src/base/strings/safe_sprintf.h - cobalt - Git at Google

 // Copyright 2013 The Chromium Authors. All rights reserved.
 // Use of this source code is governed by a BSD-style license that can be
 // found in the LICENSE file.

 #ifndef BASE_STRINGS_SAFE_SPRINTF_H_
 #define BASE_STRINGS_SAFE_SPRINTF_H_

 #include "build/build_config.h"

 #include <stdlib.h>

 #if defined(OS_POSIX) || defined(OS_FUCHSIA)
 // For ssize_t
 #include <unistd.h>
 #endif

 #include "base/base_export.h"
 #include "starboard/common/string.h"
 #include "starboard/types.h"

 namespace base {
 namespace strings {

 #if defined(COMPILER_MSVC)
 // Define ssize_t inside of our namespace.
 #if defined(_WIN64)
 typedef __int64 ssize_t;
 #else
 typedef long ssize_t;
 #endif
 #endif

 // SafeSPrintf() is a type-safe and completely self-contained version of
 // snprintf().
 //
 // SafeSNPrintf() is an alternative function signature that can be used when
 // not dealing with fixed-sized buffers. When possible, SafeSPrintf() should
 // always be used instead of SafeSNPrintf()
 //
 // These functions allow for formatting complicated messages from contexts that
 // require strict async-signal-safety. In fact, it is safe to call them from
 // any low-level execution context, as they are guaranteed to make no library
 // or system calls. It deliberately never touches "errno", either.
 //
 // The only exception to this rule is that in debug builds the code calls
 // RAW_CHECK() to help diagnose problems when the format string does not
 // match the rest of the arguments. In release builds, no CHECK()s are used,
 // and SafeSPrintf() instead returns an output string that expands only
 // those arguments that match their format characters. Mismatched arguments
 // are ignored.
 //
 // The code currently only supports a subset of format characters:
 //   %c, %o, %d, %x, %X, %p, and %s.
 //
 // SafeSPrintf() aims to be as liberal as reasonably possible. Integer-like
 // values of arbitrary width can be passed to all of the format characters
 // that expect integers. Thus, it is explicitly legal to pass an "int" to
 // "%c", and output will automatically look at the LSB only. It is also
 // explicitly legal to pass either signed or unsigned values, and the format
 // characters will automatically interpret the arguments accordingly.
 //
 // It is still not legal to mix-and-match integer-like values with pointer
 // values. For instance, you cannot pass a pointer to %x, nor can you pass an
 // integer to %p.
 //
 // The one exception is "0" zero being accepted by "%p". This works-around
 // the problem of C++ defining NULL as an integer-like value.
 //
 // All format characters take an optional width parameter. This must be a
 // positive integer. For %d, %o, %x, %X and %p, if the width starts with
 // a leading '0', padding is done with '0' instead of ' ' characters.
 //
 // There are a few features of snprintf()-style format strings, that
 // SafeSPrintf() does not support at this time.
 //
 // If an actual user showed up, there is no particularly strong reason they
 // couldn't be added. But that assumes that the trade-offs between complexity
 // and utility are favorable.
 //
 // For example, adding support for negative padding widths, and for %n are all
 // likely to be viewed positively. They are all clearly useful, low-risk, easy
 // to test, don't jeopardize the async-signal-safety of the code, and overall
 // have little impact on other parts of SafeSPrintf() function.
 //
 // On the other hands, adding support for alternate forms, positional
 // arguments, grouping, wide characters, localization or floating point numbers
 // are all unlikely to ever be added.
 //
 // SafeSPrintf() and SafeSNPrintf() mimic the behavior of snprintf() and they
 // return the number of bytes needed to store the untruncated output. This
 // does *not* include the terminating NUL byte.
 //
 // They return -1, iff a fatal error happened. This typically can only happen,
 // if the buffer size is a) negative, or b) zero (i.e. not even the NUL byte
 // can be written). The return value can never be larger than SSIZE_MAX-1.
 // This ensures that the caller can always add one to the signed return code
 // in order to determine the amount of storage that needs to be allocated.
 //
 // While the code supports type checking and while it is generally very careful
 // to avoid printing incorrect values, it tends to be conservative in printing
 // as much as possible, even when given incorrect parameters. Typically, in
 // case of an error, the format string will not be expanded. (i.e. something
 // like SafeSPrintf(buf, "%p %d", 1, 2) results in "%p 2"). See above for
 // the use of RAW_CHECK() in debug builds, though.
 //
 // Basic example:
 //   char buf[20];
 //   base::strings::SafeSPrintf(buf, "The answer: %2d", 42);
 //
 // Example with dynamically sized buffer (async-signal-safe). This code won't
 // work on Visual studio, as it requires dynamically allocating arrays on the
 // stack. Consider picking a smaller value for |kMaxSize| if stack size is
 // limited and known. On the other hand, if the parameters to SafeSNPrintf()
 // are trusted and not controllable by the user, you can consider eliminating
 // the check for |kMaxSize| altogether. The current value of SSIZE_MAX is
 // essentially a no-op that just illustrates how to implement an upper bound:
 //   const size_t kInitialSize = 128;
 //   const size_t kMaxSize = std::numeric_limits<ssize_t>::max();
 //   size_t size = kInitialSize;
 //   for (;;) {
 //     char buf[size];
 //     size = SafeSNPrintf(buf, size, "Error message \"%s\"\n", err) + 1;
 //     if (sizeof(buf) < kMaxSize && size > kMaxSize) {
 //       size = kMaxSize;
 //       continue;
 //     } else if (size > sizeof(buf))
 //       continue;
 //     write(2, buf, size-1);
 //     break;
 //   }

 namespace internal {
 // Helpers that use C++ overloading, templates, and specializations to deduce
 // and record type information from function arguments. This allows us to
 // later write a type-safe version of snprintf().

 struct Arg {
   enum Type { INT, UINT, STRING, POINTER };

   // Any integer-like value.
   Arg(signed char c) : type(INT) {
     integer.i = c;
     integer.width = sizeof(char);
   }
   Arg(unsigned char c) : type(UINT) {
     integer.i = c;
     integer.width = sizeof(char);
   }
   Arg(signed short j) : type(INT) {
     integer.i = j;
     integer.width = sizeof(short);
   }
   Arg(unsigned short j) : type(UINT) {
     integer.i = j;
     integer.width = sizeof(short);
   }
   Arg(signed int j) : type(INT) {
     integer.i = j;
     integer.width = sizeof(int);
   }
   Arg(unsigned int j) : type(UINT) {
     integer.i = j;
     integer.width = sizeof(int);
   }
   Arg(signed long j) : type(INT) {
     integer.i = j;
     integer.width = sizeof(long);
   }
   Arg(unsigned long j) : type(UINT) {
     integer.i = j;
     integer.width = sizeof(long);
   }
   Arg(signed long long j) : type(INT) {
     integer.i = j;
     integer.width = sizeof(long long);
   }
   Arg(unsigned long long j) : type(UINT) {
     integer.i = j;
     integer.width = sizeof(long long);
   }

   // A C-style text string.
   Arg(const char* s) : str(s), type(STRING) { }
   Arg(char* s)       : str(s), type(STRING) { }

   // Any pointer value that can be cast to a "void*".
   template<class T> Arg(T* p) : ptr((void*)p), type(POINTER) { }

   union {
     // An integer-like value.
     struct {
       int64_t       i;
       unsigned char width;
     } integer;

     // A C-style text string.
     const char* str;

     // A pointer to an arbitrary object.
     const void* ptr;
   };
   const enum Type type;
 };

 // This is the internal function that performs the actual formatting of
 // an snprintf()-style format string.
 BASE_EXPORT ssize_t SafeSNPrintf(char* buf, size_t sz, const char* fmt,
                                  const Arg* args, size_t max_args);

 #if !defined(NDEBUG)
 // In debug builds, allow unit tests to artificially lower the kSSizeMax
 // constant that is used as a hard upper-bound for all buffers. In normal
 // use, this constant should always be std::numeric_limits<ssize_t>::max().
 BASE_EXPORT void SetSafeSPrintfSSizeMaxForTest(size_t max);
 BASE_EXPORT size_t GetSafeSPrintfSSizeMaxForTest();
 #endif

 }  // namespace internal

 template<typename... Args>
 ssize_t SafeSNPrintf(char* buf, size_t N, const char* fmt, Args... args) {
   // Use Arg() object to record type information and then copy arguments to an
   // array to make it easier to iterate over them.
   const internal::Arg arg_array[] = { args... };
   return internal::SafeSNPrintf(buf, N, fmt, arg_array, sizeof...(args));
 }

 template<size_t N, typename... Args>
 ssize_t SafeSPrintf(char (&buf)[N], const char* fmt, Args... args) {
   // Use Arg() object to record type information and then copy arguments to an
   // array to make it easier to iterate over them.
   const internal::Arg arg_array[] = { args... };
   return internal::SafeSNPrintf(buf, N, fmt, arg_array, sizeof...(args));
 }

 // Fast-path when we don't actually need to substitute any arguments.
 BASE_EXPORT ssize_t SafeSNPrintf(char* buf, size_t N, const char* fmt);
 template<size_t N>
 inline ssize_t SafeSPrintf(char (&buf)[N], const char* fmt) {
   return SafeSNPrintf(buf, N, fmt);
 }

 }  // namespace strings
 }  // namespace base

 #endif  // BASE_STRINGS_SAFE_SPRINTF_H_
	// Copyright 2013 The Chromium Authors. All rights reserved.
	// Use of this source code is governed by a BSD-style license that can be
	// found in the LICENSE file.

	#ifndef BASE_STRINGS_SAFE_SPRINTF_H_
	#define BASE_STRINGS_SAFE_SPRINTF_H_

	#include "build/build_config.h"

	#include <stdlib.h>

	#if defined(OS_POSIX) \|\| defined(OS_FUCHSIA)
	// For ssize_t
	#include <unistd.h>
	#endif

	#include "base/base_export.h"
	#include "starboard/common/string.h"
	#include "starboard/types.h"

	namespace base {
	namespace strings {

	#if defined(COMPILER_MSVC)
	// Define ssize_t inside of our namespace.
	#if defined(_WIN64)
	typedef __int64 ssize_t;
	#else
	typedef long ssize_t;
	#endif
	#endif

	// SafeSPrintf() is a type-safe and completely self-contained version of
	// snprintf().
	//
	// SafeSNPrintf() is an alternative function signature that can be used when
	// not dealing with fixed-sized buffers. When possible, SafeSPrintf() should
	// always be used instead of SafeSNPrintf()
	//
	// These functions allow for formatting complicated messages from contexts that
	// require strict async-signal-safety. In fact, it is safe to call them from
	// any low-level execution context, as they are guaranteed to make no library
	// or system calls. It deliberately never touches "errno", either.
	//
	// The only exception to this rule is that in debug builds the code calls
	// RAW_CHECK() to help diagnose problems when the format string does not
	// match the rest of the arguments. In release builds, no CHECK()s are used,
	// and SafeSPrintf() instead returns an output string that expands only
	// those arguments that match their format characters. Mismatched arguments
	// are ignored.
	//
	// The code currently only supports a subset of format characters:
	// %c, %o, %d, %x, %X, %p, and %s.
	//
	// SafeSPrintf() aims to be as liberal as reasonably possible. Integer-like
	// values of arbitrary width can be passed to all of the format characters
	// that expect integers. Thus, it is explicitly legal to pass an "int" to
	// "%c", and output will automatically look at the LSB only. It is also
	// explicitly legal to pass either signed or unsigned values, and the format
	// characters will automatically interpret the arguments accordingly.
	//
	// It is still not legal to mix-and-match integer-like values with pointer
	// values. For instance, you cannot pass a pointer to %x, nor can you pass an
	// integer to %p.
	//
	// The one exception is "0" zero being accepted by "%p". This works-around
	// the problem of C++ defining NULL as an integer-like value.
	//
	// All format characters take an optional width parameter. This must be a
	// positive integer. For %d, %o, %x, %X and %p, if the width starts with
	// a leading '0', padding is done with '0' instead of ' ' characters.
	//
	// There are a few features of snprintf()-style format strings, that
	// SafeSPrintf() does not support at this time.
	//
	// If an actual user showed up, there is no particularly strong reason they
	// couldn't be added. But that assumes that the trade-offs between complexity
	// and utility are favorable.
	//
	// For example, adding support for negative padding widths, and for %n are all
	// likely to be viewed positively. They are all clearly useful, low-risk, easy
	// to test, don't jeopardize the async-signal-safety of the code, and overall
	// have little impact on other parts of SafeSPrintf() function.
	//
	// On the other hands, adding support for alternate forms, positional
	// arguments, grouping, wide characters, localization or floating point numbers
	// are all unlikely to ever be added.
	//
	// SafeSPrintf() and SafeSNPrintf() mimic the behavior of snprintf() and they
	// return the number of bytes needed to store the untruncated output. This
	// does not include the terminating NUL byte.
	//
	// They return -1, iff a fatal error happened. This typically can only happen,
	// if the buffer size is a) negative, or b) zero (i.e. not even the NUL byte
	// can be written). The return value can never be larger than SSIZE_MAX-1.
	// This ensures that the caller can always add one to the signed return code
	// in order to determine the amount of storage that needs to be allocated.
	//
	// While the code supports type checking and while it is generally very careful
	// to avoid printing incorrect values, it tends to be conservative in printing
	// as much as possible, even when given incorrect parameters. Typically, in
	// case of an error, the format string will not be expanded. (i.e. something
	// like SafeSPrintf(buf, "%p %d", 1, 2) results in "%p 2"). See above for
	// the use of RAW_CHECK() in debug builds, though.
	//
	// Basic example:
	// char buf[20];
	// base::strings::SafeSPrintf(buf, "The answer: %2d", 42);
	//
	// Example with dynamically sized buffer (async-signal-safe). This code won't
	// work on Visual studio, as it requires dynamically allocating arrays on the
	// stack. Consider picking a smaller value for \|kMaxSize\| if stack size is
	// limited and known. On the other hand, if the parameters to SafeSNPrintf()
	// are trusted and not controllable by the user, you can consider eliminating
	// the check for \|kMaxSize\| altogether. The current value of SSIZE_MAX is
	// essentially a no-op that just illustrates how to implement an upper bound:
	// const size_t kInitialSize = 128;
	// const size_t kMaxSize = std::numeric_limits<ssize_t>::max();
	// size_t size = kInitialSize;
	// for (;;) {
	// char buf[size];
	// size = SafeSNPrintf(buf, size, "Error message \"%s\"\n", err) + 1;
	// if (sizeof(buf) < kMaxSize && size > kMaxSize) {
	// size = kMaxSize;
	// continue;
	// } else if (size > sizeof(buf))
	// continue;
	// write(2, buf, size-1);
	// break;
	// }

	namespace internal {
	// Helpers that use C++ overloading, templates, and specializations to deduce
	// and record type information from function arguments. This allows us to
	// later write a type-safe version of snprintf().

	struct Arg {
	enum Type { INT, UINT, STRING, POINTER };

	// Any integer-like value.
	Arg(signed char c) : type(INT) {
	integer.i = c;
	integer.width = sizeof(char);
	}
	Arg(unsigned char c) : type(UINT) {
	integer.i = c;
	integer.width = sizeof(char);
	}
	Arg(signed short j) : type(INT) {
	integer.i = j;
	integer.width = sizeof(short);
	}
	Arg(unsigned short j) : type(UINT) {
	integer.i = j;
	integer.width = sizeof(short);
	}
	Arg(signed int j) : type(INT) {
	integer.i = j;
	integer.width = sizeof(int);
	}
	Arg(unsigned int j) : type(UINT) {
	integer.i = j;
	integer.width = sizeof(int);
	}
	Arg(signed long j) : type(INT) {
	integer.i = j;
	integer.width = sizeof(long);
	}
	Arg(unsigned long j) : type(UINT) {
	integer.i = j;
	integer.width = sizeof(long);
	}
	Arg(signed long long j) : type(INT) {
	integer.i = j;
	integer.width = sizeof(long long);
	}
	Arg(unsigned long long j) : type(UINT) {
	integer.i = j;
	integer.width = sizeof(long long);
	}

	// A C-style text string.
	Arg(const char* s) : str(s), type(STRING) { }
	Arg(char* s) : str(s), type(STRING) { }

	// Any pointer value that can be cast to a "void*".
	template<class T> Arg(T* p) : ptr((void*)p), type(POINTER) { }

	union {
	// An integer-like value.
	struct {
	int64_t i;
	unsigned char width;
	} integer;

	// A C-style text string.
	const char* str;

	// A pointer to an arbitrary object.
	const void* ptr;
	};
	const enum Type type;
	};

	// This is the internal function that performs the actual formatting of
	// an snprintf()-style format string.
	BASE_EXPORT ssize_t SafeSNPrintf(char* buf, size_t sz, const char* fmt,
	const Arg* args, size_t max_args);

	#if !defined(NDEBUG)
	// In debug builds, allow unit tests to artificially lower the kSSizeMax
	// constant that is used as a hard upper-bound for all buffers. In normal
	// use, this constant should always be std::numeric_limits<ssize_t>::max().
	BASE_EXPORT void SetSafeSPrintfSSizeMaxForTest(size_t max);
	BASE_EXPORT size_t GetSafeSPrintfSSizeMaxForTest();
	#endif

	} // namespace internal

	template<typename... Args>
	ssize_t SafeSNPrintf(char* buf, size_t N, const char* fmt, Args... args) {
	// Use Arg() object to record type information and then copy arguments to an
	// array to make it easier to iterate over them.
	const internal::Arg arg_array[] = { args... };
	return internal::SafeSNPrintf(buf, N, fmt, arg_array, sizeof...(args));
	}

	template<size_t N, typename... Args>
	ssize_t SafeSPrintf(char (&buf)[N], const char* fmt, Args... args) {
	// Use Arg() object to record type information and then copy arguments to an
	// array to make it easier to iterate over them.
	const internal::Arg arg_array[] = { args... };
	return internal::SafeSNPrintf(buf, N, fmt, arg_array, sizeof...(args));
	}

	// Fast-path when we don't actually need to substitute any arguments.
	BASE_EXPORT ssize_t SafeSNPrintf(char* buf, size_t N, const char* fmt);
	template<size_t N>
	inline ssize_t SafeSPrintf(char (&buf)[N], const char* fmt) {
	return SafeSNPrintf(buf, N, fmt);
	}

	} // namespace strings
	} // namespace base

	#endif // BASE_STRINGS_SAFE_SPRINTF_H_