问题:
在做Windows应用与HID设备通讯时,异步读取发现丢数据的问题,发现驱动层接收到的数据并不是马上存入接收缓存中等待应用去读取,而是丢失不定长的数据后再存入缓存中。具体操作如下:
1、打开文件是以异步读取方式打开:
hd = CreateFile(HidFunctionClassData->DevicePath, GENERIC_READ | GENERIC_WRITE,
FILE_SHARE_READ | FILE_SHARE_WRITE, NULL, OPEN_EXISTING, FILE_FLAG_OVERLAPPED, NULL);2、打开后设置接收缓存大小,并读出设置值确认设置成功:
HidD_SetNumInputBuffers(hd, 128);
HidD_GetNumInputBuffers(hd, &inputBufSize);3、用ReadFile读取数据:
ReadFile(handle, rBuffer, Capabilities.InputReportByteLength, &dwRet, &rOverLap);
WaitForSingleObject(rOverLap.hEvent, 100) ;4、启动一个专门接收数据的线程,轮询读取;具体现象:
下位机每隔15ms上传一帧数据,上位机每隔20ms接收一次,发现刚开始每接收一帧就会丢失一帧,接收了不定长的数据后才不丢数据,直到接收缓存满;分析:
如果驱动层接收的数据都会进入接收缓存,那么在接收缓存未满之前是不会丢失数据的,所以现在怀疑是不是刚开始的数据没有进入缓存,或者已经被接收了; 读取函数如下:
int HIDDeviceRead(HANDLE handle, LPVOID lpBuffer, DWORD dwSize)
{
if (handle == NULL || handle == INVALID_HANDLE_VALUE)
return 0;
if (rOverLap.hEvent == NULL || rOverLap.hEvent == INVALID_HANDLE_VALUE)
return 0;
if (lpBuffer == NULL)
return 0;
BYTE rBuffer[512] = { 0 };
DWORD dwRet;
BOOL bRet = 0;
DWORD err;
char log[128];
rBuffer[0] = 0x00;
//调用成功,返回非0,调用不成功, 返回为0
if (!ReadFile(handle, rBuffer, Capabilities.InputReportByteLength, &dwRet, &rOverLap))
{
if ((err = GetLastError()) != ERROR_IO_PENDING)
{
sprintf(log, "Read data err:%d.\r\n", err);
_cprintf(log);
return bRet;
}
if (::WaitForSingleObject(rOverLap.hEvent, 100) != WAIT_TIMEOUT)
{
//::GetOverlappedResult(handle, &rOverLap, &dwRet, TRUE);
dwRet = rOverLap.InternalHigh;
bRet = min(dwRet, dwSize);
memcpy(lpBuffer, &rBuffer[1], bRet);
}
}
else
{
bRet = min(dwRet, dwSize);
memcpy(lpBuffer, &rBuffer[1], bRet);
}
ResetEvent(wOverLap.hEvent);
return bRet;
}
在做Windows应用与HID设备通讯时,异步读取发现丢数据的问题,发现驱动层接收到的数据并不是马上存入接收缓存中等待应用去读取,而是丢失不定长的数据后再存入缓存中。具体操作如下:
1、打开文件是以异步读取方式打开:
hd = CreateFile(HidFunctionClassData->DevicePath, GENERIC_READ | GENERIC_WRITE,
FILE_SHARE_READ | FILE_SHARE_WRITE, NULL, OPEN_EXISTING, FILE_FLAG_OVERLAPPED, NULL);2、打开后设置接收缓存大小,并读出设置值确认设置成功:
HidD_SetNumInputBuffers(hd, 128);
HidD_GetNumInputBuffers(hd, &inputBufSize);3、用ReadFile读取数据:
ReadFile(handle, rBuffer, Capabilities.InputReportByteLength, &dwRet, &rOverLap);
WaitForSingleObject(rOverLap.hEvent, 100) ;4、启动一个专门接收数据的线程,轮询读取;具体现象:
下位机每隔15ms上传一帧数据,上位机每隔20ms接收一次,发现刚开始每接收一帧就会丢失一帧,接收了不定长的数据后才不丢数据,直到接收缓存满;分析:
如果驱动层接收的数据都会进入接收缓存,那么在接收缓存未满之前是不会丢失数据的,所以现在怀疑是不是刚开始的数据没有进入缓存,或者已经被接收了; 读取函数如下:
int HIDDeviceRead(HANDLE handle, LPVOID lpBuffer, DWORD dwSize)
{
if (handle == NULL || handle == INVALID_HANDLE_VALUE)
return 0;
if (rOverLap.hEvent == NULL || rOverLap.hEvent == INVALID_HANDLE_VALUE)
return 0;
if (lpBuffer == NULL)
return 0;
BYTE rBuffer[512] = { 0 };
DWORD dwRet;
BOOL bRet = 0;
DWORD err;
char log[128];
rBuffer[0] = 0x00;
//调用成功,返回非0,调用不成功, 返回为0
if (!ReadFile(handle, rBuffer, Capabilities.InputReportByteLength, &dwRet, &rOverLap))
{
if ((err = GetLastError()) != ERROR_IO_PENDING)
{
sprintf(log, "Read data err:%d.\r\n", err);
_cprintf(log);
return bRet;
}
if (::WaitForSingleObject(rOverLap.hEvent, 100) != WAIT_TIMEOUT)
{
//::GetOverlappedResult(handle, &rOverLap, &dwRet, TRUE);
dwRet = rOverLap.InternalHigh;
bRet = min(dwRet, dwSize);
memcpy(lpBuffer, &rBuffer[1], bRet);
}
}
else
{
bRet = min(dwRet, dwSize);
memcpy(lpBuffer, &rBuffer[1], bRet);
}
ResetEvent(wOverLap.hEvent);
return bRet;
}
开一个线程以阻塞式读数据,如果没数据ReadFile就会阻塞在那里,这样保证只要有数据就能收到。
//a函数中需要将循环传进来的buffer,组成240字节(也是固定的)的新buffer进行处理,
//在处理的时候每次从新buffer中取两个字节打印
#ifdef _MSC_VER
#pragma warning(disable:4996)
#endif
#include <stdio.h>
#include <stdlib.h>
#include <string.h>
#ifdef _MSC_VER
#include <windows.h>
#include <process.h>
#include <io.h>
#define MYVOID void
#define vsnprintf _vsnprintf
#else
#include <unistd.h>
#include <sys/time.h>
#include <pthread.h>
#define CRITICAL_SECTION pthread_mutex_t
#define MYVOID void *
#endif
//Log{
#define MAXLOGSIZE 20000000
#define MAXLINSIZE 16000
#include <time.h>
#include <sys/timeb.h>
#include <stdarg.h>
char logfilename1[]="MyLog1.log";
char logfilename2[]="MyLog2.log";
static char logstr[MAXLINSIZE+1];
char datestr[16];
char timestr[16];
char mss[4];
CRITICAL_SECTION cs_log;
FILE *flog;
#ifdef _MSC_VER
void Lock(CRITICAL_SECTION *l) {
EnterCriticalSection(l);
}
void Unlock(CRITICAL_SECTION *l) {
LeaveCriticalSection(l);
}
void sleep_ms(int ms) {
Sleep(ms);
}
#else
void Lock(CRITICAL_SECTION *l) {
pthread_mutex_lock(l);
}
void Unlock(CRITICAL_SECTION *l) {
pthread_mutex_unlock(l);
}
void sleep_ms(int ms) {
usleep(ms*1000);
}
#endif
void LogV(const char *pszFmt,va_list argp) {
struct tm *now;
struct timeb tb; if (NULL==pszFmt||0==pszFmt[0]) return;
vsnprintf(logstr,MAXLINSIZE,pszFmt,argp);
ftime(&tb);
now=localtime(&tb.time);
sprintf(datestr,"%04d-%02d-%02d",now->tm_year+1900,now->tm_mon+1,now->tm_mday);
sprintf(timestr,"%02d:%02d:%02d",now->tm_hour ,now->tm_min ,now->tm_sec );
sprintf(mss,"%03d",tb.millitm);
printf("%s %s.%s %s",datestr,timestr,mss,logstr);
flog=fopen(logfilename1,"a");
if (NULL!=flog) {
fprintf(flog,"%s %s.%s %s",datestr,timestr,mss,logstr);
if (ftell(flog)>MAXLOGSIZE) {
fclose(flog);
if (rename(logfilename1,logfilename2)) {
remove(logfilename2);
rename(logfilename1,logfilename2);
}
} else {
fclose(flog);
}
}
}
void Log(const char *pszFmt,...) {
va_list argp; Lock(&cs_log);
va_start(argp,pszFmt);
LogV(pszFmt,argp);
va_end(argp);
Unlock(&cs_log);
}
//Log}
#define ASIZE 200
#define BSIZE 240
#define CSIZE 2
char Abuf[ASIZE];
char Cbuf[CSIZE];
CRITICAL_SECTION cs_HEX;
CRITICAL_SECTION cs_BBB;
struct FIFO_BUFFER {
int head;
int tail;
int size;
char data[BSIZE];
} BBB;
int No_Loop=0;
void HexDump(int cn,char *buf,int len) {
int i,j,k;
char binstr[80]; Lock(&cs_HEX);
for (i=0;i<len;i++) {
if (0==(i%16)) {
sprintf(binstr,"%03d %04x -",cn,i);
sprintf(binstr,"%s %02x",binstr,(unsigned char)buf[i]);
} else if (15==(i%16)) {
sprintf(binstr,"%s %02x",binstr,(unsigned char)buf[i]);
sprintf(binstr,"%s ",binstr);
for (j=i-15;j<=i;j++) {
sprintf(binstr,"%s%c",binstr,('!'<buf[j]&&buf[j]<='~')?buf[j]:'.');
}
Log("%s\n",binstr);
} else {
sprintf(binstr,"%s %02x",binstr,(unsigned char)buf[i]);
}
}
if (0!=(i%16)) {
k=16-(i%16);
for (j=0;j<k;j++) {
sprintf(binstr,"%s ",binstr);
}
sprintf(binstr,"%s ",binstr);
k=16-k;
for (j=i-k;j<i;j++) {
sprintf(binstr,"%s%c",binstr,('!'<buf[j]&&buf[j]<='~')?buf[j]:'.');
}
Log("%s\n",binstr);
}
Unlock(&cs_HEX);
}
int GetFromRBuf(int cn,CRITICAL_SECTION *cs,struct FIFO_BUFFER *fbuf,char *buf,int len) {
int lent,len1,len2; lent=0;
Lock(cs);
if (fbuf->size>=len) {
lent=len;
if (fbuf->head+lent>BSIZE) {
len1=BSIZE-fbuf->head;
memcpy(buf ,fbuf->data+fbuf->head,len1);
len2=lent-len1;
memcpy(buf+len1,fbuf->data ,len2);
fbuf->head=len2;
} else {
memcpy(buf ,fbuf->data+fbuf->head,lent);
fbuf->head+=lent;
}
fbuf->size-=lent;
}
Unlock(cs);
return lent;
}
MYVOID thdB(void *pcn) {
char *recv_buf;
int recv_nbytes;
int cn;
int wc;
int pb; cn=(int)pcn;
Log("%03d thdB thread begin...\n",cn);
while (1) {
sleep_ms(10);
recv_buf=(char *)Cbuf;
recv_nbytes=CSIZE;
wc=0;
while (1) {
pb=GetFromRBuf(cn,&cs_BBB,&BBB,recv_buf,recv_nbytes);
if (pb) {
Log("%03d recv %d bytes\n",cn,pb);
HexDump(cn,recv_buf,pb);
sleep_ms(1);
} else {
sleep_ms(1000);
}
if (No_Loop) break;//
wc++;
if (wc>3600) Log("%03d %d==wc>3600!\n",cn,wc);
}
if (No_Loop) break;//
}
#ifndef _MSC_VER
pthread_exit(NULL);
#endif
}
int PutToRBuf(int cn,CRITICAL_SECTION *cs,struct FIFO_BUFFER *fbuf,char *buf,int len) {
int lent,len1,len2; Lock(cs);
lent=len;
if (fbuf->size+lent>BSIZE) {
lent=BSIZE-fbuf->size;
}
if (fbuf->tail+lent>BSIZE) {
len1=BSIZE-fbuf->tail;
memcpy(fbuf->data+fbuf->tail,buf ,len1);
len2=lent-len1;
memcpy(fbuf->data ,buf+len1,len2);
fbuf->tail=len2;
} else {
memcpy(fbuf->data+fbuf->tail,buf ,lent);
fbuf->tail+=lent;
}
fbuf->size+=lent;
Unlock(cs);
return lent;
}
MYVOID thdA(void *pcn) {
char *send_buf;
int send_nbytes;
int cn;
int wc;
int a;
int pa; cn=(int)pcn;
Log("%03d thdA thread begin...\n",cn);
a=0;
while (1) {
sleep_ms(100);
memset(Abuf,a,ASIZE);
a=(a+1)%256;
if (16==a) {No_Loop=1;break;}//去掉这句可以让程序一直循环直到按Ctrl+C或Ctrl+Break或当前目录下存在文件No_Loop
send_buf=(char *)Abuf;
send_nbytes=ASIZE;
Log("%03d sending %d bytes\n",cn,send_nbytes);
HexDump(cn,send_buf,send_nbytes);
wc=0;
while (1) {
pa=PutToRBuf(cn,&cs_BBB,&BBB,send_buf,send_nbytes);
Log("%03d sent %d bytes\n",cn,pa);
HexDump(cn,send_buf,pa);
send_buf+=pa;
send_nbytes-=pa;
if (send_nbytes<=0) break;//
sleep_ms(1000);
if (No_Loop) break;//
wc++;
if (wc>3600) Log("%03d %d==wc>3600!\n",cn,wc);
}
if (No_Loop) break;//
}
#ifndef _MSC_VER
pthread_exit(NULL);
#endif
}
int main() {
#ifdef _MSC_VER
InitializeCriticalSection(&cs_log);
InitializeCriticalSection(&cs_HEX);
InitializeCriticalSection(&cs_BBB);
#else
pthread_t threads[2];
int threadsN;
int rc;
pthread_mutex_init(&cs_log,NULL);
pthread_mutex_init(&cs_HEX,NULL);
pthread_mutex_init(&cs_BBB,NULL);
#endif
Log("Start===========================================================\n"); BBB.head=0;
BBB.tail=0;
BBB.size=0;#ifdef _MSC_VER
_beginthread((void(__cdecl *)(void *))thdA,0,(void *)1);
_beginthread((void(__cdecl *)(void *))thdB,0,(void *)2);
#else
threadsN=0;
rc=pthread_create(&(threads[threadsN++]),NULL,thdA,(void *)1);if (rc) Log("%d=pthread_create %d error!\n",rc,threadsN-1);
rc=pthread_create(&(threads[threadsN++]),NULL,thdB,(void *)2);if (rc) Log("%d=pthread_create %d error!\n",rc,threadsN-1);
#endif if (!access("No_Loop",0)) {
remove("No_Loop");
if (!access("No_Loop",0)) {
No_Loop=1;
}
}
while (1) {
sleep_ms(1000);
if (No_Loop) break;//
if (!access("No_Loop",0)) {
No_Loop=1;
}
}
sleep_ms(3000);
Log("End=============================================================\n");
#ifdef _MSC_VER
DeleteCriticalSection(&cs_BBB);
DeleteCriticalSection(&cs_HEX);
DeleteCriticalSection(&cs_log);
#else
pthread_mutex_destroy(&cs_BBB);
pthread_mutex_destroy(&cs_HEX);
pthread_mutex_destroy(&cs_log);
#endif
return 0;
}任何收发两端速度不一致的通讯,都需要在它们之间使用一个足够大的FIFO缓冲区。
对任何FIFO缓冲区的使用,都需要仔细考虑接收端接收时超时无数据和发送端发送时FIFO缓冲区已满这两种情况下该如何做。
这些概念都在这段经典代码中有所体现。
这段经典代码还包括以下必须考虑的因素:
◆跨Windows和Linux平台
◆多线程锁
◆多线程日志
◆日志文件占用的磁盘空间可控
◆日志中的时间包括毫秒
◆传输的数据对应的每个字节到底是几
◆如何退出多线程程序
◆……