int main(){
//printf("1erwerwer\n");
mf_handle_t mf = mf_open("test");
//printf("2\n");
char buf[20 ] = "1111";
mf_write(mf, buf, 4, 3);
//printf("3\n");
mf_read(mf, buf, 10, 1);
//printf("4\n");
printf("%s\n %d\n", buf, (int)mf_file_size(mf));
//printf("%d\n", 40*1024*(1024*1024/sysconf(_SC_PAGE_SIZE)));
mf_close(mf);
//printf("5\n");
return 0;
}
/*
* Sync the memory file *mfp to disk.
* Flags:
* MFS_ALL If not given, blocks with negative numbers are not synced,
* even when they are dirty!
* MFS_STOP Stop syncing when a character becomes available, but sync at
* least one block.
* MFS_FLUSH Make sure buffers are flushed to disk, so they will survive a
* system crash.
* MFS_ZERO Only write block 0.
*
* Return FAIL for failure, OK otherwise
*/
int
mf_sync(memfile_T *mfp, int flags)
{
int status;
bhdr_T *hp;
#if defined(SYNC_DUP_CLOSE)
int fd;
#endif
int got_int_save = got_int;
if (mfp->mf_fd < 0) /* there is no file, nothing to do */
{
mfp->mf_dirty = FALSE;
return FAIL;
}
/* Only a CTRL-C while writing will break us here, not one typed
* previously. */
got_int = FALSE;
/*
* sync from last to first (may reduce the probability of an inconsistent
* file) If a write fails, it is very likely caused by a full filesystem.
* Then we only try to write blocks within the existing file. If that also
* fails then we give up.
*/
status = OK;
for (hp = mfp->mf_used_last; hp != NULL; hp = hp->bh_prev)
if (((flags & MFS_ALL) || hp->bh_bnum >= 0)
&& (hp->bh_flags & BH_DIRTY)
&& (status == OK || (hp->bh_bnum >= 0
&& hp->bh_bnum < mfp->mf_infile_count)))
{
if ((flags & MFS_ZERO) && hp->bh_bnum != 0)
continue;
if (mf_write(mfp, hp) == FAIL)
{
if (status == FAIL) /* double error: quit syncing */
break;
status = FAIL;
}
if (flags & MFS_STOP)
{
/* Stop when char available now. */
if (ui_char_avail())
break;
}
else
ui_breakcheck();
if (got_int)
break;
}
/*
* If the whole list is flushed, the memfile is not dirty anymore.
* In case of an error this flag is also set, to avoid trying all the time.
*/
if (hp == NULL || status == FAIL)
mfp->mf_dirty = FALSE;
if ((flags & MFS_FLUSH) && *p_sws != NUL)
{
#if defined(UNIX)
# ifdef HAVE_FSYNC
/*
* most Unixes have the very useful fsync() function, just what we need.
* However, with OS/2 and EMX it is also available, but there are
* reports of bad problems with it (a bug in HPFS.IFS).
* So we disable use of it here in case someone tries to be smart
* and changes os_os2_cfg.h... (even though there is no __EMX__ test
* in the #if, as __EMX__ does not have sync(); we hope for a timely
* sync from the system itself).
*/
# if defined(__EMX__)
error "Don't use fsync with EMX! Read emxdoc.doc or emxfix01.doc for info."
# endif
if (STRCMP(p_sws, "fsync") == 0)
{
if (fsync(mfp->mf_fd))
status = FAIL;
}
else
# endif
/* OpenNT is strictly POSIX (Benzinger) */
/* Tandem/Himalaya NSK-OSS doesn't have sync() */
/* No sync() on Stratus VOS */
# if defined(__OPENNT) || defined(__TANDEM) || defined(__VOS__)
fflush(NULL);
# else
sync();
# endif
#endif
#ifdef VMS
if (STRCMP(p_sws, "fsync") == 0)
{
if (fsync(mfp->mf_fd))
status = FAIL;
}
#endif
#ifdef SYNC_DUP_CLOSE
/*
* Win32 is a bit more work: Duplicate the file handle and close it.
* This should flush the file to disk.
*/
if ((fd = dup(mfp->mf_fd)) >= 0)
close(fd);
#endif
#ifdef AMIGA
# if defined(__AROS__) || defined(__amigaos4__)
if (fsync(mfp->mf_fd) != 0)
status = FAIL;
# else
/*
* Flush() only exists for AmigaDos 2.0.
* For 1.3 it should be done with close() + open(), but then the risk
* is that the open() may fail and lose the file....
*/
# ifdef FEAT_ARP
if (dos2)
# endif
# ifdef SASC
{
struct UFB *fp = chkufb(mfp->mf_fd);
if (fp != NULL)
Flush(fp->ufbfh);
}
# else
# if defined(_DCC) || defined(__GNUC__) || defined(__MORPHOS__)
{
# if defined(__GNUC__) && !defined(__MORPHOS__) && defined(__libnix__)
/* Have function (in libnix at least),
* but ain't got no prototype anywhere. */
extern unsigned long fdtofh(int filedescriptor);
# endif
# if !defined(__libnix__)
fflush(NULL);
# else
BPTR fh = (BPTR)fdtofh(mfp->mf_fd);
if (fh != 0)
Flush(fh);
# endif
}
# else /* assume Manx */
Flush(_devtab[mfp->mf_fd].fd);
# endif
# endif
# endif
#endif /* AMIGA */
}
int main(int argc, char *argv[])
{
int status;
unsigned char *p;
int k;
TSTTITLE("TESTING WRITE MIDIFILE");
TSTSECTION("Buffer write function");
TSTGROUP("Buffer sizing");
status = chk_evt_buf(16);
TST("Room allocated", (status == 0 && (evt_buf_sz - evt_buf_wm) >= 1024));
TSTGROUP("Buffer writing");
p=evt_buf;
b_write8(0xAB);
b_write7(0xCD);
#if 0
b_write16(0xFEDA); /* 1111 1110 1101 1010*/
b_write14(0xFEDA);
b_write32(0xFEEDBAC0);
#endif
TST("Write 8 bits",(p[0] == 0xAB));
TST("Write 7 bits",(p[1] == (0xCD & 0x7F)));
#if 0
TST("Write 16 bits",(p[2] == 0xFE && p[3] == 0xDA)); /*1111 1110 1101 1010*/
TST("Write 14 bits",(p[4] == 0x7D && p[5] == 0x5A)); /*0111 1101 0101 1010*/
TSTONFAIL("Bytes written: %02x %02x",p[4],p[5]);
#endif
TSTGROUP("Raw write track");
h_writetrack = (t_writetrack) mywritetrack1;
h_error = (t_error) mf_null_handler;
status = write_track(1);
TST("write_track() returned unsuccessfully",(status == 309));
TSTONFAIL("return code: %d\n",status);
midi_file = fopen("test_file.mid","wb");
status = write_track(1);
TST("write_track() returned successfully",(status == 0));
fclose(midi_file);
midi_file = fopen("test_file.mid","rb");
TST("File reopened for read",(midi_file != NULL));
if (midi_file) {
/* Now, if everything went well the file should contain:
* MTrk 00 00 00 0C 00 90 3C 64 60 3E 64 83 60 FF 2F 00
*/
TSTWRITE("#");
p = "MTrk\0\0\0\x0C\0\x90\x3C\x64\x60\x3E\x64\x83\x60\xFF\x2F\0";
for (k=0; k<20; k++) {
if (p[k] != fgetc(midi_file)) break;
TSTWRITE(" %02X",p[k]);
}
TSTWRITE("\n");
TST("File written correctly",(k == 20));
fclose(midi_file);
midi_file = NULL;
}
h_writetrack = (t_writetrack) mywritetrack2;
status = mf_write("test_file.mid",0,1,96);
TST("mf_write succeeded",(status == 0));
TSTDONE();
if (midi_file) fclose(midi_file);
return (0);
}
//串口接收数据保存在文件中
//轮询timeout次还没数据读入就退出
//cycletime 读文件时轮询扫描的周期 单位ms
void m_creatFile(char * pathname ,int timeout,u16 cycletime)
{
u8 t=0;
mf_open((u8*)pathname,FA_OPEN_ALWAYS| FA_READ|FA_WRITE);
while(1)
{
/*
---------------------串口状态-------------------------
//串口1中断服务程序
//注意,读取USARTx->SR能避免莫名其妙的错误
//u8 USART_RX_BUF[USART_REC_LEN]; //接收缓冲,最大USART_REC_LEN个字节.
//接收状态
//bit15, 接收完成标志
//bit14, 接收到0x0d
//bit13~0, 接收到的有效字节数目
//u16 USART_RX_STA=0; //接收状态标记
---------------------FATFS函数-------------------------
//void mymemset(void *s,u8 c,u32 count); //设置内存
//void mymemcpy(void *des,void *src,u32 n);//复制内存
//void myfree(u8 memx,void *ptr); //内存释放(外部调用)
//u8 mf_write(u8*dat,u16 len);
*/
//成功读入一行数据
if(USART_RX_STA&0x8000)
{
//串口收到数据长度
int len = USART_RX_STA&0x3fff;
//开辟空间
char * conn_recv = (char*)mymalloc(SRAMIN,len+1);
mymemset(conn_recv,0,len+1); //设置内存
//取串口的数据
mymemcpy(conn_recv, USART_RX_BUF,len);
//显示到屏幕
com_statusBar(conn_recv);
//发送$$开始的字符串表示文件接收完成
if(conn_recv[0]=='$'&&conn_recv[1]=='$')
{
//关闭文件
mf_close();
//释放内存
myfree(SRAMIN,conn_recv);
//状态复位
USART_RX_STA=0;
//break;
return ;
}
//状态复位
USART_RX_STA=0;
//串口接收到的数据保存到本地
mf_write((u8*)conn_recv,len);
//写换行符\n
mf_write((u8*)"\n",1);
//释放内存
myfree(SRAMIN,conn_recv);
t=0;
}
t++;
//超时退出
if(t == timeout){
return;
}
//串口轮询时间与等于200ms
delay_ms(cycletime);
LED0=!LED0;
}
}
