/*
* SPDX-License-Identifier: BSD-2-Clause
*
* Copyright (C) 2018, 2019 embedded brains GmbH
*
* Redistribution and use in source and binary forms, with or without
* modification, are permitted provided that the following conditions
* are met:
* 1. Redistributions of source code must retain the above copyright
* notice, this list of conditions and the following disclaimer.
* 2. Redistributions in binary form must reproduce the above copyright
* notice, this list of conditions and the following disclaimer in the
* documentation and/or other materials provided with the distribution.
*
* THIS SOFTWARE IS PROVIDED BY THE COPYRIGHT HOLDERS AND CONTRIBUTORS "AS IS"
* AND ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE
* IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR PURPOSE
* ARE DISCLAIMED. IN NO EVENT SHALL THE COPYRIGHT OWNER OR CONTRIBUTORS BE
* LIABLE FOR ANY DIRECT, INDIRECT, INCIDENTAL, SPECIAL, EXEMPLARY, OR
* CONSEQUENTIAL DAMAGES (INCLUDING, BUT NOT LIMITED TO, PROCUREMENT OF
* SUBSTITUTE GOODS OR SERVICES; LOSS OF USE, DATA, OR PROFITS; OR BUSINESS
* INTERRUPTION) HOWEVER CAUSED AND ON ANY THEORY OF LIABILITY, WHETHER IN
* CONTRACT, STRICT LIABILITY, OR TORT (INCLUDING NEGLIGENCE OR OTHERWISE)
* ARISING IN ANY WAY OUT OF THE USE OF THIS SOFTWARE, EVEN IF ADVISED OF THE
* POSSIBILITY OF SUCH DAMAGE.
*/
#ifdef HAVE_CONFIG_H
#include "config.h"
#endif
#include <rtems/record.h>
#include <rtems.h>
#include <sys/endian.h>
#include <sys/socket.h>
#include <string.h>
#include <unistd.h>
#include <netinet/in.h>
#ifdef RTEMS_NETWORKING
#include <rtems/rtems_bsdnet.h>
#endif
#include <tmacros.h>
const char rtems_test_name[] = "RECORD 1";
#define ITEM_COUNT 4
#define ITEM_SIZE (ITEM_COUNT * sizeof(rtems_record_item))
typedef struct {
Record_Control control;
rtems_record_item items[ITEM_COUNT];
} test_context;
static test_context test_instance;
const unsigned int _Record_Item_count = ITEM_COUNT;
#define UE(user) RTEMS_RECORD_USER(user)
#define TE(t, e) RTEMS_RECORD_TIME_EVENT(t, e)
static const rtems_record_item expected_items_0[ITEM_COUNT] = {
{ .event = TE(2, UE(1)), .data = 3 }
};
static const rtems_record_item expected_items_1[ITEM_COUNT] = {
{ .event = TE(2, UE(1)), .data = 3 },
{ .event = TE(6, UE(5)), .data = 7 }
};
static const rtems_record_item expected_items_2[ITEM_COUNT] = {
{ .event = TE(2, UE(1)), .data = 3 },
{ .event = TE(6, UE(5)), .data = 7 },
{ .event = TE(10, UE(9)), .data = 11 }
};
static const rtems_record_item expected_items_3[ITEM_COUNT] = {
{ .event = TE(2, UE(1)), .data = 3 },
{ .event = TE(6, UE(5)), .data = 7 },
{ .event = TE(10, UE(9)), .data = 11 },
{ .event = TE(14, UE(13)), .data = 15 }
};
static const rtems_record_item expected_items_4[ITEM_COUNT] = {
{ .event = TE(18, UE(17)), .data = 19 },
{ .event = TE(6, UE(5)), .data = 7 },
{ .event = TE(10, UE(9)), .data = 11 },
{ .event = TE(14, UE(13)), .data = 15 }
};
static const rtems_record_item expected_items_5[ITEM_COUNT] = {
{ .event = TE(2, UE(1)), .data = 3 }
};
static const rtems_record_item expected_items_6[ITEM_COUNT] = {
{ .event = TE(2, UE(1)), .data = 3 },
{ .event = TE(6, UE(5)), .data = 7 }
};
static const rtems_record_item expected_items_7[ITEM_COUNT] = {
{ .event = TE(2, UE(1)), .data = 3 },
{ .event = TE(6, UE(5)), .data = 7 },
{ .event = TE(10, UE(9)), .data = 11 }
};
static const rtems_record_item expected_items_8[] = {
{ .event = TE(0, RTEMS_RECORD_PROCESSOR), .data = 0 },
{ .event = TE(0, RTEMS_RECORD_PER_CPU_TAIL), .data = 0 },
{ .event = TE(0, RTEMS_RECORD_PER_CPU_HEAD), .data = 3 },
{ .event = TE(2, UE(1)), .data = 3 },
{ .event = TE(5, UE(4)), .data = 6 },
{ .event = TE(8, UE(7)), .data = 9 }
};
static const rtems_record_item expected_items_9[] = {
{ .event = TE(0, RTEMS_RECORD_PROCESSOR), .data = 0 },
{ .event = TE(0, RTEMS_RECORD_PER_CPU_TAIL), .data = 3 },
{ .event = TE(0, RTEMS_RECORD_PER_CPU_HEAD), .data = 5 },
{ .event = TE(11, UE(10)), .data = 12 },
{ .event = TE(14, UE(13)), .data = 15 }
};
static const rtems_record_item expected_items_10[] = {
{ .event = TE(0, RTEMS_RECORD_PROCESSOR), .data = 0 },
{ .event = TE(0, RTEMS_RECORD_PER_CPU_TAIL), .data = 5 },
{ .event = TE(0, RTEMS_RECORD_PER_CPU_HEAD), .data = 8 },
{ .event = TE(17, UE(16)), .data = 18 },
{ .event = TE(20, UE(19)), .data = 21 },
{ .event = TE(23, UE(22)), .data = 24 }
};
static const rtems_record_item expected_items_11[] = {
{ .event = TE(0, RTEMS_RECORD_PROCESSOR), .data = 0 },
{ .event = TE(0, RTEMS_RECORD_PER_CPU_TAIL), .data = 8 },
{ .event = TE(0, RTEMS_RECORD_PER_CPU_HEAD), .data = 9 },
{ .event = TE(26, UE(25)), .data = 27 }
};
static const rtems_record_item expected_items_12[] = {
{ .event = TE(0, RTEMS_RECORD_PROCESSOR), .data = 0 },
{ .event = TE(0, RTEMS_RECORD_PER_CPU_TAIL), .data = 9 },
{ .event = TE(0, RTEMS_RECORD_PER_CPU_HEAD), .data = 15 },
{ .event = TE(38, UE(37)), .data = 39 },
{ .event = TE(41, UE(40)), .data = 42 },
{ .event = TE(44, UE(43)), .data = 45 }
};
#ifdef RTEMS_NETWORKING
static const rtems_record_item expected_items_13[] = {
{ .event = TE(0, RTEMS_RECORD_THREAD_ID), .data = 0x9010001 },
{
.event = TE(0, RTEMS_RECORD_THREAD_NAME),
.data = rtems_build_name('I', 'D', 'L', 'E')
},
{ .event = TE(0, RTEMS_RECORD_THREAD_ID), .data = 0xa010001 },
{
.event = TE(0, RTEMS_RECORD_THREAD_NAME),
.data = rtems_build_name('U', 'I', '1', ' ')
},
{ .event = TE(0, RTEMS_RECORD_THREAD_ID), .data = 0xa010002 },
{
.event = TE(0, RTEMS_RECORD_THREAD_NAME),
.data = rtems_build_name('n', 't', 'w', 'k')
},
{ .event = TE(0, RTEMS_RECORD_THREAD_ID), .data = 0xa010003 },
{
.event = TE(0, RTEMS_RECORD_THREAD_NAME),
.data = rtems_build_name('R', 'C', 'R', 'D')
}
};
#endif
static void init_context(test_context *ctx)
{
memset(ctx, 0, sizeof(*ctx));
ctx->control.mask = ITEM_COUNT - 1;
}
static void test_capacity(const Record_Control *control)
{
unsigned int capacity;
capacity = _Record_Capacity(control, 0, 0);
rtems_test_assert(capacity == 3);
capacity = _Record_Capacity(control, 0, 1);
rtems_test_assert(capacity == 2);
capacity = _Record_Capacity(control, 0, 2);
rtems_test_assert(capacity == 1);
capacity = _Record_Capacity(control, 0, 3);
rtems_test_assert(capacity == 0);
capacity = _Record_Capacity(control, 3, 3);
rtems_test_assert(capacity == 3);
capacity = _Record_Capacity(control, 3, 0);
rtems_test_assert(capacity == 2);
capacity = _Record_Capacity(control, 3, 1);
rtems_test_assert(capacity == 1);
capacity = _Record_Capacity(control, 3, 2);
rtems_test_assert(capacity == 0);
}
static void test_index(const Record_Control *control)
{
unsigned int index;
index = _Record_Index(control, 0);
rtems_test_assert(index == 0);
index = _Record_Index(control, 1);
rtems_test_assert(index == 1);
index = _Record_Index(control, 2);
rtems_test_assert(index == 2);
index = _Record_Index(control, 3);
rtems_test_assert(index == 3);
index = _Record_Index(control, 4);
rtems_test_assert(index == 0);
}
static void test_add_2_items(test_context *ctx, Record_Control *control)
{
rtems_record_context rc;
init_context(ctx);
rtems_record_prepare(&rc);
rtems_test_assert(rc.control == control);
rtems_test_assert(rc.head == 0);
rtems_test_assert(_Record_Head(control) == 0);
rtems_test_assert(_Record_Tail(control) == 0);
rc.now = RTEMS_RECORD_TIME_EVENT(2, 0);
rtems_record_add(&rc, UE(1), 3);
rtems_test_assert(rc.head == 1);
rtems_test_assert(memcmp(control->Items, expected_items_0, ITEM_SIZE) == 0);
rtems_test_assert(_Record_Head(control) == 0);
rtems_test_assert(_Record_Tail(control) == 0);
rc.now = RTEMS_RECORD_TIME_EVENT(6, 0);
rtems_record_add(&rc, UE(5), 7);
rtems_record_commit(&rc);
rtems_test_assert(rc.head == 2);
rtems_test_assert(memcmp(control->Items, expected_items_1, ITEM_SIZE) == 0);
rtems_test_assert(_Record_Head(control) == 2);
rtems_test_assert(_Record_Tail(control) == 0);
}
static void test_add_3_items(test_context *ctx, Record_Control *control)
{
rtems_record_context rc;
init_context(ctx);
rtems_record_prepare(&rc);
rtems_test_assert(rc.control == control);
rtems_test_assert(rc.head == 0);
rtems_test_assert(_Record_Head(control) == 0);
rtems_test_assert(_Record_Tail(control) == 0);
rc.now = RTEMS_RECORD_TIME_EVENT(2, 0);
rtems_record_add(&rc, UE(1), 3);
rtems_test_assert(rc.head == 1);
rtems_test_assert(memcmp(control->Items, expected_items_5, ITEM_SIZE) == 0);
rtems_test_assert(_Record_Head(control) == 0);
rtems_test_assert(_Record_Tail(control) == 0);
rc.now = RTEMS_RECORD_TIME_EVENT(6, 0);
rtems_record_add(&rc, UE(5), 7);
rtems_test_assert(rc.head == 2);
rtems_test_assert(memcmp(control->Items, expected_items_6, ITEM_SIZE) == 0);
rtems_test_assert(_Record_Head(control) == 0);
rtems_test_assert(_Record_Tail(control) == 0);
rc.now = RTEMS_RECORD_TIME_EVENT(10, 0);
rtems_record_add(&rc, UE(9), 11);
rtems_record_commit(&rc);
rtems_test_assert(rc.head == 3);
rtems_test_assert(memcmp(control->Items, expected_items_7, ITEM_SIZE) == 0);
rtems_test_assert(_Record_Head(control) == 3);
rtems_test_assert(_Record_Tail(control) == 0);
}
static void set_time(rtems_record_item *item, uint32_t time)
{
uint32_t event;
event = item->event;
event &= 0x3ff;
event |= time << 10;
item->event = event;
}
static void test_produce(test_context *ctx, Record_Control *control)
{
init_context(ctx);
rtems_record_produce(UE(1), 3);
set_time(&control->Items[0], 2);
rtems_test_assert(memcmp(control->Items, expected_items_0, ITEM_SIZE) == 0);
rtems_test_assert(_Record_Head(control) == 1);
rtems_test_assert(_Record_Tail(control) == 0);
rtems_record_produce(UE(5), 7);
set_time(&control->Items[1], 6);
rtems_test_assert(memcmp(control->Items, expected_items_1, ITEM_SIZE) == 0);
rtems_test_assert(_Record_Head(control) == 2);
rtems_test_assert(_Record_Tail(control) == 0);
rtems_record_produce(UE(9), 11);
set_time(&control->Items[2], 10);
rtems_test_assert(memcmp(control->Items, expected_items_2, ITEM_SIZE) == 0);
rtems_test_assert(_Record_Head(control) == 3);
rtems_test_assert(_Record_Tail(control) == 0);
rtems_record_produce(UE(13), 15);
set_time(&control->Items[3], 14);
rtems_test_assert(memcmp(control->Items, expected_items_3, ITEM_SIZE) == 0);
rtems_test_assert(_Record_Head(control) == 4);
rtems_test_assert(_Record_Tail(control) == 0);
rtems_record_produce(UE(17), 19);
set_time(&control->Items[0], 18);
rtems_test_assert(memcmp(control->Items, expected_items_4, ITEM_SIZE) == 0);
rtems_test_assert(_Record_Head(control) == 5);
rtems_test_assert(_Record_Tail(control) == 0);
}
static void test_produce_2(test_context *ctx, Record_Control *control)
{
init_context(ctx);
rtems_record_produce_2(UE(1), 3, UE(5), 7);
set_time(&control->Items[0], 2);
set_time(&control->Items[1], 6);
rtems_test_assert(memcmp(control->Items, expected_items_1, ITEM_SIZE) == 0);
rtems_test_assert(_Record_Head(control) == 2);
rtems_test_assert(_Record_Tail(control) == 0);
rtems_record_produce(UE(9), 11);
set_time(&control->Items[2], 10);
rtems_test_assert(memcmp(control->Items, expected_items_2, ITEM_SIZE) == 0);
rtems_test_assert(_Record_Head(control) == 3);
rtems_test_assert(_Record_Tail(control) == 0);
rtems_record_produce_2(UE(13), 15, UE(17), 19);
set_time(&control->Items[3], 14);
set_time(&control->Items[0], 18);
rtems_test_assert(memcmp(control->Items, expected_items_4, ITEM_SIZE) == 0);
rtems_test_assert(_Record_Head(control) == 5);
rtems_test_assert(_Record_Tail(control) == 0);
}
static void test_produce_n(test_context *ctx, Record_Control *control)
{
rtems_record_item items[5];
init_context(ctx);
items[0].event = UE(1);
items[0].data = 3;
items[1].event = UE(5);
items[1].data = 7;
items[2].event = UE(9);
items[2].data = 11;
items[3].event = UE(13);
items[3].data = 15;
items[4].event = UE(17);
items[4].data = 19;
rtems_record_produce_n(items, RTEMS_ARRAY_SIZE(items));
set_time(&control->Items[1], 6);
set_time(&control->Items[2], 10);
set_time(&control->Items[3], 14);
set_time(&control->Items[0], 18);
rtems_test_assert(memcmp(control->Items, expected_items_4, ITEM_SIZE) == 0);
rtems_test_assert(_Record_Head(control) == 5);
rtems_test_assert(_Record_Tail(control) == 0);
}
typedef struct {
size_t todo;
const rtems_record_item *items;
} visitor_context;
static void visitor(const rtems_record_item *items, size_t count, void *arg)
{
visitor_context *vctx;
vctx = arg;
rtems_test_assert(vctx->todo >= count);
while (count > 0) {
rtems_test_assert(memcmp(items, vctx->items, sizeof(*items)) == 0);
++items;
++vctx->items;
--count;
--vctx->todo;
}
}
static void test_drain(test_context *ctx, Record_Control *control)
{
visitor_context vctx;
init_context(ctx);
vctx.todo = 0;
vctx.items = NULL;
rtems_record_drain(visitor, &vctx);
rtems_test_assert(vctx.todo == 0);
rtems_record_produce(UE(1), 3);
set_time(&control->Items[0], 2);
rtems_record_produce(UE(4), 6);
set_time(&control->Items[1], 5);
rtems_record_produce(UE(7), 9);
set_time(&control->Items[2], 8);
vctx.todo = RTEMS_ARRAY_SIZE(expected_items_8);
vctx.items = expected_items_8;
rtems_record_drain(visitor, &vctx);
rtems_test_assert(vctx.todo == 0);
vctx.todo = 0;
vctx.items = NULL;
rtems_record_drain(visitor, &vctx);
rtems_test_assert(vctx.todo == 0);
rtems_record_produce(UE(10), 12);
set_time(&control->Items[3], 11);
rtems_record_produce(UE(13), 15);
set_time(&control->Items[0], 14);
vctx.todo = RTEMS_ARRAY_SIZE(expected_items_9);
vctx.items = expected_items_9;
rtems_record_drain(visitor, &vctx);
rtems_test_assert(vctx.todo == 0);
vctx.todo = 0;
vctx.items = NULL;
rtems_record_drain(visitor, &vctx);
rtems_test_assert(vctx.todo == 0);
rtems_record_produce(UE(16), 18);
set_time(&control->Items[1], 17);
rtems_record_produce(UE(19), 21);
set_time(&control->Items[2], 20);
rtems_record_produce(UE(22), 24);
set_time(&control->Items[3], 23);
vctx.todo = RTEMS_ARRAY_SIZE(expected_items_10);
vctx.items = expected_items_10;
rtems_record_drain(visitor, &vctx);
rtems_test_assert(vctx.todo == 0);
vctx.todo = 0;
vctx.items = NULL;
rtems_record_drain(visitor, &vctx);
rtems_test_assert(vctx.todo == 0);
rtems_record_produce(UE(25), 27);
set_time(&control->Items[0], 26);
vctx.todo = RTEMS_ARRAY_SIZE(expected_items_11);
vctx.items = expected_items_11;
rtems_record_drain(visitor, &vctx);
rtems_test_assert(vctx.todo == 0);
vctx.todo = 0;
vctx.items = NULL;
rtems_record_drain(visitor, &vctx);
rtems_test_assert(vctx.todo == 0);
rtems_record_produce(UE(28), 30);
set_time(&control->Items[1], 29);
rtems_record_produce(UE(31), 33);
set_time(&control->Items[2], 32);
rtems_record_produce(UE(34), 36);
set_time(&control->Items[3], 35);
rtems_record_produce(UE(37), 39);
set_time(&control->Items[0], 38);
rtems_record_produce(UE(40), 42);
set_time(&control->Items[1], 41);
rtems_record_produce(UE(43), 45);
set_time(&control->Items[2], 44);
vctx.todo = RTEMS_ARRAY_SIZE(expected_items_12);
vctx.items = expected_items_12;
rtems_record_drain(visitor, &vctx);
rtems_test_assert(vctx.todo == 0);
vctx.todo = 0;
vctx.items = NULL;
rtems_record_drain(visitor, &vctx);
rtems_test_assert(vctx.todo == 0);
}
#ifdef RTEMS_NETWORKING
#define PORT 1234
static uint32_t get_format(void)
{
uint32_t format;
#if BYTE_ORDER == LITTLE_ENDIAN
#if __INTPTR_WIDTH__ == 32
format = RTEMS_RECORD_FORMAT_LE_32;
#elif __INTPTR_WIDTH__ == 64
format = RTEMS_RECORD_FORMAT_LE_64;
#else
#error "unexpected __INTPTR_WIDTH__"
#endif
#elif BYTE_ORDER == BIG_ENDIAN
#if __INTPTR_WIDTH__ == 32
format = RTEMS_RECORD_FORMAT_BE_32;
#elif __INTPTR_WIDTH__ == 64
format = RTEMS_RECORD_FORMAT_BE_64;
#else
#error "unexpected __INTPTR_WIDTH__"
#endif
#else
#error "unexpected BYTE_ORDER"
#endif
return format;
}
static int connect_client(void)
{
struct sockaddr_in addr;
int fd;
int rv;
ssize_t n;
uint32_t v;
rtems_record_item item;
rtems_record_item items[8];
fd = socket(PF_INET, SOCK_STREAM, 0);
rtems_test_assert(fd >= 0);
memset(&addr, 0, sizeof(addr));
addr.sin_family = AF_INET;
addr.sin_port = htons(PORT);
addr.sin_addr.s_addr = htonl(INADDR_ANY);
rv = connect(fd, (struct sockaddr *) &addr, sizeof(addr));
rtems_test_assert(rv == 0);
n = read(fd, &v, sizeof(v));
rtems_test_assert(n == 4);
rtems_test_assert(v == get_format());
n = read(fd, &v, sizeof(v));
rtems_test_assert(n == 4);
rtems_test_assert(v == RTEMS_RECORD_MAGIC);
n = read(fd, &item, sizeof(item));
rtems_test_assert(n == (ssize_t) sizeof(item));
rtems_test_assert(item.event == TE(0, RTEMS_RECORD_VERSION));
rtems_test_assert(item.data == RTEMS_RECORD_THE_VERSION);
n = read(fd, &item, sizeof(item));
rtems_test_assert(n == (ssize_t) sizeof(item));
rtems_test_assert(item.event == TE(0, RTEMS_RECORD_PROCESSOR_MAXIMUM));
rtems_test_assert(item.data == 0);
n = read(fd, &item, sizeof(item));
rtems_test_assert(n == (ssize_t) sizeof(item));
rtems_test_assert(item.event == TE(0, RTEMS_RECORD_PER_CPU_COUNT));
rtems_test_assert(item.data == ITEM_COUNT);
n = read(fd, &item, sizeof(item));
rtems_test_assert(n == (ssize_t) sizeof(item));
rtems_test_assert(item.event == TE(0, RTEMS_RECORD_FREQUENCY));
rtems_test_assert(item.data == rtems_counter_frequency());
n = read(fd, items, sizeof(expected_items_13));
rtems_test_assert(n == (ssize_t) sizeof(expected_items_13));
rtems_test_assert(
memcmp(items, expected_items_13, sizeof(expected_items_13)) == 0
);
return fd;
}
static void produce_and_read(int fd, Record_Control *control)
{
rtems_record_item items[6];
ssize_t n;
rtems_record_produce(UE(1), 3);
set_time(&control->Items[0], 2);
rtems_record_produce(UE(4), 6);
set_time(&control->Items[1], 5);
rtems_record_produce(UE(7), 9);
set_time(&control->Items[2], 8);
n = read(fd, items, sizeof(expected_items_8));
rtems_test_assert(n == (ssize_t) sizeof(expected_items_8));
rtems_test_assert(
memcmp(items, expected_items_8, sizeof(expected_items_8)) == 0
);
rtems_record_produce(UE(10), 12);
set_time(&control->Items[3], 11);
rtems_record_produce(UE(13), 15);
set_time(&control->Items[0], 14);
n = read(fd, items, sizeof(expected_items_9));
rtems_test_assert(n == (ssize_t) sizeof(expected_items_9));
rtems_test_assert(
memcmp(items, expected_items_9, sizeof(expected_items_9)) == 0
);
rtems_record_produce(UE(16), 18);
set_time(&control->Items[1], 17);
rtems_record_produce(UE(19), 21);
set_time(&control->Items[2], 20);
rtems_record_produce(UE(22), 24);
set_time(&control->Items[3], 23);
n = read(fd, items, sizeof(expected_items_10));
rtems_test_assert(n == (ssize_t) sizeof(expected_items_10));
rtems_test_assert(
memcmp(items, expected_items_10, sizeof(expected_items_10)) == 0
);
rtems_record_produce(UE(25), 27);
set_time(&control->Items[0], 26);
n = read(fd, items, sizeof(expected_items_11));
rtems_test_assert(n == (ssize_t) sizeof(expected_items_11));
rtems_test_assert(
memcmp(items, expected_items_11, sizeof(expected_items_11)) == 0
);
rtems_record_produce(UE(28), 30);
set_time(&control->Items[1], 29);
rtems_record_produce(UE(31), 33);
set_time(&control->Items[2], 32);
rtems_record_produce(UE(34), 36);
set_time(&control->Items[3], 35);
rtems_record_produce(UE(37), 39);
set_time(&control->Items[0], 38);
rtems_record_produce(UE(40), 42);
set_time(&control->Items[1], 41);
rtems_record_produce(UE(43), 45);
set_time(&control->Items[2], 44);
n = read(fd, items, sizeof(expected_items_12));
rtems_test_assert(n == (ssize_t) sizeof(expected_items_12));
rtems_test_assert(
memcmp(items, expected_items_12, sizeof(expected_items_12)) == 0
);
}
static void test_server(test_context *ctx, Record_Control *control)
{
rtems_status_code sc;
int rv;
int fd;
init_context(ctx);
rv = rtems_bsdnet_initialize_network();
rtems_test_assert(rv == 0);
sc = rtems_record_start_server(1, PORT, 1);
rtems_test_assert(sc == RTEMS_SUCCESSFUL);
fd = connect_client();
produce_and_read(fd, control);
rv = close(fd);
rtems_test_assert(rv == 0);
}
#endif
static void Init(rtems_task_argument arg)
{
test_context *ctx;
Per_CPU_Control *cpu_self;
TEST_BEGIN();
ctx = &test_instance;
cpu_self = _Per_CPU_Get_snapshot();
cpu_self->record = &ctx->control;
init_context(ctx);
test_capacity(&ctx->control);
test_index(&ctx->control);
test_add_2_items(ctx, &ctx->control);
test_add_3_items(ctx, &ctx->control);
test_produce(ctx, &ctx->control);
test_produce_2(ctx, &ctx->control);
test_produce_n(ctx, &ctx->control);
test_drain(ctx, &ctx->control);
#ifdef RTEMS_NETWORKING
test_server(ctx, &ctx->control);
#endif
TEST_END();
rtems_test_exit(0);
}
#define CONFIGURE_APPLICATION_NEEDS_CLOCK_DRIVER
#define CONFIGURE_APPLICATION_NEEDS_SIMPLE_CONSOLE_DRIVER
#ifdef RTEMS_NETWORKING
#define CONFIGURE_LIBIO_MAXIMUM_FILE_DESCRIPTORS 7
#define CONFIGURE_MAXIMUM_TASKS 3
#define CONFIGURE_MAXIMUM_TIMERS 1
#define CONFIGURE_INIT_TASK_ATTRIBUTES RTEMS_FLOATING_POINT
#else
#define CONFIGURE_MAXIMUM_TASKS 1
#endif
#define CONFIGURE_INIT_TASK_PRIORITY 2
#define CONFIGURE_INIT_TASK_INITIAL_MODES RTEMS_DEFAULT_MODES
#define CONFIGURE_INITIAL_EXTENSIONS RTEMS_TEST_INITIAL_EXTENSION
#define CONFIGURE_RTEMS_INIT_TASKS_TABLE
#define CONFIGURE_INIT
#include <rtems/confdefs.h>
