Don't use assert() to check the results of pthread_*() calls.

[meshlink] / test / channels-aio-cornercases.c

#ifdef NDEBUG
#undef NDEBUG
#endif

#include <assert.h>
#include <stdio.h>
#include <unistd.h>
#include <stdlib.h>
#include <string.h>
#include <sys/time.h>

#include "meshlink.h"
#include "utils.h"

static const size_t size = 10000000; // size of data to transfer

struct aio_info {
        int port;
        int callbacks;
        size_t size;
        struct timeval tv;
        struct sync_flag flag;
};

struct channel_info {
        char *data;
        struct aio_info aio_infos[2];
};

static struct sync_flag b_received_flag;

static void aio_cb(meshlink_handle_t *mesh, meshlink_channel_t *channel, const void *data, size_t len, void *priv) {
        (void)mesh;
        (void)channel;
        (void)data;
        (void)len;

        struct aio_info *info = priv;

        fprintf(stderr, "%d:%s aio_cb %s %p %zu\n", info->port, mesh->name, channel->node->name, data, len);

        gettimeofday(&info->tv, NULL);
        info->callbacks++;
        info->size += len;
        set_sync_flag(&info->flag, true);
}

static void aio_cb_close(meshlink_handle_t *mesh, meshlink_channel_t *channel, const void *data, size_t len, void *priv) {
        aio_cb(mesh, channel, data, len, priv);
        struct aio_info *info = priv;
        fprintf(stderr, "%d:%s aio_cb %s closing\n", info->port, mesh->name, channel->node->name);
        meshlink_channel_close(mesh, channel);
}

static bool accept_cb(meshlink_handle_t *mesh, meshlink_channel_t *channel, uint16_t port, const void *data, size_t len) {
        assert(!data);
        assert(!len);

        fprintf(stderr, "%d:%s accept_cb %s\n", port, mesh->name, channel->node->name);

        struct channel_info *infos = mesh->priv;
        struct channel_info *info = &infos[port - 1];

        switch(port) {
        case 1:
        case 3:
                assert(meshlink_channel_aio_receive(mesh, channel, info->data, size / 4, aio_cb, &info->aio_infos[0]));
                assert(meshlink_channel_aio_receive(mesh, channel, info->data + size / 4, size - size / 4, aio_cb_close, &info->aio_infos[1]));
                break;

        case 2:
        case 4:
                assert(meshlink_channel_aio_receive(mesh, channel, info->data, size / 4, aio_cb_close, &info->aio_infos[0]));
                assert(meshlink_channel_aio_receive(mesh, channel, info->data + size / 4, size - size / 4, aio_cb, &info->aio_infos[1]));
                set_sync_flag(&info->aio_infos[1].flag, true);
                break;

        default:
                return false;
        }

        return true;
}

int main(void) {
        init_sync_flag(&b_received_flag);

        meshlink_set_log_cb(NULL, MESHLINK_WARNING, log_cb);

        // Prepare data buffers

        char *outdata = malloc(size);
        assert(outdata);

        for(size_t i = 0; i < size; i++) {
                outdata[i] = i;
        }

        static const size_t nchannels = 4;
        struct channel_info in_infos[nchannels];
        struct channel_info out_infos[nchannels];

        memset(in_infos, 0, sizeof(in_infos));
        memset(out_infos, 0, sizeof(out_infos));

        for(size_t i = 0; i < nchannels; i++) {
                init_sync_flag(&in_infos[i].aio_infos[0].flag);
                init_sync_flag(&in_infos[i].aio_infos[1].flag);
                init_sync_flag(&out_infos[i].aio_infos[0].flag);
                init_sync_flag(&out_infos[i].aio_infos[1].flag);

                in_infos[i].data = malloc(size);
                assert(in_infos[i].data);
                out_infos[i].data = outdata;

                out_infos[i].aio_infos[0].port = i + 1;
                out_infos[i].aio_infos[1].port = i + 1;
                in_infos[i].aio_infos[0].port = i + 1;
                in_infos[i].aio_infos[1].port = i + 1;
        }

        // Open two new meshlink instance.

        meshlink_handle_t *mesh_a, *mesh_b;
        open_meshlink_pair(&mesh_a, &mesh_b, "channels_aio_cornercases");

        // Set the callbacks.

        mesh_b->priv = in_infos;

        meshlink_set_channel_accept_cb(mesh_b, accept_cb);

        // Start both instances

        start_meshlink_pair(mesh_a, mesh_b);
        sleep(1);

        // Open channels from a to b.

        meshlink_node_t *b = meshlink_get_node(mesh_a, "b");
        assert(b);

        meshlink_channel_t *channels[nchannels + 1];

        // Send a large buffer of data on each channel.

        for(size_t i = 0; i < nchannels; i++) {
                channels[i] = meshlink_channel_open(mesh_a, b, i + 1, NULL, NULL, 0);
                assert(channels[i]);

                if(i < 2) {
                        assert(meshlink_channel_aio_send(mesh_a, channels[i], outdata, size / 3, aio_cb, &out_infos[i].aio_infos[0]));
                        assert(meshlink_channel_aio_send(mesh_a, channels[i], outdata + size / 3, size - size / 3, aio_cb_close, &out_infos[i].aio_infos[1]));
                        assert(wait_sync_flag(&out_infos[i].aio_infos[0].flag, 10));
                        assert(wait_sync_flag(&out_infos[i].aio_infos[1].flag, 10));
                } else {
                        assert(meshlink_channel_aio_send(mesh_a, channels[i], outdata, size / 3, aio_cb_close, &out_infos[i].aio_infos[0]));
                        assert(meshlink_channel_aio_send(mesh_a, channels[i], outdata + size / 3, size - size / 3, aio_cb, &out_infos[i].aio_infos[1]));
                        assert(wait_sync_flag(&out_infos[i].aio_infos[0].flag, 10));
                        set_sync_flag(&out_infos[i].aio_infos[1].flag, true);
                }
        }

        // Wait for all AIO buffers to finish.

        for(size_t i = 0; i < nchannels; i++) {
                assert(wait_sync_flag(&in_infos[i].aio_infos[0].flag, 10));
                assert(wait_sync_flag(&in_infos[i].aio_infos[1].flag, 10));
                assert(wait_sync_flag(&out_infos[i].aio_infos[0].flag, 10));
                assert(wait_sync_flag(&out_infos[i].aio_infos[1].flag, 10));
        }

        // Check that everything is correct.

        assert(!memcmp(in_infos[0].data, out_infos[0].data, size));
        assert(!memcmp(in_infos[1].data, out_infos[1].data, size / 4));
        assert(memcmp(in_infos[1].data, out_infos[1].data + size / 4, size - size / 4));
        assert(!memcmp(in_infos[2].data, out_infos[2].data, size / 3));
        assert(memcmp(in_infos[2].data, out_infos[2].data + size / 3, size - size / 3));
        assert(!memcmp(in_infos[3].data, out_infos[3].data, size / 4));
        assert(memcmp(in_infos[3].data, out_infos[3].data + size / 4, size / 3 - size / 4));
        assert(memcmp(in_infos[3].data, out_infos[3].data + size / 3, size - size / 3));

        // Clean up.

        close_meshlink_pair(mesh_a, mesh_b);

        free(outdata);

        for(size_t i = 0; i < nchannels; i++) {
                free(in_infos[i].data);
        }
}