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annotate win32-mingw/include/kj/async-prelude.h @ 150:0a1a4a299a5d

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OSX binaries for Cap'n Proto
author Chris Cannam <cannam@all-day-breakfast.com>
date Wed, 05 Jul 2017 09:46:34 +0100
parents 279b18cc7785
children
rev   line source
cannam@149 1 // Copyright (c) 2013-2014 Sandstorm Development Group, Inc. and contributors
cannam@149 2 // Licensed under the MIT License:
cannam@149 3 //
cannam@149 4 // Permission is hereby granted, free of charge, to any person obtaining a copy
cannam@149 5 // of this software and associated documentation files (the "Software"), to deal
cannam@149 6 // in the Software without restriction, including without limitation the rights
cannam@149 7 // to use, copy, modify, merge, publish, distribute, sublicense, and/or sell
cannam@149 8 // copies of the Software, and to permit persons to whom the Software is
cannam@149 9 // furnished to do so, subject to the following conditions:
cannam@149 10 //
cannam@149 11 // The above copyright notice and this permission notice shall be included in
cannam@149 12 // all copies or substantial portions of the Software.
cannam@149 13 //
cannam@149 14 // THE SOFTWARE IS PROVIDED "AS IS", WITHOUT WARRANTY OF ANY KIND, EXPRESS OR
cannam@149 15 // IMPLIED, INCLUDING BUT NOT LIMITED TO THE WARRANTIES OF MERCHANTABILITY,
cannam@149 16 // FITNESS FOR A PARTICULAR PURPOSE AND NONINFRINGEMENT. IN NO EVENT SHALL THE
cannam@149 17 // AUTHORS OR COPYRIGHT HOLDERS BE LIABLE FOR ANY CLAIM, DAMAGES OR OTHER
cannam@149 18 // LIABILITY, WHETHER IN AN ACTION OF CONTRACT, TORT OR OTHERWISE, ARISING FROM,
cannam@149 19 // OUT OF OR IN CONNECTION WITH THE SOFTWARE OR THE USE OR OTHER DEALINGS IN
cannam@149 20 // THE SOFTWARE.
cannam@149 21
cannam@149 22 // This file contains a bunch of internal declarations that must appear before async.h can start.
cannam@149 23 // We don't define these directly in async.h because it makes the file hard to read.
cannam@149 24
cannam@149 25 #ifndef KJ_ASYNC_PRELUDE_H_
cannam@149 26 #define KJ_ASYNC_PRELUDE_H_
cannam@149 27
cannam@149 28 #if defined(__GNUC__) && !KJ_HEADER_WARNINGS
cannam@149 29 #pragma GCC system_header
cannam@149 30 #endif
cannam@149 31
cannam@149 32 #include "exception.h"
cannam@149 33 #include "tuple.h"
cannam@149 34
cannam@149 35 namespace kj {
cannam@149 36
cannam@149 37 class EventLoop;
cannam@149 38 template <typename T>
cannam@149 39 class Promise;
cannam@149 40 class WaitScope;
cannam@149 41
cannam@149 42 template <typename T>
cannam@149 43 Promise<Array<T>> joinPromises(Array<Promise<T>>&& promises);
cannam@149 44 Promise<void> joinPromises(Array<Promise<void>>&& promises);
cannam@149 45
cannam@149 46 namespace _ { // private
cannam@149 47
cannam@149 48 template <typename T> struct JoinPromises_ { typedef T Type; };
cannam@149 49 template <typename T> struct JoinPromises_<Promise<T>> { typedef T Type; };
cannam@149 50
cannam@149 51 template <typename T>
cannam@149 52 using JoinPromises = typename JoinPromises_<T>::Type;
cannam@149 53 // If T is Promise<U>, resolves to U, otherwise resolves to T.
cannam@149 54 //
cannam@149 55 // TODO(cleanup): Rename to avoid confusion with joinPromises() call which is completely
cannam@149 56 // unrelated.
cannam@149 57
cannam@149 58 class PropagateException {
cannam@149 59 // A functor which accepts a kj::Exception as a parameter and returns a broken promise of
cannam@149 60 // arbitrary type which simply propagates the exception.
cannam@149 61 public:
cannam@149 62 class Bottom {
cannam@149 63 public:
cannam@149 64 Bottom(Exception&& exception): exception(kj::mv(exception)) {}
cannam@149 65
cannam@149 66 Exception asException() { return kj::mv(exception); }
cannam@149 67
cannam@149 68 private:
cannam@149 69 Exception exception;
cannam@149 70 };
cannam@149 71
cannam@149 72 Bottom operator()(Exception&& e) {
cannam@149 73 return Bottom(kj::mv(e));
cannam@149 74 }
cannam@149 75 Bottom operator()(const Exception& e) {
cannam@149 76 return Bottom(kj::cp(e));
cannam@149 77 }
cannam@149 78 };
cannam@149 79
cannam@149 80 template <typename Func, typename T>
cannam@149 81 struct ReturnType_ { typedef decltype(instance<Func>()(instance<T>())) Type; };
cannam@149 82 template <typename Func>
cannam@149 83 struct ReturnType_<Func, void> { typedef decltype(instance<Func>()()) Type; };
cannam@149 84
cannam@149 85 template <typename Func, typename T>
cannam@149 86 using ReturnType = typename ReturnType_<Func, T>::Type;
cannam@149 87 // The return type of functor Func given a parameter of type T, with the special exception that if
cannam@149 88 // T is void, this is the return type of Func called with no arguments.
cannam@149 89
cannam@149 90 template <typename T> struct SplitTuplePromise_ { typedef Promise<T> Type; };
cannam@149 91 template <typename... T>
cannam@149 92 struct SplitTuplePromise_<kj::_::Tuple<T...>> {
cannam@149 93 typedef kj::Tuple<Promise<JoinPromises<T>>...> Type;
cannam@149 94 };
cannam@149 95
cannam@149 96 template <typename T>
cannam@149 97 using SplitTuplePromise = typename SplitTuplePromise_<T>::Type;
cannam@149 98 // T -> Promise<T>
cannam@149 99 // Tuple<T> -> Tuple<Promise<T>>
cannam@149 100
cannam@149 101 struct Void {};
cannam@149 102 // Application code should NOT refer to this! See `kj::READY_NOW` instead.
cannam@149 103
cannam@149 104 template <typename T> struct FixVoid_ { typedef T Type; };
cannam@149 105 template <> struct FixVoid_<void> { typedef Void Type; };
cannam@149 106 template <typename T> using FixVoid = typename FixVoid_<T>::Type;
cannam@149 107 // FixVoid<T> is just T unless T is void in which case it is _::Void (an empty struct).
cannam@149 108
cannam@149 109 template <typename T> struct UnfixVoid_ { typedef T Type; };
cannam@149 110 template <> struct UnfixVoid_<Void> { typedef void Type; };
cannam@149 111 template <typename T> using UnfixVoid = typename UnfixVoid_<T>::Type;
cannam@149 112 // UnfixVoid is the opposite of FixVoid.
cannam@149 113
cannam@149 114 template <typename In, typename Out>
cannam@149 115 struct MaybeVoidCaller {
cannam@149 116 // Calls the function converting a Void input to an empty parameter list and a void return
cannam@149 117 // value to a Void output.
cannam@149 118
cannam@149 119 template <typename Func>
cannam@149 120 static inline Out apply(Func& func, In&& in) {
cannam@149 121 return func(kj::mv(in));
cannam@149 122 }
cannam@149 123 };
cannam@149 124 template <typename In, typename Out>
cannam@149 125 struct MaybeVoidCaller<In&, Out> {
cannam@149 126 template <typename Func>
cannam@149 127 static inline Out apply(Func& func, In& in) {
cannam@149 128 return func(in);
cannam@149 129 }
cannam@149 130 };
cannam@149 131 template <typename Out>
cannam@149 132 struct MaybeVoidCaller<Void, Out> {
cannam@149 133 template <typename Func>
cannam@149 134 static inline Out apply(Func& func, Void&& in) {
cannam@149 135 return func();
cannam@149 136 }
cannam@149 137 };
cannam@149 138 template <typename In>
cannam@149 139 struct MaybeVoidCaller<In, Void> {
cannam@149 140 template <typename Func>
cannam@149 141 static inline Void apply(Func& func, In&& in) {
cannam@149 142 func(kj::mv(in));
cannam@149 143 return Void();
cannam@149 144 }
cannam@149 145 };
cannam@149 146 template <typename In>
cannam@149 147 struct MaybeVoidCaller<In&, Void> {
cannam@149 148 template <typename Func>
cannam@149 149 static inline Void apply(Func& func, In& in) {
cannam@149 150 func(in);
cannam@149 151 return Void();
cannam@149 152 }
cannam@149 153 };
cannam@149 154 template <>
cannam@149 155 struct MaybeVoidCaller<Void, Void> {
cannam@149 156 template <typename Func>
cannam@149 157 static inline Void apply(Func& func, Void&& in) {
cannam@149 158 func();
cannam@149 159 return Void();
cannam@149 160 }
cannam@149 161 };
cannam@149 162
cannam@149 163 template <typename T>
cannam@149 164 inline T&& returnMaybeVoid(T&& t) {
cannam@149 165 return kj::fwd<T>(t);
cannam@149 166 }
cannam@149 167 inline void returnMaybeVoid(Void&& v) {}
cannam@149 168
cannam@149 169 class ExceptionOrValue;
cannam@149 170 class PromiseNode;
cannam@149 171 class ChainPromiseNode;
cannam@149 172 template <typename T>
cannam@149 173 class ForkHub;
cannam@149 174
cannam@149 175 class TaskSetImpl;
cannam@149 176
cannam@149 177 class Event;
cannam@149 178
cannam@149 179 class PromiseBase {
cannam@149 180 public:
cannam@149 181 kj::String trace();
cannam@149 182 // Dump debug info about this promise.
cannam@149 183
cannam@149 184 private:
cannam@149 185 Own<PromiseNode> node;
cannam@149 186
cannam@149 187 PromiseBase() = default;
cannam@149 188 PromiseBase(Own<PromiseNode>&& node): node(kj::mv(node)) {}
cannam@149 189
cannam@149 190 friend class kj::EventLoop;
cannam@149 191 friend class ChainPromiseNode;
cannam@149 192 template <typename>
cannam@149 193 friend class kj::Promise;
cannam@149 194 friend class TaskSetImpl;
cannam@149 195 template <typename U>
cannam@149 196 friend Promise<Array<U>> kj::joinPromises(Array<Promise<U>>&& promises);
cannam@149 197 friend Promise<void> kj::joinPromises(Array<Promise<void>>&& promises);
cannam@149 198 };
cannam@149 199
cannam@149 200 void detach(kj::Promise<void>&& promise);
cannam@149 201 void waitImpl(Own<_::PromiseNode>&& node, _::ExceptionOrValue& result, WaitScope& waitScope);
cannam@149 202 Promise<void> yield();
cannam@149 203 Own<PromiseNode> neverDone();
cannam@149 204
cannam@149 205 class NeverDone {
cannam@149 206 public:
cannam@149 207 template <typename T>
cannam@149 208 operator Promise<T>() const {
cannam@149 209 return Promise<T>(false, neverDone());
cannam@149 210 }
cannam@149 211
cannam@149 212 KJ_NORETURN(void wait(WaitScope& waitScope) const);
cannam@149 213 };
cannam@149 214
cannam@149 215 } // namespace _ (private)
cannam@149 216 } // namespace kj
cannam@149 217
cannam@149 218 #endif // KJ_ASYNC_PRELUDE_H_