1 | // |
---|
2 | // Cforall Version 1.0.0 Copyright (C) 2020 University of Waterloo |
---|
3 | // |
---|
4 | // The contents of this file are covered under the licence agreement in the |
---|
5 | // file "LICENCE" distributed with Cforall. |
---|
6 | // |
---|
7 | // concurrency/future.hfa -- |
---|
8 | // |
---|
9 | // Author : Thierry Delisle & Peiran Hong & Colby Parsons |
---|
10 | // Created On : Wed Jan 06 17:33:18 2021 |
---|
11 | // Last Modified By : |
---|
12 | // Last Modified On : |
---|
13 | // Update Count : |
---|
14 | // |
---|
15 | |
---|
16 | #pragma once |
---|
17 | |
---|
18 | #include "bits/locks.hfa" |
---|
19 | #include "monitor.hfa" |
---|
20 | #include "select.hfa" |
---|
21 | #include "locks.hfa" |
---|
22 | |
---|
23 | //---------------------------------------------------------------------------- |
---|
24 | // future |
---|
25 | // I don't use future_t here since I need to use a lock for this future |
---|
26 | // since it supports multiple consumers |
---|
27 | // future_t is lockfree and uses atomics which aren't needed given we use locks here |
---|
28 | forall( T ) { |
---|
29 | // enum { FUTURE_EMPTY = 0, FUTURE_FULFILLED = 1 }; // Enums seem to be broken so feel free to add this back afterwards |
---|
30 | |
---|
31 | // temporary enum replacement |
---|
32 | const int FUTURE_EMPTY = 0; |
---|
33 | const int FUTURE_FULFILLED = 1; |
---|
34 | |
---|
35 | struct future { |
---|
36 | int state; |
---|
37 | T result; |
---|
38 | dlist( select_node ) waiters; |
---|
39 | futex_mutex lock; |
---|
40 | }; |
---|
41 | __CFA_SELECT_GET_TYPE( future(T) ); |
---|
42 | |
---|
43 | struct future_node { |
---|
44 | inline select_node; |
---|
45 | T * my_result; |
---|
46 | }; |
---|
47 | |
---|
48 | static inline { |
---|
49 | |
---|
50 | void ?{}( future_node(T) & this, thread$ * blocked_thread, T * my_result ) { |
---|
51 | ((select_node &)this){ blocked_thread }; |
---|
52 | this.my_result = my_result; |
---|
53 | } |
---|
54 | |
---|
55 | void ?{}( future(T) & this ) { |
---|
56 | this.waiters{}; |
---|
57 | this.state = FUTURE_EMPTY; |
---|
58 | this.lock{}; |
---|
59 | } |
---|
60 | |
---|
61 | // Reset future back to original state |
---|
62 | void reset( future(T) & this ) with(this) |
---|
63 | { |
---|
64 | lock( lock ); |
---|
65 | if( ! waiters`isEmpty ) |
---|
66 | abort("Attempting to reset a future with blocked waiters"); |
---|
67 | state = FUTURE_EMPTY; |
---|
68 | unlock( lock ); |
---|
69 | } |
---|
70 | |
---|
71 | // check if the future is available |
---|
72 | // currently no mutual exclusion because I can't see when you need this call to be synchronous or protected |
---|
73 | bool available( future(T) & this ) { return __atomic_load_n( &this.state, __ATOMIC_RELAXED ); } |
---|
74 | |
---|
75 | |
---|
76 | // memcpy wrapper to help copy values |
---|
77 | void copy_T( T & from, T & to ) { |
---|
78 | memcpy((void *)&to, (void *)&from, sizeof(T)); |
---|
79 | } |
---|
80 | |
---|
81 | // internal helper to signal waiters off of the future |
---|
82 | void _internal_flush( future(T) & this ) with(this) { |
---|
83 | while( ! waiters`isEmpty ) { |
---|
84 | if ( !__handle_waituntil_OR( waiters ) ) // handle special waituntil OR case |
---|
85 | break; // if handle_OR returns false then waiters is empty so break |
---|
86 | select_node &s = try_pop_front( waiters ); |
---|
87 | |
---|
88 | if ( s.clause_status == 0p ) // poke in result so that woken threads do not need to reacquire any locks |
---|
89 | copy_T( result, *(((future_node(T) &)s).my_result) ); |
---|
90 | |
---|
91 | wake_one( waiters, s ); |
---|
92 | } |
---|
93 | } |
---|
94 | |
---|
95 | // Fulfil the future, returns whether or not someone was unblocked |
---|
96 | bool fulfil( future(T) & this, T val ) with(this) { |
---|
97 | lock( lock ); |
---|
98 | if( state != FUTURE_EMPTY ) |
---|
99 | abort("Attempting to fulfil a future that has already been fulfilled"); |
---|
100 | |
---|
101 | copy_T( val, result ); |
---|
102 | |
---|
103 | bool ret_val = ! waiters`isEmpty; |
---|
104 | state = FUTURE_FULFILLED; |
---|
105 | _internal_flush( this ); |
---|
106 | unlock( lock ); |
---|
107 | return ret_val; |
---|
108 | } |
---|
109 | |
---|
110 | // Wait for the future to be fulfilled |
---|
111 | // Also return whether the thread had to block or not |
---|
112 | [T, bool] get( future(T) & this ) with( this ) { |
---|
113 | lock( lock ); |
---|
114 | T ret_val; |
---|
115 | if( state == FUTURE_FULFILLED ) { |
---|
116 | copy_T( result, ret_val ); |
---|
117 | unlock( lock ); |
---|
118 | return [ret_val, false]; |
---|
119 | } |
---|
120 | |
---|
121 | future_node(T) node = { active_thread(), &ret_val }; |
---|
122 | insert_last( waiters, ((select_node &)node) ); |
---|
123 | unlock( lock ); |
---|
124 | park( ); |
---|
125 | |
---|
126 | return [ret_val, true]; |
---|
127 | } |
---|
128 | |
---|
129 | // Wait for the future to be fulfilled |
---|
130 | T get( future(T) & this ) { |
---|
131 | [T, bool] tt; |
---|
132 | tt = get(this); |
---|
133 | return tt.0; |
---|
134 | } |
---|
135 | |
---|
136 | // Gets value if it is available and returns [ val, true ] |
---|
137 | // otherwise returns [ default_val, false] |
---|
138 | // will not block |
---|
139 | [T, bool] try_get( future(T) & this ) with(this) { |
---|
140 | lock( lock ); |
---|
141 | T ret_val; |
---|
142 | if( state == FUTURE_FULFILLED ) { |
---|
143 | copy_T( result, ret_val ); |
---|
144 | unlock( lock ); |
---|
145 | return [ret_val, true]; |
---|
146 | } |
---|
147 | unlock( lock ); |
---|
148 | |
---|
149 | return [ret_val, false]; |
---|
150 | } |
---|
151 | |
---|
152 | bool register_select( future(T) & this, select_node & s ) with(this) { |
---|
153 | lock( lock ); |
---|
154 | |
---|
155 | // check if we can complete operation. If so race to establish winner in special OR case |
---|
156 | if ( !s.park_counter && state != FUTURE_EMPTY ) { |
---|
157 | if ( !__make_select_node_available( s ) ) { // we didn't win the race so give up on registering |
---|
158 | unlock( lock ); |
---|
159 | return false; |
---|
160 | } |
---|
161 | } |
---|
162 | |
---|
163 | // future not ready -> insert select node and return |
---|
164 | if( state == FUTURE_EMPTY ) { |
---|
165 | insert_last( waiters, s ); |
---|
166 | unlock( lock ); |
---|
167 | return false; |
---|
168 | } |
---|
169 | |
---|
170 | __make_select_node_available( s ); |
---|
171 | unlock( lock ); |
---|
172 | return true; |
---|
173 | } |
---|
174 | |
---|
175 | bool unregister_select( future(T) & this, select_node & s ) with(this) { |
---|
176 | if ( ! s`isListed ) return false; |
---|
177 | lock( lock ); |
---|
178 | if ( s`isListed ) remove( s ); |
---|
179 | unlock( lock ); |
---|
180 | return false; |
---|
181 | } |
---|
182 | |
---|
183 | bool on_selected( future(T) & this, select_node & node ) { return true; } |
---|
184 | } |
---|
185 | } |
---|
186 | |
---|
187 | //-------------------------------------------------------------------------------------------------------- |
---|
188 | // These futures below do not support select statements so they may not have as many features as 'future' |
---|
189 | // however the 'single_future' is cheap and cheerful and is most likely more performant than 'future' |
---|
190 | // since it uses raw atomics and no locks |
---|
191 | // |
---|
192 | // As far as 'multi_future' goes I can't see many use cases as it will be less performant than 'future' |
---|
193 | // since it is monitor based and also is not compatible with select statements |
---|
194 | //-------------------------------------------------------------------------------------------------------- |
---|
195 | |
---|
196 | forall( T ) { |
---|
197 | struct single_future { |
---|
198 | inline future_t; |
---|
199 | T result; |
---|
200 | }; |
---|
201 | |
---|
202 | static inline { |
---|
203 | // Reset future back to original state |
---|
204 | void reset(single_future(T) & this) { reset( (future_t&)this ); } |
---|
205 | |
---|
206 | // check if the future is available |
---|
207 | bool available( single_future(T) & this ) { return available( (future_t&)this ); } |
---|
208 | |
---|
209 | // Mark the future as abandoned, meaning it will be deleted by the server |
---|
210 | // This doesn't work beause of the potential need for a destructor |
---|
211 | void abandon( single_future(T) & this ); |
---|
212 | |
---|
213 | // Fulfil the future, returns whether or not someone was unblocked |
---|
214 | thread$ * fulfil( single_future(T) & this, T result ) { |
---|
215 | this.result = result; |
---|
216 | return fulfil( (future_t&)this ); |
---|
217 | } |
---|
218 | |
---|
219 | // Wait for the future to be fulfilled |
---|
220 | // Also return whether the thread had to block or not |
---|
221 | [T, bool] wait( single_future(T) & this ) { |
---|
222 | bool r = wait( (future_t&)this ); |
---|
223 | return [this.result, r]; |
---|
224 | } |
---|
225 | |
---|
226 | // Wait for the future to be fulfilled |
---|
227 | T wait( single_future(T) & this ) { |
---|
228 | [T, bool] tt; |
---|
229 | tt = wait(this); |
---|
230 | return tt.0; |
---|
231 | } |
---|
232 | } |
---|
233 | } |
---|
234 | |
---|
235 | forall( T ) { |
---|
236 | monitor multi_future { |
---|
237 | inline future_t; |
---|
238 | condition blocked; |
---|
239 | bool has_first; |
---|
240 | T result; |
---|
241 | }; |
---|
242 | |
---|
243 | static inline { |
---|
244 | void ?{}(multi_future(T) & this) { |
---|
245 | this.has_first = false; |
---|
246 | } |
---|
247 | |
---|
248 | bool $first( multi_future(T) & mutex this ) { |
---|
249 | if (this.has_first) { |
---|
250 | wait( this.blocked ); |
---|
251 | return false; |
---|
252 | } |
---|
253 | |
---|
254 | this.has_first = true; |
---|
255 | return true; |
---|
256 | } |
---|
257 | |
---|
258 | void $first_done( multi_future(T) & mutex this ) { |
---|
259 | this.has_first = false; |
---|
260 | signal_all( this.blocked ); |
---|
261 | } |
---|
262 | |
---|
263 | // Reset future back to original state |
---|
264 | void reset(multi_future(T) & mutex this) { |
---|
265 | if( this.has_first != false) abort("Attempting to reset a multi_future with at least one blocked threads"); |
---|
266 | if( !is_empty(this.blocked) ) abort("Attempting to reset a multi_future with multiple blocked threads"); |
---|
267 | reset( (future_t&)this ); |
---|
268 | } |
---|
269 | |
---|
270 | // Fulfil the future, returns whether or not someone was unblocked |
---|
271 | bool fulfil( multi_future(T) & this, T result ) { |
---|
272 | this.result = result; |
---|
273 | return fulfil( (future_t&)this ) != 0p; |
---|
274 | } |
---|
275 | |
---|
276 | // Wait for the future to be fulfilled |
---|
277 | // Also return whether the thread had to block or not |
---|
278 | [T, bool] wait( multi_future(T) & this ) { |
---|
279 | bool sw = $first( this ); |
---|
280 | bool w = !sw; |
---|
281 | if ( sw ) { |
---|
282 | w = wait( (future_t&)this ); |
---|
283 | $first_done( this ); |
---|
284 | } |
---|
285 | |
---|
286 | return [this.result, w]; |
---|
287 | } |
---|
288 | |
---|
289 | // Wait for the future to be fulfilled |
---|
290 | T wait( multi_future(T) & this ) { |
---|
291 | return wait(this).0; |
---|
292 | } |
---|
293 | } |
---|
294 | } |
---|