#include "SkBitmapScaler.h" #include "SkBitmapFilter.h" #include "SkRect.h" #include "SkTArray.h" #include "SkErrorInternals.h" #include "SkConvolver.h" // SkResizeFilter ---------------------------------------------------------------- // Encapsulates computation and storage of the filters required for one complete // resize operation. class SkResizeFilter { public: SkResizeFilter(SkBitmapScaler::ResizeMethod method, int srcFullWidth, int srcFullHeight, float destWidth, float destHeight, const SkRect& destSubset, const SkConvolutionProcs& convolveProcs); ~SkResizeFilter() { SkDELETE( fBitmapFilter ); } // Returns the filled filter values. const SkConvolutionFilter1D& xFilter() { return fXFilter; } const SkConvolutionFilter1D& yFilter() { return fYFilter; } private: SkBitmapFilter* fBitmapFilter; // Computes one set of filters either horizontally or vertically. The caller // will specify the "min" and "max" rather than the bottom/top and // right/bottom so that the same code can be re-used in each dimension. // // |srcDependLo| and |srcDependSize| gives the range for the source // depend rectangle (horizontally or vertically at the caller's discretion // -- see above for what this means). // // Likewise, the range of destination values to compute and the scale factor // for the transform is also specified. void computeFilters(int srcSize, float destSubsetLo, float destSubsetSize, float scale, SkConvolutionFilter1D* output, const SkConvolutionProcs& convolveProcs); SkConvolutionFilter1D fXFilter; SkConvolutionFilter1D fYFilter; }; SkResizeFilter::SkResizeFilter(SkBitmapScaler::ResizeMethod method, int srcFullWidth, int srcFullHeight, float destWidth, float destHeight, const SkRect& destSubset, const SkConvolutionProcs& convolveProcs) { // method will only ever refer to an "algorithm method". SkASSERT((SkBitmapScaler::RESIZE_FIRST_ALGORITHM_METHOD <= method) && (method <= SkBitmapScaler::RESIZE_LAST_ALGORITHM_METHOD)); switch(method) { case SkBitmapScaler::RESIZE_BOX: fBitmapFilter = SkNEW(SkBoxFilter); break; case SkBitmapScaler::RESIZE_TRIANGLE: fBitmapFilter = SkNEW(SkTriangleFilter); break; case SkBitmapScaler::RESIZE_MITCHELL: fBitmapFilter = SkNEW_ARGS(SkMitchellFilter, (1.f/3.f, 1.f/3.f)); break; case SkBitmapScaler::RESIZE_HAMMING: fBitmapFilter = SkNEW(SkHammingFilter); break; case SkBitmapScaler::RESIZE_LANCZOS3: fBitmapFilter = SkNEW(SkLanczosFilter); break; default: // NOTREACHED: fBitmapFilter = SkNEW_ARGS(SkMitchellFilter, (1.f/3.f, 1.f/3.f)); break; } float scaleX = destWidth / srcFullWidth; float scaleY = destHeight / srcFullHeight; this->computeFilters(srcFullWidth, destSubset.fLeft, destSubset.width(), scaleX, &fXFilter, convolveProcs); if (srcFullWidth == srcFullHeight && destSubset.fLeft == destSubset.fTop && destSubset.width() == destSubset.height()&& scaleX == scaleY) { fYFilter = fXFilter; } else { this->computeFilters(srcFullHeight, destSubset.fTop, destSubset.height(), scaleY, &fYFilter, convolveProcs); } } // TODO(egouriou): Take advantage of periods in the convolution. // Practical resizing filters are periodic outside of the border area. // For Lanczos, a scaling by a (reduced) factor of p/q (q pixels in the // source become p pixels in the destination) will have a period of p. // A nice consequence is a period of 1 when downscaling by an integral // factor. Downscaling from typical display resolutions is also bound // to produce interesting periods as those are chosen to have multiple // small factors. // Small periods reduce computational load and improve cache usage if // the coefficients can be shared. For periods of 1 we can consider // loading the factors only once outside the borders. void SkResizeFilter::computeFilters(int srcSize, float destSubsetLo, float destSubsetSize, float scale, SkConvolutionFilter1D* output, const SkConvolutionProcs& convolveProcs) { float destSubsetHi = destSubsetLo + destSubsetSize; // [lo, hi) // When we're doing a magnification, the scale will be larger than one. This // means the destination pixels are much smaller than the source pixels, and // that the range covered by the filter won't necessarily cover any source // pixel boundaries. Therefore, we use these clamped values (max of 1) for // some computations. float clampedScale = SkTMin(1.0f, scale); // This is how many source pixels from the center we need to count // to support the filtering function. float srcSupport = fBitmapFilter->width() / clampedScale; // Speed up the divisions below by turning them into multiplies. float invScale = 1.0f / scale; SkTArray filterValues(64); SkTArray fixedFilterValues(64); // Loop over all pixels in the output range. We will generate one set of // filter values for each one. Those values will tell us how to blend the // source pixels to compute the destination pixel. for (int destSubsetI = SkScalarFloorToInt(destSubsetLo); destSubsetI < SkScalarCeilToInt(destSubsetHi); destSubsetI++) { // Reset the arrays. We don't declare them inside so they can re-use the // same malloc-ed buffer. filterValues.reset(); fixedFilterValues.reset(); // This is the pixel in the source directly under the pixel in the dest. // Note that we base computations on the "center" of the pixels. To see // why, observe that the destination pixel at coordinates (0, 0) in a 5.0x // downscale should "cover" the pixels around the pixel with *its center* // at coordinates (2.5, 2.5) in the source, not those around (0, 0). // Hence we need to scale coordinates (0.5, 0.5), not (0, 0). float srcPixel = (static_cast(destSubsetI) + 0.5f) * invScale; // Compute the (inclusive) range of source pixels the filter covers. int srcBegin = SkTMax(0, SkScalarFloorToInt(srcPixel - srcSupport)); int srcEnd = SkTMin(srcSize - 1, SkScalarCeilToInt(srcPixel + srcSupport)); // Compute the unnormalized filter value at each location of the source // it covers. float filterSum = 0.0f; // Sub of the filter values for normalizing. for (int curFilterPixel = srcBegin; curFilterPixel <= srcEnd; curFilterPixel++) { // Distance from the center of the filter, this is the filter coordinate // in source space. We also need to consider the center of the pixel // when comparing distance against 'srcPixel'. In the 5x downscale // example used above the distance from the center of the filter to // the pixel with coordinates (2, 2) should be 0, because its center // is at (2.5, 2.5). float srcFilterDist = ((static_cast(curFilterPixel) + 0.5f) - srcPixel); // Since the filter really exists in dest space, map it there. float destFilterDist = srcFilterDist * clampedScale; // Compute the filter value at that location. float filterValue = fBitmapFilter->evaluate(destFilterDist); filterValues.push_back(filterValue); filterSum += filterValue; } SkASSERT(!filterValues.empty()); // The filter must be normalized so that we don't affect the brightness of // the image. Convert to normalized fixed point. short fixedSum = 0; for (int i = 0; i < filterValues.count(); i++) { short curFixed = output->FloatToFixed(filterValues[i] / filterSum); fixedSum += curFixed; fixedFilterValues.push_back(curFixed); } // The conversion to fixed point will leave some rounding errors, which // we add back in to avoid affecting the brightness of the image. We // arbitrarily add this to the center of the filter array (this won't always // be the center of the filter function since it could get clipped on the // edges, but it doesn't matter enough to worry about that case). short leftovers = output->FloatToFixed(1.0f) - fixedSum; fixedFilterValues[fixedFilterValues.count() / 2] += leftovers; // Now it's ready to go. output->AddFilter(srcBegin, &fixedFilterValues[0], static_cast(fixedFilterValues.count())); } if (convolveProcs.fApplySIMDPadding) { convolveProcs.fApplySIMDPadding( output ); } } static SkBitmapScaler::ResizeMethod ResizeMethodToAlgorithmMethod( SkBitmapScaler::ResizeMethod method) { // Convert any "Quality Method" into an "Algorithm Method" if (method >= SkBitmapScaler::RESIZE_FIRST_ALGORITHM_METHOD && method <= SkBitmapScaler::RESIZE_LAST_ALGORITHM_METHOD) { return method; } // The call to SkBitmapScalerGtv::Resize() above took care of // GPU-acceleration in the cases where it is possible. So now we just // pick the appropriate software method for each resize quality. switch (method) { // Users of RESIZE_GOOD are willing to trade a lot of quality to // get speed, allowing the use of linear resampling to get hardware // acceleration (SRB). Hence any of our "good" software filters // will be acceptable, so we use a triangle. case SkBitmapScaler::RESIZE_GOOD: return SkBitmapScaler::RESIZE_TRIANGLE; // Users of RESIZE_BETTER are willing to trade some quality in order // to improve performance, but are guaranteed not to devolve to a linear // resampling. In visual tests we see that Hamming-1 is not as good as // Lanczos-2, however it is about 40% faster and Lanczos-2 itself is // about 30% faster than Lanczos-3. The use of Hamming-1 has been deemed // an acceptable trade-off between quality and speed. case SkBitmapScaler::RESIZE_BETTER: return SkBitmapScaler::RESIZE_HAMMING; default: #ifdef SK_HIGH_QUALITY_IS_LANCZOS return SkBitmapScaler::RESIZE_LANCZOS3; #else return SkBitmapScaler::RESIZE_MITCHELL; #endif } } // static bool SkBitmapScaler::Resize(SkBitmap* resultPtr, const SkBitmap& source, ResizeMethod method, float destWidth, float destHeight, const SkConvolutionProcs& convolveProcs, SkBitmap::Allocator* allocator) { SkRect destSubset = { 0, 0, destWidth, destHeight }; // Ensure that the ResizeMethod enumeration is sound. SkASSERT(((RESIZE_FIRST_QUALITY_METHOD <= method) && (method <= RESIZE_LAST_QUALITY_METHOD)) || ((RESIZE_FIRST_ALGORITHM_METHOD <= method) && (method <= RESIZE_LAST_ALGORITHM_METHOD))); SkRect dest = { 0, 0, destWidth, destHeight }; if (!dest.contains(destSubset)) { SkErrorInternals::SetError( kInvalidArgument_SkError, "Sorry, the destination bitmap scale subset " "falls outside the full destination bitmap." ); } // If the size of source or destination is 0, i.e. 0x0, 0xN or Nx0, just // return empty. if (source.width() < 1 || source.height() < 1 || destWidth < 1 || destHeight < 1) { // todo: seems like we could handle negative dstWidth/Height, since that // is just a negative scale (flip) return false; } method = ResizeMethodToAlgorithmMethod(method); // Check that we deal with an "algorithm methods" from this point onward. SkASSERT((SkBitmapScaler::RESIZE_FIRST_ALGORITHM_METHOD <= method) && (method <= SkBitmapScaler::RESIZE_LAST_ALGORITHM_METHOD)); SkAutoLockPixels locker(source); if (!source.readyToDraw() || source.colorType() != kN32_SkColorType) { return false; } SkResizeFilter filter(method, source.width(), source.height(), destWidth, destHeight, destSubset, convolveProcs); // Get a source bitmap encompassing this touched area. We construct the // offsets and row strides such that it looks like a new bitmap, while // referring to the old data. const unsigned char* sourceSubset = reinterpret_cast(source.getPixels()); // Convolve into the result. SkBitmap result; result.setInfo(SkImageInfo::MakeN32(SkScalarCeilToInt(destSubset.width()), SkScalarCeilToInt(destSubset.height()), source.alphaType())); result.allocPixels(allocator, NULL); if (!result.readyToDraw()) { return false; } BGRAConvolve2D(sourceSubset, static_cast(source.rowBytes()), !source.isOpaque(), filter.xFilter(), filter.yFilter(), static_cast(result.rowBytes()), static_cast(result.getPixels()), convolveProcs, true); *resultPtr = result; resultPtr->lockPixels(); SkASSERT(NULL != resultPtr->getPixels()); return true; }