Mercurial

comparison third_party/libuv/test/test-ipc-send-recv.c @ 160:948de3f54cea

Find changesets by keywords (author, files, the commit message), revision number or hash, or revset expression.
[ThirdParty] Added libuv
author June Park <parkjune1995@gmail.com>
date Wed, 14 Jan 2026 19:39:52 -0800
parents
children
comparison
equal deleted inserted replaced
159:05cf9467a1c3 160:948de3f54cea
1 /* Copyright Joyent, Inc. and other Node contributors. All rights reserved.
2 *
3 * Permission is hereby granted, free of charge, to any person obtaining a copy
4 * of this software and associated documentation files (the "Software"), to
5 * deal in the Software without restriction, including without limitation the
6 * rights to use, copy, modify, merge, publish, distribute, sublicense, and/or
7 * sell copies of the Software, and to permit persons to whom the Software is
8 * furnished to do so, subject to the following conditions:
9 *
10 * The above copyright notice and this permission notice shall be included in
11 * all copies or substantial portions of the Software.
12 *
13 * THE SOFTWARE IS PROVIDED "AS IS", WITHOUT WARRANTY OF ANY KIND, EXPRESS OR
14 * IMPLIED, INCLUDING BUT NOT LIMITED TO THE WARRANTIES OF MERCHANTABILITY,
15 * FITNESS FOR A PARTICULAR PURPOSE AND NONINFRINGEMENT. IN NO EVENT SHALL THE
16 * AUTHORS OR COPYRIGHT HOLDERS BE LIABLE FOR ANY CLAIM, DAMAGES OR OTHER
17 * LIABILITY, WHETHER IN AN ACTION OF CONTRACT, TORT OR OTHERWISE, ARISING
18 * FROM, OUT OF OR IN CONNECTION WITH THE SOFTWARE OR THE USE OR OTHER DEALINGS
19 * IN THE SOFTWARE.
20 */
21
22 #include "uv.h"
23 #include "task.h"
24
25 #include <stdio.h>
26 #include <string.h>
27
28 /* See test-ipc.c */
29 void spawn_helper(uv_pipe_t* channel,
30 uv_process_t* process,
31 const char* helper);
32
33 void ipc_send_recv_helper_threadproc(void* arg);
34
35 union handles {
36 uv_handle_t handle;
37 uv_stream_t stream;
38 uv_pipe_t pipe;
39 uv_tcp_t tcp;
40 uv_tty_t tty;
41 };
42
43 struct test_ctx {
44 uv_pipe_t channel;
45 uv_connect_t connect_req;
46 uv_write_t write_req;
47 uv_write_t write_req2;
48 uv_handle_type expected_type;
49 union handles send;
50 union handles send2;
51 union handles recv;
52 union handles recv2;
53 };
54
55 struct echo_ctx {
56 uv_pipe_t listen;
57 uv_pipe_t channel;
58 uv_write_t write_req;
59 uv_write_t write_req2;
60 uv_handle_type expected_type;
61 union handles recv;
62 union handles recv2;
63 };
64
65 static struct test_ctx ctx;
66 static struct echo_ctx ctx2;
67
68 /* Used in write2_cb to decide if we need to cleanup or not */
69 static int is_child_process;
70 static int is_in_process;
71 static int read_cb_count;
72 static int recv_cb_count;
73 static int write2_cb_called;
74
75
76 static void alloc_cb(uv_handle_t* handle,
77 size_t suggested_size,
78 uv_buf_t* buf) {
79 /* We're not actually reading anything so a small buffer is okay
80 * but it needs to be heap-allocated to appease TSan.
81 */
82 buf->len = 8;
83 buf->base = malloc(buf->len);
84 ASSERT_NOT_NULL(buf->base);
85 }
86
87
88 static void recv_cb(uv_stream_t* handle,
89 ssize_t nread,
90 const uv_buf_t* buf) {
91 uv_handle_type pending;
92 uv_pipe_t* pipe;
93 int r;
94 union handles* recv;
95
96 free(buf->base);
97
98 pipe = (uv_pipe_t*) handle;
99 ASSERT_PTR_EQ(pipe, &ctx.channel);
100
101 do {
102 if (++recv_cb_count == 1) {
103 recv = &ctx.recv;
104 } else {
105 recv = &ctx.recv2;
106 }
107
108 /* Depending on the OS, the final recv_cb can be called after
109 * the child process has terminated which can result in nread
110 * being UV_EOF instead of the number of bytes read. Since
111 * the other end of the pipe has closed this UV_EOF is an
112 * acceptable value. */
113 if (nread == UV_EOF) {
114 /* UV_EOF is only acceptable for the final recv_cb call */
115 ASSERT_EQ(2, recv_cb_count);
116 } else {
117 ASSERT_GE(nread, 0);
118 ASSERT_GT(uv_pipe_pending_count(pipe), 0);
119
120 pending = uv_pipe_pending_type(pipe);
121 ASSERT_EQ(pending, ctx.expected_type);
122
123 if (pending == UV_NAMED_PIPE)
124 r = uv_pipe_init(ctx.channel.loop, &recv->pipe, 0);
125 else if (pending == UV_TCP)
126 r = uv_tcp_init(ctx.channel.loop, &recv->tcp);
127 else
128 abort();
129 ASSERT_OK(r);
130
131 r = uv_accept(handle, &recv->stream);
132 ASSERT_OK(r);
133 }
134 } while (uv_pipe_pending_count(pipe) > 0);
135
136 /* Close after two writes received */
137 if (recv_cb_count == 2) {
138 uv_close((uv_handle_t*)&ctx.channel, NULL);
139 }
140 }
141
142 static void connect_cb(uv_connect_t* req, int status) {
143 int r;
144 uv_buf_t buf;
145
146 ASSERT_PTR_EQ(req, &ctx.connect_req);
147 ASSERT_OK(status);
148
149 buf = uv_buf_init(".", 1);
150 r = uv_write2(&ctx.write_req,
151 (uv_stream_t*)&ctx.channel,
152 &buf, 1,
153 &ctx.send.stream,
154 NULL);
155 ASSERT_OK(r);
156
157 /* Perform two writes to the same pipe to make sure that on Windows we are
158 * not running into issue 505:
159 * https://github.com/libuv/libuv/issues/505 */
160 buf = uv_buf_init(".", 1);
161 r = uv_write2(&ctx.write_req2,
162 (uv_stream_t*)&ctx.channel,
163 &buf, 1,
164 &ctx.send2.stream,
165 NULL);
166 ASSERT_OK(r);
167
168 r = uv_read_start((uv_stream_t*)&ctx.channel, alloc_cb, recv_cb);
169 ASSERT_OK(r);
170 }
171
172 static int run_test(int inprocess) {
173 uv_process_t process;
174 uv_thread_t tid;
175 int r;
176
177 if (inprocess) {
178 r = uv_thread_create(&tid, ipc_send_recv_helper_threadproc, (void *) 42);
179 ASSERT_OK(r);
180
181 uv_sleep(1000);
182
183 r = uv_pipe_init(uv_default_loop(), &ctx.channel, 1);
184 ASSERT_OK(r);
185
186 uv_pipe_connect(&ctx.connect_req, &ctx.channel, TEST_PIPENAME_3, connect_cb);
187 } else {
188 spawn_helper(&ctx.channel, &process, "ipc_send_recv_helper");
189
190 connect_cb(&ctx.connect_req, 0);
191 }
192
193 r = uv_run(uv_default_loop(), UV_RUN_DEFAULT);
194 ASSERT_OK(r);
195
196 ASSERT_EQ(2, recv_cb_count);
197
198 if (inprocess) {
199 r = uv_thread_join(&tid);
200 ASSERT_OK(r);
201 }
202
203 return 0;
204 }
205
206 static int run_ipc_send_recv_pipe(int inprocess) {
207 int r;
208
209 ctx.expected_type = UV_NAMED_PIPE;
210
211 r = uv_pipe_init(uv_default_loop(), &ctx.send.pipe, 1);
212 ASSERT_OK(r);
213
214 r = uv_pipe_bind(&ctx.send.pipe, TEST_PIPENAME);
215 ASSERT_OK(r);
216
217 r = uv_pipe_init(uv_default_loop(), &ctx.send2.pipe, 1);
218 ASSERT_OK(r);
219
220 r = uv_pipe_bind(&ctx.send2.pipe, TEST_PIPENAME_2);
221 ASSERT_OK(r);
222
223 r = run_test(inprocess);
224 ASSERT_OK(r);
225
226 MAKE_VALGRIND_HAPPY(uv_default_loop());
227 return 0;
228 }
229
230 TEST_IMPL(ipc_send_recv_pipe) {
231 #if defined(NO_SEND_HANDLE_ON_PIPE)
232 RETURN_SKIP(NO_SEND_HANDLE_ON_PIPE);
233 #endif
234 return run_ipc_send_recv_pipe(0);
235 }
236
237 TEST_IMPL(ipc_send_recv_pipe_inprocess) {
238 #if defined(NO_SEND_HANDLE_ON_PIPE)
239 RETURN_SKIP(NO_SEND_HANDLE_ON_PIPE);
240 #endif
241 return run_ipc_send_recv_pipe(1);
242 }
243
244 static int run_ipc_send_recv_tcp(int inprocess) {
245 struct sockaddr_in addr;
246 int r;
247
248 ASSERT_OK(uv_ip4_addr("127.0.0.1", TEST_PORT, &addr));
249
250 ctx.expected_type = UV_TCP;
251
252 r = uv_tcp_init(uv_default_loop(), &ctx.send.tcp);
253 ASSERT_OK(r);
254
255 r = uv_tcp_init(uv_default_loop(), &ctx.send2.tcp);
256 ASSERT_OK(r);
257
258 r = uv_tcp_bind(&ctx.send.tcp, (const struct sockaddr*) &addr, 0);
259 ASSERT_OK(r);
260
261 r = uv_tcp_bind(&ctx.send2.tcp, (const struct sockaddr*) &addr, 0);
262 ASSERT_OK(r);
263
264 r = run_test(inprocess);
265 ASSERT_OK(r);
266
267 MAKE_VALGRIND_HAPPY(uv_default_loop());
268 return 0;
269 }
270
271 TEST_IMPL(ipc_send_recv_tcp) {
272 #if defined(NO_SEND_HANDLE_ON_PIPE)
273 RETURN_SKIP(NO_SEND_HANDLE_ON_PIPE);
274 #endif
275 return run_ipc_send_recv_tcp(0);
276 }
277
278 TEST_IMPL(ipc_send_recv_tcp_inprocess) {
279 #if defined(NO_SEND_HANDLE_ON_PIPE)
280 RETURN_SKIP(NO_SEND_HANDLE_ON_PIPE);
281 #endif
282 return run_ipc_send_recv_tcp(1);
283 }
284
285
286 /* Everything here runs in a child process or second thread. */
287
288 static void write2_cb(uv_write_t* req, int status) {
289 ASSERT_OK(status);
290
291 /* After two successful writes in the child process, allow the child
292 * process to be closed. */
293 if (++write2_cb_called == 2 && (is_child_process || is_in_process)) {
294 uv_close(&ctx2.recv.handle, NULL);
295 uv_close(&ctx2.recv2.handle, NULL);
296 uv_close((uv_handle_t*)&ctx2.channel, NULL);
297 uv_close((uv_handle_t*)&ctx2.listen, NULL);
298 }
299 }
300
301 static void read_cb(uv_stream_t* handle,
302 ssize_t nread,
303 const uv_buf_t* rdbuf) {
304 uv_buf_t wrbuf;
305 uv_pipe_t* pipe;
306 uv_handle_type pending;
307 int r;
308 union handles* recv;
309 uv_write_t* write_req;
310
311 free(rdbuf->base);
312
313 if (nread == UV_EOF || nread == UV_ECONNABORTED) {
314 return;
315 }
316
317 ASSERT_GE(nread, 0);
318
319 pipe = (uv_pipe_t*) handle;
320 ASSERT_PTR_EQ(pipe, &ctx2.channel);
321
322 while (uv_pipe_pending_count(pipe) > 0) {
323 if (++read_cb_count == 2) {
324 recv = &ctx2.recv;
325 write_req = &ctx2.write_req;
326 } else {
327 recv = &ctx2.recv2;
328 write_req = &ctx2.write_req2;
329 }
330
331 pending = uv_pipe_pending_type(pipe);
332 ASSERT(pending == UV_NAMED_PIPE || pending == UV_TCP);
333
334 if (pending == UV_NAMED_PIPE)
335 r = uv_pipe_init(ctx2.channel.loop, &recv->pipe, 0);
336 else if (pending == UV_TCP)
337 r = uv_tcp_init(ctx2.channel.loop, &recv->tcp);
338 else
339 abort();
340 ASSERT_OK(r);
341
342 r = uv_accept(handle, &recv->stream);
343 ASSERT_OK(r);
344
345 wrbuf = uv_buf_init(".", 1);
346 r = uv_write2(write_req,
347 (uv_stream_t*)&ctx2.channel,
348 &wrbuf,
349 1,
350 &recv->stream,
351 write2_cb);
352 ASSERT_OK(r);
353 }
354 }
355
356 static void send_recv_start(void) {
357 int r;
358 ASSERT_EQ(1, uv_is_readable((uv_stream_t*)&ctx2.channel));
359 ASSERT_EQ(1, uv_is_writable((uv_stream_t*)&ctx2.channel));
360 ASSERT_OK(uv_is_closing((uv_handle_t*)&ctx2.channel));
361
362 r = uv_read_start((uv_stream_t*)&ctx2.channel, alloc_cb, read_cb);
363 ASSERT_OK(r);
364 }
365
366 static void listen_cb(uv_stream_t* handle, int status) {
367 int r;
368 ASSERT_PTR_EQ(handle, (uv_stream_t*)&ctx2.listen);
369 ASSERT_OK(status);
370
371 r = uv_accept((uv_stream_t*)&ctx2.listen, (uv_stream_t*)&ctx2.channel);
372 ASSERT_OK(r);
373
374 send_recv_start();
375 }
376
377 int run_ipc_send_recv_helper(uv_loop_t* loop, int inprocess) {
378 int r;
379
380 is_in_process = inprocess;
381
382 memset(&ctx2, 0, sizeof(ctx2));
383
384 r = uv_pipe_init(loop, &ctx2.listen, 0);
385 ASSERT_OK(r);
386
387 r = uv_pipe_init(loop, &ctx2.channel, 1);
388 ASSERT_OK(r);
389
390 if (inprocess) {
391 r = uv_pipe_bind(&ctx2.listen, TEST_PIPENAME_3);
392 ASSERT_OK(r);
393
394 r = uv_listen((uv_stream_t*)&ctx2.listen, SOMAXCONN, listen_cb);
395 ASSERT_OK(r);
396 } else {
397 r = uv_pipe_open(&ctx2.channel, 0);
398 ASSERT_OK(r);
399
400 send_recv_start();
401 }
402
403 notify_parent_process();
404 r = uv_run(loop, UV_RUN_DEFAULT);
405 ASSERT_OK(r);
406
407 return 0;
408 }
409
410 /* stdin is a duplex channel over which a handle is sent.
411 * We receive it and send it back where it came from.
412 */
413 int ipc_send_recv_helper(void) {
414 int r;
415
416 r = run_ipc_send_recv_helper(uv_default_loop(), 0);
417 ASSERT_OK(r);
418
419 MAKE_VALGRIND_HAPPY(uv_default_loop());
420 return 0;
421 }
422
423 void ipc_send_recv_helper_threadproc(void* arg) {
424 int r;
425 uv_loop_t loop;
426
427 r = uv_loop_init(&loop);
428 ASSERT_OK(r);
429
430 r = run_ipc_send_recv_helper(&loop, 1);
431 ASSERT_OK(r);
432
433 r = uv_loop_close(&loop);
434 ASSERT_OK(r);
435 }