/* * The ManaPlus Client * Copyright (C) 2007-2009 The Mana World Development Team * Copyright (C) 2009-2010 The Mana Developers * Copyright (C) 2011 The ManaPlus Developers * * This file is part of The ManaPlus Client. * * This program is free software; you can redistribute it and/or modify * it under the terms of the GNU General Public License as published by * the Free Software Foundation; either version 2 of the License, or * any later version. * * This program is distributed in the hope that it will be useful, * but WITHOUT ANY WARRANTY; without even the implied warranty of * MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the * GNU General Public License for more details. * * You should have received a copy of the GNU General Public License * along with this program. If not, see <http://www.gnu.org/licenses/>. */ #include "gui/widgets/layout.h" #include "log.h" #include <cassert> #include "debug.h" ContainerPlacer ContainerPlacer::at(int x, int y) { return ContainerPlacer(mContainer, &mCell->at(x, y)); } LayoutCell &ContainerPlacer::operator() (int x, int y, gcn::Widget *wg, int w, int h) { mContainer->add(wg); return mCell->place(wg, x, y, w, h); } LayoutCell::~LayoutCell() { if (mType == ARRAY) { delete mArray; mArray = 0; } } LayoutArray &LayoutCell::getArray() { assert(mType != WIDGET); if (mType == ARRAY) return *mArray; mArray = new LayoutArray; mType = ARRAY; mExtent[0] = 1; mExtent[1] = 1; mHPadding = 0; mVPadding = 0; mAlign[0] = FILL; mAlign[1] = FILL; return *mArray; } void LayoutCell::reflow(int nx, int ny, int nw, int nh) { assert(mType != NONE); nx += mHPadding; ny += mVPadding; nw -= 2 * mHPadding; nh -= 2 * mVPadding; if (mType == ARRAY) mArray->reflow(nx, ny, nw, nh); else mWidget->setDimension(gcn::Rectangle(nx, ny, nw, nh)); } void LayoutCell::computeSizes() { assert(mType == ARRAY); std::vector< std::vector< LayoutCell * > >::iterator i = mArray->mCells.begin(); while (i != mArray->mCells.end()) { std::vector< LayoutCell * >::iterator j = i->begin(); while (j != i->end()) { LayoutCell *cell = *j; if (cell && cell->mType == ARRAY) cell->computeSizes(); ++j; } ++i; } mSize[0] = mArray->getSize(0); mSize[1] = mArray->getSize(1); } LayoutArray::LayoutArray(): mSpacing(4) { } LayoutArray::~LayoutArray() { std::vector< std::vector< LayoutCell * > >::iterator i = mCells.begin(); while (i != mCells.end()) { std::vector< LayoutCell * >::iterator j = i->begin(); while (j != i->end()) { delete *j; ++j; } ++i; } } LayoutCell &LayoutArray::at(int x, int y, int w, int h) { resizeGrid(x + w, y + h); LayoutCell *&cell = mCells[y][x]; if (!cell) cell = new LayoutCell; return *cell; } void LayoutArray::resizeGrid(int w, int h) { bool extW = w && w > static_cast<int>(mSizes[0].size()), extH = h && h > static_cast<int>(mSizes[1].size()); if (!extW && !extH) return; if (extH) { mSizes[1].resize(h, Layout::AUTO_DEF); mCells.resize(h); if (!extW) w = static_cast<int>(mSizes[0].size()); } if (extW) mSizes[0].resize(w, Layout::AUTO_DEF); std::vector< std::vector< LayoutCell * > >::iterator i = mCells.begin(); while (i != mCells.end()) { i->resize(w, 0); ++i; } } void LayoutArray::setColWidth(int n, int w) { resizeGrid(n + 1, 0); mSizes[0][n] = w; } void LayoutArray::setRowHeight(int n, int h) { resizeGrid(0, n + 1); mSizes[1][n] = h; } void LayoutArray::matchColWidth(int n1, int n2) { resizeGrid(std::max(n1, n2) + 1, 0); std::vector<int> widths = getSizes(0, Layout::AUTO_DEF); int s = std::max(widths[n1], widths[n2]); mSizes[0][n1] = s; mSizes[0][n2] = s; } void LayoutArray::extend(int x, int y, int w, int h) { LayoutCell &cell = at(x, y, w, h); cell.mExtent[0] = w; cell.mExtent[1] = h; } LayoutCell &LayoutArray::place(gcn::Widget *widget, int x, int y, int w, int h) { LayoutCell &cell = at(x, y, w, h); assert(cell.mType == LayoutCell::NONE); cell.mType = LayoutCell::WIDGET; cell.mWidget = widget; if (widget) { cell.mSize[0] = w == 1 ? widget->getWidth() : 0; cell.mSize[1] = h == 1 ? widget->getHeight() : 0; } else { cell.mSize[0] = 1; cell.mSize[1] = 1; } cell.mExtent[0] = w; cell.mExtent[1] = h; cell.mHPadding = 0; cell.mVPadding = 0; cell.mAlign[0] = LayoutCell::FILL; cell.mAlign[1] = LayoutCell::FILL; int &cs = mSizes[0][x], &rs = mSizes[1][y]; if (cs == Layout::AUTO_DEF && w == 1) cs = 0; if (rs == Layout::AUTO_DEF && h == 1) rs = 0; return cell; } void LayoutArray::align(int &pos, int &size, int dim, LayoutCell const &cell, int *sizes) const { int size_max = sizes[0]; for (int i = 1; i < cell.mExtent[dim]; ++i) size_max += sizes[i] + mSpacing; size = std::min<int>(cell.mSize[dim], size_max); switch (cell.mAlign[dim]) { case LayoutCell::LEFT: return; case LayoutCell::RIGHT: pos += size_max - size; return; case LayoutCell::CENTER: pos += (size_max - size) / 2; return; case LayoutCell::FILL: size = size_max; return; default: logger->log1("LayoutArray::align unknown layout"); return; } } std::vector<int> LayoutArray::getSizes(int dim, int upp) const { int gridW = static_cast<int>(mSizes[0].size()), gridH = static_cast<int>(mSizes[1].size()); std::vector<int> sizes = mSizes[dim]; // Compute minimum sizes. for (int gridY = 0; gridY < gridH; ++gridY) { for (int gridX = 0; gridX < gridW; ++gridX) { LayoutCell const *cell = mCells[gridY][gridX]; if (!cell || cell->mType == LayoutCell::NONE) continue; if (cell->mExtent[dim] == 1) { int n = (dim == 0 ? gridX : gridY); int s = cell->mSize[dim] + cell->mVPadding * 2; if (s > sizes[n]) sizes[n] = s; } } } if (upp == Layout::AUTO_DEF) return sizes; // Compute the FILL sizes. int nb = static_cast<int>(sizes.size()); int nbFill = 0; for (int i = 0; i < nb; ++i) { if (mSizes[dim][i] <= Layout::AUTO_DEF) { ++nbFill; if (mSizes[dim][i] == Layout::AUTO_SET || sizes[i] <= Layout::AUTO_DEF) { sizes[i] = 0; } } upp -= sizes[i] + mSpacing; } upp = upp + mSpacing; if (nbFill == 0) return sizes; for (int i = 0; i < nb; ++i) { if (mSizes[dim][i] > Layout::AUTO_DEF) continue; int s = upp / nbFill; sizes[i] += s; upp -= s; --nbFill; } return sizes; } int LayoutArray::getSize(int dim) const { std::vector<int> sizes = getSizes(dim, Layout::AUTO_DEF); int size = 0; int nb = static_cast<int>(sizes.size()); for (int i = 0; i < nb; ++i) { if (sizes[i] > Layout::AUTO_DEF) size += sizes[i]; size += mSpacing; } return size - mSpacing; } void LayoutArray::reflow(int nx, int ny, int nw, int nh) { int gridW = static_cast<int>(mSizes[0].size()), gridH = static_cast<int>(mSizes[1].size()); std::vector<int> widths = getSizes(0, nw); std::vector<int> heights = getSizes(1, nh); int y = ny; for (int gridY = 0; gridY < gridH; ++gridY) { int x = nx; for (int gridX = 0; gridX < gridW; ++gridX) { LayoutCell *cell = mCells[gridY][gridX]; if (cell && cell->mType != LayoutCell::NONE) { int dx = x, dy = y, dw = 0, dh = 0; align(dx, dw, 0, *cell, &widths[gridX]); align(dy, dh, 1, *cell, &heights[gridY]); cell->reflow(dx, dy, dw, dh); } x += widths[gridX] + mSpacing; } y += heights[gridY] + mSpacing; } } Layout::Layout(): mComputed(false) { getArray(); setPadding(6); } void Layout::reflow(int &nw, int &nh) { if (!mComputed) { computeSizes(); mComputed = true; } nw = (nw == 0 ? mSize[0] + 2 * mHPadding : nw); nh = (nh == 0 ? mSize[1] + 2 * mVPadding : nh); LayoutCell::reflow(0, 0, nw, nh); }