment on Result<const V, E> and Result<V, const E>.
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static_assert(!std::is_const_v<V>);
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static_assert(!std::is_const_v<E>);
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static_assert(!std::is_reference_v<V>);
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static_assert(!std::is_reference_v<E>);
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using Impl = typename detail::SelectResultImpl<V, E>::Type;
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Impl mImpl;
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public:
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using ok_type = V;
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using err_type = E;
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/** Create a success result. */
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MOZ_IMPLICIT constexpr Result(V&& aValue) : mImpl(std::forward<V>(aValue)) {
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MOZ_ASSERT(isOk());
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}
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/** Create a success result. */
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MOZ_IMPLICIT constexpr Result(const V& aValue) : mImpl(aValue) {
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MOZ_ASSERT(isOk());
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}
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/** Create a success result in-place. */
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template <typename... Args>
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explicit constexpr Result(std::in_place_t, Args&&... aArgs)
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: mImpl(std::in_place, std::forward<Args>(aArgs)...) {
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MOZ_ASSERT(isOk());
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}
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/** Create an error result. */
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explicit constexpr Result(E aErrorValue) : mImpl(std::move(aErrorValue)) {
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MOZ_ASSERT(isErr());
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}
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/**
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* Create a (success/error) result from another (success/error) result with a
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* different but convertible error type. */
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template <typename E2,
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typename = std::enable_if_t<std::is_convertible_v<E2, E>>>
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MOZ_IMPLICIT constexpr Result(Result<V, E2>&& aOther)
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: mImpl(aOther.isOk() ? Impl{aOther.unwrap()}
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: Impl{aOther.unwrapErr()}) {}
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/**
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* Implementation detail of MOZ_TRY().
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* Create an error result from another error result.
|
|
*/
|
|
template <typename E2>
|
|
MOZ_IMPLICIT constexpr Result(GenericErrorResult<E2>&& aErrorResult)
|
|
: mImpl(std::move(aErrorResult.mErrorValue)) {
|
|
static_assert(std::is_convertible_v<E2, E>, "E2 must be convertible to E");
|
|
MOZ_ASSERT(isErr());
|
|
}
|
|
|
|
/**
|
|
* Implementation detail of MOZ_TRY().
|
|
* Create an error result from another error result.
|
|
*/
|
|
template <typename E2>
|
|
MOZ_IMPLICIT constexpr Result(const GenericErrorResult<E2>& aErrorResult)
|
|
: mImpl(aErrorResult.mErrorValue) {
|
|
static_assert(std::is_convertible_v<E2, E>, "E2 must be convertible to E");
|
|
MOZ_ASSERT(isErr());
|
|
}
|
|
|
|
Result(const Result&) = delete;
|
|
Result(Result&&) = default;
|
|
Result& operator=(const Result&) = delete;
|
|
Result& operator=(Result&&) = default;
|
|
|
|
/** True if this Result is a success result. */
|
|
constexpr bool isOk() const { return mImpl.isOk(); }
|
|
|
|
/** True if this Result is an error result. */
|
|
constexpr bool isErr() const { return !mImpl.isOk(); }
|
|
|
|
/** Take the success value from this Result, which must be a success result.
|
|
*/
|
|
constexpr V unwrap() {
|
|
MOZ_ASSERT(isOk());
|
|
return mImpl.unwrap();
|
|
}
|
|
|
|
/**
|
|
* Take the success value from this Result, which must be a success result.
|
|
* If it is an error result, then return the aValue.
|
|
*/
|
|
constexpr V unwrapOr(V aValue) {
|
|
return MOZ_LIKELY(isOk()) ? mImpl.unwrap() : std::move(aValue);
|
|
}
|
|
|
|
/** Take the error value from this Result, which must be an error result. */
|
|
constexpr E unwrapErr() {
|
|
MOZ_ASSERT(isErr());
|
|
return mImpl.unwrapErr();
|
|
}
|
|
|
|
/** See the success value from this Result, which must be a success result. */
|
|
constexpr decltype(auto) inspect() const {
|
|
static_assert(!std::is_reference_v<
|
|
std::invoke_result_t<decltype(&Impl::inspect), Impl>> ||
|
|
std::is_const_v<std::remove_reference_t<
|
|
std::invoke_result_t<decltype(&Impl::inspect), Impl>>>);
|
|
MOZ_ASSERT(isOk());
|
|
return mImpl.inspect();
|
|
}
|
|
|
|
/** See the error value from this Result, which must be an error result. */
|
|
constexpr decltype(auto) inspectErr() const {
|
|
static_assert(
|
|
!std::is_reference_v<
|
|
std::invoke_result_t<decltype(&Impl::inspectErr), Impl>> ||
|
|
std::is_const_v<std::remove_reference_t<
|
|
std::invoke_result_t<decltype(&Impl::inspectErr), Impl>>>);
|
|
MOZ_ASSERT(isErr());
|
|
return mImpl.inspectErr();
|
|
}
|
|
|
|
/** Propagate the error value from this Result, which must be an error result.
|
|
*
|
|
* This can be used to propagate an error from a function call to the caller
|
|
* with a different value type, but the same error type:
|
|
*
|
|
* Result<T1, E> Func1() {
|
|
* Result<T2, E> res = Func2();
|
|
* if (res.isErr()) { return res.propagateErr(); }
|
|
* }
|
|
*/
|
|
constexpr GenericErrorResult<E> propagateErr() {
|
|
MOZ_ASSERT(isErr());
|
|
return GenericErrorResult<E>{mImpl.unwrapErr(), ErrorPropagationTag{}};
|
|
}
|
|
|
|
/**
|
|
* Map a function V -> V2 over this result's success variant. If this result
|
|
* is an error, do not invoke the function and propagate the error.
|
|
*
|
|
* Mapping over success values invokes the function to produce a new success
|
|
* value:
|
|
*
|
|
* // Map Result<int, E> to another Result<int, E>
|
|
* Result<int, E> res(5);
|
|
* Result<int, E> res2 = res.map([](int x) { return x * x; });
|
|
* MOZ_ASSERT(res.isOk());
|
|
* MOZ_ASSERT(res2.unwrap() == 25);
|
|
*
|
|
* // Map Result<const char*, E> to Result<size_t, E>
|
|
* Result<const char*, E> res("hello, map!");
|
|
* Result<size_t, E> res2 = res.map(strlen);
|
|
* MOZ_ASSERT(res.isOk());
|
|
* MOZ_ASSERT(res2.unwrap() == 11);
|
|
*
|
|
* Mapping over an error does not invoke the function and propagates the
|
|
* error:
|
|
*
|
|
* Result<V, int> res(5);
|
|
* MOZ_ASSERT(res.isErr());
|
|
* Result<V2, int> res2 = res.map([](V v) { ... });
|
|
* MOZ_ASSERT(res2.isErr());
|
|
* MOZ_ASSERT(res2.unwrapErr() == 5);
|
|
*/
|
|
template <typename F>
|
|
constexpr auto map(F f) -> Result<std::result_of_t<F(V)>, E> {
|
|
using RetResult = Result<std::result_of_t<F(V)>, E>;
|
|
return MOZ_LIKELY(isOk()) ? RetResult(f(unwrap())) : RetResult(unwrapErr());
|
|
}
|
|
|
|
/**
|
|
* Map a function E -> E2 over this result's error variant. If this result is
|
|
* a success, do not invoke the function and move the success over.
|
|
*
|
|
* Mapping over error values invokes the function to produce a new error
|
|
* value:
|
|
*
|
|
* // Map Result<V, int> to another Result<V, int>
|
|
* Result<V, int> res(5);
|
|
* Result<V, int> res2 = res.mapErr([](int x) { return x * x; });
|
|
* MOZ_ASSERT(res2.isErr());
|
|
* MOZ_ASSERT(res2.unwrapErr() == 25);
|
|
*
|
|
* // Map Result<V, const char*> to Result<V, size_t>
|
|
* Result<V, const char*> res("hello, mapErr!");
|
|
* Result<V, size_t> res2 = res.mapErr(strlen);
|
|
* MOZ_ASSERT(res2.isErr());
|
|
* MOZ_ASSERT(res2.unwrapErr() == 14);
|
|
*
|
|
* Mapping over a success does not invoke the function and moves the success:
|
|
*
|
|
* Result<int, E> res(5);
|
|
* MOZ_ASSERT(res.isOk());
|
|
* Result<int, E2> res2 = res.mapErr([](E e) { ... });
|
|
* MOZ_ASSERT(res2.isOk());
|
|
* MOZ_ASSERT(res2.unwrap() == 5);
|
|
*/
|
|
template <typename F>
|
|
constexpr auto mapErr(F f) {
|
|
using RetResult = Result<V, std::result_of_t<F(E)>>;
|
|
return MOZ_UNLIKELY(isErr()) ? RetResult(f(unwrapErr()))
|
|
: RetResult(unwrap());
|
|
}
|
|
|
|
/**
|
|
* Map a function E -> Result<V, E2> over this result's error variant. If
|
|
* this result is a success, do not invoke the function and move the success
|
|
* over.
|
|
*
|
|
* `orElse`ing over error values invokes the function to produce a new
|
|
* result:
|
|
*
|
|
* // `orElse` Result<V, int> error variant to another Result<V, int>
|
|
* // error variant or Result<V, int> success variant
|
|
* auto orElse = [](int x) -> Result<V, int> {
|
|
* if (x != 6) {
|
|
* return Err(x * x);
|
|
* }
|
|
* return V(...);
|
|
* };
|
|
*
|
|
* Result<V, int> res(5);
|
|
* auto res2 = res.orElse(orElse);
|
|
* MOZ_ASSERT(res2.isErr());
|
|
* MOZ_ASSERT(res2.unwrapErr() == 25);
|
|
*
|
|
* Result<V, int> res3(6);
|
|
* auto res4 = res3.orElse(orElse);
|
|
* MOZ_ASSERT(res4.isOk());
|
|
* MOZ_ASSERT(res4.unwrap() == ...);
|
|
*
|
|
* // `orElse` Result<V, const char*> error variant to Result<V, size_t>
|
|
* // error variant or Result<V, size_t> success variant
|
|
* auto orElse = [](const char* s) -> Result<V, size_t> {
|
|
* if (strcmp(s, "foo")) {
|
|
* return Err(strlen(s));
|
|
* }
|
|
* return V(...);
|
|
* };
|
|
*
|
|
* Result<V, const char*> res("hello, orElse!");
|
|
* auto res2 = res.orElse(orElse);
|
|
* MOZ_ASSERT(res2.isErr());
|
|
* MOZ_ASSERT(res2.unwrapErr() == 14);
|
|
*
|
|
* Result<V, const char*> res3("foo");
|
|
* auto res4 = ress.orElse(orElse);
|
|
* MOZ_ASSERT(res4.isOk());
|
|
* MOZ_ASSERT(res4.unwrap() == ...);
|
|
*
|
|
* `orElse`ing over a success does not invoke the function and moves the
|
|
* success:
|
|
*
|
|
* Result<int, E> res(5);
|
|
* MOZ_ASSERT(res.isOk());
|
|
* Result<int, E2> res2 = res.orElse([](E e) { ... });
|
|
* MOZ_ASSERT(res2.isOk());
|
|
* MOZ_ASSERT(res2.unwrap() == 5);
|
|
*/
|
|
template <typename F>
|
|
auto orElse(F f) -> Result<V, typename std::result_of_t<F(E)>::err_type> {
|
|
return MOZ_UNLIKELY(isErr()) ? f(unwrapErr()) : unwrap();
|
|
}
|
|
|
|
/**
|
|
* Given a function V -> Result<V2, E>, apply it to this result's success
|
|
* value and return its result. If this result is an error value, it is
|
|
* propagated.
|
|
*
|
|
* This is sometimes called "flatMap" or ">>=" in other contexts.
|
|
*
|
|
* `andThen`ing over success values invokes the function to produce a new
|
|
* result:
|
|
*
|
|
* Result<const char*, Error> res("hello, andThen!");
|
|
* Result<HtmlFreeString, Error> res2 = res.andThen([](const char* s) {
|
|
* return containsHtmlTag(s)
|
|
* ? Result<HtmlFreeString, Error>(Error("Invalid: contains HTML"))
|
|
* : Result<HtmlFreeString, Error>(HtmlFreeString(s));
|
|
* }
|
|
* });
|
|
* MOZ_ASSERT(res2.isOk());
|
|
* MOZ_ASSERT(res2.unwrap() == HtmlFreeString("hello, andThen!");
|
|
*
|
|
* `andThen`ing over error results does not invoke the function, and just
|
|
* propagates the error result:
|
|
*
|
|
* Result<int, const char*> res("some error");
|
|
* auto res2 = res.andThen([](int x) { ... });
|
|
* MOZ_ASSERT(res2.isErr());
|
|
* MOZ_ASSERT(res.unwrapErr() == res2.unwrapErr());
|
|
*/
|
|
template <typename F, typename = std::enable_if_t<detail::IsResult<
|
|
std::invoke_result_t<F, V&&>>::value>>
|
|
constexpr auto andThen(F f) -> std::invoke_result_t<F, V&&> {
|
|
return MOZ_LIKELY(isOk()) ? f(unwrap()) : propagateErr();
|
|
}
|
|
};
|
|
|
|
/**
|
|
* A type that auto-converts to an error Result. This is like a Result without
|
|
* a success type. It's the best return type for functions that always return
|
|
* an error--functions designed to build and populate error objects. It's also
|
|
* useful in error-handling macros; see MOZ_TRY for an example.
|
|
*/
|
|
template <typename E>
|
|
class [[nodiscard]] GenericErrorResult {
|
|
E mErrorValue;
|
|
|
|
template <typename V, typename E2>
|
|
friend class Result;
|
|
|
|
public:
|
|
explicit constexpr GenericErrorResult(const E& aErrorValue)
|
|
: mErrorValue(aErrorValue) {}
|
|
|
|
explicit constexpr GenericErrorResult(E&& aErrorValue)
|
|
: mErrorValue(std::move(aErrorValue)) {}
|
|
|
|
constexpr GenericErrorResult(const E& aErrorValue, const ErrorPropagationTag&)
|
|
: GenericErrorResult(aErrorValue) {}
|
|
|
|
constexpr GenericErrorResult(E&& aErrorValue, const ErrorPropagationTag&)
|
|
: GenericErrorResult(std::move(aErrorValue)) {}
|
|
};
|
|
|
|
template <typename E>
|
|
inline constexpr auto Err(E&& aErrorValue) {
|
|
return GenericErrorResult<std::decay_t<E>>(std::forward<E>(aErrorValue));
|
|
}
|
|
|
|
} // namespace mozilla
|
|
|
|
/**
|
|
* MOZ_TRY(expr) is the C++ equivalent of Rust's `try!(expr);`. First, it
|
|
* evaluates expr, which must produce a Result value. On success, it
|
|
* discards the result altogether. On error, it immediately returns an error
|
|
* Result from the enclosing function.
|
|
*/
|
|
#define MOZ_TRY(expr) \
|
|
do { \
|
|
auto mozTryTempResult_ = ::mozilla::ToResult(expr); \
|
|
if (MOZ_UNLIKELY(mozTryTempResult_.isErr())) { \
|
|
return mozTryTempResult_.propagateErr(); \
|
|
} \
|
|
} while (0)
|
|
|
|
/**
|
|
* MOZ_TRY_VAR(target, expr) is the C++ equivalent of Rust's `target =
|
|
* try!(expr);`. First, it evaluates expr, which must produce a Result value. On
|
|
* success, the result's success value is assigned to target. On error,
|
|
* immediately returns the error result. |target| must be an lvalue.
|
|
*/
|
|
#define MOZ_TRY_VAR(target, expr) \
|
|
do { \
|
|
auto mozTryVarTempResult_ = (expr); \
|
|
if (MOZ_UNLIKELY(mozTryVarTempResult_.isErr())) { \
|
|
return mozTryVarTempResult_.propagateErr(); \
|
|
} \
|
|
(target) = mozTryVarTempResult_.unwrap(); \
|
|
} while (0)
|
|
|
|
#endif // mozilla_Result_h
|