* THEORY OF LIABILITY, WHETHER IN CONTRACT, STRICT LIABILITY, OR TORT
* (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY OUT OF THE USE
* OF THIS SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF SUCH DAMAGE.
+ *
+ * Authors: Gabe Black
+ * Ali Saidi
+ * Nathan Binkert
*/
//The purpose of this file is to provide endainness conversion utility
#ifndef __SIM_BYTE_SWAP_HH__
#define __SIM_BYTE_SWAP_HH__
-#include "sim/host.hh"
+#include "base/bigint.hh"
+#include "base/misc.hh"
+#include "base/types.hh"
// This lets us figure out what the byte order of the host system is
#if defined(linux)
// If one doesn't exist, we pretty much get what is listed below, so it all
// works out
#include <byteswap.h>
+#elif defined (__sun)
+#include <sys/isa_defs.h>
#else
#include <machine/endian.h>
#endif
+#if defined(__APPLE__)
+#include <libkern/OSByteOrder.h>
+#endif
+
+enum ByteOrder {BigEndianByteOrder, LittleEndianByteOrder};
+
//These functions actually perform the swapping for parameters
//of various bit lengths
-static inline uint64_t
+inline uint64_t
swap_byte64(uint64_t x)
{
#if defined(linux)
return bswap_64(x);
+#elif defined(__APPLE__)
+ return OSSwapInt64(x);
#else
return (uint64_t)((((uint64_t)(x) & 0xff) << 56) |
((uint64_t)(x) & 0xff00ULL) << 40 |
#endif
}
-static inline uint32_t
+inline uint32_t
swap_byte32(uint32_t x)
{
#if defined(linux)
return bswap_32(x);
+#elif defined(__APPLE__)
+ return OSSwapInt32(x);
#else
return (uint32_t)(((uint32_t)(x) & 0xff) << 24 |
((uint32_t)(x) & 0xff00) << 8 | ((uint32_t)(x) & 0xff0000) >> 8 |
#endif
}
-static inline uint16_t
+inline uint16_t
swap_byte16(uint16_t x)
{
#if defined(linux)
return bswap_16(x);
+#elif defined(__APPLE__)
+ return OSSwapInt16(x);
#else
return (uint16_t)(((uint16_t)(x) & 0xff) << 8 |
((uint16_t)(x) & 0xff00) >> 8);
#endif
}
-//This lets the compiler figure out how to call the swap_byte functions above
-//for different data types.
-static inline uint64_t swap_byte(uint64_t x) {return swap_byte64(x);}
-static inline int64_t swap_byte(int64_t x) {return swap_byte64((uint64_t)x);}
-static inline uint32_t swap_byte(uint32_t x) {return swap_byte32(x);}
-static inline int32_t swap_byte(int32_t x) {return swap_byte32((uint32_t)x);}
-//This is to prevent the following two functions from compiling on
-//64bit machines. It won't detect everything, so it should be changed.
-#ifndef __x86_64__
-static inline long swap_byte(long x) {return swap_byte32((long)x);}
-static inline unsigned long swap_byte(unsigned long x)
- { return swap_byte32((unsigned long)x);}
-#endif
-static inline uint16_t swap_byte(uint16_t x) {return swap_byte32(x);}
-static inline int16_t swap_byte(int16_t x) {return swap_byte16((uint16_t)x);}
-static inline uint8_t swap_byte(uint8_t x) {return x;}
-static inline int8_t swap_byte(int8_t x) {return x;}
-static inline double swap_byte(double x) {return swap_byte64((uint64_t)x);}
-static inline float swap_byte(float x) {return swap_byte32((uint32_t)x);}
+// This function lets the compiler figure out how to call the
+// swap_byte functions above for different data types. Since the
+// sizeof() values are known at compile time, it should inline to a
+// direct call to the right swap_byteNN() function.
+template <typename T>
+inline T swap_byte(T x) {
+ if (sizeof(T) == 8)
+ return swap_byte64((uint64_t)x);
+ else if (sizeof(T) == 4)
+ return swap_byte32((uint32_t)x);
+ else if (sizeof(T) == 2)
+ return swap_byte16((uint16_t)x);
+ else if (sizeof(T) == 1)
+ return x;
+ else
+ panic("Can't byte-swap values larger than 64 bits");
+}
+
+template<>
+inline Twin64_t swap_byte<Twin64_t>(Twin64_t x)
+{
+ x.a = swap_byte(x.a);
+ x.b = swap_byte(x.b);
+ return x;
+}
+
+template<>
+inline Twin32_t swap_byte<Twin32_t>(Twin32_t x)
+{
+ x.a = swap_byte(x.a);
+ x.b = swap_byte(x.b);
+ return x;
+}
//The conversion functions with fixed endianness on both ends don't need to
//be in a namespace
-template <typename T> static inline T betole(T value) {return swap_byte(value);}
-template <typename T> static inline T letobe(T value) {return swap_byte(value);}
+template <typename T> inline T betole(T value) {return swap_byte(value);}
+template <typename T> inline T letobe(T value) {return swap_byte(value);}
//For conversions not involving the guest system, we can define the functions
//conditionally based on the BYTE_ORDER macro and outside of the namespaces
-#if BYTE_ORDER == BIG_ENDIAN
-template <typename T> static inline T htole(T value) {return swap_byte(value);}
-template <typename T> static inline T letoh(T value) {return swap_byte(value);}
-template <typename T> static inline T htobe(T value) {return value;}
-template <typename T> static inline T betoh(T value) {return value;}
-#elif BYTE_ORDER == LITTLE_ENDIAN
-template <typename T> static inline T htole(T value) {return value;}
-template <typename T> static inline T letoh(T value) {return value;}
-template <typename T> static inline T htobe(T value) {return swap_byte(value);}
-template <typename T> static inline T betoh(T value) {return swap_byte(value);}
+#if defined(_BIG_ENDIAN) || !defined(_LITTLE_ENDIAN) && BYTE_ORDER == BIG_ENDIAN
+const ByteOrder HostByteOrder = BigEndianByteOrder;
+template <typename T> inline T htole(T value) {return swap_byte(value);}
+template <typename T> inline T letoh(T value) {return swap_byte(value);}
+template <typename T> inline T htobe(T value) {return value;}
+template <typename T> inline T betoh(T value) {return value;}
+#elif defined(_LITTLE_ENDIAN) || BYTE_ORDER == LITTLE_ENDIAN
+const ByteOrder HostByteOrder = LittleEndianByteOrder;
+template <typename T> inline T htole(T value) {return value;}
+template <typename T> inline T letoh(T value) {return value;}
+template <typename T> inline T htobe(T value) {return swap_byte(value);}
+template <typename T> inline T betoh(T value) {return swap_byte(value);}
#else
#error Invalid Endianess
#endif
namespace BigEndianGuest
{
- template <typename T>
- static inline T gtole(T value) {return betole(value);}
- template <typename T>
- static inline T letog(T value) {return letobe(value);}
- template <typename T>
- static inline T gtobe(T value) {return value;}
- template <typename T>
- static inline T betog(T value) {return value;}
- template <typename T>
- static inline T htog(T value) {return htobe(value);}
- template <typename T>
- static inline T gtoh(T value) {return betoh(value);}
+ const ByteOrder GuestByteOrder = BigEndianByteOrder;
+ template <typename T>
+ inline T gtole(T value) {return betole(value);}
+ template <typename T>
+ inline T letog(T value) {return letobe(value);}
+ template <typename T>
+ inline T gtobe(T value) {return value;}
+ template <typename T>
+ inline T betog(T value) {return value;}
+ template <typename T>
+ inline T htog(T value) {return htobe(value);}
+ template <typename T>
+ inline T gtoh(T value) {return betoh(value);}
}
namespace LittleEndianGuest
{
- template <typename T>
- static inline T gtole(T value) {return value;}
- template <typename T>
- static inline T letog(T value) {return value;}
- template <typename T>
- static inline T gtobe(T value) {return letobe(value);}
- template <typename T>
- static inline T betog(T value) {return betole(value);}
- template <typename T>
- static inline T htog(T value) {return htole(value);}
- template <typename T>
- static inline T gtoh(T value) {return letoh(value);}
+ const ByteOrder GuestByteOrder = LittleEndianByteOrder;
+ template <typename T>
+ inline T gtole(T value) {return value;}
+ template <typename T>
+ inline T letog(T value) {return value;}
+ template <typename T>
+ inline T gtobe(T value) {return letobe(value);}
+ template <typename T>
+ inline T betog(T value) {return betole(value);}
+ template <typename T>
+ inline T htog(T value) {return htole(value);}
+ template <typename T>
+ inline T gtoh(T value) {return letoh(value);}
}
#endif // __SIM_BYTE_SWAP_HH__