注意:这与在编译时确定整数类型的位数非常相似,但这是一个非常简化的版本,全部包含在单个版本中.cpp
编辑:添加了一个解决方案 - 虽然给出了一个正确的解释(并被接受),我找到了一种解决问题的方法.
问题在于功能如
msg(int32_t);
msg(int64_t);
像这样的电话
long long myLong = 6;
msg(myLong); // Won't compile on gcc (4.6.3), call is ambiguous
这在MSVC上编译.任何人都可以解释为什么这个失败了gcc(我假设它可能与gcc通常严格符合标准的事实有关)以及如何正确实现相同效果的例子?
#include <iostream>
#include <stdint.h>
#include <boost/integer.hpp>
using namespace std;
void msg(int v) { cout << "int: " << sizeof(int) << ' ' << v << '\n'; }
void msg(long v) { cout << "long: " << sizeof(long) << ' ' << v << '\n'; }
void msg(long long v) { cout << "long long: " << sizeof(long long) << ' ' << v << '\n'; }
void msg2(int32_t v) { cout << "int32_t: " << sizeof(int32_t) << ' ' << v << '\n'; }
void msg2(int64_t v) { cout << "int64_t: " << sizeof(int64_t) << ' ' << v << '\n'; }
void msg2(uint32_t v) { cout << "uint32_t: " << sizeof(uint32_t) << ' ' << v << '\n'; }
void msg2(uint64_t v) { cout << "uint64_t: " << sizeof(uint64_t) << ' ' << v << '\n'; }
int main()
{
int myInt = -5;
long myLong = -6L;
long long myLongLong = -7LL;
unsigned int myUInt = 5;
unsigned int myULong = 6L;
unsigned long long myULongLong = 7LL;
msg(myInt);
msg(myLong);
msg(myLongLong);
msg2(myInt);
msg2(myLong); // fails on gcc 4.6.3 (32 bit)
msg2(myLongLong);
msg2(myUInt);
msg2(myULong); // fails on gcc 4.6.3 (32 bit)
msg2(myULongLong);
return 0;
}
// Output from MSVC (and gcc if you omit lines that would be commented out)
int: 4 5
long: 4 6
long long: 8 7
int32_t: 4 -5
int32_t: 4 -6 // omitted on gcc
int64_t: 8 -7
uint32_t: 4 5
uint32_t: 4 6 // omitted on gcc
uint64_t: 8 7
解决方案是提供一个成功映射的功能int,long并long long提供适当的int32_t或int64_t.这可以在运行时通过if (sizeof(int)==sizeof(int32_t))类型语句轻松完成,但最好是编译时解决方案.通过使用可以获得编译时解决方案boost::enable_if.
以下适用于MSVC10和gcc 4.6.3.通过禁用非整数类型可以进一步增强解决方案,但这不在此问题的范围内.
#include <iostream>
#include <stdint.h>
#include <boost/integer.hpp>
#include <boost/utility/enable_if.hpp>
#include <boost/type_traits/is_signed.hpp>
#include <boost/type_traits/is_unsigned.hpp>
using namespace std;
template <class InputT>
typename boost::enable_if_c<sizeof(InputT)==sizeof(int32_t) && boost::is_signed<InputT>::value,
int32_t>::type ConvertIntegral(InputT z) { return static_cast<int32_t>(z); }
template <class InputT>
typename boost::enable_if_c<sizeof(InputT)==sizeof(int64_t) && boost::is_signed<InputT>::value,
int64_t>::type ConvertIntegral(InputT z) { return static_cast<int64_t>(z); }
template <class InputT>
typename boost::enable_if_c<sizeof(InputT)==sizeof(uint32_t) && boost::is_unsigned<InputT>::value,
uint32_t>::type ConvertIntegral(InputT z) { return static_cast<uint32_t>(z); }
template <class InputT>
typename boost::enable_if_c<sizeof(InputT)==sizeof(uint64_t) && boost::is_unsigned<InputT>::value,
uint64_t>::type ConvertIntegral(InputT z) { return static_cast<uint64_t>(z); }
void msg(int v) { cout << "int: " << sizeof(int) << ' ' << v << '\n'; }
void msg(long v) { cout << "long: " << sizeof(long) << ' ' << v << '\n'; }
void msg(long long v) { cout << "long long: " << sizeof(long long) << ' ' << v << '\n'; }
void msg2(int32_t v) { cout << "int32_t: " << sizeof(int32_t) << ' ' << v << '\n'; }
void msg2(int64_t v) { cout << "int64_t: " << sizeof(int64_t) << ' ' << v << '\n'; }
void msg2(uint32_t v) { cout << "uint32_t: " << sizeof(uint32_t) << ' ' << v << '\n'; }
void msg2(uint64_t v) { cout << "uint64_t: " << sizeof(uint64_t) << ' ' << v << '\n'; }
int main()
{
int myInt = -5;
long myLong = -6L;
long long myLongLong = -7LL;
unsigned int myUInt = 5;
unsigned int myULong = 6L;
unsigned long long myULongLong = 7LL;
msg(myInt);
msg(myLong);
msg(myLongLong);
msg2(ConvertIntegral(myInt));
msg2(ConvertIntegral(myLong));
msg2(ConvertIntegral(myLongLong));
msg2(ConvertIntegral(myUInt));
msg2(ConvertIntegral(myULong));
msg2(ConvertIntegral(myULongLong));
return 0;
}
Greg 一语中的:int32_t和int64_t是类型定义,可能是也可能不是long。如果两者都不是 的 typedef long,则重载决策可能会失败。和long->int32_t均long->int64_t具有 Rank=Promotion(表 12、13.3.3.1.2)