/* * Copyright 2012 Google Inc. * * Use of this source code is governed by a BSD-style license that can be * found in the LICENSE file. */ #ifndef SkMathPriv_DEFINED #define SkMathPriv_DEFINED #include "SkMath.h" #if defined(SK_BUILD_FOR_IOS) && (defined(SK_BUILD_FOR_ARM32) || defined(SK_BUILD_FOR_ARM64)) // iOS on ARM starts processes with the Flush-To-Zero (FTZ) and // Denormals-Are-Zero (DAZ) bits in the fpscr register set. // Algorithms that rely on denormalized numbers need alternative implementations. // This can also be controlled in SSE with the MXCSR register, // x87 with FSTCW/FLDCW, and mips with FCSR. This should be detected at runtime, // or the library built one way or the other more generally (by the build). #define SK_CPU_FLUSH_TO_ZERO #endif /** Returns -1 if n < 0, else returns 0 */ #define SkExtractSign(n) ((int32_t)(n) >> 31) /** If sign == -1, returns -n, else sign must be 0, and returns n. Typically used in conjunction with SkExtractSign(). */ static inline int32_t SkApplySign(int32_t n, int32_t sign) { SkASSERT(sign == 0 || sign == -1); return (n ^ sign) - sign; } /** Return x with the sign of y */ static inline int32_t SkCopySign32(int32_t x, int32_t y) { return SkApplySign(x, SkExtractSign(x ^ y)); } /** Given a positive value and a positive max, return the value pinned against max. Note: only works as long as max - value doesn't wrap around @return max if value >= max, else value */ static inline unsigned SkClampUMax(unsigned value, unsigned max) { if (value > max) { value = max; } return value; } // If a signed int holds min_int (e.g. 0x80000000) it is undefined what happens when // we negate it (even though we *know* we're 2's complement and we'll get the same // value back). So we create this helper function that casts to size_t (unsigned) first, // to avoid the complaint. static inline size_t sk_negate_to_size_t(int32_t value) { #if defined(_MSC_VER) #pragma warning(push) #pragma warning(disable : 4146) // Thanks MSVC, we know what we're negating an unsigned #endif return -static_cast(value); #if defined(_MSC_VER) #pragma warning(pop) #endif } /////////////////////////////////////////////////////////////////////////////// /** Return a*b/255, truncating away any fractional bits. Only valid if both a and b are 0..255 */ static inline U8CPU SkMulDiv255Trunc(U8CPU a, U8CPU b) { SkASSERT((uint8_t)a == a); SkASSERT((uint8_t)b == b); unsigned prod = a*b + 1; return (prod + (prod >> 8)) >> 8; } /** Return (a*b)/255, taking the ceiling of any fractional bits. Only valid if both a and b are 0..255. The expected result equals (a * b + 254) / 255. */ static inline U8CPU SkMulDiv255Ceiling(U8CPU a, U8CPU b) { SkASSERT((uint8_t)a == a); SkASSERT((uint8_t)b == b); unsigned prod = a*b + 255; return (prod + (prod >> 8)) >> 8; } /** Just the rounding step in SkDiv255Round: round(value / 255) */ static inline unsigned SkDiv255Round(unsigned prod) { prod += 128; return (prod + (prod >> 8)) >> 8; } static inline float SkPinToUnitFloat(float x) { return SkTMin(SkTMax(x, 0.0f), 1.0f); } /** * Swap byte order of a 4-byte value, e.g. 0xaarrggbb -> 0xbbggrraa. */ #if defined(_MSC_VER) #include static inline uint32_t SkBSwap32(uint32_t v) { return _byteswap_ulong(v); } #else static inline uint32_t SkBSwap32(uint32_t v) { return __builtin_bswap32(v); } #endif //! Returns the number of leading zero bits (0...32) int SkCLZ_portable(uint32_t); #ifndef SkCLZ #if defined(SK_BUILD_FOR_WIN32) #include static inline int SkCLZ(uint32_t mask) { if (mask) { unsigned long index; _BitScanReverse(&index, mask); // Suppress this bogus /analyze warning. The check for non-zero // guarantees that _BitScanReverse will succeed. #pragma warning(suppress : 6102) // Using 'index' from failed function call return index ^ 0x1F; } else { return 32; } } #elif defined(SK_CPU_ARM32) || defined(__GNUC__) || defined(__clang__) static inline int SkCLZ(uint32_t mask) { // __builtin_clz(0) is undefined, so we have to detect that case. return mask ? __builtin_clz(mask) : 32; } #else #define SkCLZ(x) SkCLZ_portable(x) #endif #endif /** * Returns the smallest power-of-2 that is >= the specified value. If value * is already a power of 2, then it is returned unchanged. It is undefined * if value is <= 0. */ static inline int SkNextPow2(int value) { SkASSERT(value > 0); return 1 << (32 - SkCLZ(value - 1)); } /** * Returns the largest power-of-2 that is <= the specified value. If value * is already a power of 2, then it is returned unchanged. It is undefined * if value is <= 0. */ static inline int SkPrevPow2(int value) { SkASSERT(value > 0); return 1 << (32 - SkCLZ(value >> 1)); } /** * Returns the log2 of the specified value, were that value to be rounded up * to the next power of 2. It is undefined to pass 0. Examples: * SkNextLog2(1) -> 0 * SkNextLog2(2) -> 1 * SkNextLog2(3) -> 2 * SkNextLog2(4) -> 2 * SkNextLog2(5) -> 3 */ static inline int SkNextLog2(uint32_t value) { SkASSERT(value != 0); return 32 - SkCLZ(value - 1); } /** * Returns the log2 of the specified value, were that value to be rounded down * to the previous power of 2. It is undefined to pass 0. Examples: * SkPrevLog2(1) -> 0 * SkPrevLog2(2) -> 1 * SkPrevLog2(3) -> 1 * SkPrevLog2(4) -> 2 * SkPrevLog2(5) -> 2 */ static inline int SkPrevLog2(uint32_t value) { SkASSERT(value != 0); return 32 - SkCLZ(value >> 1); } /////////////////////////////////////////////////////////////////////////////// /** * Return the next power of 2 >= n. */ static inline uint32_t GrNextPow2(uint32_t n) { return n ? (1 << (32 - SkCLZ(n - 1))) : 1; } /** * Returns the next power of 2 >= n or n if the next power of 2 can't be represented by size_t. */ static inline size_t GrNextSizePow2(size_t n) { constexpr int kNumSizeTBits = 8 * sizeof(size_t); constexpr size_t kHighBitSet = size_t(1) << (kNumSizeTBits - 1); if (!n) { return 1; } else if (n >= kHighBitSet) { return n; } n--; uint32_t shift = 1; while (shift < kNumSizeTBits) { n |= n >> shift; shift <<= 1; } return n + 1; } #endif