| // Copyright 2016 The Fuchsia Authors. All rights reserved. |
| // Use of this source code is governed by a BSD-style license that can be |
| // found in the LICENSE file. |
| |
| #include <zircon/assert.h> |
| #include <zircon/compiler.h> |
| #include <zircon/rights.h> |
| #include <zircon/syscalls.h> |
| #include <zircon/syscalls/object.h> |
| #include <unittest/unittest.h> |
| #include <stdbool.h> |
| #include <stdio.h> |
| #include <stdlib.h> |
| #include <threads.h> |
| #include <unistd.h> |
| |
| static zx_handle_t _channel[4]; |
| |
| /** |
| * Channel tests with wait multiple. |
| * |
| * Tests signal state persistence and various combinations of states on multiple handles. |
| * |
| * Test sequence (may not be exact due to concurrency): |
| * 1. Create 2 channels and start a reader thread. |
| * 2. Reader blocks wait on both channels. |
| * 3. Write to both channels and yield. |
| * 4. Reader wake up with channel 1 and channel 2 readable. |
| * 5. Reader reads from channel 1, and calls wait again. |
| * 6. Reader should wake up immediately, with channel 1 not readable and channel 2 readable. |
| * 7. Reader blocks on wait. |
| * 8. Write to channel 1 and yield. |
| * 9. Reader wake up with channel 1 readable and reads from channel 1. |
| * 10. Reader blocks on wait. |
| * 11. Write to channel 2 and close both channels, then yield. |
| * 12. Reader wake up with channel 2 closed and readable. |
| * 13. Read from channel 2 and wait. |
| * 14. Reader wake up with channel 2 closed, closes both channels and exit. |
| */ |
| |
| static int reader_thread(void* arg) { |
| const unsigned int index = 2; |
| zx_handle_t* channel = &_channel[index]; |
| __UNUSED zx_status_t status; |
| unsigned int packets[2] = {0, 0}; |
| bool closed[2] = {false, false}; |
| zx_wait_item_t items[2]; |
| items[0].handle = channel[0]; |
| items[1].handle = channel[1]; |
| items[0].waitfor = ZX_CHANNEL_READABLE | ZX_CHANNEL_PEER_CLOSED; |
| items[1].waitfor = ZX_CHANNEL_READABLE | ZX_CHANNEL_PEER_CLOSED; |
| do { |
| status = zx_object_wait_many(items, 2, ZX_TIME_INFINITE); |
| ZX_ASSERT(status == ZX_OK); |
| uint32_t data; |
| uint32_t num_bytes = sizeof(uint32_t); |
| if (items[0].pending & ZX_CHANNEL_READABLE) { |
| status = zx_channel_read(channel[0], 0u, &data, NULL, |
| num_bytes, 0, &num_bytes, NULL); |
| ZX_ASSERT(status == ZX_OK); |
| packets[0] += 1; |
| } else if (items[1].pending & ZX_CHANNEL_READABLE) { |
| status = zx_channel_read(channel[1], 0u, &data, NULL, |
| num_bytes, 0, &num_bytes, NULL); |
| ZX_ASSERT(status == ZX_OK); |
| packets[1] += 1; |
| } else { |
| if (items[0].pending & ZX_CHANNEL_PEER_CLOSED) |
| closed[0] = true; |
| if (items[1].pending & ZX_CHANNEL_PEER_CLOSED) |
| closed[1] = true; |
| } |
| } while (!closed[0] || !closed[1]); |
| ZX_ASSERT(packets[0] == 3); |
| ZX_ASSERT(packets[1] == 2); |
| return 0; |
| } |
| |
| static zx_signals_t get_satisfied_signals(zx_handle_t handle) { |
| zx_signals_t pending = 0; |
| zx_status_t status = zx_object_wait_one(handle, 0u, 0u, &pending); |
| ZX_ASSERT(status == ZX_ERR_TIMED_OUT); |
| return pending; |
| } |
| |
| static bool channel_test(void) { |
| BEGIN_TEST; |
| |
| zx_status_t status; |
| |
| zx_handle_t h[2]; |
| status = zx_channel_create(0, &h[0], &h[1]); |
| ASSERT_EQ(status, ZX_OK, "error in channel create"); |
| |
| // Check that koids line up. |
| zx_info_handle_basic_t info[2] = {}; |
| status = zx_object_get_info(h[0], ZX_INFO_HANDLE_BASIC, &info[0], sizeof(info[0]), NULL, NULL); |
| ASSERT_EQ(status, ZX_OK, ""); |
| status = zx_object_get_info(h[1], ZX_INFO_HANDLE_BASIC, &info[1], sizeof(info[1]), NULL, NULL); |
| ASSERT_EQ(status, ZX_OK, ""); |
| ASSERT_NE(info[0].koid, 0u, "zero koid!"); |
| ASSERT_NE(info[0].related_koid, 0u, "zero peer koid!"); |
| ASSERT_NE(info[1].koid, 0u, "zero koid!"); |
| ASSERT_NE(info[1].related_koid, 0u, "zero peer koid!"); |
| ASSERT_EQ(info[0].koid, info[1].related_koid, "mismatched koids!"); |
| ASSERT_EQ(info[1].koid, info[0].related_koid, "mismatched koids!"); |
| |
| ASSERT_EQ(get_satisfied_signals(h[0]), ZX_CHANNEL_WRITABLE, ""); |
| ASSERT_EQ(get_satisfied_signals(h[1]), ZX_CHANNEL_WRITABLE, ""); |
| |
| _channel[0] = h[0]; |
| _channel[2] = h[1]; |
| |
| static const uint32_t write_data = 0xdeadbeef; |
| status = zx_channel_write(_channel[0], 0u, &write_data, sizeof(uint32_t), NULL, 0u); |
| ASSERT_EQ(status, ZX_OK, "error in message write"); |
| ASSERT_EQ(get_satisfied_signals( |
| _channel[0]), ZX_CHANNEL_WRITABLE, ""); |
| ASSERT_EQ(get_satisfied_signals( |
| _channel[2]), ZX_CHANNEL_READABLE | ZX_CHANNEL_WRITABLE, ""); |
| |
| status = zx_channel_create(0, &h[0], &h[1]); |
| ASSERT_EQ(status, ZX_OK, "error in channel create"); |
| |
| _channel[1] = h[0]; |
| _channel[3] = h[1]; |
| |
| thrd_t thread; |
| ASSERT_EQ(thrd_create(&thread, reader_thread, NULL), thrd_success, "error in thread create"); |
| |
| status = zx_channel_write(_channel[1], 0u, &write_data, sizeof(uint32_t), NULL, 0u); |
| ASSERT_EQ(status, ZX_OK, "error in message write"); |
| |
| usleep(1); |
| |
| status = zx_channel_write(_channel[0], 0u, &write_data, sizeof(uint32_t), NULL, 0u); |
| ASSERT_EQ(status, ZX_OK, "error in message write"); |
| |
| status = zx_channel_write(_channel[0], 0u, &write_data, sizeof(uint32_t), NULL, 0u); |
| ASSERT_EQ(status, ZX_OK, "error in message write"); |
| |
| usleep(1); |
| |
| status = zx_channel_write(_channel[1], 0u, &write_data, sizeof(uint32_t), NULL, 0u); |
| ASSERT_EQ(status, ZX_OK, "error in message write"); |
| |
| zx_handle_close(_channel[1]); |
| // The reader thread is reading from _channel[3], so we may or may not have "readable". |
| ASSERT_TRUE((get_satisfied_signals(_channel[3]) & ZX_CHANNEL_PEER_CLOSED), ""); |
| |
| usleep(1); |
| zx_handle_close(_channel[0]); |
| |
| EXPECT_EQ(thrd_join(thread, NULL), thrd_success, "error in thread join"); |
| |
| // Since the the other side of _channel[3] is closed, and the read thread read everything |
| // from it, the only satisfied/satisfiable signals should be "peer closed". |
| ASSERT_EQ(get_satisfied_signals( |
| _channel[3]), ZX_CHANNEL_PEER_CLOSED, ""); |
| |
| zx_handle_close(_channel[2]); |
| zx_handle_close(_channel[3]); |
| |
| END_TEST; |
| } |
| |
| static bool channel_read_error_test(void) { |
| BEGIN_TEST; |
| zx_handle_t channel[2]; |
| zx_status_t status = zx_channel_create(0, &channel[0], &channel[1]); |
| ASSERT_EQ(status, ZX_OK, "error in channel create"); |
| |
| // Read from an empty channel. |
| status = zx_channel_read(channel[0], 0u, NULL, NULL, 0, 0, NULL, NULL); |
| ASSERT_EQ(status, ZX_ERR_SHOULD_WAIT, "read on empty non-closed channel produced incorrect error"); |
| |
| char data = 'x'; |
| status = zx_channel_write(channel[1], 0u, &data, 1u, NULL, 0u); |
| ASSERT_EQ(status, ZX_OK, "write failed"); |
| |
| zx_handle_close(channel[1]); |
| |
| // Read a message with the peer closed, should yield the message. |
| char read_data = '\0'; |
| uint32_t read_data_size = 1u; |
| status = zx_channel_read(channel[0], 0u, &read_data, NULL, |
| read_data_size, 0, &read_data_size, NULL); |
| ASSERT_EQ(status, ZX_OK, "read failed with peer closed but message in the channel"); |
| ASSERT_EQ(read_data_size, 1u, "read returned incorrect number of bytes"); |
| ASSERT_EQ(read_data, 'x', "read returned incorrect data"); |
| |
| // Read from an empty channel with a closed peer, should yield a channel closed error. |
| status = zx_channel_read(channel[0], 0u, NULL, NULL, 0, 0, NULL, NULL); |
| ASSERT_EQ(status, ZX_ERR_PEER_CLOSED, "read on empty closed channel produced incorrect error"); |
| |
| END_TEST; |
| } |
| |
| static bool channel_close_test(void) { |
| BEGIN_TEST; |
| zx_handle_t channel[2]; |
| |
| // Channels should gain PEER_CLOSED (and lose WRITABLE) if their peer is closed |
| ASSERT_EQ(zx_channel_create(0, &channel[0], &channel[1]), ZX_OK, ""); |
| ASSERT_EQ(zx_handle_close(channel[1]), ZX_OK, ""); |
| ASSERT_EQ(get_satisfied_signals( |
| channel[0]), ZX_CHANNEL_PEER_CLOSED, ""); |
| ASSERT_EQ(zx_handle_close(channel[0]), ZX_OK, ""); |
| |
| ASSERT_EQ(zx_channel_create(0, &channel[0], &channel[1]), ZX_OK, ""); |
| zx_handle_t channel1[2]; |
| ASSERT_EQ(zx_channel_create(0, &channel1[0], &channel1[1]), ZX_OK, ""); |
| zx_handle_t channel2[2]; |
| ASSERT_EQ(zx_channel_create(0, &channel2[0], &channel2[1]), ZX_OK, ""); |
| |
| // Write channel1[0] to channel[0] (to be received by channel[1]) |
| // and channel2[0] to channel[1] (to be received by channel[0]). |
| ASSERT_EQ(zx_channel_write(channel[0], 0u, NULL, 0u, &channel1[0], 1u), ZX_OK, ""); |
| channel1[0] = ZX_HANDLE_INVALID; |
| ASSERT_EQ(zx_channel_write(channel[1], 0u, NULL, 0u, &channel2[0], 1u), ZX_OK, ""); |
| channel2[0] = ZX_HANDLE_INVALID; |
| |
| // Close channel[1]; the former channel1[0] should be closed, so channel1[1] should have |
| // peer closed. |
| ASSERT_EQ(zx_handle_close(channel[1]), ZX_OK, ""); |
| channel[1] = ZX_HANDLE_INVALID; |
| ASSERT_EQ(zx_object_wait_one( |
| channel1[1], ZX_CHANNEL_PEER_CLOSED, ZX_TIME_INFINITE, NULL), ZX_OK, ""); |
| ASSERT_EQ(get_satisfied_signals( |
| channel2[1]), ZX_CHANNEL_WRITABLE, ""); |
| |
| // Close channel[0]; the former channel2[0] should be closed, so channel2[1] |
| // should have peer closed. |
| ASSERT_EQ(zx_handle_close(channel[0]), ZX_OK, ""); |
| channel[0] = ZX_HANDLE_INVALID; |
| ASSERT_EQ(get_satisfied_signals( |
| channel1[1]), ZX_CHANNEL_PEER_CLOSED, ""); |
| ASSERT_EQ(zx_object_wait_one( |
| channel2[1], ZX_CHANNEL_PEER_CLOSED, ZX_TIME_INFINITE, NULL), ZX_OK, ""); |
| |
| ASSERT_EQ(zx_handle_close(channel1[1]), ZX_OK, ""); |
| ASSERT_EQ(zx_handle_close(channel2[1]), ZX_OK, ""); |
| |
| END_TEST; |
| } |
| |
| static bool channel_peer_closed_test(void) { |
| BEGIN_TEST; |
| |
| zx_handle_t channel[2]; |
| ASSERT_EQ(zx_channel_create(0, &channel[0], &channel[1]), ZX_OK, ""); |
| ASSERT_EQ(zx_handle_close(channel[1]), ZX_OK, ""); |
| ASSERT_EQ(zx_object_signal_peer(channel[0], 0u, ZX_USER_SIGNAL_0), ZX_ERR_PEER_CLOSED, ""); |
| ASSERT_EQ(zx_handle_close(channel[0]), ZX_OK, ""); |
| |
| END_TEST; |
| } |
| |
| static bool channel_non_transferable(void) { |
| BEGIN_TEST; |
| |
| zx_handle_t channel[2]; |
| ASSERT_EQ(zx_channel_create(0, &channel[0], &channel[1]), ZX_OK, ""); |
| zx_handle_t event; |
| ASSERT_EQ(zx_event_create(0u, &event), 0, "failed to create event"); |
| zx_info_handle_basic_t event_handle_info; |
| |
| zx_status_t status = zx_object_get_info(event, ZX_INFO_HANDLE_BASIC, &event_handle_info, |
| sizeof(event_handle_info), NULL, NULL); |
| ASSERT_EQ(status, ZX_OK, "failed to get event info"); |
| zx_rights_t initial_event_rights = event_handle_info.rights; |
| zx_handle_t non_transferable_event; |
| zx_handle_duplicate( |
| event, initial_event_rights & ~ZX_RIGHT_TRANSFER, &non_transferable_event); |
| |
| zx_status_t write_result = zx_channel_write( |
| channel[0], 0u, NULL, 0, &non_transferable_event, 1u); |
| EXPECT_EQ(write_result, ZX_ERR_ACCESS_DENIED, "message_write should fail with ACCESS_DENIED"); |
| |
| zx_status_t close_result = zx_handle_close(non_transferable_event); |
| EXPECT_EQ(close_result, ZX_ERR_BAD_HANDLE, ""); |
| |
| END_TEST; |
| } |
| |
| static bool channel_duplicate_handles(void) { |
| BEGIN_TEST; |
| |
| zx_handle_t channel[2]; |
| ASSERT_EQ(zx_channel_create(0, &channel[0], &channel[1]), ZX_OK, ""); |
| |
| zx_handle_t event; |
| ASSERT_EQ(zx_event_create(0u, &event), 0, "failed to create event"); |
| |
| zx_handle_t dup_handles[2] = { event, event }; |
| zx_status_t write_result = zx_channel_write(channel[0], 0u, NULL, 0, dup_handles, 2u); |
| EXPECT_EQ(write_result, ZX_ERR_BAD_HANDLE, "message_write should fail with ZX_ERR_INVALID_ARGS"); |
| |
| zx_status_t close_result = zx_handle_close(event); |
| EXPECT_EQ(close_result, ZX_ERR_BAD_HANDLE, ""); |
| close_result = zx_handle_close(channel[0]); |
| EXPECT_EQ(close_result, ZX_OK, ""); |
| close_result = zx_handle_close(channel[1]); |
| EXPECT_EQ(close_result, ZX_OK, ""); |
| |
| END_TEST; |
| } |
| |
| static const uint32_t multithread_read_num_messages = 5000u; |
| |
| #define MSG_UNSET ((uint32_t)-1) |
| #define MSG_READ_FAILED ((uint32_t)-2) |
| #define MSG_WRONG_SIZE ((uint32_t)-3) |
| #define MSG_BAD_DATA ((uint32_t)-4) |
| |
| static int multithread_reader(void* arg) { |
| for (uint32_t i = 0; i < multithread_read_num_messages / 2; i++) { |
| uint32_t msg = MSG_UNSET; |
| uint32_t msg_size = sizeof(msg); |
| zx_status_t status = zx_channel_read(_channel[0], 0u, &msg, NULL, |
| msg_size, 0, &msg_size, NULL); |
| if (status != ZX_OK) { |
| ((uint32_t*)arg)[i] = MSG_READ_FAILED; |
| break; |
| } |
| if (msg_size != sizeof(msg)) { |
| ((uint32_t*)arg)[i] = MSG_WRONG_SIZE; |
| break; |
| } |
| if (msg >= multithread_read_num_messages) { |
| ((uint32_t*)arg)[i] = MSG_BAD_DATA; |
| break; |
| } |
| |
| ((uint32_t*)arg)[i] = msg; |
| } |
| return 0; |
| } |
| |
| static bool channel_multithread_read(void) { |
| BEGIN_TEST; |
| |
| // We'll write from channel[0] and read from channel[1]. |
| zx_handle_t channel[2]; |
| ASSERT_EQ(zx_channel_create(0, &channel[0], &channel[1]), ZX_OK, ""); |
| |
| for (uint32_t i = 0; i < multithread_read_num_messages; i++) |
| ASSERT_EQ(zx_channel_write(channel[0], 0, &i, sizeof(i), NULL, 0), ZX_OK, ""); |
| |
| _channel[0] = channel[1]; |
| |
| // Start two threads to read messages (each will read half). Each will store the received |
| // message data in the corresponding array. |
| uint32_t* received0 = malloc(multithread_read_num_messages / 2 * sizeof(uint32_t)); |
| ASSERT_TRUE(received0, "malloc failed"); |
| uint32_t* received1 = malloc(multithread_read_num_messages / 2 * sizeof(uint32_t)); |
| ASSERT_TRUE(received1, "malloc failed"); |
| thrd_t reader0; |
| ASSERT_EQ(thrd_create(&reader0, multithread_reader, received0), thrd_success, |
| "thrd_create failed"); |
| thrd_t reader1; |
| ASSERT_EQ(thrd_create(&reader1, multithread_reader, received1), thrd_success, |
| "thrd_create failed"); |
| |
| // Wait for threads. |
| EXPECT_EQ(thrd_join(reader0, NULL), thrd_success, ""); |
| EXPECT_EQ(thrd_join(reader1, NULL), thrd_success, ""); |
| |
| EXPECT_EQ(zx_handle_close(channel[0]), ZX_OK, ""); |
| EXPECT_EQ(zx_handle_close(channel[1]), ZX_OK, ""); |
| |
| // Check data. |
| bool* received_flags = calloc(multithread_read_num_messages, sizeof(bool)); |
| |
| for (uint32_t i = 0; i < multithread_read_num_messages / 2; i++) { |
| uint32_t msg = received0[i]; |
| ASSERT_NE(msg, MSG_READ_FAILED, "read failed"); |
| ASSERT_NE(msg, MSG_WRONG_SIZE, "got wrong message size"); |
| ASSERT_NE(msg, MSG_BAD_DATA, "got bad message data"); |
| ASSERT_LT(msg, multithread_read_num_messages, "???"); |
| ASSERT_FALSE(received_flags[msg], "got duplicate message"); |
| } |
| for (uint32_t i = 0; i < multithread_read_num_messages / 2; i++) { |
| uint32_t msg = received1[i]; |
| ASSERT_NE(msg, MSG_READ_FAILED, "read failed"); |
| ASSERT_NE(msg, MSG_WRONG_SIZE, "got wrong message size"); |
| ASSERT_NE(msg, MSG_BAD_DATA, "got bad message data"); |
| ASSERT_LT(msg, multithread_read_num_messages, "???"); |
| ASSERT_FALSE(received_flags[msg], "got duplicate message"); |
| } |
| |
| free(received0); |
| free(received1); |
| free(received_flags); |
| |
| _channel[0] = ZX_HANDLE_INVALID; |
| |
| END_TEST; |
| } |
| |
| // |handle| must be valid (and duplicatable and transferable) if |num_handles > 0|. |
| static void write_test_message(zx_handle_t channel, |
| zx_handle_t handle, |
| uint32_t size, |
| uint32_t num_handles) { |
| static const char data[1000] = {}; |
| zx_handle_t handles[10] = {}; |
| |
| ZX_ASSERT(size <= sizeof(data)); |
| ZX_ASSERT(num_handles <= countof(handles)); |
| |
| for (uint32_t i = 0; i < num_handles; i++) { |
| zx_status_t status = zx_handle_duplicate(handle, ZX_RIGHT_TRANSFER, &handles[i]); |
| ZX_ASSERT(status == ZX_OK); |
| } |
| |
| zx_status_t status = zx_channel_write(channel, 0u, data, size, handles, num_handles); |
| ZX_ASSERT(status == ZX_OK); |
| } |
| |
| static bool channel_may_discard(void) { |
| BEGIN_TEST; |
| |
| zx_handle_t channel[2]; |
| ASSERT_EQ(zx_channel_create(0, &channel[0], &channel[1]), ZX_OK, ""); |
| |
| zx_handle_t event; |
| ASSERT_EQ(zx_event_create(0u, &event), 0, "failed to create event"); |
| |
| EXPECT_EQ(zx_object_wait_one(channel[1], ZX_CHANNEL_READABLE, 0u, NULL), ZX_ERR_TIMED_OUT, ""); |
| |
| write_test_message(channel[0], event, 10u, 0u); |
| EXPECT_EQ(zx_channel_read(channel[1], ZX_CHANNEL_READ_MAY_DISCARD, NULL, NULL, 0, 0, NULL, NULL), |
| ZX_ERR_BUFFER_TOO_SMALL, ""); |
| |
| EXPECT_EQ(zx_object_wait_one(channel[1], ZX_CHANNEL_READABLE, 0u, NULL), ZX_ERR_TIMED_OUT, ""); |
| |
| char data[1000]; |
| uint32_t size; |
| |
| write_test_message(channel[0], event, 100u, 0u); |
| size = 10u; |
| EXPECT_EQ(zx_channel_read(channel[1], ZX_CHANNEL_READ_MAY_DISCARD, data, NULL, size, 0, &size, NULL), |
| ZX_ERR_BUFFER_TOO_SMALL, ""); |
| EXPECT_EQ(size, 100u, "wrong size"); |
| |
| EXPECT_EQ(zx_object_wait_one(channel[1], ZX_CHANNEL_READABLE, 0u, NULL), ZX_ERR_TIMED_OUT, ""); |
| |
| zx_handle_t handles[10]; |
| uint32_t num_handles; |
| |
| write_test_message(channel[0], event, 0u, 5u); |
| size = 10u; |
| num_handles = 1u; |
| EXPECT_EQ(zx_channel_read(channel[1], ZX_CHANNEL_READ_MAY_DISCARD, data, handles, |
| size, num_handles, &size, &num_handles), |
| ZX_ERR_BUFFER_TOO_SMALL, ""); |
| EXPECT_EQ(size, 0u, "wrong size"); |
| EXPECT_EQ(num_handles, 5u, "wrong number of handles"); |
| |
| EXPECT_EQ(zx_object_wait_one(channel[1], ZX_CHANNEL_READABLE, 0u, NULL), ZX_ERR_TIMED_OUT, ""); |
| |
| write_test_message(channel[0], event, 100u, 5u); |
| size = 10u; |
| num_handles = 1u; |
| EXPECT_EQ(zx_channel_read(channel[1], ZX_CHANNEL_READ_MAY_DISCARD, data, handles, |
| size, num_handles, &size, &num_handles), |
| ZX_ERR_BUFFER_TOO_SMALL, ""); |
| EXPECT_EQ(size, 100u, "wrong size"); |
| EXPECT_EQ(num_handles, 5u, "wrong number of handles"); |
| |
| EXPECT_EQ(zx_object_wait_one(channel[1], ZX_CHANNEL_READABLE, 0u, NULL), ZX_ERR_TIMED_OUT, ""); |
| |
| zx_status_t close_result = zx_handle_close(event); |
| EXPECT_EQ(close_result, ZX_OK, ""); |
| close_result = zx_handle_close(channel[0]); |
| EXPECT_EQ(close_result, ZX_OK, ""); |
| close_result = zx_handle_close(channel[1]); |
| EXPECT_EQ(close_result, ZX_OK, ""); |
| |
| END_TEST; |
| } |
| |
| #define MAX_DELAY 4 |
| |
| enum { |
| OP_ECHO = 0, |
| OP_NOTXID, |
| OP_RUNT, |
| OP_TOOBIG, |
| OP_DELAY, |
| OP_IGNORE, |
| OP_HANDLE, |
| OP_SHUTDOWN, |
| OP_POSTSHUTDOWN |
| }; |
| |
| typedef struct { |
| zx_txid_t txid; |
| uint32_t op; |
| unsigned data[8]; |
| } msg_t; |
| |
| static int cc_server(void* ptr) { |
| zx_status_t status; |
| zx_handle_t h = (zx_handle_t) (uintptr_t) ptr; |
| |
| uint32_t pending[MAX_DELAY]; |
| size_t pending_count = 0; |
| |
| for (;;) { |
| zx_object_wait_one(h, ZX_CHANNEL_READABLE | ZX_CHANNEL_PEER_CLOSED, |
| ZX_TIME_INFINITE, NULL); |
| |
| msg_t msg; |
| zx_handle_t handle = ZX_HANDLE_INVALID; |
| uint32_t bc = 0, hc = 0; |
| status = zx_channel_read(h, 0, &msg, &handle, sizeof(msg), 1, &bc, &hc); |
| if (status != ZX_OK) { |
| fprintf(stderr, "call_server() read failed: %d\n", status); |
| return -1; |
| } |
| |
| if (bc != sizeof(msg)) { |
| msg.op = OP_RUNT; |
| } |
| |
| if ((hc > 0) && (msg.op != OP_HANDLE)) { |
| fprintf(stderr, "call_server() got unexpected handle on op %u\n", msg.op); |
| return -1; |
| } |
| |
| switch(msg.op) { |
| case OP_RUNT: |
| memset(msg.data, 0xee, sizeof(msg.data)); |
| break; |
| case OP_ECHO: |
| case OP_TOOBIG: |
| case OP_HANDLE: |
| break; |
| case OP_DELAY: |
| for (unsigned n = 0; n < pending_count; n++) { |
| if (pending[n] == msg.txid) { |
| fprintf(stderr, "call_server() kernel re-used a txid!\n"); |
| return -1; |
| } |
| } |
| pending[pending_count++] = msg.txid; |
| if (pending_count < MAX_DELAY) { |
| continue; |
| } |
| while (pending_count > 0) { |
| pending_count--; |
| msg.op = OP_DELAY; |
| msg.txid = pending[pending_count]; |
| status = zx_channel_write(h, 0, &msg, sizeof(msg), NULL, 0); |
| if (status != ZX_OK) { |
| fprintf(stderr, "call_server() replay write failed: %d\n", status); |
| return -1; |
| } |
| } |
| continue; |
| case OP_IGNORE: |
| continue; |
| case OP_SHUTDOWN: |
| zx_handle_close(h); |
| return 0; |
| } |
| |
| status = zx_channel_write(h, 0, &msg, sizeof(msg), &handle, hc); |
| if (status != ZX_OK) { |
| fprintf(stderr, "call_server() write failed: %d\n", status); |
| return -1; |
| } |
| } |
| return 0; |
| } |
| |
| static unsigned fillbyte = 1; |
| |
| static zx_status_t do_cc(zx_handle_t cli, uint32_t op) { |
| msg_t msg; |
| msg_t rsp; |
| zx_handle_t h = ZX_HANDLE_INVALID; |
| |
| unsigned fill = (op == OP_RUNT) ? 0xee : fillbyte++; |
| |
| msg.txid = 0x11223344; |
| msg.op = op; |
| memset(msg.data, fill, sizeof(msg.data)); |
| |
| zx_channel_call_args_t args = { |
| .wr_bytes = &msg, |
| .wr_handles = &h, |
| .rd_bytes = &rsp, |
| .rd_handles = &h, |
| .wr_num_bytes = sizeof(msg), |
| .wr_num_handles = 0, |
| .rd_num_bytes = sizeof(msg), |
| .rd_num_handles = 0, |
| }; |
| |
| switch (op) { |
| case OP_RUNT: |
| args.wr_num_bytes = sizeof(zx_txid_t); |
| break; |
| case OP_NOTXID: |
| args.wr_num_bytes = 1; |
| break; |
| case OP_TOOBIG: |
| args.rd_num_bytes = sizeof(zx_txid_t); |
| break; |
| case OP_HANDLE: |
| if (zx_event_create(0, &h) != ZX_OK) { |
| return -1005; |
| } |
| args.wr_num_handles = 1; |
| args.rd_num_handles = 1; |
| } |
| |
| zx_status_t status; |
| uint32_t bytes = 0; |
| uint32_t handles = 0; |
| |
| zx_time_t timeout = (op == OP_IGNORE) ? 0 : ZX_TIME_INFINITE; |
| |
| status = zx_channel_call(cli, 0, timeout, &args, &bytes, &handles); |
| if (status != ZX_OK) { |
| if ((op == OP_IGNORE) && (status == ZX_ERR_TIMED_OUT)) { |
| return ZX_OK; |
| } |
| if ((op == OP_NOTXID) && (status == ZX_ERR_INVALID_ARGS)) { |
| return ZX_OK; |
| } |
| if ((op == OP_SHUTDOWN) && (status == ZX_ERR_PEER_CLOSED)) { |
| return ZX_OK; |
| } |
| if ((op == OP_POSTSHUTDOWN) && (status == ZX_ERR_PEER_CLOSED)) { |
| return ZX_OK; |
| } |
| if ((op == OP_TOOBIG) && (status == ZX_ERR_BUFFER_TOO_SMALL)) { |
| return ZX_OK; |
| } |
| fprintf(stderr, "do_cc: channel_call() status=%d\n", status); |
| return -1000; |
| } |
| |
| if (handles == 1) { |
| zx_handle_close(h); |
| if (op != OP_HANDLE) { |
| return -1004; |
| } |
| } |
| |
| if ((bytes != sizeof(msg)) || ((op != OP_HANDLE) && (handles != 0))) { |
| return -1001; |
| } |
| |
| if (msg.op != rsp.op) { |
| return -1002; |
| } |
| |
| switch (op) { |
| case OP_HANDLE: |
| case OP_ECHO: |
| case OP_RUNT: |
| if (memcmp(msg.data, rsp.data, sizeof(msg.data))) { |
| return -1003; |
| } |
| break; |
| } |
| |
| return ZX_OK; |
| } |
| |
| static int cc_client(void* ptr) { |
| zx_handle_t cli = (zx_handle_t) (uintptr_t) ptr; |
| return do_cc(cli, OP_DELAY); |
| } |
| |
| static bool channel_call(void) { |
| BEGIN_TEST; |
| |
| zx_handle_t cli, srv; |
| ASSERT_EQ(zx_channel_create(0, &cli, &srv), ZX_OK, ""); |
| |
| // start test server |
| thrd_t srvt; |
| ASSERT_EQ(thrd_create(&srvt, cc_server, (void*) (uintptr_t) srv), thrd_success, ""); |
| |
| ASSERT_EQ(do_cc(cli, OP_ECHO), ZX_OK, ""); |
| ASSERT_EQ(do_cc(cli, OP_RUNT), ZX_OK, ""); |
| ASSERT_EQ(do_cc(cli, OP_TOOBIG), ZX_OK, ""); |
| ASSERT_EQ(do_cc(cli, OP_ECHO), ZX_OK, ""); |
| ASSERT_EQ(do_cc(cli, OP_NOTXID), ZX_OK, ""); |
| ASSERT_EQ(do_cc(cli, OP_IGNORE), ZX_OK, ""); |
| ASSERT_EQ(do_cc(cli, OP_HANDLE), ZX_OK, ""); |
| |
| // do four OP_DELAYs on four different threads |
| thrd_t a,b,c,d; |
| ASSERT_EQ(thrd_create(&a, cc_client, (void*) (uintptr_t) cli), thrd_success, ""); |
| ASSERT_EQ(thrd_create(&b, cc_client, (void*) (uintptr_t) cli), thrd_success, ""); |
| ASSERT_EQ(thrd_create(&c, cc_client, (void*) (uintptr_t) cli), thrd_success, ""); |
| ASSERT_EQ(thrd_create(&d, cc_client, (void*) (uintptr_t) cli), thrd_success, ""); |
| |
| // server will respond in opposite order once it has received all of them |
| |
| // verify that they all finish |
| int r; |
| ASSERT_EQ(thrd_join(a, &r), thrd_success, ""); |
| ASSERT_EQ(r, 0, ""); |
| ASSERT_EQ(thrd_join(b, &r), thrd_success, ""); |
| ASSERT_EQ(r, 0, ""); |
| ASSERT_EQ(thrd_join(c, &r), thrd_success, ""); |
| ASSERT_EQ(r, 0, ""); |
| ASSERT_EQ(thrd_join(d, &r), thrd_success, ""); |
| ASSERT_EQ(r, 0, ""); |
| |
| ASSERT_EQ(do_cc(cli, OP_SHUTDOWN), ZX_OK, ""); |
| |
| ASSERT_EQ(do_cc(cli, OP_POSTSHUTDOWN), ZX_OK, ""); |
| ASSERT_EQ(zx_handle_close(cli), ZX_OK, ""); |
| |
| END_TEST; |
| } |
| |
| static bool channel_call_consumes_handles(void) { |
| BEGIN_TEST; |
| |
| zx_handle_t cli, srv; |
| ASSERT_EQ(zx_channel_create(0, &cli, &srv), ZX_OK, ""); |
| ASSERT_EQ(zx_handle_close(srv), ZX_OK, ""); |
| |
| zx_handle_t h; |
| ASSERT_EQ(zx_event_create(0, &h), ZX_OK, ""); |
| |
| uint8_t msg[64]; |
| memset(msg, 0, sizeof(msg)); |
| |
| zx_channel_call_args_t args = { |
| .wr_bytes = &msg, |
| .wr_handles = &h, |
| .rd_bytes = &msg, |
| .rd_handles = NULL, |
| .wr_num_bytes = sizeof(msg), |
| .wr_num_handles = 1, |
| .rd_num_bytes = sizeof(msg), |
| .rd_num_handles = 0, |
| }; |
| |
| uint32_t act_bytes = 0xffffffff; |
| uint32_t act_handles = 0xffffffff; |
| |
| zx_status_t r = zx_channel_call(cli, 42, ZX_TIME_INFINITE, &args, &act_bytes, |
| &act_handles); |
| |
| ASSERT_EQ(r, ZX_ERR_INVALID_ARGS, ""); |
| ASSERT_EQ(zx_handle_close(h), ZX_ERR_BAD_HANDLE, ""); |
| |
| END_TEST; |
| } |
| |
| static bool create_and_nest(zx_handle_t out, zx_handle_t* end, size_t n) { |
| BEGIN_TEST; |
| |
| zx_handle_t channel[2]; |
| if (n == 1) { |
| ASSERT_EQ(zx_channel_create(0, &channel[0], end), ZX_OK, ""); |
| ASSERT_EQ(zx_channel_write(out, 0u, NULL, 0u, channel, 1u), ZX_OK, ""); |
| return true; |
| } |
| |
| ASSERT_EQ(zx_channel_create(0, &channel[0], &channel[1]), ZX_OK, ""); |
| ASSERT_TRUE(create_and_nest(channel[0], end, n - 1), ""); |
| ASSERT_EQ(zx_channel_write(out, 0u, NULL, 0u, channel, 2u), ZX_OK, ""); |
| |
| END_TEST; |
| } |
| |
| static int call_server2(void* ptr) { |
| zx_handle_t h = (zx_handle_t) (uintptr_t) ptr; |
| zx_nanosleep(zx_deadline_after(ZX_MSEC(250))); |
| zx_handle_close(h); |
| return 0; |
| } |
| |
| static bool channel_call2(void) { |
| BEGIN_TEST; |
| |
| zx_handle_t cli, srv; |
| ASSERT_EQ(zx_channel_create(0, &cli, &srv), ZX_OK, ""); |
| |
| thrd_t t; |
| ASSERT_EQ(thrd_create(&t, call_server2, (void*) (uintptr_t) srv), thrd_success, ""); |
| |
| char msg[8] = { 0, }; |
| zx_channel_call_args_t args = { |
| .wr_bytes = msg, |
| .wr_handles = NULL, |
| .wr_num_bytes = sizeof(msg), |
| .wr_num_handles = 0, |
| .rd_bytes = NULL, |
| .rd_handles = NULL, |
| .rd_num_bytes = 0, |
| .rd_num_handles = 0, |
| }; |
| |
| uint32_t act_bytes = 0xffffffff; |
| uint32_t act_handles = 0xffffffff; |
| |
| zx_status_t r = zx_channel_call(cli, 0, zx_deadline_after(ZX_MSEC(1000)), &args, &act_bytes, |
| &act_handles); |
| |
| zx_handle_close(cli); |
| |
| EXPECT_EQ(r, ZX_ERR_PEER_CLOSED, ""); |
| |
| int retv = 0; |
| EXPECT_EQ(thrd_join(t, &retv), thrd_success, ""); |
| EXPECT_EQ(retv, 0, ""); |
| |
| END_TEST; |
| } |
| |
| // SYSCALL_zx_channel_call_finish is an internal system call used in the |
| // vDSO's implementation of zx_channel_call. It's not part of the ABI and |
| // so it's not exported from the vDSO. It's hard to test the kernel's |
| // invariants without calling this directly. So use some chicanery to |
| // find its address in the vDSO despite it not being public. |
| // |
| // The vdso-code.h header file is generated from the vDSO binary. It gives |
| // the offsets of the internal functions. So take a public vDSO function, |
| // subtract its offset to discover the vDSO base (could do this other ways, |
| // but this is the simplest), and then add the offset of the internal |
| // SYSCALL_zx_channel_call_finish function we want to call. |
| #include "vdso-code.h" |
| static zx_status_t zx_channel_call_finish(zx_time_t deadline, |
| const zx_channel_call_args_t* args, |
| uint32_t* actual_bytes, |
| uint32_t* actual_handles) { |
| uintptr_t vdso_base = |
| (uintptr_t)&zx_handle_close - VDSO_SYSCALL_zx_handle_close; |
| uintptr_t fnptr = vdso_base + VDSO_SYSCALL_zx_channel_call_finish; |
| return (*(__typeof(zx_channel_call_finish)*)fnptr)( |
| deadline, args, actual_bytes, actual_handles); |
| } |
| |
| static bool bad_channel_call_finish(void) { |
| BEGIN_TEST; |
| |
| char msg[8] = { 0, }; |
| zx_channel_call_args_t args = { |
| .wr_bytes = msg, |
| .wr_handles = NULL, |
| .wr_num_bytes = sizeof(msg), |
| .wr_num_handles = 0, |
| .rd_bytes = NULL, |
| .rd_handles = NULL, |
| .rd_num_bytes = 0, |
| .rd_num_handles = 0, |
| }; |
| |
| uint32_t act_bytes = 0xffffffff; |
| uint32_t act_handles = 0xffffffff; |
| |
| // Call channel_call_finish without having had a channel call interrupted |
| zx_status_t r = zx_channel_call_finish(zx_deadline_after(ZX_MSEC(1000)), &args, &act_bytes, |
| &act_handles); |
| |
| EXPECT_EQ(r, ZX_ERR_BAD_STATE, ""); |
| |
| END_TEST; |
| } |
| |
| static bool channel_nest(void) { |
| BEGIN_TEST; |
| zx_handle_t channel[2]; |
| |
| ASSERT_EQ(zx_channel_create(0, &channel[0], &channel[1]), ZX_OK, ""); |
| |
| zx_handle_t end; |
| // Nest 200 channels, each one in the payload of the previous one. Without |
| // the SafeDeleter in fbl_recycle() this blows the kernel stack when calling |
| // the destructors. |
| ASSERT_TRUE(create_and_nest(channel[0], &end, 200), ""); |
| EXPECT_EQ(zx_handle_close(channel[1]), ZX_OK, ""); |
| EXPECT_EQ(zx_object_wait_one(channel[0], ZX_CHANNEL_PEER_CLOSED, ZX_TIME_INFINITE, NULL), ZX_OK, ""); |
| |
| EXPECT_EQ(zx_object_wait_one(end, ZX_CHANNEL_PEER_CLOSED, ZX_TIME_INFINITE, NULL), ZX_OK, ""); |
| EXPECT_EQ(zx_handle_close(end), ZX_OK, ""); |
| |
| EXPECT_EQ(zx_handle_close(channel[0]), ZX_OK, ""); |
| |
| END_TEST; |
| } |
| |
| // Test the case of writing a channel handle to itself. The kernel |
| // currently disallows this, because otherwise it would create a reference |
| // cycle and potentially allow channels to be leaked. |
| static bool channel_disallow_write_to_self(void) { |
| BEGIN_TEST; |
| |
| zx_handle_t channel[2]; |
| ASSERT_EQ(zx_channel_create(0, &channel[0], &channel[1]), ZX_OK, ""); |
| EXPECT_EQ(zx_channel_write(channel[0], 0, NULL, 0, &channel[0], 1), |
| ZX_ERR_NOT_SUPPORTED, ""); |
| // Clean up. |
| EXPECT_EQ(zx_handle_close(channel[0]), ZX_ERR_BAD_HANDLE, ""); |
| EXPECT_EQ(zx_handle_close(channel[1]), ZX_OK, ""); |
| |
| END_TEST; |
| } |
| |
| static bool channel_read_etc(void) { |
| BEGIN_TEST; |
| |
| zx_handle_t event; |
| ASSERT_EQ(zx_event_create(0u, &event), ZX_OK, ""); |
| ASSERT_EQ(zx_handle_replace(event, ZX_RIGHT_SIGNAL | ZX_RIGHT_TRANSFER, &event), ZX_OK, ""); |
| |
| zx_handle_t fifo[2]; |
| ASSERT_EQ(zx_fifo_create(32u, 8u, 0u, &fifo[0], &fifo[1]), ZX_OK, ""); |
| |
| zx_handle_t sent[] = { |
| fifo[0], |
| event, |
| fifo[1] |
| }; |
| |
| zx_handle_t channel[2]; |
| ASSERT_EQ(zx_channel_create(0, &channel[0], &channel[1]), ZX_OK, ""); |
| EXPECT_EQ(zx_channel_write(channel[0], 0u, NULL, 0, sent, 3u), ZX_OK, ""); |
| |
| zx_handle_info_t recv[] = {{}, {}, {}}; |
| uint32_t actual_bytes; |
| uint32_t actual_handles; |
| |
| EXPECT_EQ(zx_channel_read_etc( |
| channel[1], 0u, NULL, recv, 0u, 3u, &actual_bytes, &actual_handles), ZX_OK, ""); |
| |
| EXPECT_EQ(actual_bytes, 0u, ""); |
| EXPECT_EQ(actual_handles, 3u, ""); |
| EXPECT_EQ(recv[0].type, ZX_OBJ_TYPE_FIFO, ""); |
| EXPECT_EQ(recv[0].rights, ZX_DEFAULT_FIFO_RIGHTS, ""); |
| |
| EXPECT_EQ(recv[1].type, ZX_OBJ_TYPE_EVENT, ""); |
| EXPECT_EQ(recv[1].rights, ZX_RIGHT_SIGNAL | ZX_RIGHT_TRANSFER, ""); |
| |
| EXPECT_EQ(recv[2].type, ZX_OBJ_TYPE_FIFO, ""); |
| EXPECT_EQ(recv[2].rights, ZX_DEFAULT_FIFO_RIGHTS, ""); |
| |
| EXPECT_EQ(zx_handle_close(channel[0]), ZX_OK, ""); |
| EXPECT_EQ(zx_handle_close(channel[1]), ZX_OK, ""); |
| EXPECT_EQ(zx_handle_close(recv[0].handle), ZX_OK, ""); |
| EXPECT_EQ(zx_handle_close(recv[1].handle), ZX_OK, ""); |
| EXPECT_EQ(zx_handle_close(recv[2].handle), ZX_OK, ""); |
| |
| END_TEST; |
| } |
| |
| // Write and read messages of different sizes. |
| static bool channel_write_different_sizes(void) { |
| BEGIN_TEST; |
| zx_handle_t channel[2]; |
| ASSERT_EQ(zx_channel_create(0, &channel[0], &channel[1]), ZX_OK, ""); |
| |
| char* data_to_send = malloc(ZX_CHANNEL_MAX_MSG_BYTES); |
| ASSERT_NE(NULL, data_to_send, ""); |
| char* data_recv = malloc(ZX_CHANNEL_MAX_MSG_BYTES); |
| ASSERT_NE(NULL, data_recv, ""); |
| |
| uint32_t actual_bytes = 0; |
| uint32_t actual_handles = 0; |
| |
| // Send a bunch of messages, each with a random number of bytes and handles. num_msgs should be |
| // large enough to provide decent coverage and small enough so the test executes quickly. |
| const size_t num_msgs = 1000; |
| srand(0); |
| for (size_t i = 0; i < num_msgs; ++i) { |
| uint32_t num_bytes = rand() % ZX_CHANNEL_MAX_MSG_BYTES; |
| uint32_t num_handles = rand() % ZX_CHANNEL_MAX_MSG_HANDLES; |
| |
| // Create some handle pairs. Keep one of each pair in |handles|, put the other in |
| // |handles_to_send|. |
| zx_handle_t handles[ZX_CHANNEL_MAX_MSG_HANDLES] = {0}; |
| zx_handle_t handles_to_send[ZX_CHANNEL_MAX_MSG_HANDLES] = {0}; |
| zx_handle_t handles_recv[ZX_CHANNEL_MAX_MSG_HANDLES] = {0}; |
| for (size_t i = 0; i < ZX_CHANNEL_MAX_MSG_HANDLES; ++i) { |
| if (i < num_handles) { |
| ASSERT_EQ(zx_channel_create(0u, &handles[i], &handles_to_send[i]), ZX_OK, ""); |
| } else { |
| handles[i] = ZX_HANDLE_INVALID; |
| handles_to_send[i] = ZX_HANDLE_INVALID; |
| } |
| handles_recv[i] = ZX_HANDLE_INVALID; |
| } |
| |
| memset(data_to_send, i % 256, i); |
| ASSERT_EQ(zx_channel_write(channel[0], 0u, data_to_send, num_bytes, handles_to_send, |
| num_handles), |
| ZX_OK, ""); |
| memset(data_recv, 0, ZX_CHANNEL_MAX_MSG_BYTES); |
| ASSERT_EQ(zx_channel_read(channel[1], 0u, data_recv, handles_recv, ZX_CHANNEL_MAX_MSG_BYTES, |
| num_handles, &actual_bytes, &actual_handles), |
| ZX_OK, ""); |
| ASSERT_EQ(actual_bytes, num_bytes, ""); |
| ASSERT_EQ(actual_handles, num_handles, ""); |
| ASSERT_EQ(memcmp(data_to_send, data_recv, num_bytes), 0, ""); |
| |
| // Close them. |
| for (size_t i = 0; i< ZX_CHANNEL_MAX_MSG_HANDLES; ++i) { |
| if (i < num_handles) { |
| ASSERT_EQ(zx_handle_close(handles_recv[i]), ZX_OK, ""); |
| ASSERT_EQ(zx_handle_close(handles[i]), ZX_OK, ""); |
| } else { |
| ASSERT_EQ(handles_recv[i], ZX_HANDLE_INVALID, ""); |
| } |
| } |
| } |
| |
| free(data_recv); |
| free(data_to_send); |
| EXPECT_EQ(zx_handle_close(channel[0]), ZX_OK, ""); |
| EXPECT_EQ(zx_handle_close(channel[1]), ZX_OK, ""); |
| END_TEST; |
| } |
| |
| static bool channel_write_takes_all_handles(void) { |
| BEGIN_TEST; |
| |
| zx_handle_t channel[2]; |
| ASSERT_EQ(zx_channel_create(0, &channel[0], &channel[1]), ZX_OK, ""); |
| |
| #define TOO_MANY_HANDLES 2000 |
| zx_handle_t handles[TOO_MANY_HANDLES]; |
| for (size_t i = 0; i < TOO_MANY_HANDLES; ++i) { |
| ASSERT_EQ(zx_event_create(0, &handles[i]), ZX_OK, ""); |
| } |
| |
| char bytes[1] = {5}; |
| ASSERT_EQ(zx_channel_write(channel[0], 0, bytes, 1, handles, TOO_MANY_HANDLES), |
| ZX_ERR_OUT_OF_RANGE, "write didn't fail"); |
| |
| for (size_t i = 0; i < TOO_MANY_HANDLES; ++i) { |
| ASSERT_EQ(zx_handle_close(handles[i]), ZX_ERR_BAD_HANDLE, "handle not closed"); |
| } |
| |
| END_TEST; |
| } |
| |
| BEGIN_TEST_CASE(channel_tests) |
| RUN_TEST(channel_test) |
| RUN_TEST(channel_read_error_test) |
| RUN_TEST(channel_close_test) |
| RUN_TEST(channel_peer_closed_test) |
| RUN_TEST(channel_non_transferable) |
| RUN_TEST(channel_duplicate_handles) |
| RUN_TEST(channel_multithread_read) |
| RUN_TEST(channel_may_discard) |
| RUN_TEST(channel_call) |
| RUN_TEST(channel_call_consumes_handles) |
| RUN_TEST(channel_call2) |
| RUN_TEST(bad_channel_call_finish) |
| RUN_TEST(channel_nest) |
| RUN_TEST(channel_disallow_write_to_self) |
| RUN_TEST(channel_read_etc) |
| RUN_TEST(channel_write_different_sizes) |
| RUN_TEST(channel_write_takes_all_handles) |
| END_TEST_CASE(channel_tests) |
| |
| #ifndef BUILD_COMBINED_TESTS |
| int main(int argc, char** argv) { |
| return unittest_run_all_tests(argc, argv) ? 0 : -1; |
| } |
| #endif |