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export {defaultLayout, initTree};
const DEFAULT_TILE_SPACING = 5;
const DEFAULT_HEADER_SZ = 20;
const staticSqrLayout = { //determines layout for squares in a specified rectangle, with spacing
TILE_SPACING: DEFAULT_TILE_SPACING,
HEADER_SZ: DEFAULT_HEADER_SZ,
genLayout(nodes, x0, y0, w, h, hideHeader){
//get number-of-columns with highest occupied-fraction of rectangles with aspect-ratio w/h
//account for tile-spacing?, account for parent-box-border?, cache results?,
let hOffset = (hideHeader ? 0 : this.HEADER_SZ);
let numTiles = nodes.length, ar = (w - this.TILE_SPACING)/(h - hOffset - this.TILE_SPACING);
let numCols, numRows, bestFrac = 0;
for (let nc = 1; nc <= numTiles; nc++){
let nr = Math.ceil(numTiles/nc);
let ar2 = nc/nr;
let frac = ar > ar2 ? ar2/ar : ar/ar2;
if (frac > bestFrac){
bestFrac = frac;
numCols = nc;
numRows = nr;
}
}
//compute other parameters
let tileSz = Math.min(
((w - this.TILE_SPACING) / numCols) - this.TILE_SPACING,
((h - this.TILE_SPACING - hOffset) / numRows) - this.TILE_SPACING);
//determine layout
return {
coords: Object.fromEntries(
nodes.map((el, idx) => [el.tolNode.name, {
x: x0 + this.TILE_SPACING + (idx % numCols)*(tileSz + this.TILE_SPACING),
y: y0 + this.TILE_SPACING + hOffset + Math.floor(idx / numCols)*(tileSz + this.TILE_SPACING),
w: tileSz,
h: tileSz
}])
),
w: numCols * (tileSz + this.TILE_SPACING) + this.TILE_SPACING,
h: numRows * (tileSz + this.TILE_SPACING) + this.TILE_SPACING + hOffset,
};
},
initLayoutInfo(tree){
return;
},
updateLayoutInfoOnExpand(nodeList){
return;
},
updateLayoutInfoOnCollapse(nodeList){
return;
}
};
const staticRectLayout = {
TILE_SPACING: DEFAULT_TILE_SPACING,
HEADER_SZ: DEFAULT_HEADER_SZ,
genLayout(nodes, x0, y0, w, h, hideHeader){
if (nodes.every(e => e.children.length == 0)){
return staticSqrLayout.genLayout(nodes, x0, y0, w, h, hideHeader);
}
//if a node has children, find 'best' grid-arrangement
let hOffset = (hideHeader ? 0 : this.HEADER_SZ);
let availW = w - this.TILE_SPACING, availH = h - this.TILE_SPACING - hOffset;
let numChildren = nodes.length;
let rowBrks = [0]; //holds node indices at which each row starts
let rowBreaks, bestScore = Number.NEGATIVE_INFINITY, rowsOfCounts, cellWidths, cellHeights, nodeDims;
while (true){
//create list-of-lists representing each row's cells' tileCounts
let rowsOfCnts = Array(rowBrks.length).fill();
for (let r = 0; r < rowBrks.length; r++){
let numNodes = (r == rowBrks.length-1) ? numChildren-rowBrks[r] : rowBrks[r+1]-rowBrks[r];
let rowNodeIdxs = Array.from({length: numNodes}, (x,i) => i+rowBrks[r]);
rowsOfCnts[r] = rowNodeIdxs.map(idx => nodes[idx].tileCount);
}
//get cell dims
let totalTileCount = nodes.map(e => e.tileCount).reduce((x,y) => x+y);
let cellHs = rowsOfCnts.map(row => row.reduce((x, y) => x+y) / totalTileCount * availH);
let cellWs = Array(numChildren).fill();
for (let r = 0; r < rowsOfCnts.length; r++){
let rowCount = rowsOfCnts[r].reduce((x,y) => x+y);
for (let c = 0; c < rowsOfCnts[r].length; c++){
cellWs[rowBrks[r]+c] = rowsOfCnts[r][c] / rowCount * availW;
}
}
//get node dims and score
let score = 0;
let nodeDs = Array(numChildren).fill();
for (let r = 0; r < rowBrks.length; r++){
for (let c = 0; c < rowsOfCnts[r].length; c++){
let nodeIdx = rowBrks[r]+c;
let cellW = cellWs[nodeIdx], cellH = cellHs[r];
let ar = (cellW - this.TILE_SPACING) / (cellH - this.TILE_SPACING);
let ar2 = nodes[nodeIdx].arFromArea(cellW - this.TILE_SPACING, cellH - this.TILE_SPACING);
let frac = ar > ar2 ? ar2/ar : ar/ar2;
score += frac * (cellW * cellH);
nodeDs[nodeIdx] = ar > ar2 ? [cellW*frac, cellH] : [cellW, cellH*frac];
}
}
if (score > bestScore){
bestScore = score;
rowBreaks = [...rowBrks];
rowsOfCounts = rowsOfCnts;
cellWidths = cellWs;
cellHeights = cellHs;
nodeDims = nodeDs;
}
//update rowBrks or exit loop
let i = rowBrks.length-1, exitLoop = false;
while (true){
if (i > 0 && rowBrks[i] < numChildren-1 - (rowBrks.length-1 - i)){
rowBrks[i]++;
break;
} else if (i > 0){
i--;
} else {
if (rowBrks.length < numChildren){
rowBrks = Array.from({length: rowBrks.length+1}, (x,i) => i);
} else {
exitLoop = true;
}
break;
}
}
if (exitLoop)
break;
}
//for each row, shift empty right-space to rightmost cell
for (let r = 0; r < rowBreaks.length; r++){
let empHorzTotal = 0;
for (let c = 0; c < rowsOfCounts[r].length - 1; c++){
let nodeIdx = rowBreaks[r] + c;
let empHorz = cellWidths[nodeIdx] - nodeDims[nodeIdx][0];
cellWidths[nodeIdx] -= empHorz;
empHorzTotal += empHorz;
}
cellWidths[rowBreaks[r] + rowsOfCounts[r].length - 1] += empHorzTotal;
}
//shift empty bottom-space to bottom-most row
let empVertTotal = 0;
for (let r = 0; r < rowBreaks.length - 1; r++){
let nodeIdxs = Array.from({length: rowsOfCounts[r].length}, (x,i) => rowBreaks[r] + i);
let empVerts = nodeIdxs.map(idx => cellHeights[r] - nodeDims[idx][1]);
let minEmpVert = Math.min(...empVerts);
cellHeights[r] -= minEmpVert;
empVertTotal += minEmpVert;
}
cellHeights[rowBreaks.length - 1] += empVertTotal;
//determine layout
let cellHorzPoints = Array(cellWidths.length).fill(0);
for (let r = 0; r < rowBreaks.length; r++){
for (let c = 1; c < rowsOfCounts[r].length; c++){
let nodeIdx = rowBreaks[r]+c;
cellHorzPoints[nodeIdx] = cellHorzPoints[nodeIdx-1] + cellWidths[nodeIdx-1];
}
}
let cellVertPoints = Array(cellHeights.length).fill(0);
for (let r = 1; r < rowBreaks.length; r++){
cellVertPoints[r] = cellVertPoints[r-1] + cellHeights[r-1];
}
return {
coords: Object.fromEntries(
nodes.map((el, idx) => {
let cellW = cellWidths[idx];
let rowIdx = rowBreaks.findIndex((e,i) => i==rowBreaks.length-1 || rowBreaks[i+1] > idx);
let cellH = cellHeights[rowIdx];
let cellAR = cellW / cellH;
return [el.tolNode.name, {
x: x0 + this.TILE_SPACING + cellHorzPoints[idx],
y: y0 + this.TILE_SPACING + cellVertPoints[rowIdx] + hOffset,
w: (el.children.length == 0 ? (cellAR>1 ? cellW * 1/cellAR : cellW) : cellW) - this.TILE_SPACING,
h: (el.children.length == 0 ? (cellAR>1 ? cellH : cellH * cellAR) : cellH) - this.TILE_SPACING
}];
})
),
w: w,
h: h,
};
},
initLayoutInfo(tree){
if (tree.children.length > 0){
tree.children.forEach(e => this.initLayoutInfo(e));
}
this.updateLayoutInfo(tree);
},
updateLayoutInfoOnExpand(nodeList){ //given list of tree-nodes from expanded_child-to-parent, update layout-info
nodeList[0].children.forEach(this.updateLayoutInfo);
for (let node of nodeList){
this.updateLayoutInfo(node);
}
},
updateLayoutInfoOnCollapse(nodeList){ //given list of tree-nodes from child_to_collapse-to-parent, update layout-info
for (let node of nodeList){
this.updateLayoutInfo(node);
}
},
updateLayoutInfo(tree){
if (tree.children.length == 0){
tree.tileCount = 1;
tree.arFromArea = (w, h) => 1;
} else {
tree.tileCount = tree.children.map(e => e.tileCount).reduce((x,y) => x+y);
if (tree.children.every(e => e.children.length == 0)){
tree.arFromArea = (w, h) => {
let layout = staticSqrLayout.genLayout(tree.children, 0, 0, w, h, tree.hideHeader);
return layout.w / layout.h;
}
} else {
tree.arFromArea = (w, h) => w/h;
}
}
}
};
const sweepToSideLayout = {
TILE_SPACING: DEFAULT_TILE_SPACING,
HEADER_SZ: DEFAULT_HEADER_SZ,
genLayout(nodes, x0, y0, w, h, hideHeader){
//separate leaf and non-leaf nodes
let leaves = [], nonLeaves = [];
nodes.forEach(e => (e.children.length == 0 ? leaves : nonLeaves).push(e));
//determine layout
if (nonLeaves.length == 0){ //if all leaves, use squares-layout
return staticSqrLayout.genLayout(nodes, x0, y0, w, h, hideHeader);
} else { //if some non-leaves, use rect-layout
if (leaves.length == 0){
return staticRectLayout.genLayout(nonLeaves, x0, y0, w, h, hideHeader);
} else {
let ratio = leaves.length / (leaves.length + nonLeaves.map(e => e.tileCount).reduce((x,y) => x+y));
let hOffset = (hideHeader ? 0 : this.HEADER_SZ);
//get swept-area layout
let area = {x: x0, y: y0+hOffset, w: w, h: h-hOffset};
let leftLayout = staticSqrLayout.genLayout(leaves, area.x, area.y, area.w*ratio, area.h, true);
let topLayout = staticSqrLayout.genLayout(leaves, area.x, area.y, area.w, area.h*ratio, true);
//let sweptLayout = leftLayout;
let sweptLayout = (leftLayout.w*leftLayout.h > topLayout.w*topLayout.h) ? leftLayout : topLayout;
//get remaining-area layout
if (sweptLayout == leftLayout){
area.x += leftLayout.w - this.TILE_SPACING;
area.w += -leftLayout.w + this.TILE_SPACING;
} else {
area.y += topLayout.h - this.TILE_SPACING;
area.h += -topLayout.h + this.TILE_SPACING;
}
let nonLeavesLayout = staticRectLayout.genLayout(nonLeaves, area.x, area.y, area.w, area.h, true);
//return combined layout
return {coords: {...sweptLayout.coords, ...nonLeavesLayout.coords}, w: w, h: h};
}
}
},
initLayoutInfo(tree){
staticRectLayout.initLayoutInfo(tree);
},
updateLayoutInfoOnExpand(nodeList){
staticRectLayout.updateLayoutInfoOnExpand(nodeList);
},
updateLayoutInfoOnCollapse(nodeList){
staticRectLayout.updateLayoutInfoOnCollapse(nodeList);
}
};
let defaultLayout = sweepToSideLayout;
function initTree(tol, lvl, layout = defaultLayout){
let tree = {tolNode: tol, children: []};
initTreeRec(tree, lvl);
layout.initLayoutInfo(tree)
return tree;
}
function initTreeRec(tree, lvl){
if (lvl > 0){
tree.children = tree.tolNode.children.map(e => initTreeRec({tolNode: e, children: []}, lvl-1));
}
return tree;
}
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