Embedded/filex
1
0
Fork 0
mirror of https://github.com/azure-rtos/filex.git synced 2025-01-25 01:32:54 +08:00
Code Issues Projects Releases Wiki Activity
filex/test/regression_test/filex_utility_fat_flush_test.c
TiejunZhou 9448cdfd6d
Add test files and regression build system (#43) 
* Add test files and regression build system
2023-11-22 15:11:59 +08:00

431 lines
13 KiB
C
Raw Permalink Blame History

/* This FileX test concentrates on the utility FAT flush operation. */
#ifndef FX_STANDALONE_ENABLE
#include "tx_api.h"
#endif
#include "fx_api.h"
#include "fx_utility.h"
#include <stdio.h>
#include "fx_ram_driver_test.h"
#define DEMO_STACK_SIZE 4096
#define CACHE_SIZE 16*128
/* Define the ThreadX and FileX object control blocks... */
#ifndef FX_STANDALONE_ENABLE
static TX_THREAD ftest_0;
#endif
static FX_MEDIA ram_disk;
static FX_FILE my_file;
/* Define the counters used in the test application... */
#ifndef FX_STANDALONE_ENABLE
static UCHAR *ram_disk_memory;
static UCHAR *cache_buffer;
#else
static UCHAR cache_buffer[CACHE_SIZE];
#endif
/* Define thread prototypes. */
void filex_utility_fat_flush_application_define(void *first_unused_memory);
static void ftest_0_entry(ULONG thread_input);
VOID _fx_ram_driver(FX_MEDIA *media_ptr);
void test_control_return(UINT status);
/* Define what the initial system looks like. */
#ifdef CTEST
void test_application_define(void *first_unused_memory)
#else
void filex_utility_fat_flush_application_define(void *first_unused_memory)
#endif
{
#ifndef FX_STANDALONE_ENABLE
UCHAR *pointer;
/* Setup the working pointer. */
pointer = (UCHAR *) first_unused_memory;
/* Create the main thread. */
tx_thread_create(&ftest_0, "thread 0", ftest_0_entry, 0,
pointer, DEMO_STACK_SIZE,
4, 4, TX_NO_TIME_SLICE, TX_AUTO_START);
pointer = pointer + DEMO_STACK_SIZE;
/* Setup memory for the RAM disk and the sector cache. */
cache_buffer = pointer;
pointer = pointer + CACHE_SIZE;
ram_disk_memory = pointer;
#endif
/* Initialize the FileX system. */
fx_system_initialize();
#ifdef FX_STANDALONE_ENABLE
ftest_0_entry(0);
#endif
}
/* Define the test threads. */
static void ftest_0_entry(ULONG thread_input)
{
UINT status;
ULONG actual;
ULONG read_value;
ULONG write_value;
ULONG available_bytes;
ULONG i;
FX_PARAMETER_NOT_USED(thread_input);
/* Print out some test information banners. */
printf("FileX Test: Utility FAT flush test.......................................");
/* Format the media. This needs to be done before opening it! */
status = fx_media_format(&ram_disk,
_fx_ram_driver, // Driver entry
ram_disk_memory, // RAM disk memory pointer
cache_buffer, // Media buffer pointer
CACHE_SIZE, // Media buffer size
"MY_RAM_DISK", // Volume Name
1, // Number of FATs
32, // Directory Entries
0, // Hidden sectors
511, // Total sectors
128, // Sector size
1, // Sectors per cluster
1, // Heads
1); // Sectors per track
/* Determine if the format had an error. */
if (status)
{
printf("ERROR!\n");
test_control_return(2);
}
/* Open the ram_disk. */
status = fx_media_open(&ram_disk, "RAM DISK", _fx_ram_driver, ram_disk_memory, cache_buffer, CACHE_SIZE);
/* Check the status. */
if (status != FX_SUCCESS)
{
/* Error, return error code. */
printf("ERROR!\n");
test_control_return(21);
}
/* Create a file called TEST.TXT in the root directory. */
status = fx_file_create(&ram_disk, "TEST.TXT");
/* Check the create status. */
if (status != FX_SUCCESS)
{
printf("ERROR!\n");
test_control_return(3);
}
/* Open the test file. */
status = fx_file_open(&ram_disk, &my_file, "TEST.TXT", FX_OPEN_FOR_WRITE);
/* Check the file open status. */
if (status != FX_SUCCESS)
{
printf("ERROR!\n");
test_control_return(4);
}
/* Pickup the available bytes in the media. */
status = fx_media_space_available(&ram_disk, &available_bytes);
/* Check for available bytes error. */
if ((status != FX_SUCCESS) || (available_bytes < sizeof(ULONG)))
{
printf("ERROR!\n");
test_control_return(5);
}
/* Loop to write successive bytes out to the file.... to fill the media! */
i = 0;
write_value = 0;
while (i < available_bytes)
{
/* Write 4 bytes to the file. */
status = fx_file_write(&my_file, (void *) &write_value, sizeof(ULONG));
/* Check the file write status. */
if (status != FX_SUCCESS)
{
printf("ERROR!\n");
test_control_return(6);
}
/* Increment byte count. */
i = i + sizeof(ULONG);
/* Increment write value. */
write_value++;
}
/* Pickup the available bytes in the media again. */
status = fx_media_space_available(&ram_disk, &i);
/* Check for available bytes error. */
if ((status != FX_SUCCESS) || (i != 0))
{
printf("ERROR!\n");
test_control_return(7);
}
for (i = 0; i < FX_MAX_FAT_CACHE; i++)
{
ram_disk.fx_media_fat_cache[i].fx_fat_cache_entry_cluster = 496;
ram_disk.fx_media_fat_cache[i].fx_fat_cache_entry_value = 1;
ram_disk.fx_media_fat_cache[i].fx_fat_cache_entry_dirty = 1;
}
_fx_utility_FAT_flush(&ram_disk);
/* Note: If definition of FX_FAT_MAP_SIZE is changed in future, the value checked in
return_value_if_fail will change for individual array element */
for(i=0;i<FX_FAT_MAP_SIZE;i++)
{
return_value_if_fail((ram_disk.fx_media_fat_secondary_update_map[i]==63),8)
}
fx_media_close(&ram_disk);
/* Test with FAT 16 */
/* Format the media. This needs to be done before opening it! */
status = fx_media_format(&ram_disk,
_fx_ram_driver, // Driver entry
ram_disk_memory, // RAM disk memory pointer
cache_buffer, // Media buffer pointer
CACHE_SIZE, // Media buffer size
"MY_RAM_DISK", // Volume Name
1, // Number of FATs
32, // Directory Entries
0, // Hidden sectors
14000, // Total sectors - FAT16
64, // Sector size
2, // Sectors per cluster
1, // Heads
1); // Sectors per track
/* Determine if the format had an error. */
if (status)
{
printf("ERROR!\n");
test_control_return(2);
}
/* Open the ram_disk. */
status = fx_media_open(&ram_disk, "RAM DISK", _fx_ram_driver, ram_disk_memory, cache_buffer, CACHE_SIZE);
/* Check the status. */
if (status != FX_SUCCESS)
{
/* Error, return error code. */
printf("ERROR!\n");
test_control_return(21);
}
/* Create a file called TEST.TXT in the root directory. */
status = fx_file_create(&ram_disk, "TEST.TXT");
/* Check the create status. */
if (status != FX_SUCCESS)
{
printf("ERROR!\n");
test_control_return(3);
}
/* Open the test file. */
status = fx_file_open(&ram_disk, &my_file, "TEST.TXT", FX_OPEN_FOR_WRITE);
/* Check the file open status. */
if (status != FX_SUCCESS)
{
printf("ERROR!\n");
test_control_return(4);
}
/* Pickup the available bytes in the media. */
status = fx_media_space_available(&ram_disk, &available_bytes);
/* Check for available bytes error. */
if ((status != FX_SUCCESS) || (available_bytes < sizeof(ULONG)))
{
printf("ERROR!\n");
test_control_return(5);
}
/* Loop to write successive bytes out to the file.... to fill the media! */
i = 0;
write_value = 0;
while (i < available_bytes)
{
/* Write 4 bytes to the file. */
status = fx_file_write(&my_file, (void *) &write_value, sizeof(ULONG));
/* Check the file write status. */
if (status != FX_SUCCESS)
{
printf("ERROR!\n");
test_control_return(6);
}
/* Increment byte count. */
i = i + sizeof(ULONG);
/* Increment write value. */
write_value++;
}
/* Pickup the available bytes in the media again. */
status = fx_media_space_available(&ram_disk, &i);
/* Check for available bytes error. */
if ((status != FX_SUCCESS) || (i != 0))
{
printf("ERROR!\n");
test_control_return(7);
}
for (i = 0; i < FX_MAX_FAT_CACHE; i++)
{
ram_disk.fx_media_fat_cache[i].fx_fat_cache_entry_cluster = 0xA6;
ram_disk.fx_media_fat_cache[i].fx_fat_cache_entry_value = 1;
ram_disk.fx_media_fat_cache[i].fx_fat_cache_entry_dirty = 1;
}
_fx_utility_FAT_flush(&ram_disk);
/* Note: If definition of FX_FAT_MAP_SIZE is changed in future, the value checked in
return_value_if_fail will change for individual array element */
for(i=0;i<FX_FAT_MAP_SIZE;i++)
{
return_value_if_fail((ram_disk.fx_media_fat_secondary_update_map[i]==255),8)
}
fx_media_close(&ram_disk);
/* Test with FAT32. */
status = fx_media_format(&ram_disk,
_fx_ram_driver, // Driver entry
ram_disk_memory, // RAM disk memory pointer
cache_buffer, // Media buffer pointer
CACHE_SIZE, // Media buffer size
"MY_RAM_DISK", // Volume Name
1, // Number of FATs
32, // Directory Entries
0, // Hidden sectors
70000, // Total sectors - FAT32
512, // Sector size
1, // Sectors per cluster
1, // Heads
1); // Sectors per track
status += fx_media_open(&ram_disk, "RAM DISK", _fx_ram_driver, ram_disk_memory, cache_buffer, CACHE_SIZE);
status += fx_file_create(&ram_disk, "TEST.TXT");
return_if_fail(FX_SUCCESS == status);
/* Open the test file. */
status = fx_file_open(&ram_disk, &my_file, "TEST.TXT", FX_OPEN_FOR_WRITE);
/* Check the file open status. */
if (status != FX_SUCCESS)
{
printf("ERROR!\n");
test_control_return(4);
}
/* Pickup the available bytes in the media. */
status = fx_media_space_available(&ram_disk, &available_bytes);
/* Check for available bytes error. */
if ((status != FX_SUCCESS) || (available_bytes < sizeof(ULONG)))
{
printf("ERROR!\n");
test_control_return(5);
}
/* Loop to write successive bytes out to the file.... to fill the media! */
i = 0;
write_value = 0;
while (i < available_bytes/128)
{
/* Write 4 bytes to the file. */
status = fx_file_write(&my_file, (void *) &write_value, sizeof(ULONG));
/* Check the file write status. */
if (status != FX_SUCCESS)
{
printf("ERROR!\n");
test_control_return(6);
}
/* Increment byte count. */
i = i + sizeof(ULONG);
/* Increment write value. */
write_value++;
}
for (i = 0; i < FX_MAX_FAT_CACHE; i++)
{
ram_disk.fx_media_fat_cache[i].fx_fat_cache_entry_cluster = 0xF160;
ram_disk.fx_media_fat_cache[i].fx_fat_cache_entry_value = 1;
ram_disk.fx_media_fat_cache[i].fx_fat_cache_entry_dirty = 1;
}
_fx_utility_FAT_flush(&ram_disk);
/* Note: If definition of FX_FAT_MAP_SIZE is changed in future, the value checked in
return_value_if_fail will change for individual array element */
for(i=0;i<FX_FAT_MAP_SIZE;i++)
{
return_value_if_fail((ram_disk.fx_media_fat_secondary_update_map[i]==65),8)
}
fx_media_close(&ram_disk);
printf("SUCCESS!\n");
test_control_return(0);
}
Reference in New Issue View Git Blame Copy Permalink