Leaked source code of windows server 2003
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// begin_strsafe
/******************************************************************
* *
* strsafe.h -- This module defines safer C library string *
* routine replacements. These are meant to make C *
* a bit more safe in reference to security and *
* robustness *
* *
* Copyright (c) Microsoft Corp. All rights reserved. *
* *
******************************************************************/
#ifndef _STRSAFE_H_INCLUDED_
#define _STRSAFE_H_INCLUDED_
// end_strsafe
// begin_ntstrsafe
/******************************************************************
* *
* ntstrsafe.h -- This module defines safer C library string *
* routine replacements for drivers. These are *
* meant to make C a bit more safe in reference *
* to security and robustness. A similar file, *
* strsafe.h, is available for applications. *
* *
* Copyright (c) Microsoft Corp. All rights reserved. *
* *
******************************************************************/
#ifndef _NTSTRSAFE_H_INCLUDED_
#define _NTSTRSAFE_H_INCLUDED_
// end_ntstrsafe
// begin_strsafe begin_ntstrsafe
#pragma once
#include <stdio.h> // for _vsnprintf, _vsnwprintf, getc, getwc
#include <string.h> // for memset
#include <stdarg.h> // for va_start, etc.
// end_strsafe end_ntstrsafe
// begin_strsafe
#ifndef _SIZE_T_DEFINED
#ifdef _WIN64
typedef unsigned __int64 size_t;
#else
typedef __w64 unsigned int size_t;
#endif // !_WIN64
#define _SIZE_T_DEFINED
#endif // !_SIZE_T_DEFINED
#if !defined(_WCHAR_T_DEFINED) && !defined(_NATIVE_WCHAR_T_DEFINED)
typedef unsigned short wchar_t;
#define _WCHAR_T_DEFINED
#endif
#ifndef _HRESULT_DEFINED
#define _HRESULT_DEFINED
typedef long HRESULT;
#endif // !_HRESULT_DEFINED
#ifndef SUCCEEDED
#define SUCCEEDED(hr) ((HRESULT)(hr) >= 0)
#endif
#ifndef FAILED
#define FAILED(hr) ((HRESULT)(hr) < 0)
#endif
#ifndef S_OK
#define S_OK ((HRESULT)0x00000000L)
#endif
// end_strsafe
// begin_strsafe begin_ntstrsafe
#ifdef __cplusplus
#define _STRSAFE_EXTERN_C extern "C"
#else
#define _STRSAFE_EXTERN_C extern
#endif
// end_strsafe end_ntstrsafe
// begin_strsafe
// If you do not want to use these functions inline (and instead want to link w/ strsafe.lib), then
// #define STRSAFE_LIB before including this header file.
#if defined(STRSAFE_LIB)
#define STRSAFEAPI _STRSAFE_EXTERN_C HRESULT __stdcall
#pragma comment(lib, "strsafe.lib")
// end_strsafe
// begin_ntstrsafe
//
// The following steps are *REQUIRED* if ntstrsafe.h is used for drivers on:
// Windows 2000
// Windows Millennium Edition
// Windows 98 Second Edition
// Windows 98
//
// 1. #define STRSAFE_LIB before including this header file.
// 2. Add strsafe.lib to the TARGET_LIBS line in SOURCES
//
// Drivers running on XP and later can skip these steps to create a smaller
// driver.
//
#if defined(STRSAFE_LIB)
#define STRSAFEAPI _STRSAFE_EXTERN_C HRESULT __stdcall
#pragma comment(lib, "strsafe.lib")
// end_ntstrsafe
// begin_strsafe begin_ntstrsafe
#elif defined(STRSAFE_LIB_IMPL)
#define STRSAFEAPI _STRSAFE_EXTERN_C HRESULT __stdcall
#else
#define STRSAFEAPI __inline HRESULT __stdcall
#define STRSAFE_INLINE
#endif
// Some functions always run inline because they use stdin and we want to avoid building multiple
// versions of strsafe lib depending on if you use msvcrt, libcmt, etc.
#define STRSAFE_INLINE_API __inline HRESULT __stdcall
// The user can request no "Cb" or no "Cch" fuctions, but not both!
#if defined(STRSAFE_NO_CB_FUNCTIONS) && defined(STRSAFE_NO_CCH_FUNCTIONS)
#error cannot specify both STRSAFE_NO_CB_FUNCTIONS and STRSAFE_NO_CCH_FUNCTIONS !!
#endif
// This should only be defined when we are building strsafe.lib
#ifdef STRSAFE_LIB_IMPL
#define STRSAFE_INLINE
#endif
// If both strsafe.h and ntstrsafe.h are included, only use definitions from one.
// end_strsafe end_ntstrsafe
// begin_ntstrsafe
#ifndef _STRSAFE_H_INCLUDED_
// end_ntstrsafe
// begin_strsafe
#ifndef _NTSTRSAFE_H_INCLUDED_
// end_strsafe
// begin_strsafe begin_ntstrsafe
#define STRSAFE_MAX_CCH 2147483647 // max # of characters we support (same as INT_MAX)
// Flags for controling the Ex functions
//
// STRSAFE_FILL_BYTE(0xFF) 0x000000FF // bottom byte specifies fill pattern
#define STRSAFE_IGNORE_NULLS 0x00000100 // treat null as TEXT("") -- don't fault on NULL buffers
#define STRSAFE_FILL_BEHIND_NULL 0x00000200 // fill in extra space behind the null terminator
#define STRSAFE_FILL_ON_FAILURE 0x00000400 // on failure, overwrite pszDest with fill pattern and null terminate it
#define STRSAFE_NULL_ON_FAILURE 0x00000800 // on failure, set *pszDest = TEXT('\0')
#define STRSAFE_NO_TRUNCATION 0x00001000 // instead of returning a truncated result, copy/append nothing to pszDest and null terminate it
#define STRSAFE_VALID_FLAGS (0x000000FF | STRSAFE_IGNORE_NULLS | STRSAFE_FILL_BEHIND_NULL | STRSAFE_FILL_ON_FAILURE | STRSAFE_NULL_ON_FAILURE | STRSAFE_NO_TRUNCATION)
// helper macro to set the fill character and specify buffer filling
#define STRSAFE_FILL_BYTE(x) ((unsigned long)((x & 0x000000FF) | STRSAFE_FILL_BEHIND_NULL))
#define STRSAFE_FAILURE_BYTE(x) ((unsigned long)((x & 0x000000FF) | STRSAFE_FILL_ON_FAILURE))
#define STRSAFE_GET_FILL_PATTERN(dwFlags) ((int)(dwFlags & 0x000000FF))
// end_strsafe end_ntstrsafe
// begin_ntstrsafe
#endif // _STRSAFE_H_INCLUDED_
// end_ntstrsafe
// begin_strsafe
#endif // _NTSTRSAFE_H_INCLUDED_
// end_strsafe
// begin_strsafe begin_ntstrsafe
// end_strsafe end_ntstrsafe
// begin_strsafe
// STRSAFE error return codes
//
#define STRSAFE_E_INSUFFICIENT_BUFFER ((HRESULT)0x8007007AL) // 0x7A = 122L = ERROR_INSUFFICIENT_BUFFER
#define STRSAFE_E_INVALID_PARAMETER ((HRESULT)0x80070057L) // 0x57 = 87L = ERROR_INVALID_PARAMETER
#define STRSAFE_E_END_OF_FILE ((HRESULT)0x80070026L) // 0x26 = 38L = ERROR_HANDLE_EOF
// end_strsafe
// begin_strsafe begin_ntstrsafe
// prototypes for the worker functions
#ifdef STRSAFE_INLINE
STRSAFEAPI StringCopyWorkerA(char* pszDest, size_t cchDest, const char* pszSrc);
STRSAFEAPI StringCopyWorkerW(wchar_t* pszDest, size_t cchDest, const wchar_t* pszSrc);
STRSAFEAPI StringCopyExWorkerA(char* pszDest, size_t cchDest, size_t cbDest, const char* pszSrc, char** ppszDestEnd, size_t* pcchRemaining, unsigned long dwFlags);
STRSAFEAPI StringCopyExWorkerW(wchar_t* pszDest, size_t cchDest, size_t cbDest, const wchar_t* pszSrc, wchar_t** ppszDestEnd, size_t* pcchRemaining, unsigned long dwFlags);
STRSAFEAPI StringCopyNWorkerA(char* pszDest, size_t cchDest, const char* pszSrc, size_t cchSrc);
STRSAFEAPI StringCopyNWorkerW(wchar_t* pszDest, size_t cchDest, const wchar_t* pszSrc, size_t cchSrc);
STRSAFEAPI StringCopyNExWorkerA(char* pszDest, size_t cchDest, size_t cbDest, const char* pszSrc, size_t cchSrc, char** ppszDestEnd, size_t* pcchRemaining, unsigned long dwFlags);
STRSAFEAPI StringCopyNExWorkerW(wchar_t* pszDest, size_t cchDest, size_t cbDest, const wchar_t* pszSrc, size_t cchSrc, wchar_t** ppszDestEnd, size_t* pcchRemaining, unsigned long dwFlags);
STRSAFEAPI StringCatWorkerA(char* pszDest, size_t cchDest, const char* pszSrc);
STRSAFEAPI StringCatWorkerW(wchar_t* pszDest, size_t cchDest, const wchar_t* pszSrc);
STRSAFEAPI StringCatExWorkerA(char* pszDest, size_t cchDest, size_t cbDest, const char* pszSrc, char** ppszDestEnd, size_t* pcchRemaining, unsigned long dwFlags);
STRSAFEAPI StringCatExWorkerW(wchar_t* pszDest, size_t cchDest, size_t cbDest, const wchar_t* pszSrc, wchar_t** ppszDestEnd, size_t* pcchRemaining, unsigned long dwFlags);
STRSAFEAPI StringCatNWorkerA(char* pszDest, size_t cchDest, const char* pszSrc, size_t cchMaxAppend);
STRSAFEAPI StringCatNWorkerW(wchar_t* pszDest, size_t cchDest, const wchar_t* pszSrc, size_t cchMaxAppend);
STRSAFEAPI StringCatNExWorkerA(char* pszDest, size_t cchDest, size_t cbDest, const char* pszSrc, size_t cchMaxAppend, char** ppszDestEnd, size_t* pcchRemaining, unsigned long dwFlags);
STRSAFEAPI StringCatNExWorkerW(wchar_t* pszDest, size_t cchDest, size_t cbDest, const wchar_t* pszSrc, size_t cchMaxAppend, wchar_t** ppszDestEnd, size_t* pcchRemaining, unsigned long dwFlags);
STRSAFEAPI StringVPrintfWorkerA(char* pszDest, size_t cchDest, const char* pszFormat, va_list argList);
STRSAFEAPI StringVPrintfWorkerW(wchar_t* pszDest, size_t cchDest, const wchar_t* pszFormat, va_list argList);
STRSAFEAPI StringVPrintfExWorkerA(char* pszDest, size_t cchDest, size_t cbDest, char** ppszDestEnd, size_t* pcchRemaining, unsigned long dwFlags, const char* pszFormat, va_list argList);
STRSAFEAPI StringVPrintfExWorkerW(wchar_t* pszDest, size_t cchDest, size_t cbDest, wchar_t** ppszDestEnd, size_t* pcchRemaining, unsigned long dwFlags, const wchar_t* pszFormat, va_list argList);
STRSAFEAPI StringLengthWorkerA(const char* psz, size_t cchMax, size_t* pcch);
STRSAFEAPI StringLengthWorkerW(const wchar_t* psz, size_t cchMax, size_t* pcch);
#endif // STRSAFE_INLINE
// end_strsafe end_ntstrsafe
// begin_strsafe
#ifndef STRSAFE_LIB_IMPL
// these functions are always inline
STRSAFE_INLINE_API StringGetsExWorkerA(char* pszDest, size_t cchDest, size_t cbDest, char** ppszDestEnd, size_t* pcchRemaining, unsigned long dwFlags);
STRSAFE_INLINE_API StringGetsExWorkerW(wchar_t* pszDest, size_t cchDest, size_t cbDest, wchar_t** ppszDestEnd, size_t* pcchRemaining, unsigned long dwFlags);
#endif
#ifdef _NTSTRSAFE_H_INCLUDED_
#pragma warning(push)
#pragma warning(disable : 4995)
#endif // _NTSTRSAFE_H_INCLUDED_
// end_strsafe
// begin_ntstrsafe
#ifdef _STRSAFE_H_INCLUDED_
#pragma warning(push)
#pragma warning(disable : 4995)
#endif // _STRSAFE_H_INCLUDED_
// end_ntstrsafe
// begin_strsafe begin_ntstrsafe
#ifndef STRSAFE_NO_CCH_FUNCTIONS
/*++
STDAPI
StringCchCopy(
OUT LPTSTR pszDest,
IN size_t cchDest,
IN LPCTSTR pszSrc
);
Routine Description:
This routine is a safer version of the C built-in function 'strcpy'.
The size of the destination buffer (in characters) is a parameter and
this function will not write past the end of this buffer and it will
ALWAYS null terminate the destination buffer (unless it is zero length).
This routine is not a replacement for strncpy. That function will pad the
destination string with extra null termination characters if the count is
greater than the length of the source string, and it will fail to null
terminate the destination string if the source string length is greater
than or equal to the count. You can not blindly use this instead of strncpy:
it is common for code to use it to "patch" strings and you would introduce
errors if the code started null terminating in the middle of the string.
This function returns a hresult, and not a pointer. It returns
S_OK if the string was copied without truncation and null terminated,
otherwise it will return a failure code. In failure cases as much of
pszSrc will be copied to pszDest as possible, and pszDest will be null
terminated.
Arguments:
pszDest - destination string
cchDest - size of destination buffer in characters.
length must be = (_tcslen(src) + 1) to hold all of the
source including the null terminator
pszSrc - source string which must be null terminated
Notes:
Behavior is undefined if source and destination strings overlap.
pszDest and pszSrc should not be NULL. See StringCchCopyEx if you require
the handling of NULL values.
Return Value:
S_OK - if there was source data and it was all copied and the
resultant dest string was null terminated
failure - you can use the macro HRESULT_CODE() to get a win32
error code for all hresult failure cases
STRSAFE_E_INSUFFICIENT_BUFFER /
HRESULT_CODE(hr) == ERROR_INSUFFICIENT_BUFFER
- this return value is an indication that the copy
operation failed due to insufficient space. When this
error occurs, the destination buffer is modified to
contain a truncated version of the ideal result and is
null terminated. This is useful for situations where
truncation is ok
It is strongly recommended to use the SUCCEEDED() / FAILED() macros to test the
return value of this function.
--*/
STRSAFEAPI StringCchCopyA(char* pszDest, size_t cchDest, const char* pszSrc);
STRSAFEAPI StringCchCopyW(wchar_t* pszDest, size_t cchDest, const wchar_t* pszSrc);
// end_strsafe end_ntstrsafe
// begin_strsafe
#ifdef UNICODE
#define StringCchCopy StringCchCopyW
#else
#define StringCchCopy StringCchCopyA
#endif // !UNICODE
// end_strsafe
// begin_strsafe begin_ntstrsafe
#ifdef STRSAFE_INLINE
STRSAFEAPI StringCchCopyA(char* pszDest, size_t cchDest, const char* pszSrc)
{
HRESULT hr;
if (cchDest > STRSAFE_MAX_CCH)
{
hr = STRSAFE_E_INVALID_PARAMETER;
}
else
{
hr = StringCopyWorkerA(pszDest, cchDest, pszSrc);
}
return hr;
}
STRSAFEAPI StringCchCopyW(wchar_t* pszDest, size_t cchDest, const wchar_t* pszSrc)
{
HRESULT hr;
if (cchDest > STRSAFE_MAX_CCH)
{
hr = STRSAFE_E_INVALID_PARAMETER;
}
else
{
hr = StringCopyWorkerW(pszDest, cchDest, pszSrc);
}
return hr;
}
#endif // STRSAFE_INLINE
#endif // !STRSAFE_NO_CCH_FUNCTIONS
#ifndef STRSAFE_NO_CB_FUNCTIONS
/*++
STDAPI
StringCbCopy(
OUT LPTSTR pszDest,
IN size_t cbDest,
IN LPCTSTR pszSrc
);
Routine Description:
This routine is a safer version of the C built-in function 'strcpy'.
The size of the destination buffer (in bytes) is a parameter and this
function will not write past the end of this buffer and it will ALWAYS
null terminate the destination buffer (unless it is zero length).
This routine is not a replacement for strncpy. That function will pad the
destination string with extra null termination characters if the count is
greater than the length of the source string, and it will fail to null
terminate the destination string if the source string length is greater
than or equal to the count. You can not blindly use this instead of strncpy:
it is common for code to use it to "patch" strings and you would introduce
errors if the code started null terminating in the middle of the string.
This function returns a hresult, and not a pointer. It returns
S_OK if the string was copied without truncation and null terminated,
otherwise it will return a failure code. In failure cases as much of pszSrc
will be copied to pszDest as possible, and pszDest will be null terminated.
Arguments:
pszDest - destination string
cbDest - size of destination buffer in bytes.
length must be = ((_tcslen(src) + 1) * sizeof(TCHAR)) to
hold all of the source including the null terminator
pszSrc - source string which must be null terminated
Notes:
Behavior is undefined if source and destination strings overlap.
pszDest and pszSrc should not be NULL. See StringCbCopyEx if you require
the handling of NULL values.
Return Value:
S_OK - if there was source data and it was all copied and the
resultant dest string was null terminated
failure - you can use the macro HRESULT_CODE() to get a win32
error code for all hresult failure cases
STRSAFE_E_INSUFFICIENT_BUFFER /
HRESULT_CODE(hr) == ERROR_INSUFFICIENT_BUFFER
- this return value is an indication that the copy
operation failed due to insufficient space. When this
error occurs, the destination buffer is modified to
contain a truncated version of the ideal result and is
null terminated. This is useful for situations where
truncation is ok
It is strongly recommended to use the SUCCEEDED() / FAILED() macros to test the
return value of this function.
--*/
STRSAFEAPI StringCbCopyA(char* pszDest, size_t cbDest, const char* pszSrc);
STRSAFEAPI StringCbCopyW(wchar_t* pszDest, size_t cbDest, const wchar_t* pszSrc);
// end_strsafe end_ntstrsafe
// begin_strsafe
#ifdef UNICODE
#define StringCbCopy StringCbCopyW
#else
#define StringCbCopy StringCbCopyA
#endif // !UNICODE
// end_strsafe
// begin_strsafe begin_ntstrsafe
#ifdef STRSAFE_INLINE
STRSAFEAPI StringCbCopyA(char* pszDest, size_t cbDest, const char* pszSrc)
{
HRESULT hr;
size_t cchDest;
// convert to count of characters
cchDest = cbDest / sizeof(char);
if (cchDest > STRSAFE_MAX_CCH)
{
hr = STRSAFE_E_INVALID_PARAMETER;
}
else
{
hr = StringCopyWorkerA(pszDest, cchDest, pszSrc);
}
return hr;
}
STRSAFEAPI StringCbCopyW(wchar_t* pszDest, size_t cbDest, const wchar_t* pszSrc)
{
HRESULT hr;
size_t cchDest;
// convert to count of characters
cchDest = cbDest / sizeof(wchar_t);
if (cchDest > STRSAFE_MAX_CCH)
{
hr = STRSAFE_E_INVALID_PARAMETER;
}
else
{
hr = StringCopyWorkerW(pszDest, cchDest, pszSrc);
}
return hr;
}
#endif // STRSAFE_INLINE
#endif // !STRSAFE_NO_CB_FUNCTIONS
#ifndef STRSAFE_NO_CCH_FUNCTIONS
/*++
STDAPI
StringCchCopyEx(
OUT LPTSTR pszDest OPTIONAL,
IN size_t cchDest,
IN LPCTSTR pszSrc OPTIONAL,
OUT LPTSTR* ppszDestEnd OPTIONAL,
OUT size_t* pcchRemaining OPTIONAL,
IN DWORD dwFlags
);
Routine Description:
This routine is a safer version of the C built-in function 'strcpy' with
some additional parameters. In addition to functionality provided by
StringCchCopy, this routine also returns a pointer to the end of the
destination string and the number of characters left in the destination string
including the null terminator. The flags parameter allows additional controls.
Arguments:
pszDest - destination string
cchDest - size of destination buffer in characters.
length must be = (_tcslen(pszSrc) + 1) to hold all of
the source including the null terminator
pszSrc - source string which must be null terminated
ppszDestEnd - if ppszDestEnd is non-null, the function will return a
pointer to the end of the destination string. If the
function copied any data, the result will point to the
null termination character
pcchRemaining - if pcchRemaining is non-null, the function will return the
number of characters left in the destination string,
including the null terminator
dwFlags - controls some details of the string copy:
STRSAFE_FILL_BEHIND_NULL
if the function succeeds, the low byte of dwFlags will be
used to fill the uninitialize part of destination buffer
behind the null terminator
STRSAFE_IGNORE_NULLS
treat NULL string pointers like empty strings (TEXT("")).
this flag is useful for emulating functions like lstrcpy
STRSAFE_FILL_ON_FAILURE
if the function fails, the low byte of dwFlags will be
used to fill all of the destination buffer, and it will
be null terminated. This will overwrite any truncated
string returned when the failure is
STRSAFE_E_INSUFFICIENT_BUFFER
STRSAFE_NO_TRUNCATION /
STRSAFE_NULL_ON_FAILURE
if the function fails, the destination buffer will be set
to the empty string. This will overwrite any truncated string
returned when the failure is STRSAFE_E_INSUFFICIENT_BUFFER.
Notes:
Behavior is undefined if source and destination strings overlap.
pszDest and pszSrc should not be NULL unless the STRSAFE_IGNORE_NULLS flag
is specified. If STRSAFE_IGNORE_NULLS is passed, both pszDest and pszSrc
may be NULL. An error may still be returned even though NULLS are ignored
due to insufficient space.
Return Value:
S_OK - if there was source data and it was all copied and the
resultant dest string was null terminated
failure - you can use the macro HRESULT_CODE() to get a win32
error code for all hresult failure cases
STRSAFE_E_INSUFFICIENT_BUFFER /
HRESULT_CODE(hr) == ERROR_INSUFFICIENT_BUFFER
- this return value is an indication that the copy
operation failed due to insufficient space. When this
error occurs, the destination buffer is modified to
contain a truncated version of the ideal result and is
null terminated. This is useful for situations where
truncation is ok.
It is strongly recommended to use the SUCCEEDED() / FAILED() macros to test the
return value of this function
--*/
STRSAFEAPI StringCchCopyExA(char* pszDest, size_t cchDest, const char* pszSrc, char** ppszDestEnd, size_t* pcchRemaining, unsigned long dwFlags);
STRSAFEAPI StringCchCopyExW(wchar_t* pszDest, size_t cchDest, const wchar_t* pszSrc, wchar_t** ppszDestEnd, size_t* pcchRemaining, unsigned long dwFlags);
// end_strsafe end_ntstrsafe
// begin_strsafe
#ifdef UNICODE
#define StringCchCopyEx StringCchCopyExW
#else
#define StringCchCopyEx StringCchCopyExA
#endif // !UNICODE
// end_strsafe
// begin_strsafe begin_ntstrsafe
#ifdef STRSAFE_INLINE
STRSAFEAPI StringCchCopyExA(char* pszDest, size_t cchDest, const char* pszSrc, char** ppszDestEnd, size_t* pcchRemaining, unsigned long dwFlags)
{
HRESULT hr;
if (cchDest > STRSAFE_MAX_CCH)
{
hr = STRSAFE_E_INVALID_PARAMETER;
}
else
{
size_t cbDest;
// safe to multiply cchDest * sizeof(char) since cchDest < STRSAFE_MAX_CCH and sizeof(char) is 1
cbDest = cchDest * sizeof(char);
hr = StringCopyExWorkerA(pszDest, cchDest, cbDest, pszSrc, ppszDestEnd, pcchRemaining, dwFlags);
}
return hr;
}
STRSAFEAPI StringCchCopyExW(wchar_t* pszDest, size_t cchDest, const wchar_t* pszSrc, wchar_t** ppszDestEnd, size_t* pcchRemaining, unsigned long dwFlags)
{
HRESULT hr;
if (cchDest > STRSAFE_MAX_CCH)
{
hr = STRSAFE_E_INVALID_PARAMETER;
}
else
{
size_t cbDest;
// safe to multiply cchDest * sizeof(wchar_t) since cchDest < STRSAFE_MAX_CCH and sizeof(wchar_t) is 2
cbDest = cchDest * sizeof(wchar_t);
hr = StringCopyExWorkerW(pszDest, cchDest, cbDest, pszSrc, ppszDestEnd, pcchRemaining, dwFlags);
}
return hr;
}
#endif // STRSAFE_INLINE
#endif // !STRSAFE_NO_CCH_FUNCTIONS
#ifndef STRSAFE_NO_CB_FUNCTIONS
/*++
STDAPI
StringCbCopyEx(
OUT LPTSTR pszDest OPTIONAL,
IN size_t cbDest,
IN LPCTSTR pszSrc OPTIONAL,
OUT LPTSTR* ppszDestEnd OPTIONAL,
OUT size_t* pcbRemaining OPTIONAL,
IN DWORD dwFlags
);
Routine Description:
This routine is a safer version of the C built-in function 'strcpy' with
some additional parameters. In addition to functionality provided by
StringCbCopy, this routine also returns a pointer to the end of the
destination string and the number of bytes left in the destination string
including the null terminator. The flags parameter allows additional controls.
Arguments:
pszDest - destination string
cbDest - size of destination buffer in bytes.
length must be ((_tcslen(pszSrc) + 1) * sizeof(TCHAR)) to
hold all of the source including the null terminator
pszSrc - source string which must be null terminated
ppszDestEnd - if ppszDestEnd is non-null, the function will return a
pointer to the end of the destination string. If the
function copied any data, the result will point to the
null termination character
pcbRemaining - pcbRemaining is non-null,the function will return the
number of bytes left in the destination string,
including the null terminator
dwFlags - controls some details of the string copy:
STRSAFE_FILL_BEHIND_NULL
if the function succeeds, the low byte of dwFlags will be
used to fill the uninitialize part of destination buffer
behind the null terminator
STRSAFE_IGNORE_NULLS
treat NULL string pointers like empty strings (TEXT("")).
this flag is useful for emulating functions like lstrcpy
STRSAFE_FILL_ON_FAILURE
if the function fails, the low byte of dwFlags will be
used to fill all of the destination buffer, and it will
be null terminated. This will overwrite any truncated
string returned when the failure is
STRSAFE_E_INSUFFICIENT_BUFFER
STRSAFE_NO_TRUNCATION /
STRSAFE_NULL_ON_FAILURE
if the function fails, the destination buffer will be set
to the empty string. This will overwrite any truncated string
returned when the failure is STRSAFE_E_INSUFFICIENT_BUFFER.
Notes:
Behavior is undefined if source and destination strings overlap.
pszDest and pszSrc should not be NULL unless the STRSAFE_IGNORE_NULLS flag
is specified. If STRSAFE_IGNORE_NULLS is passed, both pszDest and pszSrc
may be NULL. An error may still be returned even though NULLS are ignored
due to insufficient space.
Return Value:
S_OK - if there was source data and it was all copied and the
resultant dest string was null terminated
failure - you can use the macro HRESULT_CODE() to get a win32
error code for all hresult failure cases
STRSAFE_E_INSUFFICIENT_BUFFER /
HRESULT_CODE(hr) == ERROR_INSUFFICIENT_BUFFER
- this return value is an indication that the copy
operation failed due to insufficient space. When this
error occurs, the destination buffer is modified to
contain a truncated version of the ideal result and is
null terminated. This is useful for situations where
truncation is ok.
It is strongly recommended to use the SUCCEEDED() / FAILED() macros to test the
return value of this function
--*/
STRSAFEAPI StringCbCopyExA(char* pszDest, size_t cbDest, const char* pszSrc, char** ppszDestEnd, size_t* pcbRemaining, unsigned long dwFlags);
STRSAFEAPI StringCbCopyExW(wchar_t* pszDest, size_t cbDest, const wchar_t* pszSrc, wchar_t** ppszDestEnd, size_t* pcbRemaining, unsigned long dwFlags);
// end_strsafe end_ntstrsafe
// begin_strsafe
#ifdef UNICODE
#define StringCbCopyEx StringCbCopyExW
#else
#define StringCbCopyEx StringCbCopyExA
#endif // !UNICODE
// end_strsafe
// begin_strsafe begin_ntstrsafe
#ifdef STRSAFE_INLINE
STRSAFEAPI StringCbCopyExA(char* pszDest, size_t cbDest, const char* pszSrc, char** ppszDestEnd, size_t* pcbRemaining, unsigned long dwFlags)
{
HRESULT hr;
size_t cchDest;
size_t cchRemaining = 0;
cchDest = cbDest / sizeof(char);
if (cchDest > STRSAFE_MAX_CCH)
{
hr = STRSAFE_E_INVALID_PARAMETER;
}
else
{
hr = StringCopyExWorkerA(pszDest, cchDest, cbDest, pszSrc, ppszDestEnd, &cchRemaining, dwFlags);
}
if (SUCCEEDED(hr) || (hr == STRSAFE_E_INSUFFICIENT_BUFFER))
{
if (pcbRemaining)
{
// safe to multiply cchRemaining * sizeof(char) since cchRemaining < STRSAFE_MAX_CCH and sizeof(char) is 1
*pcbRemaining = (cchRemaining * sizeof(char)) + (cbDest % sizeof(char));
}
}
return hr;
}
STRSAFEAPI StringCbCopyExW(wchar_t* pszDest, size_t cbDest, const wchar_t* pszSrc, wchar_t** ppszDestEnd, size_t* pcbRemaining, unsigned long dwFlags)
{
HRESULT hr;
size_t cchDest;
size_t cchRemaining = 0;
cchDest = cbDest / sizeof(wchar_t);
if (cchDest > STRSAFE_MAX_CCH)
{
hr = STRSAFE_E_INVALID_PARAMETER;
}
else
{
hr = StringCopyExWorkerW(pszDest, cchDest, cbDest, pszSrc, ppszDestEnd, &cchRemaining, dwFlags);
}
if (SUCCEEDED(hr) || (hr == STRSAFE_E_INSUFFICIENT_BUFFER))
{
if (pcbRemaining)
{
// safe to multiply cchRemaining * sizeof(wchar_t) since cchRemaining < STRSAFE_MAX_CCH and sizeof(wchar_t) is 2
*pcbRemaining = (cchRemaining * sizeof(wchar_t)) + (cbDest % sizeof(wchar_t));
}
}
return hr;
}
#endif // STRSAFE_INLINE
#endif // !STRSAFE_NO_CB_FUNCTIONS
#ifndef STRSAFE_NO_CCH_FUNCTIONS
/*++
STDAPI
StringCchCopyN(
OUT LPTSTR pszDest,
IN size_t cchDest,
IN LPCTSTR pszSrc,
IN size_t cchSrc
);
Routine Description:
This routine is a safer version of the C built-in function 'strncpy'.
The size of the destination buffer (in characters) is a parameter and
this function will not write past the end of this buffer and it will
ALWAYS null terminate the destination buffer (unless it is zero length).
This routine is meant as a replacement for strncpy, but it does behave
differently. This function will not pad the destination buffer with extra
null termination characters if cchSrc is greater than the length of pszSrc.
This function returns a hresult, and not a pointer. It returns
S_OK if the entire string or the first cchSrc characters were copied
without truncation and the resultant destination string was null terminated,
otherwise it will return a failure code. In failure cases as much of pszSrc
will be copied to pszDest as possible, and pszDest will be null terminated.
Arguments:
pszDest - destination string
cchDest - size of destination buffer in characters.
length must be = (_tcslen(src) + 1) to hold all of the
source including the null terminator
pszSrc - source string
cchSrc - maximum number of characters to copy from source string,
not including the null terminator.
Notes:
Behavior is undefined if source and destination strings overlap.
pszDest and pszSrc should not be NULL. See StringCchCopyNEx if you require
the handling of NULL values.
Return Value:
S_OK - if there was source data and it was all copied and the
resultant dest string was null terminated
failure - you can use the macro HRESULT_CODE() to get a win32
error code for all hresult failure cases
STRSAFE_E_INSUFFICIENT_BUFFER /
HRESULT_CODE(hr) == ERROR_INSUFFICIENT_BUFFER
- this return value is an indication that the copy
operation failed due to insufficient space. When this
error occurs, the destination buffer is modified to
contain a truncated version of the ideal result and is
null terminated. This is useful for situations where
truncation is ok
It is strongly recommended to use the SUCCEEDED() / FAILED() macros to test the
return value of this function.
--*/
STRSAFEAPI StringCchCopyNA(char* pszDest, size_t cchDest, const char* pszSrc, size_t cchSrc);
STRSAFEAPI StringCchCopyNW(wchar_t* pszDest, size_t cchDest, const wchar_t* pszSrc, size_t cchSrc);
// end_strsafe end_ntstrsafe
// begin_strsafe
#ifdef UNICODE
#define StringCchCopyN StringCchCopyNW
#else
#define StringCchCopyN StringCchCopyNA
#endif // !UNICODE
// end_strsafe
// begin_strsafe begin_ntstrsafe
#ifdef STRSAFE_INLINE
STRSAFEAPI StringCchCopyNA(char* pszDest, size_t cchDest, const char* pszSrc, size_t cchSrc)
{
HRESULT hr;
if ((cchDest > STRSAFE_MAX_CCH) ||
(cchSrc > STRSAFE_MAX_CCH))
{
hr = STRSAFE_E_INVALID_PARAMETER;
}
else
{
hr = StringCopyNWorkerA(pszDest, cchDest, pszSrc, cchSrc);
}
return hr;
}
STRSAFEAPI StringCchCopyNW(wchar_t* pszDest, size_t cchDest, const wchar_t* pszSrc, size_t cchSrc)
{
HRESULT hr;
if ((cchDest > STRSAFE_MAX_CCH) ||
(cchSrc > STRSAFE_MAX_CCH))
{
hr = STRSAFE_E_INVALID_PARAMETER;
}
else
{
hr = StringCopyNWorkerW(pszDest, cchDest, pszSrc, cchSrc);
}
return hr;
}
#endif // STRSAFE_INLINE
#endif // !STRSAFE_NO_CCH_FUNCTIONS
#ifndef STRSAFE_NO_CB_FUNCTIONS
/*++
STDAPI
StringCbCopyN(
OUT LPTSTR pszDest,
IN size_t cbDest,
IN LPCTSTR pszSrc,
IN size_t cbSrc
);
Routine Description:
This routine is a safer version of the C built-in function 'strncpy'.
The size of the destination buffer (in bytes) is a parameter and this
function will not write past the end of this buffer and it will ALWAYS
null terminate the destination buffer (unless it is zero length).
This routine is meant as a replacement for strncpy, but it does behave
differently. This function will not pad the destination buffer with extra
null termination characters if cbSrc is greater than the size of pszSrc.
This function returns a hresult, and not a pointer. It returns
S_OK if the entire string or the first cbSrc characters were
copied without truncation and the resultant destination string was null
terminated, otherwise it will return a failure code. In failure cases as
much of pszSrc will be copied to pszDest as possible, and pszDest will be
null terminated.
Arguments:
pszDest - destination string
cbDest - size of destination buffer in bytes.
length must be = ((_tcslen(src) + 1) * sizeof(TCHAR)) to
hold all of the source including the null terminator
pszSrc - source string
cbSrc - maximum number of bytes to copy from source string,
not including the null terminator.
Notes:
Behavior is undefined if source and destination strings overlap.
pszDest and pszSrc should not be NULL. See StringCbCopyEx if you require
the handling of NULL values.
Return Value:
S_OK - if there was source data and it was all copied and the
resultant dest string was null terminated
failure - you can use the macro HRESULT_CODE() to get a win32
error code for all hresult failure cases
STRSAFE_E_INSUFFICIENT_BUFFER /
HRESULT_CODE(hr) == ERROR_INSUFFICIENT_BUFFER
- this return value is an indication that the copy
operation failed due to insufficient space. When this
error occurs, the destination buffer is modified to
contain a truncated version of the ideal result and is
null terminated. This is useful for situations where
truncation is ok
It is strongly recommended to use the SUCCEEDED() / FAILED() macros to test the
return value of this function.
--*/
STRSAFEAPI StringCbCopyNA(char* pszDest, size_t cbDest, const char* pszSrc, size_t cbSrc);
STRSAFEAPI StringCbCopyNW(wchar_t* pszDest, size_t cbDest, const wchar_t* pszSrc, size_t cbSrc);
// end_strsafe end_ntstrsafe
// begin_strsafe
#ifdef UNICODE
#define StringCbCopyN StringCbCopyNW
#else
#define StringCbCopyN StringCbCopyNA
#endif // !UNICODE
// end_strsafe
// begin_strsafe begin_ntstrsafe
#ifdef STRSAFE_INLINE
STRSAFEAPI StringCbCopyNA(char* pszDest, size_t cbDest, const char* pszSrc, size_t cbSrc)
{
HRESULT hr;
size_t cchDest;
size_t cchSrc;
// convert to count of characters
cchDest = cbDest / sizeof(char);
cchSrc = cbSrc / sizeof(char);
if ((cchDest > STRSAFE_MAX_CCH) ||
(cchSrc > STRSAFE_MAX_CCH))
{
hr = STRSAFE_E_INVALID_PARAMETER;
}
else
{
hr = StringCopyNWorkerA(pszDest, cchDest, pszSrc, cchSrc);
}
return hr;
}
STRSAFEAPI StringCbCopyNW(wchar_t* pszDest, size_t cbDest, const wchar_t* pszSrc, size_t cbSrc)
{
HRESULT hr;
size_t cchDest;
size_t cchSrc;
// convert to count of characters
cchDest = cbDest / sizeof(wchar_t);
cchSrc = cbSrc / sizeof(wchar_t);
if ((cchDest > STRSAFE_MAX_CCH) ||
(cchSrc > STRSAFE_MAX_CCH))
{
hr = STRSAFE_E_INVALID_PARAMETER;
}
else
{
hr = StringCopyNWorkerW(pszDest, cchDest, pszSrc, cchSrc);
}
return hr;
}
#endif // STRSAFE_INLINE
#endif // !STRSAFE_NO_CB_FUNCTIONS
#ifndef STRSAFE_NO_CCH_FUNCTIONS
/*++
STDAPI
StringCchCopyNEx(
OUT LPTSTR pszDest OPTIONAL,
IN size_t cchDest,
IN LPCTSTR pszSrc OPTIONAL,
IN size_t cchSrc,
OUT LPTSTR* ppszDestEnd OPTIONAL,
OUT size_t* pcchRemaining OPTIONAL,
IN DWORD dwFlags
);
Routine Description:
This routine is a safer version of the C built-in function 'strncpy' with
some additional parameters. In addition to functionality provided by
StringCchCopyN, this routine also returns a pointer to the end of the
destination string and the number of characters left in the destination
string including the null terminator. The flags parameter allows
additional controls.
This routine is meant as a replacement for strncpy, but it does behave
differently. This function will not pad the destination buffer with extra
null termination characters if cchSrc is greater than the length of pszSrc.
Arguments:
pszDest - destination string
cchDest - size of destination buffer in characters.
length must be = (_tcslen(pszSrc) + 1) to hold all of
the source including the null terminator
pszSrc - source string
cchSrc - maximum number of characters to copy from the source
string
ppszDestEnd - if ppszDestEnd is non-null, the function will return a
pointer to the end of the destination string. If the
function copied any data, the result will point to the
null termination character
pcchRemaining - if pcchRemaining is non-null, the function will return the
number of characters left in the destination string,
including the null terminator
dwFlags - controls some details of the string copy:
STRSAFE_FILL_BEHIND_NULL
if the function succeeds, the low byte of dwFlags will be
used to fill the uninitialize part of destination buffer
behind the null terminator
STRSAFE_IGNORE_NULLS
treat NULL string pointers like empty strings (TEXT("")).
this flag is useful for emulating functions like lstrcpy
STRSAFE_FILL_ON_FAILURE
if the function fails, the low byte of dwFlags will be
used to fill all of the destination buffer, and it will
be null terminated. This will overwrite any truncated
string returned when the failure is
STRSAFE_E_INSUFFICIENT_BUFFER
STRSAFE_NO_TRUNCATION /
STRSAFE_NULL_ON_FAILURE
if the function fails, the destination buffer will be set
to the empty string. This will overwrite any truncated string
returned when the failure is STRSAFE_E_INSUFFICIENT_BUFFER.
Notes:
Behavior is undefined if source and destination strings overlap.
pszDest and pszSrc should not be NULL unless the STRSAFE_IGNORE_NULLS flag
is specified. If STRSAFE_IGNORE_NULLS is passed, both pszDest and pszSrc
may be NULL. An error may still be returned even though NULLS are ignored
due to insufficient space.
Return Value:
S_OK - if there was source data and it was all copied and the
resultant dest string was null terminated
failure - you can use the macro HRESULT_CODE() to get a win32
error code for all hresult failure cases
STRSAFE_E_INSUFFICIENT_BUFFER /
HRESULT_CODE(hr) == ERROR_INSUFFICIENT_BUFFER
- this return value is an indication that the copy
operation failed due to insufficient space. When this
error occurs, the destination buffer is modified to
contain a truncated version of the ideal result and is
null terminated. This is useful for situations where
truncation is ok.
It is strongly recommended to use the SUCCEEDED() / FAILED() macros to test the
return value of this function
--*/
STRSAFEAPI StringCchCopyNExA(char* pszDest, size_t cchDest, const char* pszSrc, size_t cchSrc, char** ppszDestEnd, size_t* pcchRemaining, unsigned long dwFlags);
STRSAFEAPI StringCchCopyNExW(wchar_t* pszDest, size_t cchDest, const wchar_t* pszSrc, size_t cchSrc, wchar_t** ppszDestEnd, size_t* pcchRemaining, unsigned long dwFlags);
// end_strsafe end_ntstrsafe
// begin_strsafe
#ifdef UNICODE
#define StringCchCopyNEx StringCchCopyNExW
#else
#define StringCchCopyNEx StringCchCopyNExA
#endif // !UNICODE
// end_strsafe
// begin_strsafe begin_ntstrsafe
#ifdef STRSAFE_INLINE
STRSAFEAPI StringCchCopyNExA(char* pszDest, size_t cchDest, const char* pszSrc, size_t cchSrc, char** ppszDestEnd, size_t* pcchRemaining, unsigned long dwFlags)
{
HRESULT hr;
if ((cchDest > STRSAFE_MAX_CCH) ||
(cchSrc > STRSAFE_MAX_CCH))
{
hr = STRSAFE_E_INVALID_PARAMETER;
}
else
{
size_t cbDest;
// safe to multiply cchDest * sizeof(char) since cchDest < STRSAFE_MAX_CCH and sizeof(char) is 1
cbDest = cchDest * sizeof(char);
hr = StringCopyNExWorkerA(pszDest, cchDest, cbDest, pszSrc, cchSrc, ppszDestEnd, pcchRemaining, dwFlags);
}
return hr;
}
STRSAFEAPI StringCchCopyNExW(wchar_t* pszDest, size_t cchDest, const wchar_t* pszSrc, size_t cchSrc, wchar_t** ppszDestEnd, size_t* pcchRemaining, unsigned long dwFlags)
{
HRESULT hr;
if ((cchDest > STRSAFE_MAX_CCH) ||
(cchSrc > STRSAFE_MAX_CCH))
{
hr = STRSAFE_E_INVALID_PARAMETER;
}
else
{
size_t cbDest;
// safe to multiply cchDest * sizeof(wchar_t) since cchDest < STRSAFE_MAX_CCH and sizeof(wchar_t) is 2
cbDest = cchDest * sizeof(wchar_t);
hr = StringCopyNExWorkerW(pszDest, cchDest, cbDest, pszSrc, cchSrc, ppszDestEnd, pcchRemaining, dwFlags);
}
return hr;
}
#endif // STRSAFE_INLINE
#endif // !STRSAFE_NO_CCH_FUNCTIONS
#ifndef STRSAFE_NO_CB_FUNCTIONS
/*++
STDAPI
StringCbCopyNEx(
OUT LPTSTR pszDest OPTIONAL,
IN size_t cbDest,
IN LPCTSTR pszSrc OPTIONAL,
IN size_t cbSrc,
OUT LPTSTR* ppszDestEnd OPTIONAL,
OUT size_t* pcbRemaining OPTIONAL,
IN DWORD dwFlags
);
Routine Description:
This routine is a safer version of the C built-in function 'strncpy' with
some additional parameters. In addition to functionality provided by
StringCbCopyN, this routine also returns a pointer to the end of the
destination string and the number of bytes left in the destination string
including the null terminator. The flags parameter allows additional controls.
This routine is meant as a replacement for strncpy, but it does behave
differently. This function will not pad the destination buffer with extra
null termination characters if cbSrc is greater than the size of pszSrc.
Arguments:
pszDest - destination string
cbDest - size of destination buffer in bytes.
length must be ((_tcslen(pszSrc) + 1) * sizeof(TCHAR)) to
hold all of the source including the null terminator
pszSrc - source string
cbSrc - maximum number of bytes to copy from source string
ppszDestEnd - if ppszDestEnd is non-null, the function will return a
pointer to the end of the destination string. If the
function copied any data, the result will point to the
null termination character
pcbRemaining - pcbRemaining is non-null,the function will return the
number of bytes left in the destination string,
including the null terminator
dwFlags - controls some details of the string copy:
STRSAFE_FILL_BEHIND_NULL
if the function succeeds, the low byte of dwFlags will be
used to fill the uninitialize part of destination buffer
behind the null terminator
STRSAFE_IGNORE_NULLS
treat NULL string pointers like empty strings (TEXT("")).
this flag is useful for emulating functions like lstrcpy
STRSAFE_FILL_ON_FAILURE
if the function fails, the low byte of dwFlags will be
used to fill all of the destination buffer, and it will
be null terminated. This will overwrite any truncated
string returned when the failure is
STRSAFE_E_INSUFFICIENT_BUFFER
STRSAFE_NO_TRUNCATION /
STRSAFE_NULL_ON_FAILURE
if the function fails, the destination buffer will be set
to the empty string. This will overwrite any truncated string
returned when the failure is STRSAFE_E_INSUFFICIENT_BUFFER.
Notes:
Behavior is undefined if source and destination strings overlap.
pszDest and pszSrc should not be NULL unless the STRSAFE_IGNORE_NULLS flag
is specified. If STRSAFE_IGNORE_NULLS is passed, both pszDest and pszSrc
may be NULL. An error may still be returned even though NULLS are ignored
due to insufficient space.
Return Value:
S_OK - if there was source data and it was all copied and the
resultant dest string was null terminated
failure - you can use the macro HRESULT_CODE() to get a win32
error code for all hresult failure cases
STRSAFE_E_INSUFFICIENT_BUFFER /
HRESULT_CODE(hr) == ERROR_INSUFFICIENT_BUFFER
- this return value is an indication that the copy
operation failed due to insufficient space. When this
error occurs, the destination buffer is modified to
contain a truncated version of the ideal result and is
null terminated. This is useful for situations where
truncation is ok.
It is strongly recommended to use the SUCCEEDED() / FAILED() macros to test the
return value of this function
--*/
STRSAFEAPI StringCbCopyNExA(char* pszDest, size_t cbDest, const char* pszSrc, size_t cbSrc, char** ppszDestEnd, size_t* pcbRemaining, unsigned long dwFlags);
STRSAFEAPI StringCbCopyNExW(wchar_t* pszDest, size_t cbDest, const wchar_t* pszSrc, size_t cbSrc, wchar_t** ppszDestEnd, size_t* pcbRemaining, unsigned long dwFlags);
// end_strsafe end_ntstrsafe
// begin_strsafe
#ifdef UNICODE
#define StringCbCopyNEx StringCbCopyNExW
#else
#define StringCbCopyNEx StringCbCopyNExA
#endif // !UNICODE
// end_strsafe
// begin_strsafe begin_ntstrsafe
#ifdef STRSAFE_INLINE
STRSAFEAPI StringCbCopyNExA(char* pszDest, size_t cbDest, const char* pszSrc, size_t cbSrc, char** ppszDestEnd, size_t* pcbRemaining, unsigned long dwFlags)
{
HRESULT hr;
size_t cchDest;
size_t cchSrc;
size_t cchRemaining = 0;
cchDest = cbDest / sizeof(char);
cchSrc = cbSrc / sizeof(char);
if ((cchDest > STRSAFE_MAX_CCH) ||
(cchSrc > STRSAFE_MAX_CCH))
{
hr = STRSAFE_E_INVALID_PARAMETER;
}
else
{
hr = StringCopyNExWorkerA(pszDest, cchDest, cbDest, pszSrc, cchSrc, ppszDestEnd, &cchRemaining, dwFlags);
}
if (SUCCEEDED(hr) || (hr == STRSAFE_E_INSUFFICIENT_BUFFER))
{
if (pcbRemaining)
{
// safe to multiply cchRemaining * sizeof(char) since cchRemaining < STRSAFE_MAX_CCH and sizeof(char) is 1
*pcbRemaining = (cchRemaining * sizeof(char)) + (cbDest % sizeof(char));
}
}
return hr;
}
STRSAFEAPI StringCbCopyNExW(wchar_t* pszDest, size_t cbDest, const wchar_t* pszSrc, size_t cbSrc, wchar_t** ppszDestEnd, size_t* pcbRemaining, unsigned long dwFlags)
{
HRESULT hr;
size_t cchDest;
size_t cchSrc;
size_t cchRemaining = 0;
cchDest = cbDest / sizeof(wchar_t);
cchSrc = cbSrc / sizeof(wchar_t);
if ((cchDest > STRSAFE_MAX_CCH) ||
(cchSrc > STRSAFE_MAX_CCH))
{
hr = STRSAFE_E_INVALID_PARAMETER;
}
else
{
hr = StringCopyNExWorkerW(pszDest, cchDest, cbDest, pszSrc, cchSrc, ppszDestEnd, &cchRemaining, dwFlags);
}
if (SUCCEEDED(hr) || (hr == STRSAFE_E_INSUFFICIENT_BUFFER))
{
if (pcbRemaining)
{
// safe to multiply cchRemaining * sizeof(wchar_t) since cchRemaining < STRSAFE_MAX_CCH and sizeof(wchar_t) is 2
*pcbRemaining = (cchRemaining * sizeof(wchar_t)) + (cbDest % sizeof(wchar_t));
}
}
return hr;
}
#endif // STRSAFE_INLINE
#endif // !STRSAFE_NO_CB_FUNCTIONS
#ifndef STRSAFE_NO_CCH_FUNCTIONS
/*++
STDAPI
StringCchCat(
IN OUT LPTSTR pszDest,
IN size_t cchDest,
IN LPCTSTR pszSrc
);
Routine Description:
This routine is a safer version of the C built-in function 'strcat'.
The size of the destination buffer (in characters) is a parameter and this
function will not write past the end of this buffer and it will ALWAYS
null terminate the destination buffer (unless it is zero length).
This function returns a hresult, and not a pointer. It returns
S_OK if the string was concatenated without truncation and null terminated,
otherwise it will return a failure code. In failure cases as much of pszSrc
will be appended to pszDest as possible, and pszDest will be null
terminated.
Arguments:
pszDest - destination string which must be null terminated
cchDest - size of destination buffer in characters.
length must be = (_tcslen(pszDest) + _tcslen(pszSrc) + 1)
to hold all of the combine string plus the null
terminator
pszSrc - source string which must be null terminated
Notes:
Behavior is undefined if source and destination strings overlap.
pszDest and pszSrc should not be NULL. See StringCchCatEx if you require
the handling of NULL values.
Return Value:
S_OK - if there was source data and it was all concatenated and
the resultant dest string was null terminated
failure - you can use the macro HRESULT_CODE() to get a win32
error code for all hresult failure cases
STRSAFE_E_INSUFFICIENT_BUFFER /
HRESULT_CODE(hr) == ERROR_INSUFFICIENT_BUFFER
- this return value is an indication that the operation
failed due to insufficient space. When this error occurs,
the destination buffer is modified to contain a truncated
version of the ideal result and is null terminated. This
is useful for situations where truncation is ok.
It is strongly recommended to use the SUCCEEDED() / FAILED() macros to test the
return value of this function
--*/
STRSAFEAPI StringCchCatA(char* pszDest, size_t cchDest, const char* pszSrc);
STRSAFEAPI StringCchCatW(wchar_t* pszDest, size_t cchDest, const wchar_t* pszSrc);
// end_strsafe end_ntstrsafe
// begin_strsafe
#ifdef UNICODE
#define StringCchCat StringCchCatW
#else
#define StringCchCat StringCchCatA
#endif // !UNICODE
// end_strsafe
// begin_strsafe begin_ntstrsafe
#ifdef STRSAFE_INLINE
STRSAFEAPI StringCchCatA(char* pszDest, size_t cchDest, const char* pszSrc)
{
HRESULT hr;
if (cchDest > STRSAFE_MAX_CCH)
{
hr = STRSAFE_E_INVALID_PARAMETER;
}
else
{
hr = StringCatWorkerA(pszDest, cchDest, pszSrc);
}
return hr;
}
STRSAFEAPI StringCchCatW(wchar_t* pszDest, size_t cchDest, const wchar_t* pszSrc)
{
HRESULT hr;
if (cchDest > STRSAFE_MAX_CCH)
{
hr = STRSAFE_E_INVALID_PARAMETER;
}
else
{
hr = StringCatWorkerW(pszDest, cchDest, pszSrc);
}
return hr;
}
#endif // STRSAFE_INLINE
#endif // !STRSAFE_NO_CCH_FUNCTIONS
#ifndef STRSAFE_NO_CB_FUNCTIONS
/*++
STDAPI
StringCbCat(
IN OUT LPTSTR pszDest,
IN size_t cbDest,
IN LPCTSTR pszSrc
);
Routine Description:
This routine is a safer version of the C built-in function 'strcat'.
The size of the destination buffer (in bytes) is a parameter and this
function will not write past the end of this buffer and it will ALWAYS
null terminate the destination buffer (unless it is zero length).
This function returns a hresult, and not a pointer. It returns
S_OK if the string was concatenated without truncation and null terminated,
otherwise it will return a failure code. In failure cases as much of pszSrc
will be appended to pszDest as possible, and pszDest will be null
terminated.
Arguments:
pszDest - destination string which must be null terminated
cbDest - size of destination buffer in bytes.
length must be = ((_tcslen(pszDest) + _tcslen(pszSrc) + 1) * sizeof(TCHAR)
to hold all of the combine string plus the null
terminator
pszSrc - source string which must be null terminated
Notes:
Behavior is undefined if source and destination strings overlap.
pszDest and pszSrc should not be NULL. See StringCbCatEx if you require
the handling of NULL values.
Return Value:
S_OK - if there was source data and it was all concatenated and
the resultant dest string was null terminated
failure - you can use the macro HRESULT_CODE() to get a win32
error code for all hresult failure cases
STRSAFE_E_INSUFFICIENT_BUFFER /
HRESULT_CODE(hr) == ERROR_INSUFFICIENT_BUFFER
- this return value is an indication that the operation
failed due to insufficient space. When this error occurs,
the destination buffer is modified to contain a truncated
version of the ideal result and is null terminated. This
is useful for situations where truncation is ok.
It is strongly recommended to use the SUCCEEDED() / FAILED() macros to test the
return value of this function
--*/
STRSAFEAPI StringCbCatA(char* pszDest, size_t cbDest, const char* pszSrc);
STRSAFEAPI StringCbCatW(wchar_t* pszDest, size_t cbDest, const wchar_t* pszSrc);
// end_strsafe end_ntstrsafe
// begin_strsafe
#ifdef UNICODE
#define StringCbCat StringCbCatW
#else
#define StringCbCat StringCbCatA
#endif // !UNICODE
// end_strsafe
// begin_strsafe begin_ntstrsafe
#ifdef STRSAFE_INLINE
STRSAFEAPI StringCbCatA(char* pszDest, size_t cbDest, const char* pszSrc)
{
HRESULT hr;
size_t cchDest;
cchDest = cbDest / sizeof(char);
if (cchDest > STRSAFE_MAX_CCH)
{
hr = STRSAFE_E_INVALID_PARAMETER;
}
else
{
hr = StringCatWorkerA(pszDest, cchDest, pszSrc);
}
return hr;
}
STRSAFEAPI StringCbCatW(wchar_t* pszDest, size_t cbDest, const wchar_t* pszSrc)
{
HRESULT hr;
size_t cchDest;
cchDest = cbDest / sizeof(wchar_t);
if (cchDest > STRSAFE_MAX_CCH)
{
hr = STRSAFE_E_INVALID_PARAMETER;
}
else
{
hr = StringCatWorkerW(pszDest, cchDest, pszSrc);
}
return hr;
}
#endif // STRSAFE_INLINE
#endif // !STRSAFE_NO_CB_FUNCTIONS
#ifndef STRSAFE_NO_CCH_FUNCTIONS
/*++
STDAPI
StringCchCatEx(
IN OUT LPTSTR pszDest OPTIONAL,
IN size_t cchDest,
IN LPCTSTR pszSrc OPTIONAL,
OUT LPTSTR* ppszDestEnd OPTIONAL,
OUT size_t* pcchRemaining OPTIONAL,
IN DWORD dwFlags
);
Routine Description:
This routine is a safer version of the C built-in function 'strcat' with
some additional parameters. In addition to functionality provided by
StringCchCat, this routine also returns a pointer to the end of the
destination string and the number of characters left in the destination string
including the null terminator. The flags parameter allows additional controls.
Arguments:
pszDest - destination string which must be null terminated
cchDest - size of destination buffer in characters
length must be (_tcslen(pszDest) + _tcslen(pszSrc) + 1)
to hold all of the combine string plus the null
terminator.
pszSrc - source string which must be null terminated
ppszDestEnd - if ppszDestEnd is non-null, the function will return a
pointer to the end of the destination string. If the
function appended any data, the result will point to the
null termination character
pcchRemaining - if pcchRemaining is non-null, the function will return the
number of characters left in the destination string,
including the null terminator
dwFlags - controls some details of the string copy:
STRSAFE_FILL_BEHIND_NULL
if the function succeeds, the low byte of dwFlags will be
used to fill the uninitialize part of destination buffer
behind the null terminator
STRSAFE_IGNORE_NULLS
treat NULL string pointers like empty strings (TEXT("")).
this flag is useful for emulating functions like lstrcat
STRSAFE_FILL_ON_FAILURE
if the function fails, the low byte of dwFlags will be
used to fill all of the destination buffer, and it will
be null terminated. This will overwrite any pre-existing
or truncated string
STRSAFE_NULL_ON_FAILURE
if the function fails, the destination buffer will be set
to the empty string. This will overwrite any pre-existing or
truncated string
STRSAFE_NO_TRUNCATION
if the function returns STRSAFE_E_INSUFFICIENT_BUFFER, pszDest
will not contain a truncated string, it will remain unchanged.
Notes:
Behavior is undefined if source and destination strings overlap.
pszDest and pszSrc should not be NULL unless the STRSAFE_IGNORE_NULLS flag
is specified. If STRSAFE_IGNORE_NULLS is passed, both pszDest and pszSrc
may be NULL. An error may still be returned even though NULLS are ignored
due to insufficient space.
Return Value:
S_OK - if there was source data and it was all concatenated and
the resultant dest string was null terminated
failure - you can use the macro HRESULT_CODE() to get a win32
error code for all hresult failure cases
STRSAFE_E_INSUFFICIENT_BUFFER /
HRESULT_CODE(hr) == ERROR_INSUFFICIENT_BUFFER
- this return value is an indication that the operation
failed due to insufficient space. When this error
occurs, the destination buffer is modified to contain
a truncated version of the ideal result and is null
terminated. This is useful for situations where
truncation is ok.
It is strongly recommended to use the SUCCEEDED() / FAILED() macros to test the
return value of this function
--*/
STRSAFEAPI StringCchCatExA(char* pszDest, size_t cchDest, const char* pszSrc, char** ppszDestEnd, size_t* pcchRemaining, unsigned long dwFlags);
STRSAFEAPI StringCchCatExW(wchar_t* pszDest, size_t cchDest, const wchar_t* pszSrc, wchar_t** ppszDestEnd, size_t* pcchRemaining, unsigned long dwFlags);
// end_strsafe end_ntstrsafe
// begin_strsafe
#ifdef UNICODE
#define StringCchCatEx StringCchCatExW
#else
#define StringCchCatEx StringCchCatExA
#endif // !UNICODE
// end_strsafe
// begin_strsafe begin_ntstrsafe
#ifdef STRSAFE_INLINE
STRSAFEAPI StringCchCatExA(char* pszDest, size_t cchDest, const char* pszSrc, char** ppszDestEnd, size_t* pcchRemaining, unsigned long dwFlags)
{
HRESULT hr;
if (cchDest > STRSAFE_MAX_CCH)
{
hr = STRSAFE_E_INVALID_PARAMETER;
}
else
{
size_t cbDest;
// safe to multiply cchDest * sizeof(char) since cchDest < STRSAFE_MAX_CCH and sizeof(char) is 1
cbDest = cchDest * sizeof(char);
hr = StringCatExWorkerA(pszDest, cchDest, cbDest, pszSrc, ppszDestEnd, pcchRemaining, dwFlags);
}
return hr;
}
STRSAFEAPI StringCchCatExW(wchar_t* pszDest, size_t cchDest, const wchar_t* pszSrc, wchar_t** ppszDestEnd, size_t* pcchRemaining, unsigned long dwFlags)
{
HRESULT hr;
if (cchDest > STRSAFE_MAX_CCH)
{
hr = STRSAFE_E_INVALID_PARAMETER;
}
else
{
size_t cbDest;
// safe to multiply cchDest * sizeof(wchar_t) since cchDest < STRSAFE_MAX_CCH and sizeof(wchar_t) is 2
cbDest = cchDest * sizeof(wchar_t);
hr = StringCatExWorkerW(pszDest, cchDest, cbDest, pszSrc, ppszDestEnd, pcchRemaining, dwFlags);
}
return hr;
}
#endif // STRSAFE_INLINE
#endif // !STRSAFE_NO_CCH_FUNCTIONS
#ifndef STRSAFE_NO_CB_FUNCTIONS
/*++
STDAPI
StringCbCatEx(
IN OUT LPTSTR pszDest OPTIONAL,
IN size_t cbDest,
IN LPCTSTR pszSrc OPTIONAL,
OUT LPTSTR* ppszDestEnd OPTIONAL,
OUT size_t* pcbRemaining OPTIONAL,
IN DWORD dwFlags
);
Routine Description:
This routine is a safer version of the C built-in function 'strcat' with
some additional parameters. In addition to functionality provided by
StringCbCat, this routine also returns a pointer to the end of the
destination string and the number of bytes left in the destination string
including the null terminator. The flags parameter allows additional controls.
Arguments:
pszDest - destination string which must be null terminated
cbDest - size of destination buffer in bytes.
length must be ((_tcslen(pszDest) + _tcslen(pszSrc) + 1) * sizeof(TCHAR)
to hold all of the combine string plus the null
terminator.
pszSrc - source string which must be null terminated
ppszDestEnd - if ppszDestEnd is non-null, the function will return a
pointer to the end of the destination string. If the
function appended any data, the result will point to the
null termination character
pcbRemaining - if pcbRemaining is non-null, the function will return
the number of bytes left in the destination string,
including the null terminator
dwFlags - controls some details of the string copy:
STRSAFE_FILL_BEHIND_NULL
if the function succeeds, the low byte of dwFlags will be
used to fill the uninitialize part of destination buffer
behind the null terminator
STRSAFE_IGNORE_NULLS
treat NULL string pointers like empty strings (TEXT("")).
this flag is useful for emulating functions like lstrcat
STRSAFE_FILL_ON_FAILURE
if the function fails, the low byte of dwFlags will be
used to fill all of the destination buffer, and it will
be null terminated. This will overwrite any pre-existing
or truncated string
STRSAFE_NULL_ON_FAILURE
if the function fails, the destination buffer will be set
to the empty string. This will overwrite any pre-existing or
truncated string
STRSAFE_NO_TRUNCATION
if the function returns STRSAFE_E_INSUFFICIENT_BUFFER, pszDest
will not contain a truncated string, it will remain unchanged.
Notes:
Behavior is undefined if source and destination strings overlap.
pszDest and pszSrc should not be NULL unless the STRSAFE_IGNORE_NULLS flag
is specified. If STRSAFE_IGNORE_NULLS is passed, both pszDest and pszSrc
may be NULL. An error may still be returned even though NULLS are ignored
due to insufficient space.
Return Value:
S_OK - if there was source data and it was all concatenated
and the resultant dest string was null terminated
failure - you can use the macro HRESULT_CODE() to get a win32
error code for all hresult failure cases
STRSAFE_E_INSUFFICIENT_BUFFER /
HRESULT_CODE(hr) == ERROR_INSUFFICIENT_BUFFER
- this return value is an indication that the operation
failed due to insufficient space. When this error
occurs, the destination buffer is modified to contain
a truncated version of the ideal result and is null
terminated. This is useful for situations where
truncation is ok.
It is strongly recommended to use the SUCCEEDED() / FAILED() macros to test the
return value of this function
--*/
STRSAFEAPI StringCbCatExA(char* pszDest, size_t cbDest, const char* pszSrc, char** ppszDestEnd, size_t* pcbRemaining, unsigned long dwFlags);
STRSAFEAPI StringCbCatExW(wchar_t* pszDest, size_t cbDest, const wchar_t* pszSrc, wchar_t** ppszDestEnd, size_t* pcbRemaining, unsigned long dwFlags);
// end_strsafe end_ntstrsafe
// begin_strsafe
#ifdef UNICODE
#define StringCbCatEx StringCbCatExW
#else
#define StringCbCatEx StringCbCatExA
#endif // !UNICODE
// end_strsafe
// begin_strsafe begin_ntstrsafe
#ifdef STRSAFE_INLINE
STRSAFEAPI StringCbCatExA(char* pszDest, size_t cbDest, const char* pszSrc, char** ppszDestEnd, size_t* pcbRemaining, unsigned long dwFlags)
{
HRESULT hr;
size_t cchDest;
size_t cchRemaining = 0;
cchDest = cbDest / sizeof(char);
if (cchDest > STRSAFE_MAX_CCH)
{
hr = STRSAFE_E_INVALID_PARAMETER;
}
else
{
hr = StringCatExWorkerA(pszDest, cchDest, cbDest, pszSrc, ppszDestEnd, &cchRemaining, dwFlags);
}
if (SUCCEEDED(hr) || (hr == STRSAFE_E_INSUFFICIENT_BUFFER))
{
if (pcbRemaining)
{
// safe to multiply cchRemaining * sizeof(char) since cchRemaining < STRSAFE_MAX_CCH and sizeof(char) is 1
*pcbRemaining = (cchRemaining * sizeof(char)) + (cbDest % sizeof(char));
}
}
return hr;
}
STRSAFEAPI StringCbCatExW(wchar_t* pszDest, size_t cbDest, const wchar_t* pszSrc, wchar_t** ppszDestEnd, size_t* pcbRemaining, unsigned long dwFlags)
{
HRESULT hr;
size_t cchDest;
size_t cchRemaining = 0;
cchDest = cbDest / sizeof(wchar_t);
if (cchDest > STRSAFE_MAX_CCH)
{
hr = STRSAFE_E_INVALID_PARAMETER;
}
else
{
hr = StringCatExWorkerW(pszDest, cchDest, cbDest, pszSrc, ppszDestEnd, &cchRemaining, dwFlags);
}
if (SUCCEEDED(hr) || (hr == STRSAFE_E_INSUFFICIENT_BUFFER))
{
if (pcbRemaining)
{
// safe to multiply cchRemaining * sizeof(wchar_t) since cchRemaining < STRSAFE_MAX_CCH and sizeof(wchar_t) is 2
*pcbRemaining = (cchRemaining * sizeof(wchar_t)) + (cbDest % sizeof(wchar_t));
}
}
return hr;
}
#endif // STRSAFE_INLINE
#endif // !STRSAFE_NO_CB_FUNCTIONS
#ifndef STRSAFE_NO_CCH_FUNCTIONS
/*++
STDAPI
StringCchCatN(
IN OUT LPTSTR pszDest,
IN size_t cchDest,
IN LPCTSTR pszSrc,
IN size_t cchMaxAppend
);
Routine Description:
This routine is a safer version of the C built-in function 'strncat'.
The size of the destination buffer (in characters) is a parameter as well as
the maximum number of characters to append, excluding the null terminator.
This function will not write past the end of the destination buffer and it will
ALWAYS null terminate pszDest (unless it is zero length).
This function returns a hresult, and not a pointer. It returns
S_OK if all of pszSrc or the first cchMaxAppend characters were appended
to the destination string and it was null terminated, otherwise it will
return a failure code. In failure cases as much of pszSrc will be appended
to pszDest as possible, and pszDest will be null terminated.
Arguments:
pszDest - destination string which must be null terminated
cchDest - size of destination buffer in characters.
length must be (_tcslen(pszDest) + min(cchMaxAppend, _tcslen(pszSrc)) + 1)
to hold all of the combine string plus the null
terminator.
pszSrc - source string
cchMaxAppend - maximum number of characters to append
Notes:
Behavior is undefined if source and destination strings overlap.
pszDest and pszSrc should not be NULL. See StringCchCatNEx if you require
the handling of NULL values.
Return Value:
S_OK - if all of pszSrc or the first cchMaxAppend characters
were concatenated to pszDest and the resultant dest
string was null terminated
failure - you can use the macro HRESULT_CODE() to get a win32
error code for all hresult failure cases
STRSAFE_E_INSUFFICIENT_BUFFER /
HRESULT_CODE(hr) == ERROR_INSUFFICIENT_BUFFER
- this return value is an indication that the operation
failed due to insufficient space. When this error
occurs, the destination buffer is modified to contain
a truncated version of the ideal result and is null
terminated. This is useful for situations where
truncation is ok.
It is strongly recommended to use the SUCCEEDED() / FAILED() macros to test the
return value of this function
--*/
STRSAFEAPI StringCchCatNA(char* pszDest, size_t cchDest, const char* pszSrc, size_t cchMaxAppend);
STRSAFEAPI StringCchCatNW(wchar_t* pszDest, size_t cchDest, const wchar_t* pszSrc, size_t cchMaxAppend);
// end_strsafe end_ntstrsafe
// begin_strsafe
#ifdef UNICODE
#define StringCchCatN StringCchCatNW
#else
#define StringCchCatN StringCchCatNA
#endif // !UNICODE
// end_strsafe
// begin_strsafe begin_ntstrsafe
#ifdef STRSAFE_INLINE
STRSAFEAPI StringCchCatNA(char* pszDest, size_t cchDest, const char* pszSrc, size_t cchMaxAppend)
{
HRESULT hr;
if (cchDest > STRSAFE_MAX_CCH)
{
hr = STRSAFE_E_INVALID_PARAMETER;
}
else
{
hr = StringCatNWorkerA(pszDest, cchDest, pszSrc, cchMaxAppend);
}
return hr;
}
STRSAFEAPI StringCchCatNW(wchar_t* pszDest, size_t cchDest, const wchar_t* pszSrc, size_t cchMaxAppend)
{
HRESULT hr;
if (cchDest > STRSAFE_MAX_CCH)
{
hr = STRSAFE_E_INVALID_PARAMETER;
}
else
{
hr = StringCatNWorkerW(pszDest, cchDest, pszSrc, cchMaxAppend);
}
return hr;
}
#endif // STRSAFE_INLINE
#endif // !STRSAFE_NO_CCH_FUNCTIONS
#ifndef STRSAFE_NO_CB_FUNCTIONS
/*++
STDAPI
StringCbCatN(
IN OUT LPTSTR pszDest,
IN size_t cbDest,
IN LPCTSTR pszSrc,
IN size_t cbMaxAppend
);
Routine Description:
This routine is a safer version of the C built-in function 'strncat'.
The size of the destination buffer (in bytes) is a parameter as well as
the maximum number of bytes to append, excluding the null terminator.
This function will not write past the end of the destination buffer and it will
ALWAYS null terminate pszDest (unless it is zero length).
This function returns a hresult, and not a pointer. It returns
S_OK if all of pszSrc or the first cbMaxAppend bytes were appended
to the destination string and it was null terminated, otherwise it will
return a failure code. In failure cases as much of pszSrc will be appended
to pszDest as possible, and pszDest will be null terminated.
Arguments:
pszDest - destination string which must be null terminated
cbDest - size of destination buffer in bytes.
length must be ((_tcslen(pszDest) + min(cbMaxAppend / sizeof(TCHAR), _tcslen(pszSrc)) + 1) * sizeof(TCHAR)
to hold all of the combine string plus the null
terminator.
pszSrc - source string
cbMaxAppend - maximum number of bytes to append
Notes:
Behavior is undefined if source and destination strings overlap.
pszDest and pszSrc should not be NULL. See StringCbCatNEx if you require
the handling of NULL values.
Return Value:
S_OK - if all of pszSrc or the first cbMaxAppend bytes were
concatenated to pszDest and the resultant dest string
was null terminated
failure - you can use the macro HRESULT_CODE() to get a win32
error code for all hresult failure cases
STRSAFE_E_INSUFFICIENT_BUFFER /
HRESULT_CODE(hr) == ERROR_INSUFFICIENT_BUFFER
- this return value is an indication that the operation
failed due to insufficient space. When this error
occurs, the destination buffer is modified to contain
a truncated version of the ideal result and is null
terminated. This is useful for situations where
truncation is ok.
It is strongly recommended to use the SUCCEEDED() / FAILED() macros to test the
return value of this function
--*/
STRSAFEAPI StringCbCatNA(char* pszDest, size_t cbDest, const char* pszSrc, size_t cbMaxAppend);
STRSAFEAPI StringCbCatNW(wchar_t* pszDest, size_t cbDest, const wchar_t* pszSrc, size_t cbMaxAppend);
// end_strsafe end_ntstrsafe
// begin_strsafe
#ifdef UNICODE
#define StringCbCatN StringCbCatNW
#else
#define StringCbCatN StringCbCatNA
#endif // !UNICODE
// end_strsafe
// begin_strsafe begin_ntstrsafe
#ifdef STRSAFE_INLINE
STRSAFEAPI StringCbCatNA(char* pszDest, size_t cbDest, const char* pszSrc, size_t cbMaxAppend)
{
HRESULT hr;
size_t cchDest;
cchDest = cbDest / sizeof(char);
if (cchDest > STRSAFE_MAX_CCH)
{
hr = STRSAFE_E_INVALID_PARAMETER;
}
else
{
size_t cchMaxAppend;
cchMaxAppend = cbMaxAppend / sizeof(char);
hr = StringCatNWorkerA(pszDest, cchDest, pszSrc, cchMaxAppend);
}
return hr;
}
STRSAFEAPI StringCbCatNW(wchar_t* pszDest, size_t cbDest, const wchar_t* pszSrc, size_t cbMaxAppend)
{
HRESULT hr;
size_t cchDest;
cchDest = cbDest / sizeof(wchar_t);
if (cchDest > STRSAFE_MAX_CCH)
{
hr = STRSAFE_E_INVALID_PARAMETER;
}
else
{
size_t cchMaxAppend;
cchMaxAppend = cbMaxAppend / sizeof(wchar_t);
hr = StringCatNWorkerW(pszDest, cchDest, pszSrc, cchMaxAppend);
}
return hr;
}
#endif // STRSAFE_INLINE
#endif // !STRSAFE_NO_CB_FUNCTIONS
#ifndef STRSAFE_NO_CCH_FUNCTIONS
/*++
STDAPI
StringCchCatNEx(
IN OUT LPTSTR pszDest OPTIONAL,
IN size_t cchDest,
IN LPCTSTR pszSrc OPTIONAL,
IN size_t cchMaxAppend,
OUT LPTSTR* ppszDestEnd OPTIONAL,
OUT size_t* pcchRemaining OPTIONAL,
IN DWORD dwFlags
);
Routine Description:
This routine is a safer version of the C built-in function 'strncat', with
some additional parameters. In addition to functionality provided by
StringCchCatN, this routine also returns a pointer to the end of the
destination string and the number of characters left in the destination string
including the null terminator. The flags parameter allows additional controls.
Arguments:
pszDest - destination string which must be null terminated
cchDest - size of destination buffer in characters.
length must be (_tcslen(pszDest) + min(cchMaxAppend, _tcslen(pszSrc)) + 1)
to hold all of the combine string plus the null
terminator.
pszSrc - source string
cchMaxAppend - maximum number of characters to append
ppszDestEnd - if ppszDestEnd is non-null, the function will return a
pointer to the end of the destination string. If the
function appended any data, the result will point to the
null termination character
pcchRemaining - if pcchRemaining is non-null, the function will return the
number of characters left in the destination string,
including the null terminator
dwFlags - controls some details of the string copy:
STRSAFE_FILL_BEHIND_NULL
if the function succeeds, the low byte of dwFlags will be
used to fill the uninitialize part of destination buffer
behind the null terminator
STRSAFE_IGNORE_NULLS
treat NULL string pointers like empty strings (TEXT(""))
STRSAFE_FILL_ON_FAILURE
if the function fails, the low byte of dwFlags will be
used to fill all of the destination buffer, and it will
be null terminated. This will overwrite any pre-existing
or truncated string
STRSAFE_NULL_ON_FAILURE
if the function fails, the destination buffer will be set
to the empty string. This will overwrite any pre-existing or
truncated string
STRSAFE_NO_TRUNCATION
if the function returns STRSAFE_E_INSUFFICIENT_BUFFER, pszDest
will not contain a truncated string, it will remain unchanged.
Notes:
Behavior is undefined if source and destination strings overlap.
pszDest and pszSrc should not be NULL unless the STRSAFE_IGNORE_NULLS flag
is specified. If STRSAFE_IGNORE_NULLS is passed, both pszDest and pszSrc
may be NULL. An error may still be returned even though NULLS are ignored
due to insufficient space.
Return Value:
S_OK - if all of pszSrc or the first cchMaxAppend characters
were concatenated to pszDest and the resultant dest
string was null terminated
failure - you can use the macro HRESULT_CODE() to get a win32
error code for all hresult failure cases
STRSAFE_E_INSUFFICIENT_BUFFER /
HRESULT_CODE(hr) == ERROR_INSUFFICIENT_BUFFER
- this return value is an indication that the operation
failed due to insufficient space. When this error
occurs, the destination buffer is modified to contain
a truncated version of the ideal result and is null
terminated. This is useful for situations where
truncation is ok.
It is strongly recommended to use the SUCCEEDED() / FAILED() macros to test the
return value of this function
--*/
STRSAFEAPI StringCchCatNExA(char* pszDest, size_t cchDest, const char* pszSrc, size_t cchMaxAppend, char** ppszDestEnd, size_t* pcchRemaining, unsigned long dwFlags);
STRSAFEAPI StringCchCatNExW(wchar_t* pszDest, size_t cchDest, const wchar_t* pszSrc, size_t cchMaxAppend, wchar_t** ppszDestEnd, size_t* pcchRemaining, unsigned long dwFlags);
// end_strsafe end_ntstrsafe
// begin_strsafe
#ifdef UNICODE
#define StringCchCatNEx StringCchCatNExW
#else
#define StringCchCatNEx StringCchCatNExA
#endif // !UNICODE
// end_strsafe
// begin_strsafe begin_ntstrsafe
#ifdef STRSAFE_INLINE
STRSAFEAPI StringCchCatNExA(char* pszDest, size_t cchDest, const char* pszSrc, size_t cchMaxAppend, char** ppszDestEnd, size_t* pcchRemaining, unsigned long dwFlags)
{
HRESULT hr;
if (cchDest > STRSAFE_MAX_CCH)
{
hr = STRSAFE_E_INVALID_PARAMETER;
}
else
{
size_t cbDest;
// safe to multiply cchDest * sizeof(char) since cchDest < STRSAFE_MAX_CCH and sizeof(char) is 1
cbDest = cchDest * sizeof(char);
hr = StringCatNExWorkerA(pszDest, cchDest, cbDest, pszSrc, cchMaxAppend, ppszDestEnd, pcchRemaining, dwFlags);
}
return hr;
}
STRSAFEAPI StringCchCatNExW(wchar_t* pszDest, size_t cchDest, const wchar_t* pszSrc, size_t cchMaxAppend, wchar_t** ppszDestEnd, size_t* pcchRemaining, unsigned long dwFlags)
{
HRESULT hr;
if (cchDest > STRSAFE_MAX_CCH)
{
hr = STRSAFE_E_INVALID_PARAMETER;
}
else
{
size_t cbDest;
// safe to multiply cchDest * sizeof(wchar_t) since cchDest < STRSAFE_MAX_CCH and sizeof(wchar_t) is 2
cbDest = cchDest * sizeof(wchar_t);
hr = StringCatNExWorkerW(pszDest, cchDest, cbDest, pszSrc, cchMaxAppend, ppszDestEnd, pcchRemaining, dwFlags);
}
return hr;
}
#endif // STRSAFE_INLINE
#endif // !STRSAFE_NO_CCH_FUNCTIONS
#ifndef STRSAFE_NO_CB_FUNCTIONS
/*++
STDAPI
StringCbCatNEx(
IN OUT LPTSTR pszDest OPTIONAL,
IN size_t cbDest,
IN LPCTSTR pszSrc OPTIONAL,
IN size_t cbMaxAppend,
OUT LPTSTR* ppszDestEnd OPTIONAL,
OUT size_t* pcchRemaining OPTIONAL,
IN DWORD dwFlags
);
Routine Description:
This routine is a safer version of the C built-in function 'strncat', with
some additional parameters. In addition to functionality provided by
StringCbCatN, this routine also returns a pointer to the end of the
destination string and the number of bytes left in the destination string
including the null terminator. The flags parameter allows additional controls.
Arguments:
pszDest - destination string which must be null terminated
cbDest - size of destination buffer in bytes.
length must be ((_tcslen(pszDest) + min(cbMaxAppend / sizeof(TCHAR), _tcslen(pszSrc)) + 1) * sizeof(TCHAR)
to hold all of the combine string plus the null
terminator.
pszSrc - source string
cbMaxAppend - maximum number of bytes to append
ppszDestEnd - if ppszDestEnd is non-null, the function will return a
pointer to the end of the destination string. If the
function appended any data, the result will point to the
null termination character
pcbRemaining - if pcbRemaining is non-null, the function will return the
number of bytes left in the destination string,
including the null terminator
dwFlags - controls some details of the string copy:
STRSAFE_FILL_BEHIND_NULL
if the function succeeds, the low byte of dwFlags will be
used to fill the uninitialize part of destination buffer
behind the null terminator
STRSAFE_IGNORE_NULLS
treat NULL string pointers like empty strings (TEXT(""))
STRSAFE_FILL_ON_FAILURE
if the function fails, the low byte of dwFlags will be
used to fill all of the destination buffer, and it will
be null terminated. This will overwrite any pre-existing
or truncated string
STRSAFE_NULL_ON_FAILURE
if the function fails, the destination buffer will be set
to the empty string. This will overwrite any pre-existing or
truncated string
STRSAFE_NO_TRUNCATION
if the function returns STRSAFE_E_INSUFFICIENT_BUFFER, pszDest
will not contain a truncated string, it will remain unchanged.
Notes:
Behavior is undefined if source and destination strings overlap.
pszDest and pszSrc should not be NULL unless the STRSAFE_IGNORE_NULLS flag
is specified. If STRSAFE_IGNORE_NULLS is passed, both pszDest and pszSrc
may be NULL. An error may still be returned even though NULLS are ignored
due to insufficient space.
Return Value:
S_OK - if all of pszSrc or the first cbMaxAppend bytes were
concatenated to pszDest and the resultant dest string
was null terminated
failure - you can use the macro HRESULT_CODE() to get a win32
error code for all hresult failure cases
STRSAFE_E_INSUFFICIENT_BUFFER /
HRESULT_CODE(hr) == ERROR_INSUFFICIENT_BUFFER
- this return value is an indication that the operation
failed due to insufficient space. When this error
occurs, the destination buffer is modified to contain
a truncated version of the ideal result and is null
terminated. This is useful for situations where
truncation is ok.
It is strongly recommended to use the SUCCEEDED() / FAILED() macros to test the
return value of this function
--*/
STRSAFEAPI StringCbCatNExA(char* pszDest, size_t cbDest, const char* pszSrc, size_t cbMaxAppend, char** ppszDestEnd, size_t* pcbRemaining, unsigned long dwFlags);
STRSAFEAPI StringCbCatNExW(wchar_t* pszDest, size_t cbDest, const wchar_t* pszSrc, size_t cbMaxAppend, wchar_t** ppszDestEnd, size_t* pcbRemaining, unsigned long dwFlags);
// end_strsafe end_ntstrsafe
// begin_strsafe
#ifdef UNICODE
#define StringCbCatNEx StringCbCatNExW
#else
#define StringCbCatNEx StringCbCatNExA
#endif // !UNICODE
// end_strsafe
// begin_strsafe begin_ntstrsafe
#ifdef STRSAFE_INLINE
STRSAFEAPI StringCbCatNExA(char* pszDest, size_t cbDest, const char* pszSrc, size_t cbMaxAppend, char** ppszDestEnd, size_t* pcbRemaining, unsigned long dwFlags)
{
HRESULT hr;
size_t cchDest;
size_t cchRemaining = 0;
cchDest = cbDest / sizeof(char);
if (cchDest > STRSAFE_MAX_CCH)
{
hr = STRSAFE_E_INVALID_PARAMETER;
}
else
{
size_t cchMaxAppend;
cchMaxAppend = cbMaxAppend / sizeof(char);
hr = StringCatNExWorkerA(pszDest, cchDest, cbDest, pszSrc, cchMaxAppend, ppszDestEnd, &cchRemaining, dwFlags);
}
if (SUCCEEDED(hr) || (hr == STRSAFE_E_INSUFFICIENT_BUFFER))
{
if (pcbRemaining)
{
// safe to multiply cchRemaining * sizeof(char) since cchRemaining < STRSAFE_MAX_CCH and sizeof(char) is 1
*pcbRemaining = (cchRemaining * sizeof(char)) + (cbDest % sizeof(char));
}
}
return hr;
}
STRSAFEAPI StringCbCatNExW(wchar_t* pszDest, size_t cbDest, const wchar_t* pszSrc, size_t cbMaxAppend, wchar_t** ppszDestEnd, size_t* pcbRemaining, unsigned long dwFlags)
{
HRESULT hr;
size_t cchDest;
size_t cchRemaining = 0;
cchDest = cbDest / sizeof(wchar_t);
if (cchDest > STRSAFE_MAX_CCH)
{
hr = STRSAFE_E_INVALID_PARAMETER;
}
else
{
size_t cchMaxAppend;
cchMaxAppend = cbMaxAppend / sizeof(wchar_t);
hr = StringCatNExWorkerW(pszDest, cchDest, cbDest, pszSrc, cchMaxAppend, ppszDestEnd, &cchRemaining, dwFlags);
}
if (SUCCEEDED(hr) || (hr == STRSAFE_E_INSUFFICIENT_BUFFER))
{
if (pcbRemaining)
{
// safe to multiply cchRemaining * sizeof(wchar_t) since cchRemaining < STRSAFE_MAX_CCH and sizeof(wchar_t) is 2
*pcbRemaining = (cchRemaining * sizeof(wchar_t)) + (cbDest % sizeof(wchar_t));
}
}
return hr;
}
#endif // STRSAFE_INLINE
#endif // !STRSAFE_NO_CB_FUNCTIONS
#ifndef STRSAFE_NO_CCH_FUNCTIONS
/*++
STDAPI
StringCchVPrintf(
OUT LPTSTR pszDest,
IN size_t cchDest,
IN LPCTSTR pszFormat,
IN va_list argList
);
Routine Description:
This routine is a safer version of the C built-in function 'vsprintf'.
The size of the destination buffer (in characters) is a parameter and
this function will not write past the end of this buffer and it will
ALWAYS null terminate the destination buffer (unless it is zero length).
This function returns a hresult, and not a pointer. It returns
S_OK if the string was printed without truncation and null terminated,
otherwise it will return a failure code. In failure cases it will return
a truncated version of the ideal result.
Arguments:
pszDest - destination string
cchDest - size of destination buffer in characters
length must be sufficient to hold the resulting formatted
string, including the null terminator.
pszFormat - format string which must be null terminated
argList - va_list from the variable arguments according to the
stdarg.h convention
Notes:
Behavior is undefined if destination, format strings or any arguments
strings overlap.
pszDest and pszFormat should not be NULL. See StringCchVPrintfEx if you
require the handling of NULL values.
Return Value:
S_OK - if there was sufficient space in the dest buffer for
the resultant string and it was null terminated.
failure - you can use the macro HRESULT_CODE() to get a win32
error code for all hresult failure cases
STRSAFE_E_INSUFFICIENT_BUFFER /
HRESULT_CODE(hr) == ERROR_INSUFFICIENT_BUFFER
- this return value is an indication that the print
operation failed due to insufficient space. When this
error occurs, the destination buffer is modified to
contain a truncated version of the ideal result and is
null terminated. This is useful for situations where
truncation is ok.
It is strongly recommended to use the SUCCEEDED() / FAILED() macros to test the
return value of this function
--*/
STRSAFEAPI StringCchVPrintfA(char* pszDest, size_t cchDest, const char* pszFormat, va_list argList);
STRSAFEAPI StringCchVPrintfW(wchar_t* pszDest, size_t cchDest, const wchar_t* pszFormat, va_list argList);
// end_strsafe end_ntstrsafe
// begin_strsafe
#ifdef UNICODE
#define StringCchVPrintf StringCchVPrintfW
#else
#define StringCchVPrintf StringCchVPrintfA
#endif // !UNICODE
// end_strsafe
// begin_strsafe begin_ntstrsafe
#ifdef STRSAFE_INLINE
STRSAFEAPI StringCchVPrintfA(char* pszDest, size_t cchDest, const char* pszFormat, va_list argList)
{
HRESULT hr;
if (cchDest > STRSAFE_MAX_CCH)
{
hr = STRSAFE_E_INVALID_PARAMETER;
}
else
{
hr = StringVPrintfWorkerA(pszDest, cchDest, pszFormat, argList);
}
return hr;
}
STRSAFEAPI StringCchVPrintfW(wchar_t* pszDest, size_t cchDest, const wchar_t* pszFormat, va_list argList)
{
HRESULT hr;
if (cchDest > STRSAFE_MAX_CCH)
{
hr = STRSAFE_E_INVALID_PARAMETER;
}
else
{
hr = StringVPrintfWorkerW(pszDest, cchDest, pszFormat, argList);
}
return hr;
}
#endif // STRSAFE_INLINE
#endif // !STRSAFE_NO_CCH_FUNCTIONS
#ifndef STRSAFE_NO_CB_FUNCTIONS
/*++
STDAPI
StringCbVPrintf(
OUT LPTSTR pszDest,
IN size_t cbDest,
IN LPCTSTR pszFormat,
IN va_list argList
);
Routine Description:
This routine is a safer version of the C built-in function 'vsprintf'.
The size of the destination buffer (in bytes) is a parameter and
this function will not write past the end of this buffer and it will
ALWAYS null terminate the destination buffer (unless it is zero length).
This function returns a hresult, and not a pointer. It returns
S_OK if the string was printed without truncation and null terminated,
otherwise it will return a failure code. In failure cases it will return
a truncated version of the ideal result.
Arguments:
pszDest - destination string
cbDest - size of destination buffer in bytes
length must be sufficient to hold the resulting formatted
string, including the null terminator.
pszFormat - format string which must be null terminated
argList - va_list from the variable arguments according to the
stdarg.h convention
Notes:
Behavior is undefined if destination, format strings or any arguments
strings overlap.
pszDest and pszFormat should not be NULL. See StringCbVPrintfEx if you
require the handling of NULL values.
Return Value:
S_OK - if there was sufficient space in the dest buffer for
the resultant string and it was null terminated.
failure - you can use the macro HRESULT_CODE() to get a win32
error code for all hresult failure cases
STRSAFE_E_INSUFFICIENT_BUFFER /
HRESULT_CODE(hr) == ERROR_INSUFFICIENT_BUFFER
- this return value is an indication that the print
operation failed due to insufficient space. When this
error occurs, the destination buffer is modified to
contain a truncated version of the ideal result and is
null terminated. This is useful for situations where
truncation is ok.
It is strongly recommended to use the SUCCEEDED() / FAILED() macros to test the
return value of this function
--*/
STRSAFEAPI StringCbVPrintfA(char* pszDest, size_t cbDest, const char* pszFormat, va_list argList);
STRSAFEAPI StringCbVPrintfW(wchar_t* pszDest, size_t cbDest, const wchar_t* pszFormat, va_list argList);
// end_strsafe end_ntstrsafe
// begin_strsafe
#ifdef UNICODE
#define StringCbVPrintf StringCbVPrintfW
#else
#define StringCbVPrintf StringCbVPrintfA
#endif // !UNICODE
// end_strsafe
// begin_strsafe begin_ntstrsafe
#ifdef STRSAFE_INLINE
STRSAFEAPI StringCbVPrintfA(char* pszDest, size_t cbDest, const char* pszFormat, va_list argList)
{
HRESULT hr;
size_t cchDest;
cchDest = cbDest / sizeof(char);
if (cchDest > STRSAFE_MAX_CCH)
{
hr = STRSAFE_E_INVALID_PARAMETER;
}
else
{
hr = StringVPrintfWorkerA(pszDest, cchDest, pszFormat, argList);
}
return hr;
}
STRSAFEAPI StringCbVPrintfW(wchar_t* pszDest, size_t cbDest, const wchar_t* pszFormat, va_list argList)
{
HRESULT hr;
size_t cchDest;
cchDest = cbDest / sizeof(wchar_t);
if (cchDest > STRSAFE_MAX_CCH)
{
hr = STRSAFE_E_INVALID_PARAMETER;
}
else
{
hr = StringVPrintfWorkerW(pszDest, cchDest, pszFormat, argList);
}
return hr;
}
#endif // STRSAFE_INLINE
#endif // !STRSAFE_NO_CB_FUNCTIONS
#ifndef STRSAFE_NO_CCH_FUNCTIONS
/*++
STDAPI
StringCchPrintf(
OUT LPTSTR pszDest,
IN size_t cchDest,
IN LPCTSTR pszFormat,
...
);
Routine Description:
This routine is a safer version of the C built-in function 'sprintf'.
The size of the destination buffer (in characters) is a parameter and
this function will not write past the end of this buffer and it will
ALWAYS null terminate the destination buffer (unless it is zero length).
This function returns a hresult, and not a pointer. It returns
S_OK if the string was printed without truncation and null terminated,
otherwise it will return a failure code. In failure cases it will return
a truncated version of the ideal result.
Arguments:
pszDest - destination string
cchDest - size of destination buffer in characters
length must be sufficient to hold the resulting formatted
string, including the null terminator.
pszFormat - format string which must be null terminated
... - additional parameters to be formatted according to
the format string
Notes:
Behavior is undefined if destination, format strings or any arguments
strings overlap.
pszDest and pszFormat should not be NULL. See StringCchPrintfEx if you
require the handling of NULL values.
Return Value:
S_OK - if there was sufficient space in the dest buffer for
the resultant string and it was null terminated.
failure - you can use the macro HRESULT_CODE() to get a win32
error code for all hresult failure cases
STRSAFE_E_INSUFFICIENT_BUFFER /
HRESULT_CODE(hr) == ERROR_INSUFFICIENT_BUFFER
- this return value is an indication that the print
operation failed due to insufficient space. When this
error occurs, the destination buffer is modified to
contain a truncated version of the ideal result and is
null terminated. This is useful for situations where
truncation is ok.
It is strongly recommended to use the SUCCEEDED() / FAILED() macros to test the
return value of this function
--*/
STRSAFEAPI StringCchPrintfA(char* pszDest, size_t cchDest, const char* pszFormat, ...);
STRSAFEAPI StringCchPrintfW(wchar_t* pszDest, size_t cchDest, const wchar_t* pszFormat, ...);
// end_strsafe end_ntstrsafe
// begin_strsafe
#ifdef UNICODE
#define StringCchPrintf StringCchPrintfW
#else
#define StringCchPrintf StringCchPrintfA
#endif // !UNICODE
// end_strsafe
// begin_strsafe begin_ntstrsafe
#ifdef STRSAFE_INLINE
STRSAFEAPI StringCchPrintfA(char* pszDest, size_t cchDest, const char* pszFormat, ...)
{
HRESULT hr;
if (cchDest > STRSAFE_MAX_CCH)
{
hr = STRSAFE_E_INVALID_PARAMETER;
}
else
{
va_list argList;
va_start(argList, pszFormat);
hr = StringVPrintfWorkerA(pszDest, cchDest, pszFormat, argList);
va_end(argList);
}
return hr;
}
STRSAFEAPI StringCchPrintfW(wchar_t* pszDest, size_t cchDest, const wchar_t* pszFormat, ...)
{
HRESULT hr;
if (cchDest > STRSAFE_MAX_CCH)
{
hr = STRSAFE_E_INVALID_PARAMETER;
}
else
{
va_list argList;
va_start(argList, pszFormat);
hr = StringVPrintfWorkerW(pszDest, cchDest, pszFormat, argList);
va_end(argList);
}
return hr;
}
#endif // STRSAFE_INLINE
#endif // !STRSAFE_NO_CCH_FUNCTIONS
#ifndef STRSAFE_NO_CB_FUNCTIONS
/*++
STDAPI
StringCbPrintf(
OUT LPTSTR pszDest,
IN size_t cbDest,
IN LPCTSTR pszFormat,
...
);
Routine Description:
This routine is a safer version of the C built-in function 'sprintf'.
The size of the destination buffer (in bytes) is a parameter and
this function will not write past the end of this buffer and it will
ALWAYS null terminate the destination buffer (unless it is zero length).
This function returns a hresult, and not a pointer. It returns
S_OK if the string was printed without truncation and null terminated,
otherwise it will return a failure code. In failure cases it will return
a truncated version of the ideal result.
Arguments:
pszDest - destination string
cbDest - size of destination buffer in bytes
length must be sufficient to hold the resulting formatted
string, including the null terminator.
pszFormat - format string which must be null terminated
... - additional parameters to be formatted according to
the format string
Notes:
Behavior is undefined if destination, format strings or any arguments
strings overlap.
pszDest and pszFormat should not be NULL. See StringCbPrintfEx if you
require the handling of NULL values.
Return Value:
S_OK - if there was sufficient space in the dest buffer for
the resultant string and it was null terminated.
failure - you can use the macro HRESULT_CODE() to get a win32
error code for all hresult failure cases
STRSAFE_E_INSUFFICIENT_BUFFER /
HRESULT_CODE(hr) == ERROR_INSUFFICIENT_BUFFER
- this return value is an indication that the print
operation failed due to insufficient space. When this
error occurs, the destination buffer is modified to
contain a truncated version of the ideal result and is
null terminated. This is useful for situations where
truncation is ok.
It is strongly recommended to use the SUCCEEDED() / FAILED() macros to test the
return value of this function
--*/
STRSAFEAPI StringCbPrintfA(char* pszDest, size_t cbDest, const char* pszFormat, ...);
STRSAFEAPI StringCbPrintfW(wchar_t* pszDest, size_t cbDest, const wchar_t* pszFormat, ...);
// end_strsafe end_ntstrsafe
// begin_strsafe
#ifdef UNICODE
#define StringCbPrintf StringCbPrintfW
#else
#define StringCbPrintf StringCbPrintfA
#endif // !UNICODE
// end_strsafe
// begin_strsafe begin_ntstrsafe
#ifdef STRSAFE_INLINE
STRSAFEAPI StringCbPrintfA(char* pszDest, size_t cbDest, const char* pszFormat, ...)
{
HRESULT hr;
size_t cchDest;
cchDest = cbDest / sizeof(char);
if (cchDest > STRSAFE_MAX_CCH)
{
hr = STRSAFE_E_INVALID_PARAMETER;
}
else
{
va_list argList;
va_start(argList, pszFormat);
hr = StringVPrintfWorkerA(pszDest, cchDest, pszFormat, argList);
va_end(argList);
}
return hr;
}
STRSAFEAPI StringCbPrintfW(wchar_t* pszDest, size_t cbDest, const wchar_t* pszFormat, ...)
{
HRESULT hr;
size_t cchDest;
cchDest = cbDest / sizeof(wchar_t);
if (cchDest > STRSAFE_MAX_CCH)
{
hr = STRSAFE_E_INVALID_PARAMETER;
}
else
{
va_list argList;
va_start(argList, pszFormat);
hr = StringVPrintfWorkerW(pszDest, cchDest, pszFormat, argList);
va_end(argList);
}
return hr;
}
#endif // STRSAFE_INLINE
#endif // !STRSAFE_NO_CB_FUNCTIONS
#ifndef STRSAFE_NO_CCH_FUNCTIONS
/*++
STDAPI
StringCchPrintfEx(
OUT LPTSTR pszDest OPTIONAL,
IN size_t cchDest,
OUT LPTSTR* ppszDestEnd OPTIONAL,
OUT size_t* pcchRemaining OPTIONAL,
IN DWORD dwFlags,
IN LPCTSTR pszFormat OPTIONAL,
...
);
Routine Description:
This routine is a safer version of the C built-in function 'sprintf' with
some additional parameters. In addition to functionality provided by
StringCchPrintf, this routine also returns a pointer to the end of the
destination string and the number of characters left in the destination string
including the null terminator. The flags parameter allows additional controls.
Arguments:
pszDest - destination string
cchDest - size of destination buffer in characters.
length must be sufficient to contain the resulting
formatted string plus the null terminator.
ppszDestEnd - if ppszDestEnd is non-null, the function will return a
pointer to the end of the destination string. If the
function printed any data, the result will point to the
null termination character
pcchRemaining - if pcchRemaining is non-null, the function will return
the number of characters left in the destination string,
including the null terminator
dwFlags - controls some details of the string copy:
STRSAFE_FILL_BEHIND_NULL
if the function succeeds, the low byte of dwFlags will be
used to fill the uninitialize part of destination buffer
behind the null terminator
STRSAFE_IGNORE_NULLS
treat NULL string pointers like empty strings (TEXT(""))
STRSAFE_FILL_ON_FAILURE
if the function fails, the low byte of dwFlags will be
used to fill all of the destination buffer, and it will
be null terminated. This will overwrite any truncated
string returned when the failure is
STRSAFE_E_INSUFFICIENT_BUFFER
STRSAFE_NO_TRUNCATION /
STRSAFE_NULL_ON_FAILURE
if the function fails, the destination buffer will be set
to the empty string. This will overwrite any truncated string
returned when the failure is STRSAFE_E_INSUFFICIENT_BUFFER.
pszFormat - format string which must be null terminated
... - additional parameters to be formatted according to
the format string
Notes:
Behavior is undefined if destination, format strings or any arguments
strings overlap.
pszDest and pszFormat should not be NULL unless the STRSAFE_IGNORE_NULLS
flag is specified. If STRSAFE_IGNORE_NULLS is passed, both pszDest and
pszFormat may be NULL. An error may still be returned even though NULLS
are ignored due to insufficient space.
Return Value:
S_OK - if there was source data and it was all concatenated and
the resultant dest string was null terminated
failure - you can use the macro HRESULT_CODE() to get a win32
error code for all hresult failure cases
STRSAFE_E_INSUFFICIENT_BUFFER /
HRESULT_CODE(hr) == ERROR_INSUFFICIENT_BUFFER
- this return value is an indication that the print
operation failed due to insufficient space. When this
error occurs, the destination buffer is modified to
contain a truncated version of the ideal result and is
null terminated. This is useful for situations where
truncation is ok.
It is strongly recommended to use the SUCCEEDED() / FAILED() macros to test the
return value of this function
--*/
STRSAFEAPI StringCchPrintfExA(char* pszDest, size_t cchDest, char** ppszDestEnd, size_t* pcchRemaining, unsigned long dwFlags, const char* pszFormat, ...);
STRSAFEAPI StringCchPrintfExW(wchar_t* pszDest, size_t cchDest, wchar_t** ppszDestEnd, size_t* pcchRemaining, unsigned long dwFlags, const wchar_t* pszFormat, ...);
// end_strsafe end_ntstrsafe
// begin_strsafe
#ifdef UNICODE
#define StringCchPrintfEx StringCchPrintfExW
#else
#define StringCchPrintfEx StringCchPrintfExA
#endif // !UNICODE
// end_strsafe
// begin_strsafe begin_ntstrsafe
#ifdef STRSAFE_INLINE
STRSAFEAPI StringCchPrintfExA(char* pszDest, size_t cchDest, char** ppszDestEnd, size_t* pcchRemaining, unsigned long dwFlags, const char* pszFormat, ...)
{
HRESULT hr;
if (cchDest > STRSAFE_MAX_CCH)
{
hr = STRSAFE_E_INVALID_PARAMETER;
}
else
{
size_t cbDest;
va_list argList;
// safe to multiply cchDest * sizeof(char) since cchDest < STRSAFE_MAX_CCH and sizeof(char) is 1
cbDest = cchDest * sizeof(char);
va_start(argList, pszFormat);
hr = StringVPrintfExWorkerA(pszDest, cchDest, cbDest, ppszDestEnd, pcchRemaining, dwFlags, pszFormat, argList);
va_end(argList);
}
return hr;
}
STRSAFEAPI StringCchPrintfExW(wchar_t* pszDest, size_t cchDest, wchar_t** ppszDestEnd, size_t* pcchRemaining, unsigned long dwFlags, const wchar_t* pszFormat, ...)
{
HRESULT hr;
if (cchDest > STRSAFE_MAX_CCH)
{
hr = STRSAFE_E_INVALID_PARAMETER;
}
else
{
size_t cbDest;
va_list argList;
// safe to multiply cchDest * sizeof(wchar_t) since cchDest < STRSAFE_MAX_CCH and sizeof(wchar_t) is 2
cbDest = cchDest * sizeof(wchar_t);
va_start(argList, pszFormat);
hr = StringVPrintfExWorkerW(pszDest, cchDest, cbDest, ppszDestEnd, pcchRemaining, dwFlags, pszFormat, argList);
va_end(argList);
}
return hr;
}
#endif // STRSAFE_INLINE
#endif // !STRSAFE_NO_CCH_FUNCTIONS
#ifndef STRSAFE_NO_CB_FUNCTIONS
/*++
STDAPI
StringCbPrintfEx(
OUT LPTSTR pszDest OPTIONAL,
IN size_t cbDest,
OUT LPTSTR* ppszDestEnd OPTIONAL,
OUT size_t* pcbRemaining OPTIONAL,
IN DWORD dwFlags,
IN LPCTSTR pszFormat OPTIONAL,
...
);
Routine Description:
This routine is a safer version of the C built-in function 'sprintf' with
some additional parameters. In addition to functionality provided by
StringCbPrintf, this routine also returns a pointer to the end of the
destination string and the number of bytes left in the destination string
including the null terminator. The flags parameter allows additional controls.
Arguments:
pszDest - destination string
cbDest - size of destination buffer in bytes.
length must be sufficient to contain the resulting
formatted string plus the null terminator.
ppszDestEnd - if ppszDestEnd is non-null, the function will return a
pointer to the end of the destination string. If the
function printed any data, the result will point to the
null termination character
pcbRemaining - if pcbRemaining is non-null, the function will return
the number of bytes left in the destination string,
including the null terminator
dwFlags - controls some details of the string copy:
STRSAFE_FILL_BEHIND_NULL
if the function succeeds, the low byte of dwFlags will be
used to fill the uninitialize part of destination buffer
behind the null terminator
STRSAFE_IGNORE_NULLS
treat NULL string pointers like empty strings (TEXT(""))
STRSAFE_FILL_ON_FAILURE
if the function fails, the low byte of dwFlags will be
used to fill all of the destination buffer, and it will
be null terminated. This will overwrite any truncated
string returned when the failure is
STRSAFE_E_INSUFFICIENT_BUFFER
STRSAFE_NO_TRUNCATION /
STRSAFE_NULL_ON_FAILURE
if the function fails, the destination buffer will be set
to the empty string. This will overwrite any truncated string
returned when the failure is STRSAFE_E_INSUFFICIENT_BUFFER.
pszFormat - format string which must be null terminated
... - additional parameters to be formatted according to
the format string
Notes:
Behavior is undefined if destination, format strings or any arguments
strings overlap.
pszDest and pszFormat should not be NULL unless the STRSAFE_IGNORE_NULLS
flag is specified. If STRSAFE_IGNORE_NULLS is passed, both pszDest and
pszFormat may be NULL. An error may still be returned even though NULLS
are ignored due to insufficient space.
Return Value:
S_OK - if there was source data and it was all concatenated and
the resultant dest string was null terminated
failure - you can use the macro HRESULT_CODE() to get a win32
error code for all hresult failure cases
STRSAFE_E_INSUFFICIENT_BUFFER /
HRESULT_CODE(hr) == ERROR_INSUFFICIENT_BUFFER
- this return value is an indication that the print
operation failed due to insufficient space. When this
error occurs, the destination buffer is modified to
contain a truncated version of the ideal result and is
null terminated. This is useful for situations where
truncation is ok.
It is strongly recommended to use the SUCCEEDED() / FAILED() macros to test the
return value of this function
--*/
STRSAFEAPI StringCbPrintfExA(char* pszDest, size_t cbDest, char** ppszDestEnd, size_t* pcbRemaining, unsigned long dwFlags, const char* pszFormat, ...);
STRSAFEAPI StringCbPrintfExW(wchar_t* pszDest, size_t cbDest, wchar_t** ppszDestEnd, size_t* pcbRemaining, unsigned long dwFlags, const wchar_t* pszFormat, ...);
// end_strsafe end_ntstrsafe
// begin_strsafe
#ifdef UNICODE
#define StringCbPrintfEx StringCbPrintfExW
#else
#define StringCbPrintfEx StringCbPrintfExA
#endif // !UNICODE
// end_strsafe
// begin_strsafe begin_ntstrsafe
#ifdef STRSAFE_INLINE
STRSAFEAPI StringCbPrintfExA(char* pszDest, size_t cbDest, char** ppszDestEnd, size_t* pcbRemaining, unsigned long dwFlags, const char* pszFormat, ...)
{
HRESULT hr;
size_t cchDest;
size_t cchRemaining = 0;
cchDest = cbDest / sizeof(char);
if (cchDest > STRSAFE_MAX_CCH)
{
hr = STRSAFE_E_INVALID_PARAMETER;
}
else
{
va_list argList;
va_start(argList, pszFormat);
hr = StringVPrintfExWorkerA(pszDest, cchDest, cbDest, ppszDestEnd, &cchRemaining, dwFlags, pszFormat, argList);
va_end(argList);
}
if (SUCCEEDED(hr) || (hr == STRSAFE_E_INSUFFICIENT_BUFFER))
{
if (pcbRemaining)
{
// safe to multiply cchRemaining * sizeof(char) since cchRemaining < STRSAFE_MAX_CCH and sizeof(char) is 1
*pcbRemaining = (cchRemaining * sizeof(char)) + (cbDest % sizeof(char));
}
}
return hr;
}
STRSAFEAPI StringCbPrintfExW(wchar_t* pszDest, size_t cbDest, wchar_t** ppszDestEnd, size_t* pcbRemaining, unsigned long dwFlags, const wchar_t* pszFormat, ...)
{
HRESULT hr;
size_t cchDest;
size_t cchRemaining = 0;
cchDest = cbDest / sizeof(wchar_t);
if (cchDest > STRSAFE_MAX_CCH)
{
hr = STRSAFE_E_INVALID_PARAMETER;
}
else
{
va_list argList;
va_start(argList, pszFormat);
hr = StringVPrintfExWorkerW(pszDest, cchDest, cbDest, ppszDestEnd, &cchRemaining, dwFlags, pszFormat, argList);
va_end(argList);
}
if (SUCCEEDED(hr) || (hr == STRSAFE_E_INSUFFICIENT_BUFFER))
{
if (pcbRemaining)
{
// safe to multiply cchRemaining * sizeof(wchar_t) since cchRemaining < STRSAFE_MAX_CCH and sizeof(wchar_t) is 2
*pcbRemaining = (cchRemaining * sizeof(wchar_t)) + (cbDest % sizeof(wchar_t));
}
}
return hr;
}
#endif // STRSAFE_INLINE
#endif // !STRSAFE_NO_CB_FUNCTIONS
#ifndef STRSAFE_NO_CCH_FUNCTIONS
/*++
STDAPI
StringCchVPrintfEx(
OUT LPTSTR pszDest OPTIONAL,
IN size_t cchDest,
OUT LPTSTR* ppszDestEnd OPTIONAL,
OUT size_t* pcchRemaining OPTIONAL,
IN DWORD dwFlags,
IN LPCTSTR pszFormat OPTIONAL,
IN va_list argList
);
Routine Description:
This routine is a safer version of the C built-in function 'vsprintf' with
some additional parameters. In addition to functionality provided by
StringCchVPrintf, this routine also returns a pointer to the end of the
destination string and the number of characters left in the destination string
including the null terminator. The flags parameter allows additional controls.
Arguments:
pszDest - destination string
cchDest - size of destination buffer in characters.
length must be sufficient to contain the resulting
formatted string plus the null terminator.
ppszDestEnd - if ppszDestEnd is non-null, the function will return a
pointer to the end of the destination string. If the
function printed any data, the result will point to the
null termination character
pcchRemaining - if pcchRemaining is non-null, the function will return
the number of characters left in the destination string,
including the null terminator
dwFlags - controls some details of the string copy:
STRSAFE_FILL_BEHIND_NULL
if the function succeeds, the low byte of dwFlags will be
used to fill the uninitialize part of destination buffer
behind the null terminator
STRSAFE_IGNORE_NULLS
treat NULL string pointers like empty strings (TEXT(""))
STRSAFE_FILL_ON_FAILURE
if the function fails, the low byte of dwFlags will be
used to fill all of the destination buffer, and it will
be null terminated. This will overwrite any truncated
string returned when the failure is
STRSAFE_E_INSUFFICIENT_BUFFER
STRSAFE_NO_TRUNCATION /
STRSAFE_NULL_ON_FAILURE
if the function fails, the destination buffer will be set
to the empty string. This will overwrite any truncated string
returned when the failure is STRSAFE_E_INSUFFICIENT_BUFFER.
pszFormat - format string which must be null terminated
argList - va_list from the variable arguments according to the
stdarg.h convention
Notes:
Behavior is undefined if destination, format strings or any arguments
strings overlap.
pszDest and pszFormat should not be NULL unless the STRSAFE_IGNORE_NULLS
flag is specified. If STRSAFE_IGNORE_NULLS is passed, both pszDest and
pszFormat may be NULL. An error may still be returned even though NULLS
are ignored due to insufficient space.
Return Value:
S_OK - if there was source data and it was all concatenated and
the resultant dest string was null terminated
failure - you can use the macro HRESULT_CODE() to get a win32
error code for all hresult failure cases
STRSAFE_E_INSUFFICIENT_BUFFER /
HRESULT_CODE(hr) == ERROR_INSUFFICIENT_BUFFER
- this return value is an indication that the print
operation failed due to insufficient space. When this
error occurs, the destination buffer is modified to
contain a truncated version of the ideal result and is
null terminated. This is useful for situations where
truncation is ok.
It is strongly recommended to use the SUCCEEDED() / FAILED() macros to test the
return value of this function
--*/
STRSAFEAPI StringCchVPrintfExA(char* pszDest, size_t cchDest, char** ppszDestEnd, size_t* pcchRemaining, unsigned long dwFlags, const char* pszFormat, va_list argList);
STRSAFEAPI StringCchVPrintfExW(wchar_t* pszDest, size_t cchDest, wchar_t** ppszDestEnd, size_t* pcchRemaining, unsigned long dwFlags, const wchar_t* pszFormat, va_list argList);
// end_strsafe end_ntstrsafe
// begin_strsafe
#ifdef UNICODE
#define StringCchVPrintfEx StringCchVPrintfExW
#else
#define StringCchVPrintfEx StringCchVPrintfExA
#endif // !UNICODE
// end_strsafe
// begin_strsafe begin_ntstrsafe
#ifdef STRSAFE_INLINE
STRSAFEAPI StringCchVPrintfExA(char* pszDest, size_t cchDest, char** ppszDestEnd, size_t* pcchRemaining, unsigned long dwFlags, const char* pszFormat, va_list argList)
{
HRESULT hr;
if (cchDest > STRSAFE_MAX_CCH)
{
hr = STRSAFE_E_INVALID_PARAMETER;
}
else
{
size_t cbDest;
// safe to multiply cchDest * sizeof(char) since cchDest < STRSAFE_MAX_CCH and sizeof(char) is 1
cbDest = cchDest * sizeof(char);
hr = StringVPrintfExWorkerA(pszDest, cchDest, cbDest, ppszDestEnd, pcchRemaining, dwFlags, pszFormat, argList);
}
return hr;
}
STRSAFEAPI StringCchVPrintfExW(wchar_t* pszDest, size_t cchDest, wchar_t** ppszDestEnd, size_t* pcchRemaining, unsigned long dwFlags, const wchar_t* pszFormat, va_list argList)
{
HRESULT hr;
if (cchDest > STRSAFE_MAX_CCH)
{
hr = STRSAFE_E_INVALID_PARAMETER;
}
else
{
size_t cbDest;
// safe to multiply cchDest * sizeof(wchar_t) since cchDest < STRSAFE_MAX_CCH and sizeof(wchar_t) is 2
cbDest = cchDest * sizeof(wchar_t);
hr = StringVPrintfExWorkerW(pszDest, cchDest, cbDest, ppszDestEnd, pcchRemaining, dwFlags, pszFormat, argList);
}
return hr;
}
#endif // STRSAFE_INLINE
#endif // !STRSAFE_NO_CCH_FUNCTIONS
#ifndef STRSAFE_NO_CB_FUNCTIONS
/*++
STDAPI
StringCbVPrintfEx(
OUT LPTSTR pszDest OPTIONAL,
IN size_t cbDest,
OUT LPTSTR* ppszDestEnd OPTIONAL,
OUT size_t* pcbRemaining OPTIONAL,
IN DWORD dwFlags,
IN LPCTSTR pszFormat OPTIONAL,
IN va_list argList
);
Routine Description:
This routine is a safer version of the C built-in function 'vsprintf' with
some additional parameters. In addition to functionality provided by
StringCbVPrintf, this routine also returns a pointer to the end of the
destination string and the number of characters left in the destination string
including the null terminator. The flags parameter allows additional controls.
Arguments:
pszDest - destination string
cbDest - size of destination buffer in bytes.
length must be sufficient to contain the resulting
formatted string plus the null terminator.
ppszDestEnd - if ppszDestEnd is non-null, the function will return
a pointer to the end of the destination string. If the
function printed any data, the result will point to the
null termination character
pcbRemaining - if pcbRemaining is non-null, the function will return
the number of bytes left in the destination string,
including the null terminator
dwFlags - controls some details of the string copy:
STRSAFE_FILL_BEHIND_NULL
if the function succeeds, the low byte of dwFlags will be
used to fill the uninitialize part of destination buffer
behind the null terminator
STRSAFE_IGNORE_NULLS
treat NULL string pointers like empty strings (TEXT(""))
STRSAFE_FILL_ON_FAILURE
if the function fails, the low byte of dwFlags will be
used to fill all of the destination buffer, and it will
be null terminated. This will overwrite any truncated
string returned when the failure is
STRSAFE_E_INSUFFICIENT_BUFFER
STRSAFE_NO_TRUNCATION /
STRSAFE_NULL_ON_FAILURE
if the function fails, the destination buffer will be set
to the empty string. This will overwrite any truncated string
returned when the failure is STRSAFE_E_INSUFFICIENT_BUFFER.
pszFormat - format string which must be null terminated
argList - va_list from the variable arguments according to the
stdarg.h convention
Notes:
Behavior is undefined if destination, format strings or any arguments
strings overlap.
pszDest and pszFormat should not be NULL unless the STRSAFE_IGNORE_NULLS
flag is specified. If STRSAFE_IGNORE_NULLS is passed, both pszDest and
pszFormat may be NULL. An error may still be returned even though NULLS
are ignored due to insufficient space.
Return Value:
S_OK - if there was source data and it was all concatenated and
the resultant dest string was null terminated
failure - you can use the macro HRESULT_CODE() to get a win32
error code for all hresult failure cases
STRSAFE_E_INSUFFICIENT_BUFFER /
HRESULT_CODE(hr) == ERROR_INSUFFICIENT_BUFFER
- this return value is an indication that the print
operation failed due to insufficient space. When this
error occurs, the destination buffer is modified to
contain a truncated version of the ideal result and is
null terminated. This is useful for situations where
truncation is ok.
It is strongly recommended to use the SUCCEEDED() / FAILED() macros to test the
return value of this function
--*/
STRSAFEAPI StringCbVPrintfExA(char* pszDest, size_t cbDest, char** ppszDestEnd, size_t* pcbRemaining, unsigned long dwFlags, const char* pszFormat, va_list argList);
STRSAFEAPI StringCbVPrintfExW(wchar_t* pszDest, size_t cbDest, wchar_t** ppszDestEnd, size_t* pcbRemaining, unsigned long dwFlags, const wchar_t* pszFormat, va_list argList);
// end_strsafe end_ntstrsafe
// begin_strsafe
#ifdef UNICODE
#define StringCbVPrintfEx StringCbVPrintfExW
#else
#define StringCbVPrintfEx StringCbVPrintfExA
#endif // !UNICODE
// end_strsafe
// begin_strsafe begin_ntstrsafe
#ifdef STRSAFE_INLINE
STRSAFEAPI StringCbVPrintfExA(char* pszDest, size_t cbDest, char** ppszDestEnd, size_t* pcbRemaining, unsigned long dwFlags, const char* pszFormat, va_list argList)
{
HRESULT hr;
size_t cchDest;
size_t cchRemaining = 0;
cchDest = cbDest / sizeof(char);
if (cchDest > STRSAFE_MAX_CCH)
{
hr = STRSAFE_E_INVALID_PARAMETER;
}
else
{
hr = StringVPrintfExWorkerA(pszDest, cchDest, cbDest, ppszDestEnd, &cchRemaining, dwFlags, pszFormat, argList);
}
if (SUCCEEDED(hr) || (hr == STRSAFE_E_INSUFFICIENT_BUFFER))
{
if (pcbRemaining)
{
// safe to multiply cchRemaining * sizeof(char) since cchRemaining < STRSAFE_MAX_CCH and sizeof(char) is 1
*pcbRemaining = (cchRemaining * sizeof(char)) + (cbDest % sizeof(char));
}
}
return hr;
}
STRSAFEAPI StringCbVPrintfExW(wchar_t* pszDest, size_t cbDest, wchar_t** ppszDestEnd, size_t* pcbRemaining, unsigned long dwFlags, const wchar_t* pszFormat, va_list argList)
{
HRESULT hr;
size_t cchDest;
size_t cchRemaining = 0;
cchDest = cbDest / sizeof(wchar_t);
if (cchDest > STRSAFE_MAX_CCH)
{
hr = STRSAFE_E_INVALID_PARAMETER;
}
else
{
hr = StringVPrintfExWorkerW(pszDest, cchDest, cbDest, ppszDestEnd, &cchRemaining, dwFlags, pszFormat, argList);
}
if (SUCCEEDED(hr) || (hr == STRSAFE_E_INSUFFICIENT_BUFFER))
{
if (pcbRemaining)
{
// safe to multiply cchRemaining * sizeof(wchar_t) since cchRemaining < STRSAFE_MAX_CCH and sizeof(wchar_t) is 2
*pcbRemaining = (cchRemaining * sizeof(wchar_t)) + (cbDest % sizeof(wchar_t));
}
}
return hr;
}
#endif // STRSAFE_INLINE
#endif // !STRSAFE_NO_CB_FUNCTIONS
// end_strsafe end_ntstrsafe
// begin_strsafe
#ifndef STRSAFE_NO_CCH_FUNCTIONS
/*++
STDAPI
StringCchGets(
OUT LPTSTR pszDest,
IN size_t cchDest
);
Routine Description:
This routine is a safer version of the C built-in function 'gets'.
The size of the destination buffer (in characters) is a parameter and
this function will not write past the end of this buffer and it will
ALWAYS null terminate the destination buffer (unless it is zero length).
This routine is not a replacement for fgets. That function does not replace
newline characters with a null terminator.
This function returns a hresult, and not a pointer. It returns
S_OK if any characters were read from stdin and copied to pszDest and
pszDest was null terminated, otherwise it will return a failure code.
Arguments:
pszDest - destination string
cchDest - size of destination buffer in characters.
Notes:
pszDest should not be NULL. See StringCchGetsEx if you require the handling
of NULL values.
cchDest must be > 1 for this function to succeed.
Return Value:
S_OK - data was read from stdin and copied, and the resultant
dest string was null terminated
failure - you can use the macro HRESULT_CODE() to get a win32
error code for all hresult failure cases
STRSAFE_E_END_OF_FILE /
HRESULT_CODE(hr) == ERROR_HANDLE_EOF
- this return value indicates an error or end-of-file
condition, use feof or ferror to determine which one has
occured.
STRSAFE_E_INSUFFICIENT_BUFFER /
HRESULT_CODE(hr) == ERROR_INSUFFICIENT_BUFFER
- this return value is an indication that there was
insufficient space in the destination buffer to copy any
data
It is strongly recommended to use the SUCCEEDED() / FAILED() macros to test the
return value of this function.
--*/
#ifndef STRSAFE_LIB_IMPL
STRSAFE_INLINE_API StringCchGetsA(char* pszDest, size_t cchDest);
STRSAFE_INLINE_API StringCchGetsW(wchar_t* pszDest, size_t cchDest);
#ifdef UNICODE
#define StringCchGets StringCchGetsW
#else
#define StringCchGets StringCchGetsA
#endif // !UNICODE
STRSAFE_INLINE_API StringCchGetsA(char* pszDest, size_t cchDest)
{
HRESULT hr;
if (cchDest > STRSAFE_MAX_CCH)
{
hr = STRSAFE_E_INVALID_PARAMETER;
}
else
{
size_t cbDest;
// safe to multiply cchDest * sizeof(char) since cchDest < STRSAFE_MAX_CCH and sizeof(char) is 1
cbDest = cchDest * sizeof(char);
hr = StringGetsExWorkerA(pszDest, cchDest, cbDest, NULL, NULL, 0);
}
return hr;
}
STRSAFE_INLINE_API StringCchGetsW(wchar_t* pszDest, size_t cchDest)
{
HRESULT hr;
if (cchDest > STRSAFE_MAX_CCH)
{
hr = STRSAFE_E_INVALID_PARAMETER;
}
else
{
size_t cbDest;
// safe to multiply cchDest * sizeof(wchar_t) since cchDest < STRSAFE_MAX_CCH and sizeof(wchar_t) is 2
cbDest = cchDest * sizeof(wchar_t);
hr = StringGetsExWorkerW(pszDest, cchDest, cbDest, NULL, NULL, 0);
}
return hr;
}
#endif // !STRSAFE_NO_CCH_FUNCTIONS
#endif // !STRSAFE_LIB_IMPL
#ifndef STRSAFE_NO_CB_FUNCTIONS
/*++
STDAPI
StringCbGets(
OUT LPTSTR pszDest,
IN size_t cbDest
);
Routine Description:
This routine is a safer version of the C built-in function 'gets'.
The size of the destination buffer (in bytes) is a parameter and
this function will not write past the end of this buffer and it will
ALWAYS null terminate the destination buffer (unless it is zero length).
This routine is not a replacement for fgets. That function does not replace
newline characters with a null terminator.
This function returns a hresult, and not a pointer. It returns
S_OK if any characters were read from stdin and copied to pszDest
and pszDest was null terminated, otherwise it will return a failure code.
Arguments:
pszDest - destination string
cbDest - size of destination buffer in bytes.
Notes:
pszDest should not be NULL. See StringCbGetsEx if you require the handling
of NULL values.
cbDest must be > sizeof(TCHAR) for this function to succeed.
Return Value:
S_OK - data was read from stdin and copied, and the resultant
dest string was null terminated
failure - you can use the macro HRESULT_CODE() to get a win32
error code for all hresult failure cases
STRSAFE_E_END_OF_FILE /
HRESULT_CODE(hr) == ERROR_HANDLE_EOF
- this return value indicates an error or end-of-file
condition, use feof or ferror to determine which one has
occured.
STRSAFE_E_INSUFFICIENT_BUFFER /
HRESULT_CODE(hr) == ERROR_INSUFFICIENT_BUFFER
- this return value is an indication that there was
insufficient space in the destination buffer to copy any
data
It is strongly recommended to use the SUCCEEDED() / FAILED() macros to test the
return value of this function.
--*/
#ifndef STRSAFE_LIB_IMPL
STRSAFE_INLINE_API StringCbGetsA(char* pszDest, size_t cbDest);
STRSAFE_INLINE_API StringCbGetsW(wchar_t* pszDest, size_t cbDest);
#ifdef UNICODE
#define StringCbGets StringCbGetsW
#else
#define StringCbGets StringCbGetsA
#endif // !UNICODE
STRSAFE_INLINE_API StringCbGetsA(char* pszDest, size_t cbDest)
{
HRESULT hr;
size_t cchDest;
// convert to count of characters
cchDest = cbDest / sizeof(char);
if (cchDest > STRSAFE_MAX_CCH)
{
hr = STRSAFE_E_INVALID_PARAMETER;
}
else
{
hr = StringGetsExWorkerA(pszDest, cchDest, cbDest, NULL, NULL, 0);
}
return hr;
}
STRSAFE_INLINE_API StringCbGetsW(wchar_t* pszDest, size_t cbDest)
{
HRESULT hr;
size_t cchDest;
// convert to count of characters
cchDest = cbDest / sizeof(wchar_t);
if (cchDest > STRSAFE_MAX_CCH)
{
hr = STRSAFE_E_INVALID_PARAMETER;
}
else
{
hr = StringGetsExWorkerW(pszDest, cchDest, cbDest, NULL, NULL, 0);
}
return hr;
}
#endif // !STRSAFE_NO_CB_FUNCTIONS
#endif // !STRSAFE_LIB_IMPL
#ifndef STRSAFE_NO_CCH_FUNCTIONS
/*++
STDAPI
StringCchGetsEx(
OUT LPTSTR pszDest OPTIONAL,
IN size_t cchDest,
OUT LPTSTR* ppszDestEnd OPTIONAL,
OUT size_t* pcchRemaining OPTIONAL,
IN DWORD dwFlags
);
Routine Description:
This routine is a safer version of the C built-in function 'gets' with
some additional parameters. In addition to functionality provided by
StringCchGets, this routine also returns a pointer to the end of the
destination string and the number of characters left in the destination string
including the null terminator. The flags parameter allows additional controls.
Arguments:
pszDest - destination string
cchDest - size of destination buffer in characters.
ppszDestEnd - if ppszDestEnd is non-null, the function will return a
pointer to the end of the destination string. If the
function copied any data, the result will point to the
null termination character
pcchRemaining - if pcchRemaining is non-null, the function will return the
number of characters left in the destination string,
including the null terminator
dwFlags - controls some details of the string copy:
STRSAFE_FILL_BEHIND_NULL
if the function succeeds, the low byte of dwFlags will be
used to fill the uninitialize part of destination buffer
behind the null terminator
STRSAFE_IGNORE_NULLS
treat NULL string pointers like empty strings (TEXT("")).
STRSAFE_FILL_ON_FAILURE
if the function fails, the low byte of dwFlags will be
used to fill all of the destination buffer, and it will
be null terminated.
STRSAFE_NO_TRUNCATION /
STRSAFE_NULL_ON_FAILURE
if the function fails, the destination buffer will be set
to the empty string.
Notes:
pszDest should not be NULL unless the STRSAFE_IGNORE_NULLS flag is specified.
If STRSAFE_IGNORE_NULLS is passed and pszDest is NULL, an error may still be
returned even though NULLS are ignored
cchDest must be > 1 for this function to succeed.
Return Value:
S_OK - data was read from stdin and copied, and the resultant
dest string was null terminated
failure - you can use the macro HRESULT_CODE() to get a win32
error code for all hresult failure cases
STRSAFE_E_END_OF_FILE /
HRESULT_CODE(hr) == ERROR_HANDLE_EOF
- this return value indicates an error or end-of-file
condition, use feof or ferror to determine which one has
occured.
STRSAFE_E_INSUFFICIENT_BUFFER /
HRESULT_CODE(hr) == ERROR_INSUFFICIENT_BUFFER
- this return value is an indication that there was
insufficient space in the destination buffer to copy any
data
It is strongly recommended to use the SUCCEEDED() / FAILED() macros to test the
return value of this function.
--*/
#ifndef STRSAFE_LIB_IMPL
STRSAFE_INLINE_API StringCchGetsExA(char* pszDest, size_t cchDest, char** ppszDestEnd, size_t* pcchRemaining, unsigned long dwFlags);
STRSAFE_INLINE_API StringCchGetsExW(wchar_t* pszDest, size_t cchDest, wchar_t** ppszDestEnd, size_t* pcchRemaining, unsigned long dwFlags);
#ifdef UNICODE
#define StringCchGetsEx StringCchGetsExW
#else
#define StringCchGetsEx StringCchGetsExA
#endif // !UNICODE
STRSAFE_INLINE_API StringCchGetsExA(char* pszDest, size_t cchDest, char** ppszDestEnd, size_t* pcchRemaining, unsigned long dwFlags)
{
HRESULT hr;
if (cchDest > STRSAFE_MAX_CCH)
{
hr = STRSAFE_E_INVALID_PARAMETER;
}
else
{
size_t cbDest;
// safe to multiply cchDest * sizeof(char) since cchDest < STRSAFE_MAX_CCH and sizeof(char) is 1
cbDest = cchDest * sizeof(char);
hr = StringGetsExWorkerA(pszDest, cchDest, cbDest, ppszDestEnd, pcchRemaining, dwFlags);
}
return hr;
}
STRSAFE_INLINE_API StringCchGetsExW(wchar_t* pszDest, size_t cchDest, wchar_t** ppszDestEnd, size_t* pcchRemaining, unsigned long dwFlags)
{
HRESULT hr;
if (cchDest > STRSAFE_MAX_CCH)
{
hr = STRSAFE_E_INVALID_PARAMETER;
}
else
{
size_t cbDest;
// safe to multiply cchDest * sizeof(wchar_t) since cchDest < STRSAFE_MAX_CCH and sizeof(wchar_t) is 2
cbDest = cchDest * sizeof(wchar_t);
hr = StringGetsExWorkerW(pszDest, cchDest, cbDest, ppszDestEnd, pcchRemaining, dwFlags);
}
return hr;
}
#endif // !STRSAFE_NO_CCH_FUNCTIONS
#endif // !STRSAFE_LIB_IMPL
#ifndef STRSAFE_NO_CB_FUNCTIONS
/*++
STDAPI
StringCbGetsEx(
OUT LPTSTR pszDest OPTIONAL,
IN size_t cbDest,
OUT LPTSTR* ppszDestEnd OPTIONAL,
OUT size_t* pcbRemaining OPTIONAL,
IN DWORD dwFlags
);
Routine Description:
This routine is a safer version of the C built-in function 'gets' with
some additional parameters. In addition to functionality provided by
StringCbGets, this routine also returns a pointer to the end of the
destination string and the number of characters left in the destination string
including the null terminator. The flags parameter allows additional controls.
Arguments:
pszDest - destination string
cbDest - size of destination buffer in bytes.
ppszDestEnd - if ppszDestEnd is non-null, the function will return a
pointer to the end of the destination string. If the
function copied any data, the result will point to the
null termination character
pcbRemaining - if pbRemaining is non-null, the function will return the
number of bytes left in the destination string,
including the null terminator
dwFlags - controls some details of the string copy:
STRSAFE_FILL_BEHIND_NULL
if the function succeeds, the low byte of dwFlags will be
used to fill the uninitialize part of destination buffer
behind the null terminator
STRSAFE_IGNORE_NULLS
treat NULL string pointers like empty strings (TEXT("")).
STRSAFE_FILL_ON_FAILURE
if the function fails, the low byte of dwFlags will be
used to fill all of the destination buffer, and it will
be null terminated.
STRSAFE_NO_TRUNCATION /
STRSAFE_NULL_ON_FAILURE
if the function fails, the destination buffer will be set
to the empty string.
Notes:
pszDest should not be NULL unless the STRSAFE_IGNORE_NULLS flag is specified.
If STRSAFE_IGNORE_NULLS is passed and pszDest is NULL, an error may still be
returned even though NULLS are ignored
cbDest must be > sizeof(TCHAR) for this function to succeed
Return Value:
S_OK - data was read from stdin and copied, and the resultant
dest string was null terminated
failure - you can use the macro HRESULT_CODE() to get a win32
error code for all hresult failure cases
STRSAFE_E_END_OF_FILE /
HRESULT_CODE(hr) == ERROR_HANDLE_EOF
- this return value indicates an error or end-of-file
condition, use feof or ferror to determine which one has
occured.
STRSAFE_E_INSUFFICIENT_BUFFER /
HRESULT_CODE(hr) == ERROR_INSUFFICIENT_BUFFER
- this return value is an indication that there was
insufficient space in the destination buffer to copy any
data
It is strongly recommended to use the SUCCEEDED() / FAILED() macros to test the
return value of this function.
--*/
#ifndef STRSAFE_LIB_IMPL
STRSAFE_INLINE_API StringCbGetsExA(char* pszDest, size_t cbDest, char** ppszDestEnd, size_t* pbRemaining, unsigned long dwFlags);
STRSAFE_INLINE_API StringCbGetsExW(wchar_t* pszDest, size_t cbDest, wchar_t** ppszDestEnd, size_t* pcbRemaining, unsigned long dwFlags);
#ifdef UNICODE
#define StringCbGetsEx StringCbGetsExW
#else
#define StringCbGetsEx StringCbGetsExA
#endif // !UNICODE
STRSAFE_INLINE_API StringCbGetsExA(char* pszDest, size_t cbDest, char** ppszDestEnd, size_t* pcbRemaining, unsigned long dwFlags)
{
HRESULT hr;
size_t cchDest;
size_t cchRemaining = 0;
cchDest = cbDest / sizeof(char);
if (cchDest > STRSAFE_MAX_CCH)
{
hr = STRSAFE_E_INVALID_PARAMETER;
}
else
{
hr = StringGetsExWorkerA(pszDest, cchDest, cbDest, ppszDestEnd, &cchRemaining, dwFlags);
}
if (SUCCEEDED(hr) ||
(hr == STRSAFE_E_INSUFFICIENT_BUFFER) ||
(hr == STRSAFE_E_END_OF_FILE))
{
if (pcbRemaining)
{
// safe to multiply cchRemaining * sizeof(char) since cchRemaining < STRSAFE_MAX_CCH and sizeof(char) is 1
*pcbRemaining = (cchRemaining * sizeof(char)) + (cbDest % sizeof(char));
}
}
return hr;
}
STRSAFE_INLINE_API StringCbGetsExW(wchar_t* pszDest, size_t cbDest, wchar_t** ppszDestEnd, size_t* pcbRemaining, unsigned long dwFlags)
{
HRESULT hr;
size_t cchDest;
size_t cchRemaining = 0;
cchDest = cbDest / sizeof(wchar_t);
if (cchDest > STRSAFE_MAX_CCH)
{
hr = STRSAFE_E_INVALID_PARAMETER;
}
else
{
hr = StringGetsExWorkerW(pszDest, cchDest, cbDest, ppszDestEnd, &cchRemaining, dwFlags);
}
if (SUCCEEDED(hr) ||
(hr == STRSAFE_E_INSUFFICIENT_BUFFER) ||
(hr == STRSAFE_E_END_OF_FILE))
{
if (pcbRemaining)
{
// safe to multiply cchRemaining * sizeof(wchar_t) since cchRemaining < STRSAFE_MAX_CCH and sizeof(wchar_t) is 2
*pcbRemaining = (cchRemaining * sizeof(wchar_t)) + (cbDest % sizeof(wchar_t));
}
}
return hr;
}
#endif // !STRSAFE_NO_CB_FUNCTIONS
#endif // !STRSAFE_LIB_IMPL
// end_strsafe
// begin_strsafe begin_ntstrsafe
#ifndef STRSAFE_NO_CCH_FUNCTIONS
/*++
STDAPI
StringCchLength(
IN LPCTSTR psz,
IN size_t cchMax,
OUT size_t* pcch OPTIONAL
);
Routine Description:
This routine is a safer version of the C built-in function 'strlen'.
It is used to make sure a string is not larger than a given length, and
it optionally returns the current length in characters not including
the null terminator.
This function returns a hresult, and not a pointer. It returns
S_OK if the string is non-null and the length including the null
terminator is less than or equal to cchMax characters.
Arguments:
psz - string to check the length of
cchMax - maximum number of characters including the null terminator
that psz is allowed to contain
pcch - if the function succeeds and pcch is non-null, the current length
in characters of psz excluding the null terminator will be returned.
This out parameter is equivalent to the return value of strlen(psz)
Notes:
psz can be null but the function will fail
cchMax should be greater than zero or the function will fail
Return Value:
S_OK - psz is non-null and the length including the null
terminator is less than or equal to cchMax characters
failure - you can use the macro HRESULT_CODE() to get a win32
error code for all hresult failure cases
It is strongly recommended to use the SUCCEEDED() / FAILED() macros to test the
return value of this function.
--*/
STRSAFEAPI StringCchLengthA(const char* psz, size_t cchMax, size_t* pcch);
STRSAFEAPI StringCchLengthW(const wchar_t* psz, size_t cchMax, size_t* pcch);
// end_strsafe end_ntstrsafe
// begin_strsafe
#ifdef UNICODE
#define StringCchLength StringCchLengthW
#else
#define StringCchLength StringCchLengthA
#endif // !UNICODE
// end_strsafe
// begin_strsafe begin_ntstrsafe
#ifdef STRSAFE_INLINE
STRSAFEAPI StringCchLengthA(const char* psz, size_t cchMax, size_t* pcch)
{
HRESULT hr;
if ((psz == NULL) || (cchMax > STRSAFE_MAX_CCH))
{
hr = STRSAFE_E_INVALID_PARAMETER;
}
else
{
hr = StringLengthWorkerA(psz, cchMax, pcch);
}
return hr;
}
STRSAFEAPI StringCchLengthW(const wchar_t* psz, size_t cchMax, size_t* pcch)
{
HRESULT hr;
if ((psz == NULL) || (cchMax > STRSAFE_MAX_CCH))
{
hr = STRSAFE_E_INVALID_PARAMETER;
}
else
{
hr = StringLengthWorkerW(psz, cchMax, pcch);
}
return hr;
}
#endif // STRSAFE_INLINE
#endif // !STRSAFE_NO_CCH_FUNCTIONS
#ifndef STRSAFE_NO_CB_FUNCTIONS
/*++
STDAPI
StringCbLength(
IN LPCTSTR psz,
IN size_t cbMax,
OUT size_t* pcb OPTIONAL
);
Routine Description:
This routine is a safer version of the C built-in function 'strlen'.
It is used to make sure a string is not larger than a given length, and
it optionally returns the current length in bytes not including
the null terminator.
This function returns a hresult, and not a pointer. It returns
S_OK if the string is non-null and the length including the null
terminator is less than or equal to cbMax bytes.
Arguments:
psz - string to check the length of
cbMax - maximum number of bytes including the null terminator
that psz is allowed to contain
pcb - if the function succeeds and pcb is non-null, the current length
in bytes of psz excluding the null terminator will be returned.
This out parameter is equivalent to the return value of strlen(psz) * sizeof(TCHAR)
Notes:
psz can be null but the function will fail
cbMax should be greater than or equal to sizeof(TCHAR) or the function will fail
Return Value:
S_OK - psz is non-null and the length including the null
terminator is less than or equal to cbMax bytes
failure - you can use the macro HRESULT_CODE() to get a win32
error code for all hresult failure cases
It is strongly recommended to use the SUCCEEDED() / FAILED() macros to test the
return value of this function.
--*/
STRSAFEAPI StringCbLengthA(const char* psz, size_t cchMax, size_t* pcch);
STRSAFEAPI StringCbLengthW(const wchar_t* psz, size_t cchMax, size_t* pcch);
// end_strsafe end_ntstrsafe
// begin_strsafe
#ifdef UNICODE
#define StringCbLength StringCbLengthW
#else
#define StringCbLength StringCbLengthA
#endif // !UNICODE
// end_strsafe
// begin_strsafe begin_ntstrsafe
#ifdef STRSAFE_INLINE
STRSAFEAPI StringCbLengthA(const char* psz, size_t cbMax, size_t* pcb)
{
HRESULT hr;
size_t cchMax;
size_t cch = 0;
cchMax = cbMax / sizeof(char);
if ((psz == NULL) || (cchMax > STRSAFE_MAX_CCH))
{
hr = STRSAFE_E_INVALID_PARAMETER;
}
else
{
hr = StringLengthWorkerA(psz, cchMax, &cch);
}
if (SUCCEEDED(hr) && pcb)
{
// safe to multiply cch * sizeof(char) since cch < STRSAFE_MAX_CCH and sizeof(char) is 1
*pcb = cch * sizeof(char);
}
return hr;
}
STRSAFEAPI StringCbLengthW(const wchar_t* psz, size_t cbMax, size_t* pcb)
{
HRESULT hr;
size_t cchMax;
size_t cch = 0;
cchMax = cbMax / sizeof(wchar_t);
if ((psz == NULL) || (cchMax > STRSAFE_MAX_CCH))
{
hr = STRSAFE_E_INVALID_PARAMETER;
}
else
{
hr = StringLengthWorkerW(psz, cchMax, &cch);
}
if (SUCCEEDED(hr) && pcb)
{
// safe to multiply cch * sizeof(wchar_t) since cch < STRSAFE_MAX_CCH and sizeof(wchar_t) is 2
*pcb = cch * sizeof(wchar_t);
}
return hr;
}
#endif // STRSAFE_INLINE
#endif // !STRSAFE_NO_CB_FUNCTIONS
// these are the worker functions that actually do the work
#ifdef STRSAFE_INLINE
STRSAFEAPI StringCopyWorkerA(char* pszDest, size_t cchDest, const char* pszSrc)
{
HRESULT hr = S_OK;
if (cchDest == 0)
{
// can not null terminate a zero-byte dest buffer
hr = STRSAFE_E_INVALID_PARAMETER;
}
else
{
while (cchDest && (*pszSrc != '\0'))
{
*pszDest++ = *pszSrc++;
cchDest--;
}
if (cchDest == 0)
{
// we are going to truncate pszDest
pszDest--;
hr = STRSAFE_E_INSUFFICIENT_BUFFER;
}
*pszDest= '\0';
}
return hr;
}
STRSAFEAPI StringCopyWorkerW(wchar_t* pszDest, size_t cchDest, const wchar_t* pszSrc)
{
HRESULT hr = S_OK;
if (cchDest == 0)
{
// can not null terminate a zero-byte dest buffer
hr = STRSAFE_E_INVALID_PARAMETER;
}
else
{
while (cchDest && (*pszSrc != L'\0'))
{
*pszDest++ = *pszSrc++;
cchDest--;
}
if (cchDest == 0)
{
// we are going to truncate pszDest
pszDest--;
hr = STRSAFE_E_INSUFFICIENT_BUFFER;
}
*pszDest= L'\0';
}
return hr;
}
STRSAFEAPI StringCopyExWorkerA(char* pszDest, size_t cchDest, size_t cbDest, const char* pszSrc, char** ppszDestEnd, size_t* pcchRemaining, unsigned long dwFlags)
{
HRESULT hr = S_OK;
char* pszDestEnd = pszDest;
size_t cchRemaining = 0;
// ASSERT(cbDest == (cchDest * sizeof(char)) ||
// cbDest == (cchDest * sizeof(char)) + (cbDest % sizeof(char)));
// only accept valid flags
if (dwFlags & (~STRSAFE_VALID_FLAGS))
{
hr = STRSAFE_E_INVALID_PARAMETER;
}
else
{
if (dwFlags & STRSAFE_IGNORE_NULLS)
{
if (pszDest == NULL)
{
if ((cchDest != 0) || (cbDest != 0))
{
// NULL pszDest and non-zero cchDest/cbDest is invalid
hr = STRSAFE_E_INVALID_PARAMETER;
}
}
if (pszSrc == NULL)
{
pszSrc = "";
}
}
if (SUCCEEDED(hr))
{
if (cchDest == 0)
{
pszDestEnd = pszDest;
cchRemaining = 0;
// only fail if there was actually src data to copy
if (*pszSrc != '\0')
{
if (pszDest == NULL)
{
hr = STRSAFE_E_INVALID_PARAMETER;
}
else
{
hr = STRSAFE_E_INSUFFICIENT_BUFFER;
}
}
}
else
{
pszDestEnd = pszDest;
cchRemaining = cchDest;
while (cchRemaining && (*pszSrc != '\0'))
{
*pszDestEnd++= *pszSrc++;
cchRemaining--;
}
if (cchRemaining > 0)
{
if (dwFlags & STRSAFE_FILL_BEHIND_NULL)
{
memset(pszDestEnd + 1, STRSAFE_GET_FILL_PATTERN(dwFlags), ((cchRemaining - 1) * sizeof(char)) + (cbDest % sizeof(char)));
}
}
else
{
// we are going to truncate pszDest
pszDestEnd--;
cchRemaining++;
hr = STRSAFE_E_INSUFFICIENT_BUFFER;
}
*pszDestEnd = '\0';
}
}
}
if (FAILED(hr))
{
if (pszDest)
{
if (dwFlags & STRSAFE_FILL_ON_FAILURE)
{
memset(pszDest, STRSAFE_GET_FILL_PATTERN(dwFlags), cbDest);
if (STRSAFE_GET_FILL_PATTERN(dwFlags) == 0)
{
pszDestEnd = pszDest;
cchRemaining = cchDest;
}
else if (cchDest > 0)
{
pszDestEnd = pszDest + cchDest - 1;
cchRemaining = 1;
// null terminate the end of the string
*pszDestEnd = '\0';
}
}
if (dwFlags & (STRSAFE_NULL_ON_FAILURE | STRSAFE_NO_TRUNCATION))
{
if (cchDest > 0)
{
pszDestEnd = pszDest;
cchRemaining = cchDest;
// null terminate the beginning of the string
*pszDestEnd = '\0';
}
}
}
}
if (SUCCEEDED(hr) || (hr == STRSAFE_E_INSUFFICIENT_BUFFER))
{
if (ppszDestEnd)
{
*ppszDestEnd = pszDestEnd;
}
if (pcchRemaining)
{
*pcchRemaining = cchRemaining;
}
}
return hr;
}
STRSAFEAPI StringCopyExWorkerW(wchar_t* pszDest, size_t cchDest, size_t cbDest, const wchar_t* pszSrc, wchar_t** ppszDestEnd, size_t* pcchRemaining, unsigned long dwFlags)
{
HRESULT hr = S_OK;
wchar_t* pszDestEnd = pszDest;
size_t cchRemaining = 0;
// ASSERT(cbDest == (cchDest * sizeof(wchar_t)) ||
// cbDest == (cchDest * sizeof(wchar_t)) + (cbDest % sizeof(wchar_t)));
// only accept valid flags
if (dwFlags & (~STRSAFE_VALID_FLAGS))
{
hr = STRSAFE_E_INVALID_PARAMETER;
}
else
{
if (dwFlags & STRSAFE_IGNORE_NULLS)
{
if (pszDest == NULL)
{
if ((cchDest != 0) || (cbDest != 0))
{
// NULL pszDest and non-zero cchDest/cbDest is invalid
hr = STRSAFE_E_INVALID_PARAMETER;
}
}
if (pszSrc == NULL)
{
pszSrc = L"";
}
}
if (SUCCEEDED(hr))
{
if (cchDest == 0)
{
pszDestEnd = pszDest;
cchRemaining = 0;
// only fail if there was actually src data to copy
if (*pszSrc != L'\0')
{
if (pszDest == NULL)
{
hr = STRSAFE_E_INVALID_PARAMETER;
}
else
{
hr = STRSAFE_E_INSUFFICIENT_BUFFER;
}
}
}
else
{
pszDestEnd = pszDest;
cchRemaining = cchDest;
while (cchRemaining && (*pszSrc != L'\0'))
{
*pszDestEnd++= *pszSrc++;
cchRemaining--;
}
if (cchRemaining > 0)
{
if (dwFlags & STRSAFE_FILL_BEHIND_NULL)
{
memset(pszDestEnd + 1, STRSAFE_GET_FILL_PATTERN(dwFlags), ((cchRemaining - 1) * sizeof(wchar_t)) + (cbDest % sizeof(wchar_t)));
}
}
else
{
// we are going to truncate pszDest
pszDestEnd--;
cchRemaining++;
hr = STRSAFE_E_INSUFFICIENT_BUFFER;
}
*pszDestEnd = L'\0';
}
}
}
if (FAILED(hr))
{
if (pszDest)
{
if (dwFlags & STRSAFE_FILL_ON_FAILURE)
{
memset(pszDest, STRSAFE_GET_FILL_PATTERN(dwFlags), cbDest);
if (STRSAFE_GET_FILL_PATTERN(dwFlags) == 0)
{
pszDestEnd = pszDest;
cchRemaining = cchDest;
}
else if (cchDest > 0)
{
pszDestEnd = pszDest + cchDest - 1;
cchRemaining = 1;
// null terminate the end of the string
*pszDestEnd = L'\0';
}
}
if (dwFlags & (STRSAFE_NULL_ON_FAILURE | STRSAFE_NO_TRUNCATION))
{
if (cchDest > 0)
{
pszDestEnd = pszDest;
cchRemaining = cchDest;
// null terminate the beginning of the string
*pszDestEnd = L'\0';
}
}
}
}
if (SUCCEEDED(hr) || (hr == STRSAFE_E_INSUFFICIENT_BUFFER))
{
if (ppszDestEnd)
{
*ppszDestEnd = pszDestEnd;
}
if (pcchRemaining)
{
*pcchRemaining = cchRemaining;
}
}
return hr;
}
STRSAFEAPI StringCopyNWorkerA(char* pszDest, size_t cchDest, const char* pszSrc, size_t cchSrc)
{
HRESULT hr = S_OK;
if (cchDest == 0)
{
// can not null terminate a zero-byte dest buffer
hr = STRSAFE_E_INVALID_PARAMETER;
}
else
{
while (cchDest && cchSrc && (*pszSrc != '\0'))
{
*pszDest++= *pszSrc++;
cchDest--;
cchSrc--;
}
if (cchDest == 0)
{
// we are going to truncate pszDest
pszDest--;
hr = STRSAFE_E_INSUFFICIENT_BUFFER;
}
*pszDest= '\0';
}
return hr;
}
STRSAFEAPI StringCopyNWorkerW(wchar_t* pszDest, size_t cchDest, const wchar_t* pszSrc, size_t cchSrc)
{
HRESULT hr = S_OK;
if (cchDest == 0)
{
// can not null terminate a zero-byte dest buffer
hr = STRSAFE_E_INVALID_PARAMETER;
}
else
{
while (cchDest && cchSrc && (*pszSrc != L'\0'))
{
*pszDest++= *pszSrc++;
cchDest--;
cchSrc--;
}
if (cchDest == 0)
{
// we are going to truncate pszDest
pszDest--;
hr = STRSAFE_E_INSUFFICIENT_BUFFER;
}
*pszDest= L'\0';
}
return hr;
}
STRSAFEAPI StringCopyNExWorkerA(char* pszDest, size_t cchDest, size_t cbDest, const char* pszSrc, size_t cchSrc, char** ppszDestEnd, size_t* pcchRemaining, unsigned long dwFlags)
{
HRESULT hr = S_OK;
char* pszDestEnd = pszDest;
size_t cchRemaining = 0;
// ASSERT(cbDest == (cchDest * sizeof(char)) ||
// cbDest == (cchDest * sizeof(char)) + (cbDest % sizeof(char)));
// only accept valid flags
if (dwFlags & (~STRSAFE_VALID_FLAGS))
{
hr = STRSAFE_E_INVALID_PARAMETER;
}
else
{
if (dwFlags & STRSAFE_IGNORE_NULLS)
{
if (pszDest == NULL)
{
if ((cchDest != 0) || (cbDest != 0))
{
// NULL pszDest and non-zero cchDest/cbDest is invalid
hr = STRSAFE_E_INVALID_PARAMETER;
}
}
if (pszSrc == NULL)
{
pszSrc = "";
}
}
if (SUCCEEDED(hr))
{
if (cchDest == 0)
{
pszDestEnd = pszDest;
cchRemaining = 0;
// only fail if there was actually src data to copy
if (*pszSrc != '\0')
{
if (pszDest == NULL)
{
hr = STRSAFE_E_INVALID_PARAMETER;
}
else
{
hr = STRSAFE_E_INSUFFICIENT_BUFFER;
}
}
}
else
{
pszDestEnd = pszDest;
cchRemaining = cchDest;
while (cchRemaining && cchSrc && (*pszSrc != '\0'))
{
*pszDestEnd++= *pszSrc++;
cchRemaining--;
cchSrc--;
}
if (cchRemaining > 0)
{
if (dwFlags & STRSAFE_FILL_BEHIND_NULL)
{
memset(pszDestEnd + 1, STRSAFE_GET_FILL_PATTERN(dwFlags), ((cchRemaining - 1) * sizeof(char)) + (cbDest % sizeof(char)));
}
}
else
{
// we are going to truncate pszDest
pszDestEnd--;
cchRemaining++;
hr = STRSAFE_E_INSUFFICIENT_BUFFER;
}
*pszDestEnd = '\0';
}
}
}
if (FAILED(hr))
{
if (pszDest)
{
if (dwFlags & STRSAFE_FILL_ON_FAILURE)
{
memset(pszDest, STRSAFE_GET_FILL_PATTERN(dwFlags), cbDest);
if (STRSAFE_GET_FILL_PATTERN(dwFlags) == 0)
{
pszDestEnd = pszDest;
cchRemaining = cchDest;
}
else if (cchDest > 0)
{
pszDestEnd = pszDest + cchDest - 1;
cchRemaining = 1;
// null terminate the end of the string
*pszDestEnd = '\0';
}
}
if (dwFlags & (STRSAFE_NULL_ON_FAILURE | STRSAFE_NO_TRUNCATION))
{
if (cchDest > 0)
{
pszDestEnd = pszDest;
cchRemaining = cchDest;
// null terminate the beginning of the string
*pszDestEnd = '\0';
}
}
}
}
if (SUCCEEDED(hr) || (hr == STRSAFE_E_INSUFFICIENT_BUFFER))
{
if (ppszDestEnd)
{
*ppszDestEnd = pszDestEnd;
}
if (pcchRemaining)
{
*pcchRemaining = cchRemaining;
}
}
return hr;
}
STRSAFEAPI StringCopyNExWorkerW(wchar_t* pszDest, size_t cchDest, size_t cbDest, const wchar_t* pszSrc, size_t cchSrc, wchar_t** ppszDestEnd, size_t* pcchRemaining, unsigned long dwFlags)
{
HRESULT hr = S_OK;
wchar_t* pszDestEnd = pszDest;
size_t cchRemaining = 0;
// ASSERT(cbDest == (cchDest * sizeof(wchar_t)) ||
// cbDest == (cchDest * sizeof(wchar_t)) + (cbDest % sizeof(wchar_t)));
// only accept valid flags
if (dwFlags & (~STRSAFE_VALID_FLAGS))
{
hr = STRSAFE_E_INVALID_PARAMETER;
}
else
{
if (dwFlags & STRSAFE_IGNORE_NULLS)
{
if (pszDest == NULL)
{
if ((cchDest != 0) || (cbDest != 0))
{
// NULL pszDest and non-zero cchDest/cbDest is invalid
hr = STRSAFE_E_INVALID_PARAMETER;
}
}
if (pszSrc == NULL)
{
pszSrc = L"";
}
}
if (SUCCEEDED(hr))
{
if (cchDest == 0)
{
pszDestEnd = pszDest;
cchRemaining = 0;
// only fail if there was actually src data to copy
if (*pszSrc != L'\0')
{
if (pszDest == NULL)
{
hr = STRSAFE_E_INVALID_PARAMETER;
}
else
{
hr = STRSAFE_E_INSUFFICIENT_BUFFER;
}
}
}
else
{
pszDestEnd = pszDest;
cchRemaining = cchDest;
while (cchRemaining && cchSrc && (*pszSrc != L'\0'))
{
*pszDestEnd++= *pszSrc++;
cchRemaining--;
cchSrc--;
}
if (cchRemaining > 0)
{
if (dwFlags & STRSAFE_FILL_BEHIND_NULL)
{
memset(pszDestEnd + 1, STRSAFE_GET_FILL_PATTERN(dwFlags), ((cchRemaining - 1) * sizeof(wchar_t)) + (cbDest % sizeof(wchar_t)));
}
}
else
{
// we are going to truncate pszDest
pszDestEnd--;
cchRemaining++;
hr = STRSAFE_E_INSUFFICIENT_BUFFER;
}
*pszDestEnd = L'\0';
}
}
}
if (FAILED(hr))
{
if (pszDest)
{
if (dwFlags & STRSAFE_FILL_ON_FAILURE)
{
memset(pszDest, STRSAFE_GET_FILL_PATTERN(dwFlags), cbDest);
if (STRSAFE_GET_FILL_PATTERN(dwFlags) == 0)
{
pszDestEnd = pszDest;
cchRemaining = cchDest;
}
else if (cchDest > 0)
{
pszDestEnd = pszDest + cchDest - 1;
cchRemaining = 1;
// null terminate the end of the string
*pszDestEnd = L'\0';
}
}
if (dwFlags & (STRSAFE_NULL_ON_FAILURE | STRSAFE_NO_TRUNCATION))
{
if (cchDest > 0)
{
pszDestEnd = pszDest;
cchRemaining = cchDest;
// null terminate the beginning of the string
*pszDestEnd = L'\0';
}
}
}
}
if (SUCCEEDED(hr) || (hr == STRSAFE_E_INSUFFICIENT_BUFFER))
{
if (ppszDestEnd)
{
*ppszDestEnd = pszDestEnd;
}
if (pcchRemaining)
{
*pcchRemaining = cchRemaining;
}
}
return hr;
}
STRSAFEAPI StringCatWorkerA(char* pszDest, size_t cchDest, const char* pszSrc)
{
HRESULT hr;
size_t cchDestCurrent;
hr = StringLengthWorkerA(pszDest, cchDest, &cchDestCurrent);
if (SUCCEEDED(hr))
{
hr = StringCopyWorkerA(pszDest + cchDestCurrent,
cchDest - cchDestCurrent,
pszSrc);
}
return hr;
}
STRSAFEAPI StringCatWorkerW(wchar_t* pszDest, size_t cchDest, const wchar_t* pszSrc)
{
HRESULT hr;
size_t cchDestCurrent;
hr = StringLengthWorkerW(pszDest, cchDest, &cchDestCurrent);
if (SUCCEEDED(hr))
{
hr = StringCopyWorkerW(pszDest + cchDestCurrent,
cchDest - cchDestCurrent,
pszSrc);
}
return hr;
}
STRSAFEAPI StringCatExWorkerA(char* pszDest, size_t cchDest, size_t cbDest, const char* pszSrc, char** ppszDestEnd, size_t* pcchRemaining, unsigned long dwFlags)
{
HRESULT hr = S_OK;
char* pszDestEnd = pszDest;
size_t cchRemaining = 0;
// ASSERT(cbDest == (cchDest * sizeof(char)) ||
// cbDest == (cchDest * sizeof(char)) + (cbDest % sizeof(char)));
// only accept valid flags
if (dwFlags & (~STRSAFE_VALID_FLAGS))
{
hr = STRSAFE_E_INVALID_PARAMETER;
}
else
{
size_t cchDestCurrent;
if (dwFlags & STRSAFE_IGNORE_NULLS)
{
if (pszDest == NULL)
{
if ((cchDest == 0) && (cbDest == 0))
{
cchDestCurrent = 0;
}
else
{
// NULL pszDest and non-zero cchDest/cbDest is invalid
hr = STRSAFE_E_INVALID_PARAMETER;
}
}
else
{
hr = StringLengthWorkerA(pszDest, cchDest, &cchDestCurrent);
if (SUCCEEDED(hr))
{
pszDestEnd = pszDest + cchDestCurrent;
cchRemaining = cchDest - cchDestCurrent;
}
}
if (pszSrc == NULL)
{
pszSrc = "";
}
}
else
{
hr = StringLengthWorkerA(pszDest, cchDest, &cchDestCurrent);
if (SUCCEEDED(hr))
{
pszDestEnd = pszDest + cchDestCurrent;
cchRemaining = cchDest - cchDestCurrent;
}
}
if (SUCCEEDED(hr))
{
if (cchDest == 0)
{
// only fail if there was actually src data to append
if (*pszSrc != '\0')
{
if (pszDest == NULL)
{
hr = STRSAFE_E_INVALID_PARAMETER;
}
else
{
hr = STRSAFE_E_INSUFFICIENT_BUFFER;
}
}
}
else
{
// we handle the STRSAFE_FILL_ON_FAILURE and STRSAFE_NULL_ON_FAILURE cases below, so do not pass
// those flags through
hr = StringCopyExWorkerA(pszDestEnd,
cchRemaining,
(cchRemaining * sizeof(char)) + (cbDest % sizeof(char)),
pszSrc,
&pszDestEnd,
&cchRemaining,
dwFlags & (~(STRSAFE_FILL_ON_FAILURE | STRSAFE_NULL_ON_FAILURE)));
}
}
}
if (FAILED(hr))
{
if (pszDest)
{
// STRSAFE_NO_TRUNCATION is taken care of by StringCopyExWorkerA()
if (dwFlags & STRSAFE_FILL_ON_FAILURE)
{
memset(pszDest, STRSAFE_GET_FILL_PATTERN(dwFlags), cbDest);
if (STRSAFE_GET_FILL_PATTERN(dwFlags) == 0)
{
pszDestEnd = pszDest;
cchRemaining = cchDest;
}
else
if (cchDest > 0)
{
pszDestEnd = pszDest + cchDest - 1;
cchRemaining = 1;
// null terminate the end of the string
*pszDestEnd = '\0';
}
}
if (dwFlags & STRSAFE_NULL_ON_FAILURE)
{
if (cchDest > 0)
{
pszDestEnd = pszDest;
cchRemaining = cchDest;
// null terminate the beginning of the string
*pszDestEnd = '\0';
}
}
}
}
if (SUCCEEDED(hr) || (hr == STRSAFE_E_INSUFFICIENT_BUFFER))
{
if (ppszDestEnd)
{
*ppszDestEnd = pszDestEnd;
}
if (pcchRemaining)
{
*pcchRemaining = cchRemaining;
}
}
return hr;
}
STRSAFEAPI StringCatExWorkerW(wchar_t* pszDest, size_t cchDest, size_t cbDest, const wchar_t* pszSrc, wchar_t** ppszDestEnd, size_t* pcchRemaining, unsigned long dwFlags)
{
HRESULT hr = S_OK;
wchar_t* pszDestEnd = pszDest;
size_t cchRemaining = 0;
// ASSERT(cbDest == (cchDest * sizeof(wchar_t)) ||
// cbDest == (cchDest * sizeof(wchar_t)) + (cbDest % sizeof(wchar_t)));
// only accept valid flags
if (dwFlags & (~STRSAFE_VALID_FLAGS))
{
hr = STRSAFE_E_INVALID_PARAMETER;
}
else
{
size_t cchDestCurrent;
if (dwFlags & STRSAFE_IGNORE_NULLS)
{
if (pszDest == NULL)
{
if ((cchDest == 0) && (cbDest == 0))
{
cchDestCurrent = 0;
}
else
{
// NULL pszDest and non-zero cchDest/cbDest is invalid
hr = STRSAFE_E_INVALID_PARAMETER;
}
}
else
{
hr = StringLengthWorkerW(pszDest, cchDest, &cchDestCurrent);
if (SUCCEEDED(hr))
{
pszDestEnd = pszDest + cchDestCurrent;
cchRemaining = cchDest - cchDestCurrent;
}
}
if (pszSrc == NULL)
{
pszSrc = L"";
}
}
else
{
hr = StringLengthWorkerW(pszDest, cchDest, &cchDestCurrent);
if (SUCCEEDED(hr))
{
pszDestEnd = pszDest + cchDestCurrent;
cchRemaining = cchDest - cchDestCurrent;
}
}
if (SUCCEEDED(hr))
{
if (cchDest == 0)
{
// only fail if there was actually src data to append
if (*pszSrc != L'\0')
{
if (pszDest == NULL)
{
hr = STRSAFE_E_INVALID_PARAMETER;
}
else
{
hr = STRSAFE_E_INSUFFICIENT_BUFFER;
}
}
}
else
{
// we handle the STRSAFE_FILL_ON_FAILURE and STRSAFE_NULL_ON_FAILURE cases below, so do not pass
// those flags through
hr = StringCopyExWorkerW(pszDestEnd,
cchRemaining,
(cchRemaining * sizeof(wchar_t)) + (cbDest % sizeof(wchar_t)),
pszSrc,
&pszDestEnd,
&cchRemaining,
dwFlags & (~(STRSAFE_FILL_ON_FAILURE | STRSAFE_NULL_ON_FAILURE)));
}
}
}
if (FAILED(hr))
{
if (pszDest)
{
// STRSAFE_NO_TRUNCATION is taken care of by StringCopyExWorkerW()
if (dwFlags & STRSAFE_FILL_ON_FAILURE)
{
memset(pszDest, STRSAFE_GET_FILL_PATTERN(dwFlags), cbDest);
if (STRSAFE_GET_FILL_PATTERN(dwFlags) == 0)
{
pszDestEnd = pszDest;
cchRemaining = cchDest;
}
else if (cchDest > 0)
{
pszDestEnd = pszDest + cchDest - 1;
cchRemaining = 1;
// null terminate the end of the string
*pszDestEnd = L'\0';
}
}
if (dwFlags & STRSAFE_NULL_ON_FAILURE)
{
if (cchDest > 0)
{
pszDestEnd = pszDest;
cchRemaining = cchDest;
// null terminate the beginning of the string
*pszDestEnd = L'\0';
}
}
}
}
if (SUCCEEDED(hr) || (hr == STRSAFE_E_INSUFFICIENT_BUFFER))
{
if (ppszDestEnd)
{
*ppszDestEnd = pszDestEnd;
}
if (pcchRemaining)
{
*pcchRemaining = cchRemaining;
}
}
return hr;
}
STRSAFEAPI StringCatNWorkerA(char* pszDest, size_t cchDest, const char* pszSrc, size_t cchMaxAppend)
{
HRESULT hr;
size_t cchDestCurrent;
hr = StringLengthWorkerA(pszDest, cchDest, &cchDestCurrent);
if (SUCCEEDED(hr))
{
hr = StringCopyNWorkerA(pszDest + cchDestCurrent,
cchDest - cchDestCurrent,
pszSrc,
cchMaxAppend);
}
return hr;
}
STRSAFEAPI StringCatNWorkerW(wchar_t* pszDest, size_t cchDest, const wchar_t* pszSrc, size_t cchMaxAppend)
{
HRESULT hr;
size_t cchDestCurrent;
hr = StringLengthWorkerW(pszDest, cchDest, &cchDestCurrent);
if (SUCCEEDED(hr))
{
hr = StringCopyNWorkerW(pszDest + cchDestCurrent,
cchDest - cchDestCurrent,
pszSrc,
cchMaxAppend);
}
return hr;
}
STRSAFEAPI StringCatNExWorkerA(char* pszDest, size_t cchDest, size_t cbDest, const char* pszSrc, size_t cchMaxAppend, char** ppszDestEnd, size_t* pcchRemaining, unsigned long dwFlags)
{
HRESULT hr = S_OK;
char* pszDestEnd = pszDest;
size_t cchRemaining = 0;
size_t cchDestCurrent = 0;
// ASSERT(cbDest == (cchDest * sizeof(char)) ||
// cbDest == (cchDest * sizeof(char)) + (cbDest % sizeof(char)));
// only accept valid flags
if (dwFlags & (~STRSAFE_VALID_FLAGS))
{
hr = STRSAFE_E_INVALID_PARAMETER;
}
else
{
if (dwFlags & STRSAFE_IGNORE_NULLS)
{
if (pszDest == NULL)
{
if ((cchDest == 0) && (cbDest == 0))
{
cchDestCurrent = 0;
}
else
{
// NULL pszDest and non-zero cchDest/cbDest is invalid
hr = STRSAFE_E_INVALID_PARAMETER;
}
}
else
{
hr = StringLengthWorkerA(pszDest, cchDest, &cchDestCurrent);
if (SUCCEEDED(hr))
{
pszDestEnd = pszDest + cchDestCurrent;
cchRemaining = cchDest - cchDestCurrent;
}
}
if (pszSrc == NULL)
{
pszSrc = "";
}
}
else
{
hr = StringLengthWorkerA(pszDest, cchDest, &cchDestCurrent);
if (SUCCEEDED(hr))
{
pszDestEnd = pszDest + cchDestCurrent;
cchRemaining = cchDest - cchDestCurrent;
}
}
if (SUCCEEDED(hr))
{
if (cchDest == 0)
{
// only fail if there was actually src data to append
if (*pszSrc != '\0')
{
if (pszDest == NULL)
{
hr = STRSAFE_E_INVALID_PARAMETER;
}
else
{
hr = STRSAFE_E_INSUFFICIENT_BUFFER;
}
}
}
else
{
// we handle the STRSAFE_FILL_ON_FAILURE and STRSAFE_NULL_ON_FAILURE cases below, so do not pass
// those flags through
hr = StringCopyNExWorkerA(pszDestEnd,
cchRemaining,
(cchRemaining * sizeof(char)) + (cbDest % sizeof(char)),
pszSrc,
cchMaxAppend,
&pszDestEnd,
&cchRemaining,
dwFlags & (~(STRSAFE_FILL_ON_FAILURE | STRSAFE_NULL_ON_FAILURE)));
}
}
}
if (FAILED(hr))
{
if (pszDest)
{
// STRSAFE_NO_TRUNCATION is taken care of by StringCopyNExWorkerA()
if (dwFlags & STRSAFE_FILL_ON_FAILURE)
{
memset(pszDest, STRSAFE_GET_FILL_PATTERN(dwFlags), cbDest);
if (STRSAFE_GET_FILL_PATTERN(dwFlags) == 0)
{
pszDestEnd = pszDest;
cchRemaining = cchDest;
}
else if (cchDest > 0)
{
pszDestEnd = pszDest + cchDest - 1;
cchRemaining = 1;
// null terminate the end of the string
*pszDestEnd = '\0';
}
}
if (dwFlags & (STRSAFE_NULL_ON_FAILURE))
{
if (cchDest > 0)
{
pszDestEnd = pszDest;
cchRemaining = cchDest;
// null terminate the beginning of the string
*pszDestEnd = '\0';
}
}
}
}
if (SUCCEEDED(hr) || (hr == STRSAFE_E_INSUFFICIENT_BUFFER))
{
if (ppszDestEnd)
{
*ppszDestEnd = pszDestEnd;
}
if (pcchRemaining)
{
*pcchRemaining = cchRemaining;
}
}
return hr;
}
STRSAFEAPI StringCatNExWorkerW(wchar_t* pszDest, size_t cchDest, size_t cbDest, const wchar_t* pszSrc, size_t cchMaxAppend, wchar_t** ppszDestEnd, size_t* pcchRemaining, unsigned long dwFlags)
{
HRESULT hr = S_OK;
wchar_t* pszDestEnd = pszDest;
size_t cchRemaining = 0;
size_t cchDestCurrent = 0;
// ASSERT(cbDest == (cchDest * sizeof(wchar_t)) ||
// cbDest == (cchDest * sizeof(wchar_t)) + (cbDest % sizeof(wchar_t)));
// only accept valid flags
if (dwFlags & (~STRSAFE_VALID_FLAGS))
{
hr = STRSAFE_E_INVALID_PARAMETER;
}
else
{
if (dwFlags & STRSAFE_IGNORE_NULLS)
{
if (pszDest == NULL)
{
if ((cchDest == 0) && (cbDest == 0))
{
cchDestCurrent = 0;
}
else
{
// NULL pszDest and non-zero cchDest/cbDest is invalid
hr = STRSAFE_E_INVALID_PARAMETER;
}
}
else
{
hr = StringLengthWorkerW(pszDest, cchDest, &cchDestCurrent);
if (SUCCEEDED(hr))
{
pszDestEnd = pszDest + cchDestCurrent;
cchRemaining = cchDest - cchDestCurrent;
}
}
if (pszSrc == NULL)
{
pszSrc = L"";
}
}
else
{
hr = StringLengthWorkerW(pszDest, cchDest, &cchDestCurrent);
if (SUCCEEDED(hr))
{
pszDestEnd = pszDest + cchDestCurrent;
cchRemaining = cchDest - cchDestCurrent;
}
}
if (SUCCEEDED(hr))
{
if (cchDest == 0)
{
// only fail if there was actually src data to append
if (*pszSrc != L'\0')
{
if (pszDest == NULL)
{
hr = STRSAFE_E_INVALID_PARAMETER;
}
else
{
hr = STRSAFE_E_INSUFFICIENT_BUFFER;
}
}
}
else
{
// we handle the STRSAFE_FILL_ON_FAILURE and STRSAFE_NULL_ON_FAILURE cases below, so do not pass
// those flags through
hr = StringCopyNExWorkerW(pszDestEnd,
cchRemaining,
(cchRemaining * sizeof(wchar_t)) + (cbDest % sizeof(wchar_t)),
pszSrc,
cchMaxAppend,
&pszDestEnd,
&cchRemaining,
dwFlags & (~(STRSAFE_FILL_ON_FAILURE | STRSAFE_NULL_ON_FAILURE)));
}
}
}
if (FAILED(hr))
{
if (pszDest)
{
// STRSAFE_NO_TRUNCATION is taken care of by StringCopyNExWorkerW()
if (dwFlags & STRSAFE_FILL_ON_FAILURE)
{
memset(pszDest, STRSAFE_GET_FILL_PATTERN(dwFlags), cbDest);
if (STRSAFE_GET_FILL_PATTERN(dwFlags) == 0)
{
pszDestEnd = pszDest;
cchRemaining = cchDest;
}
else if (cchDest > 0)
{
pszDestEnd = pszDest + cchDest - 1;
cchRemaining = 1;
// null terminate the end of the string
*pszDestEnd = L'\0';
}
}
if (dwFlags & (STRSAFE_NULL_ON_FAILURE))
{
if (cchDest > 0)
{
pszDestEnd = pszDest;
cchRemaining = cchDest;
// null terminate the beginning of the string
*pszDestEnd = L'\0';
}
}
}
}
if (SUCCEEDED(hr) || (hr == STRSAFE_E_INSUFFICIENT_BUFFER))
{
if (ppszDestEnd)
{
*ppszDestEnd = pszDestEnd;
}
if (pcchRemaining)
{
*pcchRemaining = cchRemaining;
}
}
return hr;
}
STRSAFEAPI StringVPrintfWorkerA(char* pszDest, size_t cchDest, const char* pszFormat, va_list argList)
{
HRESULT hr = S_OK;
if (cchDest == 0)
{
// can not null terminate a zero-byte dest buffer
hr = STRSAFE_E_INVALID_PARAMETER;
}
else
{
int iRet;
size_t cchMax;
// leave the last space for the null terminator
cchMax = cchDest - 1;
iRet = _vsnprintf(pszDest, cchMax, pszFormat, argList);
// ASSERT((iRet < 0) || (((size_t)iRet) <= cchMax));
if ((iRet < 0) || (((size_t)iRet) > cchMax))
{
// need to null terminate the string
pszDest += cchMax;
*pszDest = '\0';
// we have truncated pszDest
hr = STRSAFE_E_INSUFFICIENT_BUFFER;
}
else if (((size_t)iRet) == cchMax)
{
// need to null terminate the string
pszDest += cchMax;
*pszDest = '\0';
}
}
return hr;
}
STRSAFEAPI StringVPrintfWorkerW(wchar_t* pszDest, size_t cchDest, const wchar_t* pszFormat, va_list argList)
{
HRESULT hr = S_OK;
if (cchDest == 0)
{
// can not null terminate a zero-byte dest buffer
hr = STRSAFE_E_INVALID_PARAMETER;
}
else
{
int iRet;
size_t cchMax;
// leave the last space for the null terminator
cchMax = cchDest - 1;
iRet = _vsnwprintf(pszDest, cchMax, pszFormat, argList);
// ASSERT((iRet < 0) || (((size_t)iRet) <= cchMax));
if ((iRet < 0) || (((size_t)iRet) > cchMax))
{
// need to null terminate the string
pszDest += cchMax;
*pszDest = L'\0';
// we have truncated pszDest
hr = STRSAFE_E_INSUFFICIENT_BUFFER;
}
else if (((size_t)iRet) == cchMax)
{
// need to null terminate the string
pszDest += cchMax;
*pszDest = L'\0';
}
}
return hr;
}
STRSAFEAPI StringVPrintfExWorkerA(char* pszDest, size_t cchDest, size_t cbDest, char** ppszDestEnd, size_t* pcchRemaining, unsigned long dwFlags, const char* pszFormat, va_list argList)
{
HRESULT hr = S_OK;
char* pszDestEnd = pszDest;
size_t cchRemaining = 0;
// ASSERT(cbDest == (cchDest * sizeof(char)) ||
// cbDest == (cchDest * sizeof(char)) + (cbDest % sizeof(char)));
// only accept valid flags
if (dwFlags & (~STRSAFE_VALID_FLAGS))
{
hr = STRSAFE_E_INVALID_PARAMETER;
}
else
{
if (dwFlags & STRSAFE_IGNORE_NULLS)
{
if (pszDest == NULL)
{
if ((cchDest != 0) || (cbDest != 0))
{
// NULL pszDest and non-zero cchDest/cbDest is invalid
hr = STRSAFE_E_INVALID_PARAMETER;
}
}
if (pszFormat == NULL)
{
pszFormat = "";
}
}
if (SUCCEEDED(hr))
{
if (cchDest == 0)
{
pszDestEnd = pszDest;
cchRemaining = 0;
// only fail if there was actually a non-empty format string
if (*pszFormat != '\0')
{
if (pszDest == NULL)
{
hr = STRSAFE_E_INVALID_PARAMETER;
}
else
{
hr = STRSAFE_E_INSUFFICIENT_BUFFER;
}
}
}
else
{
int iRet;
size_t cchMax;
// leave the last space for the null terminator
cchMax = cchDest - 1;
iRet = _vsnprintf(pszDest, cchMax, pszFormat, argList);
// ASSERT((iRet < 0) || (((size_t)iRet) <= cchMax));
if ((iRet < 0) || (((size_t)iRet) > cchMax))
{
// we have truncated pszDest
pszDestEnd = pszDest + cchMax;
cchRemaining = 1;
// need to null terminate the string
*pszDestEnd = '\0';
hr = STRSAFE_E_INSUFFICIENT_BUFFER;
}
else if (((size_t)iRet) == cchMax)
{
// string fit perfectly
pszDestEnd = pszDest + cchMax;
cchRemaining = 1;
// need to null terminate the string
*pszDestEnd = '\0';
}
else if (((size_t)iRet) < cchMax)
{
// there is extra room
pszDestEnd = pszDest + iRet;
cchRemaining = cchDest - iRet;
if (dwFlags & STRSAFE_FILL_BEHIND_NULL)
{
memset(pszDestEnd + 1, STRSAFE_GET_FILL_PATTERN(dwFlags), ((cchRemaining - 1) * sizeof(char)) + (cbDest % sizeof(char)));
}
}
}
}
}
if (FAILED(hr))
{
if (pszDest)
{
if (dwFlags & STRSAFE_FILL_ON_FAILURE)
{
memset(pszDest, STRSAFE_GET_FILL_PATTERN(dwFlags), cbDest);
if (STRSAFE_GET_FILL_PATTERN(dwFlags) == 0)
{
pszDestEnd = pszDest;
cchRemaining = cchDest;
}
else if (cchDest > 0)
{
pszDestEnd = pszDest + cchDest - 1;
cchRemaining = 1;
// null terminate the end of the string
*pszDestEnd = '\0';
}
}
if (dwFlags & (STRSAFE_NULL_ON_FAILURE | STRSAFE_NO_TRUNCATION))
{
if (cchDest > 0)
{
pszDestEnd = pszDest;
cchRemaining = cchDest;
// null terminate the beginning of the string
*pszDestEnd = '\0';
}
}
}
}
if (SUCCEEDED(hr) || (hr == STRSAFE_E_INSUFFICIENT_BUFFER))
{
if (ppszDestEnd)
{
*ppszDestEnd = pszDestEnd;
}
if (pcchRemaining)
{
*pcchRemaining = cchRemaining;
}
}
return hr;
}
STRSAFEAPI StringVPrintfExWorkerW(wchar_t* pszDest, size_t cchDest, size_t cbDest, wchar_t** ppszDestEnd, size_t* pcchRemaining, unsigned long dwFlags, const wchar_t* pszFormat, va_list argList)
{
HRESULT hr = S_OK;
wchar_t* pszDestEnd = pszDest;
size_t cchRemaining = 0;
// ASSERT(cbDest == (cchDest * sizeof(wchar_t)) ||
// cbDest == (cchDest * sizeof(wchar_t)) + (cbDest % sizeof(wchar_t)));
// only accept valid flags
if (dwFlags & (~STRSAFE_VALID_FLAGS))
{
hr = STRSAFE_E_INVALID_PARAMETER;
}
else
{
if (dwFlags & STRSAFE_IGNORE_NULLS)
{
if (pszDest == NULL)
{
if ((cchDest != 0) || (cbDest != 0))
{
// NULL pszDest and non-zero cchDest/cbDest is invalid
hr = STRSAFE_E_INVALID_PARAMETER;
}
}
if (pszFormat == NULL)
{
pszFormat = L"";
}
}
if (SUCCEEDED(hr))
{
if (cchDest == 0)
{
pszDestEnd = pszDest;
cchRemaining = 0;
// only fail if there was actually a non-empty format string
if (*pszFormat != L'\0')
{
if (pszDest == NULL)
{
hr = STRSAFE_E_INVALID_PARAMETER;
}
else
{
hr = STRSAFE_E_INSUFFICIENT_BUFFER;
}
}
}
else
{
int iRet;
size_t cchMax;
// leave the last space for the null terminator
cchMax = cchDest - 1;
iRet = _vsnwprintf(pszDest, cchMax, pszFormat, argList);
// ASSERT((iRet < 0) || (((size_t)iRet) <= cchMax));
if ((iRet < 0) || (((size_t)iRet) > cchMax))
{
// we have truncated pszDest
pszDestEnd = pszDest + cchMax;
cchRemaining = 1;
// need to null terminate the string
*pszDestEnd = L'\0';
hr = STRSAFE_E_INSUFFICIENT_BUFFER;
}
else if (((size_t)iRet) == cchMax)
{
// string fit perfectly
pszDestEnd = pszDest + cchMax;
cchRemaining = 1;
// need to null terminate the string
*pszDestEnd = L'\0';
}
else if (((size_t)iRet) < cchMax)
{
// there is extra room
pszDestEnd = pszDest + iRet;
cchRemaining = cchDest - iRet;
if (dwFlags & STRSAFE_FILL_BEHIND_NULL)
{
memset(pszDestEnd + 1, STRSAFE_GET_FILL_PATTERN(dwFlags), ((cchRemaining - 1) * sizeof(wchar_t)) + (cbDest % sizeof(wchar_t)));
}
}
}
}
}
if (FAILED(hr))
{
if (pszDest)
{
if (dwFlags & STRSAFE_FILL_ON_FAILURE)
{
memset(pszDest, STRSAFE_GET_FILL_PATTERN(dwFlags), cbDest);
if (STRSAFE_GET_FILL_PATTERN(dwFlags) == 0)
{
pszDestEnd = pszDest;
cchRemaining = cchDest;
}
else if (cchDest > 0)
{
pszDestEnd = pszDest + cchDest - 1;
cchRemaining = 1;
// null terminate the end of the string
*pszDestEnd = L'\0';
}
}
if (dwFlags & (STRSAFE_NULL_ON_FAILURE | STRSAFE_NO_TRUNCATION))
{
if (cchDest > 0)
{
pszDestEnd = pszDest;
cchRemaining = cchDest;
// null terminate the beginning of the string
*pszDestEnd = L'\0';
}
}
}
}
if (SUCCEEDED(hr) || (hr == STRSAFE_E_INSUFFICIENT_BUFFER))
{
if (ppszDestEnd)
{
*ppszDestEnd = pszDestEnd;
}
if (pcchRemaining)
{
*pcchRemaining = cchRemaining;
}
}
return hr;
}
STRSAFEAPI StringLengthWorkerA(const char* psz, size_t cchMax, size_t* pcch)
{
HRESULT hr = S_OK;
size_t cchMaxPrev = cchMax;
while (cchMax && (*psz != '\0'))
{
psz++;
cchMax--;
}
if (cchMax == 0)
{
// the string is longer than cchMax
hr = STRSAFE_E_INVALID_PARAMETER;
}
if (SUCCEEDED(hr) && pcch)
{
*pcch = cchMaxPrev - cchMax;
}
return hr;
}
STRSAFEAPI StringLengthWorkerW(const wchar_t* psz, size_t cchMax, size_t* pcch)
{
HRESULT hr = S_OK;
size_t cchMaxPrev = cchMax;
while (cchMax && (*psz != L'\0'))
{
psz++;
cchMax--;
}
if (cchMax == 0)
{
// the string is longer than cchMax
hr = STRSAFE_E_INVALID_PARAMETER;
}
if (SUCCEEDED(hr) && pcch)
{
*pcch = cchMaxPrev - cchMax;
}
return hr;
}
#endif // STRSAFE_INLINE
// end_strsafe end_ntstrsafe
// begin_strsafe
#ifndef STRSAFE_LIB_IMPL
STRSAFE_INLINE_API StringGetsExWorkerA(char* pszDest, size_t cchDest, size_t cbDest, char** ppszDestEnd, size_t* pcchRemaining, unsigned long dwFlags)
{
HRESULT hr = S_OK;
char* pszDestEnd = pszDest;
size_t cchRemaining = 0;
// ASSERT(cbDest == (cchDest * sizeof(char)) ||
// cbDest == (cchDest * sizeof(char)) + (cbDest % sizeof(char)));
// only accept valid flags
if (dwFlags & (~STRSAFE_VALID_FLAGS))
{
hr = STRSAFE_E_INVALID_PARAMETER;
}
else
{
if (dwFlags & STRSAFE_IGNORE_NULLS)
{
if (pszDest == NULL)
{
if ((cchDest != 0) || (cbDest != 0))
{
// NULL pszDest and non-zero cchDest/cbDest is invalid
hr = STRSAFE_E_INVALID_PARAMETER;
}
}
}
if (SUCCEEDED(hr))
{
if (cchDest <= 1)
{
pszDestEnd = pszDest;
cchRemaining = cchDest;
if (cchDest == 1)
{
*pszDestEnd = '\0';
}
hr = STRSAFE_E_INSUFFICIENT_BUFFER;
}
else
{
char ch;
pszDestEnd = pszDest;
cchRemaining = cchDest;
while ((cchRemaining > 1) && (ch = (char)getc(stdin)) != '\n')
{
if (ch == EOF)
{
if (pszDestEnd == pszDest)
{
// we failed to read anything from stdin
hr = STRSAFE_E_END_OF_FILE;
}
break;
}
*pszDestEnd = ch;
pszDestEnd++;
cchRemaining--;
}
if (cchRemaining > 0)
{
// there is extra room
if (dwFlags & STRSAFE_FILL_BEHIND_NULL)
{
memset(pszDestEnd + 1, STRSAFE_GET_FILL_PATTERN(dwFlags), ((cchRemaining - 1) * sizeof(char)) + (cbDest % sizeof(char)));
}
}
*pszDestEnd = '\0';
}
}
}
if (FAILED(hr))
{
if (pszDest)
{
if (dwFlags & STRSAFE_FILL_ON_FAILURE)
{
memset(pszDest, STRSAFE_GET_FILL_PATTERN(dwFlags), cbDest);
if (STRSAFE_GET_FILL_PATTERN(dwFlags) == 0)
{
pszDestEnd = pszDest;
cchRemaining = cchDest;
}
else if (cchDest > 0)
{
pszDestEnd = pszDest + cchDest - 1;
cchRemaining = 1;
// null terminate the end of the string
*pszDestEnd = '\0';
}
}
if (dwFlags & (STRSAFE_NULL_ON_FAILURE | STRSAFE_NO_TRUNCATION))
{
if (cchDest > 0)
{
pszDestEnd = pszDest;
cchRemaining = cchDest;
// null terminate the beginning of the string
*pszDestEnd = '\0';
}
}
}
}
if (SUCCEEDED(hr) ||
(hr == STRSAFE_E_INSUFFICIENT_BUFFER) ||
(hr == STRSAFE_E_END_OF_FILE))
{
if (ppszDestEnd)
{
*ppszDestEnd = pszDestEnd;
}
if (pcchRemaining)
{
*pcchRemaining = cchRemaining;
}
}
return hr;
}
STRSAFE_INLINE_API StringGetsExWorkerW(wchar_t* pszDest, size_t cchDest, size_t cbDest, wchar_t** ppszDestEnd, size_t* pcchRemaining, unsigned long dwFlags)
{
HRESULT hr = S_OK;
wchar_t* pszDestEnd = pszDest;
size_t cchRemaining = 0;
// ASSERT(cbDest == (cchDest * sizeof(char)) ||
// cbDest == (cchDest * sizeof(char)) + (cbDest % sizeof(char)));
// only accept valid flags
if (dwFlags & (~STRSAFE_VALID_FLAGS))
{
hr = STRSAFE_E_INVALID_PARAMETER;
}
else
{
if (dwFlags & STRSAFE_IGNORE_NULLS)
{
if (pszDest == NULL)
{
if ((cchDest != 0) || (cbDest != 0))
{
// NULL pszDest and non-zero cchDest/cbDest is invalid
hr = STRSAFE_E_INVALID_PARAMETER;
}
}
}
if (SUCCEEDED(hr))
{
if (cchDest <= 1)
{
pszDestEnd = pszDest;
cchRemaining = cchDest;
if (cchDest == 1)
{
*pszDestEnd = L'\0';
}
hr = STRSAFE_E_INSUFFICIENT_BUFFER;
}
else
{
wchar_t ch;
pszDestEnd = pszDest;
cchRemaining = cchDest;
while ((cchRemaining > 1) && (ch = (wchar_t)getwc(stdin)) != L'\n')
{
if (ch == EOF)
{
if (pszDestEnd == pszDest)
{
// we failed to read anything from stdin
hr = STRSAFE_E_END_OF_FILE;
}
break;
}
*pszDestEnd = ch;
pszDestEnd++;
cchRemaining--;
}
if (cchRemaining > 0)
{
// there is extra room
if (dwFlags & STRSAFE_FILL_BEHIND_NULL)
{
memset(pszDestEnd + 1, STRSAFE_GET_FILL_PATTERN(dwFlags), ((cchRemaining - 1) * sizeof(wchar_t)) + (cbDest % sizeof(wchar_t)));
}
}
*pszDestEnd = L'\0';
}
}
}
if (FAILED(hr))
{
if (pszDest)
{
if (dwFlags & STRSAFE_FILL_ON_FAILURE)
{
memset(pszDest, STRSAFE_GET_FILL_PATTERN(dwFlags), cbDest);
if (STRSAFE_GET_FILL_PATTERN(dwFlags) == 0)
{
pszDestEnd = pszDest;
cchRemaining = cchDest;
}
else if (cchDest > 0)
{
pszDestEnd = pszDest + cchDest - 1;
cchRemaining = 1;
// null terminate the end of the string
*pszDestEnd = L'\0';
}
}
if (dwFlags & (STRSAFE_NULL_ON_FAILURE | STRSAFE_NO_TRUNCATION))
{
if (cchDest > 0)
{
pszDestEnd = pszDest;
cchRemaining = cchDest;
// null terminate the beginning of the string
*pszDestEnd = L'\0';
}
}
}
}
if (SUCCEEDED(hr) ||
(hr == STRSAFE_E_INSUFFICIENT_BUFFER) ||
(hr == STRSAFE_E_END_OF_FILE))
{
if (ppszDestEnd)
{
*ppszDestEnd = pszDestEnd;
}
if (pcchRemaining)
{
*pcchRemaining = cchRemaining;
}
}
return hr;
}
#endif // !STRSAFE_LIB_IMPL
// end_strsafe
// begin_strsafe begin_ntstrsafe
// Do not call these functions, they are worker functions for internal use within this file
#ifdef DEPRECATE_SUPPORTED
#pragma deprecated(StringCopyWorkerA)
#pragma deprecated(StringCopyWorkerW)
#pragma deprecated(StringCopyExWorkerA)
#pragma deprecated(StringCopyExWorkerW)
#pragma deprecated(StringCatWorkerA)
#pragma deprecated(StringCatWorkerW)
#pragma deprecated(StringCatExWorkerA)
#pragma deprecated(StringCatExWorkerW)
#pragma deprecated(StringCatNWorkerA)
#pragma deprecated(StringCatNWorkerW)
#pragma deprecated(StringCatNExWorkerA)
#pragma deprecated(StringCatNExWorkerW)
#pragma deprecated(StringVPrintfWorkerA)
#pragma deprecated(StringVPrintfWorkerW)
#pragma deprecated(StringVPrintfExWorkerA)
#pragma deprecated(StringVPrintfExWorkerW)
#pragma deprecated(StringLengthWorkerA)
#pragma deprecated(StringLengthWorkerW)
#else
#define StringCopyWorkerA StringCopyWorkerA_instead_use_StringCchCopyA_or_StringCchCopyExA;
#define StringCopyWorkerW StringCopyWorkerW_instead_use_StringCchCopyW_or_StringCchCopyExW;
#define StringCopyExWorkerA StringCopyExWorkerA_instead_use_StringCchCopyA_or_StringCchCopyExA;
#define StringCopyExWorkerW StringCopyExWorkerW_instead_use_StringCchCopyW_or_StringCchCopyExW;
#define StringCatWorkerA StringCatWorkerA_instead_use_StringCchCatA_or_StringCchCatExA;
#define StringCatWorkerW StringCatWorkerW_instead_use_StringCchCatW_or_StringCchCatExW;
#define StringCatExWorkerA StringCatExWorkerA_instead_use_StringCchCatA_or_StringCchCatExA;
#define StringCatExWorkerW StringCatExWorkerW_instead_use_StringCchCatW_or_StringCchCatExW;
#define StringCatNWorkerA StringCatNWorkerA_instead_use_StringCchCatNA_or_StrincCbCatNA;
#define StringCatNWorkerW StringCatNWorkerW_instead_use_StringCchCatNW_or_StringCbCatNW;
#define StringCatNExWorkerA StringCatNExWorkerA_instead_use_StringCchCatNExA_or_StringCbCatNExA;
#define StringCatNExWorkerW StringCatNExWorkerW_instead_use_StringCchCatNExW_or_StringCbCatNExW;
#define StringVPrintfWorkerA StringVPrintfWorkerA_instead_use_StringCchVPrintfA_or_StringCchVPrintfExA;
#define StringVPrintfWorkerW StringVPrintfWorkerW_instead_use_StringCchVPrintfW_or_StringCchVPrintfExW;
#define StringVPrintfExWorkerA StringVPrintfExWorkerA_instead_use_StringCchVPrintfA_or_StringCchVPrintfExA;
#define StringVPrintfExWorkerW StringVPrintfExWorkerW_instead_use_StringCchVPrintfW_or_StringCchVPrintfExW;
#define StringLengthWorkerA StringLengthWorkerA_instead_use_StringCchLengthA_or_StringCbLengthA;
#define StringLengthWorkerW StringLengthWorkerW_instead_use_StringCchLengthW_or_StringCbLengthW;
#endif // !DEPRECATE_SUPPORTED
#ifndef STRSAFE_NO_DEPRECATE
// Deprecate all of the unsafe functions to generate compiletime errors. If you do not want
// this then you can #define STRSAFE_NO_DEPRECATE before including this file.
#ifdef DEPRECATE_SUPPORTED
// end_strsafe end_ntstrsafe
// begin_strsafe
// First all the names that are a/w variants (or shouldn't be #defined by now anyway).
#pragma deprecated(lstrcpyA)
#pragma deprecated(lstrcpyW)
#pragma deprecated(lstrcatA)
#pragma deprecated(lstrcatW)
#pragma deprecated(wsprintfA)
#pragma deprecated(wsprintfW)
#pragma deprecated(StrCpyW)
#pragma deprecated(StrCatW)
#pragma deprecated(StrNCatA)
#pragma deprecated(StrNCatW)
#pragma deprecated(StrCatNA)
#pragma deprecated(StrCatNW)
#pragma deprecated(wvsprintfA)
#pragma deprecated(wvsprintfW)
// end_strsafe
// begin_strsafe begin_ntstrsafe
#pragma deprecated(strcpy)
#pragma deprecated(wcscpy)
#pragma deprecated(strcat)
#pragma deprecated(wcscat)
#pragma deprecated(sprintf)
#pragma deprecated(swprintf)
#pragma deprecated(vsprintf)
#pragma deprecated(vswprintf)
#pragma deprecated(_snprintf)
#pragma deprecated(_snwprintf)
#pragma deprecated(_vsnprintf)
#pragma deprecated(_vsnwprintf)
// end_strsafe end_ntstrsafe
// begin_strsafe
#pragma deprecated(gets)
#pragma deprecated(_getws)
// Then all the windows.h names - we need to undef and redef based on UNICODE setting
#undef lstrcpy
#undef lstrcat
#undef wsprintf
#undef wvsprintf
#pragma deprecated(lstrcpy)
#pragma deprecated(lstrcat)
#pragma deprecated(wsprintf)
#pragma deprecated(wvsprintf)
#ifdef UNICODE
#define lstrcpy lstrcpyW
#define lstrcat lstrcatW
#define wsprintf wsprintfW
#define wvsprintf wvsprintfW
#else
#define lstrcpy lstrcpyA
#define lstrcat lstrcatA
#define wsprintf wsprintfA
#define wvsprintf wvsprintfA
#endif
// Then the shlwapi names - they key off UNICODE also.
#undef StrCpyA
#undef StrCpy
#undef StrCatA
#undef StrCat
#undef StrNCat
#undef StrCatN
#pragma deprecated(StrCpyA)
#pragma deprecated(StrCatA)
#pragma deprecated(StrCatN)
#pragma deprecated(StrCpy)
#pragma deprecated(StrCat)
#pragma deprecated(StrNCat)
#define StrCpyA lstrcpyA
#define StrCatA lstrcatA
#define StrCatN StrNCat
#ifdef UNICODE
#define StrCpy StrCpyW
#define StrCat StrCatW
#define StrNCat StrNCatW
#else
#define StrCpy lstrcpyA
#define StrCat lstrcatA
#define StrNCat StrNCatA
#endif
// Then all the CRT names - we need to undef/redef based on _UNICODE value.
#undef _tcscpy
#undef _ftcscpy
#undef _tcscat
#undef _ftcscat
#undef _stprintf
#undef _sntprintf
#undef _vstprintf
#undef _vsntprintf
#undef _getts
#pragma deprecated(_tcscpy)
#pragma deprecated(_ftcscpy)
#pragma deprecated(_tcscat)
#pragma deprecated(_ftcscat)
#pragma deprecated(_stprintf)
#pragma deprecated(_sntprintf)
#pragma deprecated(_vstprintf)
#pragma deprecated(_vsntprintf)
#pragma deprecated(_getts)
#ifdef _UNICODE
#define _tcscpy wcscpy
#define _ftcscpy wcscpy
#define _tcscat wcscat
#define _ftcscat wcscat
#define _stprintf swprintf
#define _sntprintf _snwprintf
#define _vstprintf vswprintf
#define _vsntprintf _vsnwprintf
#define _getts _getws
#else
#define _tcscpy strcpy
#define _ftcscpy strcpy
#define _tcscat strcat
#define _ftcscat strcat
#define _stprintf sprintf
#define _sntprintf _snprintf
#define _vstprintf vsprintf
#define _vsntprintf _vsnprintf
#define _getts gets
#endif
// end_strsafe
// begin_strsafe begin_ntstrsafe
#else // DEPRECATE_SUPPORTED
#undef strcpy
#define strcpy strcpy_instead_use_StringCbCopyA_or_StringCchCopyA;
#undef wcscpy
#define wcscpy wcscpy_instead_use_StringCbCopyW_or_StringCchCopyW;
#undef strcat
#define strcat strcat_instead_use_StringCbCatA_or_StringCchCatA;
#undef wcscat
#define wcscat wcscat_instead_use_StringCbCatW_or_StringCchCatW;
#undef sprintf
#define sprintf sprintf_instead_use_StringCbPrintfA_or_StringCchPrintfA;
#undef swprintf
#define swprintf swprintf_instead_use_StringCbPrintfW_or_StringCchPrintfW;
#undef vsprintf
#define vsprintf vsprintf_instead_use_StringCbVPrintfA_or_StringCchVPrintfA;
#undef vswprintf
#define vswprintf vswprintf_instead_use_StringCbVPrintfW_or_StringCchVPrintfW;
#undef _snprintf
#define _snprintf _snprintf_instead_use_StringCbPrintfA_or_StringCchPrintfA;
#undef _snwprintf
#define _snwprintf _snwprintf_instead_use_StringCbPrintfW_or_StringCchPrintfW;
#undef _vsnprintf
#define _vsnprintf _vsnprintf_instead_use_StringCbVPrintfA_or_StringCchVPrintfA;
#undef _vsnwprintf
#define _vsnwprintf _vsnwprintf_instead_use_StringCbVPrintfW_or_StringCchVPrintfW;
// end_strsafe end_ntstrsafe
// begin_strsafe
#undef strcpyA
#define strcpyA strcpyA_instead_use_StringCbCopyA_or_StringCchCopyA;
#undef strcpyW
#define strcpyW strcpyW_instead_use_StringCbCopyW_or_StringCchCopyW;
#undef lstrcpy
#define lstrcpy lstrcpy_instead_use_StringCbCopy_or_StringCchCopy;
#undef lstrcpyA
#define lstrcpyA lstrcpyA_instead_use_StringCbCopyA_or_StringCchCopyA;
#undef lstrcpyW
#define lstrcpyW lstrcpyW_instead_use_StringCbCopyW_or_StringCchCopyW;
#undef StrCpy
#define StrCpy StrCpy_instead_use_StringCbCopy_or_StringCchCopy;
#undef StrCpyA
#define StrCpyA StrCpyA_instead_use_StringCbCopyA_or_StringCchCopyA;
#undef StrCpyW
#define StrCpyW StrCpyW_instead_use_StringCbCopyW_or_StringCchCopyW;
#undef _tcscpy
#define _tcscpy _tcscpy_instead_use_StringCbCopy_or_StringCchCopy;
#undef _ftcscpy
#define _ftcscpy _ftcscpy_instead_use_StringCbCopy_or_StringCchCopy;
#undef lstrcat
#define lstrcat lstrcat_instead_use_StringCbCat_or_StringCchCat;
#undef lstrcatA
#define lstrcatA lstrcatA_instead_use_StringCbCatA_or_StringCchCatA;
#undef lstrcatW
#define lstrcatW lstrcatW_instead_use_StringCbCatW_or_StringCchCatW;
#undef StrCat
#define StrCat StrCat_instead_use_StringCbCat_or_StringCchCat;
#undef StrCatA
#define StrCatA StrCatA_instead_use_StringCbCatA_or_StringCchCatA;
#undef StrCatW
#define StrCatW StrCatW_instead_use_StringCbCatW_or_StringCchCatW;
#undef StrNCat
#define StrNCat StrNCat_instead_use_StringCbCatN_or_StringCchCatN;
#undef StrNCatA
#define StrNCatA StrNCatA_instead_use_StringCbCatNA_or_StringCchCatNA;
#undef StrNCatW
#define StrNCatW StrNCatW_instead_use_StringCbCatNW_or_StringCchCatNW;
#undef StrCatN
#define StrCatN StrCatN_instead_use_StringCbCatN_or_StringCchCatN;
#undef StrCatNA
#define StrCatNA StrCatNA_instead_use_StringCbCatNA_or_StringCchCatNA;
#undef StrCatNW
#define StrCatNW StrCatNW_instead_use_StringCbCatNW_or_StringCchCatNW;
#undef _tcscat
#define _tcscat _tcscat_instead_use_StringCbCat_or_StringCchCat;
#undef _ftcscat
#define _ftcscat _ftcscat_instead_use_StringCbCat_or_StringCchCat;
#undef wsprintf
#define wsprintf wsprintf_instead_use_StringCbPrintf_or_StringCchPrintf;
#undef wsprintfA
#define wsprintfA wsprintfA_instead_use_StringCbPrintfA_or_StringCchPrintfA;
#undef wsprintfW
#define wsprintfW wsprintfW_instead_use_StringCbPrintfW_or_StringCchPrintfW;
#undef wvsprintf
#define wvsprintf wvsprintf_instead_use_StringCbVPrintf_or_StringCchVPrintf;
#undef wvsprintfA
#define wvsprintfA wvsprintfA_instead_use_StringCbVPrintfA_or_StringCchVPrintfA;
#undef wvsprintfW
#define wvsprintfW wvsprintfW_instead_use_StringCbVPrintfW_or_StringCchVPrintfW;
#undef _vstprintf
#define _vstprintf _vstprintf_instead_use_StringCbVPrintf_or_StringCchVPrintf;
#undef _vsntprintf
#define _vsntprintf _vsntprintf_instead_use_StringCbVPrintf_or_StringCchVPrintf;
#undef _stprintf
#define _stprintf _stprintf_instead_use_StringCbPrintf_or_StringCchPrintf;
#undef _sntprintf
#define _sntprintf _sntprintf_instead_use_StringCbPrintf_or_StringCchPrintf;
#undef _getts
#define _getts _getts_instead_use_StringCbGets_or_StringCchGets;
#undef gets
#define gets _gets_instead_use_StringCbGetsA_or_StringCchGetsA;
#undef _getws
#define _getws _getws_instead_use_StringCbGetsW_or_StringCchGetsW;
// end_strsafe
// begin_strsafe begin_ntstrsafe
#endif // !DEPRECATE_SUPPORTED
#endif // !STRSAFE_NO_DEPRECATE
// end_strsafe end_ntstrsafe
// begin_ntstrsafe
#ifdef _STRSAFE_H_INCLUDED_
#pragma warning(pop)
#endif // _STRSAFE_H_INCLUDED_
// end_ntstrsafe
// begin_strsafe
#ifdef _NTSTRSAFE_H_INCLUDED_
#pragma warning(pop)
#endif // _NTSTRSAFE_H_INCLUDED_
#endif // _STRSAFE_H_INCLUDED_
// end_strsafe
// begin_ntstrsafe
#endif // _NTSTRSAFE_H_INCLUDED_
// end_ntstrsafe