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iD/js/lib/d3.v3.js
Bryan Housel f67d51492a add d3.geo.length
2015-04-01 11:04:20 -04:00

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!function(){
var d3 = {version: "3.5.5"}; // semver
d3.ascending = d3_ascending;
function d3_ascending(a, b) {
return a < b ? -1 : a > b ? 1 : a >= b ? 0 : NaN;
}
d3.descending = function(a, b) {
return b < a ? -1 : b > a ? 1 : b >= a ? 0 : NaN;
};
d3.min = function(array, f) {
var i = -1,
n = array.length,
a,
b;
if (arguments.length === 1) {
while (++i < n) if ((b = array[i]) != null && b >= b) { a = b; break; }
while (++i < n) if ((b = array[i]) != null && a > b) a = b;
} else {
while (++i < n) if ((b = f.call(array, array[i], i)) != null && b >= b) { a = b; break; }
while (++i < n) if ((b = f.call(array, array[i], i)) != null && a > b) a = b;
}
return a;
};
d3.max = function(array, f) {
var i = -1,
n = array.length,
a,
b;
if (arguments.length === 1) {
while (++i < n) if ((b = array[i]) != null && b >= b) { a = b; break; }
while (++i < n) if ((b = array[i]) != null && b > a) a = b;
} else {
while (++i < n) if ((b = f.call(array, array[i], i)) != null && b >= b) { a = b; break; }
while (++i < n) if ((b = f.call(array, array[i], i)) != null && b > a) a = b;
}
return a;
};
d3.extent = function(array, f) {
var i = -1,
n = array.length,
a,
b,
c;
if (arguments.length === 1) {
while (++i < n) if ((b = array[i]) != null && b >= b) { a = c = b; break; }
while (++i < n) if ((b = array[i]) != null) {
if (a > b) a = b;
if (c < b) c = b;
}
} else {
while (++i < n) if ((b = f.call(array, array[i], i)) != null && b >= b) { a = c = b; break; }
while (++i < n) if ((b = f.call(array, array[i], i)) != null) {
if (a > b) a = b;
if (c < b) c = b;
}
}
return [a, c];
};
function d3_number(x) {
return x === null ? NaN : +x;
}
function d3_numeric(x) {
return !isNaN(x);
}
d3.sum = function(array, f) {
var s = 0,
n = array.length,
a,
i = -1;
if (arguments.length === 1) {
while (++i < n) if (d3_numeric(a = +array[i])) s += a; // zero and null are equivalent
} else {
while (++i < n) if (d3_numeric(a = +f.call(array, array[i], i))) s += a;
}
return s;
};
d3.mean = function(array, f) {
var s = 0,
n = array.length,
a,
i = -1,
j = n;
if (arguments.length === 1) {
while (++i < n) if (d3_numeric(a = d3_number(array[i]))) s += a; else --j;
} else {
while (++i < n) if (d3_numeric(a = d3_number(f.call(array, array[i], i)))) s += a; else --j;
}
if (j) return s / j;
};
// R-7 per <http://en.wikipedia.org/wiki/Quantile>
d3.quantile = function(values, p) {
var H = (values.length - 1) * p + 1,
h = Math.floor(H),
v = +values[h - 1],
e = H - h;
return e ? v + e * (values[h] - v) : v;
};
d3.median = function(array, f) {
var numbers = [],
n = array.length,
a,
i = -1;
if (arguments.length === 1) {
while (++i < n) if (d3_numeric(a = d3_number(array[i]))) numbers.push(a);
} else {
while (++i < n) if (d3_numeric(a = d3_number(f.call(array, array[i], i)))) numbers.push(a);
}
if (numbers.length) return d3.quantile(numbers.sort(d3_ascending), .5);
};
d3.variance = function(array, f) {
var n = array.length,
m = 0,
a,
d,
s = 0,
i = -1,
j = 0;
if (arguments.length === 1) {
while (++i < n) {
if (d3_numeric(a = d3_number(array[i]))) {
d = a - m;
m += d / ++j;
s += d * (a - m);
}
}
} else {
while (++i < n) {
if (d3_numeric(a = d3_number(f.call(array, array[i], i)))) {
d = a - m;
m += d / ++j;
s += d * (a - m);
}
}
}
if (j > 1) return s / (j - 1);
};
d3.deviation = function() {
var v = d3.variance.apply(this, arguments);
return v ? Math.sqrt(v) : v;
};
function d3_bisector(compare) {
return {
left: function(a, x, lo, hi) {
if (arguments.length < 3) lo = 0;
if (arguments.length < 4) hi = a.length;
while (lo < hi) {
var mid = lo + hi >>> 1;
if (compare(a[mid], x) < 0) lo = mid + 1;
else hi = mid;
}
return lo;
},
right: function(a, x, lo, hi) {
if (arguments.length < 3) lo = 0;
if (arguments.length < 4) hi = a.length;
while (lo < hi) {
var mid = lo + hi >>> 1;
if (compare(a[mid], x) > 0) hi = mid;
else lo = mid + 1;
}
return lo;
}
};
}
var d3_bisect = d3_bisector(d3_ascending);
d3.bisectLeft = d3_bisect.left;
d3.bisect = d3.bisectRight = d3_bisect.right;
d3.bisector = function(f) {
return d3_bisector(f.length === 1
? function(d, x) { return d3_ascending(f(d), x); }
: f);
};
d3.shuffle = function(array, i0, i1) {
if ((m = arguments.length) < 3) { i1 = array.length; if (m < 2) i0 = 0; }
var m = i1 - i0, t, i;
while (m) {
i = Math.random() * m-- | 0;
t = array[m + i0], array[m + i0] = array[i + i0], array[i + i0] = t;
}
return array;
};
d3.permute = function(array, indexes) {
var i = indexes.length, permutes = new Array(i);
while (i--) permutes[i] = array[indexes[i]];
return permutes;
};
d3.pairs = function(array) {
var i = 0, n = array.length - 1, p0, p1 = array[0], pairs = new Array(n < 0 ? 0 : n);
while (i < n) pairs[i] = [p0 = p1, p1 = array[++i]];
return pairs;
};
d3.zip = function() {
if (!(n = arguments.length)) return [];
for (var i = -1, m = d3.min(arguments, d3_zipLength), zips = new Array(m); ++i < m;) {
for (var j = -1, n, zip = zips[i] = new Array(n); ++j < n;) {
zip[j] = arguments[j][i];
}
}
return zips;
};
function d3_zipLength(d) {
return d.length;
}
d3.transpose = function(matrix) {
return d3.zip.apply(d3, matrix);
};
d3.keys = function(map) {
var keys = [];
for (var key in map) keys.push(key);
return keys;
};
d3.values = function(map) {
var values = [];
for (var key in map) values.push(map[key]);
return values;
};
d3.entries = function(map) {
var entries = [];
for (var key in map) entries.push({key: key, value: map[key]});
return entries;
};
d3.merge = function(arrays) {
var n = arrays.length,
m,
i = -1,
j = 0,
merged,
array;
while (++i < n) j += arrays[i].length;
merged = new Array(j);
while (--n >= 0) {
array = arrays[n];
m = array.length;
while (--m >= 0) {
merged[--j] = array[m];
}
}
return merged;
};
var abs = Math.abs;
d3.range = function(start, stop, step) {
if (arguments.length < 3) {
step = 1;
if (arguments.length < 2) {
stop = start;
start = 0;
}
}
if ((stop - start) / step === Infinity) throw new Error("infinite range");
var range = [],
k = d3_range_integerScale(abs(step)),
i = -1,
j;
start *= k, stop *= k, step *= k;
if (step < 0) while ((j = start + step * ++i) > stop) range.push(j / k);
else while ((j = start + step * ++i) < stop) range.push(j / k);
return range;
};
function d3_range_integerScale(x) {
var k = 1;
while (x * k % 1) k *= 10;
return k;
}
function d3_class(ctor, properties) {
for (var key in properties) {
Object.defineProperty(ctor.prototype, key, {
value: properties[key],
enumerable: false
});
}
}
d3.map = function(object, f) {
var map = new d3_Map;
if (object instanceof d3_Map) {
object.forEach(function(key, value) { map.set(key, value); });
} else if (Array.isArray(object)) {
var i = -1,
n = object.length,
o;
if (arguments.length === 1) while (++i < n) map.set(i, object[i]);
else while (++i < n) map.set(f.call(object, o = object[i], i), o);
} else {
for (var key in object) map.set(key, object[key]);
}
return map;
};
function d3_Map() {
this._ = Object.create(null);
}
var d3_map_proto = "__proto__",
d3_map_zero = "\0";
d3_class(d3_Map, {
has: d3_map_has,
get: function(key) {
return this._[d3_map_escape(key)];
},
set: function(key, value) {
return this._[d3_map_escape(key)] = value;
},
remove: d3_map_remove,
keys: d3_map_keys,
values: function() {
var values = [];
for (var key in this._) values.push(this._[key]);
return values;
},
entries: function() {
var entries = [];
for (var key in this._) entries.push({key: d3_map_unescape(key), value: this._[key]});
return entries;
},
size: d3_map_size,
empty: d3_map_empty,
forEach: function(f) {
for (var key in this._) f.call(this, d3_map_unescape(key), this._[key]);
}
});
function d3_map_escape(key) {
return (key += "") === d3_map_proto || key[0] === d3_map_zero ? d3_map_zero + key : key;
}
function d3_map_unescape(key) {
return (key += "")[0] === d3_map_zero ? key.slice(1) : key;
}
function d3_map_has(key) {
return d3_map_escape(key) in this._;
}
function d3_map_remove(key) {
return (key = d3_map_escape(key)) in this._ && delete this._[key];
}
function d3_map_keys() {
var keys = [];
for (var key in this._) keys.push(d3_map_unescape(key));
return keys;
}
function d3_map_size() {
var size = 0;
for (var key in this._) ++size;
return size;
}
function d3_map_empty() {
for (var key in this._) return false;
return true;
}
d3.nest = function() {
var nest = {},
keys = [],
sortKeys = [],
sortValues,
rollup;
function map(mapType, array, depth) {
if (depth >= keys.length) return rollup
? rollup.call(nest, array) : (sortValues
? array.sort(sortValues)
: array);
var i = -1,
n = array.length,
key = keys[depth++],
keyValue,
object,
setter,
valuesByKey = new d3_Map,
values;
while (++i < n) {
if (values = valuesByKey.get(keyValue = key(object = array[i]))) {
values.push(object);
} else {
valuesByKey.set(keyValue, [object]);
}
}
if (mapType) {
object = mapType();
setter = function(keyValue, values) {
object.set(keyValue, map(mapType, values, depth));
};
} else {
object = {};
setter = function(keyValue, values) {
object[keyValue] = map(mapType, values, depth);
};
}
valuesByKey.forEach(setter);
return object;
}
function entries(map, depth) {
if (depth >= keys.length) return map;
var array = [],
sortKey = sortKeys[depth++];
map.forEach(function(key, keyMap) {
array.push({key: key, values: entries(keyMap, depth)});
});
return sortKey
? array.sort(function(a, b) { return sortKey(a.key, b.key); })
: array;
}
nest.map = function(array, mapType) {
return map(mapType, array, 0);
};
nest.entries = function(array) {
return entries(map(d3.map, array, 0), 0);
};
nest.key = function(d) {
keys.push(d);
return nest;
};
// Specifies the order for the most-recently specified key.
// Note: only applies to entries. Map keys are unordered!
nest.sortKeys = function(order) {
sortKeys[keys.length - 1] = order;
return nest;
};
// Specifies the order for leaf values.
// Applies to both maps and entries array.
nest.sortValues = function(order) {
sortValues = order;
return nest;
};
nest.rollup = function(f) {
rollup = f;
return nest;
};
return nest;
};
d3.set = function(array) {
var set = new d3_Set;
if (array) for (var i = 0, n = array.length; i < n; ++i) set.add(array[i]);
return set;
};
function d3_Set() {
this._ = Object.create(null);
}
d3_class(d3_Set, {
has: d3_map_has,
add: function(key) {
this._[d3_map_escape(key += "")] = true;
return key;
},
remove: d3_map_remove,
values: d3_map_keys,
size: d3_map_size,
empty: d3_map_empty,
forEach: function(f) {
for (var key in this._) f.call(this, d3_map_unescape(key));
}
});
d3.behavior = {};
var d3_document = this.document;
function d3_documentElement(node) {
return node
&& (node.ownerDocument // node is a Node
|| node.document // node is a Window
|| node).documentElement; // node is a Document
}
function d3_window(node) {
return node
&& ((node.ownerDocument && node.ownerDocument.defaultView) // node is a Node
|| (node.document && node) // node is a Window
|| node.defaultView); // node is a Document
}
// Copies a variable number of methods from source to target.
d3.rebind = function(target, source) {
var i = 1, n = arguments.length, method;
while (++i < n) target[method = arguments[i]] = d3_rebind(target, source, source[method]);
return target;
};
// Method is assumed to be a standard D3 getter-setter:
// If passed with no arguments, gets the value.
// If passed with arguments, sets the value and returns the target.
function d3_rebind(target, source, method) {
return function() {
var value = method.apply(source, arguments);
return value === source ? target : value;
};
}
function d3_vendorSymbol(object, name) {
if (name in object) return name;
name = name.charAt(0).toUpperCase() + name.slice(1);
for (var i = 0, n = d3_vendorPrefixes.length; i < n; ++i) {
var prefixName = d3_vendorPrefixes[i] + name;
if (prefixName in object) return prefixName;
}
}
var d3_vendorPrefixes = ["webkit", "ms", "moz", "Moz", "o", "O"];
var d3_arraySlice = [].slice,
d3_array = function(list) { return d3_arraySlice.call(list); }; // conversion for NodeLists
function d3_noop() {}
d3.dispatch = function() {
var dispatch = new d3_dispatch,
i = -1,
n = arguments.length;
while (++i < n) dispatch[arguments[i]] = d3_dispatch_event(dispatch);
return dispatch;
};
function d3_dispatch() {}
d3_dispatch.prototype.on = function(type, listener) {
var i = type.indexOf("."),
name = "";
// Extract optional namespace, e.g., "click.foo"
if (i >= 0) {
name = type.slice(i + 1);
type = type.slice(0, i);
}
if (type) return arguments.length < 2
? this[type].on(name)
: this[type].on(name, listener);
if (arguments.length === 2) {
if (listener == null) for (type in this) {
if (this.hasOwnProperty(type)) this[type].on(name, null);
}
return this;
}
};
function d3_dispatch_event(dispatch) {
var listeners = [],
listenerByName = new d3_Map;
function event() {
var z = listeners, // defensive reference
i = -1,
n = z.length,
l;
while (++i < n) if (l = z[i].on) l.apply(this, arguments);
return dispatch;
}
event.on = function(name, listener) {
var l = listenerByName.get(name),
i;
// return the current listener, if any
if (arguments.length < 2) return l && l.on;
// remove the old listener, if any (with copy-on-write)
if (l) {
l.on = null;
listeners = listeners.slice(0, i = listeners.indexOf(l)).concat(listeners.slice(i + 1));
listenerByName.remove(name);
}
// add the new listener, if any
if (listener) listeners.push(listenerByName.set(name, {on: listener}));
return dispatch;
};
return event;
}
d3.event = null;
function d3_eventPreventDefault() {
d3.event.preventDefault();
}
function d3_eventCancel() {
d3.event.preventDefault();
d3.event.stopPropagation();
}
function d3_eventSource() {
var e = d3.event, s;
while (s = e.sourceEvent) e = s;
return e;
}
// Like d3.dispatch, but for custom events abstracting native UI events. These
// events have a target component (such as a brush), a target element (such as
// the svg:g element containing the brush) and the standard arguments `d` (the
// target element's data) and `i` (the selection index of the target element).
function d3_eventDispatch(target) {
var dispatch = new d3_dispatch,
i = 0,
n = arguments.length;
while (++i < n) dispatch[arguments[i]] = d3_dispatch_event(dispatch);
// Creates a dispatch context for the specified `thiz` (typically, the target
// DOM element that received the source event) and `argumentz` (typically, the
// data `d` and index `i` of the target element). The returned function can be
// used to dispatch an event to any registered listeners; the function takes a
// single argument as input, being the event to dispatch. The event must have
// a "type" attribute which corresponds to a type registered in the
// constructor. This context will automatically populate the "sourceEvent" and
// "target" attributes of the event, as well as setting the `d3.event` global
// for the duration of the notification.
dispatch.of = function(thiz, argumentz) {
return function(e1) {
try {
var e0 =
e1.sourceEvent = d3.event;
e1.target = target;
d3.event = e1;
dispatch[e1.type].apply(thiz, argumentz);
} finally {
d3.event = e0;
}
};
};
return dispatch;
}
d3.requote = function(s) {
return s.replace(d3_requote_re, "\\$&");
};
var d3_requote_re = /[\\\^\$\*\+\?\|\[\]\(\)\.\{\}]/g;
var d3_subclass = {}.__proto__?
// Until ECMAScript supports array subclassing, prototype injection works well.
function(object, prototype) {
object.__proto__ = prototype;
}:
// And if your browser doesn't support __proto__, we'll use direct extension.
function(object, prototype) {
for (var property in prototype) object[property] = prototype[property];
};
function d3_selection(groups) {
d3_subclass(groups, d3_selectionPrototype);
return groups;
}
var d3_select = function(s, n) { return n.querySelector(s); },
d3_selectAll = function(s, n) { return n.querySelectorAll(s); },
d3_selectMatches = function(n, s) {
var d3_selectMatcher = n.matches || n[d3_vendorSymbol(n, "matchesSelector")];
d3_selectMatches = function(n, s) {
return d3_selectMatcher.call(n, s);
};
return d3_selectMatches(n, s);
};
// Prefer Sizzle, if available.
if (typeof Sizzle === "function") {
d3_select = function(s, n) { return Sizzle(s, n)[0] || null; };
d3_selectAll = Sizzle;
d3_selectMatches = Sizzle.matchesSelector;
}
d3.selection = function() {
return d3.select(d3_document.documentElement);
};
var d3_selectionPrototype = d3.selection.prototype = [];
d3_selectionPrototype.select = function(selector) {
var subgroups = [],
subgroup,
subnode,
group,
node;
selector = d3_selection_selector(selector);
for (var j = -1, m = this.length; ++j < m;) {
subgroups.push(subgroup = []);
subgroup.parentNode = (group = this[j]).parentNode;
for (var i = -1, n = group.length; ++i < n;) {
if (node = group[i]) {
subgroup.push(subnode = selector.call(node, node.__data__, i, j));
if (subnode && "__data__" in node) subnode.__data__ = node.__data__;
} else {
subgroup.push(null);
}
}
}
return d3_selection(subgroups);
};
function d3_selection_selector(selector) {
return typeof selector === "function" ? selector : function() {
return d3_select(selector, this);
};
}
d3_selectionPrototype.selectAll = function(selector) {
var subgroups = [],
subgroup,
node;
selector = d3_selection_selectorAll(selector);
for (var j = -1, m = this.length; ++j < m;) {
for (var group = this[j], i = -1, n = group.length; ++i < n;) {
if (node = group[i]) {
subgroups.push(subgroup = d3_array(selector.call(node, node.__data__, i, j)));
subgroup.parentNode = node;
}
}
}
return d3_selection(subgroups);
};
function d3_selection_selectorAll(selector) {
return typeof selector === "function" ? selector : function() {
return d3_selectAll(selector, this);
};
}
var d3_nsPrefix = {
svg: "http://www.w3.org/2000/svg",
xhtml: "http://www.w3.org/1999/xhtml",
xlink: "http://www.w3.org/1999/xlink",
xml: "http://www.w3.org/XML/1998/namespace",
xmlns: "http://www.w3.org/2000/xmlns/"
};
d3.ns = {
prefix: d3_nsPrefix,
qualify: function(name) {
var i = name.indexOf(":"),
prefix = name;
if (i >= 0) {
prefix = name.slice(0, i);
name = name.slice(i + 1);
}
return d3_nsPrefix.hasOwnProperty(prefix)
? {space: d3_nsPrefix[prefix], local: name}
: name;
}
};
d3_selectionPrototype.attr = function(name, value) {
if (arguments.length < 2) {
// For attr(string), return the attribute value for the first node.
if (typeof name === "string") {
var node = this.node();
name = d3.ns.qualify(name);
return name.local
? node.getAttributeNS(name.space, name.local)
: node.getAttribute(name);
}
// For attr(object), the object specifies the names and values of the
// attributes to set or remove. The values may be functions that are
// evaluated for each element.
for (value in name) this.each(d3_selection_attr(value, name[value]));
return this;
}
return this.each(d3_selection_attr(name, value));
};
function d3_selection_attr(name, value) {
name = d3.ns.qualify(name);
// For attr(string, null), remove the attribute with the specified name.
function attrNull() {
this.removeAttribute(name);
}
function attrNullNS() {
this.removeAttributeNS(name.space, name.local);
}
// For attr(string, string), set the attribute with the specified name.
function attrConstant() {
this.setAttribute(name, value);
}
function attrConstantNS() {
this.setAttributeNS(name.space, name.local, value);
}
// For attr(string, function), evaluate the function for each element, and set
// or remove the attribute as appropriate.
function attrFunction() {
var x = value.apply(this, arguments);
if (x == null) this.removeAttribute(name);
else this.setAttribute(name, x);
}
function attrFunctionNS() {
var x = value.apply(this, arguments);
if (x == null) this.removeAttributeNS(name.space, name.local);
else this.setAttributeNS(name.space, name.local, x);
}
return value == null
? (name.local ? attrNullNS : attrNull) : (typeof value === "function"
? (name.local ? attrFunctionNS : attrFunction)
: (name.local ? attrConstantNS : attrConstant));
}
function d3_collapse(s) {
return s.trim().replace(/\s+/g, " ");
}
d3_selectionPrototype.classed = function(name, value) {
if (arguments.length < 2) {
// For classed(string), return true only if the first node has the specified
// class or classes. Note that even if the browser supports DOMTokenList, it
// probably doesn't support it on SVG elements (which can be animated).
if (typeof name === "string") {
var node = this.node(),
n = (name = d3_selection_classes(name)).length,
i = -1;
if (value = node.classList) {
while (++i < n) if (!value.contains(name[i])) return false;
} else {
value = node.getAttribute("class");
while (++i < n) if (!d3_selection_classedRe(name[i]).test(value)) return false;
}
return true;
}
// For classed(object), the object specifies the names of classes to add or
// remove. The values may be functions that are evaluated for each element.
for (value in name) this.each(d3_selection_classed(value, name[value]));
return this;
}
// Otherwise, both a name and a value are specified, and are handled as below.
return this.each(d3_selection_classed(name, value));
};
function d3_selection_classedRe(name) {
return new RegExp("(?:^|\\s+)" + d3.requote(name) + "(?:\\s+|$)", "g");
}
function d3_selection_classes(name) {
return (name + "").trim().split(/^|\s+/);
}
// Multiple class names are allowed (e.g., "foo bar").
function d3_selection_classed(name, value) {
name = d3_selection_classes(name).map(d3_selection_classedName);
var n = name.length;
function classedConstant() {
var i = -1;
while (++i < n) name[i](this, value);
}
// When the value is a function, the function is still evaluated only once per
// element even if there are multiple class names.
function classedFunction() {
var i = -1, x = value.apply(this, arguments);
while (++i < n) name[i](this, x);
}
return typeof value === "function"
? classedFunction
: classedConstant;
}
function d3_selection_classedName(name) {
var re = d3_selection_classedRe(name);
return function(node, value) {
if (c = node.classList) return value ? c.add(name) : c.remove(name);
var c = node.getAttribute("class") || "";
if (value) {
re.lastIndex = 0;
if (!re.test(c)) node.setAttribute("class", d3_collapse(c + " " + name));
} else {
node.setAttribute("class", d3_collapse(c.replace(re, " ")));
}
};
}
d3_selectionPrototype.style = function(name, value, priority) {
var n = arguments.length;
if (n < 3) {
// For style(object) or style(object, string), the object specifies the
// names and values of the attributes to set or remove. The values may be
// functions that are evaluated for each element. The optional string
// specifies the priority.
if (typeof name !== "string") {
if (n < 2) value = "";
for (priority in name) this.each(d3_selection_style(priority, name[priority], value));
return this;
}
// For style(string), return the computed style value for the first node.
if (n < 2) {
var node = this.node();
return d3_window(node).getComputedStyle(node, null).getPropertyValue(name);
}
// For style(string, string) or style(string, function), use the default
// priority. The priority is ignored for style(string, null).
priority = "";
}
// Otherwise, a name, value and priority are specified, and handled as below.
return this.each(d3_selection_style(name, value, priority));
};
function d3_selection_style(name, value, priority) {
// For style(name, null) or style(name, null, priority), remove the style
// property with the specified name. The priority is ignored.
function styleNull() {
this.style.removeProperty(name);
}
// For style(name, string) or style(name, string, priority), set the style
// property with the specified name, using the specified priority.
function styleConstant() {
this.style.setProperty(name, value, priority);
}
// For style(name, function) or style(name, function, priority), evaluate the
// function for each element, and set or remove the style property as
// appropriate. When setting, use the specified priority.
function styleFunction() {
var x = value.apply(this, arguments);
if (x == null) this.style.removeProperty(name);
else this.style.setProperty(name, x, priority);
}
return value == null
? styleNull : (typeof value === "function"
? styleFunction : styleConstant);
}
d3_selectionPrototype.property = function(name, value) {
if (arguments.length < 2) {
// For property(string), return the property value for the first node.
if (typeof name === "string") return this.node()[name];
// For property(object), the object specifies the names and values of the
// properties to set or remove. The values may be functions that are
// evaluated for each element.
for (value in name) this.each(d3_selection_property(value, name[value]));
return this;
}
// Otherwise, both a name and a value are specified, and are handled as below.
return this.each(d3_selection_property(name, value));
};
function d3_selection_property(name, value) {
// For property(name, null), remove the property with the specified name.
function propertyNull() {
delete this[name];
}
// For property(name, string), set the property with the specified name.
function propertyConstant() {
this[name] = value;
}
// For property(name, function), evaluate the function for each element, and
// set or remove the property as appropriate.
function propertyFunction() {
var x = value.apply(this, arguments);
if (x == null) delete this[name];
else this[name] = x;
}
return value == null
? propertyNull : (typeof value === "function"
? propertyFunction : propertyConstant);
}
d3_selectionPrototype.text = function(value) {
return arguments.length
? this.each(typeof value === "function"
? function() { var v = value.apply(this, arguments); this.textContent = v == null ? "" : v; } : value == null
? function() { if (this.textContent !== "") this.textContent = ""; }
: function() { if (this.textContent !== value) this.textContent = value; })
: this.node().textContent;
};
d3_selectionPrototype.html = function(value) {
return arguments.length
? this.each(typeof value === "function"
? function() { var v = value.apply(this, arguments); this.innerHTML = v == null ? "" : v; } : value == null
? function() { this.innerHTML = ""; }
: function() { this.innerHTML = value; })
: this.node().innerHTML;
};
d3_selectionPrototype.append = function(name) {
name = d3_selection_creator(name);
return this.select(function() {
return this.appendChild(name.apply(this, arguments));
});
};
function d3_selection_creator(name) {
function create() {
var document = this.ownerDocument,
namespace = this.namespaceURI;
return namespace
? document.createElementNS(namespace, name)
: document.createElement(name);
}
function createNS() {
return this.ownerDocument.createElementNS(name.space, name.local);
}
return typeof name === "function" ? name
: (name = d3.ns.qualify(name)).local ? createNS
: create;
}
d3_selectionPrototype.insert = function(name, before) {
name = d3_selection_creator(name);
before = d3_selection_selector(before);
return this.select(function() {
return this.insertBefore(name.apply(this, arguments), before.apply(this, arguments) || null);
});
};
// TODO remove(selector)?
// TODO remove(node)?
// TODO remove(function)?
d3_selectionPrototype.remove = function() {
return this.each(d3_selectionRemove);
};
function d3_selectionRemove() {
var parent = this.parentNode;
if (parent) parent.removeChild(this);
}
d3_selectionPrototype.data = function(value, key) {
var i = -1,
n = this.length,
group,
node;
// If no value is specified, return the first value.
if (!arguments.length) {
value = new Array(n = (group = this[0]).length);
while (++i < n) {
if (node = group[i]) {
value[i] = node.__data__;
}
}
return value;
}
function bind(group, groupData) {
var i,
n = group.length,
m = groupData.length,
n0 = Math.min(n, m),
updateNodes = new Array(m),
enterNodes = new Array(m),
exitNodes = new Array(n),
node,
nodeData;
if (key) {
var nodeByKeyValue = new d3_Map,
keyValues = new Array(n),
keyValue;
for (i = -1; ++i < n;) {
if (nodeByKeyValue.has(keyValue = key.call(node = group[i], node.__data__, i))) {
exitNodes[i] = node; // duplicate selection key
} else {
nodeByKeyValue.set(keyValue, node);
}
keyValues[i] = keyValue;
}
for (i = -1; ++i < m;) {
if (!(node = nodeByKeyValue.get(keyValue = key.call(groupData, nodeData = groupData[i], i)))) {
enterNodes[i] = d3_selection_dataNode(nodeData);
} else if (node !== true) { // no duplicate data key
updateNodes[i] = node;
node.__data__ = nodeData;
}
nodeByKeyValue.set(keyValue, true);
}
for (i = -1; ++i < n;) {
if (nodeByKeyValue.get(keyValues[i]) !== true) {
exitNodes[i] = group[i];
}
}
} else {
for (i = -1; ++i < n0;) {
node = group[i];
nodeData = groupData[i];
if (node) {
node.__data__ = nodeData;
updateNodes[i] = node;
} else {
enterNodes[i] = d3_selection_dataNode(nodeData);
}
}
for (; i < m; ++i) {
enterNodes[i] = d3_selection_dataNode(groupData[i]);
}
for (; i < n; ++i) {
exitNodes[i] = group[i];
}
}
enterNodes.update
= updateNodes;
enterNodes.parentNode
= updateNodes.parentNode
= exitNodes.parentNode
= group.parentNode;
enter.push(enterNodes);
update.push(updateNodes);
exit.push(exitNodes);
}
var enter = d3_selection_enter([]),
update = d3_selection([]),
exit = d3_selection([]);
if (typeof value === "function") {
while (++i < n) {
bind(group = this[i], value.call(group, group.parentNode.__data__, i));
}
} else {
while (++i < n) {
bind(group = this[i], value);
}
}
update.enter = function() { return enter; };
update.exit = function() { return exit; };
return update;
};
function d3_selection_dataNode(data) {
return {__data__: data};
}
d3_selectionPrototype.datum = function(value) {
return arguments.length
? this.property("__data__", value)
: this.property("__data__");
};
d3_selectionPrototype.filter = function(filter) {
var subgroups = [],
subgroup,
group,
node;
if (typeof filter !== "function") filter = d3_selection_filter(filter);
for (var j = 0, m = this.length; j < m; j++) {
subgroups.push(subgroup = []);
subgroup.parentNode = (group = this[j]).parentNode;
for (var i = 0, n = group.length; i < n; i++) {
if ((node = group[i]) && filter.call(node, node.__data__, i, j)) {
subgroup.push(node);
}
}
}
return d3_selection(subgroups);
};
function d3_selection_filter(selector) {
return function() {
return d3_selectMatches(this, selector);
};
}
d3_selectionPrototype.order = function() {
for (var j = -1, m = this.length; ++j < m;) {
for (var group = this[j], i = group.length - 1, next = group[i], node; --i >= 0;) {
if (node = group[i]) {
if (next && next !== node.nextSibling) next.parentNode.insertBefore(node, next);
next = node;
}
}
}
return this;
};
d3_selectionPrototype.sort = function(comparator) {
comparator = d3_selection_sortComparator.apply(this, arguments);
for (var j = -1, m = this.length; ++j < m;) this[j].sort(comparator);
return this.order();
};
function d3_selection_sortComparator(comparator) {
if (!arguments.length) comparator = d3_ascending;
return function(a, b) {
return a && b ? comparator(a.__data__, b.__data__) : !a - !b;
};
}
d3_selectionPrototype.each = function(callback) {
return d3_selection_each(this, function(node, i, j) {
callback.call(node, node.__data__, i, j);
});
};
function d3_selection_each(groups, callback) {
for (var j = 0, m = groups.length; j < m; j++) {
for (var group = groups[j], i = 0, n = group.length, node; i < n; i++) {
if (node = group[i]) callback(node, i, j);
}
}
return groups;
}
d3_selectionPrototype.call = function(callback) {
var args = d3_array(arguments);
callback.apply(args[0] = this, args);
return this;
};
d3_selectionPrototype.empty = function() {
return !this.node();
};
d3_selectionPrototype.node = function() {
for (var j = 0, m = this.length; j < m; j++) {
for (var group = this[j], i = 0, n = group.length; i < n; i++) {
var node = group[i];
if (node) return node;
}
}
return null;
};
d3_selectionPrototype.size = function() {
var n = 0;
d3_selection_each(this, function() { ++n; });
return n;
};
function d3_selection_enter(selection) {
d3_subclass(selection, d3_selection_enterPrototype);
return selection;
}
var d3_selection_enterPrototype = [];
d3.selection.enter = d3_selection_enter;
d3.selection.enter.prototype = d3_selection_enterPrototype;
d3_selection_enterPrototype.append = d3_selectionPrototype.append;
d3_selection_enterPrototype.empty = d3_selectionPrototype.empty;
d3_selection_enterPrototype.node = d3_selectionPrototype.node;
d3_selection_enterPrototype.call = d3_selectionPrototype.call;
d3_selection_enterPrototype.size = d3_selectionPrototype.size;
d3_selection_enterPrototype.select = function(selector) {
var subgroups = [],
subgroup,
subnode,
upgroup,
group,
node;
for (var j = -1, m = this.length; ++j < m;) {
upgroup = (group = this[j]).update;
subgroups.push(subgroup = []);
subgroup.parentNode = group.parentNode;
for (var i = -1, n = group.length; ++i < n;) {
if (node = group[i]) {
subgroup.push(upgroup[i] = subnode = selector.call(group.parentNode, node.__data__, i, j));
subnode.__data__ = node.__data__;
} else {
subgroup.push(null);
}
}
}
return d3_selection(subgroups);
};
d3_selection_enterPrototype.insert = function(name, before) {
if (arguments.length < 2) before = d3_selection_enterInsertBefore(this);
return d3_selectionPrototype.insert.call(this, name, before);
};
function d3_selection_enterInsertBefore(enter) {
var i0, j0;
return function(d, i, j) {
var group = enter[j].update,
n = group.length,
node;
if (j != j0) j0 = j, i0 = 0;
if (i >= i0) i0 = i + 1;
while (!(node = group[i0]) && ++i0 < n);
return node;
};
}
// TODO fast singleton implementation?
d3.select = function(node) {
var group;
if (typeof node === "string") {
group = [d3_select(node, d3_document)];
group.parentNode = d3_document.documentElement;
} else {
group = [node];
group.parentNode = d3_documentElement(node);
}
return d3_selection([group]);
};
d3.selectAll = function(nodes) {
var group;
if (typeof nodes === "string") {
group = d3_array(d3_selectAll(nodes, d3_document));
group.parentNode = d3_document.documentElement;
} else {
group = nodes;
group.parentNode = null;
}
return d3_selection([group]);
};
d3_selectionPrototype.on = function(type, listener, capture) {
var n = arguments.length;
if (n < 3) {
// For on(object) or on(object, boolean), the object specifies the event
// types and listeners to add or remove. The optional boolean specifies
// whether the listener captures events.
if (typeof type !== "string") {
if (n < 2) listener = false;
for (capture in type) this.each(d3_selection_on(capture, type[capture], listener));
return this;
}
// For on(string), return the listener for the first node.
if (n < 2) return (n = this.node()["__on" + type]) && n._;
// For on(string, function), use the default capture.
capture = false;
}
// Otherwise, a type, listener and capture are specified, and handled as below.
return this.each(d3_selection_on(type, listener, capture));
};
function d3_selection_on(type, listener, capture) {
var name = "__on" + type,
i = type.indexOf("."),
wrap = d3_selection_onListener;
if (i > 0) type = type.slice(0, i);
var filter = d3_selection_onFilters.get(type);
if (filter) type = filter, wrap = d3_selection_onFilter;
function onRemove() {
var l = this[name];
if (l) {
this.removeEventListener(type, l, l.$);
delete this[name];
}
}
function onAdd() {
var l = wrap(listener, d3_array(arguments));
if (typeof Raven !== 'undefined') l = Raven.wrap(l);
onRemove.call(this);
this.addEventListener(type, this[name] = l, l.$ = capture);
l._ = listener;
}
function removeAll() {
var re = new RegExp("^__on([^.]+)" + d3.requote(type) + "$"),
match;
for (var name in this) {
if (match = name.match(re)) {
var l = this[name];
this.removeEventListener(match[1], l, l.$);
delete this[name];
}
}
}
return i
? listener ? onAdd : onRemove
: listener ? d3_noop : removeAll;
}
var d3_selection_onFilters = d3.map({
mouseenter: "mouseover",
mouseleave: "mouseout"
});
if (d3_document) {
d3_selection_onFilters.forEach(function(k) {
if ("on" + k in d3_document) d3_selection_onFilters.remove(k);
});
}
function d3_selection_onListener(listener, argumentz) {
return function(e) {
var o = d3.event; // Events can be reentrant (e.g., focus).
d3.event = e;
argumentz[0] = this.__data__;
try {
listener.apply(this, argumentz);
} finally {
d3.event = o;
}
};
}
function d3_selection_onFilter(listener, argumentz) {
var l = d3_selection_onListener(listener, argumentz);
return function(e) {
var target = this, related = e.relatedTarget;
if (!related || (related !== target && !(related.compareDocumentPosition(target) & 8))) {
l.call(target, e);
}
};
}
var d3_event_dragSelect,
d3_event_dragId = 0;
function d3_event_dragSuppress(node) {
var name = ".dragsuppress-" + ++d3_event_dragId,
click = "click" + name,
w = d3.select(d3_window(node))
.on("touchmove" + name, d3_eventPreventDefault)
.on("dragstart" + name, d3_eventPreventDefault)
.on("selectstart" + name, d3_eventPreventDefault);
if (d3_event_dragSelect == null) {
d3_event_dragSelect = "onselectstart" in node ? false
: d3_vendorSymbol(node.style, "userSelect");
}
if (d3_event_dragSelect) {
var style = d3_documentElement(node).style,
select = style[d3_event_dragSelect];
style[d3_event_dragSelect] = "none";
}
return function(suppressClick) {
w.on(name, null);
if (d3_event_dragSelect) style[d3_event_dragSelect] = select;
if (suppressClick) { // suppress the next click, but only if its immediate
var off = function() { w.on(click, null); };
w.on(click, function() { d3_eventCancel(); off(); }, true);
setTimeout(off, 0);
}
};
}
d3.mouse = function(container) {
return d3_mousePoint(container, d3_eventSource());
};
// https://bugs.webkit.org/show_bug.cgi?id=44083
var d3_mouse_bug44083 = this.navigator && /WebKit/.test(this.navigator.userAgent) ? -1 : 0;
function d3_mousePoint(container, e) {
if (e.changedTouches) e = e.changedTouches[0];
var svg = container.ownerSVGElement || container;
if (svg.createSVGPoint) {
var point = svg.createSVGPoint();
if (d3_mouse_bug44083 < 0) {
var window = d3_window(container);
if (window.scrollX || window.scrollY) {
svg = d3.select("body").append("svg").style({
position: "absolute",
top: 0,
left: 0,
margin: 0,
padding: 0,
border: "none"
}, "important");
var ctm = svg[0][0].getScreenCTM();
d3_mouse_bug44083 = !(ctm.f || ctm.e);
svg.remove();
}
}
if (d3_mouse_bug44083) point.x = e.pageX, point.y = e.pageY;
else point.x = e.clientX, point.y = e.clientY;
point = point.matrixTransform(container.getScreenCTM().inverse());
return [point.x, point.y];
}
var rect = container.getBoundingClientRect();
return [e.clientX - rect.left - container.clientLeft, e.clientY - rect.top - container.clientTop];
};
d3.touches = function(container, touches) {
if (arguments.length < 2) touches = d3_eventSource().touches;
return touches ? d3_array(touches).map(function(touch) {
var point = d3_mousePoint(container, touch);
point.identifier = touch.identifier;
return point;
}) : [];
};
var ε = 1e-6,
ε2 = ε * ε,
π = Math.PI,
τ = 2 * π,
τε = τ - ε,
halfπ = π / 2,
d3_radians = π / 180,
d3_degrees = 180 / π;
function d3_sgn(x) {
return x > 0 ? 1 : x < 0 ? -1 : 0;
}
// Returns the 2D cross product of AB and AC vectors, i.e., the z-component of
// the 3D cross product in a quadrant I Cartesian coordinate system (+x is
// right, +y is up). Returns a positive value if ABC is counter-clockwise,
// negative if clockwise, and zero if the points are collinear.
function d3_cross2d(a, b, c) {
return (b[0] - a[0]) * (c[1] - a[1]) - (b[1] - a[1]) * (c[0] - a[0]);
}
function d3_acos(x) {
return x > 1 ? 0 : x < -1 ? π : Math.acos(x);
}
function d3_asin(x) {
return x > 1 ? halfπ : x < -1 ? -halfπ : Math.asin(x);
}
function d3_sinh(x) {
return ((x = Math.exp(x)) - 1 / x) / 2;
}
function d3_cosh(x) {
return ((x = Math.exp(x)) + 1 / x) / 2;
}
function d3_tanh(x) {
return ((x = Math.exp(2 * x)) - 1) / (x + 1);
}
function d3_haversin(x) {
return (x = Math.sin(x / 2)) * x;
}
var ρ = Math.SQRT2,
ρ2 = 2,
ρ4 = 4;
// p0 = [ux0, uy0, w0]
// p1 = [ux1, uy1, w1]
d3.interpolateZoom = function(p0, p1) {
var ux0 = p0[0], uy0 = p0[1], w0 = p0[2],
ux1 = p1[0], uy1 = p1[1], w1 = p1[2];
var dx = ux1 - ux0,
dy = uy1 - uy0,
d2 = dx * dx + dy * dy,
d1 = Math.sqrt(d2),
b0 = (w1 * w1 - w0 * w0 + ρ4 * d2) / (2 * w0 * ρ2 * d1),
b1 = (w1 * w1 - w0 * w0 - ρ4 * d2) / (2 * w1 * ρ2 * d1),
r0 = Math.log(Math.sqrt(b0 * b0 + 1) - b0),
r1 = Math.log(Math.sqrt(b1 * b1 + 1) - b1),
dr = r1 - r0,
S = (dr || Math.log(w1 / w0)) / ρ;
function interpolate(t) {
var s = t * S;
if (dr) {
// General case.
var coshr0 = d3_cosh(r0),
u = w0 / (ρ2 * d1) * (coshr0 * d3_tanh(ρ * s + r0) - d3_sinh(r0));
return [
ux0 + u * dx,
uy0 + u * dy,
w0 * coshr0 / d3_cosh(ρ * s + r0)
];
}
// Special case for u0 ~= u1.
return [
ux0 + t * dx,
uy0 + t * dy,
w0 * Math.exp(ρ * s)
];
}
interpolate.duration = S * 1000;
return interpolate;
};
d3.behavior.zoom = function() {
var view = {x: 0, y: 0, k: 1},
translate0, // translate when we started zooming (to avoid drift)
center0, // implicit desired position of translate0 after zooming
center, // explicit desired position of translate0 after zooming
size = [960, 500], // viewport size; required for zoom interpolation
scaleExtent = d3_behavior_zoomInfinity,
duration = 250,
zooming = 0,
mousedown = "mousedown.zoom",
mousemove = "mousemove.zoom",
mouseup = "mouseup.zoom",
mousewheelTimer,
touchstart = "touchstart.zoom",
touchtime, // time of last touchstart (to detect double-tap)
event = d3_eventDispatch(zoom, "zoomstart", "zoom", "zoomend"),
x0,
x1,
y0,
y1;
// Lazily determine the DOMs support for Wheel events.
// https://developer.mozilla.org/en-US/docs/Mozilla_event_reference/wheel
if (!d3_behavior_zoomWheel) {
d3_behavior_zoomWheel = "onwheel" in d3_document ? (d3_behavior_zoomDelta = function() { return -d3.event.deltaY * (d3.event.deltaMode ? 120 : 1); }, "wheel")
: "onmousewheel" in d3_document ? (d3_behavior_zoomDelta = function() { return d3.event.wheelDelta; }, "mousewheel")
: (d3_behavior_zoomDelta = function() { return -d3.event.detail; }, "MozMousePixelScroll");
}
function zoom(g) {
g .on(mousedown, mousedowned)
.on(d3_behavior_zoomWheel + ".zoom", mousewheeled)
.on("dblclick.zoom", dblclicked)
.on(touchstart, touchstarted);
}
zoom.event = function(g) {
g.each(function() {
var dispatch = event.of(this, arguments),
view1 = view;
if (d3_transitionInheritId) {
d3.select(this).transition()
.each("start.zoom", function() {
view = this.__chart__ || {x: 0, y: 0, k: 1}; // pre-transition state
zoomstarted(dispatch);
})
.tween("zoom:zoom", function() {
var dx = size[0],
dy = size[1],
cx = center0 ? center0[0] : dx / 2,
cy = center0 ? center0[1] : dy / 2,
i = d3.interpolateZoom(
[(cx - view.x) / view.k, (cy - view.y) / view.k, dx / view.k],
[(cx - view1.x) / view1.k, (cy - view1.y) / view1.k, dx / view1.k]
);
return function(t) {
var l = i(t), k = dx / l[2];
this.__chart__ = view = {x: cx - l[0] * k, y: cy - l[1] * k, k: k};
zoomed(dispatch);
};
})
.each("interrupt.zoom", function() {
zoomended(dispatch);
})
.each("end.zoom", function() {
zoomended(dispatch);
});
} else {
this.__chart__ = view;
zoomstarted(dispatch);
zoomed(dispatch);
zoomended(dispatch);
}
});
}
zoom.translate = function(_) {
if (!arguments.length) return [view.x, view.y];
view = {x: +_[0], y: +_[1], k: view.k}; // copy-on-write
rescale();
return zoom;
};
zoom.scale = function(_) {
if (!arguments.length) return view.k;
view = {x: view.x, y: view.y, k: +_}; // copy-on-write
rescale();
return zoom;
};
zoom.scaleExtent = function(_) {
if (!arguments.length) return scaleExtent;
scaleExtent = _ == null ? d3_behavior_zoomInfinity : [+_[0], +_[1]];
return zoom;
};
zoom.center = function(_) {
if (!arguments.length) return center;
center = _ && [+_[0], +_[1]];
return zoom;
};
zoom.size = function(_) {
if (!arguments.length) return size;
size = _ && [+_[0], +_[1]];
return zoom;
};
zoom.duration = function(_) {
if (!arguments.length) return duration;
duration = +_; // TODO function based on interpolateZoom distance?
return zoom;
};
zoom.x = function(z) {
if (!arguments.length) return x1;
x1 = z;
x0 = z.copy();
view = {x: 0, y: 0, k: 1}; // copy-on-write
return zoom;
};
zoom.y = function(z) {
if (!arguments.length) return y1;
y1 = z;
y0 = z.copy();
view = {x: 0, y: 0, k: 1}; // copy-on-write
return zoom;
};
function location(p) {
return [(p[0] - view.x) / view.k, (p[1] - view.y) / view.k];
}
function point(l) {
return [l[0] * view.k + view.x, l[1] * view.k + view.y];
}
function scaleTo(s) {
view.k = Math.max(scaleExtent[0], Math.min(scaleExtent[1], s));
}
function translateTo(p, l) {
l = point(l);
view.x += p[0] - l[0];
view.y += p[1] - l[1];
}
function zoomTo(that, p, l, k) {
that.__chart__ = {x: view.x, y: view.y, k: view.k};
scaleTo(Math.pow(2, k));
translateTo(center0 = p, l);
that = d3.select(that);
if (duration > 0) that = that.transition().duration(duration);
that.call(zoom.event);
}
function rescale() {
if (x1) x1.domain(x0.range().map(function(x) { return (x - view.x) / view.k; }).map(x0.invert));
if (y1) y1.domain(y0.range().map(function(y) { return (y - view.y) / view.k; }).map(y0.invert));
}
function zoomstarted(dispatch) {
if (!zooming++) dispatch({type: "zoomstart"});
}
function zoomed(dispatch) {
rescale();
dispatch({type: "zoom", scale: view.k, translate: [view.x, view.y]});
}
function zoomended(dispatch) {
if (!--zooming) dispatch({type: "zoomend"});
center0 = null;
}
function mousedowned() {
var that = this,
target = d3.event.target,
dispatch = event.of(that, arguments),
dragged = 0,
subject = d3.select(d3_window(that)).on(mousemove, moved).on(mouseup, ended),
location0 = location(d3.mouse(that)),
dragRestore = d3_event_dragSuppress(that);
d3_selection_interrupt.call(that);
zoomstarted(dispatch);
function moved() {
dragged = 1;
translateTo(d3.mouse(that), location0);
zoomed(dispatch);
}
function ended() {
subject.on(mousemove, null).on(mouseup, null);
dragRestore(dragged && d3.event.target === target);
zoomended(dispatch);
}
}
// These closures persist for as long as at least one touch is active.
function touchstarted() {
var that = this,
dispatch = event.of(that, arguments),
locations0 = {}, // touchstart locations
distance0 = 0, // distance² between initial touches
scale0, // scale when we started touching
zoomName = ".zoom-" + d3.event.changedTouches[0].identifier,
touchmove = "touchmove" + zoomName,
touchend = "touchend" + zoomName,
targets = [],
subject = d3.select(that),
dragRestore = d3_event_dragSuppress(that);
started();
zoomstarted(dispatch);
// Workaround for Chrome issue 412723: the touchstart listener must be set
// after the touchmove listener.
subject.on(mousedown, null).on(touchstart, started); // prevent duplicate events
// Updates locations of any touches in locations0.
function relocate() {
var touches = d3.touches(that);
scale0 = view.k;
touches.forEach(function(t) {
if (t.identifier in locations0) locations0[t.identifier] = location(t);
});
return touches;
}
// Temporarily override touchstart while gesture is active.
function started() {
// Listen for touchmove and touchend on the target of touchstart.
var target = d3.event.target;
d3.select(target).on(touchmove, moved).on(touchend, ended);
targets.push(target);
// Only track touches started on the same subject element.
var changed = d3.event.changedTouches;
for (var i = 0, n = changed.length; i < n; ++i) {
locations0[changed[i].identifier] = null;
}
var touches = relocate(),
now = Date.now();
if (touches.length === 1) {
if (now - touchtime < 500) { // dbltap
var p = touches[0];
zoomTo(that, p, locations0[p.identifier], Math.floor(Math.log(view.k) / Math.LN2) + 1);
d3_eventPreventDefault();
}
touchtime = now;
} else if (touches.length > 1) {
var p = touches[0], q = touches[1],
dx = p[0] - q[0], dy = p[1] - q[1];
distance0 = dx * dx + dy * dy;
}
}
function moved() {
var touches = d3.touches(that),
p0, l0,
p1, l1;
d3_selection_interrupt.call(that);
for (var i = 0, n = touches.length; i < n; ++i, l1 = null) {
p1 = touches[i];
if (l1 = locations0[p1.identifier]) {
if (l0) break;
p0 = p1, l0 = l1;
}
}
if (l1) {
var distance1 = (distance1 = p1[0] - p0[0]) * distance1 + (distance1 = p1[1] - p0[1]) * distance1,
scale1 = distance0 && Math.sqrt(distance1 / distance0);
p0 = [(p0[0] + p1[0]) / 2, (p0[1] + p1[1]) / 2];
l0 = [(l0[0] + l1[0]) / 2, (l0[1] + l1[1]) / 2];
scaleTo(scale1 * scale0);
}
touchtime = null;
translateTo(p0, l0);
zoomed(dispatch);
}
function ended() {
// If there are any globally-active touches remaining, remove the ended
// touches from locations0.
if (d3.event.touches.length) {
var changed = d3.event.changedTouches;
for (var i = 0, n = changed.length; i < n; ++i) {
delete locations0[changed[i].identifier];
}
// If locations0 is not empty, then relocate and continue listening for
// touchmove and touchend.
for (var identifier in locations0) {
return void relocate(); // locations may have detached due to rotation
}
}
// Otherwise, remove touchmove and touchend listeners.
d3.selectAll(targets).on(zoomName, null);
subject.on(mousedown, mousedowned).on(touchstart, touchstarted);
dragRestore();
zoomended(dispatch);
}
}
function mousewheeled() {
var dispatch = event.of(this, arguments);
if (mousewheelTimer) clearTimeout(mousewheelTimer);
else translate0 = location(center0 = center || d3.mouse(this)), d3_selection_interrupt.call(this), zoomstarted(dispatch);
mousewheelTimer = setTimeout(function() { mousewheelTimer = null; zoomended(dispatch); }, 50);
d3_eventPreventDefault();
scaleTo(Math.pow(2, d3_behavior_zoomDelta() * .002) * view.k);
translateTo(center0, translate0);
zoomed(dispatch);
}
function dblclicked() {
var p = d3.mouse(this),
k = Math.log(view.k) / Math.LN2;
zoomTo(this, p, location(p), d3.event.shiftKey ? Math.ceil(k) - 1 : Math.floor(k) + 1);
}
return d3.rebind(zoom, event, "on");
};
var d3_behavior_zoomInfinity = [0, Infinity], // default scale extent
d3_behavior_zoomDelta, // initialized lazily
d3_behavior_zoomWheel;
function d3_functor(v) {
return typeof v === "function" ? v : function() { return v; };
}
d3.functor = d3_functor;
d3.touch = function(container, touches, identifier) {
if (arguments.length < 3) identifier = touches, touches = d3_eventSource().changedTouches;
if (touches) for (var i = 0, n = touches.length, touch; i < n; ++i) {
if ((touch = touches[i]).identifier === identifier) {
return d3_mousePoint(container, touch);
}
}
};
var d3_timer_queueHead,
d3_timer_queueTail,
d3_timer_interval, // is an interval (or frame) active?
d3_timer_timeout, // is a timeout active?
d3_timer_active, // active timer object
d3_timer_frame = this[d3_vendorSymbol(this, "requestAnimationFrame")] || function(callback) { setTimeout(callback, 17); };
// The timer will continue to fire until callback returns true.
d3.timer = function(callback, delay, then) {
var n = arguments.length;
if (n < 2) delay = 0;
if (n < 3) then = Date.now();
// Add the callback to the tail of the queue.
var time = then + delay, timer = {c: callback, t: time, f: false, n: null};
if (d3_timer_queueTail) d3_timer_queueTail.n = timer;
else d3_timer_queueHead = timer;
d3_timer_queueTail = timer;
// Start animatin'!
if (!d3_timer_interval) {
d3_timer_timeout = clearTimeout(d3_timer_timeout);
d3_timer_interval = 1;
d3_timer_frame(d3_timer_step);
}
};
function d3_timer_step() {
var now = d3_timer_mark(),
delay = d3_timer_sweep() - now;
if (delay > 24) {
if (isFinite(delay)) {
clearTimeout(d3_timer_timeout);
d3_timer_timeout = setTimeout(d3_timer_step, delay);
}
d3_timer_interval = 0;
} else {
d3_timer_interval = 1;
d3_timer_frame(d3_timer_step);
}
}
d3.timer.flush = function() {
d3_timer_mark();
d3_timer_sweep();
};
function d3_timer_mark() {
var now = Date.now();
d3_timer_active = d3_timer_queueHead;
while (d3_timer_active) {
if (now >= d3_timer_active.t) d3_timer_active.f = d3_timer_active.c(now - d3_timer_active.t);
d3_timer_active = d3_timer_active.n;
}
return now;
}
// Flush after callbacks to avoid concurrent queue modification.
// Returns the time of the earliest active timer, post-sweep.
function d3_timer_sweep() {
var t0,
t1 = d3_timer_queueHead,
time = Infinity;
while (t1) {
if (t1.f) {
t1 = t0 ? t0.n = t1.n : d3_timer_queueHead = t1.n;
} else {
if (t1.t < time) time = t1.t;
t1 = (t0 = t1).n;
}
}
d3_timer_queueTail = t0;
return time;
}
d3.geo = {};
d3.geo.stream = function(object, listener) {
if (object && d3_geo_streamObjectType.hasOwnProperty(object.type)) {
d3_geo_streamObjectType[object.type](object, listener);
} else {
d3_geo_streamGeometry(object, listener);
}
};
function d3_geo_streamGeometry(geometry, listener) {
if (geometry && d3_geo_streamGeometryType.hasOwnProperty(geometry.type)) {
d3_geo_streamGeometryType[geometry.type](geometry, listener);
}
}
var d3_geo_streamObjectType = {
Feature: function(feature, listener) {
d3_geo_streamGeometry(feature.geometry, listener);
},
FeatureCollection: function(object, listener) {
var features = object.features, i = -1, n = features.length;
while (++i < n) d3_geo_streamGeometry(features[i].geometry, listener);
}
};
var d3_geo_streamGeometryType = {
Sphere: function(object, listener) {
listener.sphere();
},
Point: function(object, listener) {
object = object.coordinates;
listener.point(object[0], object[1], object[2]);
},
MultiPoint: function(object, listener) {
var coordinates = object.coordinates, i = -1, n = coordinates.length;
while (++i < n) object = coordinates[i], listener.point(object[0], object[1], object[2]);
},
LineString: function(object, listener) {
d3_geo_streamLine(object.coordinates, listener, 0);
},
MultiLineString: function(object, listener) {
var coordinates = object.coordinates, i = -1, n = coordinates.length;
while (++i < n) d3_geo_streamLine(coordinates[i], listener, 0);
},
Polygon: function(object, listener) {
d3_geo_streamPolygon(object.coordinates, listener);
},
MultiPolygon: function(object, listener) {
var coordinates = object.coordinates, i = -1, n = coordinates.length;
while (++i < n) d3_geo_streamPolygon(coordinates[i], listener);
},
GeometryCollection: function(object, listener) {
var geometries = object.geometries, i = -1, n = geometries.length;
while (++i < n) d3_geo_streamGeometry(geometries[i], listener);
}
};
function d3_geo_streamLine(coordinates, listener, closed) {
var i = -1, n = coordinates.length - closed, coordinate;
listener.lineStart();
while (++i < n) coordinate = coordinates[i], listener.point(coordinate[0], coordinate[1], coordinate[2]);
listener.lineEnd();
}
function d3_geo_streamPolygon(coordinates, listener) {
var i = -1, n = coordinates.length;
listener.polygonStart();
while (++i < n) d3_geo_streamLine(coordinates[i], listener, 1);
listener.polygonEnd();
}
d3.geo.length = function(object) {
d3_geo_lengthSum = 0;
d3.geo.stream(object, d3_geo_length);
return d3_geo_lengthSum;
};
var d3_geo_lengthSum;
var d3_geo_length = {
sphere: d3_noop,
point: d3_noop,
lineStart: d3_geo_lengthLineStart,
lineEnd: d3_noop,
polygonStart: d3_noop,
polygonEnd: d3_noop
};
function d3_geo_lengthLineStart() {
var λ0, sinφ0, cosφ0;
d3_geo_length.point = function(λ, φ) {
λ0 = λ * d3_radians, sinφ0 = Math.sin(φ *= d3_radians), cosφ0 = Math.cos(φ);
d3_geo_length.point = nextPoint;
};
d3_geo_length.lineEnd = function() {
d3_geo_length.point = d3_geo_length.lineEnd = d3_noop;
};
function nextPoint(λ, φ) {
var sinφ = Math.sin(φ *= d3_radians),
cosφ = Math.cos(φ),
t = abs((λ *= d3_radians) - λ0),
cosΔλ = Math.cos(t);
d3_geo_lengthSum += Math.atan2(Math.sqrt((t = cosφ * Math.sin(t)) * t + (t = cosφ0 * sinφ - sinφ0 * cosφ * cosΔλ) * t), sinφ0 * sinφ + cosφ0 * cosφ * cosΔλ);
λ0 = λ, sinφ0 = sinφ, cosφ0 = cosφ;
}
}
function d3_identity(d) {
return d;
}
function d3_true() {
return true;
}
function d3_geo_spherical(cartesian) {
return [
Math.atan2(cartesian[1], cartesian[0]),
d3_asin(cartesian[2])
];
}
function d3_geo_sphericalEqual(a, b) {
return abs(a[0] - b[0]) < ε && abs(a[1] - b[1]) < ε;
}
// General spherical polygon clipping algorithm: takes a polygon, cuts it into
// visible line segments and rejoins the segments by interpolating along the
// clip edge.
function d3_geo_clipPolygon(segments, compare, clipStartInside, interpolate, listener) {
var subject = [],
clip = [];
segments.forEach(function(segment) {
if ((n = segment.length - 1) <= 0) return;
var n, p0 = segment[0], p1 = segment[n];
// If the first and last points of a segment are coincident, then treat as
// a closed ring.
// TODO if all rings are closed, then the winding order of the exterior
// ring should be checked.
if (d3_geo_sphericalEqual(p0, p1)) {
listener.lineStart();
for (var i = 0; i < n; ++i) listener.point((p0 = segment[i])[0], p0[1]);
listener.lineEnd();
return;
}
var a = new d3_geo_clipPolygonIntersection(p0, segment, null, true),
b = new d3_geo_clipPolygonIntersection(p0, null, a, false);
a.o = b;
subject.push(a);
clip.push(b);
a = new d3_geo_clipPolygonIntersection(p1, segment, null, false);
b = new d3_geo_clipPolygonIntersection(p1, null, a, true);
a.o = b;
subject.push(a);
clip.push(b);
});
clip.sort(compare);
d3_geo_clipPolygonLinkCircular(subject);
d3_geo_clipPolygonLinkCircular(clip);
if (!subject.length) return;
for (var i = 0, entry = clipStartInside, n = clip.length; i < n; ++i) {
clip[i].e = entry = !entry;
}
var start = subject[0],
points,
point;
while (1) {
// Find first unvisited intersection.
var current = start,
isSubject = true;
while (current.v) if ((current = current.n) === start) return;
points = current.z;
listener.lineStart();
do {
current.v = current.o.v = true;
if (current.e) {
if (isSubject) {
for (var i = 0, n = points.length; i < n; ++i) listener.point((point = points[i])[0], point[1]);
} else {
interpolate(current.x, current.n.x, 1, listener);
}
current = current.n;
} else {
if (isSubject) {
points = current.p.z;
for (var i = points.length - 1; i >= 0; --i) listener.point((point = points[i])[0], point[1]);
} else {
interpolate(current.x, current.p.x, -1, listener);
}
current = current.p;
}
current = current.o;
points = current.z;
isSubject = !isSubject;
} while (!current.v);
listener.lineEnd();
}
}
function d3_geo_clipPolygonLinkCircular(array) {
if (!(n = array.length)) return;
var n,
i = 0,
a = array[0],
b;
while (++i < n) {
a.n = b = array[i];
b.p = a;
a = b;
}
a.n = b = array[0];
b.p = a;
}
function d3_geo_clipPolygonIntersection(point, points, other, entry) {
this.x = point;
this.z = points;
this.o = other; // another intersection
this.e = entry; // is an entry?
this.v = false; // visited
this.n = this.p = null; // next & previous
}
function d3_geo_clip(pointVisible, clipLine, interpolate, clipStart) {
return function(rotate, listener) {
var line = clipLine(listener),
rotatedClipStart = rotate.invert(clipStart[0], clipStart[1]);
var clip = {
point: point,
lineStart: lineStart,
lineEnd: lineEnd,
polygonStart: function() {
clip.point = pointRing;
clip.lineStart = ringStart;
clip.lineEnd = ringEnd;
segments = [];
polygon = [];
},
polygonEnd: function() {
clip.point = point;
clip.lineStart = lineStart;
clip.lineEnd = lineEnd;
segments = d3.merge(segments);
var clipStartInside = d3_geo_pointInPolygon(rotatedClipStart, polygon);
if (segments.length) {
if (!polygonStarted) listener.polygonStart(), polygonStarted = true;
d3_geo_clipPolygon(segments, d3_geo_clipSort, clipStartInside, interpolate, listener);
} else if (clipStartInside) {
if (!polygonStarted) listener.polygonStart(), polygonStarted = true;
listener.lineStart();
interpolate(null, null, 1, listener);
listener.lineEnd();
}
if (polygonStarted) listener.polygonEnd(), polygonStarted = false;
segments = polygon = null;
},
sphere: function() {
listener.polygonStart();
listener.lineStart();
interpolate(null, null, 1, listener);
listener.lineEnd();
listener.polygonEnd();
}
};
function point(λ, φ) {
var point = rotate(λ, φ);
if (pointVisible(λ = point[0], φ = point[1])) listener.point(λ, φ);
}
function pointLine(λ, φ) {
var point = rotate(λ, φ);
line.point(point[0], point[1]);
}
function lineStart() { clip.point = pointLine; line.lineStart(); }
function lineEnd() { clip.point = point; line.lineEnd(); }
var segments;
var buffer = d3_geo_clipBufferListener(),
ringListener = clipLine(buffer),
polygonStarted = false,
polygon,
ring;
function pointRing(λ, φ) {
ring.push([λ, φ]);
var point = rotate(λ, φ);
ringListener.point(point[0], point[1]);
}
function ringStart() {
ringListener.lineStart();
ring = [];
}
function ringEnd() {
pointRing(ring[0][0], ring[0][1]);
ringListener.lineEnd();
var clean = ringListener.clean(),
ringSegments = buffer.buffer(),
segment,
n = ringSegments.length;
ring.pop();
polygon.push(ring);
ring = null;
if (!n) return;
// No intersections.
if (clean & 1) {
segment = ringSegments[0];
var n = segment.length - 1,
i = -1,
point;
if (n > 0) {
if (!polygonStarted) listener.polygonStart(), polygonStarted = true;
listener.lineStart();
while (++i < n) listener.point((point = segment[i])[0], point[1]);
listener.lineEnd();
}
return;
}
// Rejoin connected segments.
// TODO reuse bufferListener.rejoin()?
if (n > 1 && clean & 2) ringSegments.push(ringSegments.pop().concat(ringSegments.shift()));
segments.push(ringSegments.filter(d3_geo_clipSegmentLength1));
}
return clip;
};
}
function d3_geo_clipSegmentLength1(segment) {
return segment.length > 1;
}
function d3_geo_clipBufferListener() {
var lines = [],
line;
return {
lineStart: function() { lines.push(line = []); },
point: function(λ, φ) { line.push([λ, φ]); },
lineEnd: d3_noop,
buffer: function() {
var buffer = lines;
lines = [];
line = null;
return buffer;
},
rejoin: function() {
if (lines.length > 1) lines.push(lines.pop().concat(lines.shift()));
}
};
}
// Intersection points are sorted along the clip edge. For both antimeridian
// cutting and circle clipping, the same comparison is used.
function d3_geo_clipSort(a, b) {
return ((a = a.x)[0] < 0 ? a[1] - halfπ - ε : halfπ - a[1])
- ((b = b.x)[0] < 0 ? b[1] - halfπ - ε : halfπ - b[1]);
}
var d3_geo_clipAntimeridian = d3_geo_clip(
d3_true,
d3_geo_clipAntimeridianLine,
d3_geo_clipAntimeridianInterpolate,
[-π, -π / 2]);
// Takes a line and cuts into visible segments. Return values:
// 0: there were intersections or the line was empty.
// 1: no intersections.
// 2: there were intersections, and the first and last segments should be
// rejoined.
function d3_geo_clipAntimeridianLine(listener) {
var λ0 = NaN,
φ0 = NaN,
sλ0 = NaN,
clean; // no intersections
return {
lineStart: function() {
listener.lineStart();
clean = 1;
},
point: function(λ1, φ1) {
var sλ1 = λ1 > 0 ? π : -π,
= abs(λ1 - λ0);
if (abs( - π) < ε) { // line crosses a pole
listener.point(λ0, φ0 = (φ0 + φ1) / 2 > 0 ? halfπ : -halfπ);
listener.point(sλ0, φ0);
listener.lineEnd();
listener.lineStart();
listener.point(sλ1, φ0);
listener.point(λ1, φ0);
clean = 0;
} else if (sλ0 !== sλ1 && >= π) { // line crosses antimeridian
// handle degeneracies
if (abs(λ0 - sλ0) < ε) λ0 -= sλ0 * ε;
if (abs(λ1 - sλ1) < ε) λ1 -= sλ1 * ε;
φ0 = d3_geo_clipAntimeridianIntersect(λ0, φ0, λ1, φ1);
listener.point(sλ0, φ0);
listener.lineEnd();
listener.lineStart();
listener.point(sλ1, φ0);
clean = 0;
}
listener.point(λ0 = λ1, φ0 = φ1);
sλ0 = sλ1;
},
lineEnd: function() {
listener.lineEnd();
λ0 = φ0 = NaN;
},
// if there are intersections, we always rejoin the first and last segments.
clean: function() { return 2 - clean; }
};
}
function d3_geo_clipAntimeridianIntersect(λ0, φ0, λ1, φ1) {
var cosφ0,
cosφ1,
sinλ0_λ1 = Math.sin(λ0 - λ1);
return abs(sinλ0_λ1) > ε
? Math.atan((Math.sin(φ0) * (cosφ1 = Math.cos(φ1)) * Math.sin(λ1)
- Math.sin(φ1) * (cosφ0 = Math.cos(φ0)) * Math.sin(λ0))
/ (cosφ0 * cosφ1 * sinλ0_λ1))
: (φ0 + φ1) / 2;
}
function d3_geo_clipAntimeridianInterpolate(from, to, direction, listener) {
var φ;
if (from == null) {
φ = direction * halfπ;
listener.point(-π, φ);
listener.point( 0, φ);
listener.point( π, φ);
listener.point( π, 0);
listener.point( π, -φ);
listener.point( 0, -φ);
listener.point(-π, -φ);
listener.point(-π, 0);
listener.point(-π, φ);
} else if (abs(from[0] - to[0]) > ε) {
var s = from[0] < to[0] ? π : -π;
φ = direction * s / 2;
listener.point(-s, φ);
listener.point( 0, φ);
listener.point( s, φ);
} else {
listener.point(to[0], to[1]);
}
}
// TODO
// cross and scale return new vectors,
// whereas add and normalize operate in-place
function d3_geo_cartesian(spherical) {
var λ = spherical[0],
φ = spherical[1],
cosφ = Math.cos(φ);
return [
cosφ * Math.cos(λ),
cosφ * Math.sin(λ),
Math.sin(φ)
];
}
function d3_geo_cartesianDot(a, b) {
return a[0] * b[0] + a[1] * b[1] + a[2] * b[2];
}
function d3_geo_cartesianCross(a, b) {
return [
a[1] * b[2] - a[2] * b[1],
a[2] * b[0] - a[0] * b[2],
a[0] * b[1] - a[1] * b[0]
];
}
function d3_geo_cartesianAdd(a, b) {
a[0] += b[0];
a[1] += b[1];
a[2] += b[2];
}
function d3_geo_cartesianScale(vector, k) {
return [
vector[0] * k,
vector[1] * k,
vector[2] * k
];
}
function d3_geo_cartesianNormalize(d) {
var l = Math.sqrt(d[0] * d[0] + d[1] * d[1] + d[2] * d[2]);
d[0] /= l;
d[1] /= l;
d[2] /= l;
}
function d3_geo_compose(a, b) {
function compose(x, y) {
return x = a(x, y), b(x[0], x[1]);
}
if (a.invert && b.invert) compose.invert = function(x, y) {
return x = b.invert(x, y), x && a.invert(x[0], x[1]);
};
return compose;
}
function d3_geo_equirectangular(λ, φ) {
return [λ, φ];
}
(d3.geo.equirectangular = function() {
return d3_geo_projection(d3_geo_equirectangular);
}).raw = d3_geo_equirectangular.invert = d3_geo_equirectangular;
d3.geo.rotation = function(rotate) {
rotate = d3_geo_rotation(rotate[0] % 360 * d3_radians, rotate[1] * d3_radians, rotate.length > 2 ? rotate[2] * d3_radians : 0);
function forward(coordinates) {
coordinates = rotate(coordinates[0] * d3_radians, coordinates[1] * d3_radians);
return coordinates[0] *= d3_degrees, coordinates[1] *= d3_degrees, coordinates;
}
forward.invert = function(coordinates) {
coordinates = rotate.invert(coordinates[0] * d3_radians, coordinates[1] * d3_radians);
return coordinates[0] *= d3_degrees, coordinates[1] *= d3_degrees, coordinates;
};
return forward;
};
function d3_geo_identityRotation(λ, φ) {
return [λ > π ? λ - τ : λ < -π ? λ + τ : λ, φ];
}
d3_geo_identityRotation.invert = d3_geo_equirectangular;
// Note: |δλ| must be < 2π
function d3_geo_rotation(δλ, δφ, δγ) {
return δλ ? (δφ || δγ ? d3_geo_compose(d3_geo_rotationλ(δλ), d3_geo_rotationφγ(δφ, δγ))
: d3_geo_rotationλ(δλ))
: (δφ || δγ ? d3_geo_rotationφγ(δφ, δγ)
: d3_geo_identityRotation);
}
function d3_geo_forwardRotationλ(δλ) {
return function(λ, φ) {
return λ += δλ, [λ > π ? λ - τ : λ < -π ? λ + τ : λ, φ];
};
}
function d3_geo_rotationλ(δλ) {
var rotation = d3_geo_forwardRotationλ(δλ);
rotation.invert = d3_geo_forwardRotationλ(-δλ);
return rotation;
}
function d3_geo_rotationφγ(δφ, δγ) {
var cosδφ = Math.cos(δφ),
sinδφ = Math.sin(δφ),
cosδγ = Math.cos(δγ),
sinδγ = Math.sin(δγ);
function rotation(λ, φ) {
var cosφ = Math.cos(φ),
x = Math.cos(λ) * cosφ,
y = Math.sin(λ) * cosφ,
z = Math.sin(φ),
k = z * cosδφ + x * sinδφ;
return [
Math.atan2(y * cosδγ - k * sinδγ, x * cosδφ - z * sinδφ),
d3_asin(k * cosδγ + y * sinδγ)
];
}
rotation.invert = function(λ, φ) {
var cosφ = Math.cos(φ),
x = Math.cos(λ) * cosφ,
y = Math.sin(λ) * cosφ,
z = Math.sin(φ),
k = z * cosδγ - y * sinδγ;
return [
Math.atan2(y * cosδγ + z * sinδγ, x * cosδφ + k * sinδφ),
d3_asin(k * cosδφ - x * sinδφ)
];
};
return rotation;
}
d3.geo.circle = function() {
var origin = [0, 0],
angle,
precision = 6,
interpolate;
function circle() {
var center = typeof origin === "function" ? origin.apply(this, arguments) : origin,
rotate = d3_geo_rotation(-center[0] * d3_radians, -center[1] * d3_radians, 0).invert,
ring = [];
interpolate(null, null, 1, {
point: function(x, y) {
ring.push(x = rotate(x, y));
x[0] *= d3_degrees, x[1] *= d3_degrees;
}
});
return {type: "Polygon", coordinates: [ring]};
}
circle.origin = function(x) {
if (!arguments.length) return origin;
origin = x;
return circle;
};
circle.angle = function(x) {
if (!arguments.length) return angle;
interpolate = d3_geo_circleInterpolate((angle = +x) * d3_radians, precision * d3_radians);
return circle;
};
circle.precision = function(_) {
if (!arguments.length) return precision;
interpolate = d3_geo_circleInterpolate(angle * d3_radians, (precision = +_) * d3_radians);
return circle;
};
return circle.angle(90);
};
// Interpolates along a circle centered at [0°, 0°], with a given radius and
// precision.
function d3_geo_circleInterpolate(radius, precision) {
var cr = Math.cos(radius),
sr = Math.sin(radius);
return function(from, to, direction, listener) {
var step = direction * precision;
if (from != null) {
from = d3_geo_circleAngle(cr, from);
to = d3_geo_circleAngle(cr, to);
if (direction > 0 ? from < to: from > to) from += direction * τ;
} else {
from = radius + direction * τ;
to = radius - .5 * step;
}
for (var point, t = from; direction > 0 ? t > to : t < to; t -= step) {
listener.point((point = d3_geo_spherical([
cr,
-sr * Math.cos(t),
-sr * Math.sin(t)
]))[0], point[1]);
}
};
}
// Signed angle of a cartesian point relative to [cr, 0, 0].
function d3_geo_circleAngle(cr, point) {
var a = d3_geo_cartesian(point);
a[0] -= cr;
d3_geo_cartesianNormalize(a);
var angle = d3_acos(-a[1]);
return ((-a[2] < 0 ? -angle : angle) + 2 * Math.PI - ε) % (2 * Math.PI);
}
// Adds floating point numbers with twice the normal precision.
// Reference: J. R. Shewchuk, Adaptive Precision Floating-Point Arithmetic and
// Fast Robust Geometric Predicates, Discrete & Computational Geometry 18(3)
// 305363 (1997).
// Code adapted from GeographicLib by Charles F. F. Karney,
// http://geographiclib.sourceforge.net/
// See lib/geographiclib/LICENSE for details.
function d3_adder() {}
d3_adder.prototype = {
s: 0, // rounded value
t: 0, // exact error
add: function(y) {
d3_adderSum(y, this.t, d3_adderTemp);
d3_adderSum(d3_adderTemp.s, this.s, this);
if (this.s) this.t += d3_adderTemp.t;
else this.s = d3_adderTemp.t;
},
reset: function() {
this.s = this.t = 0;
},
valueOf: function() {
return this.s;
}
};
var d3_adderTemp = new d3_adder;
function d3_adderSum(a, b, o) {
var x = o.s = a + b, // a + b
bv = x - a, av = x - bv; // b_virtual & a_virtual
o.t = (a - av) + (b - bv); // a_roundoff + b_roundoff
}
d3.geo.area = function(object) {
d3_geo_areaSum = 0;
d3.geo.stream(object, d3_geo_area);
return d3_geo_areaSum;
};
var d3_geo_areaSum,
d3_geo_areaRingSum = new d3_adder;
var d3_geo_area = {
sphere: function() { d3_geo_areaSum += 4 * π; },
point: d3_noop,
lineStart: d3_noop,
lineEnd: d3_noop,
// Only count area for polygon rings.
polygonStart: function() {
d3_geo_areaRingSum.reset();
d3_geo_area.lineStart = d3_geo_areaRingStart;
},
polygonEnd: function() {
var area = 2 * d3_geo_areaRingSum;
d3_geo_areaSum += area < 0 ? 4 * π + area : area;
d3_geo_area.lineStart = d3_geo_area.lineEnd = d3_geo_area.point = d3_noop;
}
};
function d3_geo_areaRingStart() {
var λ00, φ00, λ0, cosφ0, sinφ0; // start point and previous point
// For the first point, …
d3_geo_area.point = function(λ, φ) {
d3_geo_area.point = nextPoint;
λ0 = (λ00 = λ) * d3_radians, cosφ0 = Math.cos(φ = (φ00 = φ) * d3_radians / 2 + π / 4), sinφ0 = Math.sin(φ);
};
// For subsequent points, …
function nextPoint(λ, φ) {
λ *= d3_radians;
φ = φ * d3_radians / 2 + π / 4; // half the angular distance from south pole
// Spherical excess E for a spherical triangle with vertices: south pole,
// previous point, current point. Uses a formula derived from Cagnolis
// theorem. See Todhunter, Spherical Trig. (1871), Sec. 103, Eq. (2).
var = λ - λ0,
sdλ = >= 0 ? 1 : -1,
adλ = sdλ * ,
cosφ = Math.cos(φ),
sinφ = Math.sin(φ),
k = sinφ0 * sinφ,
u = cosφ0 * cosφ + k * Math.cos(adλ),
v = k * sdλ * Math.sin(adλ);
d3_geo_areaRingSum.add(Math.atan2(v, u));
// Advance the previous points.
λ0 = λ, cosφ0 = cosφ, sinφ0 = sinφ;
}
// For the last point, return to the start.
d3_geo_area.lineEnd = function() {
nextPoint(λ00, φ00);
};
}
function d3_geo_pointInPolygon(point, polygon) {
var meridian = point[0],
parallel = point[1],
meridianNormal = [Math.sin(meridian), -Math.cos(meridian), 0],
polarAngle = 0,
winding = 0;
d3_geo_areaRingSum.reset();
for (var i = 0, n = polygon.length; i < n; ++i) {
var ring = polygon[i],
m = ring.length;
if (!m) continue;
var point0 = ring[0],
λ0 = point0[0],
φ0 = point0[1] / 2 + π / 4,
sinφ0 = Math.sin(φ0),
cosφ0 = Math.cos(φ0),
j = 1;
while (true) {
if (j === m) j = 0;
point = ring[j];
var λ = point[0],
φ = point[1] / 2 + π / 4,
sinφ = Math.sin(φ),
cosφ = Math.cos(φ),
= λ - λ0,
sdλ = >= 0 ? 1 : -1,
adλ = sdλ * ,
antimeridian = adλ > π,
k = sinφ0 * sinφ;
d3_geo_areaRingSum.add(Math.atan2(k * sdλ * Math.sin(adλ), cosφ0 * cosφ + k * Math.cos(adλ)));
polarAngle += antimeridian ? + sdλ * τ : ;
// Are the longitudes either side of the point's meridian, and are the
// latitudes smaller than the parallel?
if (antimeridian ^ λ0 >= meridian ^ λ >= meridian) {
var arc = d3_geo_cartesianCross(d3_geo_cartesian(point0), d3_geo_cartesian(point));
d3_geo_cartesianNormalize(arc);
var intersection = d3_geo_cartesianCross(meridianNormal, arc);
d3_geo_cartesianNormalize(intersection);
var φarc = (antimeridian ^ >= 0 ? -1 : 1) * d3_asin(intersection[2]);
if (parallel > φarc || parallel === φarc && (arc[0] || arc[1])) {
winding += antimeridian ^ >= 0 ? 1 : -1;
}
}
if (!j++) break;
λ0 = λ, sinφ0 = sinφ, cosφ0 = cosφ, point0 = point;
}
}
// First, determine whether the South pole is inside or outside:
//
// It is inside if:
// * the polygon winds around it in a clockwise direction.
// * the polygon does not (cumulatively) wind around it, but has a negative
// (counter-clockwise) area.
//
// Second, count the (signed) number of times a segment crosses a meridian
// from the point to the South pole. If it is zero, then the point is the
// same side as the South pole.
return (polarAngle < -ε || polarAngle < ε && d3_geo_areaRingSum < 0) ^ (winding & 1);
}
// Clip features against a small circle centered at [0°, 0°].
function d3_geo_clipCircle(radius) {
var cr = Math.cos(radius),
smallRadius = cr > 0,
notHemisphere = abs(cr) > ε, // TODO optimise for this common case
interpolate = d3_geo_circleInterpolate(radius, 6 * d3_radians);
return d3_geo_clip(visible, clipLine, interpolate, smallRadius ? [0, -radius] : [-π, radius - π]);
function visible(λ, φ) {
return Math.cos(λ) * Math.cos(φ) > cr;
}
// Takes a line and cuts into visible segments. Return values used for
// polygon clipping:
// 0: there were intersections or the line was empty.
// 1: no intersections.
// 2: there were intersections, and the first and last segments should be
// rejoined.
function clipLine(listener) {
var point0, // previous point
c0, // code for previous point
v0, // visibility of previous point
v00, // visibility of first point
clean; // no intersections
return {
lineStart: function() {
v00 = v0 = false;
clean = 1;
},
point: function(λ, φ) {
var point1 = [λ, φ],
point2,
v = visible(λ, φ),
c = smallRadius
? v ? 0 : code(λ, φ)
: v ? code(λ + (λ < 0 ? π : -π), φ) : 0;
if (!point0 && (v00 = v0 = v)) listener.lineStart();
// Handle degeneracies.
// TODO ignore if not clipping polygons.
if (v !== v0) {
point2 = intersect(point0, point1);
if (d3_geo_sphericalEqual(point0, point2) || d3_geo_sphericalEqual(point1, point2)) {
point1[0] += ε;
point1[1] += ε;
v = visible(point1[0], point1[1]);
}
}
if (v !== v0) {
clean = 0;
if (v) {
// outside going in
listener.lineStart();
point2 = intersect(point1, point0);
listener.point(point2[0], point2[1]);
} else {
// inside going out
point2 = intersect(point0, point1);
listener.point(point2[0], point2[1]);
listener.lineEnd();
}
point0 = point2;
} else if (notHemisphere && point0 && smallRadius ^ v) {
var t;
// If the codes for two points are different, or are both zero,
// and there this segment intersects with the small circle.
if (!(c & c0) && (t = intersect(point1, point0, true))) {
clean = 0;
if (smallRadius) {
listener.lineStart();
listener.point(t[0][0], t[0][1]);
listener.point(t[1][0], t[1][1]);
listener.lineEnd();
} else {
listener.point(t[1][0], t[1][1]);
listener.lineEnd();
listener.lineStart();
listener.point(t[0][0], t[0][1]);
}
}
}
if (v && (!point0 || !d3_geo_sphericalEqual(point0, point1))) {
listener.point(point1[0], point1[1]);
}
point0 = point1, v0 = v, c0 = c;
},
lineEnd: function() {
if (v0) listener.lineEnd();
point0 = null;
},
// Rejoin first and last segments if there were intersections and the first
// and last points were visible.
clean: function() { return clean | ((v00 && v0) << 1); }
};
}
// Intersects the great circle between a and b with the clip circle.
function intersect(a, b, two) {
var pa = d3_geo_cartesian(a),
pb = d3_geo_cartesian(b);
// We have two planes, n1.p = d1 and n2.p = d2.
// Find intersection line p(t) = c1 n1 + c2 n2 + t (n1 n2).
var n1 = [1, 0, 0], // normal
n2 = d3_geo_cartesianCross(pa, pb),
n2n2 = d3_geo_cartesianDot(n2, n2),
n1n2 = n2[0], // d3_geo_cartesianDot(n1, n2),
determinant = n2n2 - n1n2 * n1n2;
// Two polar points.
if (!determinant) return !two && a;
var c1 = cr * n2n2 / determinant,
c2 = -cr * n1n2 / determinant,
n1xn2 = d3_geo_cartesianCross(n1, n2),
A = d3_geo_cartesianScale(n1, c1),
B = d3_geo_cartesianScale(n2, c2);
d3_geo_cartesianAdd(A, B);
// Solve |p(t)|^2 = 1.
var u = n1xn2,
w = d3_geo_cartesianDot(A, u),
uu = d3_geo_cartesianDot(u, u),
t2 = w * w - uu * (d3_geo_cartesianDot(A, A) - 1);
if (t2 < 0) return;
var t = Math.sqrt(t2),
q = d3_geo_cartesianScale(u, (-w - t) / uu);
d3_geo_cartesianAdd(q, A);
q = d3_geo_spherical(q);
if (!two) return q;
// Two intersection points.
var λ0 = a[0],
λ1 = b[0],
φ0 = a[1],
φ1 = b[1],
z;
if (λ1 < λ0) z = λ0, λ0 = λ1, λ1 = z;
var δλ = λ1 - λ0,
polar = abs(δλ - π) < ε,
meridian = polar || δλ < ε;
if (!polar && φ1 < φ0) z = φ0, φ0 = φ1, φ1 = z;
// Check that the first point is between a and b.
if (meridian
? polar
? φ0 + φ1 > 0 ^ q[1] < (abs(q[0] - λ0) < ε ? φ0 : φ1)
: φ0 <= q[1] && q[1] <= φ1
: δλ > π ^ (λ0 <= q[0] && q[0] <= λ1)) {
var q1 = d3_geo_cartesianScale(u, (-w + t) / uu);
d3_geo_cartesianAdd(q1, A);
return [q, d3_geo_spherical(q1)];
}
}
// Generates a 4-bit vector representing the location of a point relative to
// the small circle's bounding box.
function code(λ, φ) {
var r = smallRadius ? radius : π - radius,
code = 0;
if (λ < -r) code |= 1; // left
else if (λ > r) code |= 2; // right
if (φ < -r) code |= 4; // below
else if (φ > r) code |= 8; // above
return code;
}
}
// LiangBarsky line clipping.
function d3_geom_clipLine(x0, y0, x1, y1) {
return function(line) {
var a = line.a,
b = line.b,
ax = a.x,
ay = a.y,
bx = b.x,
by = b.y,
t0 = 0,
t1 = 1,
dx = bx - ax,
dy = by - ay,
r;
r = x0 - ax;
if (!dx && r > 0) return;
r /= dx;
if (dx < 0) {
if (r < t0) return;
if (r < t1) t1 = r;
} else if (dx > 0) {
if (r > t1) return;
if (r > t0) t0 = r;
}
r = x1 - ax;
if (!dx && r < 0) return;
r /= dx;
if (dx < 0) {
if (r > t1) return;
if (r > t0) t0 = r;
} else if (dx > 0) {
if (r < t0) return;
if (r < t1) t1 = r;
}
r = y0 - ay;
if (!dy && r > 0) return;
r /= dy;
if (dy < 0) {
if (r < t0) return;
if (r < t1) t1 = r;
} else if (dy > 0) {
if (r > t1) return;
if (r > t0) t0 = r;
}
r = y1 - ay;
if (!dy && r < 0) return;
r /= dy;
if (dy < 0) {
if (r > t1) return;
if (r > t0) t0 = r;
} else if (dy > 0) {
if (r < t0) return;
if (r < t1) t1 = r;
}
if (t0 > 0) line.a = {x: ax + t0 * dx, y: ay + t0 * dy};
if (t1 < 1) line.b = {x: ax + t1 * dx, y: ay + t1 * dy};
return line;
};
}
var d3_geo_clipExtentMAX = 1e9;
d3.geo.clipExtent = function() {
var x0, y0, x1, y1,
stream,
clip,
clipExtent = {
stream: function(output) {
if (stream) stream.valid = false;
stream = clip(output);
stream.valid = true; // allow caching by d3.geo.path
return stream;
},
extent: function(_) {
if (!arguments.length) return [[x0, y0], [x1, y1]];
clip = d3_geo_clipExtent(x0 = +_[0][0], y0 = +_[0][1], x1 = +_[1][0], y1 = +_[1][1]);
if (stream) stream.valid = false, stream = null;
return clipExtent;
}
};
return clipExtent.extent([[0, 0], [960, 500]]);
};
function d3_geo_clipExtent(x0, y0, x1, y1) {
return function(listener) {
var listener_ = listener,
bufferListener = d3_geo_clipBufferListener(),
clipLine = d3_geom_clipLine(x0, y0, x1, y1),
segments,
polygon,
ring;
var clip = {
point: point,
lineStart: lineStart,
lineEnd: lineEnd,
polygonStart: function() {
listener = bufferListener;
segments = [];
polygon = [];
clean = true;
},
polygonEnd: function() {
listener = listener_;
segments = d3.merge(segments);
var clipStartInside = insidePolygon([x0, y1]),
inside = clean && clipStartInside,
visible = segments.length;
if (inside || visible) {
listener.polygonStart();
if (inside) {
listener.lineStart();
interpolate(null, null, 1, listener);
listener.lineEnd();
}
if (visible) {
d3_geo_clipPolygon(segments, compare, clipStartInside, interpolate, listener);
}
listener.polygonEnd();
}
segments = polygon = ring = null;
}
};
function insidePolygon(p) {
var wn = 0, // the winding number counter
n = polygon.length,
y = p[1];
for (var i = 0; i < n; ++i) {
for (var j = 1, v = polygon[i], m = v.length, a = v[0], b; j < m; ++j) {
b = v[j];
if (a[1] <= y) {
if (b[1] > y && d3_cross2d(a, b, p) > 0) ++wn;
} else {
if (b[1] <= y && d3_cross2d(a, b, p) < 0) --wn;
}
a = b;
}
}
return wn !== 0;
}
function interpolate(from, to, direction, listener) {
var a = 0, a1 = 0;
if (from == null ||
(a = corner(from, direction)) !== (a1 = corner(to, direction)) ||
comparePoints(from, to) < 0 ^ direction > 0) {
do {
listener.point(a === 0 || a === 3 ? x0 : x1, a > 1 ? y1 : y0);
} while ((a = (a + direction + 4) % 4) !== a1);
} else {
listener.point(to[0], to[1]);
}
}
function pointVisible(x, y) {
return x0 <= x && x <= x1 && y0 <= y && y <= y1;
}
function point(x, y) {
if (pointVisible(x, y)) listener.point(x, y);
}
var x__, y__, v__, // first point
x_, y_, v_, // previous point
first,
clean;
function lineStart() {
clip.point = linePoint;
if (polygon) polygon.push(ring = []);
first = true;
v_ = false;
x_ = y_ = NaN;
}
function lineEnd() {
// TODO rather than special-case polygons, simply handle them separately.
// Ideally, coincident intersection points should be jittered to avoid
// clipping issues.
if (segments) {
linePoint(x__, y__);
if (v__ && v_) bufferListener.rejoin();
segments.push(bufferListener.buffer());
}
clip.point = point;
if (v_) listener.lineEnd();
}
function linePoint(x, y) {
x = Math.max(-d3_geo_clipExtentMAX, Math.min(d3_geo_clipExtentMAX, x));
y = Math.max(-d3_geo_clipExtentMAX, Math.min(d3_geo_clipExtentMAX, y));
var v = pointVisible(x, y);
if (polygon) ring.push([x, y]);
if (first) {
x__ = x, y__ = y, v__ = v;
first = false;
if (v) {
listener.lineStart();
listener.point(x, y);
}
} else {
if (v && v_) listener.point(x, y);
else {
var l = {a: {x: x_, y: y_}, b: {x: x, y: y}};
if (clipLine(l)) {
if (!v_) {
listener.lineStart();
listener.point(l.a.x, l.a.y);
}
listener.point(l.b.x, l.b.y);
if (!v) listener.lineEnd();
clean = false;
} else if (v) {
listener.lineStart();
listener.point(x, y);
clean = false;
}
}
}
x_ = x, y_ = y, v_ = v;
}
return clip;
};
function corner(p, direction) {
return abs(p[0] - x0) < ε ? direction > 0 ? 0 : 3
: abs(p[0] - x1) < ε ? direction > 0 ? 2 : 1
: abs(p[1] - y0) < ε ? direction > 0 ? 1 : 0
: direction > 0 ? 3 : 2; // abs(p[1] - y1) < ε
}
function compare(a, b) {
return comparePoints(a.x, b.x);
}
function comparePoints(a, b) {
var ca = corner(a, 1),
cb = corner(b, 1);
return ca !== cb ? ca - cb
: ca === 0 ? b[1] - a[1]
: ca === 1 ? a[0] - b[0]
: ca === 2 ? a[1] - b[1]
: b[0] - a[0];
}
}
function d3_geo_conic(projectAt) {
var φ0 = 0,
φ1 = π / 3,
m = d3_geo_projectionMutator(projectAt),
p = m(φ0, φ1);
p.parallels = function(_) {
if (!arguments.length) return [φ0 / π * 180, φ1 / π * 180];
return m(φ0 = _[0] * π / 180, φ1 = _[1] * π / 180);
};
return p;
}
function d3_geo_conicEqualArea(φ0, φ1) {
var sinφ0 = Math.sin(φ0),
n = (sinφ0 + Math.sin(φ1)) / 2,
C = 1 + sinφ0 * (2 * n - sinφ0),
ρ0 = Math.sqrt(C) / n;
function forward(λ, φ) {
var ρ = Math.sqrt(C - 2 * n * Math.sin(φ)) / n;
return [
ρ * Math.sin(λ *= n),
ρ0 - ρ * Math.cos(λ)
];
}
forward.invert = function(x, y) {
var ρ0_y = ρ0 - y;
return [
Math.atan2(x, ρ0_y) / n,
d3_asin((C - (x * x + ρ0_y * ρ0_y) * n * n) / (2 * n))
];
};
return forward;
}
(d3.geo.conicEqualArea = function() {
return d3_geo_conic(d3_geo_conicEqualArea);
}).raw = d3_geo_conicEqualArea;
// ESRI:102003
d3.geo.albers = function() {
return d3.geo.conicEqualArea()
.rotate([96, 0])
.center([-.6, 38.7])
.parallels([29.5, 45.5])
.scale(1070);
};
// A composite projection for the United States, configured by default for
// 960×500. Also works quite well at 960×600 with scale 1285. The set of
// standard parallels for each region comes from USGS, which is published here:
// http://egsc.usgs.gov/isb/pubs/MapProjections/projections.html#albers
d3.geo.albersUsa = function() {
var lower48 = d3.geo.albers();
// EPSG:3338
var alaska = d3.geo.conicEqualArea()
.rotate([154, 0])
.center([-2, 58.5])
.parallels([55, 65]);
// ESRI:102007
var hawaii = d3.geo.conicEqualArea()
.rotate([157, 0])
.center([-3, 19.9])
.parallels([8, 18]);
var point,
pointStream = {point: function(x, y) { point = [x, y]; }},
lower48Point,
alaskaPoint,
hawaiiPoint;
function albersUsa(coordinates) {
var x = coordinates[0], y = coordinates[1];
point = null;
(lower48Point(x, y), point)
|| (alaskaPoint(x, y), point)
|| hawaiiPoint(x, y);
return point;
}
albersUsa.invert = function(coordinates) {
var k = lower48.scale(),
t = lower48.translate(),
x = (coordinates[0] - t[0]) / k,
y = (coordinates[1] - t[1]) / k;
return (y >= .120 && y < .234 && x >= -.425 && x < -.214 ? alaska
: y >= .166 && y < .234 && x >= -.214 && x < -.115 ? hawaii
: lower48).invert(coordinates);
};
// A naïve multi-projection stream.
// The projections must have mutually exclusive clip regions on the sphere,
// as this will avoid emitting interleaving lines and polygons.
albersUsa.stream = function(stream) {
var lower48Stream = lower48.stream(stream),
alaskaStream = alaska.stream(stream),
hawaiiStream = hawaii.stream(stream);
return {
point: function(x, y) {
lower48Stream.point(x, y);
alaskaStream.point(x, y);
hawaiiStream.point(x, y);
},
sphere: function() {
lower48Stream.sphere();
alaskaStream.sphere();
hawaiiStream.sphere();
},
lineStart: function() {
lower48Stream.lineStart();
alaskaStream.lineStart();
hawaiiStream.lineStart();
},
lineEnd: function() {
lower48Stream.lineEnd();
alaskaStream.lineEnd();
hawaiiStream.lineEnd();
},
polygonStart: function() {
lower48Stream.polygonStart();
alaskaStream.polygonStart();
hawaiiStream.polygonStart();
},
polygonEnd: function() {
lower48Stream.polygonEnd();
alaskaStream.polygonEnd();
hawaiiStream.polygonEnd();
}
};
};
albersUsa.precision = function(_) {
if (!arguments.length) return lower48.precision();
lower48.precision(_);
alaska.precision(_);
hawaii.precision(_);
return albersUsa;
};
albersUsa.scale = function(_) {
if (!arguments.length) return lower48.scale();
lower48.scale(_);
alaska.scale(_ * .35);
hawaii.scale(_);
return albersUsa.translate(lower48.translate());
};
albersUsa.translate = function(_) {
if (!arguments.length) return lower48.translate();
var k = lower48.scale(), x = +_[0], y = +_[1];
lower48Point = lower48
.translate(_)
.clipExtent([[x - .455 * k, y - .238 * k], [x + .455 * k, y + .238 * k]])
.stream(pointStream).point;
alaskaPoint = alaska
.translate([x - .307 * k, y + .201 * k])
.clipExtent([[x - .425 * k + ε, y + .120 * k + ε], [x - .214 * k - ε, y + .234 * k - ε]])
.stream(pointStream).point;
hawaiiPoint = hawaii
.translate([x - .205 * k, y + .212 * k])
.clipExtent([[x - .214 * k + ε, y + .166 * k + ε], [x - .115 * k - ε, y + .234 * k - ε]])
.stream(pointStream).point;
return albersUsa;
};
return albersUsa.scale(1070);
};
d3.geo.bounds = (function() {
var λ0, φ0, λ1, φ1, // bounds
λ_, // previous λ-coordinate
λ__, φ__, // first point
p0, // previous 3D point
dλSum,
ranges,
range;
var bound = {
point: point,
lineStart: lineStart,
lineEnd: lineEnd,
polygonStart: function() {
bound.point = ringPoint;
bound.lineStart = ringStart;
bound.lineEnd = ringEnd;
dλSum = 0;
d3_geo_area.polygonStart();
},
polygonEnd: function() {
d3_geo_area.polygonEnd();
bound.point = point;
bound.lineStart = lineStart;
bound.lineEnd = lineEnd;
if (d3_geo_areaRingSum < 0) λ0 = -(λ1 = 180), φ0 = -(φ1 = 90);
else if (dλSum > ε) φ1 = 90;
else if (dλSum < -ε) φ0 = -90;
range[0] = λ0, range[1] = λ1;
}
};
function point(λ, φ) {
ranges.push(range = [λ0 = λ, λ1 = λ]);
if (φ < φ0) φ0 = φ;
if (φ > φ1) φ1 = φ;
}
function linePoint(λ, φ) {
var p = d3_geo_cartesian([λ * d3_radians, φ * d3_radians]);
if (p0) {
var normal = d3_geo_cartesianCross(p0, p),
equatorial = [normal[1], -normal[0], 0],
inflection = d3_geo_cartesianCross(equatorial, normal);
d3_geo_cartesianNormalize(inflection);
inflection = d3_geo_spherical(inflection);
var = λ - λ_,
s = > 0 ? 1 : -1,
λi = inflection[0] * d3_degrees * s,
antimeridian = abs() > 180;
if (antimeridian ^ (s * λ_ < λi && λi < s * λ)) {
var φi = inflection[1] * d3_degrees;
if (φi > φ1) φ1 = φi;
} else if (λi = (λi + 360) % 360 - 180, antimeridian ^ (s * λ_ < λi && λi < s * λ)) {
var φi = -inflection[1] * d3_degrees;
if (φi < φ0) φ0 = φi;
} else {
if (φ < φ0) φ0 = φ;
if (φ > φ1) φ1 = φ;
}
if (antimeridian) {
if (λ < λ_) {
if (angle(λ0, λ) > angle(λ0, λ1)) λ1 = λ;
} else {
if (angle(λ, λ1) > angle(λ0, λ1)) λ0 = λ;
}
} else {
if (λ1 >= λ0) {
if (λ < λ0) λ0 = λ;
if (λ > λ1) λ1 = λ;
} else {
if (λ > λ_) {
if (angle(λ0, λ) > angle(λ0, λ1)) λ1 = λ;
} else {
if (angle(λ, λ1) > angle(λ0, λ1)) λ0 = λ;
}
}
}
} else {
point(λ, φ);
}
p0 = p, λ_ = λ;
}
function lineStart() { bound.point = linePoint; }
function lineEnd() {
range[0] = λ0, range[1] = λ1;
bound.point = point;
p0 = null;
}
function ringPoint(λ, φ) {
if (p0) {
var = λ - λ_;
dλSum += abs() > 180 ? + ( > 0 ? 360 : -360) : ;
} else λ__ = λ, φ__ = φ;
d3_geo_area.point(λ, φ);
linePoint(λ, φ);
}
function ringStart() {
d3_geo_area.lineStart();
}
function ringEnd() {
ringPoint(λ__, φ__);
d3_geo_area.lineEnd();
if (abs(dλSum) > ε) λ0 = -(λ1 = 180);
range[0] = λ0, range[1] = λ1;
p0 = null;
}
// Finds the left-right distance between two longitudes.
// This is almost the same as (λ1 - λ0 + 360°) % 360°, except that we want
// the distance between ±180° to be 360°.
function angle(λ0, λ1) { return (λ1 -= λ0) < 0 ? λ1 + 360 : λ1; }
function compareRanges(a, b) { return a[0] - b[0]; }
function withinRange(x, range) {
return range[0] <= range[1] ? range[0] <= x && x <= range[1] : x < range[0] || range[1] < x;
}
return function(feature) {
φ1 = λ1 = -(λ0 = φ0 = Infinity);
ranges = [];
d3.geo.stream(feature, bound);
var n = ranges.length;
if (n) {
// First, sort ranges by their minimum longitudes.
ranges.sort(compareRanges);
// Then, merge any ranges that overlap.
for (var i = 1, a = ranges[0], b, merged = [a]; i < n; ++i) {
b = ranges[i];
if (withinRange(b[0], a) || withinRange(b[1], a)) {
if (angle(a[0], b[1]) > angle(a[0], a[1])) a[1] = b[1];
if (angle(b[0], a[1]) > angle(a[0], a[1])) a[0] = b[0];
} else {
merged.push(a = b);
}
}
// Finally, find the largest gap between the merged ranges.
// The final bounding box will be the inverse of this gap.
var best = -Infinity, ;
for (var n = merged.length - 1, i = 0, a = merged[n], b; i <= n; a = b, ++i) {
b = merged[i];
if (( = angle(a[1], b[0])) > best) best = , λ0 = b[0], λ1 = a[1];
}
}
ranges = range = null;
return λ0 === Infinity || φ0 === Infinity
? [[NaN, NaN], [NaN, NaN]]
: [[λ0, φ0], [λ1, φ1]];
};
})();
d3.geo.centroid = function(object) {
d3_geo_centroidW0 = d3_geo_centroidW1 =
d3_geo_centroidX0 = d3_geo_centroidY0 = d3_geo_centroidZ0 =
d3_geo_centroidX1 = d3_geo_centroidY1 = d3_geo_centroidZ1 =
d3_geo_centroidX2 = d3_geo_centroidY2 = d3_geo_centroidZ2 = 0;
d3.geo.stream(object, d3_geo_centroid);
var x = d3_geo_centroidX2,
y = d3_geo_centroidY2,
z = d3_geo_centroidZ2,
m = x * x + y * y + z * z;
// If the area-weighted centroid is undefined, fall back to length-weighted centroid.
if (m < ε2) {
x = d3_geo_centroidX1, y = d3_geo_centroidY1, z = d3_geo_centroidZ1;
// If the feature has zero length, fall back to arithmetic mean of point vectors.
if (d3_geo_centroidW1 < ε) x = d3_geo_centroidX0, y = d3_geo_centroidY0, z = d3_geo_centroidZ0;
m = x * x + y * y + z * z;
// If the feature still has an undefined centroid, then return.
if (m < ε2) return [NaN, NaN];
}
return [Math.atan2(y, x) * d3_degrees, d3_asin(z / Math.sqrt(m)) * d3_degrees];
};
var d3_geo_centroidW0,
d3_geo_centroidW1,
d3_geo_centroidX0,
d3_geo_centroidY0,
d3_geo_centroidZ0,
d3_geo_centroidX1,
d3_geo_centroidY1,
d3_geo_centroidZ1,
d3_geo_centroidX2,
d3_geo_centroidY2,
d3_geo_centroidZ2;
var d3_geo_centroid = {
sphere: d3_noop,
point: d3_geo_centroidPoint,
lineStart: d3_geo_centroidLineStart,
lineEnd: d3_geo_centroidLineEnd,
polygonStart: function() {
d3_geo_centroid.lineStart = d3_geo_centroidRingStart;
},
polygonEnd: function() {
d3_geo_centroid.lineStart = d3_geo_centroidLineStart;
}
};
// Arithmetic mean of Cartesian vectors.
function d3_geo_centroidPoint(λ, φ) {
λ *= d3_radians;
var cosφ = Math.cos(φ *= d3_radians);
d3_geo_centroidPointXYZ(cosφ * Math.cos(λ), cosφ * Math.sin(λ), Math.sin(φ));
}
function d3_geo_centroidPointXYZ(x, y, z) {
++d3_geo_centroidW0;
d3_geo_centroidX0 += (x - d3_geo_centroidX0) / d3_geo_centroidW0;
d3_geo_centroidY0 += (y - d3_geo_centroidY0) / d3_geo_centroidW0;
d3_geo_centroidZ0 += (z - d3_geo_centroidZ0) / d3_geo_centroidW0;
}
function d3_geo_centroidLineStart() {
var x0, y0, z0; // previous point
d3_geo_centroid.point = function(λ, φ) {
λ *= d3_radians;
var cosφ = Math.cos(φ *= d3_radians);
x0 = cosφ * Math.cos(λ);
y0 = cosφ * Math.sin(λ);
z0 = Math.sin(φ);
d3_geo_centroid.point = nextPoint;
d3_geo_centroidPointXYZ(x0, y0, z0);
};
function nextPoint(λ, φ) {
λ *= d3_radians;
var cosφ = Math.cos(φ *= d3_radians),
x = cosφ * Math.cos(λ),
y = cosφ * Math.sin(λ),
z = Math.sin(φ),
w = Math.atan2(
Math.sqrt((w = y0 * z - z0 * y) * w + (w = z0 * x - x0 * z) * w + (w = x0 * y - y0 * x) * w),
x0 * x + y0 * y + z0 * z);
d3_geo_centroidW1 += w;
d3_geo_centroidX1 += w * (x0 + (x0 = x));
d3_geo_centroidY1 += w * (y0 + (y0 = y));
d3_geo_centroidZ1 += w * (z0 + (z0 = z));
d3_geo_centroidPointXYZ(x0, y0, z0);
}
}
function d3_geo_centroidLineEnd() {
d3_geo_centroid.point = d3_geo_centroidPoint;
}
// See J. E. Brock, The Inertia Tensor for a Spherical Triangle,
// J. Applied Mechanics 42, 239 (1975).
function d3_geo_centroidRingStart() {
var λ00, φ00, // first point
x0, y0, z0; // previous point
d3_geo_centroid.point = function(λ, φ) {
λ00 = λ, φ00 = φ;
d3_geo_centroid.point = nextPoint;
λ *= d3_radians;
var cosφ = Math.cos(φ *= d3_radians);
x0 = cosφ * Math.cos(λ);
y0 = cosφ * Math.sin(λ);
z0 = Math.sin(φ);
d3_geo_centroidPointXYZ(x0, y0, z0);
};
d3_geo_centroid.lineEnd = function() {
nextPoint(λ00, φ00);
d3_geo_centroid.lineEnd = d3_geo_centroidLineEnd;
d3_geo_centroid.point = d3_geo_centroidPoint;
};
function nextPoint(λ, φ) {
λ *= d3_radians;
var cosφ = Math.cos(φ *= d3_radians),
x = cosφ * Math.cos(λ),
y = cosφ * Math.sin(λ),
z = Math.sin(φ),
cx = y0 * z - z0 * y,
cy = z0 * x - x0 * z,
cz = x0 * y - y0 * x,
m = Math.sqrt(cx * cx + cy * cy + cz * cz),
u = x0 * x + y0 * y + z0 * z,
v = m && -d3_acos(u) / m, // area weight
w = Math.atan2(m, u); // line weight
d3_geo_centroidX2 += v * cx;
d3_geo_centroidY2 += v * cy;
d3_geo_centroidZ2 += v * cz;
d3_geo_centroidW1 += w;
d3_geo_centroidX1 += w * (x0 + (x0 = x));
d3_geo_centroidY1 += w * (y0 + (y0 = y));
d3_geo_centroidZ1 += w * (z0 + (z0 = z));
d3_geo_centroidPointXYZ(x0, y0, z0);
}
}
// TODO Unify this code with d3.geom.polygon area?
var d3_geo_pathAreaSum, d3_geo_pathAreaPolygon, d3_geo_pathArea = {
point: d3_noop,
lineStart: d3_noop,
lineEnd: d3_noop,
// Only count area for polygon rings.
polygonStart: function() {
d3_geo_pathAreaPolygon = 0;
d3_geo_pathArea.lineStart = d3_geo_pathAreaRingStart;
},
polygonEnd: function() {
d3_geo_pathArea.lineStart = d3_geo_pathArea.lineEnd = d3_geo_pathArea.point = d3_noop;
d3_geo_pathAreaSum += abs(d3_geo_pathAreaPolygon / 2);
}
};
function d3_geo_pathAreaRingStart() {
var x00, y00, x0, y0;
// For the first point, …
d3_geo_pathArea.point = function(x, y) {
d3_geo_pathArea.point = nextPoint;
x00 = x0 = x, y00 = y0 = y;
};
// For subsequent points, …
function nextPoint(x, y) {
d3_geo_pathAreaPolygon += y0 * x - x0 * y;
x0 = x, y0 = y;
}
// For the last point, return to the start.
d3_geo_pathArea.lineEnd = function() {
nextPoint(x00, y00);
};
}
var d3_geo_pathBoundsX0,
d3_geo_pathBoundsY0,
d3_geo_pathBoundsX1,
d3_geo_pathBoundsY1;
var d3_geo_pathBounds = {
point: d3_geo_pathBoundsPoint,
lineStart: d3_noop,
lineEnd: d3_noop,
polygonStart: d3_noop,
polygonEnd: d3_noop
};
function d3_geo_pathBoundsPoint(x, y) {
if (x < d3_geo_pathBoundsX0) d3_geo_pathBoundsX0 = x;
if (x > d3_geo_pathBoundsX1) d3_geo_pathBoundsX1 = x;
if (y < d3_geo_pathBoundsY0) d3_geo_pathBoundsY0 = y;
if (y > d3_geo_pathBoundsY1) d3_geo_pathBoundsY1 = y;
}
function d3_geo_pathBuffer() {
var pointCircle = d3_geo_pathBufferCircle(4.5),
buffer = [];
var stream = {
point: point,
// While inside a line, override point to moveTo then lineTo.
lineStart: function() { stream.point = pointLineStart; },
lineEnd: lineEnd,
// While inside a polygon, override lineEnd to closePath.
polygonStart: function() { stream.lineEnd = lineEndPolygon; },
polygonEnd: function() { stream.lineEnd = lineEnd; stream.point = point; },
pointRadius: function(_) {
pointCircle = d3_geo_pathBufferCircle(_);
return stream;
},
result: function() {
if (buffer.length) {
var result = buffer.join("");
buffer = [];
return result;
}
}
};
function point(x, y) {
buffer.push("M", x, ",", y, pointCircle);
}
function pointLineStart(x, y) {
buffer.push("M", x, ",", y);
stream.point = pointLine;
}
function pointLine(x, y) {
buffer.push("L", x, ",", y);
}
function lineEnd() {
stream.point = point;
}
function lineEndPolygon() {
buffer.push("Z");
}
return stream;
}
function d3_geo_pathBufferCircle(radius) {
return "m0," + radius
+ "a" + radius + "," + radius + " 0 1,1 0," + -2 * radius
+ "a" + radius + "," + radius + " 0 1,1 0," + 2 * radius
+ "z";
}
// TODO Unify this code with d3.geom.polygon centroid?
// TODO Enforce positive area for exterior, negative area for interior?
var d3_geo_pathCentroid = {
point: d3_geo_pathCentroidPoint,
// For lines, weight by length.
lineStart: d3_geo_pathCentroidLineStart,
lineEnd: d3_geo_pathCentroidLineEnd,
// For polygons, weight by area.
polygonStart: function() {
d3_geo_pathCentroid.lineStart = d3_geo_pathCentroidRingStart;
},
polygonEnd: function() {
d3_geo_pathCentroid.point = d3_geo_pathCentroidPoint;
d3_geo_pathCentroid.lineStart = d3_geo_pathCentroidLineStart;
d3_geo_pathCentroid.lineEnd = d3_geo_pathCentroidLineEnd;
}
};
function d3_geo_pathCentroidPoint(x, y) {
d3_geo_centroidX0 += x;
d3_geo_centroidY0 += y;
++d3_geo_centroidZ0;
}
function d3_geo_pathCentroidLineStart() {
var x0, y0;
d3_geo_pathCentroid.point = function(x, y) {
d3_geo_pathCentroid.point = nextPoint;
d3_geo_pathCentroidPoint(x0 = x, y0 = y);
};
function nextPoint(x, y) {
var dx = x - x0, dy = y - y0, z = Math.sqrt(dx * dx + dy * dy);
d3_geo_centroidX1 += z * (x0 + x) / 2;
d3_geo_centroidY1 += z * (y0 + y) / 2;
d3_geo_centroidZ1 += z;
d3_geo_pathCentroidPoint(x0 = x, y0 = y);
}
}
function d3_geo_pathCentroidLineEnd() {
d3_geo_pathCentroid.point = d3_geo_pathCentroidPoint;
}
function d3_geo_pathCentroidRingStart() {
var x00, y00, x0, y0;
// For the first point, …
d3_geo_pathCentroid.point = function(x, y) {
d3_geo_pathCentroid.point = nextPoint;
d3_geo_pathCentroidPoint(x00 = x0 = x, y00 = y0 = y);
};
// For subsequent points, …
function nextPoint(x, y) {
var dx = x - x0, dy = y - y0, z = Math.sqrt(dx * dx + dy * dy);
d3_geo_centroidX1 += z * (x0 + x) / 2;
d3_geo_centroidY1 += z * (y0 + y) / 2;
d3_geo_centroidZ1 += z;
z = y0 * x - x0 * y;
d3_geo_centroidX2 += z * (x0 + x);
d3_geo_centroidY2 += z * (y0 + y);
d3_geo_centroidZ2 += z * 3;
d3_geo_pathCentroidPoint(x0 = x, y0 = y);
}
// For the last point, return to the start.
d3_geo_pathCentroid.lineEnd = function() {
nextPoint(x00, y00);
};
}
function d3_geo_pathContext(context) {
var pointRadius = 4.5;
var stream = {
point: point,
// While inside a line, override point to moveTo then lineTo.
lineStart: function() { stream.point = pointLineStart; },
lineEnd: lineEnd,
// While inside a polygon, override lineEnd to closePath.
polygonStart: function() { stream.lineEnd = lineEndPolygon; },
polygonEnd: function() { stream.lineEnd = lineEnd; stream.point = point; },
pointRadius: function(_) {
pointRadius = _;
return stream;
},
result: d3_noop
};
function point(x, y) {
context.moveTo(x + pointRadius, y);
context.arc(x, y, pointRadius, 0, τ);
}
function pointLineStart(x, y) {
context.moveTo(x, y);
stream.point = pointLine;
}
function pointLine(x, y) {
context.lineTo(x, y);
}
function lineEnd() {
stream.point = point;
}
function lineEndPolygon() {
context.closePath();
}
return stream;
}
function d3_geo_resample(project) {
var δ2 = .5, // precision, px²
cosMinDistance = Math.cos(30 * d3_radians), // cos(minimum angular distance)
maxDepth = 16;
function resample(stream) {
return (maxDepth ? resampleRecursive : resampleNone)(stream);
}
function resampleNone(stream) {
return d3_geo_transformPoint(stream, function(x, y) {
x = project(x, y);
stream.point(x[0], x[1]);
});
}
function resampleRecursive(stream) {
var λ00, φ00, x00, y00, a00, b00, c00, // first point
λ0, x0, y0, a0, b0, c0; // previous point
var resample = {
point: point,
lineStart: lineStart,
lineEnd: lineEnd,
polygonStart: function() { stream.polygonStart(); resample.lineStart = ringStart; },
polygonEnd: function() { stream.polygonEnd(); resample.lineStart = lineStart; }
};
function point(x, y) {
x = project(x, y);
stream.point(x[0], x[1]);
}
function lineStart() {
x0 = NaN;
resample.point = linePoint;
stream.lineStart();
}
function linePoint(λ, φ) {
var c = d3_geo_cartesian([λ, φ]), p = project(λ, φ);
resampleLineTo(x0, y0, λ0, a0, b0, c0, x0 = p[0], y0 = p[1], λ0 = λ, a0 = c[0], b0 = c[1], c0 = c[2], maxDepth, stream);
stream.point(x0, y0);
}
function lineEnd() {
resample.point = point;
stream.lineEnd();
}
function ringStart() {
lineStart();
resample.point = ringPoint;
resample.lineEnd = ringEnd;
}
function ringPoint(λ, φ) {
linePoint(λ00 = λ, φ00 = φ), x00 = x0, y00 = y0, a00 = a0, b00 = b0, c00 = c0;
resample.point = linePoint;
}
function ringEnd() {
resampleLineTo(x0, y0, λ0, a0, b0, c0, x00, y00, λ00, a00, b00, c00, maxDepth, stream);
resample.lineEnd = lineEnd;
lineEnd();
}
return resample;
}
function resampleLineTo(x0, y0, λ0, a0, b0, c0, x1, y1, λ1, a1, b1, c1, depth, stream) {
var dx = x1 - x0,
dy = y1 - y0,
d2 = dx * dx + dy * dy;
if (d2 > 4 * δ2 && depth--) {
var a = a0 + a1,
b = b0 + b1,
c = c0 + c1,
m = Math.sqrt(a * a + b * b + c * c),
φ2 = Math.asin(c /= m),
λ2 = abs(abs(c) - 1) < ε || abs(λ0 - λ1) < ε ? (λ0 + λ1) / 2 : Math.atan2(b, a),
p = project(λ2, φ2),
x2 = p[0],
y2 = p[1],
dx2 = x2 - x0,
dy2 = y2 - y0,
dz = dy * dx2 - dx * dy2;
if (dz * dz / d2 > δ2 // perpendicular projected distance
|| abs((dx * dx2 + dy * dy2) / d2 - .5) > .3 // midpoint close to an end
|| a0 * a1 + b0 * b1 + c0 * c1 < cosMinDistance) { // angular distance
resampleLineTo(x0, y0, λ0, a0, b0, c0, x2, y2, λ2, a /= m, b /= m, c, depth, stream);
stream.point(x2, y2);
resampleLineTo(x2, y2, λ2, a, b, c, x1, y1, λ1, a1, b1, c1, depth, stream);
}
}
}
resample.precision = function(_) {
if (!arguments.length) return Math.sqrt(δ2);
maxDepth = (δ2 = _ * _) > 0 && 16;
return resample;
};
return resample;
}
d3.geo.path = function() {
var pointRadius = 4.5,
projection,
context,
projectStream,
contextStream,
cacheStream;
function path(object) {
if (object) {
if (typeof pointRadius === "function") contextStream.pointRadius(+pointRadius.apply(this, arguments));
if (!cacheStream || !cacheStream.valid) cacheStream = projectStream(contextStream);
d3.geo.stream(object, cacheStream);
}
return contextStream.result();
}
path.area = function(object) {
d3_geo_pathAreaSum = 0;
d3.geo.stream(object, projectStream(d3_geo_pathArea));
return d3_geo_pathAreaSum;
};
path.centroid = function(object) {
d3_geo_centroidX0 = d3_geo_centroidY0 = d3_geo_centroidZ0 =
d3_geo_centroidX1 = d3_geo_centroidY1 = d3_geo_centroidZ1 =
d3_geo_centroidX2 = d3_geo_centroidY2 = d3_geo_centroidZ2 = 0;
d3.geo.stream(object, projectStream(d3_geo_pathCentroid));
return d3_geo_centroidZ2 ? [d3_geo_centroidX2 / d3_geo_centroidZ2, d3_geo_centroidY2 / d3_geo_centroidZ2]
: d3_geo_centroidZ1 ? [d3_geo_centroidX1 / d3_geo_centroidZ1, d3_geo_centroidY1 / d3_geo_centroidZ1]
: d3_geo_centroidZ0 ? [d3_geo_centroidX0 / d3_geo_centroidZ0, d3_geo_centroidY0 / d3_geo_centroidZ0]
: [NaN, NaN];
};
path.bounds = function(object) {
d3_geo_pathBoundsX1 = d3_geo_pathBoundsY1 = -(d3_geo_pathBoundsX0 = d3_geo_pathBoundsY0 = Infinity);
d3.geo.stream(object, projectStream(d3_geo_pathBounds));
return [[d3_geo_pathBoundsX0, d3_geo_pathBoundsY0], [d3_geo_pathBoundsX1, d3_geo_pathBoundsY1]];
};
path.projection = function(_) {
if (!arguments.length) return projection;
projectStream = (projection = _) ? _.stream || d3_geo_pathProjectStream(_) : d3_identity;
return reset();
};
path.context = function(_) {
if (!arguments.length) return context;
contextStream = (context = _) == null ? new d3_geo_pathBuffer : new d3_geo_pathContext(_);
if (typeof pointRadius !== "function") contextStream.pointRadius(pointRadius);
return reset();
};
path.pointRadius = function(_) {
if (!arguments.length) return pointRadius;
pointRadius = typeof _ === "function" ? _ : (contextStream.pointRadius(+_), +_);
return path;
};
function reset() {
cacheStream = null;
return path;
}
return path.projection(d3.geo.albersUsa()).context(null);
};
function d3_geo_pathProjectStream(project) {
var resample = d3_geo_resample(function(x, y) { return project([x * d3_degrees, y * d3_degrees]); });
return function(stream) { return d3_geo_projectionRadians(resample(stream)); };
}
d3.geo.transform = function(methods) {
return {
stream: function(stream) {
var transform = new d3_geo_transform(stream);
for (var k in methods) transform[k] = methods[k];
return transform;
}
};
};
function d3_geo_transform(stream) {
this.stream = stream;
}
d3_geo_transform.prototype = {
point: function(x, y) { this.stream.point(x, y); },
sphere: function() { this.stream.sphere(); },
lineStart: function() { this.stream.lineStart(); },
lineEnd: function() { this.stream.lineEnd(); },
polygonStart: function() { this.stream.polygonStart(); },
polygonEnd: function() { this.stream.polygonEnd(); }
};
function d3_geo_transformPoint(stream, point) {
return {
point: point,
sphere: function() { stream.sphere(); },
lineStart: function() { stream.lineStart(); },
lineEnd: function() { stream.lineEnd(); },
polygonStart: function() { stream.polygonStart(); },
polygonEnd: function() { stream.polygonEnd(); },
};
}
d3.geo.projection = d3_geo_projection;
d3.geo.projectionMutator = d3_geo_projectionMutator;
function d3_geo_projection(project) {
return d3_geo_projectionMutator(function() { return project; })();
}
function d3_geo_projectionMutator(projectAt) {
var project,
rotate,
projectRotate,
projectResample = d3_geo_resample(function(x, y) { x = project(x, y); return [x[0] * k + δx, δy - x[1] * k]; }),
k = 150, // scale
x = 480, y = 250, // translate
λ = 0, φ = 0, // center
δλ = 0, δφ = 0, δγ = 0, // rotate
δx, δy, // center
preclip = d3_geo_clipAntimeridian,
postclip = d3_identity,
clipAngle = null,
clipExtent = null,
stream;
function projection(point) {
point = projectRotate(point[0] * d3_radians, point[1] * d3_radians);
return [point[0] * k + δx, δy - point[1] * k];
}
function invert(point) {
point = projectRotate.invert((point[0] - δx) / k, (δy - point[1]) / k);
return point && [point[0] * d3_degrees, point[1] * d3_degrees];
}
projection.stream = function(output) {
if (stream) stream.valid = false;
stream = d3_geo_projectionRadians(preclip(rotate, projectResample(postclip(output))));
stream.valid = true; // allow caching by d3.geo.path
return stream;
};
projection.clipAngle = function(_) {
if (!arguments.length) return clipAngle;
preclip = _ == null ? (clipAngle = _, d3_geo_clipAntimeridian) : d3_geo_clipCircle((clipAngle = +_) * d3_radians);
return invalidate();
};
projection.clipExtent = function(_) {
if (!arguments.length) return clipExtent;
clipExtent = _;
postclip = _ ? d3_geo_clipExtent(_[0][0], _[0][1], _[1][0], _[1][1]) : d3_identity;
return invalidate();
};
projection.scale = function(_) {
if (!arguments.length) return k;
k = +_;
return reset();
};
projection.translate = function(_) {
if (!arguments.length) return [x, y];
x = +_[0];
y = +_[1];
return reset();
};
projection.center = function(_) {
if (!arguments.length) return [λ * d3_degrees, φ * d3_degrees];
λ = _[0] % 360 * d3_radians;
φ = _[1] % 360 * d3_radians;
return reset();
};
projection.rotate = function(_) {
if (!arguments.length) return [δλ * d3_degrees, δφ * d3_degrees, δγ * d3_degrees];
δλ = _[0] % 360 * d3_radians;
δφ = _[1] % 360 * d3_radians;
δγ = _.length > 2 ? _[2] % 360 * d3_radians : 0;
return reset();
};
d3.rebind(projection, projectResample, "precision");
function reset() {
projectRotate = d3_geo_compose(rotate = d3_geo_rotation(δλ, δφ, δγ), project);
var center = project(λ, φ);
δx = x - center[0] * k;
δy = y + center[1] * k;
return invalidate();
}
function invalidate() {
if (stream) stream.valid = false, stream = null;
return projection;
}
return function() {
project = projectAt.apply(this, arguments);
projection.invert = project.invert && invert;
return reset();
};
}
function d3_geo_projectionRadians(stream) {
return d3_geo_transformPoint(stream, function(x, y) {
stream.point(x * d3_radians, y * d3_radians);
});
}
function d3_geo_mercator(λ, φ) {
return [λ, Math.log(Math.tan(π / 4 + φ / 2))];
}
d3_geo_mercator.invert = function(x, y) {
return [x, 2 * Math.atan(Math.exp(y)) - halfπ];
};
function d3_geo_mercatorProjection(project) {
var m = d3_geo_projection(project),
scale = m.scale,
translate = m.translate,
clipExtent = m.clipExtent,
clipAuto;
m.scale = function() {
var v = scale.apply(m, arguments);
return v === m ? (clipAuto ? m.clipExtent(null) : m) : v;
};
m.translate = function() {
var v = translate.apply(m, arguments);
return v === m ? (clipAuto ? m.clipExtent(null) : m) : v;
};
m.clipExtent = function(_) {
var v = clipExtent.apply(m, arguments);
if (v === m) {
if (clipAuto = _ == null) {
var k = π * scale(), t = translate();
clipExtent([[t[0] - k, t[1] - k], [t[0] + k, t[1] + k]]);
}
} else if (clipAuto) {
v = null;
}
return v;
};
return m.clipExtent(null);
}
(d3.geo.mercator = function() {
return d3_geo_mercatorProjection(d3_geo_mercator);
}).raw = d3_geo_mercator;
d3.geom = {};
d3.geom.polygon = function(coordinates) {
d3_subclass(coordinates, d3_geom_polygonPrototype);
return coordinates;
};
var d3_geom_polygonPrototype = d3.geom.polygon.prototype = [];
d3_geom_polygonPrototype.area = function() {
var i = -1,
n = this.length,
a,
b = this[n - 1],
area = 0;
while (++i < n) {
a = b;
b = this[i];
area += a[1] * b[0] - a[0] * b[1];
}
return area * .5;
};
d3_geom_polygonPrototype.centroid = function(k) {
var i = -1,
n = this.length,
x = 0,
y = 0,
a,
b = this[n - 1],
c;
if (!arguments.length) k = -1 / (6 * this.area());
while (++i < n) {
a = b;
b = this[i];
c = a[0] * b[1] - b[0] * a[1];
x += (a[0] + b[0]) * c;
y += (a[1] + b[1]) * c;
}
return [x * k, y * k];
};
// The Sutherland-Hodgman clipping algorithm.
// Note: requires the clip polygon to be counterclockwise and convex.
d3_geom_polygonPrototype.clip = function(subject) {
var input,
closed = d3_geom_polygonClosed(subject),
i = -1,
n = this.length - d3_geom_polygonClosed(this),
j,
m,
a = this[n - 1],
b,
c,
d;
while (++i < n) {
input = subject.slice();
subject.length = 0;
b = this[i];
c = input[(m = input.length - closed) - 1];
j = -1;
while (++j < m) {
d = input[j];
if (d3_geom_polygonInside(d, a, b)) {
if (!d3_geom_polygonInside(c, a, b)) {
subject.push(d3_geom_polygonIntersect(c, d, a, b));
}
subject.push(d);
} else if (d3_geom_polygonInside(c, a, b)) {
subject.push(d3_geom_polygonIntersect(c, d, a, b));
}
c = d;
}
if (closed) subject.push(subject[0]);
a = b;
}
return subject;
};
function d3_geom_polygonInside(p, a, b) {
return (b[0] - a[0]) * (p[1] - a[1]) < (b[1] - a[1]) * (p[0] - a[0]);
}
// Intersect two infinite lines cd and ab.
function d3_geom_polygonIntersect(c, d, a, b) {
var x1 = c[0], x3 = a[0], x21 = d[0] - x1, x43 = b[0] - x3,
y1 = c[1], y3 = a[1], y21 = d[1] - y1, y43 = b[1] - y3,
ua = (x43 * (y1 - y3) - y43 * (x1 - x3)) / (y43 * x21 - x43 * y21);
return [x1 + ua * x21, y1 + ua * y21];
}
// Returns true if the polygon is closed.
function d3_geom_polygonClosed(coordinates) {
var a = coordinates[0],
b = coordinates[coordinates.length - 1];
return !(a[0] - b[0] || a[1] - b[1]);
}
function d3_geom_pointX(d) {
return d[0];
}
function d3_geom_pointY(d) {
return d[1];
}
/**
* Computes the 2D convex hull of a set of points using the monotone chain
* algorithm:
* http://en.wikibooks.org/wiki/Algorithm_Implementation/Geometry/Convex_hull/Monotone_chain)
*
* The runtime of this algorithm is O(n log n), where n is the number of input
* points. However in practice it outperforms other O(n log n) hulls.
*
* @param vertices [[x1, y1], [x2, y2], ...]
* @returns polygon [[x1, y1], [x2, y2], ...]
*/
d3.geom.hull = function(vertices) {
var x = d3_geom_pointX,
y = d3_geom_pointY;
if (arguments.length) return hull(vertices);
function hull(data) {
// Hull of < 3 points is not well-defined
if (data.length < 3) return [];
var fx = d3_functor(x),
fy = d3_functor(y),
i,
n = data.length,
points = [], // of the form [[x0, y0, 0], ..., [xn, yn, n]]
flippedPoints = [];
for (i = 0 ; i < n; i++) {
points.push([+fx.call(this, data[i], i), +fy.call(this, data[i], i), i]);
}
// sort ascending by x-coord first, y-coord second
points.sort(d3_geom_hullOrder);
// we flip bottommost points across y axis so we can use the upper hull routine on both
for (i = 0; i < n; i++) flippedPoints.push([points[i][0], -points[i][1]]);
var upper = d3_geom_hullUpper(points),
lower = d3_geom_hullUpper(flippedPoints);
// construct the polygon, removing possible duplicate endpoints
var skipLeft = lower[0] === upper[0],
skipRight = lower[lower.length - 1] === upper[upper.length - 1],
polygon = [];
// add upper hull in r->l order
// then add lower hull in l->r order
for (i = upper.length - 1; i >= 0; --i) polygon.push(data[points[upper[i]][2]]);
for (i = +skipLeft; i < lower.length - skipRight; ++i) polygon.push(data[points[lower[i]][2]]);
return polygon;
}
hull.x = function(_) {
return arguments.length ? (x = _, hull) : x;
};
hull.y = function(_) {
return arguments.length ? (y = _, hull) : y;
};
return hull;
};
// finds the 'upper convex hull' (see wiki link above)
// assumes points arg has >=3 elements, is sorted by x, unique in y
// returns array of indices into points in left to right order
function d3_geom_hullUpper(points) {
var n = points.length,
hull = [0, 1],
hs = 2; // hull size
for (var i = 2; i < n; i++) {
while (hs > 1 && d3_cross2d(points[hull[hs-2]], points[hull[hs-1]], points[i]) <= 0) --hs;
hull[hs++] = i;
}
// we slice to make sure that the points we 'popped' from hull don't stay behind
return hull.slice(0, hs);
}
// comparator for ascending sort by x-coord first, y-coord second
function d3_geom_hullOrder(a, b) {
return a[0] - b[0] || a[1] - b[1];
}
// import "../transition/transition";
d3_selectionPrototype.transition = function(name) {
var id = d3_transitionInheritId || ++d3_transitionId,
ns = d3_transitionNamespace(name),
subgroups = [],
subgroup,
node,
transition = d3_transitionInherit || {time: Date.now(), ease: d3_ease_cubicInOut, delay: 0, duration: 250};
for (var j = -1, m = this.length; ++j < m;) {
subgroups.push(subgroup = []);
for (var group = this[j], i = -1, n = group.length; ++i < n;) {
if (node = group[i]) d3_transitionNode(node, i, ns, id, transition);
subgroup.push(node);
}
}
return d3_transition(subgroups, ns, id);
};
// import "../transition/transition";
// TODO Interrupt transitions for all namespaces?
d3_selectionPrototype.interrupt = function(name) {
return this.each(name == null
? d3_selection_interrupt
: d3_selection_interruptNS(d3_transitionNamespace(name)));
};
var d3_selection_interrupt = d3_selection_interruptNS(d3_transitionNamespace());
function d3_selection_interruptNS(ns) {
return function() {
var lock, active;
if ((lock = this[ns]) && (active = lock[lock.active])) {
if (--lock.count) delete lock[lock.active];
else delete this[ns];
lock.active += .5;
active.event && active.event.interrupt.call(this, this.__data__, active.index);
}
};
}
function d3_transition(groups, ns, id) {
d3_subclass(groups, d3_transitionPrototype);
// Note: read-only!
groups.namespace = ns;
groups.id = id;
return groups;
}
var d3_transitionPrototype = [],
d3_transitionId = 0,
d3_transitionInheritId,
d3_transitionInherit;
d3_transitionPrototype.call = d3_selectionPrototype.call;
d3_transitionPrototype.empty = d3_selectionPrototype.empty;
d3_transitionPrototype.node = d3_selectionPrototype.node;
d3_transitionPrototype.size = d3_selectionPrototype.size;
d3.transition = function(selection, name) {
return selection && selection.transition
? (d3_transitionInheritId ? selection.transition(name) : selection)
: d3.selection().transition(selection);
};
d3.transition.prototype = d3_transitionPrototype;
d3_transitionPrototype.select = function(selector) {
var id = this.id,
ns = this.namespace,
subgroups = [],
subgroup,
subnode,
node;
selector = d3_selection_selector(selector);
for (var j = -1, m = this.length; ++j < m;) {
subgroups.push(subgroup = []);
for (var group = this[j], i = -1, n = group.length; ++i < n;) {
if ((node = group[i]) && (subnode = selector.call(node, node.__data__, i, j))) {
if ("__data__" in node) subnode.__data__ = node.__data__;
d3_transitionNode(subnode, i, ns, id, node[ns][id]);
subgroup.push(subnode);
} else {
subgroup.push(null);
}
}
}
return d3_transition(subgroups, ns, id);
};
d3_transitionPrototype.selectAll = function(selector) {
var id = this.id,
ns = this.namespace,
subgroups = [],
subgroup,
subnodes,
node,
subnode,
transition;
selector = d3_selection_selectorAll(selector);
for (var j = -1, m = this.length; ++j < m;) {
for (var group = this[j], i = -1, n = group.length; ++i < n;) {
if (node = group[i]) {
transition = node[ns][id];
subnodes = selector.call(node, node.__data__, i, j);
subgroups.push(subgroup = []);
for (var k = -1, o = subnodes.length; ++k < o;) {
if (subnode = subnodes[k]) d3_transitionNode(subnode, k, ns, id, transition);
subgroup.push(subnode);
}
}
}
}
return d3_transition(subgroups, ns, id);
};
d3_transitionPrototype.filter = function(filter) {
var subgroups = [],
subgroup,
group,
node;
if (typeof filter !== "function") filter = d3_selection_filter(filter);
for (var j = 0, m = this.length; j < m; j++) {
subgroups.push(subgroup = []);
for (var group = this[j], i = 0, n = group.length; i < n; i++) {
if ((node = group[i]) && filter.call(node, node.__data__, i, j)) {
subgroup.push(node);
}
}
}
return d3_transition(subgroups, this.namespace, this.id);
};
d3.color = d3_color;
function d3_color() {}
d3_color.prototype.toString = function() {
return this.rgb() + "";
};
d3.hsl = d3_hsl;
function d3_hsl(h, s, l) {
return this instanceof d3_hsl ? void (this.h = +h, this.s = +s, this.l = +l)
: arguments.length < 2 ? (h instanceof d3_hsl ? new d3_hsl(h.h, h.s, h.l)
: d3_rgb_parse("" + h, d3_rgb_hsl, d3_hsl))
: new d3_hsl(h, s, l);
}
var d3_hslPrototype = d3_hsl.prototype = new d3_color;
d3_hslPrototype.brighter = function(k) {
k = Math.pow(0.7, arguments.length ? k : 1);
return new d3_hsl(this.h, this.s, this.l / k);
};
d3_hslPrototype.darker = function(k) {
k = Math.pow(0.7, arguments.length ? k : 1);
return new d3_hsl(this.h, this.s, k * this.l);
};
d3_hslPrototype.rgb = function() {
return d3_hsl_rgb(this.h, this.s, this.l);
};
function d3_hsl_rgb(h, s, l) {
var m1,
m2;
/* Some simple corrections for h, s and l. */
h = isNaN(h) ? 0 : (h %= 360) < 0 ? h + 360 : h;
s = isNaN(s) ? 0 : s < 0 ? 0 : s > 1 ? 1 : s;
l = l < 0 ? 0 : l > 1 ? 1 : l;
/* From FvD 13.37, CSS Color Module Level 3 */
m2 = l <= .5 ? l * (1 + s) : l + s - l * s;
m1 = 2 * l - m2;
function v(h) {
if (h > 360) h -= 360;
else if (h < 0) h += 360;
if (h < 60) return m1 + (m2 - m1) * h / 60;
if (h < 180) return m2;
if (h < 240) return m1 + (m2 - m1) * (240 - h) / 60;
return m1;
}
function vv(h) {
return Math.round(v(h) * 255);
}
return new d3_rgb(vv(h + 120), vv(h), vv(h - 120));
}
d3.hcl = d3_hcl;
function d3_hcl(h, c, l) {
return this instanceof d3_hcl ? void (this.h = +h, this.c = +c, this.l = +l)
: arguments.length < 2 ? (h instanceof d3_hcl ? new d3_hcl(h.h, h.c, h.l)
: (h instanceof d3_lab ? d3_lab_hcl(h.l, h.a, h.b)
: d3_lab_hcl((h = d3_rgb_lab((h = d3.rgb(h)).r, h.g, h.b)).l, h.a, h.b)))
: new d3_hcl(h, c, l);
}
var d3_hclPrototype = d3_hcl.prototype = new d3_color;
d3_hclPrototype.brighter = function(k) {
return new d3_hcl(this.h, this.c, Math.min(100, this.l + d3_lab_K * (arguments.length ? k : 1)));
};
d3_hclPrototype.darker = function(k) {
return new d3_hcl(this.h, this.c, Math.max(0, this.l - d3_lab_K * (arguments.length ? k : 1)));
};
d3_hclPrototype.rgb = function() {
return d3_hcl_lab(this.h, this.c, this.l).rgb();
};
function d3_hcl_lab(h, c, l) {
if (isNaN(h)) h = 0;
if (isNaN(c)) c = 0;
return new d3_lab(l, Math.cos(h *= d3_radians) * c, Math.sin(h) * c);
}
d3.lab = d3_lab;
function d3_lab(l, a, b) {
return this instanceof d3_lab ? void (this.l = +l, this.a = +a, this.b = +b)
: arguments.length < 2 ? (l instanceof d3_lab ? new d3_lab(l.l, l.a, l.b)
: (l instanceof d3_hcl ? d3_hcl_lab(l.h, l.c, l.l)
: d3_rgb_lab((l = d3_rgb(l)).r, l.g, l.b)))
: new d3_lab(l, a, b);
}
// Corresponds roughly to RGB brighter/darker
var d3_lab_K = 18;
// D65 standard referent
var d3_lab_X = 0.950470,
d3_lab_Y = 1,
d3_lab_Z = 1.088830;
var d3_labPrototype = d3_lab.prototype = new d3_color;
d3_labPrototype.brighter = function(k) {
return new d3_lab(Math.min(100, this.l + d3_lab_K * (arguments.length ? k : 1)), this.a, this.b);
};
d3_labPrototype.darker = function(k) {
return new d3_lab(Math.max(0, this.l - d3_lab_K * (arguments.length ? k : 1)), this.a, this.b);
};
d3_labPrototype.rgb = function() {
return d3_lab_rgb(this.l, this.a, this.b);
};
function d3_lab_rgb(l, a, b) {
var y = (l + 16) / 116,
x = y + a / 500,
z = y - b / 200;
x = d3_lab_xyz(x) * d3_lab_X;
y = d3_lab_xyz(y) * d3_lab_Y;
z = d3_lab_xyz(z) * d3_lab_Z;
return new d3_rgb(
d3_xyz_rgb( 3.2404542 * x - 1.5371385 * y - 0.4985314 * z),
d3_xyz_rgb(-0.9692660 * x + 1.8760108 * y + 0.0415560 * z),
d3_xyz_rgb( 0.0556434 * x - 0.2040259 * y + 1.0572252 * z)
);
}
function d3_lab_hcl(l, a, b) {
return l > 0
? new d3_hcl(Math.atan2(b, a) * d3_degrees, Math.sqrt(a * a + b * b), l)
: new d3_hcl(NaN, NaN, l);
}
function d3_lab_xyz(x) {
return x > 0.206893034 ? x * x * x : (x - 4 / 29) / 7.787037;
}
function d3_xyz_lab(x) {
return x > 0.008856 ? Math.pow(x, 1 / 3) : 7.787037 * x + 4 / 29;
}
function d3_xyz_rgb(r) {
return Math.round(255 * (r <= 0.00304 ? 12.92 * r : 1.055 * Math.pow(r, 1 / 2.4) - 0.055));
}
d3.rgb = d3_rgb;
function d3_rgb(r, g, b) {
return this instanceof d3_rgb ? void (this.r = ~~r, this.g = ~~g, this.b = ~~b)
: arguments.length < 2 ? (r instanceof d3_rgb ? new d3_rgb(r.r, r.g, r.b)
: d3_rgb_parse("" + r, d3_rgb, d3_hsl_rgb))
: new d3_rgb(r, g, b);
}
function d3_rgbNumber(value) {
return new d3_rgb(value >> 16, value >> 8 & 0xff, value & 0xff);
}
function d3_rgbString(value) {
return d3_rgbNumber(value) + "";
}
var d3_rgbPrototype = d3_rgb.prototype = new d3_color;
d3_rgbPrototype.brighter = function(k) {
k = Math.pow(0.7, arguments.length ? k : 1);
var r = this.r,
g = this.g,
b = this.b,
i = 30;
if (!r && !g && !b) return new d3_rgb(i, i, i);
if (r && r < i) r = i;
if (g && g < i) g = i;
if (b && b < i) b = i;
return new d3_rgb(Math.min(255, r / k), Math.min(255, g / k), Math.min(255, b / k));
};
d3_rgbPrototype.darker = function(k) {
k = Math.pow(0.7, arguments.length ? k : 1);
return new d3_rgb(k * this.r, k * this.g, k * this.b);
};
d3_rgbPrototype.hsl = function() {
return d3_rgb_hsl(this.r, this.g, this.b);
};
d3_rgbPrototype.toString = function() {
return "#" + d3_rgb_hex(this.r) + d3_rgb_hex(this.g) + d3_rgb_hex(this.b);
};
function d3_rgb_hex(v) {
return v < 0x10
? "0" + Math.max(0, v).toString(16)
: Math.min(255, v).toString(16);
}
function d3_rgb_parse(format, rgb, hsl) {
var r = 0, // red channel; int in [0, 255]
g = 0, // green channel; int in [0, 255]
b = 0, // blue channel; int in [0, 255]
m1, // CSS color specification match
m2, // CSS color specification type (e.g., rgb)
color;
/* Handle hsl, rgb. */
m1 = /([a-z]+)\((.*)\)/i.exec(format);
if (m1) {
m2 = m1[2].split(",");
switch (m1[1]) {
case "hsl": {
return hsl(
parseFloat(m2[0]), // degrees
parseFloat(m2[1]) / 100, // percentage
parseFloat(m2[2]) / 100 // percentage
);
}
case "rgb": {
return rgb(
d3_rgb_parseNumber(m2[0]),
d3_rgb_parseNumber(m2[1]),
d3_rgb_parseNumber(m2[2])
);
}
}
}
/* Named colors. */
if (color = d3_rgb_names.get(format.toLowerCase())) {
return rgb(color.r, color.g, color.b);
}
/* Hexadecimal colors: #rgb and #rrggbb. */
if (format != null && format.charAt(0) === "#" && !isNaN(color = parseInt(format.slice(1), 16))) {
if (format.length === 4) {
r = (color & 0xf00) >> 4; r = (r >> 4) | r;
g = (color & 0xf0); g = (g >> 4) | g;
b = (color & 0xf); b = (b << 4) | b;
} else if (format.length === 7) {
r = (color & 0xff0000) >> 16;
g = (color & 0xff00) >> 8;
b = (color & 0xff);
}
}
return rgb(r, g, b);
}
function d3_rgb_hsl(r, g, b) {
var min = Math.min(r /= 255, g /= 255, b /= 255),
max = Math.max(r, g, b),
d = max - min,
h,
s,
l = (max + min) / 2;
if (d) {
s = l < .5 ? d / (max + min) : d / (2 - max - min);
if (r == max) h = (g - b) / d + (g < b ? 6 : 0);
else if (g == max) h = (b - r) / d + 2;
else h = (r - g) / d + 4;
h *= 60;
} else {
h = NaN;
s = l > 0 && l < 1 ? 0 : h;
}
return new d3_hsl(h, s, l);
}
function d3_rgb_lab(r, g, b) {
r = d3_rgb_xyz(r);
g = d3_rgb_xyz(g);
b = d3_rgb_xyz(b);
var x = d3_xyz_lab((0.4124564 * r + 0.3575761 * g + 0.1804375 * b) / d3_lab_X),
y = d3_xyz_lab((0.2126729 * r + 0.7151522 * g + 0.0721750 * b) / d3_lab_Y),
z = d3_xyz_lab((0.0193339 * r + 0.1191920 * g + 0.9503041 * b) / d3_lab_Z);
return d3_lab(116 * y - 16, 500 * (x - y), 200 * (y - z));
}
function d3_rgb_xyz(r) {
return (r /= 255) <= 0.04045 ? r / 12.92 : Math.pow((r + 0.055) / 1.055, 2.4);
}
function d3_rgb_parseNumber(c) { // either integer or percentage
var f = parseFloat(c);
return c.charAt(c.length - 1) === "%" ? Math.round(f * 2.55) : f;
}
var d3_rgb_names = d3.map({
aliceblue: 0xf0f8ff,
antiquewhite: 0xfaebd7,
aqua: 0x00ffff,
aquamarine: 0x7fffd4,
azure: 0xf0ffff,
beige: 0xf5f5dc,
bisque: 0xffe4c4,
black: 0x000000,
blanchedalmond: 0xffebcd,
blue: 0x0000ff,
blueviolet: 0x8a2be2,
brown: 0xa52a2a,
burlywood: 0xdeb887,
cadetblue: 0x5f9ea0,
chartreuse: 0x7fff00,
chocolate: 0xd2691e,
coral: 0xff7f50,
cornflowerblue: 0x6495ed,
cornsilk: 0xfff8dc,
crimson: 0xdc143c,
cyan: 0x00ffff,
darkblue: 0x00008b,
darkcyan: 0x008b8b,
darkgoldenrod: 0xb8860b,
darkgray: 0xa9a9a9,
darkgreen: 0x006400,
darkgrey: 0xa9a9a9,
darkkhaki: 0xbdb76b,
darkmagenta: 0x8b008b,
darkolivegreen: 0x556b2f,
darkorange: 0xff8c00,
darkorchid: 0x9932cc,
darkred: 0x8b0000,
darksalmon: 0xe9967a,
darkseagreen: 0x8fbc8f,
darkslateblue: 0x483d8b,
darkslategray: 0x2f4f4f,
darkslategrey: 0x2f4f4f,
darkturquoise: 0x00ced1,
darkviolet: 0x9400d3,
deeppink: 0xff1493,
deepskyblue: 0x00bfff,
dimgray: 0x696969,
dimgrey: 0x696969,
dodgerblue: 0x1e90ff,
firebrick: 0xb22222,
floralwhite: 0xfffaf0,
forestgreen: 0x228b22,
fuchsia: 0xff00ff,
gainsboro: 0xdcdcdc,
ghostwhite: 0xf8f8ff,
gold: 0xffd700,
goldenrod: 0xdaa520,
gray: 0x808080,
green: 0x008000,
greenyellow: 0xadff2f,
grey: 0x808080,
honeydew: 0xf0fff0,
hotpink: 0xff69b4,
indianred: 0xcd5c5c,
indigo: 0x4b0082,
ivory: 0xfffff0,
khaki: 0xf0e68c,
lavender: 0xe6e6fa,
lavenderblush: 0xfff0f5,
lawngreen: 0x7cfc00,
lemonchiffon: 0xfffacd,
lightblue: 0xadd8e6,
lightcoral: 0xf08080,
lightcyan: 0xe0ffff,
lightgoldenrodyellow: 0xfafad2,
lightgray: 0xd3d3d3,
lightgreen: 0x90ee90,
lightgrey: 0xd3d3d3,
lightpink: 0xffb6c1,
lightsalmon: 0xffa07a,
lightseagreen: 0x20b2aa,
lightskyblue: 0x87cefa,
lightslategray: 0x778899,
lightslategrey: 0x778899,
lightsteelblue: 0xb0c4de,
lightyellow: 0xffffe0,
lime: 0x00ff00,
limegreen: 0x32cd32,
linen: 0xfaf0e6,
magenta: 0xff00ff,
maroon: 0x800000,
mediumaquamarine: 0x66cdaa,
mediumblue: 0x0000cd,
mediumorchid: 0xba55d3,
mediumpurple: 0x9370db,
mediumseagreen: 0x3cb371,
mediumslateblue: 0x7b68ee,
mediumspringgreen: 0x00fa9a,
mediumturquoise: 0x48d1cc,
mediumvioletred: 0xc71585,
midnightblue: 0x191970,
mintcream: 0xf5fffa,
mistyrose: 0xffe4e1,
moccasin: 0xffe4b5,
navajowhite: 0xffdead,
navy: 0x000080,
oldlace: 0xfdf5e6,
olive: 0x808000,
olivedrab: 0x6b8e23,
orange: 0xffa500,
orangered: 0xff4500,
orchid: 0xda70d6,
palegoldenrod: 0xeee8aa,
palegreen: 0x98fb98,
paleturquoise: 0xafeeee,
palevioletred: 0xdb7093,
papayawhip: 0xffefd5,
peachpuff: 0xffdab9,
peru: 0xcd853f,
pink: 0xffc0cb,
plum: 0xdda0dd,
powderblue: 0xb0e0e6,
purple: 0x800080,
rebeccapurple: 0x663399,
red: 0xff0000,
rosybrown: 0xbc8f8f,
royalblue: 0x4169e1,
saddlebrown: 0x8b4513,
salmon: 0xfa8072,
sandybrown: 0xf4a460,
seagreen: 0x2e8b57,
seashell: 0xfff5ee,
sienna: 0xa0522d,
silver: 0xc0c0c0,
skyblue: 0x87ceeb,
slateblue: 0x6a5acd,
slategray: 0x708090,
slategrey: 0x708090,
snow: 0xfffafa,
springgreen: 0x00ff7f,
steelblue: 0x4682b4,
tan: 0xd2b48c,
teal: 0x008080,
thistle: 0xd8bfd8,
tomato: 0xff6347,
turquoise: 0x40e0d0,
violet: 0xee82ee,
wheat: 0xf5deb3,
white: 0xffffff,
whitesmoke: 0xf5f5f5,
yellow: 0xffff00,
yellowgreen: 0x9acd32
});
d3_rgb_names.forEach(function(key, value) {
d3_rgb_names.set(key, d3_rgbNumber(value));
});
d3.interpolateRgb = d3_interpolateRgb;
function d3_interpolateRgb(a, b) {
a = d3.rgb(a);
b = d3.rgb(b);
var ar = a.r,
ag = a.g,
ab = a.b,
br = b.r - ar,
bg = b.g - ag,
bb = b.b - ab;
return function(t) {
return "#"
+ d3_rgb_hex(Math.round(ar + br * t))
+ d3_rgb_hex(Math.round(ag + bg * t))
+ d3_rgb_hex(Math.round(ab + bb * t));
};
}
d3.interpolateObject = d3_interpolateObject;
function d3_interpolateObject(a, b) {
var i = {},
c = {},
k;
for (k in a) {
if (k in b) {
i[k] = d3_interpolate(a[k], b[k]);
} else {
c[k] = a[k];
}
}
for (k in b) {
if (!(k in a)) {
c[k] = b[k];
}
}
return function(t) {
for (k in i) c[k] = i[k](t);
return c;
};
}
d3.interpolateArray = d3_interpolateArray;
function d3_interpolateArray(a, b) {
var x = [],
c = [],
na = a.length,
nb = b.length,
n0 = Math.min(a.length, b.length),
i;
for (i = 0; i < n0; ++i) x.push(d3_interpolate(a[i], b[i]));
for (; i < na; ++i) c[i] = a[i];
for (; i < nb; ++i) c[i] = b[i];
return function(t) {
for (i = 0; i < n0; ++i) c[i] = x[i](t);
return c;
};
}
d3.interpolateNumber = d3_interpolateNumber;
function d3_interpolateNumber(a, b) {
a = +a, b = +b;
return function(t) { return a * (1 - t) + b * t; };
}
d3.interpolateString = d3_interpolateString;
function d3_interpolateString(a, b) {
var bi = d3_interpolate_numberA.lastIndex = d3_interpolate_numberB.lastIndex = 0, // scan index for next number in b
am, // current match in a
bm, // current match in b
bs, // string preceding current number in b, if any
i = -1, // index in s
s = [], // string constants and placeholders
q = []; // number interpolators
// Coerce inputs to strings.
a = a + "", b = b + "";
// Interpolate pairs of numbers in a & b.
while ((am = d3_interpolate_numberA.exec(a))
&& (bm = d3_interpolate_numberB.exec(b))) {
if ((bs = bm.index) > bi) { // a string precedes the next number in b
bs = b.slice(bi, bs);
if (s[i]) s[i] += bs; // coalesce with previous string
else s[++i] = bs;
}
if ((am = am[0]) === (bm = bm[0])) { // numbers in a & b match
if (s[i]) s[i] += bm; // coalesce with previous string
else s[++i] = bm;
} else { // interpolate non-matching numbers
s[++i] = null;
q.push({i: i, x: d3_interpolateNumber(am, bm)});
}
bi = d3_interpolate_numberB.lastIndex;
}
// Add remains of b.
if (bi < b.length) {
bs = b.slice(bi);
if (s[i]) s[i] += bs; // coalesce with previous string
else s[++i] = bs;
}
// Special optimization for only a single match.
// Otherwise, interpolate each of the numbers and rejoin the string.
return s.length < 2
? (q[0] ? (b = q[0].x, function(t) { return b(t) + ""; })
: function() { return b; })
: (b = q.length, function(t) {
for (var i = 0, o; i < b; ++i) s[(o = q[i]).i] = o.x(t);
return s.join("");
});
}
var d3_interpolate_numberA = /[-+]?(?:\d+\.?\d*|\.?\d+)(?:[eE][-+]?\d+)?/g,
d3_interpolate_numberB = new RegExp(d3_interpolate_numberA.source, "g");
d3.interpolate = d3_interpolate;
function d3_interpolate(a, b) {
var i = d3.interpolators.length, f;
while (--i >= 0 && !(f = d3.interpolators[i](a, b)));
return f;
}
d3.interpolators = [
function(a, b) {
var t = typeof b;
return (t === "string" ? (d3_rgb_names.has(b) || /^(#|rgb\(|hsl\()/.test(b) ? d3_interpolateRgb : d3_interpolateString)
: b instanceof d3_color ? d3_interpolateRgb
: Array.isArray(b) ? d3_interpolateArray
: t === "object" && isNaN(b) ? d3_interpolateObject
: d3_interpolateNumber)(a, b);
}
];
d3.transform = function(string) {
var g = d3_document.createElementNS(d3.ns.prefix.svg, "g");
return (d3.transform = function(string) {
if (string != null) {
g.setAttribute("transform", string);
var t = g.transform.baseVal.consolidate();
}
return new d3_transform(t ? t.matrix : d3_transformIdentity);
})(string);
};
// Compute x-scale and normalize the first row.
// Compute shear and make second row orthogonal to first.
// Compute y-scale and normalize the second row.
// Finally, compute the rotation.
function d3_transform(m) {
var r0 = [m.a, m.b],
r1 = [m.c, m.d],
kx = d3_transformNormalize(r0),
kz = d3_transformDot(r0, r1),
ky = d3_transformNormalize(d3_transformCombine(r1, r0, -kz)) || 0;
if (r0[0] * r1[1] < r1[0] * r0[1]) {
r0[0] *= -1;
r0[1] *= -1;
kx *= -1;
kz *= -1;
}
this.rotate = (kx ? Math.atan2(r0[1], r0[0]) : Math.atan2(-r1[0], r1[1])) * d3_degrees;
this.translate = [m.e, m.f];
this.scale = [kx, ky];
this.skew = ky ? Math.atan2(kz, ky) * d3_degrees : 0;
};
d3_transform.prototype.toString = function() {
return "translate(" + this.translate
+ ")rotate(" + this.rotate
+ ")skewX(" + this.skew
+ ")scale(" + this.scale
+ ")";
};
function d3_transformDot(a, b) {
return a[0] * b[0] + a[1] * b[1];
}
function d3_transformNormalize(a) {
var k = Math.sqrt(d3_transformDot(a, a));
if (k) {
a[0] /= k;
a[1] /= k;
}
return k;
}
function d3_transformCombine(a, b, k) {
a[0] += k * b[0];
a[1] += k * b[1];
return a;
}
var d3_transformIdentity = {a: 1, b: 0, c: 0, d: 1, e: 0, f: 0};
d3.interpolateTransform = d3_interpolateTransform;
function d3_interpolateTransform(a, b) {
var s = [], // string constants and placeholders
q = [], // number interpolators
n,
A = d3.transform(a),
B = d3.transform(b),
ta = A.translate,
tb = B.translate,
ra = A.rotate,
rb = B.rotate,
wa = A.skew,
wb = B.skew,
ka = A.scale,
kb = B.scale;
if (ta[0] != tb[0] || ta[1] != tb[1]) {
s.push("translate(", null, ",", null, ")");
q.push({i: 1, x: d3_interpolateNumber(ta[0], tb[0])}, {i: 3, x: d3_interpolateNumber(ta[1], tb[1])});
} else if (tb[0] || tb[1]) {
s.push("translate(" + tb + ")");
} else {
s.push("");
}
if (ra != rb) {
if (ra - rb > 180) rb += 360; else if (rb - ra > 180) ra += 360; // shortest path
q.push({i: s.push(s.pop() + "rotate(", null, ")") - 2, x: d3_interpolateNumber(ra, rb)});
} else if (rb) {
s.push(s.pop() + "rotate(" + rb + ")");
}
if (wa != wb) {
q.push({i: s.push(s.pop() + "skewX(", null, ")") - 2, x: d3_interpolateNumber(wa, wb)});
} else if (wb) {
s.push(s.pop() + "skewX(" + wb + ")");
}
if (ka[0] != kb[0] || ka[1] != kb[1]) {
n = s.push(s.pop() + "scale(", null, ",", null, ")");
q.push({i: n - 4, x: d3_interpolateNumber(ka[0], kb[0])}, {i: n - 2, x: d3_interpolateNumber(ka[1], kb[1])});
} else if (kb[0] != 1 || kb[1] != 1) {
s.push(s.pop() + "scale(" + kb + ")");
}
n = q.length;
return function(t) {
var i = -1, o;
while (++i < n) s[(o = q[i]).i] = o.x(t);
return s.join("");
};
}
d3_transitionPrototype.tween = function(name, tween) {
var id = this.id, ns = this.namespace;
if (arguments.length < 2) return this.node()[ns][id].tween.get(name);
return d3_selection_each(this, tween == null
? function(node) { node[ns][id].tween.remove(name); }
: function(node) { node[ns][id].tween.set(name, tween); });
};
function d3_transition_tween(groups, name, value, tween) {
var id = groups.id, ns = groups.namespace;
return d3_selection_each(groups, typeof value === "function"
? function(node, i, j) { node[ns][id].tween.set(name, tween(value.call(node, node.__data__, i, j))); }
: (value = tween(value), function(node) { node[ns][id].tween.set(name, value); }));
}
d3_transitionPrototype.attr = function(nameNS, value) {
if (arguments.length < 2) {
// For attr(object), the object specifies the names and values of the
// attributes to transition. The values may be functions that are
// evaluated for each element.
for (value in nameNS) this.attr(value, nameNS[value]);
return this;
}
var interpolate = nameNS == "transform" ? d3_interpolateTransform : d3_interpolate,
name = d3.ns.qualify(nameNS);
// For attr(string, null), remove the attribute with the specified name.
function attrNull() {
this.removeAttribute(name);
}
function attrNullNS() {
this.removeAttributeNS(name.space, name.local);
}
// For attr(string, string), set the attribute with the specified name.
function attrTween(b) {
return b == null ? attrNull : (b += "", function() {
var a = this.getAttribute(name), i;
return a !== b && (i = interpolate(a, b), function(t) { this.setAttribute(name, i(t)); });
});
}
function attrTweenNS(b) {
return b == null ? attrNullNS : (b += "", function() {
var a = this.getAttributeNS(name.space, name.local), i;
return a !== b && (i = interpolate(a, b), function(t) { this.setAttributeNS(name.space, name.local, i(t)); });
});
}
return d3_transition_tween(this, "attr." + nameNS, value, name.local ? attrTweenNS : attrTween);
};
d3_transitionPrototype.attrTween = function(nameNS, tween) {
var name = d3.ns.qualify(nameNS);
function attrTween(d, i) {
var f = tween.call(this, d, i, this.getAttribute(name));
return f && function(t) { this.setAttribute(name, f(t)); };
}
function attrTweenNS(d, i) {
var f = tween.call(this, d, i, this.getAttributeNS(name.space, name.local));
return f && function(t) { this.setAttributeNS(name.space, name.local, f(t)); };
}
return this.tween("attr." + nameNS, name.local ? attrTweenNS : attrTween);
};
d3_transitionPrototype.style = function(name, value, priority) {
var n = arguments.length;
if (n < 3) {
// For style(object) or style(object, string), the object specifies the
// names and values of the attributes to set or remove. The values may be
// functions that are evaluated for each element. The optional string
// specifies the priority.
if (typeof name !== "string") {
if (n < 2) value = "";
for (priority in name) this.style(priority, name[priority], value);
return this;
}
// For style(string, string) or style(string, function), use the default
// priority. The priority is ignored for style(string, null).
priority = "";
}
// For style(name, null) or style(name, null, priority), remove the style
// property with the specified name. The priority is ignored.
function styleNull() {
this.style.removeProperty(name);
}
// For style(name, string) or style(name, string, priority), set the style
// property with the specified name, using the specified priority.
// Otherwise, a name, value and priority are specified, and handled as below.
function styleString(b) {
return b == null ? styleNull : (b += "", function() {
var a = d3_window(this).getComputedStyle(this, null).getPropertyValue(name), i;
return a !== b && (i = d3_interpolate(a, b), function(t) { this.style.setProperty(name, i(t), priority); });
});
}
return d3_transition_tween(this, "style." + name, value, styleString);
};
d3_transitionPrototype.styleTween = function(name, tween, priority) {
if (arguments.length < 3) priority = "";
function styleTween(d, i) {
var f = tween.call(this, d, i, d3_window(this).getComputedStyle(this, null).getPropertyValue(name));
return f && function(t) { this.style.setProperty(name, f(t), priority); };
}
return this.tween("style." + name, styleTween);
};
d3_transitionPrototype.text = function(value) {
return d3_transition_tween(this, "text", value, d3_transition_text);
};
function d3_transition_text(b) {
if (b == null) b = "";
return function() { this.textContent = b; };
}
d3_transitionPrototype.remove = function() {
var ns = this.namespace;
return this.each("end.transition", function() {
var p;
if (this[ns].count < 2 && (p = this.parentNode)) p.removeChild(this);
});
};
var d3_ease_default = function() { return d3_identity; };
var d3_ease = d3.map({
linear: d3_ease_default,
poly: d3_ease_poly,
quad: function() { return d3_ease_quad; },
cubic: function() { return d3_ease_cubic; },
sin: function() { return d3_ease_sin; },
exp: function() { return d3_ease_exp; },
circle: function() { return d3_ease_circle; },
elastic: d3_ease_elastic,
back: d3_ease_back,
bounce: function() { return d3_ease_bounce; }
});
var d3_ease_mode = d3.map({
"in": d3_identity,
"out": d3_ease_reverse,
"in-out": d3_ease_reflect,
"out-in": function(f) { return d3_ease_reflect(d3_ease_reverse(f)); }
});
d3.ease = function(name) {
var i = name.indexOf("-"),
t = i >= 0 ? name.slice(0, i) : name,
m = i >= 0 ? name.slice(i + 1) : "in";
t = d3_ease.get(t) || d3_ease_default;
m = d3_ease_mode.get(m) || d3_identity;
return d3_ease_clamp(m(t.apply(null, d3_arraySlice.call(arguments, 1))));
};
function d3_ease_clamp(f) {
return function(t) {
return t <= 0 ? 0 : t >= 1 ? 1 : f(t);
};
}
function d3_ease_reverse(f) {
return function(t) {
return 1 - f(1 - t);
};
}
function d3_ease_reflect(f) {
return function(t) {
return .5 * (t < .5 ? f(2 * t) : (2 - f(2 - 2 * t)));
};
}
function d3_ease_quad(t) {
return t * t;
}
function d3_ease_cubic(t) {
return t * t * t;
}
// Optimized clamp(reflect(poly(3))).
function d3_ease_cubicInOut(t) {
if (t <= 0) return 0;
if (t >= 1) return 1;
var t2 = t * t, t3 = t2 * t;
return 4 * (t < .5 ? t3 : 3 * (t - t2) + t3 - .75);
}
function d3_ease_poly(e) {
return function(t) {
return Math.pow(t, e);
};
}
function d3_ease_sin(t) {
return 1 - Math.cos(t * halfπ);
}
function d3_ease_exp(t) {
return Math.pow(2, 10 * (t - 1));
}
function d3_ease_circle(t) {
return 1 - Math.sqrt(1 - t * t);
}
function d3_ease_elastic(a, p) {
var s;
if (arguments.length < 2) p = 0.45;
if (arguments.length) s = p / τ * Math.asin(1 / a);
else a = 1, s = p / 4;
return function(t) {
return 1 + a * Math.pow(2, -10 * t) * Math.sin((t - s) * τ / p);
};
}
function d3_ease_back(s) {
if (!s) s = 1.70158;
return function(t) {
return t * t * ((s + 1) * t - s);
};
}
function d3_ease_bounce(t) {
return t < 1 / 2.75 ? 7.5625 * t * t
: t < 2 / 2.75 ? 7.5625 * (t -= 1.5 / 2.75) * t + .75
: t < 2.5 / 2.75 ? 7.5625 * (t -= 2.25 / 2.75) * t + .9375
: 7.5625 * (t -= 2.625 / 2.75) * t + .984375;
}
d3_transitionPrototype.ease = function(value) {
var id = this.id, ns = this.namespace;
if (arguments.length < 1) return this.node()[ns][id].ease;
if (typeof value !== "function") value = d3.ease.apply(d3, arguments);
return d3_selection_each(this, function(node) { node[ns][id].ease = value; });
};
d3_transitionPrototype.delay = function(value) {
var id = this.id, ns = this.namespace;
if (arguments.length < 1) return this.node()[ns][id].delay;
return d3_selection_each(this, typeof value === "function"
? function(node, i, j) { node[ns][id].delay = +value.call(node, node.__data__, i, j); }
: (value = +value, function(node) { node[ns][id].delay = value; }));
};
d3_transitionPrototype.duration = function(value) {
var id = this.id, ns = this.namespace;
if (arguments.length < 1) return this.node()[ns][id].duration;
return d3_selection_each(this, typeof value === "function"
? function(node, i, j) { node[ns][id].duration = Math.max(1, value.call(node, node.__data__, i, j)); }
: (value = Math.max(1, value), function(node) { node[ns][id].duration = value; }));
};
d3_transitionPrototype.each = function(type, listener) {
var id = this.id, ns = this.namespace;
if (arguments.length < 2) {
var inherit = d3_transitionInherit,
inheritId = d3_transitionInheritId;
try {
d3_transitionInheritId = id;
d3_selection_each(this, function(node, i, j) {
d3_transitionInherit = node[ns][id];
type.call(node, node.__data__, i, j);
});
} finally {
d3_transitionInherit = inherit;
d3_transitionInheritId = inheritId;
}
} else {
d3_selection_each(this, function(node) {
var transition = node[ns][id];
(transition.event || (transition.event = d3.dispatch("start", "end", "interrupt"))).on(type, listener);
});
}
return this;
};
d3_transitionPrototype.transition = function() {
var id0 = this.id,
id1 = ++d3_transitionId,
ns = this.namespace,
subgroups = [],
subgroup,
group,
node,
transition;
for (var j = 0, m = this.length; j < m; j++) {
subgroups.push(subgroup = []);
for (var group = this[j], i = 0, n = group.length; i < n; i++) {
if (node = group[i]) {
transition = node[ns][id0];
d3_transitionNode(node, i, ns, id1, {time: transition.time, ease: transition.ease, delay: transition.delay + transition.duration, duration: transition.duration});
}
subgroup.push(node);
}
}
return d3_transition(subgroups, ns, id1);
};
function d3_transitionNamespace(name) {
return name == null ? "__transition__" : "__transition_" + name + "__";
}
function d3_transitionNode(node, i, ns, id, inherit) {
var lock = node[ns] || (node[ns] = {active: 0, count: 0}),
transition = lock[id];
if (!transition) {
var time = inherit.time;
transition = lock[id] = {
tween: new d3_Map,
time: time,
delay: inherit.delay,
duration: inherit.duration,
ease: inherit.ease,
index: i
};
inherit = null; // allow gc
++lock.count;
d3.timer(function(elapsed) {
var delay = transition.delay,
duration,
ease,
timer = d3_timer_active,
tweened = [];
timer.t = delay + time;
if (delay <= elapsed) return start(elapsed - delay);
timer.c = start;
function start(elapsed) {
if (lock.active > id) return stop();
var active = lock[lock.active];
if (active) {
--lock.count;
delete lock[lock.active];
active.event && active.event.interrupt.call(node, node.__data__, active.index);
}
lock.active = id;
transition.event && transition.event.start.call(node, node.__data__, i);
transition.tween.forEach(function(key, value) {
if (value = value.call(node, node.__data__, i)) {
tweened.push(value);
}
});
// Deferred capture to allow tweens to initialize ease & duration.
ease = transition.ease;
duration = transition.duration;
d3.timer(function() { // defer to end of current frame
timer.c = tick(elapsed || 1) ? d3_true : tick;
return 1;
}, 0, time);
}
function tick(elapsed) {
if (lock.active !== id) return 1;
var t = elapsed / duration,
e = ease(t),
n = tweened.length;
while (n > 0) {
tweened[--n].call(node, e);
}
if (t >= 1) {
transition.event && transition.event.end.call(node, node.__data__, i);
return stop();
}
}
function stop() {
if (--lock.count) delete lock[id];
else delete node[ns];
return 1;
}
}, 0, time);
}
}
d3.xhr = d3_xhrType(d3_identity);
function d3_xhrType(response) {
return function(url, mimeType, callback) {
if (arguments.length === 2 && typeof mimeType === "function") callback = mimeType, mimeType = null;
return d3_xhr(url, mimeType, response, callback);
};
}
function d3_xhr(url, mimeType, response, callback) {
var xhr = {},
dispatch = d3.dispatch("beforesend", "progress", "load", "error"),
headers = {},
request = new XMLHttpRequest,
responseType = null;
// If IE does not support CORS, use XDomainRequest.
if (this.XDomainRequest
&& !("withCredentials" in request)
&& /^(http(s)?:)?\/\//.test(url)) request = new XDomainRequest;
"onload" in request
? request.onload = request.onerror = respond
: request.onreadystatechange = function() { request.readyState > 3 && respond(); };
function respond() {
var status = request.status, result;
if (!status && d3_xhrHasResponse(request) || status >= 200 && status < 300 || status === 304) {
try {
result = response.call(xhr, request);
} catch (e) {
dispatch.error.call(xhr, e);
return;
}
dispatch.load.call(xhr, result);
} else {
dispatch.error.call(xhr, request);
}
}
request.onprogress = function(event) {
var o = d3.event;
d3.event = event;
try { dispatch.progress.call(xhr, request); }
finally { d3.event = o; }
};
xhr.header = function(name, value) {
name = (name + "").toLowerCase();
if (arguments.length < 2) return headers[name];
if (value == null) delete headers[name];
else headers[name] = value + "";
return xhr;
};
// If mimeType is non-null and no Accept header is set, a default is used.
xhr.mimeType = function(value) {
if (!arguments.length) return mimeType;
mimeType = value == null ? null : value + "";
return xhr;
};
// Specifies what type the response value should take;
// for instance, arraybuffer, blob, document, or text.
xhr.responseType = function(value) {
if (!arguments.length) return responseType;
responseType = value;
return xhr;
};
// Specify how to convert the response content to a specific type;
// changes the callback value on "load" events.
xhr.response = function(value) {
response = value;
return xhr;
};
// Convenience methods.
["get", "post"].forEach(function(method) {
xhr[method] = function() {
return xhr.send.apply(xhr, [method].concat(d3_array(arguments)));
};
});
// If callback is non-null, it will be used for error and load events.
xhr.send = function(method, data, callback) {
if (arguments.length === 2 && typeof data === "function") callback = data, data = null;
request.open(method, url, true);
if (mimeType != null && !("accept" in headers)) headers["accept"] = mimeType + ",*/*";
if (request.setRequestHeader) for (var name in headers) request.setRequestHeader(name, headers[name]);
if (mimeType != null && request.overrideMimeType) request.overrideMimeType(mimeType);
if (responseType != null) request.responseType = responseType;
if (callback != null) xhr.on("error", callback).on("load", function(request) { callback(null, request); });
dispatch.beforesend.call(xhr, request);
request.send(data == null ? null : data);
return xhr;
};
xhr.abort = function() {
request.abort();
return xhr;
};
d3.rebind(xhr, dispatch, "on");
return callback == null ? xhr : xhr.get(d3_xhr_fixCallback(callback));
};
function d3_xhr_fixCallback(callback) {
return callback.length === 1
? function(error, request) { callback(error == null ? request : null); }
: callback;
}
function d3_xhrHasResponse(request) {
var type = request.responseType;
return type && type !== "text"
? request.response // null on error
: request.responseText; // "" on error
}
d3.text = d3_xhrType(function(request) {
return request.responseText;
});
d3.json = function(url, callback) {
return d3_xhr(url, "application/json", d3_json, callback);
};
function d3_json(request) {
return JSON.parse(request.responseText);
}
d3.html = function(url, callback) {
return d3_xhr(url, "text/html", d3_html, callback);
};
function d3_html(request) {
var range = d3_document.createRange();
range.selectNode(d3_document.body);
return range.createContextualFragment(request.responseText);
}
d3.xml = d3_xhrType(function(request) {
return request.responseXML;
});
if (typeof define === "function" && define.amd) define(d3);
else if (typeof module === "object" && module.exports) module.exports = d3;
this.d3 = d3;
}();
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