tests-gnrc_mac_internal.c
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/*
* Copyright (C) 2016, 2016 Shuguo Zhuo <shuguo.zhuo@inria.fr>
*
* This file is subject to the terms and conditions of the GNU Lesser
* General Public License v2.1. See the file LICENSE in the top level
* directory for more details.
*/
/**
* @{
*
* @file
*/
#include <string.h>
#include "embUnit.h"
#include "net/gnrc/pkt.h"
#include "net/gnrc/mac/internal.h"
#include "unittests-constants.h"
#include "tests-gnrc_mac_internal.h"
static void set_up(void)
{
gnrc_pktbuf_init();
}
#if GNRC_MAC_TX_QUEUE_SIZE != 0
/**
* @brief This function test the `gnrc_mac_queue_tx_packet()`, to see whether it can
* correctly queue the packet to the corresponded priority packet queue.
*
* In case when the `gnrc_mac_tx_neighbor_t` structure is in used (indicated by
* by `GNRC_MAC_NEIGHBOR_COUNT != 0`), `test_gnrc_mac_queue_tx_packet()` successively
* queues 4 packets, which are pkt1, pkt2, pkt3 and pkt_bcast, into a defined `tx`
* (type of `gnrc_mac_tx_t`). Pkt1, pkt2 have the same destination address of "0x76b6",
* , pkt3 is heading for "0x447e", while pkt_bcast is for broadcasting.
* Expected results: pkt1 and pkt2 should be queued to `tx::neighbors[1]::queue`,
* pkt3 should be queued to `tx::neighbors[2]::queue`, while pkt_bcast should be
* queued to `tx::neighbors[0]::queue`.
*
* In case when the `gnrc_mac_tx_neighbor_t` structure is not in used (indicated by
* by `GNRC_MAC_NEIGHBOR_COUNT == 0`), `test_gnrc_mac_queue_tx_packet()` successively
* queues 4 packets, which are pkt1, pkt2, pkt3 and pkt_bcast, into a defined `tx`
* (type of `gnrc_mac_tx_t`). Pkt1, pkt2 have the same destination address of "0x76b6",
* , pkt3 is heading for "0x447e", while pkt_bcast is for broadcasting.
* Expected results: all packets should be queued to `tx::queue`, and ranking in
* `tx::queue` according to their priorities.
*
*/
static void test_gnrc_mac_queue_tx_packet(void)
{
gnrc_mac_tx_t tx = GNRC_MAC_TX_INIT;
gnrc_pktsnip_t *hdr;
gnrc_netif_hdr_t* netif_hdr;
uint8_t dst_addr[2];
dst_addr[0] = 0x76;
dst_addr[1] = 0xb6;
hdr = gnrc_netif_hdr_build(NULL, 0, NULL, 0);
gnrc_pktsnip_t *pkt_bcast = gnrc_pktbuf_add(NULL, TEST_STRING12, sizeof(TEST_STRING12),
GNRC_NETTYPE_UNDEF);
LL_APPEND(hdr, pkt_bcast);
pkt_bcast = hdr;
netif_hdr = hdr->data;
netif_hdr->flags |= GNRC_NETIF_HDR_FLAGS_BROADCAST;
hdr = gnrc_netif_hdr_build(NULL, 0, dst_addr, 2);
gnrc_pktsnip_t *pkt1 = gnrc_pktbuf_add(NULL, TEST_STRING4, sizeof(TEST_STRING4),
GNRC_NETTYPE_UNDEF);
LL_APPEND(hdr, pkt1);
pkt1 = hdr;
hdr = gnrc_netif_hdr_build(NULL, 0, dst_addr, 2);
gnrc_pktsnip_t *pkt2 = gnrc_pktbuf_add(NULL, TEST_STRING8, sizeof(TEST_STRING8),
GNRC_NETTYPE_UNDEF);
LL_APPEND(hdr, pkt2);
pkt2 = hdr;
dst_addr[0] = 0x44;
dst_addr[1] = 0x7e;
hdr = gnrc_netif_hdr_build(NULL, 0, dst_addr, 2);
gnrc_pktsnip_t *pkt3 = gnrc_pktbuf_add(NULL, TEST_STRING16, sizeof(TEST_STRING16),
GNRC_NETTYPE_UNDEF);
LL_APPEND(hdr, pkt3);
pkt3 = hdr;
#if GNRC_MAC_NEIGHBOR_COUNT != 0
gnrc_pktsnip_t *pkt_head;
TEST_ASSERT(gnrc_mac_queue_tx_packet(&tx,1,pkt1));
pkt_head = gnrc_priority_pktqueue_head(&tx.neighbors[1].queue);
TEST_ASSERT(pkt_head == pkt1);
TEST_ASSERT(1 == gnrc_priority_pktqueue_length(&tx.neighbors[1].queue));
TEST_ASSERT_EQUAL_STRING(TEST_STRING4, pkt_head->next->data);
TEST_ASSERT(gnrc_mac_queue_tx_packet(&tx,0,pkt2));
pkt_head = gnrc_priority_pktqueue_head(&tx.neighbors[1].queue);
TEST_ASSERT(pkt_head == pkt2);
TEST_ASSERT(2 == gnrc_priority_pktqueue_length(&tx.neighbors[1].queue));
TEST_ASSERT_EQUAL_STRING(TEST_STRING8, pkt_head->next->data);
pkt_head = gnrc_priority_pktqueue_pop(&tx.neighbors[1].queue);
TEST_ASSERT(pkt_head == pkt2);
TEST_ASSERT(1 == gnrc_priority_pktqueue_length(&tx.neighbors[1].queue));
TEST_ASSERT_EQUAL_STRING(TEST_STRING8, pkt_head->next->data);
pkt_head = gnrc_priority_pktqueue_head(&tx.neighbors[1].queue);
TEST_ASSERT(pkt_head == pkt1);
TEST_ASSERT_EQUAL_STRING(TEST_STRING4, pkt_head->next->data);
TEST_ASSERT(gnrc_mac_queue_tx_packet(&tx,0,pkt3));
pkt_head = gnrc_priority_pktqueue_head(&tx.neighbors[2].queue);
TEST_ASSERT(pkt_head == pkt3);
TEST_ASSERT(1 == gnrc_priority_pktqueue_length(&tx.neighbors[2].queue));
TEST_ASSERT_EQUAL_STRING(TEST_STRING16, pkt_head->next->data);
TEST_ASSERT(gnrc_mac_queue_tx_packet(&tx,0,pkt_bcast));
pkt_head = gnrc_priority_pktqueue_head(&tx.neighbors[0].queue);
TEST_ASSERT(pkt_head == pkt_bcast);
TEST_ASSERT(1 == gnrc_priority_pktqueue_length(&tx.neighbors[0].queue));
TEST_ASSERT_EQUAL_STRING(TEST_STRING12, pkt_head->next->data);
#else
TEST_ASSERT(gnrc_mac_queue_tx_packet(&tx,1,pkt1));
TEST_ASSERT(1 == gnrc_priority_pktqueue_length(&tx.queue));
gnrc_pktsnip_t *pkt_head;
pkt_head = gnrc_priority_pktqueue_head(&tx.queue);
TEST_ASSERT(pkt_head == pkt1);
TEST_ASSERT_EQUAL_STRING(TEST_STRING4, pkt_head->next->data);
TEST_ASSERT(gnrc_mac_queue_tx_packet(&tx,1,pkt2));
TEST_ASSERT(2 == gnrc_priority_pktqueue_length(&tx.queue));
pkt_head = gnrc_priority_pktqueue_head(&tx.queue);
TEST_ASSERT(pkt_head == pkt1);
TEST_ASSERT_EQUAL_STRING(TEST_STRING4, pkt_head->next->data);
TEST_ASSERT(gnrc_mac_queue_tx_packet(&tx,0,pkt3));
TEST_ASSERT(3 == gnrc_priority_pktqueue_length(&tx.queue));
pkt_head = gnrc_priority_pktqueue_head(&tx.queue);
TEST_ASSERT(pkt_head == pkt3);
TEST_ASSERT_EQUAL_STRING(TEST_STRING16, pkt_head->next->data);
TEST_ASSERT(gnrc_mac_queue_tx_packet(&tx,0,pkt_bcast));
TEST_ASSERT(4 == gnrc_priority_pktqueue_length(&tx.queue));
pkt_head = gnrc_priority_pktqueue_head(&tx.queue);
TEST_ASSERT(pkt_head == pkt3);
pkt_head = gnrc_priority_pktqueue_pop(&tx.queue);
TEST_ASSERT(pkt_head == pkt3);
TEST_ASSERT(3 == gnrc_priority_pktqueue_length(&tx.queue));
TEST_ASSERT_EQUAL_STRING(TEST_STRING16, pkt_head->next->data);
pkt_head = gnrc_priority_pktqueue_pop(&tx.queue);
TEST_ASSERT(pkt_head == pkt_bcast);
TEST_ASSERT(2 == gnrc_priority_pktqueue_length(&tx.queue));
TEST_ASSERT_EQUAL_STRING(TEST_STRING12, pkt_head->next->data);
pkt_head = gnrc_priority_pktqueue_pop(&tx.queue);
TEST_ASSERT(pkt_head == pkt1);
TEST_ASSERT(1 == gnrc_priority_pktqueue_length(&tx.queue));
TEST_ASSERT_EQUAL_STRING(TEST_STRING4, pkt_head->next->data);
pkt_head = gnrc_priority_pktqueue_pop(&tx.queue);
TEST_ASSERT(pkt_head == pkt2);
TEST_ASSERT(0 == gnrc_priority_pktqueue_length(&tx.queue));
TEST_ASSERT_EQUAL_STRING(TEST_STRING8, pkt_head->next->data);
#endif /* GNRC_MAC_NEIGHBOR_COUNT != 0 */
}
#endif /* GNRC_MAC_TX_QUEUE_SIZE != 0 */
#if GNRC_MAC_RX_QUEUE_SIZE != 0
/**
* @brief This function test the `gnrc_mac_queue_rx_packet()`, to see whether it can
* correctly queue the packets to `rx::queue` according to their priorities.
*
* `test_gnrc_mac_queue_tx_packet()` successively queues 3 packets, which are
* pkt1, pkt2, pkt3, into a defined `rx` (type of `gnrc_mac_rx_t`).
* Pkt1, pkt2 have the same priority of "1", while pkt3 has the priority of "0".
* Expected results: after all the packets are queued, in `rx::queue`, them should
* be ranked as (from high priority to low): pkt3, pkt1 and pkt2.
*
*/
static void test_gnrc_mac_queue_rx_packet(void)
{
gnrc_mac_rx_t rx = GNRC_MAC_RX_INIT;
gnrc_pktsnip_t *pkt1 = gnrc_pktbuf_add(NULL, TEST_STRING4, sizeof(TEST_STRING4),
GNRC_NETTYPE_UNDEF);
gnrc_pktsnip_t *pkt2 = gnrc_pktbuf_add(NULL, TEST_STRING8, sizeof(TEST_STRING8),
GNRC_NETTYPE_UNDEF);
gnrc_pktsnip_t *pkt3 = gnrc_pktbuf_add(NULL, TEST_STRING16, sizeof(TEST_STRING16),
GNRC_NETTYPE_UNDEF);
TEST_ASSERT(gnrc_mac_queue_rx_packet(&rx,1,pkt1));
TEST_ASSERT(1 == gnrc_priority_pktqueue_length(&rx.queue));
gnrc_pktsnip_t *pkt_head;
pkt_head = gnrc_priority_pktqueue_head(&rx.queue);
TEST_ASSERT(pkt_head == pkt1);
TEST_ASSERT_EQUAL_STRING(TEST_STRING4, pkt_head->data);
TEST_ASSERT(gnrc_mac_queue_rx_packet(&rx,1,pkt2));
TEST_ASSERT(2 == gnrc_priority_pktqueue_length(&rx.queue));
pkt_head = gnrc_priority_pktqueue_head(&rx.queue);
TEST_ASSERT(pkt_head == pkt1);
TEST_ASSERT_EQUAL_STRING(TEST_STRING4, pkt_head->data);
TEST_ASSERT(gnrc_mac_queue_rx_packet(&rx,0,pkt3));
TEST_ASSERT(3 == gnrc_priority_pktqueue_length(&rx.queue));
pkt_head = gnrc_priority_pktqueue_head(&rx.queue);
TEST_ASSERT(pkt_head == pkt3);
TEST_ASSERT_EQUAL_STRING(TEST_STRING16, pkt_head->data);
pkt_head = gnrc_priority_pktqueue_pop(&rx.queue);
TEST_ASSERT(pkt_head == pkt3);
TEST_ASSERT(2 == gnrc_priority_pktqueue_length(&rx.queue));
TEST_ASSERT_EQUAL_STRING(TEST_STRING16, pkt_head->data);
pkt_head = gnrc_priority_pktqueue_pop(&rx.queue);
TEST_ASSERT(pkt_head == pkt1);
TEST_ASSERT(1 == gnrc_priority_pktqueue_length(&rx.queue));
TEST_ASSERT_EQUAL_STRING(TEST_STRING4, pkt_head->data);
pkt_head = gnrc_priority_pktqueue_pop(&rx.queue);
TEST_ASSERT(pkt_head == pkt2);
TEST_ASSERT(0 == gnrc_priority_pktqueue_length(&rx.queue));
TEST_ASSERT_EQUAL_STRING(TEST_STRING8, pkt_head->data);
}
#endif /* GNRC_MAC_RX_QUEUE_SIZE != 0 */
#if GNRC_MAC_DISPATCH_BUFFER_SIZE != 0
static void test_gnrc_mac_dispatch(void)
{
gnrc_mac_rx_t rx = GNRC_MAC_RX_INIT;
for (size_t i = 0; i < GNRC_MAC_DISPATCH_BUFFER_SIZE; i++) {
rx.dispatch_buffer[i] = gnrc_pktbuf_add(NULL, TEST_STRING4, sizeof(TEST_STRING4),
GNRC_NETTYPE_UNDEF);
}
gnrc_mac_dispatch(&rx);
for (size_t i = 0; i < GNRC_MAC_DISPATCH_BUFFER_SIZE; i++) {
TEST_ASSERT_NULL(rx.dispatch_buffer[i]);
}
}
#endif /* GNRC_MAC_DISPATCH_BUFFER_SIZE != 0 */
Test *tests_gnrc_mac_internal_tests(void)
{
EMB_UNIT_TESTFIXTURES(fixtures) {
#if GNRC_MAC_TX_QUEUE_SIZE != 0
new_TestFixture(test_gnrc_mac_queue_tx_packet),
#endif /* GNRC_MAC_TX_QUEUE_SIZE != 0 */
#if GNRC_MAC_RX_QUEUE_SIZE != 0
new_TestFixture(test_gnrc_mac_queue_rx_packet),
#endif /* GNRC_MAC_RX_QUEUE_SIZE != 0 */
#if GNRC_MAC_DISPATCH_BUFFER_SIZE != 0
new_TestFixture(test_gnrc_mac_dispatch),
#endif /* GNRC_MAC_DISPATCH_BUFFER_SIZE != 0 */
};
EMB_UNIT_TESTCALLER(gnrc_mac_internal_tests, set_up, NULL, fixtures);
return (Test *)&gnrc_mac_internal_tests;
}
void tests_gnrc_mac_internal(void)
{
TESTS_RUN(tests_gnrc_mac_internal_tests());
}
/** @} */