site/node_modules/d3-array/dist/d3-array.js
2024-10-14 08:09:33 +02:00

1456 lines
39 KiB
JavaScript
Raw Blame History

This file contains ambiguous Unicode characters

This file contains Unicode characters that might be confused with other characters. If you think that this is intentional, you can safely ignore this warning. Use the Escape button to reveal them.

// https://d3js.org/d3-array/ v3.2.4 Copyright 2010-2023 Mike Bostock
(function (global, factory) {
typeof exports === 'object' && typeof module !== 'undefined' ? factory(exports) :
typeof define === 'function' && define.amd ? define(['exports'], factory) :
(global = typeof globalThis !== 'undefined' ? globalThis : global || self, factory(global.d3 = global.d3 || {}));
})(this, (function (exports) { 'use strict';
function ascending(a, b) {
return a == null || b == null ? NaN : a < b ? -1 : a > b ? 1 : a >= b ? 0 : NaN;
}
function descending(a, b) {
return a == null || b == null ? NaN
: b < a ? -1
: b > a ? 1
: b >= a ? 0
: NaN;
}
function bisector(f) {
let compare1, compare2, delta;
// If an accessor is specified, promote it to a comparator. In this case we
// can test whether the search value is (self-) comparable. We cant do this
// for a comparator (except for specific, known comparators) because we cant
// tell if the comparator is symmetric, and an asymmetric comparator cant be
// used to test whether a single value is comparable.
if (f.length !== 2) {
compare1 = ascending;
compare2 = (d, x) => ascending(f(d), x);
delta = (d, x) => f(d) - x;
} else {
compare1 = f === ascending || f === descending ? f : zero;
compare2 = f;
delta = f;
}
function left(a, x, lo = 0, hi = a.length) {
if (lo < hi) {
if (compare1(x, x) !== 0) return hi;
do {
const mid = (lo + hi) >>> 1;
if (compare2(a[mid], x) < 0) lo = mid + 1;
else hi = mid;
} while (lo < hi);
}
return lo;
}
function right(a, x, lo = 0, hi = a.length) {
if (lo < hi) {
if (compare1(x, x) !== 0) return hi;
do {
const mid = (lo + hi) >>> 1;
if (compare2(a[mid], x) <= 0) lo = mid + 1;
else hi = mid;
} while (lo < hi);
}
return lo;
}
function center(a, x, lo = 0, hi = a.length) {
const i = left(a, x, lo, hi - 1);
return i > lo && delta(a[i - 1], x) > -delta(a[i], x) ? i - 1 : i;
}
return {left, center, right};
}
function zero() {
return 0;
}
function number(x) {
return x === null ? NaN : +x;
}
function* numbers(values, valueof) {
if (valueof === undefined) {
for (let value of values) {
if (value != null && (value = +value) >= value) {
yield value;
}
}
} else {
let index = -1;
for (let value of values) {
if ((value = valueof(value, ++index, values)) != null && (value = +value) >= value) {
yield value;
}
}
}
}
const ascendingBisect = bisector(ascending);
const bisectRight = ascendingBisect.right;
const bisectLeft = ascendingBisect.left;
const bisectCenter = bisector(number).center;
var bisect = bisectRight;
function blur(values, r) {
if (!((r = +r) >= 0)) throw new RangeError("invalid r");
let length = values.length;
if (!((length = Math.floor(length)) >= 0)) throw new RangeError("invalid length");
if (!length || !r) return values;
const blur = blurf(r);
const temp = values.slice();
blur(values, temp, 0, length, 1);
blur(temp, values, 0, length, 1);
blur(values, temp, 0, length, 1);
return values;
}
const blur2 = Blur2(blurf);
const blurImage = Blur2(blurfImage);
function Blur2(blur) {
return function(data, rx, ry = rx) {
if (!((rx = +rx) >= 0)) throw new RangeError("invalid rx");
if (!((ry = +ry) >= 0)) throw new RangeError("invalid ry");
let {data: values, width, height} = data;
if (!((width = Math.floor(width)) >= 0)) throw new RangeError("invalid width");
if (!((height = Math.floor(height !== undefined ? height : values.length / width)) >= 0)) throw new RangeError("invalid height");
if (!width || !height || (!rx && !ry)) return data;
const blurx = rx && blur(rx);
const blury = ry && blur(ry);
const temp = values.slice();
if (blurx && blury) {
blurh(blurx, temp, values, width, height);
blurh(blurx, values, temp, width, height);
blurh(blurx, temp, values, width, height);
blurv(blury, values, temp, width, height);
blurv(blury, temp, values, width, height);
blurv(blury, values, temp, width, height);
} else if (blurx) {
blurh(blurx, values, temp, width, height);
blurh(blurx, temp, values, width, height);
blurh(blurx, values, temp, width, height);
} else if (blury) {
blurv(blury, values, temp, width, height);
blurv(blury, temp, values, width, height);
blurv(blury, values, temp, width, height);
}
return data;
};
}
function blurh(blur, T, S, w, h) {
for (let y = 0, n = w * h; y < n;) {
blur(T, S, y, y += w, 1);
}
}
function blurv(blur, T, S, w, h) {
for (let x = 0, n = w * h; x < w; ++x) {
blur(T, S, x, x + n, w);
}
}
function blurfImage(radius) {
const blur = blurf(radius);
return (T, S, start, stop, step) => {
start <<= 2, stop <<= 2, step <<= 2;
blur(T, S, start + 0, stop + 0, step);
blur(T, S, start + 1, stop + 1, step);
blur(T, S, start + 2, stop + 2, step);
blur(T, S, start + 3, stop + 3, step);
};
}
// Given a target array T, a source array S, sets each value T[i] to the average
// of {S[i - r], …, S[i], …, S[i + r]}, where r = ⌊radius⌋, start <= i < stop,
// for each i, i + step, i + 2 * step, etc., and where S[j] is clamped between
// S[start] (inclusive) and S[stop] (exclusive). If the given radius is not an
// integer, S[i - r - 1] and S[i + r + 1] are added to the sum, each weighted
// according to r - ⌊radius⌋.
function blurf(radius) {
const radius0 = Math.floor(radius);
if (radius0 === radius) return bluri(radius);
const t = radius - radius0;
const w = 2 * radius + 1;
return (T, S, start, stop, step) => { // stop must be aligned!
if (!((stop -= step) >= start)) return; // inclusive stop
let sum = radius0 * S[start];
const s0 = step * radius0;
const s1 = s0 + step;
for (let i = start, j = start + s0; i < j; i += step) {
sum += S[Math.min(stop, i)];
}
for (let i = start, j = stop; i <= j; i += step) {
sum += S[Math.min(stop, i + s0)];
T[i] = (sum + t * (S[Math.max(start, i - s1)] + S[Math.min(stop, i + s1)])) / w;
sum -= S[Math.max(start, i - s0)];
}
};
}
// Like blurf, but optimized for integer radius.
function bluri(radius) {
const w = 2 * radius + 1;
return (T, S, start, stop, step) => { // stop must be aligned!
if (!((stop -= step) >= start)) return; // inclusive stop
let sum = radius * S[start];
const s = step * radius;
for (let i = start, j = start + s; i < j; i += step) {
sum += S[Math.min(stop, i)];
}
for (let i = start, j = stop; i <= j; i += step) {
sum += S[Math.min(stop, i + s)];
T[i] = sum / w;
sum -= S[Math.max(start, i - s)];
}
};
}
function count(values, valueof) {
let count = 0;
if (valueof === undefined) {
for (let value of values) {
if (value != null && (value = +value) >= value) {
++count;
}
}
} else {
let index = -1;
for (let value of values) {
if ((value = valueof(value, ++index, values)) != null && (value = +value) >= value) {
++count;
}
}
}
return count;
}
function length$1(array) {
return array.length | 0;
}
function empty(length) {
return !(length > 0);
}
function arrayify(values) {
return typeof values !== "object" || "length" in values ? values : Array.from(values);
}
function reducer(reduce) {
return values => reduce(...values);
}
function cross(...values) {
const reduce = typeof values[values.length - 1] === "function" && reducer(values.pop());
values = values.map(arrayify);
const lengths = values.map(length$1);
const j = values.length - 1;
const index = new Array(j + 1).fill(0);
const product = [];
if (j < 0 || lengths.some(empty)) return product;
while (true) {
product.push(index.map((j, i) => values[i][j]));
let i = j;
while (++index[i] === lengths[i]) {
if (i === 0) return reduce ? product.map(reduce) : product;
index[i--] = 0;
}
}
}
function cumsum(values, valueof) {
var sum = 0, index = 0;
return Float64Array.from(values, valueof === undefined
? v => (sum += +v || 0)
: v => (sum += +valueof(v, index++, values) || 0));
}
function variance(values, valueof) {
let count = 0;
let delta;
let mean = 0;
let sum = 0;
if (valueof === undefined) {
for (let value of values) {
if (value != null && (value = +value) >= value) {
delta = value - mean;
mean += delta / ++count;
sum += delta * (value - mean);
}
}
} else {
let index = -1;
for (let value of values) {
if ((value = valueof(value, ++index, values)) != null && (value = +value) >= value) {
delta = value - mean;
mean += delta / ++count;
sum += delta * (value - mean);
}
}
}
if (count > 1) return sum / (count - 1);
}
function deviation(values, valueof) {
const v = variance(values, valueof);
return v ? Math.sqrt(v) : v;
}
function extent(values, valueof) {
let min;
let max;
if (valueof === undefined) {
for (const value of values) {
if (value != null) {
if (min === undefined) {
if (value >= value) min = max = value;
} else {
if (min > value) min = value;
if (max < value) max = value;
}
}
}
} else {
let index = -1;
for (let value of values) {
if ((value = valueof(value, ++index, values)) != null) {
if (min === undefined) {
if (value >= value) min = max = value;
} else {
if (min > value) min = value;
if (max < value) max = value;
}
}
}
}
return [min, max];
}
// https://github.com/python/cpython/blob/a74eea238f5baba15797e2e8b570d153bc8690a7/Modules/mathmodule.c#L1423
class Adder {
constructor() {
this._partials = new Float64Array(32);
this._n = 0;
}
add(x) {
const p = this._partials;
let i = 0;
for (let j = 0; j < this._n && j < 32; j++) {
const y = p[j],
hi = x + y,
lo = Math.abs(x) < Math.abs(y) ? x - (hi - y) : y - (hi - x);
if (lo) p[i++] = lo;
x = hi;
}
p[i] = x;
this._n = i + 1;
return this;
}
valueOf() {
const p = this._partials;
let n = this._n, x, y, lo, hi = 0;
if (n > 0) {
hi = p[--n];
while (n > 0) {
x = hi;
y = p[--n];
hi = x + y;
lo = y - (hi - x);
if (lo) break;
}
if (n > 0 && ((lo < 0 && p[n - 1] < 0) || (lo > 0 && p[n - 1] > 0))) {
y = lo * 2;
x = hi + y;
if (y == x - hi) hi = x;
}
}
return hi;
}
}
function fsum(values, valueof) {
const adder = new Adder();
if (valueof === undefined) {
for (let value of values) {
if (value = +value) {
adder.add(value);
}
}
} else {
let index = -1;
for (let value of values) {
if (value = +valueof(value, ++index, values)) {
adder.add(value);
}
}
}
return +adder;
}
function fcumsum(values, valueof) {
const adder = new Adder();
let index = -1;
return Float64Array.from(values, valueof === undefined
? v => adder.add(+v || 0)
: v => adder.add(+valueof(v, ++index, values) || 0)
);
}
class InternMap extends Map {
constructor(entries, key = keyof) {
super();
Object.defineProperties(this, {_intern: {value: new Map()}, _key: {value: key}});
if (entries != null) for (const [key, value] of entries) this.set(key, value);
}
get(key) {
return super.get(intern_get(this, key));
}
has(key) {
return super.has(intern_get(this, key));
}
set(key, value) {
return super.set(intern_set(this, key), value);
}
delete(key) {
return super.delete(intern_delete(this, key));
}
}
class InternSet extends Set {
constructor(values, key = keyof) {
super();
Object.defineProperties(this, {_intern: {value: new Map()}, _key: {value: key}});
if (values != null) for (const value of values) this.add(value);
}
has(value) {
return super.has(intern_get(this, value));
}
add(value) {
return super.add(intern_set(this, value));
}
delete(value) {
return super.delete(intern_delete(this, value));
}
}
function intern_get({_intern, _key}, value) {
const key = _key(value);
return _intern.has(key) ? _intern.get(key) : value;
}
function intern_set({_intern, _key}, value) {
const key = _key(value);
if (_intern.has(key)) return _intern.get(key);
_intern.set(key, value);
return value;
}
function intern_delete({_intern, _key}, value) {
const key = _key(value);
if (_intern.has(key)) {
value = _intern.get(key);
_intern.delete(key);
}
return value;
}
function keyof(value) {
return value !== null && typeof value === "object" ? value.valueOf() : value;
}
function identity(x) {
return x;
}
function group(values, ...keys) {
return nest(values, identity, identity, keys);
}
function groups(values, ...keys) {
return nest(values, Array.from, identity, keys);
}
function flatten$1(groups, keys) {
for (let i = 1, n = keys.length; i < n; ++i) {
groups = groups.flatMap(g => g.pop().map(([key, value]) => [...g, key, value]));
}
return groups;
}
function flatGroup(values, ...keys) {
return flatten$1(groups(values, ...keys), keys);
}
function flatRollup(values, reduce, ...keys) {
return flatten$1(rollups(values, reduce, ...keys), keys);
}
function rollup(values, reduce, ...keys) {
return nest(values, identity, reduce, keys);
}
function rollups(values, reduce, ...keys) {
return nest(values, Array.from, reduce, keys);
}
function index(values, ...keys) {
return nest(values, identity, unique, keys);
}
function indexes(values, ...keys) {
return nest(values, Array.from, unique, keys);
}
function unique(values) {
if (values.length !== 1) throw new Error("duplicate key");
return values[0];
}
function nest(values, map, reduce, keys) {
return (function regroup(values, i) {
if (i >= keys.length) return reduce(values);
const groups = new InternMap();
const keyof = keys[i++];
let index = -1;
for (const value of values) {
const key = keyof(value, ++index, values);
const group = groups.get(key);
if (group) group.push(value);
else groups.set(key, [value]);
}
for (const [key, values] of groups) {
groups.set(key, regroup(values, i));
}
return map(groups);
})(values, 0);
}
function permute(source, keys) {
return Array.from(keys, key => source[key]);
}
function sort(values, ...F) {
if (typeof values[Symbol.iterator] !== "function") throw new TypeError("values is not iterable");
values = Array.from(values);
let [f] = F;
if ((f && f.length !== 2) || F.length > 1) {
const index = Uint32Array.from(values, (d, i) => i);
if (F.length > 1) {
F = F.map(f => values.map(f));
index.sort((i, j) => {
for (const f of F) {
const c = ascendingDefined(f[i], f[j]);
if (c) return c;
}
});
} else {
f = values.map(f);
index.sort((i, j) => ascendingDefined(f[i], f[j]));
}
return permute(values, index);
}
return values.sort(compareDefined(f));
}
function compareDefined(compare = ascending) {
if (compare === ascending) return ascendingDefined;
if (typeof compare !== "function") throw new TypeError("compare is not a function");
return (a, b) => {
const x = compare(a, b);
if (x || x === 0) return x;
return (compare(b, b) === 0) - (compare(a, a) === 0);
};
}
function ascendingDefined(a, b) {
return (a == null || !(a >= a)) - (b == null || !(b >= b)) || (a < b ? -1 : a > b ? 1 : 0);
}
function groupSort(values, reduce, key) {
return (reduce.length !== 2
? sort(rollup(values, reduce, key), (([ak, av], [bk, bv]) => ascending(av, bv) || ascending(ak, bk)))
: sort(group(values, key), (([ak, av], [bk, bv]) => reduce(av, bv) || ascending(ak, bk))))
.map(([key]) => key);
}
var array = Array.prototype;
var slice = array.slice;
function constant(x) {
return () => x;
}
const e10 = Math.sqrt(50),
e5 = Math.sqrt(10),
e2 = Math.sqrt(2);
function tickSpec(start, stop, count) {
const step = (stop - start) / Math.max(0, count),
power = Math.floor(Math.log10(step)),
error = step / Math.pow(10, power),
factor = error >= e10 ? 10 : error >= e5 ? 5 : error >= e2 ? 2 : 1;
let i1, i2, inc;
if (power < 0) {
inc = Math.pow(10, -power) / factor;
i1 = Math.round(start * inc);
i2 = Math.round(stop * inc);
if (i1 / inc < start) ++i1;
if (i2 / inc > stop) --i2;
inc = -inc;
} else {
inc = Math.pow(10, power) * factor;
i1 = Math.round(start / inc);
i2 = Math.round(stop / inc);
if (i1 * inc < start) ++i1;
if (i2 * inc > stop) --i2;
}
if (i2 < i1 && 0.5 <= count && count < 2) return tickSpec(start, stop, count * 2);
return [i1, i2, inc];
}
function ticks(start, stop, count) {
stop = +stop, start = +start, count = +count;
if (!(count > 0)) return [];
if (start === stop) return [start];
const reverse = stop < start, [i1, i2, inc] = reverse ? tickSpec(stop, start, count) : tickSpec(start, stop, count);
if (!(i2 >= i1)) return [];
const n = i2 - i1 + 1, ticks = new Array(n);
if (reverse) {
if (inc < 0) for (let i = 0; i < n; ++i) ticks[i] = (i2 - i) / -inc;
else for (let i = 0; i < n; ++i) ticks[i] = (i2 - i) * inc;
} else {
if (inc < 0) for (let i = 0; i < n; ++i) ticks[i] = (i1 + i) / -inc;
else for (let i = 0; i < n; ++i) ticks[i] = (i1 + i) * inc;
}
return ticks;
}
function tickIncrement(start, stop, count) {
stop = +stop, start = +start, count = +count;
return tickSpec(start, stop, count)[2];
}
function tickStep(start, stop, count) {
stop = +stop, start = +start, count = +count;
const reverse = stop < start, inc = reverse ? tickIncrement(stop, start, count) : tickIncrement(start, stop, count);
return (reverse ? -1 : 1) * (inc < 0 ? 1 / -inc : inc);
}
function nice(start, stop, count) {
let prestep;
while (true) {
const step = tickIncrement(start, stop, count);
if (step === prestep || step === 0 || !isFinite(step)) {
return [start, stop];
} else if (step > 0) {
start = Math.floor(start / step) * step;
stop = Math.ceil(stop / step) * step;
} else if (step < 0) {
start = Math.ceil(start * step) / step;
stop = Math.floor(stop * step) / step;
}
prestep = step;
}
}
function thresholdSturges(values) {
return Math.max(1, Math.ceil(Math.log(count(values)) / Math.LN2) + 1);
}
function bin() {
var value = identity,
domain = extent,
threshold = thresholdSturges;
function histogram(data) {
if (!Array.isArray(data)) data = Array.from(data);
var i,
n = data.length,
x,
step,
values = new Array(n);
for (i = 0; i < n; ++i) {
values[i] = value(data[i], i, data);
}
var xz = domain(values),
x0 = xz[0],
x1 = xz[1],
tz = threshold(values, x0, x1);
// Convert number of thresholds into uniform thresholds, and nice the
// default domain accordingly.
if (!Array.isArray(tz)) {
const max = x1, tn = +tz;
if (domain === extent) [x0, x1] = nice(x0, x1, tn);
tz = ticks(x0, x1, tn);
// If the domain is aligned with the first tick (which it will by
// default), then we can use quantization rather than bisection to bin
// values, which is substantially faster.
if (tz[0] <= x0) step = tickIncrement(x0, x1, tn);
// If the last threshold is coincident with the domains upper bound, the
// last bin will be zero-width. If the default domain is used, and this
// last threshold is coincident with the maximum input value, we can
// extend the niced upper bound by one tick to ensure uniform bin widths;
// otherwise, we simply remove the last threshold. Note that we dont
// coerce values or the domain to numbers, and thus must be careful to
// compare order (>=) rather than strict equality (===)!
if (tz[tz.length - 1] >= x1) {
if (max >= x1 && domain === extent) {
const step = tickIncrement(x0, x1, tn);
if (isFinite(step)) {
if (step > 0) {
x1 = (Math.floor(x1 / step) + 1) * step;
} else if (step < 0) {
x1 = (Math.ceil(x1 * -step) + 1) / -step;
}
}
} else {
tz.pop();
}
}
}
// Remove any thresholds outside the domain.
// Be careful not to mutate an array owned by the user!
var m = tz.length, a = 0, b = m;
while (tz[a] <= x0) ++a;
while (tz[b - 1] > x1) --b;
if (a || b < m) tz = tz.slice(a, b), m = b - a;
var bins = new Array(m + 1),
bin;
// Initialize bins.
for (i = 0; i <= m; ++i) {
bin = bins[i] = [];
bin.x0 = i > 0 ? tz[i - 1] : x0;
bin.x1 = i < m ? tz[i] : x1;
}
// Assign data to bins by value, ignoring any outside the domain.
if (isFinite(step)) {
if (step > 0) {
for (i = 0; i < n; ++i) {
if ((x = values[i]) != null && x0 <= x && x <= x1) {
bins[Math.min(m, Math.floor((x - x0) / step))].push(data[i]);
}
}
} else if (step < 0) {
for (i = 0; i < n; ++i) {
if ((x = values[i]) != null && x0 <= x && x <= x1) {
const j = Math.floor((x0 - x) * step);
bins[Math.min(m, j + (tz[j] <= x))].push(data[i]); // handle off-by-one due to rounding
}
}
}
} else {
for (i = 0; i < n; ++i) {
if ((x = values[i]) != null && x0 <= x && x <= x1) {
bins[bisect(tz, x, 0, m)].push(data[i]);
}
}
}
return bins;
}
histogram.value = function(_) {
return arguments.length ? (value = typeof _ === "function" ? _ : constant(_), histogram) : value;
};
histogram.domain = function(_) {
return arguments.length ? (domain = typeof _ === "function" ? _ : constant([_[0], _[1]]), histogram) : domain;
};
histogram.thresholds = function(_) {
return arguments.length ? (threshold = typeof _ === "function" ? _ : constant(Array.isArray(_) ? slice.call(_) : _), histogram) : threshold;
};
return histogram;
}
function max(values, valueof) {
let max;
if (valueof === undefined) {
for (const value of values) {
if (value != null
&& (max < value || (max === undefined && value >= value))) {
max = value;
}
}
} else {
let index = -1;
for (let value of values) {
if ((value = valueof(value, ++index, values)) != null
&& (max < value || (max === undefined && value >= value))) {
max = value;
}
}
}
return max;
}
function maxIndex(values, valueof) {
let max;
let maxIndex = -1;
let index = -1;
if (valueof === undefined) {
for (const value of values) {
++index;
if (value != null
&& (max < value || (max === undefined && value >= value))) {
max = value, maxIndex = index;
}
}
} else {
for (let value of values) {
if ((value = valueof(value, ++index, values)) != null
&& (max < value || (max === undefined && value >= value))) {
max = value, maxIndex = index;
}
}
}
return maxIndex;
}
function min(values, valueof) {
let min;
if (valueof === undefined) {
for (const value of values) {
if (value != null
&& (min > value || (min === undefined && value >= value))) {
min = value;
}
}
} else {
let index = -1;
for (let value of values) {
if ((value = valueof(value, ++index, values)) != null
&& (min > value || (min === undefined && value >= value))) {
min = value;
}
}
}
return min;
}
function minIndex(values, valueof) {
let min;
let minIndex = -1;
let index = -1;
if (valueof === undefined) {
for (const value of values) {
++index;
if (value != null
&& (min > value || (min === undefined && value >= value))) {
min = value, minIndex = index;
}
}
} else {
for (let value of values) {
if ((value = valueof(value, ++index, values)) != null
&& (min > value || (min === undefined && value >= value))) {
min = value, minIndex = index;
}
}
}
return minIndex;
}
// Based on https://github.com/mourner/quickselect
// ISC license, Copyright 2018 Vladimir Agafonkin.
function quickselect(array, k, left = 0, right = Infinity, compare) {
k = Math.floor(k);
left = Math.floor(Math.max(0, left));
right = Math.floor(Math.min(array.length - 1, right));
if (!(left <= k && k <= right)) return array;
compare = compare === undefined ? ascendingDefined : compareDefined(compare);
while (right > left) {
if (right - left > 600) {
const n = right - left + 1;
const m = k - left + 1;
const z = Math.log(n);
const s = 0.5 * Math.exp(2 * z / 3);
const sd = 0.5 * Math.sqrt(z * s * (n - s) / n) * (m - n / 2 < 0 ? -1 : 1);
const newLeft = Math.max(left, Math.floor(k - m * s / n + sd));
const newRight = Math.min(right, Math.floor(k + (n - m) * s / n + sd));
quickselect(array, k, newLeft, newRight, compare);
}
const t = array[k];
let i = left;
let j = right;
swap(array, left, k);
if (compare(array[right], t) > 0) swap(array, left, right);
while (i < j) {
swap(array, i, j), ++i, --j;
while (compare(array[i], t) < 0) ++i;
while (compare(array[j], t) > 0) --j;
}
if (compare(array[left], t) === 0) swap(array, left, j);
else ++j, swap(array, j, right);
if (j <= k) left = j + 1;
if (k <= j) right = j - 1;
}
return array;
}
function swap(array, i, j) {
const t = array[i];
array[i] = array[j];
array[j] = t;
}
function greatest(values, compare = ascending) {
let max;
let defined = false;
if (compare.length === 1) {
let maxValue;
for (const element of values) {
const value = compare(element);
if (defined
? ascending(value, maxValue) > 0
: ascending(value, value) === 0) {
max = element;
maxValue = value;
defined = true;
}
}
} else {
for (const value of values) {
if (defined
? compare(value, max) > 0
: compare(value, value) === 0) {
max = value;
defined = true;
}
}
}
return max;
}
function quantile(values, p, valueof) {
values = Float64Array.from(numbers(values, valueof));
if (!(n = values.length) || isNaN(p = +p)) return;
if (p <= 0 || n < 2) return min(values);
if (p >= 1) return max(values);
var n,
i = (n - 1) * p,
i0 = Math.floor(i),
value0 = max(quickselect(values, i0).subarray(0, i0 + 1)),
value1 = min(values.subarray(i0 + 1));
return value0 + (value1 - value0) * (i - i0);
}
function quantileSorted(values, p, valueof = number) {
if (!(n = values.length) || isNaN(p = +p)) return;
if (p <= 0 || n < 2) return +valueof(values[0], 0, values);
if (p >= 1) return +valueof(values[n - 1], n - 1, values);
var n,
i = (n - 1) * p,
i0 = Math.floor(i),
value0 = +valueof(values[i0], i0, values),
value1 = +valueof(values[i0 + 1], i0 + 1, values);
return value0 + (value1 - value0) * (i - i0);
}
function quantileIndex(values, p, valueof = number) {
if (isNaN(p = +p)) return;
numbers = Float64Array.from(values, (_, i) => number(valueof(values[i], i, values)));
if (p <= 0) return minIndex(numbers);
if (p >= 1) return maxIndex(numbers);
var numbers,
index = Uint32Array.from(values, (_, i) => i),
j = numbers.length - 1,
i = Math.floor(j * p);
quickselect(index, i, 0, j, (i, j) => ascendingDefined(numbers[i], numbers[j]));
i = greatest(index.subarray(0, i + 1), (i) => numbers[i]);
return i >= 0 ? i : -1;
}
function thresholdFreedmanDiaconis(values, min, max) {
const c = count(values), d = quantile(values, 0.75) - quantile(values, 0.25);
return c && d ? Math.ceil((max - min) / (2 * d * Math.pow(c, -1 / 3))) : 1;
}
function thresholdScott(values, min, max) {
const c = count(values), d = deviation(values);
return c && d ? Math.ceil((max - min) * Math.cbrt(c) / (3.49 * d)) : 1;
}
function mean(values, valueof) {
let count = 0;
let sum = 0;
if (valueof === undefined) {
for (let value of values) {
if (value != null && (value = +value) >= value) {
++count, sum += value;
}
}
} else {
let index = -1;
for (let value of values) {
if ((value = valueof(value, ++index, values)) != null && (value = +value) >= value) {
++count, sum += value;
}
}
}
if (count) return sum / count;
}
function median(values, valueof) {
return quantile(values, 0.5, valueof);
}
function medianIndex(values, valueof) {
return quantileIndex(values, 0.5, valueof);
}
function* flatten(arrays) {
for (const array of arrays) {
yield* array;
}
}
function merge(arrays) {
return Array.from(flatten(arrays));
}
function mode(values, valueof) {
const counts = new InternMap();
if (valueof === undefined) {
for (let value of values) {
if (value != null && value >= value) {
counts.set(value, (counts.get(value) || 0) + 1);
}
}
} else {
let index = -1;
for (let value of values) {
if ((value = valueof(value, ++index, values)) != null && value >= value) {
counts.set(value, (counts.get(value) || 0) + 1);
}
}
}
let modeValue;
let modeCount = 0;
for (const [value, count] of counts) {
if (count > modeCount) {
modeCount = count;
modeValue = value;
}
}
return modeValue;
}
function pairs(values, pairof = pair) {
const pairs = [];
let previous;
let first = false;
for (const value of values) {
if (first) pairs.push(pairof(previous, value));
previous = value;
first = true;
}
return pairs;
}
function pair(a, b) {
return [a, b];
}
function range(start, stop, step) {
start = +start, stop = +stop, step = (n = arguments.length) < 2 ? (stop = start, start = 0, 1) : n < 3 ? 1 : +step;
var i = -1,
n = Math.max(0, Math.ceil((stop - start) / step)) | 0,
range = new Array(n);
while (++i < n) {
range[i] = start + i * step;
}
return range;
}
function rank(values, valueof = ascending) {
if (typeof values[Symbol.iterator] !== "function") throw new TypeError("values is not iterable");
let V = Array.from(values);
const R = new Float64Array(V.length);
if (valueof.length !== 2) V = V.map(valueof), valueof = ascending;
const compareIndex = (i, j) => valueof(V[i], V[j]);
let k, r;
values = Uint32Array.from(V, (_, i) => i);
// Risky chaining due to Safari 14 https://github.com/d3/d3-array/issues/123
values.sort(valueof === ascending ? (i, j) => ascendingDefined(V[i], V[j]) : compareDefined(compareIndex));
values.forEach((j, i) => {
const c = compareIndex(j, k === undefined ? j : k);
if (c >= 0) {
if (k === undefined || c > 0) k = j, r = i;
R[j] = r;
} else {
R[j] = NaN;
}
});
return R;
}
function least(values, compare = ascending) {
let min;
let defined = false;
if (compare.length === 1) {
let minValue;
for (const element of values) {
const value = compare(element);
if (defined
? ascending(value, minValue) < 0
: ascending(value, value) === 0) {
min = element;
minValue = value;
defined = true;
}
}
} else {
for (const value of values) {
if (defined
? compare(value, min) < 0
: compare(value, value) === 0) {
min = value;
defined = true;
}
}
}
return min;
}
function leastIndex(values, compare = ascending) {
if (compare.length === 1) return minIndex(values, compare);
let minValue;
let min = -1;
let index = -1;
for (const value of values) {
++index;
if (min < 0
? compare(value, value) === 0
: compare(value, minValue) < 0) {
minValue = value;
min = index;
}
}
return min;
}
function greatestIndex(values, compare = ascending) {
if (compare.length === 1) return maxIndex(values, compare);
let maxValue;
let max = -1;
let index = -1;
for (const value of values) {
++index;
if (max < 0
? compare(value, value) === 0
: compare(value, maxValue) > 0) {
maxValue = value;
max = index;
}
}
return max;
}
function scan(values, compare) {
const index = leastIndex(values, compare);
return index < 0 ? undefined : index;
}
var shuffle = shuffler(Math.random);
function shuffler(random) {
return function shuffle(array, i0 = 0, i1 = array.length) {
let m = i1 - (i0 = +i0);
while (m) {
const i = random() * m-- | 0, t = array[m + i0];
array[m + i0] = array[i + i0];
array[i + i0] = t;
}
return array;
};
}
function sum(values, valueof) {
let sum = 0;
if (valueof === undefined) {
for (let value of values) {
if (value = +value) {
sum += value;
}
}
} else {
let index = -1;
for (let value of values) {
if (value = +valueof(value, ++index, values)) {
sum += value;
}
}
}
return sum;
}
function transpose(matrix) {
if (!(n = matrix.length)) return [];
for (var i = -1, m = min(matrix, length), transpose = new Array(m); ++i < m;) {
for (var j = -1, n, row = transpose[i] = new Array(n); ++j < n;) {
row[j] = matrix[j][i];
}
}
return transpose;
}
function length(d) {
return d.length;
}
function zip() {
return transpose(arguments);
}
function every(values, test) {
if (typeof test !== "function") throw new TypeError("test is not a function");
let index = -1;
for (const value of values) {
if (!test(value, ++index, values)) {
return false;
}
}
return true;
}
function some(values, test) {
if (typeof test !== "function") throw new TypeError("test is not a function");
let index = -1;
for (const value of values) {
if (test(value, ++index, values)) {
return true;
}
}
return false;
}
function filter(values, test) {
if (typeof test !== "function") throw new TypeError("test is not a function");
const array = [];
let index = -1;
for (const value of values) {
if (test(value, ++index, values)) {
array.push(value);
}
}
return array;
}
function map(values, mapper) {
if (typeof values[Symbol.iterator] !== "function") throw new TypeError("values is not iterable");
if (typeof mapper !== "function") throw new TypeError("mapper is not a function");
return Array.from(values, (value, index) => mapper(value, index, values));
}
function reduce(values, reducer, value) {
if (typeof reducer !== "function") throw new TypeError("reducer is not a function");
const iterator = values[Symbol.iterator]();
let done, next, index = -1;
if (arguments.length < 3) {
({done, value} = iterator.next());
if (done) return;
++index;
}
while (({done, value: next} = iterator.next()), !done) {
value = reducer(value, next, ++index, values);
}
return value;
}
function reverse(values) {
if (typeof values[Symbol.iterator] !== "function") throw new TypeError("values is not iterable");
return Array.from(values).reverse();
}
function difference(values, ...others) {
values = new InternSet(values);
for (const other of others) {
for (const value of other) {
values.delete(value);
}
}
return values;
}
function disjoint(values, other) {
const iterator = other[Symbol.iterator](), set = new InternSet();
for (const v of values) {
if (set.has(v)) return false;
let value, done;
while (({value, done} = iterator.next())) {
if (done) break;
if (Object.is(v, value)) return false;
set.add(value);
}
}
return true;
}
function intersection(values, ...others) {
values = new InternSet(values);
others = others.map(set);
out: for (const value of values) {
for (const other of others) {
if (!other.has(value)) {
values.delete(value);
continue out;
}
}
}
return values;
}
function set(values) {
return values instanceof InternSet ? values : new InternSet(values);
}
function superset(values, other) {
const iterator = values[Symbol.iterator](), set = new Set();
for (const o of other) {
const io = intern(o);
if (set.has(io)) continue;
let value, done;
while (({value, done} = iterator.next())) {
if (done) return false;
const ivalue = intern(value);
set.add(ivalue);
if (Object.is(io, ivalue)) break;
}
}
return true;
}
function intern(value) {
return value !== null && typeof value === "object" ? value.valueOf() : value;
}
function subset(values, other) {
return superset(other, values);
}
function union(...others) {
const set = new InternSet();
for (const other of others) {
for (const o of other) {
set.add(o);
}
}
return set;
}
exports.Adder = Adder;
exports.InternMap = InternMap;
exports.InternSet = InternSet;
exports.ascending = ascending;
exports.bin = bin;
exports.bisect = bisect;
exports.bisectCenter = bisectCenter;
exports.bisectLeft = bisectLeft;
exports.bisectRight = bisectRight;
exports.bisector = bisector;
exports.blur = blur;
exports.blur2 = blur2;
exports.blurImage = blurImage;
exports.count = count;
exports.cross = cross;
exports.cumsum = cumsum;
exports.descending = descending;
exports.deviation = deviation;
exports.difference = difference;
exports.disjoint = disjoint;
exports.every = every;
exports.extent = extent;
exports.fcumsum = fcumsum;
exports.filter = filter;
exports.flatGroup = flatGroup;
exports.flatRollup = flatRollup;
exports.fsum = fsum;
exports.greatest = greatest;
exports.greatestIndex = greatestIndex;
exports.group = group;
exports.groupSort = groupSort;
exports.groups = groups;
exports.histogram = bin;
exports.index = index;
exports.indexes = indexes;
exports.intersection = intersection;
exports.least = least;
exports.leastIndex = leastIndex;
exports.map = map;
exports.max = max;
exports.maxIndex = maxIndex;
exports.mean = mean;
exports.median = median;
exports.medianIndex = medianIndex;
exports.merge = merge;
exports.min = min;
exports.minIndex = minIndex;
exports.mode = mode;
exports.nice = nice;
exports.pairs = pairs;
exports.permute = permute;
exports.quantile = quantile;
exports.quantileIndex = quantileIndex;
exports.quantileSorted = quantileSorted;
exports.quickselect = quickselect;
exports.range = range;
exports.rank = rank;
exports.reduce = reduce;
exports.reverse = reverse;
exports.rollup = rollup;
exports.rollups = rollups;
exports.scan = scan;
exports.shuffle = shuffle;
exports.shuffler = shuffler;
exports.some = some;
exports.sort = sort;
exports.subset = subset;
exports.sum = sum;
exports.superset = superset;
exports.thresholdFreedmanDiaconis = thresholdFreedmanDiaconis;
exports.thresholdScott = thresholdScott;
exports.thresholdSturges = thresholdSturges;
exports.tickIncrement = tickIncrement;
exports.tickStep = tickStep;
exports.ticks = ticks;
exports.transpose = transpose;
exports.union = union;
exports.variance = variance;
exports.zip = zip;
}));