rtt-f030/components/net/lwip-2.0.2/test/unit/tcp/test_tcp_oos.c

1050 lines
35 KiB
C

#include "test_tcp_oos.h"
#include "lwip/priv/tcp_priv.h"
#include "lwip/stats.h"
#include "tcp_helper.h"
#if !LWIP_STATS || !TCP_STATS || !MEMP_STATS
#error "This tests needs TCP- and MEMP-statistics enabled"
#endif
#if !TCP_QUEUE_OOSEQ
#error "This tests needs TCP_QUEUE_OOSEQ enabled"
#endif
/** CHECK_SEGMENTS_ON_OOSEQ:
* 1: check count, seqno and len of segments on pcb->ooseq (strict)
* 0: only check that bytes are received in correct order (less strict) */
#define CHECK_SEGMENTS_ON_OOSEQ 1
#if CHECK_SEGMENTS_ON_OOSEQ
#define EXPECT_OOSEQ(x) EXPECT(x)
#else
#define EXPECT_OOSEQ(x)
#endif
/* helper functions */
/** Get the numbers of segments on the ooseq list */
static int tcp_oos_count(struct tcp_pcb* pcb)
{
int num = 0;
struct tcp_seg* seg = pcb->ooseq;
while(seg != NULL) {
num++;
seg = seg->next;
}
return num;
}
#if TCP_OOSEQ_MAX_PBUFS && (TCP_OOSEQ_MAX_PBUFS < ((TCP_WND / TCP_MSS) + 1)) && (PBUF_POOL_BUFSIZE >= (TCP_MSS + PBUF_LINK_ENCAPSULATION_HLEN + PBUF_LINK_HLEN + PBUF_IP_HLEN + PBUF_TRANSPORT_HLEN))
/** Get the numbers of pbufs on the ooseq list */
static int tcp_oos_pbuf_count(struct tcp_pcb* pcb)
{
int num = 0;
struct tcp_seg* seg = pcb->ooseq;
while(seg != NULL) {
num += pbuf_clen(seg->p);
seg = seg->next;
}
return num;
}
#endif
/** Get the seqno of a segment (by index) on the ooseq list
*
* @param pcb the pcb to check for ooseq segments
* @param seg_index index of the segment on the ooseq list
* @return seqno of the segment
*/
static u32_t
tcp_oos_seg_seqno(struct tcp_pcb* pcb, int seg_index)
{
int num = 0;
struct tcp_seg* seg = pcb->ooseq;
/* then check the actual segment */
while(seg != NULL) {
if(num == seg_index) {
return seg->tcphdr->seqno;
}
num++;
seg = seg->next;
}
fail();
return 0;
}
/** Get the tcplen (datalen + SYN/FIN) of a segment (by index) on the ooseq list
*
* @param pcb the pcb to check for ooseq segments
* @param seg_index index of the segment on the ooseq list
* @return tcplen of the segment
*/
static int
tcp_oos_seg_tcplen(struct tcp_pcb* pcb, int seg_index)
{
int num = 0;
struct tcp_seg* seg = pcb->ooseq;
/* then check the actual segment */
while(seg != NULL) {
if(num == seg_index) {
return TCP_TCPLEN(seg);
}
num++;
seg = seg->next;
}
fail();
return -1;
}
/** Get the tcplen (datalen + SYN/FIN) of all segments on the ooseq list
*
* @param pcb the pcb to check for ooseq segments
* @return tcplen of all segment
*/
static int
tcp_oos_tcplen(struct tcp_pcb* pcb)
{
int len = 0;
struct tcp_seg* seg = pcb->ooseq;
/* then check the actual segment */
while(seg != NULL) {
len += TCP_TCPLEN(seg);
seg = seg->next;
}
return len;
}
/* Setup/teardown functions */
static void
tcp_oos_setup(void)
{
tcp_remove_all();
}
static void
tcp_oos_teardown(void)
{
tcp_remove_all();
netif_list = NULL;
netif_default = NULL;
}
/* Test functions */
/** create multiple segments and pass them to tcp_input in a wrong
* order to see if ooseq-caching works correctly
* FIN is received in out-of-sequence segments only */
START_TEST(test_tcp_recv_ooseq_FIN_OOSEQ)
{
struct test_tcp_counters counters;
struct tcp_pcb* pcb;
struct pbuf *p_8_9, *p_4_8, *p_4_10, *p_2_14, *p_fin, *pinseq;
char data[] = {
1, 2, 3, 4,
5, 6, 7, 8,
9, 10, 11, 12,
13, 14, 15, 16};
ip_addr_t remote_ip, local_ip, netmask;
u16_t data_len;
u16_t remote_port = 0x100, local_port = 0x101;
struct netif netif;
LWIP_UNUSED_ARG(_i);
/* initialize local vars */
memset(&netif, 0, sizeof(netif));
IP_ADDR4(&local_ip, 192, 168, 1, 1);
IP_ADDR4(&remote_ip, 192, 168, 1, 2);
IP_ADDR4(&netmask, 255, 255, 255, 0);
test_tcp_init_netif(&netif, NULL, &local_ip, &netmask);
data_len = sizeof(data);
/* initialize counter struct */
memset(&counters, 0, sizeof(counters));
counters.expected_data_len = data_len;
counters.expected_data = data;
/* create and initialize the pcb */
pcb = test_tcp_new_counters_pcb(&counters);
EXPECT_RET(pcb != NULL);
tcp_set_state(pcb, ESTABLISHED, &local_ip, &remote_ip, local_port, remote_port);
/* create segments */
/* pinseq is sent as last segment! */
pinseq = tcp_create_rx_segment(pcb, &data[0], 4, 0, 0, TCP_ACK);
/* p1: 8 bytes before FIN */
/* seqno: 8..16 */
p_8_9 = tcp_create_rx_segment(pcb, &data[8], 8, 8, 0, TCP_ACK|TCP_FIN);
/* p2: 4 bytes before p1, including the first 4 bytes of p1 (partly duplicate) */
/* seqno: 4..11 */
p_4_8 = tcp_create_rx_segment(pcb, &data[4], 8, 4, 0, TCP_ACK);
/* p3: same as p2 but 2 bytes longer */
/* seqno: 4..13 */
p_4_10 = tcp_create_rx_segment(pcb, &data[4], 10, 4, 0, TCP_ACK);
/* p4: 14 bytes before FIN, includes data from p1 and p2, plus partly from pinseq */
/* seqno: 2..15 */
p_2_14 = tcp_create_rx_segment(pcb, &data[2], 14, 2, 0, TCP_ACK);
/* FIN, seqno 16 */
p_fin = tcp_create_rx_segment(pcb, NULL, 0,16, 0, TCP_ACK|TCP_FIN);
EXPECT(pinseq != NULL);
EXPECT(p_8_9 != NULL);
EXPECT(p_4_8 != NULL);
EXPECT(p_4_10 != NULL);
EXPECT(p_2_14 != NULL);
EXPECT(p_fin != NULL);
if ((pinseq != NULL) && (p_8_9 != NULL) && (p_4_8 != NULL) && (p_4_10 != NULL) && (p_2_14 != NULL) && (p_fin != NULL)) {
/* pass the segment to tcp_input */
test_tcp_input(p_8_9, &netif);
/* check if counters are as expected */
EXPECT(counters.close_calls == 0);
EXPECT(counters.recv_calls == 0);
EXPECT(counters.recved_bytes == 0);
EXPECT(counters.err_calls == 0);
/* check ooseq queue */
EXPECT_OOSEQ(tcp_oos_count(pcb) == 1);
EXPECT_OOSEQ(tcp_oos_seg_seqno(pcb, 0) == 8);
EXPECT_OOSEQ(tcp_oos_seg_tcplen(pcb, 0) == 9); /* includes FIN */
/* pass the segment to tcp_input */
test_tcp_input(p_4_8, &netif);
/* check if counters are as expected */
EXPECT(counters.close_calls == 0);
EXPECT(counters.recv_calls == 0);
EXPECT(counters.recved_bytes == 0);
EXPECT(counters.err_calls == 0);
/* check ooseq queue */
EXPECT_OOSEQ(tcp_oos_count(pcb) == 2);
EXPECT_OOSEQ(tcp_oos_seg_seqno(pcb, 0) == 4);
EXPECT_OOSEQ(tcp_oos_seg_tcplen(pcb, 0) == 4);
EXPECT_OOSEQ(tcp_oos_seg_seqno(pcb, 1) == 8);
EXPECT_OOSEQ(tcp_oos_seg_tcplen(pcb, 1) == 9); /* includes FIN */
/* pass the segment to tcp_input */
test_tcp_input(p_4_10, &netif);
/* check if counters are as expected */
EXPECT(counters.close_calls == 0);
EXPECT(counters.recv_calls == 0);
EXPECT(counters.recved_bytes == 0);
EXPECT(counters.err_calls == 0);
/* ooseq queue: unchanged */
EXPECT_OOSEQ(tcp_oos_count(pcb) == 2);
EXPECT_OOSEQ(tcp_oos_seg_seqno(pcb, 0) == 4);
EXPECT_OOSEQ(tcp_oos_seg_tcplen(pcb, 0) == 4);
EXPECT_OOSEQ(tcp_oos_seg_seqno(pcb, 1) == 8);
EXPECT_OOSEQ(tcp_oos_seg_tcplen(pcb, 1) == 9); /* includes FIN */
/* pass the segment to tcp_input */
test_tcp_input(p_2_14, &netif);
/* check if counters are as expected */
EXPECT(counters.close_calls == 0);
EXPECT(counters.recv_calls == 0);
EXPECT(counters.recved_bytes == 0);
EXPECT(counters.err_calls == 0);
/* check ooseq queue */
EXPECT_OOSEQ(tcp_oos_count(pcb) == 1);
EXPECT_OOSEQ(tcp_oos_seg_seqno(pcb, 0) == 2);
EXPECT_OOSEQ(tcp_oos_seg_tcplen(pcb, 0) == 15); /* includes FIN */
/* pass the segment to tcp_input */
test_tcp_input(p_fin, &netif);
/* check if counters are as expected */
EXPECT(counters.close_calls == 0);
EXPECT(counters.recv_calls == 0);
EXPECT(counters.recved_bytes == 0);
EXPECT(counters.err_calls == 0);
/* ooseq queue: unchanged */
EXPECT_OOSEQ(tcp_oos_count(pcb) == 1);
EXPECT_OOSEQ(tcp_oos_seg_seqno(pcb, 0) == 2);
EXPECT_OOSEQ(tcp_oos_seg_tcplen(pcb, 0) == 15); /* includes FIN */
/* pass the segment to tcp_input */
test_tcp_input(pinseq, &netif);
/* check if counters are as expected */
EXPECT(counters.close_calls == 1);
EXPECT(counters.recv_calls == 1);
EXPECT(counters.recved_bytes == data_len);
EXPECT(counters.err_calls == 0);
EXPECT(pcb->ooseq == NULL);
}
/* make sure the pcb is freed */
EXPECT(MEMP_STATS_GET(used, MEMP_TCP_PCB) == 1);
tcp_abort(pcb);
EXPECT(MEMP_STATS_GET(used, MEMP_TCP_PCB) == 0);
}
END_TEST
/** create multiple segments and pass them to tcp_input in a wrong
* order to see if ooseq-caching works correctly
* FIN is received IN-SEQUENCE at the end */
START_TEST(test_tcp_recv_ooseq_FIN_INSEQ)
{
struct test_tcp_counters counters;
struct tcp_pcb* pcb;
struct pbuf *p_1_2, *p_4_8, *p_3_11, *p_2_12, *p_15_1, *p_15_1a, *pinseq, *pinseqFIN;
char data[] = {
1, 2, 3, 4,
5, 6, 7, 8,
9, 10, 11, 12,
13, 14, 15, 16};
ip_addr_t remote_ip, local_ip, netmask;
u16_t data_len;
u16_t remote_port = 0x100, local_port = 0x101;
struct netif netif;
LWIP_UNUSED_ARG(_i);
/* initialize local vars */
memset(&netif, 0, sizeof(netif));
IP_ADDR4(&local_ip, 192, 168, 1, 1);
IP_ADDR4(&remote_ip, 192, 168, 1, 2);
IP_ADDR4(&netmask, 255, 255, 255, 0);
test_tcp_init_netif(&netif, NULL, &local_ip, &netmask);
data_len = sizeof(data);
/* initialize counter struct */
memset(&counters, 0, sizeof(counters));
counters.expected_data_len = data_len;
counters.expected_data = data;
/* create and initialize the pcb */
pcb = test_tcp_new_counters_pcb(&counters);
EXPECT_RET(pcb != NULL);
tcp_set_state(pcb, ESTABLISHED, &local_ip, &remote_ip, local_port, remote_port);
/* create segments */
/* p1: 7 bytes - 2 before FIN */
/* seqno: 1..2 */
p_1_2 = tcp_create_rx_segment(pcb, &data[1], 2, 1, 0, TCP_ACK);
/* p2: 4 bytes before p1, including the first 4 bytes of p1 (partly duplicate) */
/* seqno: 4..11 */
p_4_8 = tcp_create_rx_segment(pcb, &data[4], 8, 4, 0, TCP_ACK);
/* p3: same as p2 but 2 bytes longer and one byte more at the front */
/* seqno: 3..13 */
p_3_11 = tcp_create_rx_segment(pcb, &data[3], 11, 3, 0, TCP_ACK);
/* p4: 13 bytes - 2 before FIN - should be ignored as contained in p1 and p3 */
/* seqno: 2..13 */
p_2_12 = tcp_create_rx_segment(pcb, &data[2], 12, 2, 0, TCP_ACK);
/* pinseq is the first segment that is held back to create ooseq! */
/* seqno: 0..3 */
pinseq = tcp_create_rx_segment(pcb, &data[0], 4, 0, 0, TCP_ACK);
/* p5: last byte before FIN */
/* seqno: 15 */
p_15_1 = tcp_create_rx_segment(pcb, &data[15], 1, 15, 0, TCP_ACK);
/* p6: same as p5, should be ignored */
p_15_1a= tcp_create_rx_segment(pcb, &data[15], 1, 15, 0, TCP_ACK);
/* pinseqFIN: last 2 bytes plus FIN */
/* only segment containing seqno 14 and FIN */
pinseqFIN = tcp_create_rx_segment(pcb, &data[14], 2, 14, 0, TCP_ACK|TCP_FIN);
EXPECT(pinseq != NULL);
EXPECT(p_1_2 != NULL);
EXPECT(p_4_8 != NULL);
EXPECT(p_3_11 != NULL);
EXPECT(p_2_12 != NULL);
EXPECT(p_15_1 != NULL);
EXPECT(p_15_1a != NULL);
EXPECT(pinseqFIN != NULL);
if ((pinseq != NULL) && (p_1_2 != NULL) && (p_4_8 != NULL) && (p_3_11 != NULL) && (p_2_12 != NULL)
&& (p_15_1 != NULL) && (p_15_1a != NULL) && (pinseqFIN != NULL)) {
/* pass the segment to tcp_input */
test_tcp_input(p_1_2, &netif);
/* check if counters are as expected */
EXPECT(counters.close_calls == 0);
EXPECT(counters.recv_calls == 0);
EXPECT(counters.recved_bytes == 0);
EXPECT(counters.err_calls == 0);
/* check ooseq queue */
EXPECT_OOSEQ(tcp_oos_count(pcb) == 1);
EXPECT_OOSEQ(tcp_oos_seg_seqno(pcb, 0) == 1);
EXPECT_OOSEQ(tcp_oos_seg_tcplen(pcb, 0) == 2);
/* pass the segment to tcp_input */
test_tcp_input(p_4_8, &netif);
/* check if counters are as expected */
EXPECT(counters.close_calls == 0);
EXPECT(counters.recv_calls == 0);
EXPECT(counters.recved_bytes == 0);
EXPECT(counters.err_calls == 0);
/* check ooseq queue */
EXPECT_OOSEQ(tcp_oos_count(pcb) == 2);
EXPECT_OOSEQ(tcp_oos_seg_seqno(pcb, 0) == 1);
EXPECT_OOSEQ(tcp_oos_seg_tcplen(pcb, 0) == 2);
EXPECT_OOSEQ(tcp_oos_seg_seqno(pcb, 1) == 4);
EXPECT_OOSEQ(tcp_oos_seg_tcplen(pcb, 1) == 8);
/* pass the segment to tcp_input */
test_tcp_input(p_3_11, &netif);
/* check if counters are as expected */
EXPECT(counters.close_calls == 0);
EXPECT(counters.recv_calls == 0);
EXPECT(counters.recved_bytes == 0);
EXPECT(counters.err_calls == 0);
/* check ooseq queue */
EXPECT_OOSEQ(tcp_oos_count(pcb) == 2);
EXPECT_OOSEQ(tcp_oos_seg_seqno(pcb, 0) == 1);
EXPECT_OOSEQ(tcp_oos_seg_tcplen(pcb, 0) == 2);
/* p_3_11 has removed p_4_8 from ooseq */
EXPECT_OOSEQ(tcp_oos_seg_seqno(pcb, 1) == 3);
EXPECT_OOSEQ(tcp_oos_seg_tcplen(pcb, 1) == 11);
/* pass the segment to tcp_input */
test_tcp_input(p_2_12, &netif);
/* check if counters are as expected */
EXPECT(counters.close_calls == 0);
EXPECT(counters.recv_calls == 0);
EXPECT(counters.recved_bytes == 0);
EXPECT(counters.err_calls == 0);
/* check ooseq queue */
EXPECT_OOSEQ(tcp_oos_count(pcb) == 2);
EXPECT_OOSEQ(tcp_oos_seg_seqno(pcb, 0) == 1);
EXPECT_OOSEQ(tcp_oos_seg_tcplen(pcb, 0) == 1);
EXPECT_OOSEQ(tcp_oos_seg_seqno(pcb, 1) == 2);
EXPECT_OOSEQ(tcp_oos_seg_tcplen(pcb, 1) == 12);
/* pass the segment to tcp_input */
test_tcp_input(pinseq, &netif);
/* check if counters are as expected */
EXPECT(counters.close_calls == 0);
EXPECT(counters.recv_calls == 1);
EXPECT(counters.recved_bytes == 14);
EXPECT(counters.err_calls == 0);
EXPECT(pcb->ooseq == NULL);
/* pass the segment to tcp_input */
test_tcp_input(p_15_1, &netif);
/* check if counters are as expected */
EXPECT(counters.close_calls == 0);
EXPECT(counters.recv_calls == 1);
EXPECT(counters.recved_bytes == 14);
EXPECT(counters.err_calls == 0);
/* check ooseq queue */
EXPECT_OOSEQ(tcp_oos_count(pcb) == 1);
EXPECT_OOSEQ(tcp_oos_seg_seqno(pcb, 0) == 15);
EXPECT_OOSEQ(tcp_oos_seg_tcplen(pcb, 0) == 1);
/* pass the segment to tcp_input */
test_tcp_input(p_15_1a, &netif);
/* check if counters are as expected */
EXPECT(counters.close_calls == 0);
EXPECT(counters.recv_calls == 1);
EXPECT(counters.recved_bytes == 14);
EXPECT(counters.err_calls == 0);
/* check ooseq queue: unchanged */
EXPECT_OOSEQ(tcp_oos_count(pcb) == 1);
EXPECT_OOSEQ(tcp_oos_seg_seqno(pcb, 0) == 15);
EXPECT_OOSEQ(tcp_oos_seg_tcplen(pcb, 0) == 1);
/* pass the segment to tcp_input */
test_tcp_input(pinseqFIN, &netif);
/* check if counters are as expected */
EXPECT(counters.close_calls == 1);
EXPECT(counters.recv_calls == 2);
EXPECT(counters.recved_bytes == data_len);
EXPECT(counters.err_calls == 0);
EXPECT(pcb->ooseq == NULL);
}
/* make sure the pcb is freed */
EXPECT(MEMP_STATS_GET(used, MEMP_TCP_PCB) == 1);
tcp_abort(pcb);
EXPECT(MEMP_STATS_GET(used, MEMP_TCP_PCB) == 0);
}
END_TEST
static char data_full_wnd[TCP_WND + TCP_MSS];
/** create multiple segments and pass them to tcp_input with the first segment missing
* to simulate overruning the rxwin with ooseq queueing enabled */
START_TEST(test_tcp_recv_ooseq_overrun_rxwin)
{
#if !TCP_OOSEQ_MAX_BYTES && !TCP_OOSEQ_MAX_PBUFS
int i, k;
struct test_tcp_counters counters;
struct tcp_pcb* pcb;
struct pbuf *pinseq, *p_ovr;
ip_addr_t remote_ip, local_ip, netmask;
u16_t remote_port = 0x100, local_port = 0x101;
struct netif netif;
int datalen = 0;
int datalen2;
for(i = 0; i < (int)sizeof(data_full_wnd); i++) {
data_full_wnd[i] = (char)i;
}
/* initialize local vars */
memset(&netif, 0, sizeof(netif));
IP_ADDR4(&local_ip, 192, 168, 1, 1);
IP_ADDR4(&remote_ip, 192, 168, 1, 2);
IP_ADDR4(&netmask, 255, 255, 255, 0);
test_tcp_init_netif(&netif, NULL, &local_ip, &netmask);
/* initialize counter struct */
memset(&counters, 0, sizeof(counters));
counters.expected_data_len = TCP_WND;
counters.expected_data = data_full_wnd;
/* create and initialize the pcb */
pcb = test_tcp_new_counters_pcb(&counters);
EXPECT_RET(pcb != NULL);
tcp_set_state(pcb, ESTABLISHED, &local_ip, &remote_ip, local_port, remote_port);
pcb->rcv_nxt = 0x8000;
/* create segments */
/* pinseq is sent as last segment! */
pinseq = tcp_create_rx_segment(pcb, &data_full_wnd[0], TCP_MSS, 0, 0, TCP_ACK);
for(i = TCP_MSS, k = 0; i < TCP_WND; i += TCP_MSS, k++) {
int count, expected_datalen;
struct pbuf *p = tcp_create_rx_segment(pcb, &data_full_wnd[TCP_MSS*(k+1)],
TCP_MSS, TCP_MSS*(k+1), 0, TCP_ACK);
EXPECT_RET(p != NULL);
/* pass the segment to tcp_input */
test_tcp_input(p, &netif);
/* check if counters are as expected */
EXPECT(counters.close_calls == 0);
EXPECT(counters.recv_calls == 0);
EXPECT(counters.recved_bytes == 0);
EXPECT(counters.err_calls == 0);
/* check ooseq queue */
count = tcp_oos_count(pcb);
EXPECT_OOSEQ(count == k+1);
datalen = tcp_oos_tcplen(pcb);
if (i + TCP_MSS < TCP_WND) {
expected_datalen = (k+1)*TCP_MSS;
} else {
expected_datalen = TCP_WND - TCP_MSS;
}
if (datalen != expected_datalen) {
EXPECT_OOSEQ(datalen == expected_datalen);
}
}
/* pass in one more segment, cleary overrunning the rxwin */
p_ovr = tcp_create_rx_segment(pcb, &data_full_wnd[TCP_MSS*(k+1)], TCP_MSS, TCP_MSS*(k+1), 0, TCP_ACK);
EXPECT_RET(p_ovr != NULL);
/* pass the segment to tcp_input */
test_tcp_input(p_ovr, &netif);
/* check if counters are as expected */
EXPECT(counters.close_calls == 0);
EXPECT(counters.recv_calls == 0);
EXPECT(counters.recved_bytes == 0);
EXPECT(counters.err_calls == 0);
/* check ooseq queue */
EXPECT_OOSEQ(tcp_oos_count(pcb) == k);
datalen2 = tcp_oos_tcplen(pcb);
EXPECT_OOSEQ(datalen == datalen2);
/* now pass inseq */
test_tcp_input(pinseq, &netif);
EXPECT(pcb->ooseq == NULL);
/* make sure the pcb is freed */
EXPECT(MEMP_STATS_GET(used, MEMP_TCP_PCB) == 1);
tcp_abort(pcb);
EXPECT(MEMP_STATS_GET(used, MEMP_TCP_PCB) == 0);
#endif /* !TCP_OOSEQ_MAX_BYTES && !TCP_OOSEQ_MAX_PBUFS */
LWIP_UNUSED_ARG(_i);
}
END_TEST
/** similar to above test, except seqno starts near the max rxwin */
START_TEST(test_tcp_recv_ooseq_overrun_rxwin_edge)
{
#if !TCP_OOSEQ_MAX_BYTES && !TCP_OOSEQ_MAX_PBUFS
int i, k;
struct test_tcp_counters counters;
struct tcp_pcb* pcb;
struct pbuf *pinseq, *p_ovr;
ip_addr_t remote_ip, local_ip, netmask;
u16_t remote_port = 0x100, local_port = 0x101;
struct netif netif;
int datalen = 0;
int datalen2;
for(i = 0; i < (int)sizeof(data_full_wnd); i++) {
data_full_wnd[i] = (char)i;
}
/* initialize local vars */
memset(&netif, 0, sizeof(netif));
IP_ADDR4(&local_ip, 192, 168, 1, 1);
IP_ADDR4(&remote_ip, 192, 168, 1, 2);
IP_ADDR4(&netmask, 255, 255, 255, 0);
test_tcp_init_netif(&netif, NULL, &local_ip, &netmask);
/* initialize counter struct */
memset(&counters, 0, sizeof(counters));
counters.expected_data_len = TCP_WND;
counters.expected_data = data_full_wnd;
/* create and initialize the pcb */
pcb = test_tcp_new_counters_pcb(&counters);
EXPECT_RET(pcb != NULL);
tcp_set_state(pcb, ESTABLISHED, &local_ip, &remote_ip, local_port, remote_port);
pcb->rcv_nxt = 0xffffffff - (TCP_WND / 2);
/* create segments */
/* pinseq is sent as last segment! */
pinseq = tcp_create_rx_segment(pcb, &data_full_wnd[0], TCP_MSS, 0, 0, TCP_ACK);
for(i = TCP_MSS, k = 0; i < TCP_WND; i += TCP_MSS, k++) {
int count, expected_datalen;
struct pbuf *p = tcp_create_rx_segment(pcb, &data_full_wnd[TCP_MSS*(k+1)],
TCP_MSS, TCP_MSS*(k+1), 0, TCP_ACK);
EXPECT_RET(p != NULL);
/* pass the segment to tcp_input */
test_tcp_input(p, &netif);
/* check if counters are as expected */
EXPECT(counters.close_calls == 0);
EXPECT(counters.recv_calls == 0);
EXPECT(counters.recved_bytes == 0);
EXPECT(counters.err_calls == 0);
/* check ooseq queue */
count = tcp_oos_count(pcb);
EXPECT_OOSEQ(count == k+1);
datalen = tcp_oos_tcplen(pcb);
if (i + TCP_MSS < TCP_WND) {
expected_datalen = (k+1)*TCP_MSS;
} else {
expected_datalen = TCP_WND - TCP_MSS;
}
if (datalen != expected_datalen) {
EXPECT_OOSEQ(datalen == expected_datalen);
}
}
/* pass in one more segment, cleary overrunning the rxwin */
p_ovr = tcp_create_rx_segment(pcb, &data_full_wnd[TCP_MSS*(k+1)], TCP_MSS, TCP_MSS*(k+1), 0, TCP_ACK);
EXPECT_RET(p_ovr != NULL);
/* pass the segment to tcp_input */
test_tcp_input(p_ovr, &netif);
/* check if counters are as expected */
EXPECT(counters.close_calls == 0);
EXPECT(counters.recv_calls == 0);
EXPECT(counters.recved_bytes == 0);
EXPECT(counters.err_calls == 0);
/* check ooseq queue */
EXPECT_OOSEQ(tcp_oos_count(pcb) == k);
datalen2 = tcp_oos_tcplen(pcb);
EXPECT_OOSEQ(datalen == datalen2);
/* now pass inseq */
test_tcp_input(pinseq, &netif);
EXPECT(pcb->ooseq == NULL);
/* make sure the pcb is freed */
EXPECT(MEMP_STATS_GET(used, MEMP_TCP_PCB) == 1);
tcp_abort(pcb);
EXPECT(MEMP_STATS_GET(used, MEMP_TCP_PCB) == 0);
#endif /* !TCP_OOSEQ_MAX_BYTES && !TCP_OOSEQ_MAX_PBUFS */
LWIP_UNUSED_ARG(_i);
}
END_TEST
START_TEST(test_tcp_recv_ooseq_max_bytes)
{
#if TCP_OOSEQ_MAX_BYTES && (TCP_OOSEQ_MAX_BYTES < (TCP_WND + 1)) && (PBUF_POOL_BUFSIZE >= (TCP_MSS + PBUF_LINK_ENCAPSULATION_HLEN + PBUF_LINK_HLEN + PBUF_IP_HLEN + PBUF_TRANSPORT_HLEN))
int i, k;
struct test_tcp_counters counters;
struct tcp_pcb* pcb;
struct pbuf *p_ovr;
ip_addr_t remote_ip, local_ip, netmask;
u16_t remote_port = 0x100, local_port = 0x101;
struct netif netif;
int datalen = 0;
int datalen2;
for(i = 0; i < sizeof(data_full_wnd); i++) {
data_full_wnd[i] = (char)i;
}
/* initialize local vars */
memset(&netif, 0, sizeof(netif));
IP_ADDR4(&local_ip, 192, 168, 1, 1);
IP_ADDR4(&remote_ip, 192, 168, 1, 2);
IP_ADDR4(&netmask, 255, 255, 255, 0);
test_tcp_init_netif(&netif, NULL, &local_ip, &netmask);
/* initialize counter struct */
memset(&counters, 0, sizeof(counters));
counters.expected_data_len = TCP_WND;
counters.expected_data = data_full_wnd;
/* create and initialize the pcb */
pcb = test_tcp_new_counters_pcb(&counters);
EXPECT_RET(pcb != NULL);
tcp_set_state(pcb, ESTABLISHED, &local_ip, &remote_ip, local_port, remote_port);
pcb->rcv_nxt = 0x8000;
/* don't 'recv' the first segment (1 byte) so that all other segments will be ooseq */
/* create segments and 'recv' them */
for(k = 1, i = 1; k < TCP_OOSEQ_MAX_BYTES; k += TCP_MSS, i++) {
int count;
struct pbuf *p = tcp_create_rx_segment(pcb, &data_full_wnd[k],
TCP_MSS, k, 0, TCP_ACK);
EXPECT_RET(p != NULL);
EXPECT_RET(p->next == NULL);
/* pass the segment to tcp_input */
test_tcp_input(p, &netif);
/* check if counters are as expected */
EXPECT(counters.close_calls == 0);
EXPECT(counters.recv_calls == 0);
EXPECT(counters.recved_bytes == 0);
EXPECT(counters.err_calls == 0);
/* check ooseq queue */
count = tcp_oos_pbuf_count(pcb);
EXPECT_OOSEQ(count == i);
datalen = tcp_oos_tcplen(pcb);
EXPECT_OOSEQ(datalen == (i * TCP_MSS));
}
/* pass in one more segment, overrunning the limit */
p_ovr = tcp_create_rx_segment(pcb, &data_full_wnd[k+1], 1, k+1, 0, TCP_ACK);
EXPECT_RET(p_ovr != NULL);
/* pass the segment to tcp_input */
test_tcp_input(p_ovr, &netif);
/* check if counters are as expected */
EXPECT(counters.close_calls == 0);
EXPECT(counters.recv_calls == 0);
EXPECT(counters.recved_bytes == 0);
EXPECT(counters.err_calls == 0);
/* check ooseq queue (ensure the new segment was not accepted) */
EXPECT_OOSEQ(tcp_oos_count(pcb) == (i-1));
datalen2 = tcp_oos_tcplen(pcb);
EXPECT_OOSEQ(datalen2 == ((i-1) * TCP_MSS));
/* make sure the pcb is freed */
EXPECT(MEMP_STATS_GET(used, MEMP_TCP_PCB) == 1);
tcp_abort(pcb);
EXPECT(MEMP_STATS_GET(used, MEMP_TCP_PCB) == 0);
#endif /* TCP_OOSEQ_MAX_BYTES && (TCP_OOSEQ_MAX_BYTES < (TCP_WND + 1)) && (PBUF_POOL_BUFSIZE >= (TCP_MSS + PBUF_LINK_ENCAPSULATION_HLEN + PBUF_LINK_HLEN + PBUF_IP_HLEN + PBUF_TRANSPORT_HLEN)) */
LWIP_UNUSED_ARG(_i);
}
END_TEST
START_TEST(test_tcp_recv_ooseq_max_pbufs)
{
#if TCP_OOSEQ_MAX_PBUFS && (TCP_OOSEQ_MAX_PBUFS < ((TCP_WND / TCP_MSS) + 1)) && (PBUF_POOL_BUFSIZE >= (TCP_MSS + PBUF_LINK_ENCAPSULATION_HLEN + PBUF_LINK_HLEN + PBUF_IP_HLEN + PBUF_TRANSPORT_HLEN))
int i;
struct test_tcp_counters counters;
struct tcp_pcb* pcb;
struct pbuf *p_ovr;
ip_addr_t remote_ip, local_ip, netmask;
u16_t remote_port = 0x100, local_port = 0x101;
struct netif netif;
int datalen = 0;
int datalen2;
for(i = 0; i < sizeof(data_full_wnd); i++) {
data_full_wnd[i] = (char)i;
}
/* initialize local vars */
memset(&netif, 0, sizeof(netif));
IP_ADDR4(&local_ip, 192, 168, 1, 1);
IP_ADDR4(&remote_ip, 192, 168, 1, 2);
IP_ADDR4(&netmask, 255, 255, 255, 0);
test_tcp_init_netif(&netif, NULL, &local_ip, &netmask);
/* initialize counter struct */
memset(&counters, 0, sizeof(counters));
counters.expected_data_len = TCP_WND;
counters.expected_data = data_full_wnd;
/* create and initialize the pcb */
pcb = test_tcp_new_counters_pcb(&counters);
EXPECT_RET(pcb != NULL);
tcp_set_state(pcb, ESTABLISHED, &local_ip, &remote_ip, local_port, remote_port);
pcb->rcv_nxt = 0x8000;
/* don't 'recv' the first segment (1 byte) so that all other segments will be ooseq */
/* create segments and 'recv' them */
for(i = 1; i <= TCP_OOSEQ_MAX_PBUFS; i++) {
int count;
struct pbuf *p = tcp_create_rx_segment(pcb, &data_full_wnd[i],
1, i, 0, TCP_ACK);
EXPECT_RET(p != NULL);
EXPECT_RET(p->next == NULL);
/* pass the segment to tcp_input */
test_tcp_input(p, &netif);
/* check if counters are as expected */
EXPECT(counters.close_calls == 0);
EXPECT(counters.recv_calls == 0);
EXPECT(counters.recved_bytes == 0);
EXPECT(counters.err_calls == 0);
/* check ooseq queue */
count = tcp_oos_pbuf_count(pcb);
EXPECT_OOSEQ(count == i);
datalen = tcp_oos_tcplen(pcb);
EXPECT_OOSEQ(datalen == i);
}
/* pass in one more segment, overrunning the limit */
p_ovr = tcp_create_rx_segment(pcb, &data_full_wnd[i+1], 1, i+1, 0, TCP_ACK);
EXPECT_RET(p_ovr != NULL);
/* pass the segment to tcp_input */
test_tcp_input(p_ovr, &netif);
/* check if counters are as expected */
EXPECT(counters.close_calls == 0);
EXPECT(counters.recv_calls == 0);
EXPECT(counters.recved_bytes == 0);
EXPECT(counters.err_calls == 0);
/* check ooseq queue (ensure the new segment was not accepted) */
EXPECT_OOSEQ(tcp_oos_count(pcb) == (i-1));
datalen2 = tcp_oos_tcplen(pcb);
EXPECT_OOSEQ(datalen2 == (i-1));
/* make sure the pcb is freed */
EXPECT(MEMP_STATS_GET(used, MEMP_TCP_PCB) == 1);
tcp_abort(pcb);
EXPECT(MEMP_STATS_GET(used, MEMP_TCP_PCB) == 0);
#endif /* TCP_OOSEQ_MAX_PBUFS && (TCP_OOSEQ_MAX_BYTES < (TCP_WND + 1)) && (PBUF_POOL_BUFSIZE >= (TCP_MSS + PBUF_LINK_ENCAPSULATION_HLEN + PBUF_LINK_HLEN + PBUF_IP_HLEN + PBUF_TRANSPORT_HLEN)) */
LWIP_UNUSED_ARG(_i);
}
END_TEST
static void
check_rx_counters(struct tcp_pcb *pcb, struct test_tcp_counters *counters, u32_t exp_close_calls, u32_t exp_rx_calls,
u32_t exp_rx_bytes, u32_t exp_err_calls, int exp_oos_count, int exp_oos_len)
{
int oos_len;
EXPECT(counters->close_calls == exp_close_calls);
EXPECT(counters->recv_calls == exp_rx_calls);
EXPECT(counters->recved_bytes == exp_rx_bytes);
EXPECT(counters->err_calls == exp_err_calls);
/* check that pbuf is queued in ooseq */
EXPECT_OOSEQ(tcp_oos_count(pcb) == exp_oos_count);
oos_len = tcp_oos_tcplen(pcb);
EXPECT_OOSEQ(exp_oos_len == oos_len);
}
/* this test uses 4 packets:
* - data (len=TCP_MSS)
* - FIN
* - data after FIN (len=1) (invalid)
* - 2nd FIN (invalid)
*
* the parameter 'delay_packet' is a bitmask that choses which on these packets is ooseq
*/
static void test_tcp_recv_ooseq_double_FINs(int delay_packet)
{
int i, k;
struct test_tcp_counters counters;
struct tcp_pcb* pcb;
struct pbuf *p_normal_fin, *p_data_after_fin, *p, *p_2nd_fin_ooseq;
ip_addr_t remote_ip, local_ip, netmask;
u16_t remote_port = 0x100, local_port = 0x101;
struct netif netif;
u32_t exp_rx_calls = 0, exp_rx_bytes = 0, exp_close_calls = 0, exp_oos_pbufs = 0, exp_oos_tcplen = 0;
int first_dropped = 0xff;
for(i = 0; i < (int)sizeof(data_full_wnd); i++) {
data_full_wnd[i] = (char)i;
}
/* initialize local vars */
memset(&netif, 0, sizeof(netif));
IP_ADDR4(&local_ip, 192, 168, 1, 1);
IP_ADDR4(&remote_ip, 192, 168, 1, 2);
IP_ADDR4(&netmask, 255, 255, 255, 0);
test_tcp_init_netif(&netif, NULL, &local_ip, &netmask);
/* initialize counter struct */
memset(&counters, 0, sizeof(counters));
counters.expected_data_len = TCP_WND;
counters.expected_data = data_full_wnd;
/* create and initialize the pcb */
pcb = test_tcp_new_counters_pcb(&counters);
EXPECT_RET(pcb != NULL);
tcp_set_state(pcb, ESTABLISHED, &local_ip, &remote_ip, local_port, remote_port);
pcb->rcv_nxt = 0x8000;
/* create segments */
p = tcp_create_rx_segment(pcb, &data_full_wnd[0], TCP_MSS, 0, 0, TCP_ACK);
p_normal_fin = tcp_create_rx_segment(pcb, NULL, 0, TCP_MSS, 0, TCP_ACK|TCP_FIN);
k = 1;
p_data_after_fin = tcp_create_rx_segment(pcb, &data_full_wnd[TCP_MSS+1], k, TCP_MSS+1, 0, TCP_ACK);
p_2nd_fin_ooseq = tcp_create_rx_segment(pcb, NULL, 0, TCP_MSS+1+k, 0, TCP_ACK|TCP_FIN);
if(delay_packet & 1) {
/* drop normal data */
first_dropped = 1;
} else {
/* send normal data */
test_tcp_input(p, &netif);
exp_rx_calls++;
exp_rx_bytes += TCP_MSS;
}
/* check if counters are as expected */
check_rx_counters(pcb, &counters, exp_close_calls, exp_rx_calls, exp_rx_bytes, 0, exp_oos_pbufs, exp_oos_tcplen);
if(delay_packet & 2) {
/* drop FIN */
if(first_dropped > 2) {
first_dropped = 2;
}
} else {
/* send FIN */
test_tcp_input(p_normal_fin, &netif);
if (first_dropped < 2) {
/* already dropped packets, this one is ooseq */
exp_oos_pbufs++;
exp_oos_tcplen++;
} else {
/* inseq */
exp_close_calls++;
}
}
/* check if counters are as expected */
check_rx_counters(pcb, &counters, exp_close_calls, exp_rx_calls, exp_rx_bytes, 0, exp_oos_pbufs, exp_oos_tcplen);
if(delay_packet & 4) {
/* drop data-after-FIN */
if(first_dropped > 3) {
first_dropped = 3;
}
} else {
/* send data-after-FIN */
test_tcp_input(p_data_after_fin, &netif);
if (first_dropped < 3) {
/* already dropped packets, this one is ooseq */
if (delay_packet & 2) {
/* correct FIN was ooseq */
exp_oos_pbufs++;
exp_oos_tcplen += k;
}
} else {
/* inseq: no change */
}
}
/* check if counters are as expected */
check_rx_counters(pcb, &counters, exp_close_calls, exp_rx_calls, exp_rx_bytes, 0, exp_oos_pbufs, exp_oos_tcplen);
if(delay_packet & 8) {
/* drop 2nd-FIN */
if(first_dropped > 4) {
first_dropped = 4;
}
} else {
/* send 2nd-FIN */
test_tcp_input(p_2nd_fin_ooseq, &netif);
if (first_dropped < 3) {
/* already dropped packets, this one is ooseq */
if (delay_packet & 2) {
/* correct FIN was ooseq */
exp_oos_pbufs++;
exp_oos_tcplen++;
}
} else {
/* inseq: no change */
}
}
/* check if counters are as expected */
check_rx_counters(pcb, &counters, exp_close_calls, exp_rx_calls, exp_rx_bytes, 0, exp_oos_pbufs, exp_oos_tcplen);
if(delay_packet & 1) {
/* dropped normal data before */
test_tcp_input(p, &netif);
exp_rx_calls++;
exp_rx_bytes += TCP_MSS;
if((delay_packet & 2) == 0) {
/* normal FIN was NOT delayed */
exp_close_calls++;
exp_oos_pbufs = exp_oos_tcplen = 0;
}
}
/* check if counters are as expected */
check_rx_counters(pcb, &counters, exp_close_calls, exp_rx_calls, exp_rx_bytes, 0, exp_oos_pbufs, exp_oos_tcplen);
if(delay_packet & 2) {
/* dropped normal FIN before */
test_tcp_input(p_normal_fin, &netif);
exp_close_calls++;
exp_oos_pbufs = exp_oos_tcplen = 0;
}
/* check if counters are as expected */
check_rx_counters(pcb, &counters, exp_close_calls, exp_rx_calls, exp_rx_bytes, 0, exp_oos_pbufs, exp_oos_tcplen);
if(delay_packet & 4) {
/* dropped data-after-FIN before */
test_tcp_input(p_data_after_fin, &netif);
}
/* check if counters are as expected */
check_rx_counters(pcb, &counters, exp_close_calls, exp_rx_calls, exp_rx_bytes, 0, exp_oos_pbufs, exp_oos_tcplen);
if(delay_packet & 8) {
/* dropped 2nd-FIN before */
test_tcp_input(p_2nd_fin_ooseq, &netif);
}
/* check if counters are as expected */
check_rx_counters(pcb, &counters, exp_close_calls, exp_rx_calls, exp_rx_bytes, 0, exp_oos_pbufs, exp_oos_tcplen);
/* check that ooseq data has been dumped */
EXPECT(pcb->ooseq == NULL);
/* make sure the pcb is freed */
EXPECT(MEMP_STATS_GET(used, MEMP_TCP_PCB) == 1);
tcp_abort(pcb);
EXPECT(MEMP_STATS_GET(used, MEMP_TCP_PCB) == 0);
}
/** create multiple segments and pass them to tcp_input with the first segment missing
* to simulate overruning the rxwin with ooseq queueing enabled */
#define FIN_TEST(name, num) \
START_TEST(name) \
{ \
LWIP_UNUSED_ARG(_i); \
test_tcp_recv_ooseq_double_FINs(num); \
} \
END_TEST
FIN_TEST(test_tcp_recv_ooseq_double_FIN_0, 0)
FIN_TEST(test_tcp_recv_ooseq_double_FIN_1, 1)
FIN_TEST(test_tcp_recv_ooseq_double_FIN_2, 2)
FIN_TEST(test_tcp_recv_ooseq_double_FIN_3, 3)
FIN_TEST(test_tcp_recv_ooseq_double_FIN_4, 4)
FIN_TEST(test_tcp_recv_ooseq_double_FIN_5, 5)
FIN_TEST(test_tcp_recv_ooseq_double_FIN_6, 6)
FIN_TEST(test_tcp_recv_ooseq_double_FIN_7, 7)
FIN_TEST(test_tcp_recv_ooseq_double_FIN_8, 8)
FIN_TEST(test_tcp_recv_ooseq_double_FIN_9, 9)
FIN_TEST(test_tcp_recv_ooseq_double_FIN_10, 10)
FIN_TEST(test_tcp_recv_ooseq_double_FIN_11, 11)
FIN_TEST(test_tcp_recv_ooseq_double_FIN_12, 12)
FIN_TEST(test_tcp_recv_ooseq_double_FIN_13, 13)
FIN_TEST(test_tcp_recv_ooseq_double_FIN_14, 14)
FIN_TEST(test_tcp_recv_ooseq_double_FIN_15, 15)
/** Create the suite including all tests for this module */
Suite *
tcp_oos_suite(void)
{
testfunc tests[] = {
TESTFUNC(test_tcp_recv_ooseq_FIN_OOSEQ),
TESTFUNC(test_tcp_recv_ooseq_FIN_INSEQ),
TESTFUNC(test_tcp_recv_ooseq_overrun_rxwin),
TESTFUNC(test_tcp_recv_ooseq_overrun_rxwin_edge),
TESTFUNC(test_tcp_recv_ooseq_max_bytes),
TESTFUNC(test_tcp_recv_ooseq_max_pbufs),
TESTFUNC(test_tcp_recv_ooseq_double_FIN_0),
TESTFUNC(test_tcp_recv_ooseq_double_FIN_1),
TESTFUNC(test_tcp_recv_ooseq_double_FIN_2),
TESTFUNC(test_tcp_recv_ooseq_double_FIN_3),
TESTFUNC(test_tcp_recv_ooseq_double_FIN_4),
TESTFUNC(test_tcp_recv_ooseq_double_FIN_5),
TESTFUNC(test_tcp_recv_ooseq_double_FIN_6),
TESTFUNC(test_tcp_recv_ooseq_double_FIN_7),
TESTFUNC(test_tcp_recv_ooseq_double_FIN_8),
TESTFUNC(test_tcp_recv_ooseq_double_FIN_9),
TESTFUNC(test_tcp_recv_ooseq_double_FIN_10),
TESTFUNC(test_tcp_recv_ooseq_double_FIN_11),
TESTFUNC(test_tcp_recv_ooseq_double_FIN_12),
TESTFUNC(test_tcp_recv_ooseq_double_FIN_13),
TESTFUNC(test_tcp_recv_ooseq_double_FIN_14),
TESTFUNC(test_tcp_recv_ooseq_double_FIN_15)
};
return create_suite("TCP_OOS", tests, sizeof(tests)/sizeof(testfunc), tcp_oos_setup, tcp_oos_teardown);
}