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What variable type should be used for lpBuffer of C++ ReadFile and WriteFile functions to communicate between a Windows XP based PC and a micro-controller based system? The PC has WinForm application in VS2010 C++/CLI. The micro-controller firmware is ANSI C.

My PC is supposed to transmit command characters (say 'S', 'C' etc) followed by command termination character 0xd (hex for decimal 13). The micro-controller based system would respond with 5 to 10 bytes that would be mix of ASCII characters and hex numbers e.g. 'V' followed by 0x41 0x72 etc.

PC transmits and micro-controller receives:

  1. TxMessage, PP1 and pTx declared as char and keeping nNumberOfBytesToWrite as 2, makes the micro-controller receive 0x53 for 'S' followed by 0xC3 instead of 0xd.

  2. TxMessage, PP1 and pTx declared as wchar_t and keeping nNumberOfBytesToWrite as 2, makes the micro-controller receive 0x53 for 'S' only.

  3. TxMessage, PP1 and pTx declared as wchar_t and keeping nNumberOfBytesToWrite as 4, makes the micro-controller receive 0x53 for 'S' followed by 0xd correctly.

The third scheme of transmit and receive above meets my expected behavior of a solution. But the confusion is here: Although the PC might be transmitting 4 bytes (for two wchar types), the micro-controller receives 2 bytes 0x53 for 'S', correctly followed by 0xD.

Micro-controller transmits and PC receives:

Assuming that wchar_t is the right choice for lpBuffer, what should be my nNumberOfBytesToRead for receiving 10 bytes from the micro-controller? ReadFile would expect 20 bytes by virtue of wchar_t, whereas the micro-controller would transmit 10 bytes only.

Amazingly, irrespective of declaring (RxMessage, PP2 and pRx) as wchar_t, char or unsigned char, ReadFile receives 10 bytes from the micro-controller (meets my expected behavior of a solution). But the issue is that transmitting 'A' 10 times from the micro-controller, ReadFile on the PC's end receives junk like 'S', 0x0, 0xd, 0x54, 0x29.

/// Required designer variable.
HANDLE hCommPort;
BOOL fSuccess;
array<wchar_t> ^ TxMessage;
array<unsigned char> ^ RxMessage;

TxMessage = gcnew array<wchar_t> (12);
RxMessage = gcnew array<unsigned char> (12);

TxMessage[0]='S';//target cmd
TxMessage[1]=0xd;//cmd termination character
DWORD dwhandled;
 pin_ptr<wchar_t> pp1 = &TxMessage[0];
 wchar_t *pTx = pp1;
 fSuccess = WriteFile(hCommPort, pTx, 4, &dwhandled, NULL);


 pin_ptr<unsigned char> pp2 = &RxMessage[0];
 unsigned char *pRx = pp2;
 fSuccess = ReadFile(hCommPort, pRx, 10, &dwhandled, NULL);

}//if IsOpen
 this->toolStripStatusLabel4->Text="Port Not Opened";}
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migrated from Aug 18 '13 at 9:41

This question came from our site for computer enthusiasts and power users.

ReadFile/WriteFile do not care about C++ types, they operate in terms of bytes read/written. ReadFile reads specified number of bytes (or less if there is less bytes to read) from file/device, and puts them into memory pointed by lpBuffer. WriteFile writes specified number of bytes to file/device from memory pointed to by lpcBuffer. The memory buffer for these functions is simply a region of allocated memory that has the size at least as many bytes as you tell those functions in the third parameter.

wchat_t is a multibyte type. It's size can be bigger than one byte. Consequently, your TxMessage[0]='S'; TxMessage[1]=0xd; can be actually filling not two bytes in memory, but, say, 4 bytes. For example, it can be x0053 , x000D in wchar_t representation. From the point of view of WriteFile it does not care how and what you put into that memory. It will read raw memory and will write to device. So, if your device expects x530D, it might not be getting it, but x0053.

Overall, think about bytes. If you need to write 4 bytes x0A0B0C0D to your device, it does not matter HOW you allocated buffer for this value. It can be 4-byte unsigned int = x0A0B0C0D, it can be char[ 4 ] = {x0A, x0B, x0C, x0D}, it can be int short [ 2 ]= {x0A0B, x0C0D}, it can be ANY C++ type, including custom class. But the first 4 bytes of memory pointed by the memory pointer passed to WriteFile should be x0A0B0C0D.

Similarly, ReadFile will read number of bytes you specify. If your device sends you, say, 2 bytes, ReadFile will write 2 bytes it gets into memory pointed by the pointer you pass to it (and it's your responsibility to ensure it has enough bytes allocated). Again, it does not care how you allocated it as long as there are 2 bytes allocated. After that, again, you can look at these two bytes as you want - it can be char[ 2 ], can be int short etc.

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Fully agree with you @Petr, but the fact remains, Amazingly though; inspite of TxMessage = gcnew array<wchar_t> { 'S', '\r' }, and nNumberOfBytesToWrite as 4, micro-controller receives TWO bytes only that too 0x53 followed by 0xD. Making nNumberOfBytesToWrite as 2, micro-controller receives ONE byte only that too 0x53. – Rich Aug 21 '13 at 6:50
@Rich I would start by examining first 4 bytes of TxMessage. Could it be that sizeof(wchar_t)==2 indeed, you are sending x0053000D and controller protocol just ignores x00's? Because then it will also explain that when you send 2 bytes of TxMessage which are x0053, controller gets x53 ignoring x00. What if you make char TxMessage[ 2 ] = {x53, x0D} and send 2 bytes? – Petr 'lapk' Budnik Aug 21 '13 at 7:48
Just read your comment to Hans's answer. It seems to me you should verify the protocol used by the controller. Can you add the description from controller manual to the OP? I have a suspicion controller actually expects array of two-bytes values, not array of bytes. Can that be the case? – Petr 'lapk' Budnik Aug 21 '13 at 7:59
WinXP app and Controller firmware being debugged simultaneously with BreakPoints in respective IDEs. Controller firmware receives bytes in Rx buffer on Rx-Interrupts, irrespective of byte-values. The firmware breaks, when either 0xd is received or timeout of 8 secs. When TxMessage type is wchar_t, Firmware breaks immediately on receipt of 2nd byte as 0xd. Post break, Rx buffer is observed to be holding TWO bytes 0x53 and 0xD. When TxMessage is Non-wchar, firmware loop breaks only after timeout of 8 secs and Post break, Rx buffer is observed to be holding TWO bytes 0x53 followed by 0x43 – Rich Aug 21 '13 at 8:12
Solved, working perfect now, pin-ptr to FT_Handle – Rich Aug 28 '13 at 16:18

Using bytes is the natural match, serial ports are pretty fundamentally byte oriented devices. You could make your transmitting code look like this:

bool SendCommand(HANDLE hCommPort) {
    auto TxMessage = gcnew array<Byte> { 'S', '\r' };
    pin_ptr<Byte> pbytes = &TxMessage[0];
    DWORD bytesSent = 0;
    BOOL fSuccess = WriteFile(hCommPort, pbytes, TxMessage->Length, 
                              &bytesSent, NULL);
    return fSuccess && bytesSent == TxMessage->Length);

Your receiving code needs to do more work, the number of bytes you get back from ReadFile() is unpredictable. A protocol is required to indicate when you should stop reading. A fixed length response is common. Or a special last character is very common. That could look like this:

bool ReceiveResponse(HANDLE hCommPort, array<Byte>^ RxMessage, int% RxCount) {
    for (; RxCount < RxMessage->Length; ) {
        DWORD bytesReceived = 0;
        pin_ptr<Byte> pbytes = &RxMessage[0];
        BOOL fSuccess = ReadFile(hCommPort, pbytes, RxMessage->Length - RxCount, 
                                 &bytesReceived, NULL);
        if (!fSuccess) return false;
        int rxStart = RxCount;
        RxCount += bytesReceived;
        for (int ix = rxStart; ix < RxCount; ++ix) {
            if (RxMessage[ix] == '\r') return true;
    return true;

Don't overlook the .NET System::IO::Ports::SerialPort class. It has built-in Encoding support which makes it easier to work with characters vs bytes. Your ReceiveResponse() method could collapse to a simple ReadLine() call with the NewLine property set correctly.

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Appreciate your kind help. Unfortunetly, replacing wchar_t with Byte in WriteFile-part-of-code does NOT alter the run-time behavior of WriteFile. Still, micro-controller receives the two characters correctly as 0x53 followed by 0xD, only when TxMessage is declared as wchar_t. Non-wchar types (char, unsigned char, Byte etc.) make the micro-controller receives the First byte correctly as 0x53 but 2nd byte wrong as 0x43 or 0xC3. The second character remains consistent as 0x43 or 0xC3 depending on choice of non-wchar_t to TxMessage array. Pls refer my answer to Petr below too – Rich Aug 21 '13 at 6:33
Dear Hans Any advice from your end! Hope you are following the discussion with Petr above. – Rich Aug 22 '13 at 14:55
up vote 0 down vote accepted

Apologies for not able to respond earlier than this. Infact the problem was identified and corrected after posting of my last comment. It related to 9bit protocol being forced by micro-controller. Original micro-firmware is 9bit protocol to address one of many slaves. For development-testing, i had temporary modification to 8bit protocol. Unfortunately, modifications missed the UART mode register that remained as 9bit mode. With boxed/biased mind i kept debugging

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