windows-nt/Source/XPSP1/NT/net/rras/common/rtutils/client.c

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//============================================================================
// Copyright (c) 1995, Microsoft Corporation
//
// File: client.c
//
// History:
// Abolade Gbadegesin July-25-1995 Created
//
// Client struct routines and I/O routines for tracing dll
//============================================================================
#include <nt.h>
#include <ntrtl.h>
#include <nturtl.h>
#include <windows.h>
#include <stdlib.h>
#include <rtutils.h>
#include "trace.h"
//
// assumes server is locked for writing
//
DWORD
TraceCreateClient(
LPTRACE_CLIENT *lplpclient
) {
DWORD dwErr;
LPTRACE_CLIENT lpclient;
lpclient = HeapAlloc(GetProcessHeap(), 0, sizeof(TRACE_CLIENT));
if (lpclient == NULL) {
return ERROR_NOT_ENOUGH_MEMORY;
}
//
// initialize fields in the client structure
//
lpclient->TC_ClientID = MAX_CLIENT_COUNT;
lpclient->TC_Flags = 0;
lpclient->TC_File = NULL;
lpclient->TC_Console = NULL;
lpclient->TC_ConfigKey = NULL;
lpclient->TC_ConfigEvent = NULL;
lpclient->TC_MaxFileSize = DEF_MAXFILESIZE;
ZeroMemory(lpclient->TC_ClientNameA, MAX_CLIENTNAME_LENGTH * sizeof(CHAR));
ZeroMemory(lpclient->TC_ClientNameW, MAX_CLIENTNAME_LENGTH * sizeof(WCHAR));
lstrcpy(lpclient->TC_FileDir, DEF_FILEDIRECTORY);
#ifdef UNICODE
wcstombs(
lpclient->TC_FileDirA, lpclient->TC_FileDirW,
lstrlenW(lpclient->TC_FileDirW) + 1
);
#else
mbstowcs(
lpclient->TC_FileDirW, lpclient->TC_FileDirA,
lstrlenA(lpclient->TC_FileDirA) + 1
);
#endif
__try {
TRACE_STARTUP_LOCKING(lpclient);
dwErr = NO_ERROR;
}
__except(EXCEPTION_EXECUTE_HANDLER) {
dwErr = GetExceptionCode();
HeapFree(GetProcessHeap(), 0, lpclient);
lpclient = NULL;
}
InterlockedExchangePointer(lplpclient, lpclient);
return dwErr;
}
//
// assumes server is locked for writing and client is locked for writing
//
DWORD
TraceDeleteClient(
LPTRACE_SERVER lpserver,
LPTRACE_CLIENT *lplpclient
) {
LPTRACE_CLIENT lpclient;
if (lplpclient == NULL || *lplpclient == NULL) {
return ERROR_INVALID_PARAMETER;
}
lpclient = *lplpclient;
InterlockedExchangePointer(lplpclient, NULL);
InterlockedExchange(lpserver->TS_FlagsCache + lpclient->TC_ClientID, 0);
TRACE_CLEANUP_LOCKING(lpclient);
//
// closing this key will cause the event to be signalled
// however, we hold the lock on the table so the server thread
// will be blocked until the cleanup completes
//
if (lpclient->TC_ConfigKey != NULL) {
RegCloseKey(lpclient->TC_ConfigKey);
}
if (lpclient->TC_ConfigEvent != NULL) {
CloseHandle(lpclient->TC_ConfigEvent);
}
if (TRACE_CLIENT_USES_CONSOLE(lpclient)) {
TraceCloseClientConsole(lpserver, lpclient);
}
if (TRACE_CLIENT_USES_FILE(lpclient)) {
TraceCloseClientFile(lpclient);
}
HeapFree(GetProcessHeap(), 0, lpclient);
return 0;
}
//
// assumes server is locked for reading or for writing
//
LPTRACE_CLIENT
TraceFindClient(
LPTRACE_SERVER lpserver,
LPCTSTR lpszClient
) {
DWORD dwClient;
LPTRACE_CLIENT *lplpc, *lplpcstart, *lplpcend;
lplpcstart = lpserver->TS_ClientTable;
lplpcend = lplpcstart + MAX_CLIENT_COUNT;
for (lplpc = lplpcstart; lplpc < lplpcend; lplpc++) {
if (*lplpc != NULL &&
lstrcmp((*lplpc)->TC_ClientName, lpszClient) == 0) {
break;
}
}
return (lplpc < lplpcend) ? *lplpc : NULL;
}
//
// assumes that the server is locked for writing,
// and that the client is locked for writing
// also assumes the client is not already a console client
//
DWORD TraceOpenClientConsole(LPTRACE_SERVER lpserver,
LPTRACE_CLIENT lpclient) {
DWORD dwErr;
COORD screen;
HANDLE hConsole;
//
// if all console tracing is disabled, do nothing
//
if ((lpserver->TS_Flags & TRACEFLAGS_USECONSOLE) == 0) {
return 0;
}
//
// create the console if it isn't already created
//
if (lpserver->TS_Console == NULL) {
COORD screen;
//
// allocate a console and set the buffer size
//
AllocConsole();
lpserver->TS_Console = GetStdHandle(STD_INPUT_HANDLE);
if (lpserver->TS_Console == INVALID_HANDLE_VALUE )
return GetLastError();
}
//
// allocate a console for this client
//
hConsole = CreateConsoleScreenBuffer(
GENERIC_READ | GENERIC_WRITE, 0, NULL,
CONSOLE_TEXTMODE_BUFFER, NULL
);
if (hConsole == INVALID_HANDLE_VALUE) { return GetLastError(); }
//
// set the buffer to the standard size
// and save the console buffer handle
//
screen.X = DEF_SCREENBUF_WIDTH;
screen.Y = DEF_SCREENBUF_HEIGHT;
SetConsoleScreenBufferSize(hConsole, screen);
lpclient->TC_Console = hConsole;
//
// see if there was a previous console client;
// if not, set this new one's screen buffer to be
// the active screen buffer
//
if (lpserver->TS_ConsoleOwner == MAX_CLIENT_COUNT) {
TraceUpdateConsoleOwner(lpserver, 1);
}
return 0;
}
//
// assumes that the server is locked for writing,
// and that the client is locked for writing
// also assumes the client is already a console client
//
DWORD
TraceCloseClientConsole(
LPTRACE_SERVER lpserver,
LPTRACE_CLIENT lpclient
) {
HANDLE hConsole;
//
// if all console tracing is disabled, do nothing
//
if ((lpserver->TS_Flags & TRACEFLAGS_USECONSOLE) == 0) {
return 0;
}
//
// close the client's screen buffer and associated handles
//
if (lpclient->TC_Console != NULL) {
CloseHandle(lpclient->TC_Console);
lpclient->TC_Console = NULL;
}
//
// if the client owned the screen, find another owner
//
if (lpserver->TS_ConsoleOwner == lpclient->TC_ClientID) {
TraceUpdateConsoleOwner(lpserver, 1);
}
//
// if no owner was found, free the server's console
//
if (lpserver->TS_ConsoleOwner == MAX_CLIENT_COUNT ||
lpserver->TS_ConsoleOwner == lpclient->TC_ClientID) {
lpserver->TS_ConsoleOwner = MAX_CLIENT_COUNT;
CloseHandle(lpserver->TS_Console);
lpserver->TS_Console = NULL;
FreeConsole();
}
return 0;
}
//
// assumes that the server is locked for reading or writing
// and that the client is locked for writing
//
DWORD
TraceCreateClientFile(
LPTRACE_CLIENT lpclient
) {
DWORD dwErr;
HANDLE hFile;
LPOVERLAPPED lpovl;
TCHAR szFilename[MAX_PATH];
//
// create the directory in case it doesn't exist
//
CreateDirectory(lpclient->TC_FileDir, NULL);
//
// figure out the file name
//
lstrcpy(szFilename, lpclient->TC_FileDir);
lstrcat(szFilename, STR_DIRSEP);
lstrcat(szFilename, lpclient->TC_ClientName);
lstrcat(szFilename, STR_LOGEXT);
//
// open the file, disabling write sharing
//
hFile = CreateFile(
szFilename, GENERIC_READ | GENERIC_WRITE, FILE_SHARE_READ,
NULL, OPEN_ALWAYS, FILE_ATTRIBUTE_NORMAL, NULL
);
if (hFile == INVALID_HANDLE_VALUE) {
return GetLastError();
}
SetFilePointer(hFile, 0, NULL, FILE_END);
lpclient->TC_File = hFile;
return 0;
}
//
// assumes that the server is locked for reading or writing
// and that the client is locked for writing
//
DWORD
TraceMoveClientFile(
LPTRACE_CLIENT lpclient
) {
TCHAR szDestname[MAX_PATH], szSrcname[MAX_PATH];
lstrcpy(szSrcname, lpclient->TC_FileDir);
lstrcat(szSrcname, STR_DIRSEP);
lstrcat(szSrcname, lpclient->TC_ClientName);
lstrcpy(szDestname, szSrcname);
lstrcat(szSrcname, STR_LOGEXT);
lstrcat(szDestname, STR_OLDEXT);
//
// close the file handle if it is open
//
TraceCloseClientFile(lpclient);
//
// do the move
//
MoveFileEx(
szSrcname, szDestname,
MOVEFILE_REPLACE_EXISTING | MOVEFILE_COPY_ALLOWED
);
//
// re-open the log file
//
return TraceCreateClientFile(lpclient);
}
//
// assumes that the server is locked for reading or writing
// and that the client is locked for writing
//
DWORD
TraceCloseClientFile(
LPTRACE_CLIENT lpclient
) {
if (lpclient->TC_File != NULL) {
CloseHandle(lpclient->TC_File);
lpclient->TC_File = NULL;
}
return 0;
}
//
// assumes that the server is locked for reading or writing
// and that the client is locked for reading
//
DWORD
TraceWriteOutput(
LPTRACE_SERVER lpserver,
LPTRACE_CLIENT lpclient,
DWORD dwFlags,
LPCTSTR lpszOutput
) {
BOOL bSuccess;
DWORD dwFileMask, dwConsoleMask;
DWORD dwErr, dwFileSize, dwBytesToWrite, dwBytesWritten, dwChars;
dwBytesWritten = 0;
dwBytesToWrite = lstrlen(lpszOutput) * sizeof(TCHAR);
dwFileMask = dwConsoleMask = 1;
//
// if the client uses output masking, compute the mask for this message
//
if (dwFlags & TRACE_USE_MASK) {
dwFileMask = (dwFlags & lpclient->TC_FileMask);
dwConsoleMask = (dwFlags & lpclient->TC_ConsoleMask);
}
if (TRACE_CLIENT_USES_FILE(lpclient) &&
dwFileMask != 0 && lpclient->TC_File != NULL) {
//
// check the size of the file to see if it needs renaming
//
dwFileSize = GetFileSize(lpclient->TC_File, NULL);
if ((dwFileSize + dwBytesToWrite) > lpclient->TC_MaxFileSize) {
TRACE_READ_TO_WRITELOCK(lpclient);
//
// move the existing file over and start with an empty one
//
dwErr = TraceMoveClientFile(lpclient);
if (dwErr!=NO_ERROR)
return dwErr;
dwFileSize = 0;
TRACE_WRITE_TO_READLOCK(lpclient);
}
//
// perform the write operation
//
bSuccess =
WriteFile(
lpclient->TC_File, lpszOutput, dwBytesToWrite,
&dwBytesWritten, NULL
);
}
if (TRACE_CLIENT_USES_CONSOLE(lpclient) &&
dwConsoleMask != 0 && lpclient->TC_Console != NULL) {
//
// write to the console directly; this is less costly
// than writing to a file, which is fortunate since we
// cannot use completion ports with console handles
//
dwChars = dwBytesToWrite / sizeof(TCHAR);
bSuccess =
WriteConsole(
lpclient->TC_Console, lpszOutput, dwChars, &dwChars, NULL
);
}
return dwBytesWritten;
}
//----------------------------------------------------------------------------
// Function: TraceDumpLine
//
// Parameters:
// LPTRACE_CLIENT lpclient pointer to client struct for caller
// LPBYTE lpbBytes address of buffer to dump
// DWORD dwLine length of line in bytes
// DWORD dwGroup size of byte groupings
// BOOL bPrefixAddr if TRUE, prefix lines with addresses
// LPBYTE lpbPrefix address with which to prefix lines
// LPTSTR lpszPrefix optional string with which to prefix lines
//----------------------------------------------------------------------------
DWORD
TraceDumpLine(
LPTRACE_SERVER lpserver,
LPTRACE_CLIENT lpclient,
DWORD dwFlags,
LPBYTE lpbBytes,
DWORD dwLine,
DWORD dwGroup,
BOOL bPrefixAddr,
LPBYTE lpbPrefix,
LPCTSTR lpszPrefix
) {
INT offset;
LPTSTR lpszHex, lpszAscii;
TCHAR szBuffer[256] = TEXT("\r\n");
TCHAR szAscii[BYTES_PER_DUMPLINE + 2] = TEXT("");
TCHAR szHex[(3 * BYTES_PER_DUMPLINE) + 1] = TEXT("");
TCHAR szDigits[] = TEXT("0123456789ABCDEF");
//
// prepend prefix string if necessary
//
if (lpszPrefix != NULL) {
lstrcat(szBuffer, lpszPrefix);
}
//
// prepend address if needed
//
if (bPrefixAddr) {
LPTSTR lpsz;
ULONG_PTR ulpAddress = (ULONG_PTR) lpbPrefix;
ULONG i;
//
// each line prints out a hex-digit
// with the most-significant digit leftmost in the string
// prepend address to lpsz[1]..lpsz[2*sizeof(ULONG_PTR)]
//
lpsz = szBuffer + lstrlen(szBuffer);
for (i=0; i<2*sizeof(ULONG_PTR); i++) {
lpsz[2*sizeof(ULONG_PTR)-i] = szDigits[ulpAddress & 0x0F];
ulpAddress >>= 4;
}
lpsz[2*sizeof(ULONG_PTR) + 1] = TEXT(':');
lpsz[2*sizeof(ULONG_PTR) + 2] = TEXT(' ');
lpsz[2*sizeof(ULONG_PTR) + 3] = TEXT('\0');
}
lpszHex = szHex;
lpszAscii = szAscii;
//
// rather than test the size of the grouping every time through
// a loop, have a loop for each group size
//
switch(dwGroup) {
//
// single byte groupings
//
case 1: {
while (dwLine >= sizeof(BYTE)) {
//
// print hex digits
//
*lpszHex++ = szDigits[*lpbBytes / 16];
*lpszHex++ = szDigits[*lpbBytes % 16];
*lpszHex++ = TEXT(' ');
//
// print ascii characters
//
*lpszAscii++ =
(*lpbBytes >= 0x20 && *lpbBytes < 0x80) ? *lpbBytes
: TEXT('.');
++lpbBytes;
--dwLine;
}
break;
}
//
// word-sized groupings
//
case 2: {
WORD wBytes;
BYTE loByte, hiByte;
//
// should already be aligned on a word boundary
//
while (dwLine >= sizeof(WORD)) {
wBytes = *(LPWORD)lpbBytes;
loByte = LOBYTE(wBytes);
hiByte = HIBYTE(wBytes);
// print hex digits
*lpszHex++ = szDigits[hiByte / 16];
*lpszHex++ = szDigits[hiByte % 16];
*lpszHex++ = szDigits[loByte / 16];
*lpszHex++ = szDigits[loByte % 16];
*lpszHex++ = TEXT(' ');
// print ascii characters
*lpszAscii++ =
(hiByte >= 0x20 && hiByte < 0x80) ? hiByte : TEXT('.');
*lpszAscii++ =
(loByte >= 0x20 && loByte < 0x80) ? loByte : TEXT('.');
dwLine -= sizeof(WORD);
lpbBytes += sizeof(WORD);
}
break;
}
//
// double-word sized groupings
//
case 4: {
DWORD dwBytes;
BYTE loloByte, lohiByte, hiloByte, hihiByte;
//
// should already be aligned on a double-word boundary
//
while (dwLine >= sizeof(DWORD)) {
dwBytes = *(LPDWORD)lpbBytes;
hihiByte = HIBYTE(HIWORD(dwBytes));
lohiByte = LOBYTE(HIWORD(dwBytes));
hiloByte = HIBYTE(LOWORD(dwBytes));
loloByte = LOBYTE(LOWORD(dwBytes));
// print hex digits
*lpszHex++ = szDigits[hihiByte / 16];
*lpszHex++ = szDigits[hihiByte % 16];
*lpszHex++ = szDigits[lohiByte / 16];
*lpszHex++ = szDigits[lohiByte % 16];
*lpszHex++ = szDigits[hiloByte / 16];
*lpszHex++ = szDigits[hiloByte % 16];
*lpszHex++ = szDigits[loloByte / 16];
*lpszHex++ = szDigits[loloByte % 16];
*lpszHex++ = TEXT(' ');
// print ascii characters
*lpszAscii++ =
(hihiByte >= 0x20 && hihiByte < 0x80) ? hihiByte
: TEXT('.');
*lpszAscii++ =
(lohiByte >= 0x20 && lohiByte < 0x80) ? lohiByte
: TEXT('.');
*lpszAscii++ =
(hiloByte >= 0x20 && hiloByte < 0x80) ? hiloByte
: TEXT('.');
*lpszAscii++ =
(loloByte >= 0x20 && loloByte < 0x80) ? loloByte
: TEXT('.');
// on to the next double-word
dwLine -= sizeof(DWORD);
lpbBytes += sizeof(DWORD);
}
break;
}
default:
break;
}
*lpszHex = *lpszAscii = TEXT('\0');
lstrcat(szBuffer, szHex);
lstrcat(szBuffer, TEXT("|"));
lstrcat(szBuffer, szAscii);
lstrcat(szBuffer, TEXT("|"));
return TraceWriteOutput(lpserver, lpclient, dwFlags, szBuffer);
}