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	// DEFLATE is a complex format; to read this code, you should probably check the RFC first:
	// https://tools.ietf.org/html/rfc1951
	// You may also wish to take a look at the guide I made about this program:
	// https://gist.github.com/101arrowz/253f31eb5abc3d9275ab943003ffecad
	// Much of the following code is similar to that of UZIP.js:
	// https://github.com/photopea/UZIP.js
	// Many optimizations have been made, so the bundle size is ultimately smaller but performance is similar.
	// Sometimes 0 will appear where -1 would be more appropriate. This is because using a uint
	// is better for memory in most engines (I think).
	var ch2 = {};
	var wk = (function (c, id, msg, transfer, cb) {
	var u = ch2[id] \|\| (ch2[id] = URL.createObjectURL(new Blob([c], { type: 'text/javascript' })));
	var w = new Worker(u);
	w.onerror = function (e) { return cb(e.error, null); };
	w.onmessage = function (e) { return cb(null, e.data); };
	w.postMessage(msg, transfer);
	return w;
	});

	// aliases for shorter compressed code (most minifers don't do this)
	var u8 = Uint8Array, u16 = Uint16Array, u32 = Uint32Array;
	// fixed length extra bits
	var fleb = new u8([0, 0, 0, 0, 0, 0, 0, 0, 1, 1, 1, 1, 2, 2, 2, 2, 3, 3, 3, 3, 4, 4, 4, 4, 5, 5, 5, 5, 0, /* unused / 0, 0, / impossible */ 0]);
	// fixed distance extra bits
	// see fleb note
	var fdeb = new u8([0, 0, 0, 0, 1, 1, 2, 2, 3, 3, 4, 4, 5, 5, 6, 6, 7, 7, 8, 8, 9, 9, 10, 10, 11, 11, 12, 12, 13, 13, /* unused */ 0, 0]);
	// code length index map
	var clim = new u8([16, 17, 18, 0, 8, 7, 9, 6, 10, 5, 11, 4, 12, 3, 13, 2, 14, 1, 15]);
	// get base, reverse index map from extra bits
	var freb = function (eb, start) {
	var b = new u16(31);
	for (var i = 0; i < 31; ++i) {
	b[i] = start += 1 << eb[i - 1];
	}
	// numbers here are at max 18 bits
	var r = new u32(b[30]);
	for (var i = 1; i < 30; ++i) {
	for (var j = b[i]; j < b[i + 1]; ++j) {
	r[j] = ((j - b[i]) << 5) \| i;
	}
	}
	return [b, r];
	};
	var _a = freb(fleb, 2), fl = _a[0], revfl = _a[1];
	// we can ignore the fact that the other numbers are wrong; they never happen anyway
	fl[28] = 258, revfl[258] = 28;
	var _b = freb(fdeb, 0), fd = _b[0], revfd = _b[1];
	// map of value to reverse (assuming 16 bits)
	var rev = new u16(32768);
	for (var i = 0; i < 32768; ++i) {
	// reverse table algorithm from SO
	var x = ((i & 0xAAAA) >>> 1) \| ((i & 0x5555) << 1);
	x = ((x & 0xCCCC) >>> 2) \| ((x & 0x3333) << 2);
	x = ((x & 0xF0F0) >>> 4) \| ((x & 0x0F0F) << 4);
	rev[i] = (((x & 0xFF00) >>> 8) \| ((x & 0x00FF) << 8)) >>> 1;
	}
	// create huffman tree from u8 "map": index -> code length for code index
	// mb (max bits) must be at most 15
	// TODO: optimize/split up?
	var hMap = (function (cd, mb, r) {
	var s = cd.length;
	// index
	var i = 0;
	// u16 "map": index -> # of codes with bit length = index
	var l = new u16(mb);
	// length of cd must be 288 (total # of codes)
	for (; i < s; ++i)
	++l[cd[i] - 1];
	// u16 "map": index -> minimum code for bit length = index
	var le = new u16(mb);
	for (i = 0; i < mb; ++i) {
	le[i] = (le[i - 1] + l[i - 1]) << 1;
	}
	var co;
	if (r) {
	// u16 "map": index -> number of actual bits, symbol for code
	co = new u16(1 << mb);
	// bits to remove for reverser
	var rvb = 15 - mb;
	for (i = 0; i < s; ++i) {
	// ignore 0 lengths
	if (cd[i]) {
	// num encoding both symbol and bits read
	var sv = (i << 4) \| cd[i];
	// free bits
	var r_1 = mb - cd[i];
	// start value
	var v = le[cd[i] - 1]++ << r_1;
	// m is end value
	for (var m = v \| ((1 << r_1) - 1); v <= m; ++v) {
	// every 16 bit value starting with the code yields the same result
	co[rev[v] >>> rvb] = sv;
	}
	}
	}
	}
	else {
	co = new u16(s);
	for (i = 0; i < s; ++i)
	co[i] = rev[le[cd[i] - 1]++] >>> (15 - cd[i]);
	}
	return co;
	});
	// fixed length tree
	var flt = new u8(288);
	for (var i = 0; i < 144; ++i)
	flt[i] = 8;
	for (var i = 144; i < 256; ++i)
	flt[i] = 9;
	for (var i = 256; i < 280; ++i)
	flt[i] = 7;
	for (var i = 280; i < 288; ++i)
	flt[i] = 8;
	// fixed distance tree
	var fdt = new u8(32);
	for (var i = 0; i < 32; ++i)
	fdt[i] = 5;
	// fixed length map
	var flm = /#__PURE__/ hMap(flt, 9, 0), flrm = /#__PURE__/ hMap(flt, 9, 1);
	// fixed distance map
	var fdm = /#__PURE__/ hMap(fdt, 5, 0), fdrm = /#__PURE__/ hMap(fdt, 5, 1);
	// find max of array
	var max = function (a) {
	var m = a[0];
	for (var i = 1; i < a.length; ++i) {
	if (a[i] > m)
	m = a[i];
	}
	return m;
	};
	// read d, starting at bit p and mask with m
	var bits = function (d, p, m) {
	var o = (p / 8) >> 0;
	return ((d[o] \| (d[o + 1] << 8)) >>> (p & 7)) & m;
	};
	// read d, starting at bit p continuing for at least 16 bits
	var bits16 = function (d, p) {
	var o = (p / 8) >> 0;
	return ((d[o] \| (d[o + 1] << 8) \| (d[o + 2] << 16)) >>> (p & 7));
	};
	// get end of byte
	var shft = function (p) { return ((p / 8) >> 0) + (p & 7 && 1); };
	// typed array slice - allows garbage collector to free original reference,
	// while being more compatible than .slice
	var slc = function (v, s, e) {
	if (s == null \|\| s < 0)
	s = 0;
	if (e == null \|\| e > v.length)
	e = v.length;
	// can't use .constructor in case user-supplied
	var n = new (v instanceof u16 ? u16 : v instanceof u32 ? u32 : u8)(e - s);
	n.set(v.subarray(s, e));
	return n;
	};
	// expands raw DEFLATE data
	var inflt = function (dat, buf, st) {
	// source length
	var sl = dat.length;
	// have to estimate size
	var noBuf = !buf \|\| st;
	// no state
	var noSt = !st \|\| st.i;
	if (!st)
	st = {};
	// Assumes roughly 33% compression ratio average
	if (!buf)
	buf = new u8(sl * 3);
	// ensure buffer can fit at least l elements
	var cbuf = function (l) {
	var bl = buf.length;
	// need to increase size to fit
	if (l > bl) {
	// Double or set to necessary, whichever is greater
	var nbuf = new u8(Math.max(bl * 2, l));
	nbuf.set(buf);
	buf = nbuf;
	}
	};
	// last chunk bitpos bytes
	var final = st.f \|\| 0, pos = st.p \|\| 0, bt = st.b \|\| 0, lm = st.l, dm = st.d, lbt = st.m, dbt = st.n;
	// total bits
	var tbts = sl * 8;
	do {
	if (!lm) {
	// BFINAL - this is only 1 when last chunk is next
	st.f = final = bits(dat, pos, 1);
	// type: 0 = no compression, 1 = fixed huffman, 2 = dynamic huffman
	var type = bits(dat, pos + 1, 3);
	pos += 3;
	if (!type) {
	// go to end of byte boundary
	var s = shft(pos) + 4, l = dat[s - 4] \| (dat[s - 3] << 8), t = s + l;
	if (t > sl) {
	if (noSt)
	throw 'unexpected EOF';
	break;
	}
	// ensure size
	if (noBuf)
	cbuf(bt + l);
	// Copy over uncompressed data
	buf.set(dat.subarray(s, t), bt);
	// Get new bitpos, update byte count
	st.b = bt += l, st.p = pos = t * 8;
	continue;
	}
	else if (type == 1)
	lm = flrm, dm = fdrm, lbt = 9, dbt = 5;
	else if (type == 2) {
	// literal lengths
	var hLit = bits(dat, pos, 31) + 257, hcLen = bits(dat, pos + 10, 15) + 4;
	var tl = hLit + bits(dat, pos + 5, 31) + 1;
	pos += 14;
	// length+distance tree
	var ldt = new u8(tl);
	// code length tree
	var clt = new u8(19);
	for (var i = 0; i < hcLen; ++i) {
	// use index map to get real code
	clt[clim[i]] = bits(dat, pos + i * 3, 7);
	}
	pos += hcLen * 3;
	// code lengths bits
	var clb = max(clt), clbmsk = (1 << clb) - 1;
	if (!noSt && pos + tl * (clb + 7) > tbts)
	break;
	// code lengths map
	var clm = hMap(clt, clb, 1);
	for (var i = 0; i < tl;) {
	var r = clm[bits(dat, pos, clbmsk)];
	// bits read
	pos += r & 15;
	// symbol
	var s = r >>> 4;
	// code length to copy
	if (s < 16) {
	ldt[i++] = s;
	}
	else {
	// copy count
	var c = 0, n = 0;
	if (s == 16)
	n = 3 + bits(dat, pos, 3), pos += 2, c = ldt[i - 1];
	else if (s == 17)
	n = 3 + bits(dat, pos, 7), pos += 3;
	else if (s == 18)
	n = 11 + bits(dat, pos, 127), pos += 7;
	while (n--)
	ldt[i++] = c;
	}
	}
	// length tree distance tree
	var lt = ldt.subarray(0, hLit), dt = ldt.subarray(hLit);
	// max length bits
	lbt = max(lt);
	// max dist bits
	dbt = max(dt);
	lm = hMap(lt, lbt, 1);
	dm = hMap(dt, dbt, 1);
	}
	else
	throw 'invalid block type';
	if (pos > tbts)
	throw 'unexpected EOF';
	}
	// Make sure the buffer can hold this + the largest possible addition
	// Maximum chunk size (practically, theoretically infinite) is 2^17;
	if (noBuf)
	cbuf(bt + 131072);
	var lms = (1 << lbt) - 1, dms = (1 << dbt) - 1;
	var mxa = lbt + dbt + 18;
	while (noSt \|\| pos + mxa < tbts) {
	// bits read, code
	var c = lm[bits16(dat, pos) & lms], sym = c >>> 4;
	pos += c & 15;
	if (pos > tbts)
	throw 'unexpected EOF';
	if (!c)
	throw 'invalid length/literal';
	if (sym < 256)
	buf[bt++] = sym;
	else if (sym == 256) {
	lm = null;
	break;
	}
	else {
	var add = sym - 254;
	// no extra bits needed if less
	if (sym > 264) {
	// index
	var i = sym - 257, b = fleb[i];
	add = bits(dat, pos, (1 << b) - 1) + fl[i];
	pos += b;
	}
	// dist
	var d = dm[bits16(dat, pos) & dms], dsym = d >>> 4;
	if (!d)
	throw 'invalid distance';
	pos += d & 15;
	var dt = fd[dsym];
	if (dsym > 3) {
	var b = fdeb[dsym];
	dt += bits16(dat, pos) & ((1 << b) - 1), pos += b;
	}
	if (pos > tbts)
	throw 'unexpected EOF';
	if (noBuf)
	cbuf(bt + 131072);
	var end = bt + add;
	for (; bt < end; bt += 4) {
	buf[bt] = buf[bt - dt];
	buf[bt + 1] = buf[bt + 1 - dt];
	buf[bt + 2] = buf[bt + 2 - dt];
	buf[bt + 3] = buf[bt + 3 - dt];
	}
	bt = end;
	}
	}
	st.l = lm, st.p = pos, st.b = bt;
	if (lm)
	final = 1, st.m = lbt, st.d = dm, st.n = dbt;
	} while (!final);
	return bt == buf.length ? buf : slc(buf, 0, bt);
	};
	// starting at p, write the minimum number of bits that can hold v to d
	var wbits = function (d, p, v) {
	v <<= p & 7;
	var o = (p / 8) >> 0;
	d[o] \|= v;
	d[o + 1] \|= v >>> 8;
	};
	// starting at p, write the minimum number of bits (>8) that can hold v to d
	var wbits16 = function (d, p, v) {
	v <<= p & 7;
	var o = (p / 8) >> 0;
	d[o] \|= v;
	d[o + 1] \|= v >>> 8;
	d[o + 2] \|= v >>> 16;
	};
	// creates code lengths from a frequency table
	var hTree = function (d, mb) {
	// Need extra info to make a tree
	var t = [];
	for (var i = 0; i < d.length; ++i) {
	if (d[i])
	t.push({ s: i, f: d[i] });
	}
	var s = t.length;
	var t2 = t.slice();
	if (!s)
	return [new u8(0), 0];
	if (s == 1) {
	var v = new u8(t[0].s + 1);
	v[t[0].s] = 1;
	return [v, 1];
	}
	t.sort(function (a, b) { return a.f - b.f; });
	// after i2 reaches last ind, will be stopped
	// freq must be greater than largest possible number of symbols
	t.push({ s: -1, f: 25001 });
	var l = t[0], r = t[1], i0 = 0, i1 = 1, i2 = 2;
	t[0] = { s: -1, f: l.f + r.f, l: l, r: r };
	// efficient algorithm from UZIP.js
	// i0 is lookbehind, i2 is lookahead - after processing two low-freq
	// symbols that combined have high freq, will start processing i2 (high-freq,
	// non-composite) symbols instead
	// see https://reddit.com/r/photopea/comments/ikekht/uzipjs_questions/
	while (i1 != s - 1) {
	l = t[t[i0].f < t[i2].f ? i0++ : i2++];
	r = t[i0 != i1 && t[i0].f < t[i2].f ? i0++ : i2++];
	t[i1++] = { s: -1, f: l.f + r.f, l: l, r: r };
	}
	var maxSym = t2[0].s;
	for (var i = 1; i < s; ++i) {
	if (t2[i].s > maxSym)
	maxSym = t2[i].s;
	}
	// code lengths
	var tr = new u16(maxSym + 1);
	// max bits in tree
	var mbt = ln(t[i1 - 1], tr, 0);
	if (mbt > mb) {
	// more algorithms from UZIP.js
	// TODO: find out how this code works (debt)
	// ind debt
	var i = 0, dt = 0;
	// left cost
	var lft = mbt - mb, cst = 1 << lft;
	t2.sort(function (a, b) { return tr[b.s] - tr[a.s] \|\| a.f - b.f; });
	for (; i < s; ++i) {
	var i2_1 = t2[i].s;
	if (tr[i2_1] > mb) {
	dt += cst - (1 << (mbt - tr[i2_1]));
	tr[i2_1] = mb;
	}
	else
	break;
	}
	dt >>>= lft;
	while (dt > 0) {
	var i2_2 = t2[i].s;
	if (tr[i2_2] < mb)
	dt -= 1 << (mb - tr[i2_2]++ - 1);
	else
	++i;
	}
	for (; i >= 0 && dt; --i) {
	var i2_3 = t2[i].s;
	if (tr[i2_3] == mb) {
	--tr[i2_3];
	++dt;
	}
	}
	mbt = mb;
	}
	return [new u8(tr), mbt];
	};
	// get the max length and assign length codes
	var ln = function (n, l, d) {
	return n.s == -1
	? Math.max(ln(n.l, l, d + 1), ln(n.r, l, d + 1))
	: (l[n.s] = d);
	};
	// length codes generation
	var lc = function (c) {
	var s = c.length;
	// Note that the semicolon was intentional
	while (s && !c[--s])
	;
	var cl = new u16(++s);
	// ind num streak
	var cli = 0, cln = c[0], cls = 1;
	var w = function (v) { cl[cli++] = v; };
	for (var i = 1; i <= s; ++i) {
	if (c[i] == cln && i != s)
	++cls;
	else {
	if (!cln && cls > 2) {
	for (; cls > 138; cls -= 138)
	w(32754);
	if (cls > 2) {
	w(cls > 10 ? ((cls - 11) << 5) \| 28690 : ((cls - 3) << 5) \| 12305);
	cls = 0;
	}
	}
	else if (cls > 3) {
	w(cln), --cls;
	for (; cls > 6; cls -= 6)
	w(8304);
	if (cls > 2)
	w(((cls - 3) << 5) \| 8208), cls = 0;
	}
	while (cls--)
	w(cln);
	cls = 1;
	cln = c[i];
	}
	}
	return [cl.subarray(0, cli), s];
	};
	// calculate the length of output from tree, code lengths
	var clen = function (cf, cl) {
	var l = 0;
	for (var i = 0; i < cl.length; ++i)
	l += cf[i] * cl[i];
	return l;
	};
	// writes a fixed block
	// returns the new bit pos
	var wfblk = function (out, pos, dat) {
	// no need to write 00 as type: TypedArray defaults to 0
	var s = dat.length;
	var o = shft(pos + 2);
	out[o] = s & 255;
	out[o + 1] = s >>> 8;
	out[o + 2] = out[o] ^ 255;
	out[o + 3] = out[o + 1] ^ 255;
	for (var i = 0; i < s; ++i)
	out[o + i + 4] = dat[i];
	return (o + 4 + s) * 8;
	};
	// writes a block
	var wblk = function (dat, out, final, syms, lf, df, eb, li, bs, bl, p) {
	wbits(out, p++, final);
	++lf[256];
	var _a = hTree(lf, 15), dlt = _a[0], mlb = _a[1];
	var _b = hTree(df, 15), ddt = _b[0], mdb = _b[1];
	var _c = lc(dlt), lclt = _c[0], nlc = _c[1];
	var _d = lc(ddt), lcdt = _d[0], ndc = _d[1];
	var lcfreq = new u16(19);
	for (var i = 0; i < lclt.length; ++i)
	lcfreq[lclt[i] & 31]++;
	for (var i = 0; i < lcdt.length; ++i)
	lcfreq[lcdt[i] & 31]++;
	var _e = hTree(lcfreq, 7), lct = _e[0], mlcb = _e[1];
	var nlcc = 19;
	for (; nlcc > 4 && !lct[clim[nlcc - 1]]; --nlcc)
	;
	var flen = (bl + 5) << 3;
	var ftlen = clen(lf, flt) + clen(df, fdt) + eb;
	var dtlen = clen(lf, dlt) + clen(df, ddt) + eb + 14 + 3 * nlcc + clen(lcfreq, lct) + (2 * lcfreq[16] + 3 * lcfreq[17] + 7 * lcfreq[18]);
	if (flen <= ftlen && flen <= dtlen)
	return wfblk(out, p, dat.subarray(bs, bs + bl));
	var lm, ll, dm, dl;
	wbits(out, p, 1 + (dtlen < ftlen)), p += 2;
	if (dtlen < ftlen) {
	lm = hMap(dlt, mlb, 0), ll = dlt, dm = hMap(ddt, mdb, 0), dl = ddt;
	var llm = hMap(lct, mlcb, 0);
	wbits(out, p, nlc - 257);
	wbits(out, p + 5, ndc - 1);
	wbits(out, p + 10, nlcc - 4);
	p += 14;
	for (var i = 0; i < nlcc; ++i)
	wbits(out, p + 3 * i, lct[clim[i]]);
	p += 3 * nlcc;
	var lcts = [lclt, lcdt];
	for (var it = 0; it < 2; ++it) {
	var clct = lcts[it];
	for (var i = 0; i < clct.length; ++i) {
	var len = clct[i] & 31;
	wbits(out, p, llm[len]), p += lct[len];
	if (len > 15)
	wbits(out, p, (clct[i] >>> 5) & 127), p += clct[i] >>> 12;
	}
	}
	}
	else {
	lm = flm, ll = flt, dm = fdm, dl = fdt;
	}
	for (var i = 0; i < li; ++i) {
	if (syms[i] > 255) {
	var len = (syms[i] >>> 18) & 31;
	wbits16(out, p, lm[len + 257]), p += ll[len + 257];
	if (len > 7)
	wbits(out, p, (syms[i] >>> 23) & 31), p += fleb[len];
	var dst = syms[i] & 31;
	wbits16(out, p, dm[dst]), p += dl[dst];
	if (dst > 3)
	wbits16(out, p, (syms[i] >>> 5) & 8191), p += fdeb[dst];
	}
	else {
	wbits16(out, p, lm[syms[i]]), p += ll[syms[i]];
	}
	}
	wbits16(out, p, lm[256]);
	return p + ll[256];
	};
	// deflate options (nice << 13) \| chain
	var deo = /#__PURE__/ new u32([65540, 131080, 131088, 131104, 262176, 1048704, 1048832, 2114560, 2117632]);
	// empty
	var et = /#__PURE__/ new u8(0);
	// compresses data into a raw DEFLATE buffer
	var dflt = function (dat, lvl, plvl, pre, post, lst) {
	var s = dat.length;
	var o = new u8(pre + s + 5 * (1 + Math.floor(s / 7000)) + post);
	// writing to this writes to the output buffer
	var w = o.subarray(pre, o.length - post);
	var pos = 0;
	if (!lvl \|\| s < 8) {
	for (var i = 0; i <= s; i += 65535) {
	// end
	var e = i + 65535;
	if (e < s) {
	// write full block
	pos = wfblk(w, pos, dat.subarray(i, e));
	}
	else {
	// write final block
	w[i] = lst;
	pos = wfblk(w, pos, dat.subarray(i, s));
	}
	}
	}
	else {
	var opt = deo[lvl - 1];
	var n = opt >>> 13, c = opt & 8191;
	var msk_1 = (1 << plvl) - 1;
	// prev 2-byte val map curr 2-byte val map
	var prev = new u16(32768), head = new u16(msk_1 + 1);
	var bs1_1 = Math.ceil(plvl / 3), bs2_1 = 2 * bs1_1;
	var hsh = function (i) { return (dat[i] ^ (dat[i + 1] << bs1_1) ^ (dat[i + 2] << bs2_1)) & msk_1; };
	// 24576 is an arbitrary number of maximum symbols per block
	// 424 buffer for last block
	var syms = new u32(25000);
	// length/literal freq distance freq
	var lf = new u16(288), df = new u16(32);
	// l/lcnt exbits index l/lind waitdx bitpos
	var lc_1 = 0, eb = 0, i = 0, li = 0, wi = 0, bs = 0;
	for (; i < s; ++i) {
	// hash value
	var hv = hsh(i);
	// index mod 32768
	var imod = i & 32767;
	// previous index with this value
	var pimod = head[hv];
	prev[imod] = pimod;
	head[hv] = imod;
	// We always should modify head and prev, but only add symbols if
	// this data is not yet processed ("wait" for wait index)
	if (wi <= i) {
	// bytes remaining
	var rem = s - i;
	if ((lc_1 > 7000 \|\| li > 24576) && rem > 423) {
	pos = wblk(dat, w, 0, syms, lf, df, eb, li, bs, i - bs, pos);
	li = lc_1 = eb = 0, bs = i;
	for (var j = 0; j < 286; ++j)
	lf[j] = 0;
	for (var j = 0; j < 30; ++j)
	df[j] = 0;
	}
	// len dist chain
	var l = 2, d = 0, ch_1 = c, dif = (imod - pimod) & 32767;
	if (rem > 2 && hv == hsh(i - dif)) {
	var maxn = Math.min(n, rem) - 1;
	var maxd = Math.min(32767, i);
	// max possible length
	// not capped at dif because decompressors implement "rolling" index population
	var ml = Math.min(258, rem);
	while (dif <= maxd && --ch_1 && imod != pimod) {
	if (dat[i + l] == dat[i + l - dif]) {
	var nl = 0;
	for (; nl < ml && dat[i + nl] == dat[i + nl - dif]; ++nl)
	;
	if (nl > l) {
	l = nl, d = dif;
	// break out early when we reach "nice" (we are satisfied enough)
	if (nl > maxn)
	break;
	// now, find the rarest 2-byte sequence within this
	// length of literals and search for that instead.
	// Much faster than just using the start
	var mmd = Math.min(dif, nl - 2);
	var md = 0;
	for (var j = 0; j < mmd; ++j) {
	var ti = (i - dif + j + 32768) & 32767;
	var pti = prev[ti];
	var cd = (ti - pti + 32768) & 32767;
	if (cd > md)
	md = cd, pimod = ti;
	}
	}
	}
	// check the previous match
	imod = pimod, pimod = prev[imod];
	dif += (imod - pimod + 32768) & 32767;
	}
	}
	// d will be nonzero only when a match was found
	if (d) {
	// store both dist and len data in one Uint32
	// Make sure this is recognized as a len/dist with 28th bit (2^28)
	syms[li++] = 268435456 \| (revfl[l] << 18) \| revfd[d];
	var lin = revfl[l] & 31, din = revfd[d] & 31;
	eb += fleb[lin] + fdeb[din];
	++lf[257 + lin];
	++df[din];
	wi = i + l;
	++lc_1;
	}
	else {
	syms[li++] = dat[i];
	++lf[dat[i]];
	}
	}
	}
	pos = wblk(dat, w, lst, syms, lf, df, eb, li, bs, i - bs, pos);
	// this is the easiest way to avoid needing to maintain state
	if (!lst)
	pos = wfblk(w, pos, et);
	}
	return slc(o, 0, pre + shft(pos) + post);
	};
	// CRC32 table
	var crct = /#__PURE__/ (function () {
	var t = new u32(256);
	for (var i = 0; i < 256; ++i) {
	var c = i, k = 9;
	while (--k)
	c = ((c & 1) && 0xEDB88320) ^ (c >>> 1);
	t[i] = c;
	}
	return t;
	})();
	// CRC32
	var crc = function () {
	var c = 0xFFFFFFFF;
	return {
	p: function (d) {
	// closures have awful performance
	var cr = c;
	for (var i = 0; i < d.length; ++i)
	cr = crct[(cr & 255) ^ d[i]] ^ (cr >>> 8);
	c = cr;
	},
	d: function () { return c ^ 0xFFFFFFFF; }
	};
	};
	// Alder32
	var adler = function () {
	var a = 1, b = 0;
	return {
	p: function (d) {
	// closures have awful performance
	var n = a, m = b;
	var l = d.length;
	for (var i = 0; i != l;) {
	var e = Math.min(i + 5552, l);
	for (; i < e; ++i)
	n += d[i], m += n;
	n %= 65521, m %= 65521;
	}
	a = n, b = m;
	},
	d: function () { return ((a >>> 8) << 16 \| (b & 255) << 8 \| (b >>> 8)) + ((a & 255) << 23) * 2; }
	};
	};
	;
	// deflate with opts
	var dopt = function (dat, opt, pre, post, st) {
	return dflt(dat, opt.level == null ? 6 : opt.level, opt.mem == null ? Math.ceil(Math.max(8, Math.min(13, Math.log(dat.length))) * 1.5) : (12 + opt.mem), pre, post, !st);
	};
	// Walmart object spread
	var mrg = function (a, b) {
	var o = {};
	for (var k in a)
	o[k] = a[k];
	for (var k in b)
	o[k] = b[k];
	return o;
	};
	// worker clone
	// This is possibly the craziest part of the entire codebase, despite how simple it may seem.
	// The only parameter to this function is a closure that returns an array of variables outside of the function scope.
	// We're going to try to figure out the variable names used in the closure as strings because that is crucial for workerization.
	// We will return an object mapping of true variable name to value (basically, the current scope as a JS object).
	// The reason we can't just use the original variable names is minifiers mangling the toplevel scope.
	// This took me three weeks to figure out how to do.
	var wcln = function (fn, fnStr, td) {
	var dt = fn();
	var st = fn.toString();
	var ks = st.slice(st.indexOf('[') + 1, st.lastIndexOf(']')).replace(/ /g, '').split(',');
	for (var i = 0; i < dt.length; ++i) {
	var v = dt[i], k = ks[i];
	if (typeof v == 'function') {
	fnStr += ';' + k + '=';
	var st_1 = v.toString();
	if (v.prototype) {
	// for global objects
	if (st_1.indexOf('[native code]') != -1) {
	var spInd = st_1.indexOf(' ', 8) + 1;
	fnStr += st_1.slice(spInd, st_1.indexOf('(', spInd));
	}
	else {
	fnStr += st_1;
	for (var t in v.prototype)
	fnStr += ';' + k + '.prototype.' + t + '=' + v.prototype[t].toString();
	}
	}
	else
	fnStr += st_1;
	}
	else
	td[k] = v;
	}
	return [fnStr, td];
	};
	var ch = [];
	// clone bufs
	var cbfs = function (v) {
	var tl = [];
	for (var k in v) {
	if (v[k] instanceof u8 \|\| v[k] instanceof u16 \|\| v[k] instanceof u32)
	tl.push((v[k] = new v[k].constructor(v[k])).buffer);
	}
	return tl;
	};
	// use a worker to execute code
	var wrkr = function (fns, init, id, cb) {
	var _a;
	if (!ch[id]) {
	var fnStr = '', td_1 = {}, m = fns.length - 1;
	for (var i = 0; i < m; ++i)
	_a = wcln(fns[i], fnStr, td_1), fnStr = _a[0], td_1 = _a[1];
	ch[id] = wcln(fns[m], fnStr, td_1);
	}
	var td = mrg({}, ch[id][1]);
	return wk(ch[id][0] + ';onmessage=function(e){for(var k in e.data)self[k]=e.data[k];onmessage=' + init.toString() + '}', id, td, cbfs(td), cb);
	};
	// base async inflate fn
	var bInflt = function () { return [u8, u16, u32, fleb, fdeb, clim, fl, fd, flrm, fdrm, rev, hMap, max, bits, bits16, shft, slc, inflt, inflateSync, pbf, gu8]; };
	var bDflt = function () { return [u8, u16, u32, fleb, fdeb, clim, revfl, revfd, flm, flt, fdm, fdt, rev, deo, et, hMap, wbits, wbits16, hTree, ln, lc, clen, wfblk, wblk, shft, slc, dflt, dopt, deflateSync, pbf]; };
	// gzip extra
	var gze = function () { return [gzh, gzhl, wbytes, crc, crct]; };
	// gunzip extra
	var guze = function () { return [gzs, gzl]; };
	// zlib extra
	var zle = function () { return [zlh, wbytes, adler]; };
	// unzlib extra
	var zule = function () { return [zlv]; };
	// post buf
	var pbf = function (msg) { return postMessage(msg, [msg.buffer]); };
	// get u8
	var gu8 = function (o) { return o && o.size && new u8(o.size); };
	// async helper
	var cbify = function (dat, opts, fns, init, id, cb) {
	var w = wrkr(fns, init, id, function (err, dat) {
	w.terminate();
	cb(err, dat);
	});
	if (!opts.consume)
	dat = new u8(dat);
	w.postMessage([dat, opts], [dat.buffer]);
	return function () { w.terminate(); };
	};
	// auto stream
	var astrm = function (strm) {
	strm.ondata = function (dat, final) { return postMessage([dat, final], [dat.buffer]); };
	return function (ev) { return strm.push(ev.data[0], ev.data[1]); };
	};
	// async stream attach
	var astrmify = function (fns, strm, opts, init, id) {
	var t;
	var w = wrkr(fns, init, id, function (err, dat) {
	if (err)
	w.terminate(), strm.ondata.call(strm, err);
	else {
	if (dat[1])
	w.terminate();
	strm.ondata.call(strm, err, dat[0], dat[1]);
	}
	});
	w.postMessage(opts);
	strm.push = function (d, f) {
	if (t)
	throw 'stream finished';
	if (!strm.ondata)
	throw 'no stream handler';
	w.postMessage([d, t = f], [d.buffer]);
	};
	strm.terminate = function () { w.terminate(); };
	};
	// read 2 bytes
	var b2 = function (d, b) { return d[b] \| (d[b + 1] << 8); };
	// read 4 bytes
	var b4 = function (d, b) { return (d[b] \| (d[b + 1] << 8) \| (d[b + 2] << 16)) + (d[b + 3] << 23) * 2; };
	// write bytes
	var wbytes = function (d, b, v) {
	for (; v; ++b)
	d[b] = v, v >>>= 8;
	};
	// gzip header
	var gzh = function (c, o) {
	var fn = o.filename;
	c[0] = 31, c[1] = 139, c[2] = 8, c[8] = o.level < 2 ? 4 : o.level == 9 ? 2 : 0, c[9] = 3; // assume Unix
	if (o.mtime != 0)
	wbytes(c, 4, Math.floor(new Date(o.mtime \|\| Date.now()) / 1000));
	if (fn) {
	c[3] = 8;
	for (var i = 0; i <= fn.length; ++i)
	c[i + 10] = fn.charCodeAt(i);
	}
	};
	// gzip footer: -8 to -4 = CRC, -4 to -0 is length
	// gzip start
	var gzs = function (d) {
	if (d[0] != 31 \|\| d[1] != 139 \|\| d[2] != 8)
	throw 'invalid gzip data';
	var flg = d[3];
	var st = 10;
	if (flg & 4)
	st += d[10] \| (d[11] << 8) + 2;
	for (var zs = (flg >> 3 & 1) + (flg >> 4 & 1); zs > 0; zs -= !d[st++])
	;
	return st + (flg & 2);
	};
	// gzip length
	var gzl = function (d) {
	var l = d.length;
	return (d[l - 4] \| d[l - 3] << 8 \| d[l - 2] << 16) + (2 * (d[l - 1] << 23));
	};
	// gzip header length
	var gzhl = function (o) { return 10 + ((o.filename && (o.filename.length + 1)) \|\| 0); };
	// zlib header
	var zlh = function (c, o) {
	var lv = o.level, fl = lv == 0 ? 0 : lv < 6 ? 1 : lv == 9 ? 3 : 2;
	c[0] = 120, c[1] = (fl << 6) \| (fl ? (32 - 2 * fl) : 1);
	};
	// zlib valid
	var zlv = function (d) {
	if ((d[0] & 15) != 8 \|\| (d[0] >>> 4) > 7 \|\| ((d[0] << 8 \| d[1]) % 31))
	throw 'invalid zlib data';
	if (d[1] & 32)
	throw 'invalid zlib data: preset dictionaries not supported';
	};
	function AsyncCmpStrm(opts, cb) {
	if (!cb && typeof opts == 'function')
	cb = opts, opts = {};
	this.ondata = cb;
	return opts;
	}
	// zlib footer: -4 to -0 is Adler32
	/**
	* Streaming DEFLATE compression
	*/
	var Deflate = /#__PURE__/ (function () {
	function Deflate(opts, cb) {
	if (!cb && typeof opts == 'function')
	cb = opts, opts = {};
	this.ondata = cb;
	this.o = opts \|\| {};
	}
	Deflate.prototype.p = function (c, f) {
	this.ondata(dopt(c, this.o, 0, 0, !f), f);
	};
	/**
	* Pushes a chunk to be deflated
	* @param chunk The chunk to push
	* @param final Whether this is the last chunk
	*/
	Deflate.prototype.push = function (chunk, final) {
	if (this.d)
	throw 'stream finished';
	if (!this.ondata)
	throw 'no stream handler';
	this.d = final;
	this.p(chunk, final \|\| false);
	};
	return Deflate;
	}());
	export { Deflate };
	/**
	* Asynchronous streaming DEFLATE compression
	*/
	var AsyncDeflate = /#__PURE__/ (function () {
	function AsyncDeflate(opts, cb) {
	astrmify([
	bDflt,
	function () { return [astrm, Deflate]; }
	], this, AsyncCmpStrm.call(this, opts, cb), function (ev) {
	var strm = new Deflate(ev.data);
	onmessage = astrm(strm);
	}, 6);
	}
	return AsyncDeflate;
	}());
	export { AsyncDeflate };
	export function deflate(data, opts, cb) {
	if (!cb)
	cb = opts, opts = {};
	if (typeof cb != 'function')
	throw 'no callback';
	return cbify(data, opts, [
	bDflt,
	], function (ev) { return pbf(deflateSync(ev.data[0], ev.data[1])); }, 0, cb);
	}
	/**
	* Compresses data with DEFLATE without any wrapper
	* @param data The data to compress
	* @param opts The compression options
	* @returns The deflated version of the data
	*/
	export function deflateSync(data, opts) {
	if (opts === void 0) { opts = {}; }
	return dopt(data, opts, 0, 0);
	}
	/**
	* Streaming DEFLATE decompression
	*/
	var Inflate = /#__PURE__/ (function () {
	/**
	* Creates an inflation stream
	* @param cb The callback to call whenever data is inflated
	*/
	function Inflate(cb) {
	this.s = {};
	this.p = new u8(0);
	this.ondata = cb;
	}
	Inflate.prototype.e = function (c) {
	if (this.d)
	throw 'stream finished';
	if (!this.ondata)
	throw 'no stream handler';
	var l = this.p.length;
	var n = new u8(l + c.length);
	n.set(this.p), n.set(c, l), this.p = n;
	};
	Inflate.prototype.c = function (final) {
	this.d = this.s.i = final \|\| false;
	var bts = this.s.b;
	var dt = inflt(this.p, this.o, this.s);
	this.ondata(slc(dt, bts, this.s.b), this.d);
	this.o = slc(dt, this.s.b - 32768), this.s.b = this.o.length;
	this.p = slc(this.p, (this.s.p / 8) >> 0), this.s.p &= 7;
	};
	/**
	* Pushes a chunk to be inflated
	* @param chunk The chunk to push
	* @param final Whether this is the final chunk
	*/
	Inflate.prototype.push = function (chunk, final) {
	this.e(chunk), this.c(final);
	};
	return Inflate;
	}());
	export { Inflate };
	/**
	* Asynchronous streaming DEFLATE decompression
	*/
	var AsyncInflate = /#__PURE__/ (function () {
	/**
	* Creates an asynchronous inflation stream
	* @param cb The callback to call whenever data is deflated
	*/
	function AsyncInflate(cb) {
	this.ondata = cb;
	astrmify([
	bInflt,
	function () { return [astrm, Inflate]; }
	], this, 0, function () {
	var strm = new Inflate();
	onmessage = astrm(strm);
	}, 7);
	}
	return AsyncInflate;
	}());
	export { AsyncInflate };
	export function inflate(data, opts, cb) {
	if (!cb)
	cb = opts, opts = {};
	if (typeof cb != 'function')
	throw 'no callback';
	return cbify(data, opts, [
	bInflt
	], function (ev) { return pbf(inflateSync(ev.data[0], gu8(ev.data[1]))); }, 1, cb);
	}
	/**
	* Expands DEFLATE data with no wrapper
	* @param data The data to decompress
	* @param out Where to write the data. Saves memory if you know the decompressed size and provide an output buffer of that length.
	* @returns The decompressed version of the data
	*/
	export function inflateSync(data, out) {
	return inflt(data, out);
	}
	// before you yell at me for not just using extends, my reason is that TS inheritance is hard to workerize.
	/**
	* Streaming GZIP compression
	*/
	var Gzip = /#__PURE__/ (function () {
	function Gzip(opts, cb) {
	this.c = crc();
	this.l = 0;
	this.v = 1;
	Deflate.call(this, opts, cb);
	}
	/**
	* Pushes a chunk to be GZIPped
	* @param chunk The chunk to push
	* @param final Whether this is the last chunk
	*/
	Gzip.prototype.push = function (chunk, final) {
	Deflate.prototype.push.call(this, chunk, final);
	};
	Gzip.prototype.p = function (c, f) {
	this.c.p(c);
	this.l += c.length;
	var raw = dopt(c, this.o, this.v && gzhl(this.o), f && 8, !f);
	if (this.v)
	gzh(raw, this.o), this.v = 0;
	if (f)
	wbytes(raw, raw.length - 8, this.c.d()), wbytes(raw, raw.length - 4, this.l);
	this.ondata(raw, f);
	};
	return Gzip;
	}());
	export { Gzip };
	/**
	* Asynchronous streaming GZIP compression
	*/
	var AsyncGzip = /#__PURE__/ (function () {
	function AsyncGzip(opts, cb) {
	astrmify([
	bDflt,
	gze,
	function () { return [astrm, Deflate, Gzip]; }
	], this, AsyncCmpStrm.call(this, opts, cb), function (ev) {
	var strm = new Gzip(ev.data);
	onmessage = astrm(strm);
	}, 8);
	}
	return AsyncGzip;
	}());
	export { AsyncGzip };
	export function gzip(data, opts, cb) {
	if (!cb)
	cb = opts, opts = {};
	if (typeof cb != 'function')
	throw 'no callback';
	return cbify(data, opts, [
	bDflt,
	gze,
	function () { return [gzipSync]; }
	], function (ev) { return pbf(gzipSync(ev.data[0], ev.data[1])); }, 2, cb);
	}
	/**
	* Compresses data with GZIP
	* @param data The data to compress
	* @param opts The compression options
	* @returns The gzipped version of the data
	*/
	export function gzipSync(data, opts) {
	if (opts === void 0) { opts = {}; }
	var c = crc(), l = data.length;
	c.p(data);
	var d = dopt(data, opts, gzhl(opts), 8), s = d.length;
	return gzh(d, opts), wbytes(d, s - 8, c.d()), wbytes(d, s - 4, l), d;
	}
	/**
	* Streaming GZIP decompression
	*/
	var Gunzip = /#__PURE__/ (function () {
	/**
	* Creates a GUNZIP stream
	* @param cb The callback to call whenever data is inflated
	*/
	function Gunzip(cb) {
	this.v = 1;
	Inflate.call(this, cb);
	}
	/**
	* Pushes a chunk to be GUNZIPped
	* @param chunk The chunk to push
	* @param final Whether this is the last chunk
	*/
	Gunzip.prototype.push = function (chunk, final) {
	Inflate.prototype.e.call(this, chunk);
	if (this.v) {
	var s = gzs(this.p);
	if (s >= this.p.length && !final)
	return;
	this.p = this.p.subarray(s), this.v = 0;
	}
	if (final) {
	if (this.p.length < 8)
	throw 'invalid gzip stream';
	this.p = this.p.subarray(0, -8);
	}
	// necessary to prevent TS from using the closure value
	// This allows for workerization to function correctly
	Inflate.prototype.c.call(this, final);
	};
	return Gunzip;
	}());
	export { Gunzip };
	/**
	* Asynchronous streaming GZIP decompression
	*/
	var AsyncGunzip = /#__PURE__/ (function () {
	/**
	* Creates an asynchronous GUNZIP stream
	* @param cb The callback to call whenever data is deflated
	*/
	function AsyncGunzip(cb) {
	this.ondata = cb;
	astrmify([
	bInflt,
	guze,
	function () { return [astrm, Inflate, Gunzip]; }
	], this, 0, function () {
	var strm = new Gunzip();
	onmessage = astrm(strm);
	}, 9);
	}
	return AsyncGunzip;
	}());
	export { AsyncGunzip };
	export function gunzip(data, opts, cb) {
	if (!cb)
	cb = opts, opts = {};
	if (typeof cb != 'function')
	throw 'no callback';
	return cbify(data, opts, [
	bInflt,
	guze,
	function () { return [gunzipSync]; }
	], function (ev) { return pbf(gunzipSync(ev.data[0])); }, 3, cb);
	}
	/**
	* Expands GZIP data
	* @param data The data to decompress
	* @param out Where to write the data. GZIP already encodes the output size, so providing this doesn't save memory.
	* @returns The decompressed version of the data
	*/
	export function gunzipSync(data, out) {
	return inflt(data.subarray(gzs(data), -8), out \|\| new u8(gzl(data)));
	}
	/**
	* Streaming Zlib compression
	*/
	var Zlib = /#__PURE__/ (function () {
	function Zlib(opts, cb) {
	this.c = adler();
	this.v = 1;
	Deflate.call(this, opts, cb);
	}
	/**
	* Pushes a chunk to be zlibbed
	* @param chunk The chunk to push
	* @param final Whether this is the last chunk
	*/
	Zlib.prototype.push = function (chunk, final) {
	Deflate.prototype.push.call(this, chunk, final);
	};
	Zlib.prototype.p = function (c, f) {
	this.c.p(c);
	var raw = dopt(c, this.o, this.v && 2, f && 4, !f);
	if (this.v)
	zlh(raw, this.o), this.v = 0;
	if (f)
	wbytes(raw, raw.length - 4, this.c.d());
	this.ondata(raw, f);
	};
	return Zlib;
	}());
	export { Zlib };
	/**
	* Asynchronous streaming Zlib compression
	*/
	var AsyncZlib = /#__PURE__/ (function () {
	function AsyncZlib(opts, cb) {
	astrmify([
	bDflt,
	zle,
	function () { return [astrm, Deflate, Zlib]; }
	], this, AsyncCmpStrm.call(this, opts, cb), function (ev) {
	var strm = new Zlib(ev.data);
	onmessage = astrm(strm);
	}, 10);
	}
	return AsyncZlib;
	}());
	export { AsyncZlib };
	export function zlib(data, opts, cb) {
	if (!cb)
	cb = opts, opts = {};
	if (typeof cb != 'function')
	throw 'no callback';
	return cbify(data, opts, [
	bDflt,
	zle,
	function () { return [zlibSync]; }
	], function (ev) { return pbf(zlibSync(ev.data[0], ev.data[1])); }, 4, cb);
	}
	/**
	* Compress data with Zlib
	* @param data The data to compress
	* @param opts The compression options
	* @returns The zlib-compressed version of the data
	*/
	export function zlibSync(data, opts) {
	if (opts === void 0) { opts = {}; }
	var a = adler();
	a.p(data);
	var d = dopt(data, opts, 2, 4);
	return zlh(d, opts), wbytes(d, d.length - 4, a.d()), d;
	}
	/**
	* Streaming Zlib decompression
	*/
	var Unzlib = /#__PURE__/ (function () {
	/**
	* Creates a Zlib decompression stream
	* @param cb The callback to call whenever data is inflated
	*/
	function Unzlib(cb) {
	this.v = 1;
	Inflate.call(this, cb);
	}
	/**
	* Pushes a chunk to be unzlibbed
	* @param chunk The chunk to push
	* @param final Whether this is the last chunk
	*/
	Unzlib.prototype.push = function (chunk, final) {
	Inflate.prototype.e.call(this, chunk);
	if (this.v) {
	if (this.p.length < 2 && !final)
	return;
	this.p = this.p.subarray(2), this.v = 0;
	}
	if (final) {
	if (this.p.length < 4)
	throw 'invalid zlib stream';
	this.p = this.p.subarray(0, -4);
	}
	// necessary to prevent TS from using the closure value
	// This allows for workerization to function correctly
	Inflate.prototype.c.call(this, final);
	};
	return Unzlib;
	}());
	export { Unzlib };
	/**
	* Asynchronous streaming Zlib decompression
	*/
	var AsyncUnzlib = /#__PURE__/ (function () {
	/**
	* Creates an asynchronous Zlib decompression stream
	* @param cb The callback to call whenever data is deflated
	*/
	function AsyncUnzlib(cb) {
	this.ondata = cb;
	astrmify([
	bInflt,
	zule,
	function () { return [astrm, Inflate, Unzlib]; }
	], this, 0, function () {
	var strm = new Unzlib();
	onmessage = astrm(strm);
	}, 11);
	}
	return AsyncUnzlib;
	}());
	export { AsyncUnzlib };
	export function unzlib(data, opts, cb) {
	if (!cb)
	cb = opts, opts = {};
	if (typeof cb != 'function')
	throw 'no callback';
	return cbify(data, opts, [
	bInflt,
	zule,
	function () { return [unzlibSync]; }
	], function (ev) { return pbf(unzlibSync(ev.data[0], gu8(ev.data[1]))); }, 5, cb);
	}
	/**
	* Expands Zlib data
	* @param data The data to decompress
	* @param out Where to write the data. Saves memory if you know the decompressed size and provide an output buffer of that length.
	* @returns The decompressed version of the data
	*/
	export function unzlibSync(data, out) {
	return inflt((zlv(data), data.subarray(2, -4)), out);
	}
	// Default algorithm for compression (used because having a known output size allows faster decompression)
	export { gzip as compress, AsyncGzip as AsyncCompress };
	// Default algorithm for compression (used because having a known output size allows faster decompression)
	export { gzipSync as compressSync, Gzip as Compress };
	/**
	* Streaming GZIP, Zlib, or raw DEFLATE decompression
	*/
	var Decompress = /#__PURE__/ (function () {
	/**
	* Creates a decompression stream
	* @param cb The callback to call whenever data is decompressed
	*/
	function Decompress(cb) {
	this.G = Gunzip;
	this.I = Inflate;
	this.Z = Unzlib;
	this.ondata = cb;
	}
	/**
	* Pushes a chunk to be decompressed
	* @param chunk The chunk to push
	* @param final Whether this is the last chunk
	*/
	Decompress.prototype.push = function (chunk, final) {
	if (!this.ondata)
	throw 'no stream handler';
	if (!this.s) {
	if (this.p && this.p.length) {
	var n = new u8(this.p.length + chunk.length);
	n.set(this.p), n.set(chunk, this.p.length);
	}
	else
	this.p = chunk;
	if (this.p.length > 2) {
	var _this_1 = this;
	var cb = function () { _this_1.ondata.apply(_this_1, arguments); };
	this.s = (this.p[0] == 31 && this.p[1] == 139 && this.p[2] == 8)
	? new this.G(cb)
	: ((this.p[0] & 15) != 8 \|\| (this.p[0] >> 4) > 7 \|\| ((this.p[0] << 8 \| this.p[1]) % 31))
	? new this.I(cb)
	: new this.Z(cb);
	this.s.push(this.p, final);
	this.p = null;
	}
	}
	else
	this.s.push(chunk, final);
	};
	return Decompress;
	}());
	export { Decompress };
	/**
	* Asynchronous streaming GZIP, Zlib, or raw DEFLATE decompression
	*/
	var AsyncDecompress = /#__PURE__/ (function () {
	/**
	* Creates an asynchronous decompression stream
	* @param cb The callback to call whenever data is decompressed
	*/
	function AsyncDecompress(cb) {
	this.G = AsyncGunzip;
	this.I = AsyncInflate;
	this.Z = AsyncUnzlib;
	this.ondata = cb;
	}
	/**
	* Pushes a chunk to be decompressed
	* @param chunk The chunk to push
	* @param final Whether this is the last chunk
	*/
	AsyncDecompress.prototype.push = function (chunk, final) {
	Decompress.prototype.push.call(this, chunk, final);
	};
	return AsyncDecompress;
	}());
	export { AsyncDecompress };
	export function decompress(data, opts, cb) {
	if (!cb)
	cb = opts, opts = {};
	if (typeof cb != 'function')
	throw 'no callback';
	return (data[0] == 31 && data[1] == 139 && data[2] == 8)
	? gunzip(data, opts, cb)
	: ((data[0] & 15) != 8 \|\| (data[0] >> 4) > 7 \|\| ((data[0] << 8 \| data[1]) % 31))
	? inflate(data, opts, cb)
	: unzlib(data, opts, cb);
	}
	/**
	* Expands compressed GZIP, Zlib, or raw DEFLATE data, automatically detecting the format
	* @param data The data to decompress
	* @param out Where to write the data. Saves memory if you know the decompressed size and provide an output buffer of that length.
	* @returns The decompressed version of the data
	*/
	export function decompressSync(data, out) {
	return (data[0] == 31 && data[1] == 139 && data[2] == 8)
	? gunzipSync(data, out)
	: ((data[0] & 15) != 8 \|\| (data[0] >> 4) > 7 \|\| ((data[0] << 8 \| data[1]) % 31))
	? inflateSync(data, out)
	: unzlibSync(data, out);
	}
	// flatten a directory structure
	var fltn = function (d, p, t, o) {
	for (var k in d) {
	var val = d[k], n = p + k;
	if (val instanceof u8)
	t[n] = [val, o];
	else if (Array.isArray(val))
	t[n] = [val[0], mrg(o, val[1])];
	else
	fltn(val, n + '/', t, o);
	}
	};
	/**
	* Converts a string into a Uint8Array for use with compression/decompression methods
	* @param str The string to encode
	* @param latin1 Whether or not to interpret the data as Latin-1. This should
	* not need to be true unless decoding a binary string.
	* @returns The string encoded in UTF-8/Latin-1 binary
	*/
	export function strToU8(str, latin1) {
	var l = str.length;
	if (!latin1 && typeof TextEncoder != 'undefined')
	return new TextEncoder().encode(str);
	var ar = new u8(str.length + (str.length >>> 1));
	var ai = 0;
	var w = function (v) { ar[ai++] = v; };
	for (var i = 0; i < l; ++i) {
	if (ai + 5 > ar.length) {
	var n = new u8(ai + 8 + ((l - i) << 1));
	n.set(ar);
	ar = n;
	}
	var c = str.charCodeAt(i);
	if (c < 128 \|\| latin1)
	w(c);
	else if (c < 2048)
	w(192 \| (c >>> 6)), w(128 \| (c & 63));
	else if (c > 55295 && c < 57344)
	c = 65536 + (c & 1023 << 10) \| (str.charCodeAt(++i) & 1023),
	w(240 \| (c >>> 18)), w(128 \| ((c >>> 12) & 63)), w(128 \| ((c >>> 6) & 63)), w(128 \| (c & 63));
	else
	w(224 \| (c >>> 12)), w(128 \| ((c >>> 6) & 63)), w(128 \| (c & 63));
	}
	return slc(ar, 0, ai);
	}
	/**
	* Converts a Uint8Array to a string
	* @param dat The data to decode to string
	* @param latin1 Whether or not to interpret the data as Latin-1. This should
	* not need to be true unless encoding to binary string.
	* @returns The original UTF-8/Latin-1 string
	*/
	export function strFromU8(dat, latin1) {
	var r = '';
	if (!latin1 && typeof TextDecoder != 'undefined')
	return new TextDecoder().decode(dat);
	for (var i = 0; i < dat.length;) {
	var c = dat[i++];
	if (c < 128 \|\| latin1)
	r += String.fromCharCode(c);
	else if (c < 224)
	r += String.fromCharCode((c & 31) << 6 \| (dat[i++] & 63));
	else if (c < 240)
	r += String.fromCharCode((c & 15) << 12 \| (dat[i++] & 63) << 6 \| (dat[i++] & 63));
	else
	c = ((c & 15) << 18 \| (dat[i++] & 63) << 12 \| (dat[i++] & 63) << 6 \| (dat[i++] & 63)) - 65536,
	r += String.fromCharCode(55296 \| (c >> 10), 56320 \| (c & 1023));
	}
	return r;
	}
	;
	// skip local zip header
	var slzh = function (d, b) { return b + 30 + b2(d, b + 26) + b2(d, b + 28); };
	// read zip header
	var zh = function (d, b, z) {
	var fnl = b2(d, b + 28), fn = strFromU8(d.subarray(b + 46, b + 46 + fnl), !(b2(d, b + 8) & 2048)), es = b + 46 + fnl;
	var _a = z ? z64e(d, es) : [b4(d, b + 20), b4(d, b + 24), b4(d, b + 42)], sc = _a[0], su = _a[1], off = _a[2];
	return [b2(d, b + 10), sc, su, fn, es + b2(d, b + 30) + b2(d, b + 32), off];
	};
	// read zip64 extra field
	var z64e = function (d, b) {
	for (; b2(d, b) != 1; b += 4 + b2(d, b + 2))
	;
	return [b4(d, b + 12), b4(d, b + 4), b4(d, b + 20)];
	};
	// write zip header
	var wzh = function (d, b, c, cmp, su, fn, u, o, ce, t) {
	var fl = fn.length, l = cmp.length;
	wbytes(d, b, ce != null ? 0x2014B50 : 0x4034B50), b += 4;
	if (ce != null)
	d[b] = 20, b += 2;
	d[b] = 20, b += 2; // spec compliance? what's that?
	d[b++] = (t == 8 && (o.level == 1 ? 6 : o.level < 6 ? 4 : o.level == 9 ? 2 : 0)), d[b++] = u && 8;
	d[b] = t, b += 2;
	var dt = new Date(o.mtime \|\| Date.now()), y = dt.getFullYear() - 1980;
	if (y < 0 \|\| y > 119)
	throw 'date not in range 1980-2099';
	wbytes(d, b, ((y << 24) * 2) \| ((dt.getMonth() + 1) << 21) \| (dt.getDate() << 16) \| (dt.getHours() << 11) \| (dt.getMinutes() << 5) \| (dt.getSeconds() >>> 1));
	b += 4;
	wbytes(d, b, c);
	wbytes(d, b + 4, l);
	wbytes(d, b + 8, su);
	wbytes(d, b + 12, fl), b += 16; // skip extra field, comment
	if (ce != null)
	wbytes(d, b += 10, ce), b += 4;
	d.set(fn, b);
	b += fl;
	if (ce == null)
	d.set(cmp, b);
	};
	// write zip footer (end of central directory)
	var wzf = function (o, b, c, d, e) {
	wbytes(o, b, 0x6054B50); // skip disk
	wbytes(o, b + 8, c);
	wbytes(o, b + 10, c);
	wbytes(o, b + 12, d);
	wbytes(o, b + 16, e);
	};
	export function zip(data, opts, cb) {
	if (!cb)
	cb = opts, opts = {};
	if (typeof cb != 'function')
	throw 'no callback';
	var r = {};
	fltn(data, '', r, opts);
	var k = Object.keys(r);
	var lft = k.length, o = 0, tot = 0;
	var slft = lft, files = new Array(lft);
	var term = [];
	var tAll = function () {
	for (var i = 0; i < term.length; ++i)
	term[i]();
	};
	var cbf = function () {
	var out = new u8(tot + 22), oe = o, cdl = tot - o;
	tot = 0;
	for (var i = 0; i < slft; ++i) {
	var f = files[i];
	try {
	wzh(out, tot, f.c, f.d, f.m, f.n, f.u, f.p, null, f.t);
	wzh(out, o, f.c, f.d, f.m, f.n, f.u, f.p, tot, f.t), o += 46 + f.n.length, tot += 30 + f.n.length + f.d.length;
	}
	catch (e) {
	return cb(e, null);
	}
	}
	wzf(out, o, files.length, cdl, oe);
	cb(null, out);
	};
	if (!lft)
	cbf();
	var _loop_1 = function (i) {
	var fn = k[i];
	var _a = r[fn], file = _a[0], p = _a[1];
	var c = crc(), m = file.length;
	c.p(file);
	var n = strToU8(fn), s = n.length;
	var t = p.level == 0 ? 0 : 8;
	var cbl = function (e, d) {
	if (e) {
	tAll();
	cb(e, null);
	}
	else {
	var l = d.length;
	files[i] = {
	t: t,
	d: d,
	m: m,
	c: c.d(),
	u: fn.length != l,
	n: n,
	p: p
	};
	o += 30 + s + l;
	tot += 76 + 2 * s + l;
	if (!--lft)
	cbf();
	}
	};
	if (n.length > 65535)
	cbl('filename too long', null);
	if (!t)
	cbl(null, file);
	else if (m < 160000) {
	try {
	cbl(null, deflateSync(file, p));
	}
	catch (e) {
	cbl(e, null);
	}
	}
	else
	term.push(deflate(file, p, cbl));
	};
	// Cannot use lft because it can decrease
	for (var i = 0; i < slft; ++i) {
	_loop_1(i);
	}
	return tAll;
	}
	/**
	* Synchronously creates a ZIP file. Prefer using `zip` for better performance
	* with more than one file.
	* @param data The directory structure for the ZIP archive
	* @param opts The main options, merged with per-file options
	* @returns The generated ZIP archive
	*/
	export function zipSync(data, opts) {
	if (opts === void 0) { opts = {}; }
	var r = {};
	var files = [];
	fltn(data, '', r, opts);
	var o = 0;
	var tot = 0;
	for (var fn in r) {
	var _a = r[fn], file = _a[0], p = _a[1];
	var t = p.level == 0 ? 0 : 8;
	var n = strToU8(fn), s = n.length;
	if (n.length > 65535)
	throw 'filename too long';
	var d = t ? deflateSync(file, p) : file, l = d.length;
	var c = crc();
	c.p(file);
	files.push({
	t: t,
	d: d,
	m: file.length,
	c: c.d(),
	u: fn.length != s,
	n: n,
	o: o,
	p: p
	});
	o += 30 + s + l;
	tot += 76 + 2 * s + l;
	}
	var out = new u8(tot + 22), oe = o, cdl = tot - o;
	for (var i = 0; i < files.length; ++i) {
	var f = files[i];
	wzh(out, f.o, f.c, f.d, f.m, f.n, f.u, f.p, null, f.t);
	wzh(out, o, f.c, f.d, f.m, f.n, f.u, f.p, f.o, f.t), o += 46 + f.n.length;
	}
	wzf(out, o, files.length, cdl, oe);
	return out;
	}
	/**
	* Asynchronously decompresses a ZIP archive
	* @param data The raw compressed ZIP file
	* @param cb The callback to call with the decompressed files
	* @returns A function that can be used to immediately terminate the unzipping
	*/
	export function unzip(data, cb) {
	if (typeof cb != 'function')
	throw 'no callback';
	var term = [];
	var tAll = function () {
	for (var i = 0; i < term.length; ++i)
	term[i]();
	};
	var files = {};
	var e = data.length - 22;
	for (; b4(data, e) != 0x6054B50; --e) {
	if (!e \|\| data.length - e > 65558) {
	cb('invalid zip file', null);
	return;
	}
	}
	;
	var lft = b2(data, e + 8);
	if (!lft)
	cb(null, {});
	var c = lft;
	var o = b4(data, e + 16);
	var z = o == 4294967295;
	if (z) {
	e = b4(data, e - 12);
	if (b4(data, e) != 0x6064B50)
	throw 'invalid zip file';
	c = lft = b4(data, e + 32);
	o = b4(data, e + 48);
	}
	var _loop_2 = function (i) {
	var _a = zh(data, o, z), c_1 = _a[0], sc = _a[1], su = _a[2], fn = _a[3], no = _a[4], off = _a[5], b = slzh(data, off);
	o = no;
	var cbl = function (e, d) {
	if (e) {
	tAll();
	cb(e, null);
	}
	else {
	files[fn] = d;
	if (!--lft)
	cb(null, files);
	}
	};
	if (!c_1)
	cbl(null, slc(data, b, b + sc));
	else if (c_1 == 8) {
	var infl = data.subarray(b, b + sc);
	if (sc < 320000) {
	try {
	cbl(null, inflateSync(infl, new u8(su)));
	}
	catch (e) {
	cbl(e, null);
	}
	}
	else
	term.push(inflate(infl, { size: su }, cbl));
	}
	else
	cbl('unknown compression type ' + c_1, null);
	};
	for (var i = 0; i < c; ++i) {
	_loop_2(i);
	}
	return tAll;
	}
	/**
	* Synchronously decompresses a ZIP archive. Prefer using `unzip` for better
	* performance with more than one file.
	* @param data The raw compressed ZIP file
	* @returns The decompressed files
	*/
	export function unzipSync(data) {
	var files = {};
	var e = data.length - 22;
	for (; b4(data, e) != 0x6054B50; --e) {
	if (!e \|\| data.length - e > 65558)
	throw 'invalid zip file';
	}
	;
	var c = b2(data, e + 8);
	if (!c)
	return {};
	var o = b4(data, e + 16);
	var z = o == 4294967295;
	if (z) {
	e = b4(data, e - 12);
	if (b4(data, e) != 0x6064B50)
	throw 'invalid zip file';
	c = b4(data, e + 32);
	o = b4(data, e + 48);
	}
	for (var i = 0; i < c; ++i) {
	var _a = zh(data, o, z), c_2 = _a[0], sc = _a[1], su = _a[2], fn = _a[3], no = _a[4], off = _a[5], b = slzh(data, off);
	o = no;
	if (!c_2)
	files[fn] = slc(data, b, b + sc);
	else if (c_2 == 8)
	files[fn] = inflateSync(data.subarray(b, b + sc), new u8(su));
	else
	throw 'unknown compression type ' + c_2;
	}
	return files;
	}