Kenji Arai
/
RAM_Disk_Control
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main.cpp
- Committer:
- kenjiArai
- Date:
- 2019-12-27
- Revision:
- 3:c31e9e43554b
- Parent:
- 2:4c2328c61af7
- Child:
- 4:6650958e6eae
File content as of revision 3:c31e9e43554b:
/*
* Mbed Application program
* RAM Disck function with FatFs on Mbed-os5
*
* Copyright (c) 2018,'19 Kenji Arai / JH1PJL
* http://www.page.sannet.ne.jp/kenjia/index.html
* https://os.mbed.com/users/kenjiArai/
* Created: April 7th, 2018
* Revised: December 27th, 2019
*/
// Include --------------------------------------------------------------------
#include "mbed.h"
#include "FATFileSystem.h"
#include "HeapBlockDevice.h"
#include "mon.h"
#include <stdlib.h>
#include <stdio.h>
#include <errno.h>
// Definition -----------------------------------------------------------------
#if defined(TARGET_DISCO_F769NI) || defined(TARGET_DISCO_F746NG)
#define USER_SW_ON 1
#else
#define USER_SW_ON 0
#endif
#define DISK_SIZE_LIMIT (5 * 512)
#define RAM_DISK_SIZE_4MB (8192 * 512)
#define RAM_DISK_SIZE_2MB (4096 * 512)
#define RAM_DISK_SIZE_1MB (2048 * 512)
#define RAM_DISK_SIZE_512KB (1024 * 512)
#define RAM_DISK_SIZE_128KB (256 * 512)
#define RAM_DISK_SIZE_64KB (128 * 512)
#if defined(TARGET_NUCLEO_F401RE) || defined(TARGET_NUCLEO_F411RE) ||\
defined(TARGET_NUCLEO_F446RE) || defined(TARGET_NUCLEO_L476RG) ||\
defined(TARGET_NUCLEO_L152RE)
#define RAM_DISK_SIZE RAM_DISK_SIZE_64KB
#elif defined(TARGET_K64F) || defined(TARGET_NRF52840_DK) ||\
defined(TARGET_DISCO_F746NG) || defined(TARGET_DISCO_F469NI)
#define RAM_DISK_SIZE RAM_DISK_SIZE_128KB
#elif defined(TARGET_GR_LYCHEE)
#define RAM_DISK_SIZE RAM_DISK_SIZE_512KB
#elif defined(TARGET_RZ_A1H)
#define RAM_DISK_SIZE RAM_DISK_SIZE_2MB
#else
#warning "make sure disk size for your board!"
#define RAM_DISK_SIZE RAM_DISK_SIZE_64KB
#endif
#define DEBUG 0
#if DEBUG
#define DBG(...) pc.printf(__VA_ARGS__)
#else
#define DBG(...) {;}
#endif
// Constructor ----------------------------------------------------------------
DigitalOut led(LED1);
DigitalIn user_sw(BUTTON1, PullUp);
Serial pc(USBTX, USBRX, 115200);
HeapBlockDevice bd(RAM_DISK_SIZE, 512);
FATFileSystem fs("fs");
Timer tmr;
// RAM ------------------------------------------------------------------------
// ROM / Constant data --------------------------------------------------------
const char *const opening_msg0 = "RAM Disk (use Heap area) test program";
const char *const opening_msg1 = " -> run on Mbed OS-5\r\n";
// Function prototypes --------------------------------------------------------
void return_error (int ret_val);
void errno_error (void* ret_val);
//------------------------------------------------------------------------------
// Control Program
//------------------------------------------------------------------------------
int main()
{
time_t seconds;
uint32_t data0 = 10000U;
uint32_t data1 = 20000U;
uint32_t data2 = 30000U;
uint32_t data3 = 40000U;
uint32_t data4 = 50000U;
uint32_t data5 = 60000U;
if (user_sw == USER_SW_ON) {
mon();
}
DBG("line:%d\r\n", __LINE__);
pc.printf("\r\nStart\r\n");
int error = 0;
pc.printf("Welcome to the filesystem example.\r\n");
pc.printf("Mounting the filesystem on \"/fs\". \r\n");
pc.printf("Formatting a FAT, RAM-backed filesystem.\r\n");
error = FATFileSystem::format(&bd);
return_error(error);
pc.printf("Mounting the filesystem on \"/fs\". \r\n");
error = fs.mount(&bd);
return_error(error);
FILE* fp = fopen("/fs/mydata.txt", "a");
errno_error(fp);
if (fp != 0) {
pc.printf("%s%s", opening_msg0, opening_msg1);
fprintf(fp,"%s%s", opening_msg0, opening_msg1);
fclose(fp);
} else {
pc.printf("ERROR\r\n");
}
while (pc.readable()) {
char c = pc.getc(); // dummy read
mon();
}
while (true) {
DBG("line:%3d\r\n", __LINE__);
tmr.reset();
tmr.start();
uint32_t size_disk = get_disk_freespace();
uint32_t size_file = get_data_file_size("mydata.txt");
pc.printf("free disk:%8u, file:%8u ", size_disk, size_file);
fp = fopen("/fs/mydata.txt", "a");
if (size_disk <= DISK_SIZE_LIMIT) {
pc.printf("Reached RAM Disk size limitation!!\r\n");
break;
}
DBG("line:%3d\r\n", __LINE__);
if(fp != 0) {
char tmp[64];
DBG("line:%d\r\n", __LINE__);
seconds = time(NULL);
strftime(tmp, 64, "DATE %H:%M:%S,%Y/%m/%d,", localtime(&seconds));
pc.printf("%s", tmp);
fprintf(fp, "%s", tmp);
pc.printf("%08d;%08d;%08d;%08d;%08d;%08d\r\n",
++data0, ++data1, ++data2, ++data3, ++data4, ++data5);
fprintf(fp, "%08d;%08d;%08d;%08d;%08d;%08d\r\n",
data0, data1, data2, data3, data4, data5);
fclose(fp);
} else {
pc.printf("ERROR\r\n");
}
DBG("line:%3d\r\n", __LINE__);
uint32_t time_sd = tmr.read_ms();
pc.printf("time[ms]:%3d ,", time_sd);
ThisThread::sleep_for(20);
if (user_sw == USER_SW_ON) {
break;
}
if (pc.readable()) {
mon();
}
led = !led;
}
while(true) {
mon();
system_reset();
}
}
void return_error (int ret_val)
{
if (ret_val) {
pc.printf("retrun error/Failure. %d\r\n", ret_val);
}
}
void errno_error (void* ret_val)
{
if (ret_val == NULL) {
pc.printf("error #/Failure. %d \r\n", errno);
}
}