/* -*- Mode: C++; tab-width: 8; indent-tabs-mode: nil; c-basic-offset: 2 -*- */ /* vim: set ts=8 sts=2 et sw=2 tw=80: */ /* This Source Code Form is subject to the terms of the Mozilla Public * License, v. 2.0. If a copy of the MPL was not distributed with this * file, You can obtain one at http://mozilla.org/MPL/2.0/. */ #include "DashedCornerFinder.h" #include #include "BorderCache.h" #include "BorderConsts.h" #include "nsTHashMap.h" namespace mozilla { using namespace gfx; struct BestDashLength { typedef mozilla::gfx::Float Float; Float dashLength; size_t count; BestDashLength() : dashLength(0.0f), count(0) {} BestDashLength(Float aDashLength, size_t aCount) : dashLength(aDashLength), count(aCount) {} }; static const size_t DashedCornerCacheSize = 256; nsTHashMap DashedCornerCache; DashedCornerFinder::DashedCornerFinder(const Bezier& aOuterBezier, const Bezier& aInnerBezier, Float aBorderWidthH, Float aBorderWidthV, const Size& aCornerDim) : mOuterBezier(aOuterBezier), mInnerBezier(aInnerBezier), mLastOuterP(aOuterBezier.mPoints[0]), mLastInnerP(aInnerBezier.mPoints[0]), mLastOuterT(0.0f), mLastInnerT(0.0f), mBestDashLength(DOT_LENGTH * DASH_LENGTH), mHasZeroBorderWidth(false), mHasMore(true), mMaxCount(aCornerDim.width + aCornerDim.height), mType(OTHER), mI(0), mCount(0) { NS_ASSERTION(aBorderWidthH > 0.0f || aBorderWidthV > 0.0f, "At least one side should have non-zero width."); DetermineType(aBorderWidthH, aBorderWidthV); Reset(); } void DashedCornerFinder::DetermineType(Float aBorderWidthH, Float aBorderWidthV) { if (aBorderWidthH < aBorderWidthV) { // Always draw from wider side to thinner side. std::swap(mInnerBezier.mPoints[0], mInnerBezier.mPoints[3]); std::swap(mInnerBezier.mPoints[1], mInnerBezier.mPoints[2]); std::swap(mOuterBezier.mPoints[0], mOuterBezier.mPoints[3]); std::swap(mOuterBezier.mPoints[1], mOuterBezier.mPoints[2]); mLastOuterP = mOuterBezier.mPoints[0]; mLastInnerP = mInnerBezier.mPoints[0]; } // See the comment at mType declaration for each condition. Float borderRadiusA = fabs(mOuterBezier.mPoints[0].x - mOuterBezier.mPoints[3].x); Float borderRadiusB = fabs(mOuterBezier.mPoints[0].y - mOuterBezier.mPoints[3].y); if (aBorderWidthH == aBorderWidthV && borderRadiusA == borderRadiusB && borderRadiusA > aBorderWidthH * 2.0f) { Float curveHeight = borderRadiusA - aBorderWidthH / 2.0; mType = PERFECT; Float borderLength = M_PI * curveHeight / 2.0f; Float dashWidth = aBorderWidthH * DOT_LENGTH * DASH_LENGTH; size_t count = ceil(borderLength / dashWidth); if (count % 2) { count++; } mCount = count / 2 + 1; mBestDashLength = borderLength / (aBorderWidthH * count); } Float minBorderWidth = std::min(aBorderWidthH, aBorderWidthV); if (minBorderWidth == 0.0f) { mHasZeroBorderWidth = true; } if (mType == OTHER && !mHasZeroBorderWidth) { Float minBorderRadius = std::min(borderRadiusA, borderRadiusB); Float maxBorderRadius = std::max(borderRadiusA, borderRadiusB); Float maxBorderWidth = std::max(aBorderWidthH, aBorderWidthV); FindBestDashLength(minBorderWidth, maxBorderWidth, minBorderRadius, maxBorderRadius); } } bool DashedCornerFinder::HasMore(void) const { if (mHasZeroBorderWidth) { return mI < mMaxCount && mHasMore; } return mI < mCount; } DashedCornerFinder::Result DashedCornerFinder::Next(void) { Float lastOuterT, lastInnerT, outerT, innerT; if (mI == 0) { lastOuterT = 0.0f; lastInnerT = 0.0f; } else { if (mType == PERFECT) { lastOuterT = lastInnerT = (mI * 2.0f - 0.5f) / ((mCount - 1) * 2.0f); } else { Float last2OuterT = mLastOuterT; Float last2InnerT = mLastInnerT; (void)FindNext(mBestDashLength); // // mLastOuterT lastOuterT // | | // v v // +---+---+---+---+ <- last2OuterT // | |###|###| | // | |###|###| | // | |###|###| | // +---+---+---+---+ <- last2InnerT // ^ ^ // | | // mLastInnerT lastInnerT lastOuterT = (mLastOuterT + last2OuterT) / 2.0f; lastInnerT = (mLastInnerT + last2InnerT) / 2.0f; } } if ((!mHasZeroBorderWidth && mI == mCount - 1) || (mHasZeroBorderWidth && !mHasMore)) { outerT = 1.0f; innerT = 1.0f; } else { if (mType == PERFECT) { outerT = innerT = (mI * 2.0f + 0.5f) / ((mCount - 1) * 2.0f); } else { Float last2OuterT = mLastOuterT; Float last2InnerT = mLastInnerT; (void)FindNext(mBestDashLength); // // outerT last2OuterT // | | // v v // mLastOuterT -> +---+---+---+---+ // | |###|###| | // | |###|###| | // | |###|###| | // mLastInnerT -> +---+---+---+---+ // ^ ^ // | | // innerT last2InnerT outerT = (mLastOuterT + last2OuterT) / 2.0f; innerT = (mLastInnerT + last2InnerT) / 2.0f; } } mI++; Bezier outerSectionBezier; Bezier innerSectionBezier; GetSubBezier(&outerSectionBezier, mOuterBezier, lastOuterT, outerT); GetSubBezier(&innerSectionBezier, mInnerBezier, lastInnerT, innerT); return DashedCornerFinder::Result(outerSectionBezier, innerSectionBezier); } void DashedCornerFinder::Reset(void) { mLastOuterP = mOuterBezier.mPoints[0]; mLastInnerP = mInnerBezier.mPoints[0]; mLastOuterT = 0.0f; mLastInnerT = 0.0f; mHasMore = true; } Float DashedCornerFinder::FindNext(Float dashLength) { Float upper = 1.0f; Float lower = mLastOuterT; Point OuterP, InnerP; // Start from upper bound to check if this is the last segment. Float outerT = upper; Float innerT; Float W = 0.0f; Float L = 0.0f; const Float LENGTH_MARGIN = 0.1f; for (size_t i = 0; i < MAX_LOOP; i++) { OuterP = GetBezierPoint(mOuterBezier, outerT); InnerP = FindBezierNearestPoint(mInnerBezier, OuterP, outerT, &innerT); // Calculate approximate dash length. // // W = (W1 + W2) / 2 // L = (OuterL + InnerL) / 2 // dashLength = L / W // // ____----+----____ // OuterP ___--- | ---___ mLastOuterP // +--- | ---+ // | | | // | | | // | W | W1 | // | | | // W2 | | | // | | ______------+ // | ____+---- mLastInnerP // | ___--- // | __--- // +-- // InnerP // OuterL // ____---------____ // OuterP ___--- ---___ mLastOuterP // +--- ---+ // | L | // | ___----------______ | // | __--- -----+ // | __-- | // +-- | // | InnerL ______------+ // | ____----- mLastInnerP // | ___--- // | __--- // +-- // InnerP Float W1 = (mLastOuterP - mLastInnerP).Length(); Float W2 = (OuterP - InnerP).Length(); Float OuterL = GetBezierLength(mOuterBezier, mLastOuterT, outerT); Float InnerL = GetBezierLength(mInnerBezier, mLastInnerT, innerT); W = (W1 + W2) / 2.0f; L = (OuterL + InnerL) / 2.0f; if (L > W * dashLength + LENGTH_MARGIN) { if (i > 0) { upper = outerT; } } else if (L < W * dashLength - LENGTH_MARGIN) { if (i == 0) { // This is the last segment with shorter dashLength. mHasMore = false; break; } lower = outerT; } else { break; } outerT = (upper + lower) / 2.0f; } mLastOuterP = OuterP; mLastInnerP = InnerP; mLastOuterT = outerT; mLastInnerT = innerT; if (W == 0.0f) { return 1.0f; } return L / W; } void DashedCornerFinder::FindBestDashLength(Float aMinBorderWidth, Float aMaxBorderWidth, Float aMinBorderRadius, Float aMaxBorderRadius) { // If dashLength is not calculateable, find it with binary search, // such that there exists i that OuterP_i == OuterP_n and // InnerP_i == InnerP_n with given dashLength. FourFloats key(aMinBorderWidth, aMaxBorderWidth, aMinBorderRadius, aMaxBorderRadius); BestDashLength best; if (DashedCornerCache.Get(key, &best)) { mCount = best.count; mBestDashLength = best.dashLength; return; } Float lower = 1.0f; Float upper = DOT_LENGTH * DASH_LENGTH; Float dashLength = upper; size_t targetCount = 0; const Float LENGTH_MARGIN = 0.1f; for (size_t j = 0; j < MAX_LOOP; j++) { size_t count; Float actualDashLength; if (!GetCountAndLastDashLength(dashLength, &count, &actualDashLength)) { if (j == 0) { mCount = mMaxCount; break; } } if (j == 0) { if (count == 1) { // If only 1 segment fits, fill entire region // // count = 1 // mCount = 1 // | 1 | // +---+---+ // |###|###| // |###|###| // |###|###| // +---+---+ // 1 mCount = 1; break; } // targetCount should be 2n. // // targetCount = 2 // mCount = 2 // | 1 | 2 | // +---+---+---+---+ // |###| | |###| // |###| | |###| // |###| | |###| // +---+---+---+---+ // 1 2 // // targetCount = 6 // mCount = 4 // | 1 | 2 | 3 | 4 | 5 | 6 | // +---+---+---+---+---+---+---+---+---+---+---+---+ // |###| | |###|###| | |###|###| | |###| // |###| | |###|###| | |###|###| | |###| // |###| | |###|###| | |###|###| | |###| // +---+---+---+---+---+---+---+---+---+---+---+---+ // 1 2 3 4 if (count % 2) { targetCount = count + 1; } else { targetCount = count; } mCount = targetCount / 2 + 1; } if (count == targetCount) { mBestDashLength = dashLength; // actualDashLength won't be greater than dashLength. if (actualDashLength > dashLength - LENGTH_MARGIN) { break; } // We started from upper bound, no need to update range when j == 0. if (j > 0) { upper = dashLength; } } else { // |j == 0 && count != targetCount| means that |targetCount = count + 1|, // and we started from upper bound, no need to update range when j == 0. if (j > 0) { if (count > targetCount) { lower = dashLength; } else { upper = dashLength; } } } dashLength = (upper + lower) / 2.0f; } if (DashedCornerCache.Count() > DashedCornerCacheSize) { DashedCornerCache.Clear(); } DashedCornerCache.InsertOrUpdate(key, BestDashLength(mBestDashLength, mCount)); } bool DashedCornerFinder::GetCountAndLastDashLength(Float aDashLength, size_t* aCount, Float* aActualDashLength) { // Return the number of segments and the last segment's dashLength for // the given dashLength. Reset(); for (size_t i = 0; i < mMaxCount; i++) { Float actualDashLength = FindNext(aDashLength); if (mLastOuterT >= 1.0f) { *aCount = i + 1; *aActualDashLength = actualDashLength; return true; } } return false; } } // namespace mozilla