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gerrit.onosproject.org / spring-open / fb38ed6c49debddb7ab8394ee8c2139980bed25c / . / sample / ONS2014demo / web / js / rings.js
blob: 979d28bcdba7516e6a7ddd8cd9ac965252b26942 [file] [log] [blame]
(function () {
createTopologyView = function (cb) {
window.addEventListener('resize', function () {
// this is too slow. instead detect first resize event and hide the paths that have explicit matrix applied
// either that or is it possible to position the paths so they get the automatic transform as well?
// updateTopology();
});
var svg = createRootSVG();
topology = svg.append('svg:svg').attr('id', 'viewBox').attr('viewBox', '0 0 1000 1000').attr('preserveAspectRatio', 'none').
attr('id', 'viewbox').append('svg:g').attr('id', 'topology').attr('transform', 'translate(500 500)');
flowLayer = d3.select('svg');
// hack to make the shared flow drawing code work
drawingRings = true;
cb();
}
function updateLinkLines() {
// key on link dpids since these will come/go during demo
var linkLines = d3.select('svg').selectAll('.link').data(links, function (d) {
return d['src-switch']+'->'+d['dst-switch'];
});
// add new links
linkLines.enter().append("svg:path").attr("class", "link");
linkLines.attr('id', function (d) {
return makeLinkKey(d);
}).attr("d", function (d) {
var src = d3.select(document.getElementById(d['src-switch']));
var dst = d3.select(document.getElementById(d['dst-switch']));
if (src.empty() || dst.empty()) {
return "M0,0";
}
var srcPt = document.querySelector('svg').createSVGPoint();
srcPt.x = src.attr('x');
srcPt.y = src.attr('y');
srcPt = srcPt.matrixTransform(src[0][0].getCTM());
var dstPt = document.querySelector('svg').createSVGPoint();
dstPt.x = dst.attr('x');
dstPt.y = dst.attr('y');
dstPt = dstPt.matrixTransform(dst[0][0].getCTM());
var midPt = document.querySelector('svg').createSVGPoint();
midPt.x = (srcPt.x + dstPt.x)/2;
midPt.y = (srcPt.y + dstPt.y)/2;
return line([srcPt, midPt, dstPt]);
})
.attr("marker-mid", function(d) { return "url(#arrow)"; })
.classed('pending', function (d) {
return d.pending;
});
// remove old links
linkLines.exit().remove();
}
function createRingTopologyModel(model) {
var rings = [{
radius: 3,
width: widths.edge,
switches: model.edgeSwitches,
className: 'edge',
angles: []
}, {
radius: 2.25,
width: widths.aggregation,
switches: model.aggregationSwitches,
className: 'aggregation',
angles: []
}, {
radius: 0.75,
width: widths.core,
switches: model.coreSwitches,
className: 'core',
angles: []
}];
var aggRanges = {};
// arrange edge switches at equal increments
var k = 360 / rings[0].switches.length;
rings[0].switches.forEach(function (s, i) {
var angle = k * i;
rings[0].angles[i] = angle;
// record the angle for the agg switch layout
var dpid = s.dpid.split(':');
dpid[7] = '01'; // the last component of the agg switch is always '01'
var aggdpid = dpid.join(':');
var aggRange = aggRanges[aggdpid];
if (!aggRange) {
aggRange = aggRanges[aggdpid] = {};
aggRange.min = aggRange.max = angle;
} else {
aggRange.max = angle;
}
});
// arrange aggregation switches to "fan out" to edge switches
k = 360 / rings[1].switches.length;
rings[1].switches.forEach(function (s, i) {
// rings[1].angles[i] = k * i;
var range = aggRanges[s.dpid];
rings[1].angles[i] = (range.min + range.max)/2;
});
// find the association between core switches and aggregation switches
var aggregationSwitchMap = {};
model.aggregationSwitches.forEach(function (s, i) {
aggregationSwitchMap[s.dpid] = i;
});
// put core switches next to linked aggregation switches
k = 360 / rings[2].switches.length;
rings[2].switches.forEach(function (s, i) {
// rings[2].angles[i] = k * i;
var associatedAggregationSwitches = model.configuration.association[s.dpid];
// TODO: go between if there are multiple
var index = aggregationSwitchMap[associatedAggregationSwitches[0]];
rings[2].angles[i] = rings[1].angles[index];
});
// TODO: construct this form initially rather than converting. it works better because
// it allows binding by dpid
var testRings = [];
rings.forEach(function (ring) {
var testRing = [];
ring.switches.forEach(function (s, i) {
var testSwitch = {
dpid: s.dpid,
state: s.state,
radius: ring.radius,
width: ring.width,
className: ring.className,
angle: ring.angles[i],
controller: s.controller
};
testRing.push(testSwitch);
});
testRings.push(testRing);
});
// return rings;
return testRings;
}
drawTopology = function () {
// DRAW THE SWITCHES
var rings = topology.selectAll('.ring').data(createRingTopologyModel(model));
function ringEnter(data, i) {
if (!data.length) {
return;
}
// create the nodes
var nodes = d3.select(this).selectAll("g")
.data(data, function (data) {
return data.dpid;
})
.enter().append("svg:g")
.attr("id", function (data, i) {
return data.dpid;
})
.attr("transform", function(data, i) {
return "rotate(" + data.angle+ ")translate(" + data.radius * 150 + ")rotate(" + (-data.angle) + ")";
});
// add the cirles representing the switches
nodes.append("svg:circle")
.attr("transform", function(data, i) {
var m = document.querySelector('#viewbox').getTransformToElement().inverse();
if (data.scale) {
m = m.scale(data.scale);
}
return "matrix( " + m.a + " " + m.b + " " + m.c + " " + m.d + " " + m.e + " " + m.f + " )";
})
.attr("x", function (data) {
return -data.width / 2;
})
.attr("y", function (data) {
return -data.width / 2;
})
.attr("r", function (data) {
return data.width;
});
}
// append switches
rings.enter().append("svg:g")
.attr("class", "ring")
.each(ringEnter);
function ringUpdate(data, i) {
var nodes = d3.select(this).selectAll("g")
.data(data, function (data) {
return data.dpid;
});
nodes.select('circle')
.each(function (data) {
// if there's a pending state changed and then the state changes, clear the pending class
var circle = d3.select(this);
if (data.state === 'ACTIVE' && circle.classed('inactive') ||
data.state === 'INACTIVE' && circle.classed('active')) {
circle.classed('pending', false);
}
})
.attr('class', function (data) {
if (data.state === 'ACTIVE' && data.controller) {
return data.className + ' active ' + controllerColorMap[data.controller];
} else {
return data.className + ' inactive ' + 'colorInactive';
}
});
}
// update switches
rings.each(ringUpdate);
// Now setup the labels
// This is done separately because SVG draws in node order and we want the labels
// always on top
var labelRings = topology.selectAll('.labelRing').data(createRingTopologyModel(model));
function labelRingEnter(data) {
if (!data.length) {
return;
}
// create the nodes
var nodes = d3.select(this).selectAll("g")
.data(data, function (data) {
return data.dpid;
})
.enter().append("svg:g")
.classed('nolabel', true)
.attr("id", function (data) {
return data.dpid + '-label';
})
.attr("transform", function(data, i) {
return "rotate(" + data.angle+ ")translate(" + data.radius * 150 + ")rotate(" + (-data.angle) + ")";
})
// add the text nodes which show on mouse over
nodes.append("svg:text")
.text(function (data) {return data.dpid;})
.attr("x", function (data) {
if (data.angle <= 90 || data.angle >= 270 && data.angle <= 360) {
if (data.className == 'edge') {
return - data.width*3 - 4;
} else {
return - data.width - 4;
}
} else {
if (data.className == 'edge') {
return data.width*3 + 4;
} else {
return data.width + 4;
}
}
})
.attr("y", function (data) {
var y;
if (data.angle <= 90 || data.angle >= 270 && data.angle <= 360) {
if (data.className == 'edge') {
y = data.width*3/2 + 4;
} else {
y = data.width/2 + 4;
}
} else {
if (data.className == 'edge') {
y = data.width*3/2 + 4;
} else {
y = data.width/2 + 4;
}
}
return y - 6;
})
.attr("text-anchor", function (data) {
if (data.angle <= 90 || data.angle >= 270 && data.angle <= 360) {
return "end";
} else {
return "start";
}
})
.attr("transform", function(data) {
var m = document.querySelector('#viewbox').getTransformToElement().inverse();
if (data.scale) {
m = m.scale(data.scale);
}
return "matrix( " + m.a + " " + m.b + " " + m.c + " " + m.d + " " + m.e + " " + m.f + " )";
})
}
labelRings.enter().append("svg:g")
.attr("class", "textRing")
.each(labelRingEnter);
// switches should not change during operation of the ui so no
// rings.exit()
updateLinkLines();
}
})();