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annotate osx/include/kj/async-prelude.h @ 83:ae30d91d2ffe

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Replace these with versions built using an older toolset (so as to avoid ABI compatibilities when linking on Ubuntu 14.04 for packaging purposes)
author Chris Cannam
date Fri, 07 Feb 2020 11:51:13 +0000
parents 0994c39f1e94
children
rev   line source
cannam@62 1 // Copyright (c) 2013-2014 Sandstorm Development Group, Inc. and contributors
cannam@62 2 // Licensed under the MIT License:
cannam@62 3 //
cannam@62 4 // Permission is hereby granted, free of charge, to any person obtaining a copy
cannam@62 5 // of this software and associated documentation files (the "Software"), to deal
cannam@62 6 // in the Software without restriction, including without limitation the rights
cannam@62 7 // to use, copy, modify, merge, publish, distribute, sublicense, and/or sell
cannam@62 8 // copies of the Software, and to permit persons to whom the Software is
cannam@62 9 // furnished to do so, subject to the following conditions:
cannam@62 10 //
cannam@62 11 // The above copyright notice and this permission notice shall be included in
cannam@62 12 // all copies or substantial portions of the Software.
cannam@62 13 //
cannam@62 14 // THE SOFTWARE IS PROVIDED "AS IS", WITHOUT WARRANTY OF ANY KIND, EXPRESS OR
cannam@62 15 // IMPLIED, INCLUDING BUT NOT LIMITED TO THE WARRANTIES OF MERCHANTABILITY,
cannam@62 16 // FITNESS FOR A PARTICULAR PURPOSE AND NONINFRINGEMENT. IN NO EVENT SHALL THE
cannam@62 17 // AUTHORS OR COPYRIGHT HOLDERS BE LIABLE FOR ANY CLAIM, DAMAGES OR OTHER
cannam@62 18 // LIABILITY, WHETHER IN AN ACTION OF CONTRACT, TORT OR OTHERWISE, ARISING FROM,
cannam@62 19 // OUT OF OR IN CONNECTION WITH THE SOFTWARE OR THE USE OR OTHER DEALINGS IN
cannam@62 20 // THE SOFTWARE.
cannam@62 21
cannam@62 22 // This file contains a bunch of internal declarations that must appear before async.h can start.
cannam@62 23 // We don't define these directly in async.h because it makes the file hard to read.
cannam@62 24
cannam@62 25 #ifndef KJ_ASYNC_PRELUDE_H_
cannam@62 26 #define KJ_ASYNC_PRELUDE_H_
cannam@62 27
cannam@62 28 #if defined(__GNUC__) && !KJ_HEADER_WARNINGS
cannam@62 29 #pragma GCC system_header
cannam@62 30 #endif
cannam@62 31
cannam@62 32 #include "exception.h"
cannam@62 33 #include "tuple.h"
cannam@62 34
cannam@62 35 namespace kj {
cannam@62 36
cannam@62 37 class EventLoop;
cannam@62 38 template <typename T>
cannam@62 39 class Promise;
cannam@62 40 class WaitScope;
cannam@62 41
cannam@62 42 template <typename T>
cannam@62 43 Promise<Array<T>> joinPromises(Array<Promise<T>>&& promises);
cannam@62 44 Promise<void> joinPromises(Array<Promise<void>>&& promises);
cannam@62 45
cannam@62 46 namespace _ { // private
cannam@62 47
cannam@62 48 template <typename T> struct JoinPromises_ { typedef T Type; };
cannam@62 49 template <typename T> struct JoinPromises_<Promise<T>> { typedef T Type; };
cannam@62 50
cannam@62 51 template <typename T>
cannam@62 52 using JoinPromises = typename JoinPromises_<T>::Type;
cannam@62 53 // If T is Promise<U>, resolves to U, otherwise resolves to T.
cannam@62 54 //
cannam@62 55 // TODO(cleanup): Rename to avoid confusion with joinPromises() call which is completely
cannam@62 56 // unrelated.
cannam@62 57
cannam@62 58 class PropagateException {
cannam@62 59 // A functor which accepts a kj::Exception as a parameter and returns a broken promise of
cannam@62 60 // arbitrary type which simply propagates the exception.
cannam@62 61 public:
cannam@62 62 class Bottom {
cannam@62 63 public:
cannam@62 64 Bottom(Exception&& exception): exception(kj::mv(exception)) {}
cannam@62 65
cannam@62 66 Exception asException() { return kj::mv(exception); }
cannam@62 67
cannam@62 68 private:
cannam@62 69 Exception exception;
cannam@62 70 };
cannam@62 71
cannam@62 72 Bottom operator()(Exception&& e) {
cannam@62 73 return Bottom(kj::mv(e));
cannam@62 74 }
cannam@62 75 Bottom operator()(const Exception& e) {
cannam@62 76 return Bottom(kj::cp(e));
cannam@62 77 }
cannam@62 78 };
cannam@62 79
cannam@62 80 template <typename Func, typename T>
cannam@62 81 struct ReturnType_ { typedef decltype(instance<Func>()(instance<T>())) Type; };
cannam@62 82 template <typename Func>
cannam@62 83 struct ReturnType_<Func, void> { typedef decltype(instance<Func>()()) Type; };
cannam@62 84
cannam@62 85 template <typename Func, typename T>
cannam@62 86 using ReturnType = typename ReturnType_<Func, T>::Type;
cannam@62 87 // The return type of functor Func given a parameter of type T, with the special exception that if
cannam@62 88 // T is void, this is the return type of Func called with no arguments.
cannam@62 89
cannam@62 90 template <typename T> struct SplitTuplePromise_ { typedef Promise<T> Type; };
cannam@62 91 template <typename... T>
cannam@62 92 struct SplitTuplePromise_<kj::_::Tuple<T...>> {
cannam@62 93 typedef kj::Tuple<Promise<JoinPromises<T>>...> Type;
cannam@62 94 };
cannam@62 95
cannam@62 96 template <typename T>
cannam@62 97 using SplitTuplePromise = typename SplitTuplePromise_<T>::Type;
cannam@62 98 // T -> Promise<T>
cannam@62 99 // Tuple<T> -> Tuple<Promise<T>>
cannam@62 100
cannam@62 101 struct Void {};
cannam@62 102 // Application code should NOT refer to this! See `kj::READY_NOW` instead.
cannam@62 103
cannam@62 104 template <typename T> struct FixVoid_ { typedef T Type; };
cannam@62 105 template <> struct FixVoid_<void> { typedef Void Type; };
cannam@62 106 template <typename T> using FixVoid = typename FixVoid_<T>::Type;
cannam@62 107 // FixVoid<T> is just T unless T is void in which case it is _::Void (an empty struct).
cannam@62 108
cannam@62 109 template <typename T> struct UnfixVoid_ { typedef T Type; };
cannam@62 110 template <> struct UnfixVoid_<Void> { typedef void Type; };
cannam@62 111 template <typename T> using UnfixVoid = typename UnfixVoid_<T>::Type;
cannam@62 112 // UnfixVoid is the opposite of FixVoid.
cannam@62 113
cannam@62 114 template <typename In, typename Out>
cannam@62 115 struct MaybeVoidCaller {
cannam@62 116 // Calls the function converting a Void input to an empty parameter list and a void return
cannam@62 117 // value to a Void output.
cannam@62 118
cannam@62 119 template <typename Func>
cannam@62 120 static inline Out apply(Func& func, In&& in) {
cannam@62 121 return func(kj::mv(in));
cannam@62 122 }
cannam@62 123 };
cannam@62 124 template <typename In, typename Out>
cannam@62 125 struct MaybeVoidCaller<In&, Out> {
cannam@62 126 template <typename Func>
cannam@62 127 static inline Out apply(Func& func, In& in) {
cannam@62 128 return func(in);
cannam@62 129 }
cannam@62 130 };
cannam@62 131 template <typename Out>
cannam@62 132 struct MaybeVoidCaller<Void, Out> {
cannam@62 133 template <typename Func>
cannam@62 134 static inline Out apply(Func& func, Void&& in) {
cannam@62 135 return func();
cannam@62 136 }
cannam@62 137 };
cannam@62 138 template <typename In>
cannam@62 139 struct MaybeVoidCaller<In, Void> {
cannam@62 140 template <typename Func>
cannam@62 141 static inline Void apply(Func& func, In&& in) {
cannam@62 142 func(kj::mv(in));
cannam@62 143 return Void();
cannam@62 144 }
cannam@62 145 };
cannam@62 146 template <typename In>
cannam@62 147 struct MaybeVoidCaller<In&, Void> {
cannam@62 148 template <typename Func>
cannam@62 149 static inline Void apply(Func& func, In& in) {
cannam@62 150 func(in);
cannam@62 151 return Void();
cannam@62 152 }
cannam@62 153 };
cannam@62 154 template <>
cannam@62 155 struct MaybeVoidCaller<Void, Void> {
cannam@62 156 template <typename Func>
cannam@62 157 static inline Void apply(Func& func, Void&& in) {
cannam@62 158 func();
cannam@62 159 return Void();
cannam@62 160 }
cannam@62 161 };
cannam@62 162
cannam@62 163 template <typename T>
cannam@62 164 inline T&& returnMaybeVoid(T&& t) {
cannam@62 165 return kj::fwd<T>(t);
cannam@62 166 }
cannam@62 167 inline void returnMaybeVoid(Void&& v) {}
cannam@62 168
cannam@62 169 class ExceptionOrValue;
cannam@62 170 class PromiseNode;
cannam@62 171 class ChainPromiseNode;
cannam@62 172 template <typename T>
cannam@62 173 class ForkHub;
cannam@62 174
cannam@62 175 class TaskSetImpl;
cannam@62 176
cannam@62 177 class Event;
cannam@62 178
cannam@62 179 class PromiseBase {
cannam@62 180 public:
cannam@62 181 kj::String trace();
cannam@62 182 // Dump debug info about this promise.
cannam@62 183
cannam@62 184 private:
cannam@62 185 Own<PromiseNode> node;
cannam@62 186
cannam@62 187 PromiseBase() = default;
cannam@62 188 PromiseBase(Own<PromiseNode>&& node): node(kj::mv(node)) {}
cannam@62 189
cannam@62 190 friend class kj::EventLoop;
cannam@62 191 friend class ChainPromiseNode;
cannam@62 192 template <typename>
cannam@62 193 friend class kj::Promise;
cannam@62 194 friend class TaskSetImpl;
cannam@62 195 template <typename U>
cannam@62 196 friend Promise<Array<U>> kj::joinPromises(Array<Promise<U>>&& promises);
cannam@62 197 friend Promise<void> kj::joinPromises(Array<Promise<void>>&& promises);
cannam@62 198 };
cannam@62 199
cannam@62 200 void detach(kj::Promise<void>&& promise);
cannam@62 201 void waitImpl(Own<_::PromiseNode>&& node, _::ExceptionOrValue& result, WaitScope& waitScope);
cannam@62 202 Promise<void> yield();
cannam@62 203 Own<PromiseNode> neverDone();
cannam@62 204
cannam@62 205 class NeverDone {
cannam@62 206 public:
cannam@62 207 template <typename T>
cannam@62 208 operator Promise<T>() const {
cannam@62 209 return Promise<T>(false, neverDone());
cannam@62 210 }
cannam@62 211
cannam@62 212 KJ_NORETURN(void wait(WaitScope& waitScope) const);
cannam@62 213 };
cannam@62 214
cannam@62 215 } // namespace _ (private)
cannam@62 216 } // namespace kj
cannam@62 217
cannam@62 218 #endif // KJ_ASYNC_PRELUDE_H_