Esempio n. 1
0
// vector of 4 32-bit unsigned integers
func (d Uint32Div) Div(a M128i) M128i {
	t1 := sse2.MulEpu32(a, u.multiplier)  // 32x32->64 bit unsigned multiplication of a[0] and a[2]
	t2 := sse2.SrliEpi64(t1, 32)          // high dword of result 0 and 2
	t3 := sse2.SrliEpi64(a, 32)           // get a[1] and a[3] into position for multiplication
	t4 := sse2.MulEpu32(t3, u.multiplier) // 32x32->64 bit unsigned multiplication of a[1] and a[3]
	t5 := sse2.SetEpi32(-1, 0, -1, 0)     // mask of dword 1 and 3
	t6 := sse2.AndSi128(t4, t5)           // high dword of result 1 and 3
	t7 := sse2.OrSi128(t2, t6)            // combine all four results into one vector
	t8 := sse2.SubEpi32(a, t7)            // subtract
	t9 := sse2.SrlEpi32(t8, u.shift1)     // shift right logical
	t10 := sse2.AddEpi32(t7, t9)          // add
	return sse2.SrlEpi32(t10, d.u.shift2) // shift right logical
}
Esempio n. 2
0
// Mixed sse+sse2
// Applies a 3x3 matrix and sRGB gamma corrects input
// and writes it to output.
// https://github.com/rawstudio/rawstudio/blob/master/plugins/colorspace-transform/colorspace_transform_sse2.c#L205
func Transform8sRGB() {
	w := 1048
	h := 1024
	var matrix [3][3]float32

	// Input is a w * h * 4 components 16 bit per component image
	var input = make([]byte, w*h*8)

	// Output is 4 byte/pixel, RGBA image
	var output = make([]byte, w*h*4)

	// The matrix with values splatted to all registers
	var matPs = make([]x86.M128, 3*3)

	// Fill with values
	matPs[0] = sse.Set1Ps(matrix[0][0])
	matPs[1] = sse.Set1Ps(matrix[0][1])
	matPs[2] = sse.Set1Ps(matrix[0][2])
	matPs[3] = sse.Set1Ps(matrix[1][0])
	matPs[4] = sse.Set1Ps(matrix[1][1])
	matPs[5] = sse.Set1Ps(matrix[1][2])
	matPs[6] = sse.Set1Ps(matrix[2][0])
	matPs[7] = sse.Set1Ps(matrix[2][1])
	matPs[8] = sse.Set1Ps(matrix[2][2])

	for y := 0; y < h; y++ {
		i := x86.BytesToM128i(input[y*w*8 : y*w*8+w*8])
		o := x86.BytesToM128i(output[y*w*4 : y*w*4+w*4])

		// Converts 4 pixels per loop
		for x := 0; x < w/4; x++ {

			/* Load and convert to float */
			zero := sse2.SetzeroSi128()
			in := i[x*2]    // Load two pixels
			in2 := i[x*2+1] // Load two pixels
			p1 := sse2.UnpackloEpi16(in, zero)
			p2 := sse2.UnpackhiEpi16(in, zero)
			p3 := sse2.UnpackloEpi16(in2, zero)
			p4 := sse2.UnpackhiEpi16(in2, zero)
			p1f := sse2.Cvtepi32Ps(p1)
			p2f := sse2.Cvtepi32Ps(p2)
			p3f := sse2.Cvtepi32Ps(p3)
			p4f := sse2.Cvtepi32Ps(p4)

			/* Convert to planar */
			g1g0r1r0 := sse.UnpackloPs(p1f, p2f)
			b1b0 := sse.UnpackhiPs(p1f, p2f)
			g3g2r3r2 := sse.UnpackloPs(p3f, p4f)
			b3b2 := sse.UnpackhiPs(p3f, p4f)
			r := sse.MovelhPs(g1g0r1r0, g3g2r3r2)
			g := sse.MovehlPs(g3g2r3r2, g1g0r1r0)
			b := sse.MovelhPs(b1b0, b3b2)

			/* Apply matrix to convert to sRGB */
			r = sseMatrix3Mul(matPs[0:3], r, g, b)
			g = sseMatrix3Mul(matPs[3:6], r, g, b)
			b = sseMatrix3Mul(matPs[6:9], r, g, b)

			/* Normalize to 0->1 and clamp */
			normalize := sse.Set1Ps(1.0 / 65535.0)
			max_val := sse.Set1Ps(1.0)
			min_val := sse.SetzeroPs()
			r = sse.MinPs(max_val, sse.MaxPs(min_val, sse.MulPs(normalize, r)))
			g = sse.MinPs(max_val, sse.MaxPs(min_val, sse.MulPs(normalize, g)))
			b = sse.MinPs(max_val, sse.MaxPs(min_val, sse.MulPs(normalize, b)))

			/* Apply Gamma */
			/* Calculate values to be used if larger than junction point */
			mul_over := sse.Set1Ps(1.055)
			sub_over := sse.Set1Ps(0.055)
			pow_over := sse.Set1Ps(1.0 / 2.4)
			r_gam := sse.SubPs(sse.MulPs(mul_over, FastPowPs(r, pow_over)), sub_over)
			g_gam := sse.SubPs(sse.MulPs(mul_over, FastPowPs(g, pow_over)), sub_over)
			b_gam := sse.SubPs(sse.MulPs(mul_over, FastPowPs(b, pow_over)), sub_over)

			/* Create mask for values smaller than junction point */
			junction := sse.Set1Ps(0.0031308)
			mask_r := sse.CmpltPs(r, junction)
			mask_g := sse.CmpltPs(g, junction)
			mask_b := sse.CmpltPs(b, junction)

			/* Calculate value to be used if under junction */
			mul_under := sse.Set1Ps(12.92)
			r_mul := sse.AndPs(mask_r, sse.MulPs(mul_under, r))
			g_mul := sse.AndPs(mask_g, sse.MulPs(mul_under, g))
			b_mul := sse.AndPs(mask_b, sse.MulPs(mul_under, b))

			/* Select the value to be used based on the junction mask and scale to 8 bit */
			upscale := sse.Set1Ps(255.5)
			r = sse.MulPs(upscale, sse.OrPs(r_mul, sse.AndnotPs(mask_r, r_gam)))
			g = sse.MulPs(upscale, sse.OrPs(g_mul, sse.AndnotPs(mask_g, g_gam)))
			b = sse.MulPs(upscale, sse.OrPs(b_mul, sse.AndnotPs(mask_b, b_gam)))

			/* Convert to 8 bit unsigned  and interleave*/
			r_i := sse2.CvtpsEpi32(r)
			g_i := sse2.CvtpsEpi32(g)
			b_i := sse2.CvtpsEpi32(b)

			r_i = sse2.PacksEpi32(r_i, r_i)
			g_i = sse2.PacksEpi32(g_i, g_i)
			b_i = sse2.PacksEpi32(b_i, b_i)

			/* Set alpha value to 255 and store */
			alpha_mask := sse2.Set1Epi32(0xff000000)
			rg_i := sse2.UnpackloEpi16(r_i, g_i)
			bb_i := sse2.UnpackloEpi16(b_i, b_i)
			p1 = sse2.UnpackloEpi32(rg_i, bb_i)
			p2 = sse2.UnpackhiEpi32(rg_i, bb_i)

			p1 = sse2.OrSi128(alpha_mask, sse2.PackusEpi16(p1, p2))

			o[x] = p1
		}
	}
}