/**************************************************************************** ** ** Copyright (C) 2016 The Qt Company Ltd. ** Contact: https://www.qt.io/licensing/ ** ** This file is part of the QtQuick module of the Qt Toolkit. ** ** $QT_BEGIN_LICENSE:LGPL$ ** Commercial License Usage ** Licensees holding valid commercial Qt licenses may use this file in ** accordance with the commercial license agreement provided with the ** Software or, alternatively, in accordance with the terms contained in ** a written agreement between you and The Qt Company. For licensing terms ** and conditions see https://www.qt.io/terms-conditions. For further ** information use the contact form at https://www.qt.io/contact-us. ** ** GNU Lesser General Public License Usage ** Alternatively, this file may be used under the terms of the GNU Lesser ** General Public License version 3 as published by the Free Software ** Foundation and appearing in the file LICENSE.LGPL3 included in the ** packaging of this file. Please review the following information to ** ensure the GNU Lesser General Public License version 3 requirements ** will be met: https://www.gnu.org/licenses/lgpl-3.0.html. ** ** GNU General Public License Usage ** Alternatively, this file may be used under the terms of the GNU ** General Public License version 2.0 or (at your option) the GNU General ** Public license version 3 or any later version approved by the KDE Free ** Qt Foundation. The licenses are as published by the Free Software ** Foundation and appearing in the file LICENSE.GPL2 and LICENSE.GPL3 ** included in the packaging of this file. Please review the following ** information to ensure the GNU General Public License requirements will ** be met: https://www.gnu.org/licenses/gpl-2.0.html and ** https://www.gnu.org/licenses/gpl-3.0.html. ** ** $QT_END_LICENSE$ ** ****************************************************************************/ #include "qsgbasicinternalimagenode_p.h" #include #include QT_BEGIN_NAMESPACE namespace { struct SmoothVertex { float x, y, u, v; float dx, dy, du, dv; }; const QSGGeometry::AttributeSet &smoothAttributeSet() { static QSGGeometry::Attribute data[] = { QSGGeometry::Attribute::createWithAttributeType(0, 2, QSGGeometry::FloatType, QSGGeometry::PositionAttribute), QSGGeometry::Attribute::createWithAttributeType(1, 2, QSGGeometry::FloatType, QSGGeometry::TexCoordAttribute), QSGGeometry::Attribute::createWithAttributeType(2, 2, QSGGeometry::FloatType, QSGGeometry::TexCoord1Attribute), QSGGeometry::Attribute::createWithAttributeType(3, 2, QSGGeometry::FloatType, QSGGeometry::TexCoord2Attribute) }; static QSGGeometry::AttributeSet attrs = { 4, sizeof(SmoothVertex), data }; return attrs; } } QSGBasicInternalImageNode::QSGBasicInternalImageNode() : m_innerSourceRect(0, 0, 1, 1) , m_subSourceRect(0, 0, 1, 1) , m_antialiasing(false) , m_mirror(false) , m_dirtyGeometry(false) , m_geometry(QSGGeometry::defaultAttributes_TexturedPoint2D(), 4) , m_dynamicTexture(nullptr) { setGeometry(&m_geometry); #ifdef QSG_RUNTIME_DESCRIPTION qsgnode_set_description(this, QLatin1String("internalimage")); #endif } void QSGBasicInternalImageNode::setTargetRect(const QRectF &rect) { if (rect == m_targetRect) return; m_targetRect = rect; m_dirtyGeometry = true; } void QSGBasicInternalImageNode::setInnerTargetRect(const QRectF &rect) { if (rect == m_innerTargetRect) return; m_innerTargetRect = rect; m_dirtyGeometry = true; } void QSGBasicInternalImageNode::setInnerSourceRect(const QRectF &rect) { if (rect == m_innerSourceRect) return; m_innerSourceRect = rect; m_dirtyGeometry = true; } void QSGBasicInternalImageNode::setSubSourceRect(const QRectF &rect) { if (rect == m_subSourceRect) return; m_subSourceRect = rect; m_dirtyGeometry = true; } void QSGBasicInternalImageNode::setTexture(QSGTexture *texture) { Q_ASSERT(texture); setMaterialTexture(texture); updateMaterialBlending(); markDirty(DirtyMaterial); // Because the texture can be a different part of the atlas, we need to update it... m_dirtyGeometry = true; } void QSGBasicInternalImageNode::setAntialiasing(bool antialiasing) { if (antialiasing == m_antialiasing) return; m_antialiasing = antialiasing; if (m_antialiasing) { setGeometry(new QSGGeometry(smoothAttributeSet(), 0)); setFlag(OwnsGeometry, true); } else { setGeometry(&m_geometry); setFlag(OwnsGeometry, false); } updateMaterialAntialiasing(); m_dirtyGeometry = true; } void QSGBasicInternalImageNode::setMirror(bool mirror) { if (mirror == m_mirror) return; m_mirror = mirror; m_dirtyGeometry = true; } void QSGBasicInternalImageNode::update() { if (m_dirtyGeometry) updateGeometry(); } void QSGBasicInternalImageNode::preprocess() { bool doDirty = false; QSGDynamicTexture *t = qobject_cast(materialTexture()); if (t) { doDirty = t->updateTexture(); if (doDirty) { // The geometry may need updating. This is expensive however, so do // it only when something relevant has changed. if (t != m_dynamicTexture || t->textureSize() != m_dynamicTextureSize || t->normalizedTextureSubRect() != m_dynamicTextureSubRect) { updateGeometry(); m_dynamicTextureSize = t->textureSize(); m_dynamicTextureSubRect = t->normalizedTextureSubRect(); } } } m_dynamicTexture = t; if (updateMaterialBlending()) doDirty = true; if (doDirty) markDirty(DirtyMaterial); } namespace { struct X { float x, tx; }; struct Y { float y, ty; }; } static inline void appendQuad(quint16 **indices, quint16 topLeft, quint16 topRight, quint16 bottomLeft, quint16 bottomRight) { *(*indices)++ = topLeft; *(*indices)++ = bottomLeft; *(*indices)++ = bottomRight; *(*indices)++ = bottomRight; *(*indices)++ = topRight; *(*indices)++ = topLeft; } QSGGeometry *QSGBasicInternalImageNode::updateGeometry(const QRectF &targetRect, const QRectF &innerTargetRect, const QRectF &sourceRect, const QRectF &innerSourceRect, const QRectF &subSourceRect, QSGGeometry *geometry, bool mirror, bool antialiasing) { int floorLeft = qFloor(subSourceRect.left()); int ceilRight = qCeil(subSourceRect.right()); int floorTop = qFloor(subSourceRect.top()); int ceilBottom = qCeil(subSourceRect.bottom()); int hTiles = ceilRight - floorLeft; int vTiles = ceilBottom - floorTop; int hCells = hTiles; int vCells = vTiles; if (innerTargetRect.width() == 0) hCells = 0; if (innerTargetRect.left() != targetRect.left()) ++hCells; if (innerTargetRect.right() != targetRect.right()) ++hCells; if (innerTargetRect.height() == 0) vCells = 0; if (innerTargetRect.top() != targetRect.top()) ++vCells; if (innerTargetRect.bottom() != targetRect.bottom()) ++vCells; QVarLengthArray xData(2 * hCells); QVarLengthArray yData(2 * vCells); X *xs = xData.data(); Y *ys = yData.data(); if (innerTargetRect.left() != targetRect.left()) { xs[0].x = targetRect.left(); xs[0].tx = sourceRect.left(); xs[1].x = innerTargetRect.left(); xs[1].tx = innerSourceRect.left(); xs += 2; } if (innerTargetRect.width() != 0) { xs[0].x = innerTargetRect.left(); xs[0].tx = innerSourceRect.x() + (subSourceRect.left() - floorLeft) * innerSourceRect.width(); ++xs; float b = innerTargetRect.width() / subSourceRect.width(); float a = innerTargetRect.x() - subSourceRect.x() * b; for (int i = floorLeft + 1; i <= ceilRight - 1; ++i) { xs[0].x = xs[1].x = a + b * i; xs[0].tx = innerSourceRect.right(); xs[1].tx = innerSourceRect.left(); xs += 2; } xs[0].x = innerTargetRect.right(); xs[0].tx = innerSourceRect.x() + (subSourceRect.right() - ceilRight + 1) * innerSourceRect.width(); ++xs; } if (innerTargetRect.right() != targetRect.right()) { xs[0].x = innerTargetRect.right(); xs[0].tx = innerSourceRect.right(); xs[1].x = targetRect.right(); xs[1].tx = sourceRect.right(); xs += 2; } Q_ASSERT(xs == xData.data() + xData.size()); if (mirror) { float leftPlusRight = targetRect.left() + targetRect.right(); int count = xData.size(); xs = xData.data(); for (int i = 0; i < count >> 1; ++i) qSwap(xs[i], xs[count - 1 - i]); for (int i = 0; i < count; ++i) xs[i].x = leftPlusRight - xs[i].x; } if (innerTargetRect.top() != targetRect.top()) { ys[0].y = targetRect.top(); ys[0].ty = sourceRect.top(); ys[1].y = innerTargetRect.top(); ys[1].ty = innerSourceRect.top(); ys += 2; } if (innerTargetRect.height() != 0) { ys[0].y = innerTargetRect.top(); ys[0].ty = innerSourceRect.y() + (subSourceRect.top() - floorTop) * innerSourceRect.height(); ++ys; float b = innerTargetRect.height() / subSourceRect.height(); float a = innerTargetRect.y() - subSourceRect.y() * b; for (int i = floorTop + 1; i <= ceilBottom - 1; ++i) { ys[0].y = ys[1].y = a + b * i; ys[0].ty = innerSourceRect.bottom(); ys[1].ty = innerSourceRect.top(); ys += 2; } ys[0].y = innerTargetRect.bottom(); ys[0].ty = innerSourceRect.y() + (subSourceRect.bottom() - ceilBottom + 1) * innerSourceRect.height(); ++ys; } if (innerTargetRect.bottom() != targetRect.bottom()) { ys[0].y = innerTargetRect.bottom(); ys[0].ty = innerSourceRect.bottom(); ys[1].y = targetRect.bottom(); ys[1].ty = sourceRect.bottom(); ys += 2; } Q_ASSERT(ys == yData.data() + yData.size()); if (antialiasing) { QSGGeometry *g = geometry; Q_ASSERT(g); g->allocate(hCells * vCells * 4 + (hCells + vCells - 1) * 4, hCells * vCells * 6 + (hCells + vCells) * 12); g->setDrawingMode(QSGGeometry::DrawTriangles); SmoothVertex *vertices = reinterpret_cast(g->vertexData()); memset(vertices, 0, g->vertexCount() * g->sizeOfVertex()); quint16 *indices = g->indexDataAsUShort(); // The deltas are how much the fuzziness can reach into the image. // Only the border vertices are moved by the vertex shader, so the fuzziness // can't reach further into the image than the closest interior vertices. float leftDx = xData.at(1).x - xData.at(0).x; float rightDx = xData.at(xData.size() - 1).x - xData.at(xData.size() - 2).x; float topDy = yData.at(1).y - yData.at(0).y; float bottomDy = yData.at(yData.size() - 1).y - yData.at(yData.size() - 2).y; float leftDu = xData.at(1).tx - xData.at(0).tx; float rightDu = xData.at(xData.size() - 1).tx - xData.at(xData.size() - 2).tx; float topDv = yData.at(1).ty - yData.at(0).ty; float bottomDv = yData.at(yData.size() - 1).ty - yData.at(yData.size() - 2).ty; if (hCells == 1) { leftDx = rightDx *= 0.5f; leftDu = rightDu *= 0.5f; } if (vCells == 1) { topDy = bottomDy *= 0.5f; topDv = bottomDv *= 0.5f; } // This delta is how much the fuzziness can reach out from the image. float delta = float(qAbs(targetRect.width()) < qAbs(targetRect.height()) ? targetRect.width() : targetRect.height()) * 0.5f; quint16 index = 0; ys = yData.data(); for (int j = 0; j < vCells; ++j, ys += 2) { xs = xData.data(); bool isTop = j == 0; bool isBottom = j == vCells - 1; for (int i = 0; i < hCells; ++i, xs += 2) { bool isLeft = i == 0; bool isRight = i == hCells - 1; SmoothVertex *v = vertices + index; quint16 topLeft = index; for (int k = (isTop || isLeft ? 2 : 1); k--; ++v, ++index) { v->x = xs[0].x; v->u = xs[0].tx; v->y = ys[0].y; v->v = ys[0].ty; } quint16 topRight = index; for (int k = (isTop || isRight ? 2 : 1); k--; ++v, ++index) { v->x = xs[1].x; v->u = xs[1].tx; v->y = ys[0].y; v->v = ys[0].ty; } quint16 bottomLeft = index; for (int k = (isBottom || isLeft ? 2 : 1); k--; ++v, ++index) { v->x = xs[0].x; v->u = xs[0].tx; v->y = ys[1].y; v->v = ys[1].ty; } quint16 bottomRight = index; for (int k = (isBottom || isRight ? 2 : 1); k--; ++v, ++index) { v->x = xs[1].x; v->u = xs[1].tx; v->y = ys[1].y; v->v = ys[1].ty; } appendQuad(&indices, topLeft, topRight, bottomLeft, bottomRight); if (isTop) { vertices[topLeft].dy = vertices[topRight].dy = topDy; vertices[topLeft].dv = vertices[topRight].dv = topDv; vertices[topLeft + 1].dy = vertices[topRight + 1].dy = -delta; appendQuad(&indices, topLeft + 1, topRight + 1, topLeft, topRight); } if (isBottom) { vertices[bottomLeft].dy = vertices[bottomRight].dy = -bottomDy; vertices[bottomLeft].dv = vertices[bottomRight].dv = -bottomDv; vertices[bottomLeft + 1].dy = vertices[bottomRight + 1].dy = delta; appendQuad(&indices, bottomLeft, bottomRight, bottomLeft + 1, bottomRight + 1); } if (isLeft) { vertices[topLeft].dx = vertices[bottomLeft].dx = leftDx; vertices[topLeft].du = vertices[bottomLeft].du = leftDu; vertices[topLeft + 1].dx = vertices[bottomLeft + 1].dx = -delta; appendQuad(&indices, topLeft + 1, topLeft, bottomLeft + 1, bottomLeft); } if (isRight) { vertices[topRight].dx = vertices[bottomRight].dx = -rightDx; vertices[topRight].du = vertices[bottomRight].du = -rightDu; vertices[topRight + 1].dx = vertices[bottomRight + 1].dx = delta; appendQuad(&indices, topRight, topRight + 1, bottomRight, bottomRight + 1); } } } Q_ASSERT(index == g->vertexCount()); Q_ASSERT(indices - g->indexCount() == g->indexData()); } else { if (!geometry) { geometry = new QSGGeometry(QSGGeometry::defaultAttributes_TexturedPoint2D(), hCells * vCells * 4, hCells * vCells * 6, QSGGeometry::UnsignedShortType); } else { geometry->allocate(hCells * vCells * 4, hCells * vCells * 6); } geometry->setDrawingMode(QSGGeometry::DrawTriangles); QSGGeometry::TexturedPoint2D *vertices = geometry->vertexDataAsTexturedPoint2D(); ys = yData.data(); for (int j = 0; j < vCells; ++j, ys += 2) { xs = xData.data(); for (int i = 0; i < hCells; ++i, xs += 2) { vertices[0].x = vertices[2].x = xs[0].x; vertices[0].tx = vertices[2].tx = xs[0].tx; vertices[1].x = vertices[3].x = xs[1].x; vertices[1].tx = vertices[3].tx = xs[1].tx; vertices[0].y = vertices[1].y = ys[0].y; vertices[0].ty = vertices[1].ty = ys[0].ty; vertices[2].y = vertices[3].y = ys[1].y; vertices[2].ty = vertices[3].ty = ys[1].ty; vertices += 4; } } quint16 *indices = geometry->indexDataAsUShort(); for (int i = 0; i < 4 * vCells * hCells; i += 4) appendQuad(&indices, i, i + 1, i + 2, i + 3); } return geometry; } void QSGBasicInternalImageNode::updateGeometry() { Q_ASSERT(!m_targetRect.isEmpty()); const QSGTexture *t = materialTexture(); if (!t) { QSGGeometry *g = geometry(); g->allocate(4); g->setDrawingMode(QSGGeometry::DrawTriangleStrip); memset(g->vertexData(), 0, g->sizeOfVertex() * 4); } else { QRectF sourceRect = t->normalizedTextureSubRect(); QRectF innerSourceRect(sourceRect.x() + m_innerSourceRect.x() * sourceRect.width(), sourceRect.y() + m_innerSourceRect.y() * sourceRect.height(), m_innerSourceRect.width() * sourceRect.width(), m_innerSourceRect.height() * sourceRect.height()); bool hasMargins = m_targetRect != m_innerTargetRect; int floorLeft = qFloor(m_subSourceRect.left()); int ceilRight = qCeil(m_subSourceRect.right()); int floorTop = qFloor(m_subSourceRect.top()); int ceilBottom = qCeil(m_subSourceRect.bottom()); int hTiles = ceilRight - floorLeft; int vTiles = ceilBottom - floorTop; bool hasTiles = hTiles != 1 || vTiles != 1; bool fullTexture = innerSourceRect == QRectF(0, 0, 1, 1); // An image can be rendered as a single quad if: // - There are no margins, and either: // - the image isn't repeated // - the source rectangle fills the entire texture so that texture wrapping can be used, // and NPOT is supported if (!hasMargins && (!hasTiles || (fullTexture && supportsWrap(t->textureSize())))) { QRectF sr; if (!fullTexture) { sr = QRectF(innerSourceRect.x() + (m_subSourceRect.left() - floorLeft) * innerSourceRect.width(), innerSourceRect.y() + (m_subSourceRect.top() - floorTop) * innerSourceRect.height(), m_subSourceRect.width() * innerSourceRect.width(), m_subSourceRect.height() * innerSourceRect.height()); } else { sr = QRectF(m_subSourceRect.left() - floorLeft, m_subSourceRect.top() - floorTop, m_subSourceRect.width(), m_subSourceRect.height()); } if (m_mirror) { qreal oldLeft = sr.left(); sr.setLeft(sr.right()); sr.setRight(oldLeft); } if (m_antialiasing) { QSGGeometry *g = geometry(); Q_ASSERT(g != &m_geometry); g->allocate(8, 14); g->setDrawingMode(QSGGeometry::DrawTriangleStrip); SmoothVertex *vertices = reinterpret_cast(g->vertexData()); float delta = float(qAbs(m_targetRect.width()) < qAbs(m_targetRect.height()) ? m_targetRect.width() : m_targetRect.height()) * 0.5f; float sx = float(sr.width() / m_targetRect.width()); float sy = float(sr.height() / m_targetRect.height()); for (int d = -1; d <= 1; d += 2) { for (int j = 0; j < 2; ++j) { for (int i = 0; i < 2; ++i, ++vertices) { vertices->x = m_targetRect.x() + i * m_targetRect.width(); vertices->y = m_targetRect.y() + j * m_targetRect.height(); vertices->u = sr.x() + i * sr.width(); vertices->v = sr.y() + j * sr.height(); vertices->dx = (i == 0 ? delta : -delta) * d; vertices->dy = (j == 0 ? delta : -delta) * d; vertices->du = (d < 0 ? 0 : vertices->dx * sx); vertices->dv = (d < 0 ? 0 : vertices->dy * sy); } } } Q_ASSERT(vertices - g->vertexCount() == g->vertexData()); static const quint16 indices[] = { 0, 4, 1, 5, 3, 7, 2, 6, 0, 4, 4, 6, 5, 7 }; Q_ASSERT(g->sizeOfIndex() * g->indexCount() == sizeof(indices)); memcpy(g->indexDataAsUShort(), indices, sizeof(indices)); } else { m_geometry.allocate(4); m_geometry.setDrawingMode(QSGGeometry::DrawTriangleStrip); QSGGeometry::updateTexturedRectGeometry(&m_geometry, m_targetRect, sr); } } else { QSGGeometry *g = m_antialiasing ? geometry() : &m_geometry; updateGeometry(m_targetRect, m_innerTargetRect, sourceRect, innerSourceRect, m_subSourceRect, g, m_mirror, m_antialiasing); } } markDirty(DirtyGeometry); m_dirtyGeometry = false; } QT_END_NAMESPACE