src/core/SkMath.cpp - fp2-dev/platform/external/chromium_org/third_party/skia - Gitiles

 /*
  * Copyright (C) 2006-2008 The Android Open Source Project
  *
  * Licensed under the Apache License, Version 2.0 (the "License");
  * you may not use this file except in compliance with the License.
  * You may obtain a copy of the License at
  *
  *      http://www.apache.org/licenses/LICENSE-2.0
  *
  * Unless required by applicable law or agreed to in writing, software
  * distributed under the License is distributed on an "AS IS" BASIS,
  * WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
  * See the License for the specific language governing permissions and
  * limitations under the License.
  */

 #include "SkMath.h"
 #include "SkCordic.h"
 #include "SkFloatBits.h"
 #include "SkFloatingPoint.h"
 #include "Sk64.h"
 #include "SkScalar.h"

 #ifdef SK_SCALAR_IS_FLOAT
     const uint32_t gIEEENotANumber = 0x7FFFFFFF;
     const uint32_t gIEEEInfinity = 0x7F800000;
 #endif

 #define sub_shift(zeros, x, n)  \
     zeros -= n;                 \
     x >>= n

 int SkCLZ_portable(uint32_t x) {
     if (x == 0) {
         return 32;
     }

 #ifdef SK_CPU_HAS_CONDITIONAL_INSTR
     int zeros = 31;
     if (x & 0xFFFF0000) {
         sub_shift(zeros, x, 16);
     }
     if (x & 0xFF00) {
         sub_shift(zeros, x, 8);
     }
     if (x & 0xF0) {
         sub_shift(zeros, x, 4);
     }
     if (x & 0xC) {
         sub_shift(zeros, x, 2);
     }
     if (x & 0x2) {
         sub_shift(zeros, x, 1);
     }
 #else
     int zeros = ((x >> 16) - 1) >> 31 << 4;
     x <<= zeros;

     int nonzero = ((x >> 24) - 1) >> 31 << 3;
     zeros += nonzero;
     x <<= nonzero;

     nonzero = ((x >> 28) - 1) >> 31 << 2;
     zeros += nonzero;
     x <<= nonzero;

     nonzero = ((x >> 30) - 1) >> 31 << 1;
     zeros += nonzero;
     x <<= nonzero;

     zeros += (~x) >> 31;
 #endif

     return zeros;
 }

 int32_t SkMulDiv(int32_t numer1, int32_t numer2, int32_t denom) {
     SkASSERT(denom);

     Sk64 tmp;
     tmp.setMul(numer1, numer2);
     tmp.div(denom, Sk64::kTrunc_DivOption);
     return tmp.get32();
 }

 int32_t SkMulShift(int32_t a, int32_t b, unsigned shift) {
     int sign = SkExtractSign(a ^ b);

     if (shift > 63) {
         return sign;
     }

     a = SkAbs32(a);
     b = SkAbs32(b);

     uint32_t ah = a >> 16;
     uint32_t al = a & 0xFFFF;
     uint32_t bh = b >> 16;
     uint32_t bl = b & 0xFFFF;

     uint32_t A = ah * bh;
     uint32_t B = ah * bl + al * bh;
     uint32_t C = al * bl;

     /*  [  A  ]
            [  B  ]
               [  C  ]
     */
     uint32_t lo = C + (B << 16);
     int32_t  hi = A + (B >> 16) + (lo < C);

     if (sign < 0) {
         hi = -hi - Sk32ToBool(lo);
         lo = 0 - lo;
     }

     if (shift == 0) {
 #ifdef SK_DEBUGx
         SkASSERT(((int32_t)lo >> 31) == hi);
 #endif
         return lo;
     } else if (shift >= 32) {
         return hi >> (shift - 32);
     } else {
 #ifdef SK_DEBUGx
         int32_t tmp = hi >> shift;
         SkASSERT(tmp == 0 || tmp == -1);
 #endif
         // we want (hi << (32 - shift)) | (lo >> shift) but rounded
         int roundBit = (lo >> (shift - 1)) & 1;
         return ((hi << (32 - shift)) | (lo >> shift)) + roundBit;
     }
 }

 SkFixed SkFixedMul_portable(SkFixed a, SkFixed b) {
 #if 0
     Sk64    tmp;

     tmp.setMul(a, b);
     tmp.shiftRight(16);
     return tmp.fLo;
 #elif defined(SkLONGLONG)
     return (SkLONGLONG)a * b >> 16;
 #else
     int sa = SkExtractSign(a);
     int sb = SkExtractSign(b);
     // now make them positive
     a = SkApplySign(a, sa);
     b = SkApplySign(b, sb);

     uint32_t    ah = a >> 16;
     uint32_t    al = a & 0xFFFF;
     uint32_t bh = b >> 16;
     uint32_t bl = b & 0xFFFF;

     uint32_t R = ah * b + al * bh + (al * bl >> 16);

     return SkApplySign(R, sa ^ sb);
 #endif
 }

 SkFract SkFractMul_portable(SkFract a, SkFract b) {
 #if 0
     Sk64 tmp;
     tmp.setMul(a, b);
     return tmp.getFract();
 #elif defined(SkLONGLONG)
     return (SkLONGLONG)a * b >> 30;
 #else
     int sa = SkExtractSign(a);
     int sb = SkExtractSign(b);
     // now make them positive
     a = SkApplySign(a, sa);
     b = SkApplySign(b, sb);

     uint32_t ah = a >> 16;
     uint32_t al = a & 0xFFFF;
     uint32_t bh = b >> 16;
     uint32_t bl = b & 0xFFFF;

     uint32_t A = ah * bh;
     uint32_t B = ah * bl + al * bh;
     uint32_t C = al * bl;

     /*  [  A  ]
            [  B  ]
               [  C  ]
     */
     uint32_t Lo = C + (B << 16);
     uint32_t Hi = A + (B >>16) + (Lo < C);

     SkASSERT((Hi >> 29) == 0);  // else overflow

     int32_t R = (Hi << 2) + (Lo >> 30);

     return SkApplySign(R, sa ^ sb);
 #endif
 }

 int SkFixedMulCommon(SkFixed a, int b, int bias) {
     // this function only works if b is 16bits
     SkASSERT(b == (int16_t)b);
     SkASSERT(b >= 0);

     int sa = SkExtractSign(a);
     a = SkApplySign(a, sa);
     uint32_t ah = a >> 16;
     uint32_t al = a & 0xFFFF;
     uint32_t R = ah * b + ((al * b + bias) >> 16);
     return SkApplySign(R, sa);
 }

 #ifdef SK_DEBUGx
     #define TEST_FASTINVERT
 #endif

 SkFixed SkFixedFastInvert(SkFixed x) {
 /*  Adapted (stolen) from gglRecip()
 */

     if (x == SK_Fixed1) {
         return SK_Fixed1;
     }

     int      sign = SkExtractSign(x);
     uint32_t a = SkApplySign(x, sign);

     if (a <= 2) {
         return SkApplySign(SK_MaxS32, sign);
     }

 #ifdef TEST_FASTINVERT
     SkFixed orig = a;
     uint32_t slow = SkFixedDiv(SK_Fixed1, a);
 #endif

     // normalize a
     int lz = SkCLZ(a);
     a = a << lz >> 16;

     // compute 1/a approximation (0.5 <= a < 1.0)
     uint32_t r = 0x17400 - a;      // (2.90625 (~2.914) - 2*a) >> 1

     // Newton-Raphson iteration:
     // x = r*(2 - a*r) = ((r/2)*(1 - a*r/2))*4
     r = ( (0x10000 - ((a*r)>>16)) * r ) >> 15;
     r = ( (0x10000 - ((a*r)>>16)) * r ) >> (30 - lz);

 #ifdef TEST_FASTINVERT
     SkDebugf("SkFixedFastInvert(%x %g) = %x %g Slow[%x %g]\n",
                 orig, orig/65536.,
                 r, r/65536.,
                 slow, slow/65536.);
 #endif

     return SkApplySign(r, sign);
 }

 ///////////////////////////////////////////////////////////////////////////////

 #define DIVBITS_ITER(n)                                 \
     case n:                                             \
         if ((numer = (numer << 1) - denom) >= 0)        \
             result |= 1 << (n - 1); else numer += denom

 int32_t SkDivBits(int32_t numer, int32_t denom, int shift_bias) {
     SkASSERT(denom != 0);
     if (numer == 0) {
         return 0;
     }

     // make numer and denom positive, and sign hold the resulting sign
     int32_t sign = SkExtractSign(numer ^ denom);
     numer = SkAbs32(numer);
     denom = SkAbs32(denom);

     int nbits = SkCLZ(numer) - 1;
     int dbits = SkCLZ(denom) - 1;
     int bits = shift_bias - nbits + dbits;

     if (bits < 0) {  // answer will underflow
         return 0;
     }
     if (bits > 31) {  // answer will overflow
         return SkApplySign(SK_MaxS32, sign);
     }

     denom <<= dbits;
     numer <<= nbits;

     SkFixed result = 0;

     // do the first one
     if ((numer -= denom) >= 0) {
         result = 1;
     } else {
         numer += denom;
     }

     // Now fall into our switch statement if there are more bits to compute
     if (bits > 0) {
         // make room for the rest of the answer bits
         result <<= bits;
         switch (bits) {
             DIVBITS_ITER(31); DIVBITS_ITER(30); DIVBITS_ITER(29);
             DIVBITS_ITER(28); DIVBITS_ITER(27); DIVBITS_ITER(26);
             DIVBITS_ITER(25); DIVBITS_ITER(24); DIVBITS_ITER(23);
             DIVBITS_ITER(22); DIVBITS_ITER(21); DIVBITS_ITER(20);
             DIVBITS_ITER(19); DIVBITS_ITER(18); DIVBITS_ITER(17);
             DIVBITS_ITER(16); DIVBITS_ITER(15); DIVBITS_ITER(14);
             DIVBITS_ITER(13); DIVBITS_ITER(12); DIVBITS_ITER(11);
             DIVBITS_ITER(10); DIVBITS_ITER( 9); DIVBITS_ITER( 8);
             DIVBITS_ITER( 7); DIVBITS_ITER( 6); DIVBITS_ITER( 5);
             DIVBITS_ITER( 4); DIVBITS_ITER( 3); DIVBITS_ITER( 2);
             // we merge these last two together, makes GCC make better ARM
             default:
             DIVBITS_ITER( 1);
         }
     }

     if (result < 0) {
         result = SK_MaxS32;
     }
     return SkApplySign(result, sign);
 }

 /*  mod(float numer, float denom) seems to always return the sign
     of the numer, so that's what we do too
 */
 SkFixed SkFixedMod(SkFixed numer, SkFixed denom) {
     int sn = SkExtractSign(numer);
     int sd = SkExtractSign(denom);

     numer = SkApplySign(numer, sn);
     denom = SkApplySign(denom, sd);

     if (numer < denom) {
         return SkApplySign(numer, sn);
     } else if (numer == denom) {
         return 0;
     } else {
         SkFixed div = SkFixedDiv(numer, denom);
         return SkApplySign(SkFixedMul(denom, div & 0xFFFF), sn);
     }
 }

 /* www.worldserver.com/turk/computergraphics/FixedSqrt.pdf
 */
 int32_t SkSqrtBits(int32_t x, int count) {
     SkASSERT(x >= 0 && count > 0 && (unsigned)count <= 30);

     uint32_t    root = 0;
     uint32_t    remHi = 0;
     uint32_t    remLo = x;

     do {
         root <<= 1;

         remHi = (remHi<<2) | (remLo>>30);
         remLo <<= 2;

         uint32_t testDiv = (root << 1) + 1;
         if (remHi >= testDiv) {
             remHi -= testDiv;
             root++;
         }
     } while (--count >= 0);

     return root;
 }

 int32_t SkCubeRootBits(int32_t value, int bits) {
     SkASSERT(bits > 0);

     int sign = SkExtractSign(value);
     value = SkApplySign(value, sign);

     uint32_t root = 0;
     uint32_t curr = (uint32_t)value >> 30;
     value <<= 2;

     do {
         root <<= 1;
         uint32_t guess = root * root + root;
         guess = (guess << 1) + guess;   // guess *= 3
         if (guess < curr) {
             curr -= guess + 1;
             root |= 1;
         }
         curr = (curr << 3) | ((uint32_t)value >> 29);
         value <<= 3;
     } while (--bits);

     return SkApplySign(root, sign);
 }

 SkFixed SkFixedMean(SkFixed a, SkFixed b) {
     Sk64 tmp;

     tmp.setMul(a, b);
     return tmp.getSqrt();
 }

 ///////////////////////////////////////////////////////////////////////////////

 #ifdef SK_SCALAR_IS_FLOAT
 float SkScalarSinCos(float radians, float* cosValue) {
     float sinValue = sk_float_sin(radians);

     if (cosValue) {
         *cosValue = sk_float_cos(radians);
         if (SkScalarNearlyZero(*cosValue)) {
             *cosValue = 0;
         }
     }

     if (SkScalarNearlyZero(sinValue)) {
         sinValue = 0;
     }
     return sinValue;
 }
 #endif

 #define INTERP_SINTABLE
 #define BUILD_TABLE_AT_RUNTIMEx

 #define kTableSize  256

 #ifdef BUILD_TABLE_AT_RUNTIME
     static uint16_t gSkSinTable[kTableSize];

     static void build_sintable(uint16_t table[]) {
         for (int i = 0; i < kTableSize; i++) {
             double  rad = i * 3.141592653589793 / (2*kTableSize);
             double  val = sin(rad);
             int     ival = (int)(val * SK_Fixed1);
             table[i] = SkToU16(ival);
         }
     }
 #else
     #include "SkSinTable.h"
 #endif

 #define SK_Fract1024SizeOver2PI     0x28BE60    /* floatToFract(1024 / 2PI) */

 #ifdef INTERP_SINTABLE
 static SkFixed interp_table(const uint16_t table[], int index, int partial255) {
     SkASSERT((unsigned)index < kTableSize);
     SkASSERT((unsigned)partial255 <= 255);

     SkFixed lower = table[index];
     SkFixed upper = (index == kTableSize - 1) ? SK_Fixed1 : table[index + 1];

     SkASSERT(lower < upper);
     SkASSERT(lower >= 0);
     SkASSERT(upper <= SK_Fixed1);

     partial255 += (partial255 >> 7);
     return lower + ((upper - lower) * partial255 >> 8);
 }
 #endif

 SkFixed SkFixedSinCos(SkFixed radians, SkFixed* cosValuePtr) {
     SkASSERT(SK_ARRAY_COUNT(gSkSinTable) == kTableSize);

 #ifdef BUILD_TABLE_AT_RUNTIME
     static bool gFirstTime = true;
     if (gFirstTime) {
         build_sintable(gSinTable);
         gFirstTime = false;
     }
 #endif

     // make radians positive
     SkFixed sinValue, cosValue;
     int32_t cosSign = 0;
     int32_t sinSign = SkExtractSign(radians);
     radians = SkApplySign(radians, sinSign);
     // scale it to 0...1023 ...

 #ifdef INTERP_SINTABLE
     radians = SkMulDiv(radians, 2 * kTableSize * 256, SK_FixedPI);
     int findex = radians & (kTableSize * 256 - 1);
     int index = findex >> 8;
     int partial = findex & 255;
     sinValue = interp_table(gSkSinTable, index, partial);

     findex = kTableSize * 256 - findex - 1;
     index = findex >> 8;
     partial = findex & 255;
     cosValue = interp_table(gSkSinTable, index, partial);

     int quad = ((unsigned)radians / (kTableSize * 256)) & 3;
 #else
     radians = SkMulDiv(radians, 2 * kTableSize, SK_FixedPI);
     int     index = radians & (kTableSize - 1);

     if (index == 0) {
         sinValue = 0;
         cosValue = SK_Fixed1;
     } else {
         sinValue = gSkSinTable[index];
         cosValue = gSkSinTable[kTableSize - index];
     }
     int quad = ((unsigned)radians / kTableSize) & 3;
 #endif

     if (quad & 1) {
         SkTSwap<SkFixed>(sinValue, cosValue);
     }
     if (quad & 2) {
         sinSign = ~sinSign;
     }
     if (((quad - 1) & 2) == 0) {
         cosSign = ~cosSign;
     }

     // restore the sign for negative angles
     sinValue = SkApplySign(sinValue, sinSign);
     cosValue = SkApplySign(cosValue, cosSign);

 #ifdef SK_DEBUG
     if (1) {
         SkFixed sin2 = SkFixedMul(sinValue, sinValue);
         SkFixed cos2 = SkFixedMul(cosValue, cosValue);
         int diff = cos2 + sin2 - SK_Fixed1;
         SkASSERT(SkAbs32(diff) <= 7);
     }
 #endif

     if (cosValuePtr) {
         *cosValuePtr = cosValue;
     }
     return sinValue;
 }

 ///////////////////////////////////////////////////////////////////////////////

 SkFixed SkFixedTan(SkFixed radians) { return SkCordicTan(radians); }
 SkFixed SkFixedASin(SkFixed x) { return SkCordicASin(x); }
 SkFixed SkFixedACos(SkFixed x) { return SkCordicACos(x); }
 SkFixed SkFixedATan2(SkFixed y, SkFixed x) { return SkCordicATan2(y, x); }
 SkFixed SkFixedExp(SkFixed x) { return SkCordicExp(x); }
 SkFixed SkFixedLog(SkFixed x) { return SkCordicLog(x); }

 ///////////////////////////////////////////////////////////////////////////////
 ///////////////////////////////////////////////////////////////////////////////

 #ifdef SK_DEBUG

 #include "SkRandom.h"

 #ifdef SkLONGLONG
 static int symmetric_fixmul(int a, int b) {
     int sa = SkExtractSign(a);
     int sb = SkExtractSign(b);

     a = SkApplySign(a, sa);
     b = SkApplySign(b, sb);

 #if 1
     int c = (int)(((SkLONGLONG)a * b) >> 16);

     return SkApplySign(c, sa ^ sb);
 #else
     SkLONGLONG ab = (SkLONGLONG)a * b;
     if (sa ^ sb) {
         ab = -ab;
     }
     return ab >> 16;
 #endif
 }
 #endif

 #include "SkPoint.h"

 #ifdef SK_SUPPORT_UNITTEST
 static void check_length(const SkPoint& p, SkScalar targetLen) {
     float x = SkScalarToFloat(p.fX);
     float y = SkScalarToFloat(p.fY);
     float len = sk_float_sqrt(x*x + y*y);

     len /= SkScalarToFloat(targetLen);

     SkASSERT(len > 0.999f && len < 1.001f);
 }
 #endif

 #ifdef SK_CAN_USE_FLOAT

 static float nextFloat(SkRandom& rand) {
     SkFloatIntUnion data;
     data.fSignBitInt = rand.nextU();
     return data.fFloat;
 }

 /*  returns true if a == b as resulting from (int)x. Since it is undefined
     what to do if the float exceeds 2^32-1, we check for that explicitly.
 */
 static bool equal_float_native_skia(float x, uint32_t ni, uint32_t si) {
     if (!(x == x)) {    // NAN
         return si == SK_MaxS32 || si == SK_MinS32;
     }
     // for out of range, C is undefined, but skia always should return NaN32
     if (x > SK_MaxS32) {
         return si == SK_MaxS32;
     }
     if (x < -SK_MaxS32) {
         return si == SK_MinS32;
     }
     return si == ni;
 }

 static void assert_float_equal(const char op[], float x, uint32_t ni,
                                uint32_t si) {
     if (!equal_float_native_skia(x, ni, si)) {
         SkDebugf("-- %s float %g bits %x native %x skia %x\n", op, x, ni, si);
         SkASSERT(!"oops");
     }
 }

 static void test_float_cast(float x) {
     int ix = (int)x;
     int iix = SkFloatToIntCast(x);
     assert_float_equal("cast", x, ix, iix);
 }

 static void test_float_floor(float x) {
     int ix = (int)floor(x);
     int iix = SkFloatToIntFloor(x);
     assert_float_equal("floor", x, ix, iix);
 }

 static void test_float_round(float x) {
     double xx = x + 0.5;    // need intermediate double to avoid temp loss
     int ix = (int)floor(xx);
     int iix = SkFloatToIntRound(x);
     assert_float_equal("round", x, ix, iix);
 }

 static void test_float_ceil(float x) {
     int ix = (int)ceil(x);
     int iix = SkFloatToIntCeil(x);
     assert_float_equal("ceil", x, ix, iix);
 }

 static void test_float_conversions(float x) {
     test_float_cast(x);
     test_float_floor(x);
     test_float_round(x);
     test_float_ceil(x);
 }

 static void test_int2float(int ival) {
     float x0 = (float)ival;
     float x1 = SkIntToFloatCast(ival);
     float x2 = SkIntToFloatCast_NoOverflowCheck(ival);
     SkASSERT(x0 == x1);
     SkASSERT(x0 == x2);
 }

 static void unittest_fastfloat() {
     SkRandom rand;
     size_t i;

     static const float gFloats[] = {
         0.f, 1.f, 0.5f, 0.499999f, 0.5000001f, 1.f/3,
         0.000000001f, 1000000000.f,     // doesn't overflow
         0.0000000001f, 10000000000.f    // does overflow
     };
     for (i = 0; i < SK_ARRAY_COUNT(gFloats); i++) {
 //        SkDebugf("---- test floats %g %d\n", gFloats[i], (int)gFloats[i]);
         test_float_conversions(gFloats[i]);
         test_float_conversions(-gFloats[i]);
     }

     for (int outer = 0; outer < 100; outer++) {
         rand.setSeed(outer);
         for (i = 0; i < 100000; i++) {
             float x = nextFloat(rand);
             test_float_conversions(x);
         }

         test_int2float(0);
         test_int2float(1);
         test_int2float(-1);
         for (i = 0; i < 100000; i++) {
             // for now only test ints that are 24bits or less, since we don't
             // round (down) large ints the same as IEEE...
             int ival = rand.nextU() & 0xFFFFFF;
             test_int2float(ival);
             test_int2float(-ival);
         }
     }
 }

 #endif

 static void test_muldiv255() {
     for (int a = 0; a <= 255; a++) {
         for (int b = 0; b <= 255; b++) {
             int ab = a * b;
             float s = ab / 255.0f;
             int round = (int)floorf(s + 0.5f);
             int trunc = (int)floorf(s);

             int iround = SkMulDiv255Round(a, b);
             int itrunc = SkMulDiv255Trunc(a, b);

             SkASSERT(iround == round);
             SkASSERT(itrunc == trunc);

             SkASSERT(itrunc <= iround);
             SkASSERT(iround <= a);
             SkASSERT(iround <= b);
         }
     }
 }

 void SkMath::UnitTest() {
 #ifdef SK_SUPPORT_UNITTEST
     int         i;
     int32_t     x;
     SkRandom    rand;

     SkToS8(127);    SkToS8(-128);       SkToU8(255);
     SkToS16(32767); SkToS16(-32768);    SkToU16(65535);
     SkToS32(2*1024*1024);   SkToS32(-2*1024*1024);  SkToU32(4*1024*1024);

     SkCordic_UnitTest();

     // these should assert
 #if 0
     SkToS8(128);
     SkToS8(-129);
     SkToU8(256);
     SkToU8(-5);

     SkToS16(32768);
     SkToS16(-32769);
     SkToU16(65536);
     SkToU16(-5);

     if (sizeof(size_t) > 4) {
         SkToS32(4*1024*1024);
         SkToS32(-4*1024*1024);
         SkToU32(5*1024*1024);
         SkToU32(-5);
     }
 #endif

     test_muldiv255();

 #ifdef SK_DEBUG
     {
         SkScalar x = SK_ScalarNaN;
         SkASSERT(SkScalarIsNaN(x));
     }
 #endif

     for (i = 1; i <= 10; i++) {
         x = SkCubeRootBits(i*i*i, 11);
         SkASSERT(x == i);
     }

     x = SkFixedSqrt(SK_Fixed1);
     SkASSERT(x == SK_Fixed1);
     x = SkFixedSqrt(SK_Fixed1/4);
     SkASSERT(x == SK_Fixed1/2);
     x = SkFixedSqrt(SK_Fixed1*4);
     SkASSERT(x == SK_Fixed1*2);

     x = SkFractSqrt(SK_Fract1);
     SkASSERT(x == SK_Fract1);
     x = SkFractSqrt(SK_Fract1/4);
     SkASSERT(x == SK_Fract1/2);
     x = SkFractSqrt(SK_Fract1/16);
     SkASSERT(x == SK_Fract1/4);

     for (i = 1; i < 100; i++) {
         x = SkFixedSqrt(SK_Fixed1 * i * i);
         SkASSERT(x == SK_Fixed1 * i);
     }

     for (i = 0; i < 1000; i++) {
         int value = rand.nextS16();
         int max = rand.nextU16();

         int clamp = SkClampMax(value, max);
         int clamp2 = value < 0 ? 0 : (value > max ? max : value);
         SkASSERT(clamp == clamp2);
     }

     for (i = 0; i < 100000; i++) {
         SkPoint p;

         p.setLength(rand.nextS(), rand.nextS(), SK_Scalar1);
         check_length(p, SK_Scalar1);
         p.setLength(rand.nextS() >> 13, rand.nextS() >> 13, SK_Scalar1);
         check_length(p, SK_Scalar1);
     }

     {
         SkFixed result = SkFixedDiv(100, 100);
         SkASSERT(result == SK_Fixed1);
         result = SkFixedDiv(1, SK_Fixed1);
         SkASSERT(result == 1);
     }

 #ifdef SK_CAN_USE_FLOAT
     unittest_fastfloat();
 #endif

 #ifdef SkLONGLONG
     for (i = 0; i < 100000; i++) {
         SkFixed numer = rand.nextS();
         SkFixed denom = rand.nextS();
         SkFixed result = SkFixedDiv(numer, denom);
         SkLONGLONG check = ((SkLONGLONG)numer << 16) / denom;

         (void)SkCLZ(numer);
         (void)SkCLZ(denom);

         SkASSERT(result != (SkFixed)SK_NaN32);
         if (check > SK_MaxS32) {
             check = SK_MaxS32;
         } else if (check < -SK_MaxS32) {
             check = SK_MinS32;
         }
         SkASSERT(result == (int32_t)check);

         result = SkFractDiv(numer, denom);
         check = ((SkLONGLONG)numer << 30) / denom;

         SkASSERT(result != (SkFixed)SK_NaN32);
         if (check > SK_MaxS32) {
             check = SK_MaxS32;
         } else if (check < -SK_MaxS32) {
             check = SK_MinS32;
         }
         SkASSERT(result == (int32_t)check);

         // make them <= 2^24, so we don't overflow in fixmul
         numer = numer << 8 >> 8;
         denom = denom << 8 >> 8;

         result = SkFixedMul(numer, denom);
         SkFixed r2 = symmetric_fixmul(numer, denom);
 //        SkASSERT(result == r2);

         result = SkFixedMul(numer, numer);
         r2 = SkFixedSquare(numer);
         SkASSERT(result == r2);

 #ifdef SK_CAN_USE_FLOAT
         if (numer >= 0 && denom >= 0) {
             SkFixed mean = SkFixedMean(numer, denom);
             float fm = sk_float_sqrt(sk_float_abs(SkFixedToFloat(numer) * SkFixedToFloat(denom)));
             SkFixed mean2 = SkFloatToFixed(fm);
             int diff = SkAbs32(mean - mean2);
             SkASSERT(diff <= 1);
         }

         {
             SkFixed mod = SkFixedMod(numer, denom);
             float n = SkFixedToFloat(numer);
             float d = SkFixedToFloat(denom);
             float m = sk_float_mod(n, d);
 #if 0
             SkDebugf("%g mod %g = %g [%g]\n",
                     SkFixedToFloat(numer), SkFixedToFloat(denom),
                     SkFixedToFloat(mod), m);
 #endif
             SkASSERT(mod == 0 || (mod < 0) == (m < 0)); // ensure the same sign
             int diff = SkAbs32(mod - SkFloatToFixed(m));
             SkASSERT((diff >> 7) == 0);
         }
 #endif
     }
 #endif

 #ifdef SK_CAN_USE_FLOAT
     for (i = 0; i < 100000; i++) {
         SkFract x = rand.nextU() >> 1;
         double xx = (double)x / SK_Fract1;
         SkFract xr = SkFractSqrt(x);
         SkFract check = SkFloatToFract(sqrt(xx));
         SkASSERT(xr == check || xr == check-1 || xr == check+1);

         xr = SkFixedSqrt(x);
         xx = (double)x / SK_Fixed1;
         check = SkFloatToFixed(sqrt(xx));
         SkASSERT(xr == check || xr == check-1);

         xr = SkSqrt32(x);
         xx = (double)x;
         check = (int32_t)sqrt(xx);
         SkASSERT(xr == check || xr == check-1);
     }
 #endif

 #if !defined(SK_SCALAR_IS_FLOAT) && defined(SK_CAN_USE_FLOAT)
     {
         SkFixed s, c;
         s = SkFixedSinCos(0, &c);
         SkASSERT(s == 0);
         SkASSERT(c == SK_Fixed1);
     }

     int maxDiff = 0;
     for (i = 0; i < 10000; i++) {
         SkFixed rads = rand.nextS() >> 10;
         double frads = SkFixedToFloat(rads);

         SkFixed s, c;
         s = SkScalarSinCos(rads, &c);

         double fs = sin(frads);
         double fc = cos(frads);

         SkFixed is = SkFloatToFixed(fs);
         SkFixed ic = SkFloatToFixed(fc);

         maxDiff = SkMax32(maxDiff, SkAbs32(is - s));
         maxDiff = SkMax32(maxDiff, SkAbs32(ic - c));
     }
     SkDebugf("SinCos: maximum error = %d\n", maxDiff);
 #endif
 #endif
 }

 #endif
	/*
	* Copyright (C) 2006-2008 The Android Open Source Project
	*
	* Licensed under the Apache License, Version 2.0 (the "License");
	* you may not use this file except in compliance with the License.
	* You may obtain a copy of the License at
	*
	* http://www.apache.org/licenses/LICENSE-2.0
	*
	* Unless required by applicable law or agreed to in writing, software
	* distributed under the License is distributed on an "AS IS" BASIS,
	* WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
	* See the License for the specific language governing permissions and
	* limitations under the License.
	*/

	#include "SkMath.h"
	#include "SkCordic.h"
	#include "SkFloatBits.h"
	#include "SkFloatingPoint.h"
	#include "Sk64.h"
	#include "SkScalar.h"

	#ifdef SK_SCALAR_IS_FLOAT
	const uint32_t gIEEENotANumber = 0x7FFFFFFF;
	const uint32_t gIEEEInfinity = 0x7F800000;
	#endif

	#define sub_shift(zeros, x, n) \
	zeros -= n; \
	x >>= n

	int SkCLZ_portable(uint32_t x) {
	if (x == 0) {
	return 32;
	}

	#ifdef SK_CPU_HAS_CONDITIONAL_INSTR
	int zeros = 31;
	if (x & 0xFFFF0000) {
	sub_shift(zeros, x, 16);
	}
	if (x & 0xFF00) {
	sub_shift(zeros, x, 8);
	}
	if (x & 0xF0) {
	sub_shift(zeros, x, 4);
	}
	if (x & 0xC) {
	sub_shift(zeros, x, 2);
	}
	if (x & 0x2) {
	sub_shift(zeros, x, 1);
	}
	#else
	int zeros = ((x >> 16) - 1) >> 31 << 4;
	x <<= zeros;

	int nonzero = ((x >> 24) - 1) >> 31 << 3;
	zeros += nonzero;
	x <<= nonzero;

	nonzero = ((x >> 28) - 1) >> 31 << 2;
	zeros += nonzero;
	x <<= nonzero;

	nonzero = ((x >> 30) - 1) >> 31 << 1;
	zeros += nonzero;
	x <<= nonzero;

	zeros += (~x) >> 31;
	#endif

	return zeros;
	}

	int32_t SkMulDiv(int32_t numer1, int32_t numer2, int32_t denom) {
	SkASSERT(denom);

	Sk64 tmp;
	tmp.setMul(numer1, numer2);
	tmp.div(denom, Sk64::kTrunc_DivOption);
	return tmp.get32();
	}

	int32_t SkMulShift(int32_t a, int32_t b, unsigned shift) {
	int sign = SkExtractSign(a ^ b);

	if (shift > 63) {
	return sign;
	}

	a = SkAbs32(a);
	b = SkAbs32(b);

	uint32_t ah = a >> 16;
	uint32_t al = a & 0xFFFF;
	uint32_t bh = b >> 16;
	uint32_t bl = b & 0xFFFF;

	uint32_t A = ah * bh;
	uint32_t B = ah * bl + al * bh;
	uint32_t C = al * bl;

	/* [ A ]
	[ B ]
	[ C ]
	*/
	uint32_t lo = C + (B << 16);
	int32_t hi = A + (B >> 16) + (lo < C);

	if (sign < 0) {
	hi = -hi - Sk32ToBool(lo);
	lo = 0 - lo;
	}

	if (shift == 0) {
	#ifdef SK_DEBUGx
	SkASSERT(((int32_t)lo >> 31) == hi);
	#endif
	return lo;
	} else if (shift >= 32) {
	return hi >> (shift - 32);
	} else {
	#ifdef SK_DEBUGx
	int32_t tmp = hi >> shift;
	SkASSERT(tmp == 0 \|\| tmp == -1);
	#endif
	// we want (hi << (32 - shift)) \| (lo >> shift) but rounded
	int roundBit = (lo >> (shift - 1)) & 1;
	return ((hi << (32 - shift)) \| (lo >> shift)) + roundBit;
	}
	}

	SkFixed SkFixedMul_portable(SkFixed a, SkFixed b) {
	#if 0
	Sk64 tmp;

	tmp.setMul(a, b);
	tmp.shiftRight(16);
	return tmp.fLo;
	#elif defined(SkLONGLONG)
	return (SkLONGLONG)a * b >> 16;
	#else
	int sa = SkExtractSign(a);
	int sb = SkExtractSign(b);
	// now make them positive
	a = SkApplySign(a, sa);
	b = SkApplySign(b, sb);

	uint32_t ah = a >> 16;
	uint32_t al = a & 0xFFFF;
	uint32_t bh = b >> 16;
	uint32_t bl = b & 0xFFFF;

	uint32_t R = ah * b + al * bh + (al * bl >> 16);

	return SkApplySign(R, sa ^ sb);
	#endif
	}

	SkFract SkFractMul_portable(SkFract a, SkFract b) {
	#if 0
	Sk64 tmp;
	tmp.setMul(a, b);
	return tmp.getFract();
	#elif defined(SkLONGLONG)
	return (SkLONGLONG)a * b >> 30;
	#else
	int sa = SkExtractSign(a);
	int sb = SkExtractSign(b);
	// now make them positive
	a = SkApplySign(a, sa);
	b = SkApplySign(b, sb);

	uint32_t ah = a >> 16;
	uint32_t al = a & 0xFFFF;
	uint32_t bh = b >> 16;
	uint32_t bl = b & 0xFFFF;

	uint32_t A = ah * bh;
	uint32_t B = ah * bl + al * bh;
	uint32_t C = al * bl;

	/* [ A ]
	[ B ]
	[ C ]
	*/
	uint32_t Lo = C + (B << 16);
	uint32_t Hi = A + (B >>16) + (Lo < C);

	SkASSERT((Hi >> 29) == 0); // else overflow

	int32_t R = (Hi << 2) + (Lo >> 30);

	return SkApplySign(R, sa ^ sb);
	#endif
	}

	int SkFixedMulCommon(SkFixed a, int b, int bias) {
	// this function only works if b is 16bits
	SkASSERT(b == (int16_t)b);
	SkASSERT(b >= 0);

	int sa = SkExtractSign(a);
	a = SkApplySign(a, sa);
	uint32_t ah = a >> 16;
	uint32_t al = a & 0xFFFF;
	uint32_t R = ah * b + ((al * b + bias) >> 16);
	return SkApplySign(R, sa);
	}

	#ifdef SK_DEBUGx
	#define TEST_FASTINVERT
	#endif

	SkFixed SkFixedFastInvert(SkFixed x) {
	/* Adapted (stolen) from gglRecip()
	*/

	if (x == SK_Fixed1) {
	return SK_Fixed1;
	}

	int sign = SkExtractSign(x);
	uint32_t a = SkApplySign(x, sign);

	if (a <= 2) {
	return SkApplySign(SK_MaxS32, sign);
	}

	#ifdef TEST_FASTINVERT
	SkFixed orig = a;
	uint32_t slow = SkFixedDiv(SK_Fixed1, a);
	#endif

	// normalize a
	int lz = SkCLZ(a);
	a = a << lz >> 16;

	// compute 1/a approximation (0.5 <= a < 1.0)
	uint32_t r = 0x17400 - a; // (2.90625 (~2.914) - 2*a) >> 1

	// Newton-Raphson iteration:
	// x = r(2 - ar) = ((r/2)(1 - ar/2))*4
	r = ( (0x10000 - ((ar)>>16)) r ) >> 15;
	r = ( (0x10000 - ((ar)>>16)) r ) >> (30 - lz);

	#ifdef TEST_FASTINVERT
	SkDebugf("SkFixedFastInvert(%x %g) = %x %g Slow[%x %g]\n",
	orig, orig/65536.,
	r, r/65536.,
	slow, slow/65536.);
	#endif

	return SkApplySign(r, sign);
	}

	///////////////////////////////////////////////////////////////////////////////

	#define DIVBITS_ITER(n) \
	case n: \
	if ((numer = (numer << 1) - denom) >= 0) \
	result \|= 1 << (n - 1); else numer += denom

	int32_t SkDivBits(int32_t numer, int32_t denom, int shift_bias) {
	SkASSERT(denom != 0);
	if (numer == 0) {
	return 0;
	}

	// make numer and denom positive, and sign hold the resulting sign
	int32_t sign = SkExtractSign(numer ^ denom);
	numer = SkAbs32(numer);
	denom = SkAbs32(denom);

	int nbits = SkCLZ(numer) - 1;
	int dbits = SkCLZ(denom) - 1;
	int bits = shift_bias - nbits + dbits;

	if (bits < 0) { // answer will underflow
	return 0;
	}
	if (bits > 31) { // answer will overflow
	return SkApplySign(SK_MaxS32, sign);
	}

	denom <<= dbits;
	numer <<= nbits;

	SkFixed result = 0;

	// do the first one
	if ((numer -= denom) >= 0) {
	result = 1;
	} else {
	numer += denom;
	}

	// Now fall into our switch statement if there are more bits to compute
	if (bits > 0) {
	// make room for the rest of the answer bits
	result <<= bits;
	switch (bits) {
	DIVBITS_ITER(31); DIVBITS_ITER(30); DIVBITS_ITER(29);
	DIVBITS_ITER(28); DIVBITS_ITER(27); DIVBITS_ITER(26);
	DIVBITS_ITER(25); DIVBITS_ITER(24); DIVBITS_ITER(23);
	DIVBITS_ITER(22); DIVBITS_ITER(21); DIVBITS_ITER(20);
	DIVBITS_ITER(19); DIVBITS_ITER(18); DIVBITS_ITER(17);
	DIVBITS_ITER(16); DIVBITS_ITER(15); DIVBITS_ITER(14);
	DIVBITS_ITER(13); DIVBITS_ITER(12); DIVBITS_ITER(11);
	DIVBITS_ITER(10); DIVBITS_ITER( 9); DIVBITS_ITER( 8);
	DIVBITS_ITER( 7); DIVBITS_ITER( 6); DIVBITS_ITER( 5);
	DIVBITS_ITER( 4); DIVBITS_ITER( 3); DIVBITS_ITER( 2);
	// we merge these last two together, makes GCC make better ARM
	default:
	DIVBITS_ITER( 1);
	}
	}

	if (result < 0) {
	result = SK_MaxS32;
	}
	return SkApplySign(result, sign);
	}

	/* mod(float numer, float denom) seems to always return the sign
	of the numer, so that's what we do too
	*/
	SkFixed SkFixedMod(SkFixed numer, SkFixed denom) {
	int sn = SkExtractSign(numer);
	int sd = SkExtractSign(denom);

	numer = SkApplySign(numer, sn);
	denom = SkApplySign(denom, sd);

	if (numer < denom) {
	return SkApplySign(numer, sn);
	} else if (numer == denom) {
	return 0;
	} else {
	SkFixed div = SkFixedDiv(numer, denom);
	return SkApplySign(SkFixedMul(denom, div & 0xFFFF), sn);
	}
	}

	/* www.worldserver.com/turk/computergraphics/FixedSqrt.pdf
	*/
	int32_t SkSqrtBits(int32_t x, int count) {
	SkASSERT(x >= 0 && count > 0 && (unsigned)count <= 30);

	uint32_t root = 0;
	uint32_t remHi = 0;
	uint32_t remLo = x;

	do {
	root <<= 1;

	remHi = (remHi<<2) \| (remLo>>30);
	remLo <<= 2;

	uint32_t testDiv = (root << 1) + 1;
	if (remHi >= testDiv) {
	remHi -= testDiv;
	root++;
	}
	} while (--count >= 0);

	return root;
	}

	int32_t SkCubeRootBits(int32_t value, int bits) {
	SkASSERT(bits > 0);

	int sign = SkExtractSign(value);
	value = SkApplySign(value, sign);

	uint32_t root = 0;
	uint32_t curr = (uint32_t)value >> 30;
	value <<= 2;

	do {
	root <<= 1;
	uint32_t guess = root * root + root;
	guess = (guess << 1) + guess; // guess *= 3
	if (guess < curr) {
	curr -= guess + 1;
	root \|= 1;
	}
	curr = (curr << 3) \| ((uint32_t)value >> 29);
	value <<= 3;
	} while (--bits);

	return SkApplySign(root, sign);
	}

	SkFixed SkFixedMean(SkFixed a, SkFixed b) {
	Sk64 tmp;

	tmp.setMul(a, b);
	return tmp.getSqrt();
	}

	///////////////////////////////////////////////////////////////////////////////

	#ifdef SK_SCALAR_IS_FLOAT
	float SkScalarSinCos(float radians, float* cosValue) {
	float sinValue = sk_float_sin(radians);

	if (cosValue) {
	*cosValue = sk_float_cos(radians);
	if (SkScalarNearlyZero(*cosValue)) {
	*cosValue = 0;
	}
	}

	if (SkScalarNearlyZero(sinValue)) {
	sinValue = 0;
	}
	return sinValue;
	}
	#endif

	#define INTERP_SINTABLE
	#define BUILD_TABLE_AT_RUNTIMEx

	#define kTableSize 256

	#ifdef BUILD_TABLE_AT_RUNTIME
	static uint16_t gSkSinTable[kTableSize];

	static void build_sintable(uint16_t table[]) {
	for (int i = 0; i < kTableSize; i++) {
	double rad = i * 3.141592653589793 / (2*kTableSize);
	double val = sin(rad);
	int ival = (int)(val * SK_Fixed1);
	table[i] = SkToU16(ival);
	}
	}
	#else
	#include "SkSinTable.h"
	#endif

	#define SK_Fract1024SizeOver2PI 0x28BE60 /* floatToFract(1024 / 2PI) */

	#ifdef INTERP_SINTABLE
	static SkFixed interp_table(const uint16_t table[], int index, int partial255) {
	SkASSERT((unsigned)index < kTableSize);
	SkASSERT((unsigned)partial255 <= 255);

	SkFixed lower = table[index];
	SkFixed upper = (index == kTableSize - 1) ? SK_Fixed1 : table[index + 1];

	SkASSERT(lower < upper);
	SkASSERT(lower >= 0);
	SkASSERT(upper <= SK_Fixed1);

	partial255 += (partial255 >> 7);
	return lower + ((upper - lower) * partial255 >> 8);
	}
	#endif

	SkFixed SkFixedSinCos(SkFixed radians, SkFixed* cosValuePtr) {
	SkASSERT(SK_ARRAY_COUNT(gSkSinTable) == kTableSize);

	#ifdef BUILD_TABLE_AT_RUNTIME
	static bool gFirstTime = true;
	if (gFirstTime) {
	build_sintable(gSinTable);
	gFirstTime = false;
	}
	#endif

	// make radians positive
	SkFixed sinValue, cosValue;
	int32_t cosSign = 0;
	int32_t sinSign = SkExtractSign(radians);
	radians = SkApplySign(radians, sinSign);
	// scale it to 0...1023 ...

	#ifdef INTERP_SINTABLE
	radians = SkMulDiv(radians, 2 * kTableSize * 256, SK_FixedPI);
	int findex = radians & (kTableSize * 256 - 1);
	int index = findex >> 8;
	int partial = findex & 255;
	sinValue = interp_table(gSkSinTable, index, partial);

	findex = kTableSize * 256 - findex - 1;
	index = findex >> 8;
	partial = findex & 255;
	cosValue = interp_table(gSkSinTable, index, partial);

	int quad = ((unsigned)radians / (kTableSize * 256)) & 3;
	#else
	radians = SkMulDiv(radians, 2 * kTableSize, SK_FixedPI);
	int index = radians & (kTableSize - 1);

	if (index == 0) {
	sinValue = 0;
	cosValue = SK_Fixed1;
	} else {
	sinValue = gSkSinTable[index];
	cosValue = gSkSinTable[kTableSize - index];
	}
	int quad = ((unsigned)radians / kTableSize) & 3;
	#endif

	if (quad & 1) {
	SkTSwap<SkFixed>(sinValue, cosValue);
	}
	if (quad & 2) {
	sinSign = ~sinSign;
	}
	if (((quad - 1) & 2) == 0) {
	cosSign = ~cosSign;
	}

	// restore the sign for negative angles
	sinValue = SkApplySign(sinValue, sinSign);
	cosValue = SkApplySign(cosValue, cosSign);

	#ifdef SK_DEBUG
	if (1) {
	SkFixed sin2 = SkFixedMul(sinValue, sinValue);
	SkFixed cos2 = SkFixedMul(cosValue, cosValue);
	int diff = cos2 + sin2 - SK_Fixed1;
	SkASSERT(SkAbs32(diff) <= 7);
	}
	#endif

	if (cosValuePtr) {
	*cosValuePtr = cosValue;
	}
	return sinValue;
	}

	///////////////////////////////////////////////////////////////////////////////

	SkFixed SkFixedTan(SkFixed radians) { return SkCordicTan(radians); }
	SkFixed SkFixedASin(SkFixed x) { return SkCordicASin(x); }
	SkFixed SkFixedACos(SkFixed x) { return SkCordicACos(x); }
	SkFixed SkFixedATan2(SkFixed y, SkFixed x) { return SkCordicATan2(y, x); }
	SkFixed SkFixedExp(SkFixed x) { return SkCordicExp(x); }
	SkFixed SkFixedLog(SkFixed x) { return SkCordicLog(x); }

	///////////////////////////////////////////////////////////////////////////////
	///////////////////////////////////////////////////////////////////////////////

	#ifdef SK_DEBUG

	#include "SkRandom.h"

	#ifdef SkLONGLONG
	static int symmetric_fixmul(int a, int b) {
	int sa = SkExtractSign(a);
	int sb = SkExtractSign(b);

	a = SkApplySign(a, sa);
	b = SkApplySign(b, sb);

	#if 1
	int c = (int)(((SkLONGLONG)a * b) >> 16);

	return SkApplySign(c, sa ^ sb);
	#else
	SkLONGLONG ab = (SkLONGLONG)a * b;
	if (sa ^ sb) {
	ab = -ab;
	}
	return ab >> 16;
	#endif
	}
	#endif

	#include "SkPoint.h"

	#ifdef SK_SUPPORT_UNITTEST
	static void check_length(const SkPoint& p, SkScalar targetLen) {
	float x = SkScalarToFloat(p.fX);
	float y = SkScalarToFloat(p.fY);
	float len = sk_float_sqrt(xx + yy);

	len /= SkScalarToFloat(targetLen);

	SkASSERT(len > 0.999f && len < 1.001f);
	}
	#endif

	#ifdef SK_CAN_USE_FLOAT

	static float nextFloat(SkRandom& rand) {
	SkFloatIntUnion data;
	data.fSignBitInt = rand.nextU();
	return data.fFloat;
	}

	/* returns true if a == b as resulting from (int)x. Since it is undefined
	what to do if the float exceeds 2^32-1, we check for that explicitly.
	*/
	static bool equal_float_native_skia(float x, uint32_t ni, uint32_t si) {
	if (!(x == x)) { // NAN
	return si == SK_MaxS32 \|\| si == SK_MinS32;
	}
	// for out of range, C is undefined, but skia always should return NaN32
	if (x > SK_MaxS32) {
	return si == SK_MaxS32;
	}
	if (x < -SK_MaxS32) {
	return si == SK_MinS32;
	}
	return si == ni;
	}

	static void assert_float_equal(const char op[], float x, uint32_t ni,
	uint32_t si) {
	if (!equal_float_native_skia(x, ni, si)) {
	SkDebugf("-- %s float %g bits %x native %x skia %x\n", op, x, ni, si);
	SkASSERT(!"oops");
	}
	}

	static void test_float_cast(float x) {
	int ix = (int)x;
	int iix = SkFloatToIntCast(x);
	assert_float_equal("cast", x, ix, iix);
	}

	static void test_float_floor(float x) {
	int ix = (int)floor(x);
	int iix = SkFloatToIntFloor(x);
	assert_float_equal("floor", x, ix, iix);
	}

	static void test_float_round(float x) {
	double xx = x + 0.5; // need intermediate double to avoid temp loss
	int ix = (int)floor(xx);
	int iix = SkFloatToIntRound(x);
	assert_float_equal("round", x, ix, iix);
	}

	static void test_float_ceil(float x) {
	int ix = (int)ceil(x);
	int iix = SkFloatToIntCeil(x);
	assert_float_equal("ceil", x, ix, iix);
	}

	static void test_float_conversions(float x) {
	test_float_cast(x);
	test_float_floor(x);
	test_float_round(x);
	test_float_ceil(x);
	}

	static void test_int2float(int ival) {
	float x0 = (float)ival;
	float x1 = SkIntToFloatCast(ival);
	float x2 = SkIntToFloatCast_NoOverflowCheck(ival);
	SkASSERT(x0 == x1);
	SkASSERT(x0 == x2);
	}

	static void unittest_fastfloat() {
	SkRandom rand;
	size_t i;

	static const float gFloats[] = {
	0.f, 1.f, 0.5f, 0.499999f, 0.5000001f, 1.f/3,
	0.000000001f, 1000000000.f, // doesn't overflow
	0.0000000001f, 10000000000.f // does overflow
	};
	for (i = 0; i < SK_ARRAY_COUNT(gFloats); i++) {
	// SkDebugf("---- test floats %g %d\n", gFloats[i], (int)gFloats[i]);
	test_float_conversions(gFloats[i]);
	test_float_conversions(-gFloats[i]);
	}

	for (int outer = 0; outer < 100; outer++) {
	rand.setSeed(outer);
	for (i = 0; i < 100000; i++) {
	float x = nextFloat(rand);
	test_float_conversions(x);
	}

	test_int2float(0);
	test_int2float(1);
	test_int2float(-1);
	for (i = 0; i < 100000; i++) {
	// for now only test ints that are 24bits or less, since we don't
	// round (down) large ints the same as IEEE...
	int ival = rand.nextU() & 0xFFFFFF;
	test_int2float(ival);
	test_int2float(-ival);
	}
	}
	}

	#endif

	static void test_muldiv255() {
	for (int a = 0; a <= 255; a++) {
	for (int b = 0; b <= 255; b++) {
	int ab = a * b;
	float s = ab / 255.0f;
	int round = (int)floorf(s + 0.5f);
	int trunc = (int)floorf(s);

	int iround = SkMulDiv255Round(a, b);
	int itrunc = SkMulDiv255Trunc(a, b);

	SkASSERT(iround == round);
	SkASSERT(itrunc == trunc);

	SkASSERT(itrunc <= iround);
	SkASSERT(iround <= a);
	SkASSERT(iround <= b);
	}
	}
	}

	void SkMath::UnitTest() {
	#ifdef SK_SUPPORT_UNITTEST
	int i;
	int32_t x;
	SkRandom rand;

	SkToS8(127); SkToS8(-128); SkToU8(255);
	SkToS16(32767); SkToS16(-32768); SkToU16(65535);
	SkToS32(210241024); SkToS32(-210241024); SkToU32(410241024);

	SkCordic_UnitTest();

	// these should assert
	#if 0
	SkToS8(128);
	SkToS8(-129);
	SkToU8(256);
	SkToU8(-5);

	SkToS16(32768);
	SkToS16(-32769);
	SkToU16(65536);
	SkToU16(-5);

	if (sizeof(size_t) > 4) {
	SkToS32(410241024);
	SkToS32(-410241024);
	SkToU32(510241024);
	SkToU32(-5);
	}
	#endif

	test_muldiv255();

	#ifdef SK_DEBUG
	{
	SkScalar x = SK_ScalarNaN;
	SkASSERT(SkScalarIsNaN(x));
	}
	#endif

	for (i = 1; i <= 10; i++) {
	x = SkCubeRootBits(iii, 11);
	SkASSERT(x == i);
	}

	x = SkFixedSqrt(SK_Fixed1);
	SkASSERT(x == SK_Fixed1);
	x = SkFixedSqrt(SK_Fixed1/4);
	SkASSERT(x == SK_Fixed1/2);
	x = SkFixedSqrt(SK_Fixed1*4);
	SkASSERT(x == SK_Fixed1*2);

	x = SkFractSqrt(SK_Fract1);
	SkASSERT(x == SK_Fract1);
	x = SkFractSqrt(SK_Fract1/4);
	SkASSERT(x == SK_Fract1/2);
	x = SkFractSqrt(SK_Fract1/16);
	SkASSERT(x == SK_Fract1/4);

	for (i = 1; i < 100; i++) {
	x = SkFixedSqrt(SK_Fixed1 * i * i);
	SkASSERT(x == SK_Fixed1 * i);
	}

	for (i = 0; i < 1000; i++) {
	int value = rand.nextS16();
	int max = rand.nextU16();

	int clamp = SkClampMax(value, max);
	int clamp2 = value < 0 ? 0 : (value > max ? max : value);
	SkASSERT(clamp == clamp2);
	}

	for (i = 0; i < 100000; i++) {
	SkPoint p;

	p.setLength(rand.nextS(), rand.nextS(), SK_Scalar1);
	check_length(p, SK_Scalar1);
	p.setLength(rand.nextS() >> 13, rand.nextS() >> 13, SK_Scalar1);
	check_length(p, SK_Scalar1);
	}

	{
	SkFixed result = SkFixedDiv(100, 100);
	SkASSERT(result == SK_Fixed1);
	result = SkFixedDiv(1, SK_Fixed1);
	SkASSERT(result == 1);
	}

	#ifdef SK_CAN_USE_FLOAT
	unittest_fastfloat();
	#endif

	#ifdef SkLONGLONG
	for (i = 0; i < 100000; i++) {
	SkFixed numer = rand.nextS();
	SkFixed denom = rand.nextS();
	SkFixed result = SkFixedDiv(numer, denom);
	SkLONGLONG check = ((SkLONGLONG)numer << 16) / denom;

	(void)SkCLZ(numer);
	(void)SkCLZ(denom);

	SkASSERT(result != (SkFixed)SK_NaN32);
	if (check > SK_MaxS32) {
	check = SK_MaxS32;
	} else if (check < -SK_MaxS32) {
	check = SK_MinS32;
	}
	SkASSERT(result == (int32_t)check);

	result = SkFractDiv(numer, denom);
	check = ((SkLONGLONG)numer << 30) / denom;

	SkASSERT(result != (SkFixed)SK_NaN32);
	if (check > SK_MaxS32) {
	check = SK_MaxS32;
	} else if (check < -SK_MaxS32) {
	check = SK_MinS32;
	}
	SkASSERT(result == (int32_t)check);

	// make them <= 2^24, so we don't overflow in fixmul
	numer = numer << 8 >> 8;
	denom = denom << 8 >> 8;

	result = SkFixedMul(numer, denom);
	SkFixed r2 = symmetric_fixmul(numer, denom);
	// SkASSERT(result == r2);

	result = SkFixedMul(numer, numer);
	r2 = SkFixedSquare(numer);
	SkASSERT(result == r2);

	#ifdef SK_CAN_USE_FLOAT
	if (numer >= 0 && denom >= 0) {
	SkFixed mean = SkFixedMean(numer, denom);
	float fm = sk_float_sqrt(sk_float_abs(SkFixedToFloat(numer) * SkFixedToFloat(denom)));
	SkFixed mean2 = SkFloatToFixed(fm);
	int diff = SkAbs32(mean - mean2);
	SkASSERT(diff <= 1);
	}

	{
	SkFixed mod = SkFixedMod(numer, denom);
	float n = SkFixedToFloat(numer);
	float d = SkFixedToFloat(denom);
	float m = sk_float_mod(n, d);
	#if 0
	SkDebugf("%g mod %g = %g [%g]\n",
	SkFixedToFloat(numer), SkFixedToFloat(denom),
	SkFixedToFloat(mod), m);
	#endif
	SkASSERT(mod == 0 \|\| (mod < 0) == (m < 0)); // ensure the same sign
	int diff = SkAbs32(mod - SkFloatToFixed(m));
	SkASSERT((diff >> 7) == 0);
	}
	#endif
	}
	#endif

	#ifdef SK_CAN_USE_FLOAT
	for (i = 0; i < 100000; i++) {
	SkFract x = rand.nextU() >> 1;
	double xx = (double)x / SK_Fract1;
	SkFract xr = SkFractSqrt(x);
	SkFract check = SkFloatToFract(sqrt(xx));
	SkASSERT(xr == check \|\| xr == check-1 \|\| xr == check+1);

	xr = SkFixedSqrt(x);
	xx = (double)x / SK_Fixed1;
	check = SkFloatToFixed(sqrt(xx));
	SkASSERT(xr == check \|\| xr == check-1);

	xr = SkSqrt32(x);
	xx = (double)x;
	check = (int32_t)sqrt(xx);
	SkASSERT(xr == check \|\| xr == check-1);
	}
	#endif

	#if !defined(SK_SCALAR_IS_FLOAT) && defined(SK_CAN_USE_FLOAT)
	{
	SkFixed s, c;
	s = SkFixedSinCos(0, &c);
	SkASSERT(s == 0);
	SkASSERT(c == SK_Fixed1);
	}

	int maxDiff = 0;
	for (i = 0; i < 10000; i++) {
	SkFixed rads = rand.nextS() >> 10;
	double frads = SkFixedToFloat(rads);

	SkFixed s, c;
	s = SkScalarSinCos(rads, &c);

	double fs = sin(frads);
	double fc = cos(frads);

	SkFixed is = SkFloatToFixed(fs);
	SkFixed ic = SkFloatToFixed(fc);

	maxDiff = SkMax32(maxDiff, SkAbs32(is - s));
	maxDiff = SkMax32(maxDiff, SkAbs32(ic - c));
	}
	SkDebugf("SinCos: maximum error = %d\n", maxDiff);
	#endif
	#endif
	}

	#endif