// This code is in the public domain -- Ignacio Castaño #pragma once #ifndef NV_CORE_UTILS_H #define NV_CORE_UTILS_H #include "Debug.h" // nvDebugCheck #include // for placement new // Just in case. Grrr. #undef min #undef max #define NV_INT8_MIN (-128) #define NV_INT8_MAX 127 #define NV_UINT8_MAX 255 #define NV_INT16_MIN (-32767-1) #define NV_INT16_MAX 32767 #define NV_UINT16_MAX 0xffff #define NV_INT32_MIN (-2147483647-1) #define NV_INT32_MAX 2147483647 #define NV_UINT32_MAX 0xffffffff #define NV_INT64_MAX POSH_I64(9223372036854775807) #define NV_INT64_MIN (-POSH_I64(9223372036854775807)-1) #define NV_UINT64_MAX POSH_U64(0xffffffffffffffff) #define NV_HALF_MAX 65504.0F #define NV_FLOAT_MAX 3.402823466e+38F #define NV_INTEGER_TO_FLOAT_MAX 16777217 // Largest integer such that it and all smaller integers can be stored in a 32bit float. namespace nv { // Less error prone than casting. From CB: // http://cbloomrants.blogspot.com/2011/06/06-17-11-c-casting-is-devil.html // These intentionally look like casts. // uint32 casts: template inline uint32 U32(T x) { return x; } template <> inline uint32 U32(uint64 x) { nvDebugCheck(x <= NV_UINT32_MAX); return (uint32)x; } template <> inline uint32 U32(int64 x) { nvDebugCheck(x >= 0 && x <= NV_UINT32_MAX); return (uint32)x; } //template <> inline uint32 U32(uint32 x) { return x; } template <> inline uint32 U32(int32 x) { nvDebugCheck(x >= 0); return (uint32)x; } //template <> inline uint32 U32(uint16 x) { return x; } template <> inline uint32 U32(int16 x) { nvDebugCheck(x >= 0); return (uint32)x; } //template <> inline uint32 U32(uint8 x) { return x; } template <> inline uint32 U32(int8 x) { nvDebugCheck(x >= 0); return (uint32)x; } // int32 casts: template inline int32 I32(T x) { return x; } template <> inline int32 I32(uint64 x) { nvDebugCheck(x <= NV_INT32_MAX); return (int32)x; } template <> inline int32 I32(int64 x) { nvDebugCheck(x >= NV_INT32_MIN && x <= NV_UINT32_MAX); return (int32)x; } template <> inline int32 I32(uint32 x) { nvDebugCheck(x <= NV_INT32_MAX); return (int32)x; } //template <> inline int32 I32(int32 x) { return x; } //template <> inline int32 I32(uint16 x) { return x; } //template <> inline int32 I32(int16 x) { return x; } //template <> inline int32 I32(uint8 x) { return x; } //template <> inline int32 I32(int8 x) { return x; } // uint16 casts: template inline uint16 U16(T x) { return x; } template <> inline uint16 U16(uint64 x) { nvDebugCheck(x <= NV_UINT16_MAX); return (uint16)x; } template <> inline uint16 U16(int64 x) { nvDebugCheck(x >= 0 && x <= NV_UINT16_MAX); return (uint16)x; } template <> inline uint16 U16(uint32 x) { nvDebugCheck(x <= NV_UINT16_MAX); return (uint16)x; } template <> inline uint16 U16(int32 x) { nvDebugCheck(x >= 0 && x <= NV_UINT16_MAX); return (uint16)x; } //template <> inline uint16 U16(uint16 x) { return x; } template <> inline uint16 U16(int16 x) { nvDebugCheck(x >= 0); return (uint16)x; } //template <> inline uint16 U16(uint8 x) { return x; } template <> inline uint16 U16(int8 x) { nvDebugCheck(x >= 0); return (uint16)x; } // int16 casts: template inline int16 I16(T x) { return x; } template <> inline int16 I16(uint64 x) { nvDebugCheck(x <= NV_INT16_MAX); return (int16)x; } template <> inline int16 I16(int64 x) { nvDebugCheck(x >= NV_INT16_MIN && x <= NV_UINT16_MAX); return (int16)x; } template <> inline int16 I16(uint32 x) { nvDebugCheck(x <= NV_INT16_MAX); return (int16)x; } template <> inline int16 I16(int32 x) { nvDebugCheck(x >= NV_INT16_MIN && x <= NV_UINT16_MAX); return (int16)x; } template <> inline int16 I16(uint16 x) { nvDebugCheck(x <= NV_INT16_MAX); return (int16)x; } //template <> inline int16 I16(int16 x) { return x; } //template <> inline int16 I16(uint8 x) { return x; } //template <> inline int16 I16(int8 x) { return x; } // uint8 casts: template inline uint8 U8(T x) { return x; } template <> inline uint8 U8(uint64 x) { nvDebugCheck(x <= NV_UINT8_MAX); return (uint8)x; } template <> inline uint8 U8(int64 x) { nvDebugCheck(x >= 0 && x <= NV_UINT8_MAX); return (uint8)x; } template <> inline uint8 U8(uint32 x) { nvDebugCheck(x <= NV_UINT8_MAX); return (uint8)x; } template <> inline uint8 U8(int32 x) { nvDebugCheck(x >= 0 && x <= NV_UINT8_MAX); return (uint8)x; } template <> inline uint8 U8(uint16 x) { nvDebugCheck(x <= NV_UINT8_MAX); return (uint8)x; } template <> inline uint8 U8(int16 x) { nvDebugCheck(x >= 0 && x <= NV_UINT8_MAX); return (uint8)x; } //template <> inline uint8 U8(uint8 x) { return x; } template <> inline uint8 U8(int8 x) { nvDebugCheck(x >= 0); return (uint8)x; } //template <> inline uint8 U8(int8 x) { nvDebugCheck(x >= 0.0f && x <= 255.0f); return (uint8)x; } // int8 casts: template inline int8 I8(T x) { return x; } template <> inline int8 I8(uint64 x) { nvDebugCheck(x <= NV_INT8_MAX); return (int8)x; } template <> inline int8 I8(int64 x) { nvDebugCheck(x >= NV_INT8_MIN && x <= NV_UINT8_MAX); return (int8)x; } template <> inline int8 I8(uint32 x) { nvDebugCheck(x <= NV_INT8_MAX); return (int8)x; } template <> inline int8 I8(int32 x) { nvDebugCheck(x >= NV_INT8_MIN && x <= NV_UINT8_MAX); return (int8)x; } template <> inline int8 I8(uint16 x) { nvDebugCheck(x <= NV_INT8_MAX); return (int8)x; } template <> inline int8 I8(int16 x) { nvDebugCheck(x >= NV_INT8_MIN && x <= NV_UINT8_MAX); return (int8)x; } template <> inline int8 I8(uint8 x) { nvDebugCheck(x <= NV_INT8_MAX); return (int8)x; } //template <> inline int8 I8(int8 x) { return x; } // float casts: template inline float F32(T x) { return x; } template <> inline float F32(uint64 x) { nvDebugCheck(x <= NV_INTEGER_TO_FLOAT_MAX); return (float)x; } template <> inline float F32(int64 x) { nvDebugCheck(x >= -NV_INTEGER_TO_FLOAT_MAX && x <= NV_INTEGER_TO_FLOAT_MAX); return (float)x; } template <> inline float F32(uint32 x) { nvDebugCheck(x <= NV_INTEGER_TO_FLOAT_MAX); return (float)x; } template <> inline float F32(int32 x) { nvDebugCheck(x >= -NV_INTEGER_TO_FLOAT_MAX && x <= NV_INTEGER_TO_FLOAT_MAX); return (float)x; } // The compiler should not complain about these conversions: //template <> inline float F32(uint16 x) { nvDebugCheck(return (float)x; } //template <> inline float F32(int16 x) { nvDebugCheck(return (float)x; } //template <> inline float F32(uint8 x) { nvDebugCheck(return (float)x; } //template <> inline float F32(int8 x) { nvDebugCheck(return (float)x; } /// Swap two values. template inline void swap(T & a, T & b) { T temp(a); a = b; b = temp; } /// Return the maximum of the two arguments. For floating point values, it returns the second value if the first is NaN. template //inline const T & max(const T & a, const T & b) inline T max(const T & a, const T & b) { return (b < a) ? a : b; } /// Return the maximum of the four arguments. template //inline const T & max4(const T & a, const T & b, const T & c) inline T max4(const T & a, const T & b, const T & c, const T & d) { return max(max(a, b), max(c, d)); } /// Return the maximum of the three arguments. template //inline const T & max3(const T & a, const T & b, const T & c) inline T max3(const T & a, const T & b, const T & c) { return max(a, max(b, c)); } /// Return the minimum of two values. template //inline const T & min(const T & a, const T & b) inline T min(const T & a, const T & b) { return (a < b) ? a : b; } /// Return the maximum of the three arguments. template //inline const T & min3(const T & a, const T & b, const T & c) inline T min3(const T & a, const T & b, const T & c) { return min(a, min(b, c)); } /// Clamp between two values. template //inline const T & clamp(const T & x, const T & a, const T & b) inline T clamp(const T & x, const T & a, const T & b) { return min(max(x, a), b); } /** Return the next power of two. * @see http://graphics.stanford.edu/~seander/bithacks.html * @warning Behaviour for 0 is undefined. * @note isPowerOfTwo(x) == true -> nextPowerOfTwo(x) == x * @note nextPowerOfTwo(x) = 2 << log2(x-1) */ inline uint nextPowerOfTwo( uint x ) { nvDebugCheck( x != 0 ); #if 1 // On modern CPUs this is supposed to be as fast as using the bsr instruction. x--; x |= x >> 1; x |= x >> 2; x |= x >> 4; x |= x >> 8; x |= x >> 16; return x+1; #else uint p = 1; while( x > p ) { p += p; } return p; #endif } /// Return true if @a n is a power of two. inline bool isPowerOfTwo( uint n ) { return (n & (n-1)) == 0; } // @@ Move this to utils? /// Delete all the elements of a container. template void deleteAll(T & container) { for (typename T::PseudoIndex i = container.start(); !container.isDone(i); container.advance(i)) { delete container[i]; } } // @@ Specialize these methods for numeric, pointer, and pod types. template void construct_range(T * restrict ptr, uint new_size, uint old_size) { for (uint i = old_size; i < new_size; i++) { new(ptr+i) T; // placement new } } template void construct_range(T * restrict ptr, uint new_size, uint old_size, const T & elem) { for (uint i = old_size; i < new_size; i++) { new(ptr+i) T(elem); // placement new } } template void construct_range(T * restrict ptr, uint new_size, uint old_size, const T * src) { for (uint i = old_size; i < new_size; i++) { new(ptr+i) T(src[i]); // placement new } } template void destroy_range(T * restrict ptr, uint new_size, uint old_size) { for (uint i = new_size; i < old_size; i++) { (ptr+i)->~T(); // Explicit call to the destructor } } template void fill(T * restrict dst, uint count, const T & value) { for (uint i = 0; i < count; i++) { dst[i] = value; } } template void copy_range(T * restrict dst, const T * restrict src, uint count) { for (uint i = 0; i < count; i++) { dst[i] = src[i]; } } template bool find(const T & element, const T * restrict ptr, uint begin, uint end, uint * index) { for (uint i = begin; i < end; i++) { if (ptr[i] == element) { if (index != NULL) *index = i; return true; } } return false; } } // nv namespace #endif // NV_CORE_UTILS_H