void basicInput::readAsciiString(cString& ret,
uint8 terminate,
const uint numberOfCharacter)
{
/* Read single characters */
uint8 ch = terminate + 1;
uint left = numberOfCharacter;
while (ch != terminate)
{
if (left == 0)
{
TRACE(TRACE_VERY_LOW, "readString: Number of bytes for string exceeded.");
XSTL_THROW(cException, EXCEPTION_READ_ERROR);
}
// Try to read a single character from the stream
uint read = pipeRead((void *)(&ch), sizeof(ch));
if (read == 0)
{
// EOF reached and the NULL terminate couldn't be found.
XSTL_THROW(cException, EXCEPTION_READ_ERROR);
}
left--;
// Remove the terminate character
if (ch != terminate)
ret+= (char)(ch);
}
}
int read(int fd, void* buffer, unsigned int count)
{
bool result = false;
_FD_STRUCT* fds;
DWORD numRead;
fds = fds_from_index(fd);
if (fds == NULL)
{
errno = EBADF;
return -1;
}
initStdHandlesInline();
if (fds->pipe != NULL)
{
numRead = pipeRead(fds->pipe, (unsigned char*)buffer, count);
}
else if (fds->hFile != INVALID_HANDLE_VALUE)
{
if (!ReadFile(fds->hFile, buffer, count, &numRead, NULL))
{
if (GetLastError() == ERROR_HANDLE_EOF)
fds->eof = TRUE;
// else
// fds->error = TRUE;
return 0;
}
}
else
return 0;
return (int)numRead;
}
cString basicInput::readAsciiPascal16String(const uint numberOfCharacter /* = MAX_CHAR */)
{
uint16 length;
// Read the length
streamReadUint16(length);
if (length > numberOfCharacter)
{
// Invalid number of characters
XSTL_THROW(cException, EXCEPTION_READ_ERROR);
}
// Allocate dynamic memory
cBuffer string(length + 1);
// Read all bytes
uint read = pipeRead(string.getBuffer(), length);
if (read != length)
{
// EOF reached!
XSTL_THROW(cException, EXCEPTION_READ_ERROR);
}
string[length] = 0;
return cString((char *)string.getBuffer());
}
bool SchedulerBase::CreateSignalChannel(int *outSigId, SignalCallback callback, void *userdata)
{
LogAssert(IsMainThread());
if (!LogVerify(outSigId) || !LogVerify(callback))
return false;
*outSigId = -1;
// Create a set of pipes
int fdPipe[2];
int flags;
int ret = pipe(fdPipe);
if (ret != 0)
{
gLog.ErrnoError(errno, "Unable to create pipe for signaling");
return false;
}
FileDescriptor pipeRead(fdPipe[0]);
FileDescriptor pipeWrite(fdPipe[1]);
flags = fcntl(pipeRead, F_GETFL);
flags = flags | O_NONBLOCK;
if (-1 == fcntl(pipeRead, F_SETFL, flags))
{
gLog.LogError("Failed to set read pipe to non-blocking.");
return false;
}
flags = fcntl(pipeWrite, F_GETFL);
flags = flags | O_NONBLOCK;
if (-1 == fcntl(pipeWrite, F_SETFL, flags))
{
gLog.LogError("Failed to set write pipe to non-blocking.");
return false;
}
if (!watchSocket(pipeRead))
return false;
schedulerSignalItem item;
item.callback = callback;
item.userdata = userdata;
item.fdWrite = pipeWrite;
item.fdRead = pipeRead;
m_signals[item.fdRead] = item;
pipeWrite.Detach();
pipeRead.Detach();
*outSigId = item.fdWrite;
gLog.Optional(Log::TimerDetail, "Created signal channel from %d to %d .", item.fdWrite, item.fdRead);
return true;
}
void basicInput::streamReadUint8(uint8& byte)
{
uint readed = pipeRead(&byte, sizeof(uint8));
if (readed != sizeof(char))
{
XSTL_THROW(cException, EXCEPTION_READ_ERROR);
}
}
void basicInput::streamReadUint16(uint16& word)
{
uint8 buffer[sizeof(uint16)];
uint readed = pipeRead(&buffer, sizeof(uint16));
if (readed != sizeof(uint16))
{
XSTL_THROW(cException, EXCEPTION_READ_ERROR);
}
word = ((cEndian*)(this))->readUint16(buffer);
}
void basicInput::readAllStream(cBuffer& rawData)
{
if (canLength && canGetPointer)
{
uint left = length() - getPointer();
pipeRead(rawData, left);
} else
{
// Changing the page size into the default reading size.
uint savePageSize = rawData.getPageSize();
rawData.setPageSize(getPipeReadBestRequest());
uint oldBufferSize = rawData.getSize();
rawData.changeSize(oldBufferSize + getPipeReadBestRequest(), false);
uint readed = 0;
uint total = oldBufferSize;
uint8* buffer = rawData.getBuffer() + total;
// Reading loop
do
{
// Read a chunk
total += (readed = pipeRead(buffer, getPipeReadBestRequest()));
// Save space for the next reading operation
if (readed == getPipeReadBestRequest())
{
rawData.changeSize(total + getPipeReadBestRequest());
buffer = rawData.getBuffer() + total;
} else
{
// Restore the page size
rawData.setPageSize(savePageSize);
// Chop free space
rawData.changeSize(total);
}
} while (readed == getPipeReadBestRequest()); // Until there isn't error
}
}
MED_RET_T evt_getFullStatus(int num_evt_pipe, struct evt_t * evt)
{
//printk("evt chk: handler=%d evt @ %x\n",num_evt_pipe,evt);
if(num_evt_pipe >= 0 && num_evt_pipe < NB_EVT_PIPES && evt != NULL)
{
evt->evt=0;
evt->evt_class=0;
evt->data=0;
if(evt_pipe_tab[num_evt_pipe].used!=1)
return -MED_ENBUSY;
pipeRead(&(evt_pipe_tab[num_evt_pipe].evt_pipe), evt, sizeof(struct evt_t));
}
else
return -MED_EINVAL;
return MED_OK;
}
cString basicInput::readFixedSizeString(uint numberOfCharacters, int unicodeSize)
{
cBuffer buffer((numberOfCharacters + 1) * unicodeSize);
uint8* buf = buffer.getBuffer();
pipeRead(buf, numberOfCharacters * unicodeSize);
if (unicodeSize > 1)
{
buf[numberOfCharacters * unicodeSize] = 0;
cBuffer ret(sizeof(character) * (numberOfCharacters + 1));
character* retBuf = (character*)ret.getBuffer();
cChar::covert2string(retBuf, numberOfCharacters+1, buf, unicodeSize);
return cString(retBuf);
} else
{
buf[numberOfCharacters] = 0;
return cString((char*)buf);
}
}
uint basicInput::pipeRead(cBuffer& buffer, const uint length)
{
uint oldSize = buffer.getSize(); // Old size of the buffer
uint readed = 0; // The readed bytes.
/* Prepare the output buffer */
buffer.changeSize(oldSize + length);
/* Read the data */
readed = pipeRead((buffer.getBuffer() + oldSize), length);
/* Chope the data */
if (readed < length)
{
buffer.changeSize(oldSize + readed);
}
return readed;
}
void basicInput::readUnicodeString(cString& ret,
unichar terminate,
const uint numberOfCharacter)
{
/* Read single characters */
unichar ch = terminate + 1;
uint left = numberOfCharacter;
while (ch != terminate)
{
if (left == 0)
{
TRACE(TRACE_VERY_LOW, "readString: Number of bytes for string exceeded.");
XSTL_THROW(cException, EXCEPTION_READ_ERROR);
}
// Try to read a single character from the stream
uint read = pipeRead((void *)(&ch), sizeof(ch));
if (read == 0)
{
// EOF reached and the NULL terminate couldn't be found.
XSTL_THROW(cException, EXCEPTION_READ_ERROR);
}
left--;
// Remove the terminate character
if (ch != terminate)
{
#ifndef XSTL_UNICODE
ret+= cChar::covert2Ascii(ch);
#else
ret+= ch;
#endif
}
}
}
cString basicInput::readAsciiPascal8String(const uint numberOfCharacter /* = MAX_CHAR */)
{
uint8 length;
uint8 string[256];
// Read the length
streamReadUint8(length);
if (length > numberOfCharacter)
{
// Invalid number of characters
XSTL_THROW(cException, EXCEPTION_READ_ERROR);
}
// Read the string bytes
uint read = pipeRead(string, length);
if (read != length)
{
// EOF reached!
XSTL_THROW(cException, EXCEPTION_READ_ERROR);
}
string[length] = 0;
return cString((char *)string);
}
void basicInput::pipeReadNotEos(cBuffer& buffer, const uint length)
{
CHECK(pipeRead(buffer, length) == length);
}
