/* * Copyright (c) 2023 Nordic Semiconductor ASA * * SPDX-License-Identifier: Apache-2.0 */ #include #include #include #include #include "net.h" #include "access.h" #include "delayable_msg.h" #define SRC_ADDR 0x0002 #define RX_ADDR 0xc000 static void start_cb(uint16_t duration, int err, void *cb_data); struct bt_mesh_net bt_mesh; static struct bt_mesh_msg_ctx gctx = {.net_idx = 0, .app_idx = 0, .addr = 0, .recv_dst = RX_ADDR, .uuid = NULL, .recv_rssi = 0, .recv_ttl = 0x05, .send_rel = false, .rnd_delay = true, .send_ttl = 0x06}; static struct bt_mesh_send_cb send_cb = { .start = start_cb, }; static bool is_fake_random; static bool check_expectations; static bool accum_mask; static bool do_not_call_cb; static uint16_t fake_random; static uint8_t *buf_data; static size_t buf_data_size; static uint16_t id_mask; static int cb_err_status; K_SEM_DEFINE(delayed_msg_sent, 0, 1); /**** Mocked functions ****/ int bt_mesh_access_send(struct bt_mesh_msg_ctx *ctx, struct net_buf_simple *buf, uint16_t src_addr, const struct bt_mesh_send_cb *cb, void *cb_data) { if (check_expectations) { gctx.rnd_delay = false; ztest_check_expected_data(ctx, sizeof(struct bt_mesh_msg_ctx)); gctx.rnd_delay = true; ztest_check_expected_value(src_addr); ztest_check_expected_data(cb, sizeof(struct bt_mesh_send_cb)); ztest_check_expected_data(cb_data, sizeof(uint32_t)); zexpect_mem_equal(buf->data, buf_data, buf_data_size, "Buffer data corrupted"); } if (cb && !do_not_call_cb) { cb->start(0x0, cb_err_status, cb_data); } return cb_err_status; } int bt_rand(void *buf, size_t len) { if (is_fake_random) { *(uint16_t *)buf = fake_random; } else { sys_rand_get(buf, len); } return 0; } /**** Mocked functions ****/ static void start_cb(uint16_t duration, int err, void *cb_data) { zassert_equal(err, cb_err_status, "err: %d, cb_err_status: %d", err, cb_err_status); if (accum_mask) { id_mask |= 1 << *(uint16_t *)cb_data; } else { k_sem_give(&delayed_msg_sent); } } static void set_expectation(struct net_buf_simple *buf, uint32_t *buf_id) { ztest_expect_data(bt_mesh_access_send, ctx, &gctx); ztest_expect_value(bt_mesh_access_send, src_addr, SRC_ADDR); ztest_expect_data(bt_mesh_access_send, cb, &send_cb); ztest_expect_data(bt_mesh_access_send, cb_data, buf_id); buf_data = buf->__buf; buf_data_size = buf->size; check_expectations = true; } static void tc_setup(void *fixture) { is_fake_random = false; check_expectations = false; accum_mask = false; id_mask = 0; do_not_call_cb = false; cb_err_status = 0; k_sem_reset(&delayed_msg_sent); bt_mesh_delayable_msg_init(); } static void tc_teardown(void *fixture) { zassert_equal(gctx.net_idx, 0); zassert_equal(gctx.app_idx, 0); zassert_equal(gctx.addr, 0); zassert_equal(gctx.recv_dst, RX_ADDR); zassert_is_null(gctx.uuid); zassert_equal(gctx.recv_rssi, 0); zassert_equal(gctx.recv_ttl, 0x05); zassert_false(gctx.send_rel); zassert_true(gctx.rnd_delay); zassert_equal(gctx.send_ttl, 0x06); } ZTEST_SUITE(bt_mesh_delayable_msg, NULL, NULL, tc_setup, tc_teardown, NULL); /* Simple single message sending with full size. */ ZTEST(bt_mesh_delayable_msg, test_single_sending) { uint32_t buf_id = 0x55aa55aa; uint8_t *payload; NET_BUF_SIMPLE_DEFINE(buf, BT_MESH_TX_SDU_MAX); payload = net_buf_simple_add(&buf, BT_MESH_TX_SDU_MAX); for (int i = 0; i < BT_MESH_TX_SDU_MAX; i++) { payload[i] = i; } set_expectation(&buf, &buf_id); zexpect_ok(bt_mesh_delayable_msg_manage(&gctx, &buf, SRC_ADDR, &send_cb, &buf_id)); zassert_ok(k_sem_take(&delayed_msg_sent, K_SECONDS(1)), "Delayed message has not been sent."); } /* The test checks that the delayed message mechanism sorts * the incoming messages according to the transmission start timestamp. */ ZTEST(bt_mesh_delayable_msg, test_self_sorting) { uint8_t tx_data[20]; uint32_t buf1_id = 1; uint32_t buf2_id = 2; uint32_t buf3_id = 3; uint32_t buf4_id = 4; NET_BUF_SIMPLE_DEFINE(buf1, 20); NET_BUF_SIMPLE_DEFINE(buf2, 20); NET_BUF_SIMPLE_DEFINE(buf3, 20); NET_BUF_SIMPLE_DEFINE(buf4, 20); memset(tx_data, 1, 20); memcpy(net_buf_simple_add(&buf1, 20), tx_data, 20); memset(tx_data, 2, 20); memcpy(net_buf_simple_add(&buf2, 20), tx_data, 20); memset(tx_data, 3, 20); memcpy(net_buf_simple_add(&buf3, 20), tx_data, 20); memset(tx_data, 4, 20); memcpy(net_buf_simple_add(&buf4, 20), tx_data, 20); is_fake_random = true; fake_random = 30; zexpect_ok(bt_mesh_delayable_msg_manage(&gctx, &buf1, SRC_ADDR, &send_cb, &buf1_id)); fake_random = 10; zexpect_ok(bt_mesh_delayable_msg_manage(&gctx, &buf2, SRC_ADDR, &send_cb, &buf2_id)); fake_random = 20; zexpect_ok(bt_mesh_delayable_msg_manage(&gctx, &buf3, SRC_ADDR, &send_cb, &buf3_id)); fake_random = 40; zexpect_ok(bt_mesh_delayable_msg_manage(&gctx, &buf4, SRC_ADDR, &send_cb, &buf4_id)); set_expectation(&buf2, &buf2_id); zassert_ok(k_sem_take(&delayed_msg_sent, K_MSEC(100)), "Delayed message has not been sent."); set_expectation(&buf3, &buf3_id); zassert_ok(k_sem_take(&delayed_msg_sent, K_MSEC(100)), "Delayed message has not been sent."); set_expectation(&buf1, &buf1_id); zassert_ok(k_sem_take(&delayed_msg_sent, K_MSEC(100)), "Delayed message has not been sent."); set_expectation(&buf4, &buf4_id); zassert_ok(k_sem_take(&delayed_msg_sent, K_MSEC(100)), "Delayed message has not been sent."); } /* The test checks that the delayed msg mechanism can allocate new context * if all contexts are in use by sending the message, that is the closest to * the tx time. */ ZTEST(bt_mesh_delayable_msg, test_ctx_reallocation) { uint8_t tx_data[20]; uint32_t buf_id1 = 0; uint32_t buf_id2 = 1; uint32_t buf_id3 = 2; uint32_t buf_id4 = 3; uint32_t buf_id5 = 4; NET_BUF_SIMPLE_DEFINE(buf, 20); memset(tx_data, 1, 20); memcpy(net_buf_simple_add(&buf, 20), tx_data, 20); accum_mask = true; is_fake_random = true; fake_random = 10; zexpect_ok(bt_mesh_delayable_msg_manage(&gctx, &buf, SRC_ADDR, &send_cb, &buf_id1)); fake_random = 30; zexpect_ok(bt_mesh_delayable_msg_manage(&gctx, &buf, SRC_ADDR, &send_cb, &buf_id2)); fake_random = 20; zexpect_ok(bt_mesh_delayable_msg_manage(&gctx, &buf, SRC_ADDR, &send_cb, &buf_id3)); fake_random = 40; zexpect_ok(bt_mesh_delayable_msg_manage(&gctx, &buf, SRC_ADDR, &send_cb, &buf_id4)); fake_random = 40; zexpect_ok(bt_mesh_delayable_msg_manage(&gctx, &buf, SRC_ADDR, &send_cb, &buf_id5)); zassert_equal(id_mask, 0x0001, "Delayed message context reallocation was broken"); k_sleep(K_MSEC(500)); zassert_equal(id_mask, 0x001F); } /* The test checks that the delayed msg mechanism can allocate new chunks * if all chunks are in use by sending the other messages. */ ZTEST(bt_mesh_delayable_msg, test_chunk_reallocation) { uint8_t tx_data[BT_MESH_TX_SDU_MAX]; uint32_t buf_id1 = 0; uint32_t buf_id2 = 1; uint32_t buf_id3 = 2; uint32_t buf_id4 = 3; NET_BUF_SIMPLE_DEFINE(buf1, 20); NET_BUF_SIMPLE_DEFINE(buf2, BT_MESH_TX_SDU_MAX); memset(tx_data, 1, BT_MESH_TX_SDU_MAX); memcpy(net_buf_simple_add(&buf1, 20), tx_data, 20); memcpy(net_buf_simple_add(&buf2, BT_MESH_TX_SDU_MAX), tx_data, BT_MESH_TX_SDU_MAX); accum_mask = true; zexpect_ok(bt_mesh_delayable_msg_manage(&gctx, &buf1, SRC_ADDR, &send_cb, &buf_id1)); zexpect_ok(bt_mesh_delayable_msg_manage(&gctx, &buf1, SRC_ADDR, &send_cb, &buf_id2)); zexpect_ok(bt_mesh_delayable_msg_manage(&gctx, &buf1, SRC_ADDR, &send_cb, &buf_id3)); zexpect_ok(bt_mesh_delayable_msg_manage(&gctx, &buf2, SRC_ADDR, &send_cb, &buf_id4)); zassert_equal(id_mask, 0x0007, "Delayed message chunks reallocation was broken"); k_sleep(K_MSEC(500)); zassert_equal(id_mask, 0x000F); } /* The test checks that the delayed msg mechanism can reschedule access messages * transport layes doesn't have enough memory or buffers at the moment. * Also it checks that the delayed msg mechanism can handle the other transport * layer errors without rescheduling appropriate access messages. */ ZTEST(bt_mesh_delayable_msg, test_cb_error_status) { uint32_t buf_id = 0x55aa55aa; uint8_t tx_data[BT_MESH_TX_SDU_MAX]; NET_BUF_SIMPLE_DEFINE(buf1, 20); NET_BUF_SIMPLE_DEFINE(buf2, 20); NET_BUF_SIMPLE_DEFINE(buf3, 20); memset(tx_data, 1, BT_MESH_TX_SDU_MAX); memcpy(net_buf_simple_add(&buf1, 20), tx_data, 20); memcpy(net_buf_simple_add(&buf2, 20), tx_data, 20); memcpy(net_buf_simple_add(&buf3, 20), tx_data, 20); cb_err_status = -ENOBUFS; zexpect_ok(bt_mesh_delayable_msg_manage(&gctx, &buf1, SRC_ADDR, &send_cb, &buf_id)); zassert_ok(k_sem_take(&delayed_msg_sent, K_SECONDS(1)), "Delayed message has not been handled."); cb_err_status = 0; zassert_ok(k_sem_take(&delayed_msg_sent, K_SECONDS(1)), "Delayed message has not been sent."); cb_err_status = -EBUSY; zexpect_ok(bt_mesh_delayable_msg_manage(&gctx, &buf2, SRC_ADDR, &send_cb, &buf_id)); zassert_ok(k_sem_take(&delayed_msg_sent, K_SECONDS(1)), "Delayed message has not been handled."); cb_err_status = 0; zassert_ok(k_sem_take(&delayed_msg_sent, K_SECONDS(1)), "Delayed message has not been sent."); cb_err_status = -EINVAL; do_not_call_cb = true; zexpect_ok(bt_mesh_delayable_msg_manage(&gctx, &buf3, SRC_ADDR, &send_cb, &buf_id)); zassert_ok(k_sem_take(&delayed_msg_sent, K_SECONDS(1)), "Delayed message has not been handled."); cb_err_status = 0; zexpect_not_ok(k_sem_take(&delayed_msg_sent, K_SECONDS(1)), "Delayed message has not been handled."); } /* The test checks that the delayed msg mechanism raises * the model message callback with the appropriate error code after * stopping the functionality. */ ZTEST(bt_mesh_delayable_msg, test_stop_handler) { uint8_t tx_data[20]; uint32_t buf_id1 = 0; uint32_t buf_id2 = 1; uint32_t buf_id3 = 2; uint32_t buf_id4 = 3; NET_BUF_SIMPLE_DEFINE(buf, 20); memset(tx_data, 1, 20); memcpy(net_buf_simple_add(&buf, 20), tx_data, 20); accum_mask = true; cb_err_status = -ENODEV; zexpect_ok(bt_mesh_delayable_msg_manage(&gctx, &buf, SRC_ADDR, &send_cb, &buf_id1)); zexpect_ok(bt_mesh_delayable_msg_manage(&gctx, &buf, SRC_ADDR, &send_cb, &buf_id2)); zexpect_ok(bt_mesh_delayable_msg_manage(&gctx, &buf, SRC_ADDR, &send_cb, &buf_id3)); zexpect_ok(bt_mesh_delayable_msg_manage(&gctx, &buf, SRC_ADDR, &send_cb, &buf_id4)); bt_mesh_delayable_msg_stop(); zexpect_not_ok(k_sem_take(&delayed_msg_sent, K_SECONDS(1)), "Delayed message has been sent after stopping."); zassert_equal(id_mask, 0x000F, "Not all scheduled messages were handled after stopping"); }