#ifndef MACROS_H
#define MACROS_H
+#include "util/macros.h"
+#include "util/u_math.h"
+#include "util/rounding.h"
#include "imports.h"
#define INT_TO_USHORT(i) ((i) < 0 ? 0 : ((GLushort) ((i) >> 15)))
#define UINT_TO_USHORT(i) ((i) < 0 ? 0 : ((GLushort) ((i) >> 16)))
#define UNCLAMPED_FLOAT_TO_USHORT(us, f) \
- us = ( (GLushort) F_TO_I( CLAMP((f), 0.0F, 1.0F) * 65535.0F) )
+ us = ( (GLushort) _mesa_lroundevenf( CLAMP((f), 0.0F, 1.0F) * 65535.0F) )
#define CLAMPED_FLOAT_TO_USHORT(us, f) \
- us = ( (GLushort) F_TO_I( (f) * 65535.0F) )
+ us = ( (GLushort) _mesa_lroundevenf( (f) * 65535.0F) )
#define UNCLAMPED_FLOAT_TO_SHORT(s, f) \
- s = ( (GLshort) F_TO_I( CLAMP((f), -1.0F, 1.0F) * 32767.0F) )
+ s = ( (GLshort) _mesa_lroundevenf( CLAMP((f), -1.0F, 1.0F) * 32767.0F) )
/***
*** UNCLAMPED_FLOAT_TO_UBYTE: clamp float to [0,1] and map to ubyte in [0,255]
*** CLAMPED_FLOAT_TO_UBYTE: map float known to be in [0,1] to ubyte in [0,255]
***/
-#if defined(USE_IEEE) && !defined(DEBUG)
+#ifndef DEBUG
/* This function/macro is sensitive to precision. Test very carefully
* if you change it!
*/
-#define UNCLAMPED_FLOAT_TO_UBYTE(UB, F) \
+#define UNCLAMPED_FLOAT_TO_UBYTE(UB, FLT) \
do { \
fi_type __tmp; \
- __tmp.f = (F); \
+ __tmp.f = (FLT); \
if (__tmp.i < 0) \
UB = (GLubyte) 0; \
else if (__tmp.i >= IEEE_ONE) \
UB = (GLubyte) __tmp.i; \
} \
} while (0)
-#define CLAMPED_FLOAT_TO_UBYTE(UB, F) \
+#define CLAMPED_FLOAT_TO_UBYTE(UB, FLT) \
do { \
fi_type __tmp; \
- __tmp.f = (F) * (255.0F/256.0F) + 32768.0F; \
+ __tmp.f = (FLT) * (255.0F/256.0F) + 32768.0F; \
UB = (GLubyte) __tmp.i; \
} while (0)
#else
#define UNCLAMPED_FLOAT_TO_UBYTE(ub, f) \
- ub = ((GLubyte) F_TO_I(CLAMP((f), 0.0F, 1.0F) * 255.0F))
+ ub = ((GLubyte) _mesa_lroundevenf(CLAMP((f), 0.0F, 1.0F) * 255.0F))
#define CLAMPED_FLOAT_TO_UBYTE(ub, f) \
- ub = ((GLubyte) F_TO_I((f) * 255.0F))
+ ub = ((GLubyte) _mesa_lroundevenf((f) * 255.0F))
#endif
-static inline GLfloat INT_AS_FLT(GLint i)
+static fi_type UINT_AS_UNION(GLuint u)
+{
+ fi_type tmp;
+ tmp.u = u;
+ return tmp;
+}
+
+static inline fi_type INT_AS_UNION(GLint i)
{
fi_type tmp;
tmp.i = i;
- return tmp.f;
+ return tmp;
}
-static inline GLfloat UINT_AS_FLT(GLuint u)
+static inline fi_type FLOAT_AS_UNION(GLfloat f)
{
fi_type tmp;
- tmp.u = u;
- return tmp.f;
+ tmp.f = f;
+ return tmp;
+}
+
+/**
+ * Convert a floating point value to an unsigned fixed point value.
+ *
+ * \param frac_bits The number of bits used to store the fractional part.
+ */
+static inline uint32_t
+U_FIXED(float value, uint32_t frac_bits)
+{
+ value *= (1 << frac_bits);
+ return value < 0.0f ? 0 : (uint32_t) value;
}
+/**
+ * Convert a floating point value to an signed fixed point value.
+ *
+ * \param frac_bits The number of bits used to store the fractional part.
+ */
+static inline int32_t
+S_FIXED(float value, uint32_t frac_bits)
+{
+ return (int32_t) (value * (1 << frac_bits));
+}
/*@}*/
#endif
}
-/** Copy a 4-element float vector */
-static inline void
-COPY_4FV(GLfloat dst[4], const GLfloat src[4])
-{
- /* memcpy seems to be most efficient */
- memcpy(dst, src, sizeof(GLfloat) * 4);
-}
-
/** Copy \p SZ elements into a 4-element vector */
#define COPY_SZ_4V(DST, SZ, SRC) \
do { \
(DST)[3] *= S; \
} while (0)
-/** Assignment */
-#define ASSIGN_4V( V, V0, V1, V2, V3 ) \
-do { \
- V[0] = V0; \
- V[1] = V1; \
- V[2] = V2; \
- V[3] = V3; \
-} while(0)
-
/*@}*/
* The default values are chosen based on \p type.
*/
static inline void
-COPY_CLEAN_4V_TYPE_AS_FLOAT(GLfloat dst[4], int sz, const GLfloat src[4],
+COPY_CLEAN_4V_TYPE_AS_UNION(fi_type dst[4], int sz, const fi_type src[4],
GLenum type)
{
switch (type) {
case GL_FLOAT:
- ASSIGN_4V(dst, 0, 0, 0, 1);
+ ASSIGN_4V(dst, FLOAT_AS_UNION(0), FLOAT_AS_UNION(0),
+ FLOAT_AS_UNION(0), FLOAT_AS_UNION(1));
break;
case GL_INT:
- ASSIGN_4V(dst, INT_AS_FLT(0), INT_AS_FLT(0),
- INT_AS_FLT(0), INT_AS_FLT(1));
+ ASSIGN_4V(dst, INT_AS_UNION(0), INT_AS_UNION(0),
+ INT_AS_UNION(0), INT_AS_UNION(1));
break;
case GL_UNSIGNED_INT:
- ASSIGN_4V(dst, UINT_AS_FLT(0), UINT_AS_FLT(0),
- UINT_AS_FLT(0), UINT_AS_FLT(1));
+ ASSIGN_4V(dst, UINT_AS_UNION(0), UINT_AS_UNION(0),
+ UINT_AS_UNION(0), UINT_AS_UNION(1));
break;
default:
- ASSIGN_4V(dst, 0.0f, 0.0f, 0.0f, 1.0f); /* silence warnings */
- ASSERT(!"Unexpected type in COPY_CLEAN_4V_TYPE_AS_FLOAT macro");
+ ASSIGN_4V(dst, FLOAT_AS_UNION(0), FLOAT_AS_UNION(0),
+ FLOAT_AS_UNION(0), FLOAT_AS_UNION(1)); /* silence warnings */
+ assert(!"Unexpected type in COPY_CLEAN_4V_TYPE_AS_UNION macro");
}
COPY_SZ_4V(dst, sz, src);
}
-/** Clamp X to [MIN,MAX] */
-#define CLAMP( X, MIN, MAX ) ( (X)<(MIN) ? (MIN) : ((X)>(MAX) ? (MAX) : (X)) )
-
-/** Minimum of two values: */
-#define MIN2( A, B ) ( (A)<(B) ? (A) : (B) )
-
-/** Maximum of two values: */
-#define MAX2( A, B ) ( (A)>(B) ? (A) : (B) )
-
-/** Minimum and maximum of three values: */
-#define MIN3( A, B, C ) ((A) < (B) ? MIN2(A, C) : MIN2(B, C))
-#define MAX3( A, B, C ) ((A) > (B) ? MAX2(A, C) : MAX2(B, C))
-
static inline unsigned
minify(unsigned value, unsigned levels)
{
*
* \sa ROUND_DOWN_TO()
*/
-#define ALIGN(value, alignment) (((value) + (alignment) - 1) & ~((alignment) - 1))
+static inline uintptr_t
+ALIGN(uintptr_t value, int32_t alignment)
+{
+ assert((alignment > 0) && _mesa_is_pow_two(alignment));
+ return (((value) + (alignment) - 1) & ~((alignment) - 1));
+}
+
+/**
+ * Like ALIGN(), but works with a non-power-of-two alignment.
+ */
+static inline uintptr_t
+ALIGN_NPOT(uintptr_t value, int32_t alignment)
+{
+ assert(alignment > 0);
+ return (value + alignment - 1) / alignment * alignment;
+}
/**
* Align a value down to an alignment value
*
* \sa ALIGN()
*/
-#define ROUND_DOWN_TO(value, alignment) ((value) & ~(alignment - 1))
+static inline uintptr_t
+ROUND_DOWN_TO(uintptr_t value, int32_t alignment)
+{
+ assert((alignment > 0) && _mesa_is_pow_two(alignment));
+ return ((value) & ~(alignment - 1));
+}
/** Cross product of two 3-element vectors */
{
GLfloat len = (GLfloat) LEN_SQUARED_3FV(v);
if (len) {
- len = INV_SQRTF(len);
+ len = 1.0f / sqrtf(len);
v[0] *= len;
v[1] *= len;
v[2] *= len;
}
-/** Is float value negative? */
-static inline GLboolean
-IS_NEGATIVE(float x)
-{
- return signbit(x) != 0;
-}
-
/** Test two floats have opposite signs */
static inline GLboolean
DIFFERENT_SIGNS(GLfloat x, GLfloat y)
{
+#ifdef _MSC_VER
+#pragma warning( push )
+#pragma warning( disable : 6334 ) /* sizeof operator applied to an expression with an operator may yield unexpected results */
+#endif
return signbit(x) != signbit(y);
+#ifdef _MSC_VER
+#pragma warning( pop )
+#endif
}
-/** Compute ceiling of integer quotient of A divided by B. */
-#define CEILING( A, B ) ( (A) % (B) == 0 ? (A)/(B) : (A)/(B)+1 )
-
-
/** casts to silence warnings with some compilers */
#define ENUM_TO_INT(E) ((GLint)(E))
#define ENUM_TO_FLOAT(E) ((GLfloat)(GLint)(E))
#define ENUM_TO_DOUBLE(E) ((GLdouble)(GLint)(E))
#define ENUM_TO_BOOLEAN(E) ((E) ? GL_TRUE : GL_FALSE)
-/* Compute the size of an array */
-#define ARRAY_SIZE(x) (sizeof(x) / sizeof(x[0]))
+/* Stringify */
+#define STRINGIFY(x) #x
#endif