/* * Copyright (C) 2014 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 "rsCpuIntrinsic.h" #include "rsCpuIntrinsicInlines.h" using namespace android; using namespace android::renderscript; namespace android { namespace renderscript { class RsdCpuScriptIntrinsicResize : public RsdCpuScriptIntrinsic { public: virtual void populateScript(Script *); virtual void invokeFreeChildren(); virtual void setGlobalObj(uint32_t slot, ObjectBase *data); virtual ~RsdCpuScriptIntrinsicResize(); RsdCpuScriptIntrinsicResize(RsdCpuReferenceImpl *ctx, const Script *s, const Element *); virtual void preLaunch(uint32_t slot, const Allocation ** ains, uint32_t inLen, Allocation * aout, const void * usr, uint32_t usrLen, const RsScriptCall *sc); float scaleX; float scaleY; protected: ObjectBaseRef mAlloc; ObjectBaseRef mElement; static void kernelU1(const RsExpandKernelDriverInfo *info, uint32_t xstart, uint32_t xend, uint32_t outstep); static void kernelU2(const RsExpandKernelDriverInfo *info, uint32_t xstart, uint32_t xend, uint32_t outstep); static void kernelU4(const RsExpandKernelDriverInfo *info, uint32_t xstart, uint32_t xend, uint32_t outstep); static void kernelF1(const RsExpandKernelDriverInfo *info, uint32_t xstart, uint32_t xend, uint32_t outstep); static void kernelF2(const RsExpandKernelDriverInfo *info, uint32_t xstart, uint32_t xend, uint32_t outstep); static void kernelF4(const RsExpandKernelDriverInfo *info, uint32_t xstart, uint32_t xend, uint32_t outstep); }; } } void RsdCpuScriptIntrinsicResize::setGlobalObj(uint32_t slot, ObjectBase *data) { rsAssert(slot == 0); mAlloc.set(static_cast(data)); } static float4 cubicInterpolate(float4 p0,float4 p1,float4 p2,float4 p3, float x) { return p1 + 0.5f * x * (p2 - p0 + x * (2.f * p0 - 5.f * p1 + 4.f * p2 - p3 + x * (3.f * (p1 - p2) + p3 - p0))); } static float2 cubicInterpolate(float2 p0,float2 p1,float2 p2,float2 p3, float x) { return p1 + 0.5f * x * (p2 - p0 + x * (2.f * p0 - 5.f * p1 + 4.f * p2 - p3 + x * (3.f * (p1 - p2) + p3 - p0))); } static float cubicInterpolate(float p0,float p1,float p2,float p3 , float x) { return p1 + 0.5f * x * (p2 - p0 + x * (2.f * p0 - 5.f * p1 + 4.f * p2 - p3 + x * (3.f * (p1 - p2) + p3 - p0))); } static uchar4 OneBiCubic(const uchar4 *yp0, const uchar4 *yp1, const uchar4 *yp2, const uchar4 *yp3, float xf, float yf, int width) { int startx = (int) floor(xf - 1); xf = xf - floor(xf); int maxx = width - 1; int xs0 = rsMax(0, startx + 0); int xs1 = rsMax(0, startx + 1); int xs2 = rsMin(maxx, startx + 2); int xs3 = rsMin(maxx, startx + 3); float4 p0 = cubicInterpolate(convert_float4(yp0[xs0]), convert_float4(yp0[xs1]), convert_float4(yp0[xs2]), convert_float4(yp0[xs3]), xf); float4 p1 = cubicInterpolate(convert_float4(yp1[xs0]), convert_float4(yp1[xs1]), convert_float4(yp1[xs2]), convert_float4(yp1[xs3]), xf); float4 p2 = cubicInterpolate(convert_float4(yp2[xs0]), convert_float4(yp2[xs1]), convert_float4(yp2[xs2]), convert_float4(yp2[xs3]), xf); float4 p3 = cubicInterpolate(convert_float4(yp3[xs0]), convert_float4(yp3[xs1]), convert_float4(yp3[xs2]), convert_float4(yp3[xs3]), xf); float4 p = cubicInterpolate(p0, p1, p2, p3, yf); p = clamp(p + 0.5f, 0.f, 255.f); return convert_uchar4(p); } static uchar2 OneBiCubic(const uchar2 *yp0, const uchar2 *yp1, const uchar2 *yp2, const uchar2 *yp3, float xf, float yf, int width) { int startx = (int) floor(xf - 1); xf = xf - floor(xf); int maxx = width - 1; int xs0 = rsMax(0, startx + 0); int xs1 = rsMax(0, startx + 1); int xs2 = rsMin(maxx, startx + 2); int xs3 = rsMin(maxx, startx + 3); float2 p0 = cubicInterpolate(convert_float2(yp0[xs0]), convert_float2(yp0[xs1]), convert_float2(yp0[xs2]), convert_float2(yp0[xs3]), xf); float2 p1 = cubicInterpolate(convert_float2(yp1[xs0]), convert_float2(yp1[xs1]), convert_float2(yp1[xs2]), convert_float2(yp1[xs3]), xf); float2 p2 = cubicInterpolate(convert_float2(yp2[xs0]), convert_float2(yp2[xs1]), convert_float2(yp2[xs2]), convert_float2(yp2[xs3]), xf); float2 p3 = cubicInterpolate(convert_float2(yp3[xs0]), convert_float2(yp3[xs1]), convert_float2(yp3[xs2]), convert_float2(yp3[xs3]), xf); float2 p = cubicInterpolate(p0, p1, p2, p3, yf); p = clamp(p + 0.5f, 0.f, 255.f); return convert_uchar2(p); } static uchar OneBiCubic(const uchar *yp0, const uchar *yp1, const uchar *yp2, const uchar *yp3, float xf, float yf, int width) { int startx = (int) floor(xf - 1); xf = xf - floor(xf); int maxx = width - 1; int xs0 = rsMax(0, startx + 0); int xs1 = rsMax(0, startx + 1); int xs2 = rsMin(maxx, startx + 2); int xs3 = rsMin(maxx, startx + 3); float p0 = cubicInterpolate((float)yp0[xs0], (float)yp0[xs1], (float)yp0[xs2], (float)yp0[xs3], xf); float p1 = cubicInterpolate((float)yp1[xs0], (float)yp1[xs1], (float)yp1[xs2], (float)yp1[xs3], xf); float p2 = cubicInterpolate((float)yp2[xs0], (float)yp2[xs1], (float)yp2[xs2], (float)yp2[xs3], xf); float p3 = cubicInterpolate((float)yp3[xs0], (float)yp3[xs1], (float)yp3[xs2], (float)yp3[xs3], xf); float p = cubicInterpolate(p0, p1, p2, p3, yf); p = clamp(p + 0.5f, 0.f, 255.f); return (uchar)p; } extern "C" uint64_t rsdIntrinsicResize_oscctl_K(uint32_t xinc); extern "C" void rsdIntrinsicResizeB4_K( uchar4 *dst, size_t count, uint32_t xf, uint32_t xinc, uchar4 const *srcn, uchar4 const *src0, uchar4 const *src1, uchar4 const *src2, size_t xclip, size_t avail, uint64_t osc_ctl, int32_t const *yr); extern "C" void rsdIntrinsicResizeB2_K( uchar2 *dst, size_t count, uint32_t xf, uint32_t xinc, uchar2 const *srcn, uchar2 const *src0, uchar2 const *src1, uchar2 const *src2, size_t xclip, size_t avail, uint64_t osc_ctl, int32_t const *yr); extern "C" void rsdIntrinsicResizeB1_K( uchar *dst, size_t count, uint32_t xf, uint32_t xinc, uchar const *srcn, uchar const *src0, uchar const *src1, uchar const *src2, size_t xclip, size_t avail, uint64_t osc_ctl, int32_t const *yr); #if defined(ARCH_ARM_USE_INTRINSICS) static void mkYCoeff(int32_t *yr, float yf) { int32_t yf1 = rint(yf * 0x10000); int32_t yf2 = rint(yf * yf * 0x10000); int32_t yf3 = rint(yf * yf * yf * 0x10000); yr[0] = -(2 * yf2 - yf3 - yf1) >> 1; yr[1] = (3 * yf3 - 5 * yf2 + 0x20000) >> 1; yr[2] = (-3 * yf3 + 4 * yf2 + yf1) >> 1; yr[3] = -(yf3 - yf2) >> 1; } #endif static float4 OneBiCubic(const float4 *yp0, const float4 *yp1, const float4 *yp2, const float4 *yp3, float xf, float yf, int width) { int startx = (int) floor(xf - 1); xf = xf - floor(xf); int maxx = width - 1; int xs0 = rsMax(0, startx + 0); int xs1 = rsMax(0, startx + 1); int xs2 = rsMin(maxx, startx + 2); int xs3 = rsMin(maxx, startx + 3); float4 p0 = cubicInterpolate(yp0[xs0], yp0[xs1], yp0[xs2], yp0[xs3], xf); float4 p1 = cubicInterpolate(yp1[xs0], yp1[xs1], yp1[xs2], yp1[xs3], xf); float4 p2 = cubicInterpolate(yp2[xs0], yp2[xs1], yp2[xs2], yp2[xs3], xf); float4 p3 = cubicInterpolate(yp3[xs0], yp3[xs1], yp3[xs2], yp3[xs3], xf); float4 p = cubicInterpolate(p0, p1, p2, p3, yf); return p; } static float2 OneBiCubic(const float2 *yp0, const float2 *yp1, const float2 *yp2, const float2 *yp3, float xf, float yf, int width) { int startx = (int) floor(xf - 1); xf = xf - floor(xf); int maxx = width - 1; int xs0 = rsMax(0, startx + 0); int xs1 = rsMax(0, startx + 1); int xs2 = rsMin(maxx, startx + 2); int xs3 = rsMin(maxx, startx + 3); float2 p0 = cubicInterpolate(yp0[xs0], yp0[xs1], yp0[xs2], yp0[xs3], xf); float2 p1 = cubicInterpolate(yp1[xs0], yp1[xs1], yp1[xs2], yp1[xs3], xf); float2 p2 = cubicInterpolate(yp2[xs0], yp2[xs1], yp2[xs2], yp2[xs3], xf); float2 p3 = cubicInterpolate(yp3[xs0], yp3[xs1], yp3[xs2], yp3[xs3], xf); float2 p = cubicInterpolate(p0, p1, p2, p3, yf); return p; } static float OneBiCubic(const float *yp0, const float *yp1, const float *yp2, const float *yp3, float xf, float yf, int width) { int startx = (int) floor(xf - 1); xf = xf - floor(xf); int maxx = width - 1; int xs0 = rsMax(0, startx + 0); int xs1 = rsMax(0, startx + 1); int xs2 = rsMin(maxx, startx + 2); int xs3 = rsMin(maxx, startx + 3); float p0 = cubicInterpolate(yp0[xs0], yp0[xs1], yp0[xs2], yp0[xs3], xf); float p1 = cubicInterpolate(yp1[xs0], yp1[xs1], yp1[xs2], yp1[xs3], xf); float p2 = cubicInterpolate(yp2[xs0], yp2[xs1], yp2[xs2], yp2[xs3], xf); float p3 = cubicInterpolate(yp3[xs0], yp3[xs1], yp3[xs2], yp3[xs3], xf); float p = cubicInterpolate(p0, p1, p2, p3, yf); return p; } void RsdCpuScriptIntrinsicResize::kernelU4(const RsExpandKernelDriverInfo *info, uint32_t xstart, uint32_t xend, uint32_t outstep) { RsdCpuScriptIntrinsicResize *cp = (RsdCpuScriptIntrinsicResize *)info->usr; if (!cp->mAlloc.get()) { ALOGE("Resize executed without input, skipping"); return; } const uchar *pin = (const uchar *)cp->mAlloc->mHal.drvState.lod[0].mallocPtr; const int srcHeight = cp->mAlloc->mHal.drvState.lod[0].dimY; const int srcWidth = cp->mAlloc->mHal.drvState.lod[0].dimX; const size_t stride = cp->mAlloc->mHal.drvState.lod[0].stride; float yf = (info->current.y + 0.5f) * cp->scaleY - 0.5f; int starty = (int) floor(yf - 1); yf = yf - floor(yf); int maxy = srcHeight - 1; int ys0 = rsMax(0, starty + 0); int ys1 = rsMax(0, starty + 1); int ys2 = rsMin(maxy, starty + 2); int ys3 = rsMin(maxy, starty + 3); const uchar4 *yp0 = (const uchar4 *)(pin + stride * ys0); const uchar4 *yp1 = (const uchar4 *)(pin + stride * ys1); const uchar4 *yp2 = (const uchar4 *)(pin + stride * ys2); const uchar4 *yp3 = (const uchar4 *)(pin + stride * ys3); uchar4 *out = ((uchar4 *)info->outPtr[0]) + xstart; uint32_t x1 = xstart; uint32_t x2 = xend; #if defined(ARCH_ARM_USE_INTRINSICS) if (gArchUseSIMD && x2 > x1 && cp->scaleX < 4.0f) { float xf = (x1 + 0.5f) * cp->scaleX - 0.5f; long xf16 = rint(xf * 0x10000); uint32_t xinc16 = rint(cp->scaleX * 0x10000); int xoff = (xf16 >> 16) - 1; int xclip = rsMax(0, xoff) - xoff; int len = x2 - x1; int32_t yr[4]; uint64_t osc_ctl = rsdIntrinsicResize_oscctl_K(xinc16); mkYCoeff(yr, yf); xoff += xclip; rsdIntrinsicResizeB4_K( out, len, xf16 & 0xffff, xinc16, yp0 + xoff, yp1 + xoff, yp2 + xoff, yp3 + xoff, xclip, srcWidth - xoff + xclip, osc_ctl, yr); out += len; x1 += len; } #endif while(x1 < x2) { float xf = (x1 + 0.5f) * cp->scaleX - 0.5f; *out = OneBiCubic(yp0, yp1, yp2, yp3, xf, yf, srcWidth); out++; x1++; } } void RsdCpuScriptIntrinsicResize::kernelU2(const RsExpandKernelDriverInfo *info, uint32_t xstart, uint32_t xend, uint32_t outstep) { RsdCpuScriptIntrinsicResize *cp = (RsdCpuScriptIntrinsicResize *)info->usr; if (!cp->mAlloc.get()) { ALOGE("Resize executed without input, skipping"); return; } const uchar *pin = (const uchar *)cp->mAlloc->mHal.drvState.lod[0].mallocPtr; const int srcHeight = cp->mAlloc->mHal.drvState.lod[0].dimY; const int srcWidth = cp->mAlloc->mHal.drvState.lod[0].dimX; const size_t stride = cp->mAlloc->mHal.drvState.lod[0].stride; float yf = (info->current.y + 0.5f) * cp->scaleY - 0.5f; int starty = (int) floor(yf - 1); yf = yf - floor(yf); int maxy = srcHeight - 1; int ys0 = rsMax(0, starty + 0); int ys1 = rsMax(0, starty + 1); int ys2 = rsMin(maxy, starty + 2); int ys3 = rsMin(maxy, starty + 3); const uchar2 *yp0 = (const uchar2 *)(pin + stride * ys0); const uchar2 *yp1 = (const uchar2 *)(pin + stride * ys1); const uchar2 *yp2 = (const uchar2 *)(pin + stride * ys2); const uchar2 *yp3 = (const uchar2 *)(pin + stride * ys3); uchar2 *out = ((uchar2 *)info->outPtr[0]) + xstart; uint32_t x1 = xstart; uint32_t x2 = xend; #if defined(ARCH_ARM_USE_INTRINSICS) if (gArchUseSIMD && x2 > x1 && cp->scaleX < 4.0f) { float xf = (x1 + 0.5f) * cp->scaleX - 0.5f; long xf16 = rint(xf * 0x10000); uint32_t xinc16 = rint(cp->scaleX * 0x10000); int xoff = (xf16 >> 16) - 1; int xclip = rsMax(0, xoff) - xoff; int len = x2 - x1; int32_t yr[4]; uint64_t osc_ctl = rsdIntrinsicResize_oscctl_K(xinc16); mkYCoeff(yr, yf); xoff += xclip; rsdIntrinsicResizeB2_K( out, len, xf16 & 0xffff, xinc16, yp0 + xoff, yp1 + xoff, yp2 + xoff, yp3 + xoff, xclip, srcWidth - xoff + xclip, osc_ctl, yr); out += len; x1 += len; } #endif while(x1 < x2) { float xf = (x1 + 0.5f) * cp->scaleX - 0.5f; *out = OneBiCubic(yp0, yp1, yp2, yp3, xf, yf, srcWidth); out++; x1++; } } void RsdCpuScriptIntrinsicResize::kernelU1(const RsExpandKernelDriverInfo *info, uint32_t xstart, uint32_t xend, uint32_t outstep) { RsdCpuScriptIntrinsicResize *cp = (RsdCpuScriptIntrinsicResize *)info->usr; if (!cp->mAlloc.get()) { ALOGE("Resize executed without input, skipping"); return; } const uchar *pin = (const uchar *)cp->mAlloc->mHal.drvState.lod[0].mallocPtr; const int srcHeight = cp->mAlloc->mHal.drvState.lod[0].dimY; const int srcWidth = cp->mAlloc->mHal.drvState.lod[0].dimX; const size_t stride = cp->mAlloc->mHal.drvState.lod[0].stride; float yf = (info->current.y + 0.5f) * cp->scaleY - 0.5f; int starty = (int) floor(yf - 1); yf = yf - floor(yf); int maxy = srcHeight - 1; int ys0 = rsMax(0, starty + 0); int ys1 = rsMax(0, starty + 1); int ys2 = rsMin(maxy, starty + 2); int ys3 = rsMin(maxy, starty + 3); const uchar *yp0 = pin + stride * ys0; const uchar *yp1 = pin + stride * ys1; const uchar *yp2 = pin + stride * ys2; const uchar *yp3 = pin + stride * ys3; uchar *out = ((uchar *)info->outPtr[0]) + xstart; uint32_t x1 = xstart; uint32_t x2 = xend; #if defined(ARCH_ARM_USE_INTRINSICS) if (gArchUseSIMD && x2 > x1 && cp->scaleX < 4.0f) { float xf = (x1 + 0.5f) * cp->scaleX - 0.5f; long xf16 = rint(xf * 0x10000); uint32_t xinc16 = rint(cp->scaleX * 0x10000); int xoff = (xf16 >> 16) - 1; int xclip = rsMax(0, xoff) - xoff; int len = x2 - x1; int32_t yr[4]; uint64_t osc_ctl = rsdIntrinsicResize_oscctl_K(xinc16); mkYCoeff(yr, yf); xoff += xclip; rsdIntrinsicResizeB1_K( out, len, xf16 & 0xffff, xinc16, yp0 + xoff, yp1 + xoff, yp2 + xoff, yp3 + xoff, xclip, srcWidth - xoff + xclip, osc_ctl, yr); out += len; x1 += len; } #endif while(x1 < x2) { float xf = (x1 + 0.5f) * cp->scaleX - 0.5f; *out = OneBiCubic(yp0, yp1, yp2, yp3, xf, yf, srcWidth); out++; x1++; } } void RsdCpuScriptIntrinsicResize::kernelF4(const RsExpandKernelDriverInfo *info, uint32_t xstart, uint32_t xend, uint32_t outstep) { RsdCpuScriptIntrinsicResize *cp = (RsdCpuScriptIntrinsicResize *)info->usr; if (!cp->mAlloc.get()) { ALOGE("Resize executed without input, skipping"); return; } const uchar *pin = (const uchar *)cp->mAlloc->mHal.drvState.lod[0].mallocPtr; const int srcHeight = cp->mAlloc->mHal.drvState.lod[0].dimY; const int srcWidth = cp->mAlloc->mHal.drvState.lod[0].dimX; const size_t stride = cp->mAlloc->mHal.drvState.lod[0].stride; float yf = (info->current.y + 0.5f) * cp->scaleY - 0.5f; int starty = (int) floor(yf - 1); yf = yf - floor(yf); int maxy = srcHeight - 1; int ys0 = rsMax(0, starty + 0); int ys1 = rsMax(0, starty + 1); int ys2 = rsMin(maxy, starty + 2); int ys3 = rsMin(maxy, starty + 3); const float4 *yp0 = (const float4 *)(pin + stride * ys0); const float4 *yp1 = (const float4 *)(pin + stride * ys1); const float4 *yp2 = (const float4 *)(pin + stride * ys2); const float4 *yp3 = (const float4 *)(pin + stride * ys3); float4 *out = ((float4 *)info->outPtr[0]) + xstart; uint32_t x1 = xstart; uint32_t x2 = xend; while(x1 < x2) { float xf = (x1 + 0.5f) * cp->scaleX - 0.5f; *out = OneBiCubic(yp0, yp1, yp2, yp3, xf, yf, srcWidth); out++; x1++; } } void RsdCpuScriptIntrinsicResize::kernelF2(const RsExpandKernelDriverInfo *info, uint32_t xstart, uint32_t xend, uint32_t outstep) { RsdCpuScriptIntrinsicResize *cp = (RsdCpuScriptIntrinsicResize *)info->usr; if (!cp->mAlloc.get()) { ALOGE("Resize executed without input, skipping"); return; } const uchar *pin = (const uchar *)cp->mAlloc->mHal.drvState.lod[0].mallocPtr; const int srcHeight = cp->mAlloc->mHal.drvState.lod[0].dimY; const int srcWidth = cp->mAlloc->mHal.drvState.lod[0].dimX; const size_t stride = cp->mAlloc->mHal.drvState.lod[0].stride; float yf = (info->current.y + 0.5f) * cp->scaleY - 0.5f; int starty = (int) floor(yf - 1); yf = yf - floor(yf); int maxy = srcHeight - 1; int ys0 = rsMax(0, starty + 0); int ys1 = rsMax(0, starty + 1); int ys2 = rsMin(maxy, starty + 2); int ys3 = rsMin(maxy, starty + 3); const float2 *yp0 = (const float2 *)(pin + stride * ys0); const float2 *yp1 = (const float2 *)(pin + stride * ys1); const float2 *yp2 = (const float2 *)(pin + stride * ys2); const float2 *yp3 = (const float2 *)(pin + stride * ys3); float2 *out = ((float2 *)info->outPtr[0]) + xstart; uint32_t x1 = xstart; uint32_t x2 = xend; while(x1 < x2) { float xf = (x1 + 0.5f) * cp->scaleX - 0.5f; *out = OneBiCubic(yp0, yp1, yp2, yp3, xf, yf, srcWidth); out++; x1++; } } void RsdCpuScriptIntrinsicResize::kernelF1(const RsExpandKernelDriverInfo *info, uint32_t xstart, uint32_t xend, uint32_t outstep) { RsdCpuScriptIntrinsicResize *cp = (RsdCpuScriptIntrinsicResize *)info->usr; if (!cp->mAlloc.get()) { ALOGE("Resize executed without input, skipping"); return; } const uchar *pin = (const uchar *)cp->mAlloc->mHal.drvState.lod[0].mallocPtr; const int srcHeight = cp->mAlloc->mHal.drvState.lod[0].dimY; const int srcWidth = cp->mAlloc->mHal.drvState.lod[0].dimX; const size_t stride = cp->mAlloc->mHal.drvState.lod[0].stride; float yf = (info->current.y + 0.5f) * cp->scaleY - 0.5f; int starty = (int) floor(yf - 1); yf = yf - floor(yf); int maxy = srcHeight - 1; int ys0 = rsMax(0, starty + 0); int ys1 = rsMax(0, starty + 1); int ys2 = rsMin(maxy, starty + 2); int ys3 = rsMin(maxy, starty + 3); const float *yp0 = (const float *)(pin + stride * ys0); const float *yp1 = (const float *)(pin + stride * ys1); const float *yp2 = (const float *)(pin + stride * ys2); const float *yp3 = (const float *)(pin + stride * ys3); float *out = ((float *)info->outPtr[0]) + xstart; uint32_t x1 = xstart; uint32_t x2 = xend; while(x1 < x2) { float xf = (x1 + 0.5f) * cp->scaleX - 0.5f; *out = OneBiCubic(yp0, yp1, yp2, yp3, xf, yf, srcWidth); out++; x1++; } } RsdCpuScriptIntrinsicResize::RsdCpuScriptIntrinsicResize ( RsdCpuReferenceImpl *ctx, const Script *s, const Element *e) : RsdCpuScriptIntrinsic(ctx, s, e, RS_SCRIPT_INTRINSIC_ID_RESIZE) { } RsdCpuScriptIntrinsicResize::~RsdCpuScriptIntrinsicResize() { } void RsdCpuScriptIntrinsicResize::preLaunch(uint32_t slot, const Allocation ** ains, uint32_t inLen, Allocation * aout, const void * usr, uint32_t usrLen, const RsScriptCall *sc) { if (!mAlloc.get()) { ALOGE("Resize executed without input, skipping"); return; } const uint32_t srcHeight = mAlloc->mHal.drvState.lod[0].dimY; const uint32_t srcWidth = mAlloc->mHal.drvState.lod[0].dimX; const size_t stride = mAlloc->mHal.drvState.lod[0].stride; //check the data type to determine F or U. if (mAlloc->getType()->getElement()->getType() == RS_TYPE_UNSIGNED_8) { switch(mAlloc->getType()->getElement()->getVectorSize()) { case 1: mRootPtr = &kernelU1; break; case 2: mRootPtr = &kernelU2; break; case 3: case 4: mRootPtr = &kernelU4; break; } } else { switch(mAlloc->getType()->getElement()->getVectorSize()) { case 1: mRootPtr = &kernelF1; break; case 2: mRootPtr = &kernelF2; break; case 3: case 4: mRootPtr = &kernelF4; break; } } scaleX = (float)srcWidth / aout->mHal.drvState.lod[0].dimX; scaleY = (float)srcHeight / aout->mHal.drvState.lod[0].dimY; } void RsdCpuScriptIntrinsicResize::populateScript(Script *s) { s->mHal.info.exportedVariableCount = 1; } void RsdCpuScriptIntrinsicResize::invokeFreeChildren() { mAlloc.clear(); } RsdCpuScriptImpl * rsdIntrinsic_Resize(RsdCpuReferenceImpl *ctx, const Script *s, const Element *e) { return new RsdCpuScriptIntrinsicResize(ctx, s, e); }