gtest-printers.cc

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// Author: wan@google.com (Zhanyong Wan)

// Google Test - The Google C++ Testing Framework
//
// This file implements a universal value printer that can print a
// value of any type T:
//
//   void ::testing::internal::UniversalPrinter<T>::Print(value, ostream_ptr);
//
// It uses the << operator when possible, and prints the bytes in the
// object otherwise.  A user can override its behavior for a class
// type Foo by defining either operator<<(::std::ostream&, const Foo&)
// or void PrintTo(const Foo&, ::std::ostream*) in the namespace that
// defines Foo.

#include "gtest/gtest-printers.h"
#include <ctype.h>
#include <stdio.h>
#include <ostream>  // NOLINT
#include <string>
#include "gtest/internal/gtest-port.h"

namespace testing {

namespace {

using ::std::ostream;

// Prints a segment of bytes in the given object.
void PrintByteSegmentInObjectTo(const unsigned char* obj_bytes, size_t start,
                                size_t count, ostream* os) {
  char text[5] = "";
  for (size_t i = 0; i != count; i++) {
    const size_t j = start + i;
    if (i != 0) {
      // Organizes the bytes into groups of 2 for easy parsing by
      // human.
      if ((j % 2) == 0)
        *os << ' ';
      else
        *os << '-';
    }
    GTEST_SNPRINTF_(text, sizeof(text), "%02X", obj_bytes[j]);
    *os << text;
  }
}

// Prints the bytes in the given value to the given ostream.
void PrintBytesInObjectToImpl(const unsigned char* obj_bytes, size_t count,
                              ostream* os) {
  // Tells the user how big the object is.
  *os << count << "-byte object <";

  const size_t kThreshold = 132;
  const size_t kChunkSize = 64;
  // If the object size is bigger than kThreshold, we'll have to omit
  // some details by printing only the first and the last kChunkSize
  // bytes.
  // TODO(wan): let the user control the threshold using a flag.
  if (count < kThreshold) {
    PrintByteSegmentInObjectTo(obj_bytes, 0, count, os);
  } else {
    PrintByteSegmentInObjectTo(obj_bytes, 0, kChunkSize, os);
    *os << " ... ";
    // Rounds up to 2-byte boundary.
    const size_t resume_pos = (count - kChunkSize + 1)/2*2;
    PrintByteSegmentInObjectTo(obj_bytes, resume_pos, count - resume_pos, os);
  }
  *os << ">";
}

}  // namespace

namespace internal2 {

// Delegates to PrintBytesInObjectToImpl() to print the bytes in the
// given object.  The delegation simplifies the implementation, which
// uses the << operator and thus is easier done outside of the
// ::testing::internal namespace, which contains a << operator that
// sometimes conflicts with the one in STL.
void PrintBytesInObjectTo(const unsigned char* obj_bytes, size_t count,
                          ostream* os) {
  PrintBytesInObjectToImpl(obj_bytes, count, os);
}

}  // namespace internal2

namespace internal {

// Depending on the value of a char (or wchar_t), we print it in one
// of three formats:
//   - as is if it's a printable ASCII (e.g. 'a', '2', ' '),
//   - as a hexidecimal escape sequence (e.g. '\x7F'), or
//   - as a special escape sequence (e.g. '\r', '\n').
enum CharFormat {
  kAsIs,
  kHexEscape,
  kSpecialEscape
};

// Returns true if c is a printable ASCII character.  We test the
// value of c directly instead of calling isprint(), which is buggy on
// Windows Mobile.
inline bool IsPrintableAscii(wchar_t c) {
  return 0x20 <= c && c <= 0x7E;
}

// Prints a wide or narrow char c as a character literal without the
// quotes, escaping it when necessary; returns how c was formatted.
// The template argument UnsignedChar is the unsigned version of Char,
// which is the type of c.
template <typename UnsignedChar, typename Char>
static CharFormat PrintAsCharLiteralTo(Char c, ostream* os) {
  switch (static_cast<wchar_t>(c)) {
    case L'\0':
      *os << "\\0";
      break;
    case L'\'':
      *os << "\\'";
      break;
    case L'\\':
      *os << "\\\\";
      break;
    case L'\a':
      *os << "\\a";
      break;
    case L'\b':
      *os << "\\b";
      break;
    case L'\f':
      *os << "\\f";
      break;
    case L'\n':
      *os << "\\n";
      break;
    case L'\r':
      *os << "\\r";
      break;
    case L'\t':
      *os << "\\t";
      break;
    case L'\v':
      *os << "\\v";
      break;
    default:
      if (IsPrintableAscii(c)) {
        *os << static_cast<char>(c);
        return kAsIs;
      } else {
        *os << String::Format("\\x%X", static_cast<UnsignedChar>(c));
        return kHexEscape;
      }
  }
  return kSpecialEscape;
}

// Prints a char c as if it's part of a string literal, escaping it when
// necessary; returns how c was formatted.
static CharFormat PrintAsWideStringLiteralTo(wchar_t c, ostream* os) {
  switch (c) {
    case L'\'':
      *os << "'";
      return kAsIs;
    case L'"':
      *os << "\\\"";
      return kSpecialEscape;
    default:
      return PrintAsCharLiteralTo<wchar_t>(c, os);
  }
}

// Prints a char c as if it's part of a string literal, escaping it when
// necessary; returns how c was formatted.
static CharFormat PrintAsNarrowStringLiteralTo(char c, ostream* os) {
  return PrintAsWideStringLiteralTo(static_cast<unsigned char>(c), os);
}

// Prints a wide or narrow character c and its code.  '\0' is printed
// as "'\\0'", other unprintable characters are also properly escaped
// using the standard C++ escape sequence.  The template argument
// UnsignedChar is the unsigned version of Char, which is the type of c.
template <typename UnsignedChar, typename Char>
void PrintCharAndCodeTo(Char c, ostream* os) {
  // First, print c as a literal in the most readable form we can find.
  *os << ((sizeof(c) > 1) ? "L'" : "'");
  const CharFormat format = PrintAsCharLiteralTo<UnsignedChar>(c, os);
  *os << "'";

  // To aid user debugging, we also print c's code in decimal, unless
  // it's 0 (in which case c was printed as '\\0', making the code
  // obvious).
  if (c == 0)
    return;
  *os << " (" << String::Format("%d", c).c_str();

  // For more convenience, we print c's code again in hexidecimal,
  // unless c was already printed in the form '\x##' or the code is in
  // [1, 9].
  if (format == kHexEscape || (1 <= c && c <= 9)) {
    // Do nothing.
  } else {
    *os << String::Format(", 0x%X",
                          static_cast<UnsignedChar>(c)).c_str();
  }
  *os << ")";
}

void PrintTo(unsigned char c, ::std::ostream* os) {
  PrintCharAndCodeTo<unsigned char>(c, os);
}
void PrintTo(signed char c, ::std::ostream* os) {
  PrintCharAndCodeTo<unsigned char>(c, os);
}

// Prints a wchar_t as a symbol if it is printable or as its internal
// code otherwise and also as its code.  L'\0' is printed as "L'\\0'".
void PrintTo(wchar_t wc, ostream* os) {
  PrintCharAndCodeTo<wchar_t>(wc, os);
}

// Prints the given array of characters to the ostream.
// The array starts at *begin, the length is len, it may include '\0' characters
// and may not be null-terminated.
static void PrintCharsAsStringTo(const char* begin, size_t len, ostream* os) {
  *os << "\"";
  bool is_previous_hex = false;
  for (size_t index = 0; index < len; ++index) {
    const char cur = begin[index];
    if (is_previous_hex && IsXDigit(cur)) {
      // Previous character is of '\x..' form and this character can be
      // interpreted as another hexadecimal digit in its number. Break string to
      // disambiguate.
      *os << "\" \"";
    }
    is_previous_hex = PrintAsNarrowStringLiteralTo(cur, os) == kHexEscape;
  }
  *os << "\"";
}

// Prints a (const) char array of 'len' elements, starting at address 'begin'.
void UniversalPrintArray(const char* begin, size_t len, ostream* os) {
  PrintCharsAsStringTo(begin, len, os);
}

// Prints the given array of wide characters to the ostream.
// The array starts at *begin, the length is len, it may include L'\0'
// characters and may not be null-terminated.
static void PrintWideCharsAsStringTo(const wchar_t* begin, size_t len,
                                     ostream* os) {
  *os << "L\"";
  bool is_previous_hex = false;
  for (size_t index = 0; index < len; ++index) {
    const wchar_t cur = begin[index];
    if (is_previous_hex && isascii(cur) && IsXDigit(static_cast<char>(cur))) {
      // Previous character is of '\x..' form and this character can be
      // interpreted as another hexadecimal digit in its number. Break string to
      // disambiguate.
      *os << "\" L\"";
    }
    is_previous_hex = PrintAsWideStringLiteralTo(cur, os) == kHexEscape;
  }
  *os << "\"";
}

// Prints the given C string to the ostream.
void PrintTo(const char* s, ostream* os) {
  if (s == NULL) {
    *os << "NULL";
  } else {
    *os << ImplicitCast_<const void*>(s) << " pointing to ";
    PrintCharsAsStringTo(s, strlen(s), os);
  }
}

// MSVC compiler can be configured to define whar_t as a typedef
// of unsigned short. Defining an overload for const wchar_t* in that case
// would cause pointers to unsigned shorts be printed as wide strings,
// possibly accessing more memory than intended and causing invalid
// memory accesses. MSVC defines _NATIVE_WCHAR_T_DEFINED symbol when
// wchar_t is implemented as a native type.
#if !defined(_MSC_VER) || defined(_NATIVE_WCHAR_T_DEFINED)
// Prints the given wide C string to the ostream.
void PrintTo(const wchar_t* s, ostream* os) {
  if (s == NULL) {
    *os << "NULL";
  } else {
    *os << ImplicitCast_<const void*>(s) << " pointing to ";
    PrintWideCharsAsStringTo(s, wcslen(s), os);
  }
}
#endif  // wchar_t is native

// Prints a ::string object.
#if GTEST_HAS_GLOBAL_STRING
void PrintStringTo(const ::string& s, ostream* os) {
  PrintCharsAsStringTo(s.data(), s.size(), os);
}
#endif  // GTEST_HAS_GLOBAL_STRING

void PrintStringTo(const ::std::string& s, ostream* os) {
  PrintCharsAsStringTo(s.data(), s.size(), os);
}

// Prints a ::wstring object.
#if GTEST_HAS_GLOBAL_WSTRING
void PrintWideStringTo(const ::wstring& s, ostream* os) {
  PrintWideCharsAsStringTo(s.data(), s.size(), os);
}
#endif  // GTEST_HAS_GLOBAL_WSTRING

#if GTEST_HAS_STD_WSTRING
void PrintWideStringTo(const ::std::wstring& s, ostream* os) {
  PrintWideCharsAsStringTo(s.data(), s.size(), os);
}
#endif  // GTEST_HAS_STD_WSTRING

}  // namespace internal

}  // namespace testing