(function(e){if("object"==typeof exports&&"undefined"!=typeof module)module.exports=e();else if("function"==typeof define&&define.amd)define([],e);else{var f;"undefined"!=typeof window?f=window:"undefined"!=typeof global?f=global:"undefined"!=typeof self&&(f=self),f.Bitcoin=e()}})(function(){var define,module,exports;return (function e(t,n,r){function s(o,u){if(!n[o]){if(!t[o]){var a=typeof require=="function"&&require;if(!u&&a)return a(o,!0);if(i)return i(o,!0);throw new Error("Cannot find module '"+o+"'")}var f=n[o]={exports:{}};t[o][0].call(f.exports,function(e){var n=t[o][1][e];return s(n?n:e)},f,f.exports,e,t,n,r)}return n[o].exports}var i=typeof require=="function"&&require;for(var o=0;o= 0) { var v = x*this[i++]+w[j]+c; c = Math.floor(v/0x4000000); w[j++] = v&0x3ffffff; } return c; } // am2 avoids a big mult-and-extract completely. // Max digit bits should be <= 30 because we do bitwise ops // on values up to 2*hdvalue^2-hdvalue-1 (< 2^31) function am2(i,x,w,j,c,n) { var xl = x&0x7fff, xh = x>>15; while(--n >= 0) { var l = this[i]&0x7fff; var h = this[i++]>>15; var m = xh*l+h*xl; l = xl*l+((m&0x7fff)<<15)+w[j]+(c&0x3fffffff); c = (l>>>30)+(m>>>15)+xh*h+(c>>>30); w[j++] = l&0x3fffffff; } return c; } // Alternately, set max digit bits to 28 since some // browsers slow down when dealing with 32-bit numbers. function am3(i,x,w,j,c,n) { var xl = x&0x3fff, xh = x>>14; while(--n >= 0) { var l = this[i]&0x3fff; var h = this[i++]>>14; var m = xh*l+h*xl; l = xl*l+((m&0x3fff)<<14)+w[j]+c; c = (l>>28)+(m>>14)+xh*h; w[j++] = l&0xfffffff; } return c; } // wtf? BigInteger.prototype.am = am1; dbits = 26; /* if(j_lm && (navigator.appName == "Microsoft Internet Explorer")) { BigInteger.prototype.am = am2; dbits = 30; } else if(j_lm && (navigator.appName != "Netscape")) { BigInteger.prototype.am = am1; dbits = 26; } else { // Mozilla/Netscape seems to prefer am3 BigInteger.prototype.am = am3; dbits = 28; } */ BigInteger.prototype.DB = dbits; BigInteger.prototype.DM = ((1<= 0; --i) r[i] = this[i]; r.t = this.t; r.s = this.s; } // (protected) set from integer value x, -DV <= x < DV function bnpFromInt(x) { this.t = 1; this.s = (x<0)?-1:0; if(x > 0) this[0] = x; else if(x < -1) this[0] = x+DV; else this.t = 0; } // return bigint initialized to value function nbv(i) { var r = nbi(); r.fromInt(i); return r; } // (protected) set from string and radix function bnpFromString(s,b) { var self = this; var k; if(b == 16) k = 4; else if(b == 8) k = 3; else if(b == 256) k = 8; // byte array else if(b == 2) k = 1; else if(b == 32) k = 5; else if(b == 4) k = 2; else { self.fromRadix(s,b); return; } self.t = 0; self.s = 0; var i = s.length, mi = false, sh = 0; while(--i >= 0) { var x = (k==8)?s[i]&0xff:intAt(s,i); if(x < 0) { if(s.charAt(i) == "-") mi = true; continue; } mi = false; if(sh == 0) self[self.t++] = x; else if(sh+k > self.DB) { self[self.t-1] |= (x&((1<<(self.DB-sh))-1))<>(self.DB-sh)); } else self[self.t-1] |= x<= self.DB) sh -= self.DB; } if(k == 8 && (s[0]&0x80) != 0) { self.s = -1; if(sh > 0) self[self.t-1] |= ((1<<(self.DB-sh))-1)< 0 && this[this.t-1] == c) --this.t; } // (public) return string representation in given radix function bnToString(b) { var self = this; if(self.s < 0) return "-"+self.negate().toString(b); var k; if(b == 16) k = 4; else if(b == 8) k = 3; else if(b == 2) k = 1; else if(b == 32) k = 5; else if(b == 4) k = 2; else return self.toRadix(b); var km = (1< 0) { if(p < self.DB && (d = self[i]>>p) > 0) { m = true; r = int2char(d); } while(i >= 0) { if(p < k) { d = (self[i]&((1<>(p+=self.DB-k); } else { d = (self[i]>>(p-=k))&km; if(p <= 0) { p += self.DB; --i; } } if(d > 0) m = true; if(m) r += int2char(d); } } return m?r:"0"; } // (public) -this function bnNegate() { var r = nbi(); BigInteger.ZERO.subTo(this,r); return r; } // (public) |this| function bnAbs() { return (this.s<0)?this.negate():this; } // (public) return + if this > a, - if this < a, 0 if equal function bnCompareTo(a) { var r = this.s-a.s; if(r != 0) return r; var i = this.t; r = i-a.t; if(r != 0) return (this.s<0)?-r:r; while(--i >= 0) if((r=this[i]-a[i]) != 0) return r; return 0; } // returns bit length of the integer x function nbits(x) { var r = 1, t; if((t=x>>>16) != 0) { x = t; r += 16; } if((t=x>>8) != 0) { x = t; r += 8; } if((t=x>>4) != 0) { x = t; r += 4; } if((t=x>>2) != 0) { x = t; r += 2; } if((t=x>>1) != 0) { x = t; r += 1; } return r; } // (public) return the number of bits in "this" function bnBitLength() { if(this.t <= 0) return 0; return this.DB*(this.t-1)+nbits(this[this.t-1]^(this.s&this.DM)); } // (protected) r = this << n*DB function bnpDLShiftTo(n,r) { var i; for(i = this.t-1; i >= 0; --i) r[i+n] = this[i]; for(i = n-1; i >= 0; --i) r[i] = 0; r.t = this.t+n; r.s = this.s; } // (protected) r = this >> n*DB function bnpDRShiftTo(n,r) { for(var i = n; i < this.t; ++i) r[i-n] = this[i]; r.t = Math.max(this.t-n,0); r.s = this.s; } // (protected) r = this << n function bnpLShiftTo(n,r) { var self = this; var bs = n%self.DB; var cbs = self.DB-bs; var bm = (1<= 0; --i) { r[i+ds+1] = (self[i]>>cbs)|c; c = (self[i]&bm)<= 0; --i) r[i] = 0; r[ds] = c; r.t = self.t+ds+1; r.s = self.s; r.clamp(); } // (protected) r = this >> n function bnpRShiftTo(n,r) { var self = this; r.s = self.s; var ds = Math.floor(n/self.DB); if(ds >= self.t) { r.t = 0; return; } var bs = n%self.DB; var cbs = self.DB-bs; var bm = (1<>bs; for(var i = ds+1; i < self.t; ++i) { r[i-ds-1] |= (self[i]&bm)<>bs; } if(bs > 0) r[self.t-ds-1] |= (self.s&bm)<>= self.DB; } if(a.t < self.t) { c -= a.s; while(i < self.t) { c += self[i]; r[i++] = c&self.DM; c >>= self.DB; } c += self.s; } else { c += self.s; while(i < a.t) { c -= a[i]; r[i++] = c&self.DM; c >>= self.DB; } c -= a.s; } r.s = (c<0)?-1:0; if(c < -1) r[i++] = self.DV+c; else if(c > 0) r[i++] = c; r.t = i; r.clamp(); } // (protected) r = this * a, r != this,a (HAC 14.12) // "this" should be the larger one if appropriate. function bnpMultiplyTo(a,r) { var x = this.abs(), y = a.abs(); var i = x.t; r.t = i+y.t; while(--i >= 0) r[i] = 0; for(i = 0; i < y.t; ++i) r[i+x.t] = x.am(0,y[i],r,i,0,x.t); r.s = 0; r.clamp(); if(this.s != a.s) BigInteger.ZERO.subTo(r,r); } // (protected) r = this^2, r != this (HAC 14.16) function bnpSquareTo(r) { var x = this.abs(); var i = r.t = 2*x.t; while(--i >= 0) r[i] = 0; for(i = 0; i < x.t-1; ++i) { var c = x.am(i,x[i],r,2*i,0,1); if((r[i+x.t]+=x.am(i+1,2*x[i],r,2*i+1,c,x.t-i-1)) >= x.DV) { r[i+x.t] -= x.DV; r[i+x.t+1] = 1; } } if(r.t > 0) r[r.t-1] += x.am(i,x[i],r,2*i,0,1); r.s = 0; r.clamp(); } // (protected) divide this by m, quotient and remainder to q, r (HAC 14.20) // r != q, this != m. q or r may be null. function bnpDivRemTo(m,q,r) { var self = this; var pm = m.abs(); if(pm.t <= 0) return; var pt = self.abs(); if(pt.t < pm.t) { if(q != null) q.fromInt(0); if(r != null) self.copyTo(r); return; } if(r == null) r = nbi(); var y = nbi(), ts = self.s, ms = m.s; var nsh = self.DB-nbits(pm[pm.t-1]); // normalize modulus if(nsh > 0) { pm.lShiftTo(nsh,y); pt.lShiftTo(nsh,r); } else { pm.copyTo(y); pt.copyTo(r); } var ys = y.t; var y0 = y[ys-1]; if(y0 == 0) return; var yt = y0*(1<1)?y[ys-2]>>self.F2:0); var d1 = self.FV/yt, d2 = (1<= 0) { r[r.t++] = 1; r.subTo(t,r); } BigInteger.ONE.dlShiftTo(ys,t); t.subTo(y,y); // "negative" y so we can replace sub with am later while(y.t < ys) y[y.t++] = 0; while(--j >= 0) { // Estimate quotient digit var qd = (r[--i]==y0)?self.DM:Math.floor(r[i]*d1+(r[i-1]+e)*d2); if((r[i]+=y.am(0,qd,r,j,0,ys)) < qd) { // Try it out y.dlShiftTo(j,t); r.subTo(t,r); while(r[i] < --qd) r.subTo(t,r); } } if(q != null) { r.drShiftTo(ys,q); if(ts != ms) BigInteger.ZERO.subTo(q,q); } r.t = ys; r.clamp(); if(nsh > 0) r.rShiftTo(nsh,r); // Denormalize remainder if(ts < 0) BigInteger.ZERO.subTo(r,r); } // (public) this mod a function bnMod(a) { var r = nbi(); this.abs().divRemTo(a,null,r); if(this.s < 0 && r.compareTo(BigInteger.ZERO) > 0) a.subTo(r,r); return r; } // Modular reduction using "classic" algorithm function Classic(m) { this.m = m; } function cConvert(x) { if(x.s < 0 || x.compareTo(this.m) >= 0) return x.mod(this.m); else return x; } function cRevert(x) { return x; } function cReduce(x) { x.divRemTo(this.m,null,x); } function cMulTo(x,y,r) { x.multiplyTo(y,r); this.reduce(r); } function cSqrTo(x,r) { x.squareTo(r); this.reduce(r); } Classic.prototype.convert = cConvert; Classic.prototype.revert = cRevert; Classic.prototype.reduce = cReduce; Classic.prototype.mulTo = cMulTo; Classic.prototype.sqrTo = cSqrTo; // (protected) return "-1/this % 2^DB"; useful for Mont. reduction // justification: // xy == 1 (mod m) // xy = 1+km // xy(2-xy) = (1+km)(1-km) // x[y(2-xy)] = 1-k^2m^2 // x[y(2-xy)] == 1 (mod m^2) // if y is 1/x mod m, then y(2-xy) is 1/x mod m^2 // should reduce x and y(2-xy) by m^2 at each step to keep size bounded. // JS multiply "overflows" differently from C/C++, so care is needed here. function bnpInvDigit() { if(this.t < 1) return 0; var x = this[0]; if((x&1) == 0) return 0; var y = x&3; // y == 1/x mod 2^2 y = (y*(2-(x&0xf)*y))&0xf; // y == 1/x mod 2^4 y = (y*(2-(x&0xff)*y))&0xff; // y == 1/x mod 2^8 y = (y*(2-(((x&0xffff)*y)&0xffff)))&0xffff; // y == 1/x mod 2^16 // last step - calculate inverse mod DV directly; // assumes 16 < DB <= 32 and assumes ability to handle 48-bit ints y = (y*(2-x*y%this.DV))%this.DV; // y == 1/x mod 2^dbits // we really want the negative inverse, and -DV < y < DV return (y>0)?this.DV-y:-y; } // Montgomery reduction function Montgomery(m) { this.m = m; this.mp = m.invDigit(); this.mpl = this.mp&0x7fff; this.mph = this.mp>>15; this.um = (1<<(m.DB-15))-1; this.mt2 = 2*m.t; } // xR mod m function montConvert(x) { var r = nbi(); x.abs().dlShiftTo(this.m.t,r); r.divRemTo(this.m,null,r); if(x.s < 0 && r.compareTo(BigInteger.ZERO) > 0) this.m.subTo(r,r); return r; } // x/R mod m function montRevert(x) { var r = nbi(); x.copyTo(r); this.reduce(r); return r; } // x = x/R mod m (HAC 14.32) function montReduce(x) { while(x.t <= this.mt2) // pad x so am has enough room later x[x.t++] = 0; for(var i = 0; i < this.m.t; ++i) { // faster way of calculating u0 = x[i]*mp mod DV var j = x[i]&0x7fff; var u0 = (j*this.mpl+(((j*this.mph+(x[i]>>15)*this.mpl)&this.um)<<15))&x.DM; // use am to combine the multiply-shift-add into one call j = i+this.m.t; x[j] += this.m.am(0,u0,x,i,0,this.m.t); // propagate carry while(x[j] >= x.DV) { x[j] -= x.DV; x[++j]++; } } x.clamp(); x.drShiftTo(this.m.t,x); if(x.compareTo(this.m) >= 0) x.subTo(this.m,x); } // r = "x^2/R mod m"; x != r function montSqrTo(x,r) { x.squareTo(r); this.reduce(r); } // r = "xy/R mod m"; x,y != r function montMulTo(x,y,r) { x.multiplyTo(y,r); this.reduce(r); } Montgomery.prototype.convert = montConvert; Montgomery.prototype.revert = montRevert; Montgomery.prototype.reduce = montReduce; Montgomery.prototype.mulTo = montMulTo; Montgomery.prototype.sqrTo = montSqrTo; // (protected) true iff this is even function bnpIsEven() { return ((this.t>0)?(this[0]&1):this.s) == 0; } // (protected) this^e, e < 2^32, doing sqr and mul with "r" (HAC 14.79) function bnpExp(e,z) { if(e > 0xffffffff || e < 1) return BigInteger.ONE; var r = nbi(), r2 = nbi(), g = z.convert(this), i = nbits(e)-1; g.copyTo(r); while(--i >= 0) { z.sqrTo(r,r2); if((e&(1< 0) z.mulTo(r2,g,r); else { var t = r; r = r2; r2 = t; } } return z.revert(r); } // (public) this^e % m, 0 <= e < 2^32 function bnModPowInt(e,m) { var z; if(e < 256 || m.isEven()) z = new Classic(m); else z = new Montgomery(m); return this.exp(e,z); } // protected proto.copyTo = bnpCopyTo; proto.fromInt = bnpFromInt; proto.fromString = bnpFromString; proto.clamp = bnpClamp; proto.dlShiftTo = bnpDLShiftTo; proto.drShiftTo = bnpDRShiftTo; proto.lShiftTo = bnpLShiftTo; proto.rShiftTo = bnpRShiftTo; proto.subTo = bnpSubTo; proto.multiplyTo = bnpMultiplyTo; proto.squareTo = bnpSquareTo; proto.divRemTo = bnpDivRemTo; proto.invDigit = bnpInvDigit; proto.isEven = bnpIsEven; proto.exp = bnpExp; // public proto.toString = bnToString; proto.negate = bnNegate; proto.abs = bnAbs; proto.compareTo = bnCompareTo; proto.bitLength = bnBitLength; proto.mod = bnMod; proto.modPowInt = bnModPowInt; //// jsbn2 function nbi() { return new BigInteger(null); } // (public) function bnClone() { var r = nbi(); this.copyTo(r); return r; } // (public) return value as integer function bnIntValue() { if(this.s < 0) { if(this.t == 1) return this[0]-this.DV; else if(this.t == 0) return -1; } else if(this.t == 1) return this[0]; else if(this.t == 0) return 0; // assumes 16 < DB < 32 return ((this[1]&((1<<(32-this.DB))-1))<>24; } // (public) return value as short (assumes DB>=16) function bnShortValue() { return (this.t==0)?this.s:(this[0]<<16)>>16; } // (protected) return x s.t. r^x < DV function bnpChunkSize(r) { return Math.floor(Math.LN2*this.DB/Math.log(r)); } // (public) 0 if this == 0, 1 if this > 0 function bnSigNum() { if(this.s < 0) return -1; else if(this.t <= 0 || (this.t == 1 && this[0] <= 0)) return 0; else return 1; } // (protected) convert to radix string function bnpToRadix(b) { if(b == null) b = 10; if(this.signum() == 0 || b < 2 || b > 36) return "0"; var cs = this.chunkSize(b); var a = Math.pow(b,cs); var d = nbv(a), y = nbi(), z = nbi(), r = ""; this.divRemTo(d,y,z); while(y.signum() > 0) { r = (a+z.intValue()).toString(b).substr(1) + r; y.divRemTo(d,y,z); } return z.intValue().toString(b) + r; } // (protected) convert from radix string function bnpFromRadix(s,b) { var self = this; self.fromInt(0); if(b == null) b = 10; var cs = self.chunkSize(b); var d = Math.pow(b,cs), mi = false, j = 0, w = 0; for(var i = 0; i < s.length; ++i) { var x = intAt(s,i); if(x < 0) { if(s.charAt(i) == "-" && self.signum() == 0) mi = true; continue; } w = b*w+x; if(++j >= cs) { self.dMultiply(d); self.dAddOffset(w,0); j = 0; w = 0; } } if(j > 0) { self.dMultiply(Math.pow(b,j)); self.dAddOffset(w,0); } if(mi) BigInteger.ZERO.subTo(self,self); } // (protected) alternate constructor function bnpFromNumber(a,b,c) { var self = this; if("number" == typeof b) { // new BigInteger(int,int,RNG) if(a < 2) self.fromInt(1); else { self.fromNumber(a,c); if(!self.testBit(a-1)) // force MSB set self.bitwiseTo(BigInteger.ONE.shiftLeft(a-1),op_or,self); if(self.isEven()) self.dAddOffset(1,0); // force odd while(!self.isProbablePrime(b)) { self.dAddOffset(2,0); if(self.bitLength() > a) self.subTo(BigInteger.ONE.shiftLeft(a-1),self); } } } else { // new BigInteger(int,RNG) var x = new Array(), t = a&7; x.length = (a>>3)+1; b.nextBytes(x); if(t > 0) x[0] &= ((1< 0) { if(p < self.DB && (d = self[i]>>p) != (self.s&self.DM)>>p) r[k++] = d|(self.s<<(self.DB-p)); while(i >= 0) { if(p < 8) { d = (self[i]&((1<>(p+=self.DB-8); } else { d = (self[i]>>(p-=8))&0xff; if(p <= 0) { p += self.DB; --i; } } if((d&0x80) != 0) d |= -256; if(k === 0 && (self.s&0x80) != (d&0x80)) ++k; if(k > 0 || d != self.s) r[k++] = d; } } return r; } function bnEquals(a) { return(this.compareTo(a)==0); } function bnMin(a) { return(this.compareTo(a)<0)?this:a; } function bnMax(a) { return(this.compareTo(a)>0)?this:a; } // (protected) r = this op a (bitwise) function bnpBitwiseTo(a,op,r) { var self = this; var i, f, m = Math.min(a.t,self.t); for(i = 0; i < m; ++i) r[i] = op(self[i],a[i]); if(a.t < self.t) { f = a.s&self.DM; for(i = m; i < self.t; ++i) r[i] = op(self[i],f); r.t = self.t; } else { f = self.s&self.DM; for(i = m; i < a.t; ++i) r[i] = op(f,a[i]); r.t = a.t; } r.s = op(self.s,a.s); r.clamp(); } // (public) this & a function op_and(x,y) { return x&y; } function bnAnd(a) { var r = nbi(); this.bitwiseTo(a,op_and,r); return r; } // (public) this | a function op_or(x,y) { return x|y; } function bnOr(a) { var r = nbi(); this.bitwiseTo(a,op_or,r); return r; } // (public) this ^ a function op_xor(x,y) { return x^y; } function bnXor(a) { var r = nbi(); this.bitwiseTo(a,op_xor,r); return r; } // (public) this & ~a function op_andnot(x,y) { return x&~y; } function bnAndNot(a) { var r = nbi(); this.bitwiseTo(a,op_andnot,r); return r; } // (public) ~this function bnNot() { var r = nbi(); for(var i = 0; i < this.t; ++i) r[i] = this.DM&~this[i]; r.t = this.t; r.s = ~this.s; return r; } // (public) this << n function bnShiftLeft(n) { var r = nbi(); if(n < 0) this.rShiftTo(-n,r); else this.lShiftTo(n,r); return r; } // (public) this >> n function bnShiftRight(n) { var r = nbi(); if(n < 0) this.lShiftTo(-n,r); else this.rShiftTo(n,r); return r; } // return index of lowest 1-bit in x, x < 2^31 function lbit(x) { if(x == 0) return -1; var r = 0; if((x&0xffff) == 0) { x >>= 16; r += 16; } if((x&0xff) == 0) { x >>= 8; r += 8; } if((x&0xf) == 0) { x >>= 4; r += 4; } if((x&3) == 0) { x >>= 2; r += 2; } if((x&1) == 0) ++r; return r; } // (public) returns index of lowest 1-bit (or -1 if none) function bnGetLowestSetBit() { for(var i = 0; i < this.t; ++i) if(this[i] != 0) return i*this.DB+lbit(this[i]); if(this.s < 0) return this.t*this.DB; return -1; } // return number of 1 bits in x function cbit(x) { var r = 0; while(x != 0) { x &= x-1; ++r; } return r; } // (public) return number of set bits function bnBitCount() { var r = 0, x = this.s&this.DM; for(var i = 0; i < this.t; ++i) r += cbit(this[i]^x); return r; } // (public) true iff nth bit is set function bnTestBit(n) { var j = Math.floor(n/this.DB); if(j >= this.t) return(this.s!=0); return((this[j]&(1<<(n%this.DB)))!=0); } // (protected) this op (1<>= self.DB; } if(a.t < self.t) { c += a.s; while(i < self.t) { c += self[i]; r[i++] = c&self.DM; c >>= self.DB; } c += self.s; } else { c += self.s; while(i < a.t) { c += a[i]; r[i++] = c&self.DM; c >>= self.DB; } c += a.s; } r.s = (c<0)?-1:0; if(c > 0) r[i++] = c; else if(c < -1) r[i++] = self.DV+c; r.t = i; r.clamp(); } // (public) this + a function bnAdd(a) { var r = nbi(); this.addTo(a,r); return r; } // (public) this - a function bnSubtract(a) { var r = nbi(); this.subTo(a,r); return r; } // (public) this * a function bnMultiply(a) { var r = nbi(); this.multiplyTo(a,r); return r; } // (public) this^2 function bnSquare() { var r = nbi(); this.squareTo(r); return r; } // (public) this / a function bnDivide(a) { var r = nbi(); this.divRemTo(a,r,null); return r; } // (public) this % a function bnRemainder(a) { var r = nbi(); this.divRemTo(a,null,r); return r; } // (public) [this/a,this%a] function bnDivideAndRemainder(a) { var q = nbi(), r = nbi(); this.divRemTo(a,q,r); return new Array(q,r); } // (protected) this *= n, this >= 0, 1 < n < DV function bnpDMultiply(n) { this[this.t] = this.am(0,n-1,this,0,0,this.t); ++this.t; this.clamp(); } // (protected) this += n << w words, this >= 0 function bnpDAddOffset(n,w) { if(n == 0) return; while(this.t <= w) this[this.t++] = 0; this[w] += n; while(this[w] >= this.DV) { this[w] -= this.DV; if(++w >= this.t) this[this.t++] = 0; ++this[w]; } } // A "null" reducer function NullExp() {} function nNop(x) { return x; } function nMulTo(x,y,r) { x.multiplyTo(y,r); } function nSqrTo(x,r) { x.squareTo(r); } NullExp.prototype.convert = nNop; NullExp.prototype.revert = nNop; NullExp.prototype.mulTo = nMulTo; NullExp.prototype.sqrTo = nSqrTo; // (public) this^e function bnPow(e) { return this.exp(e,new NullExp()); } // (protected) r = lower n words of "this * a", a.t <= n // "this" should be the larger one if appropriate. function bnpMultiplyLowerTo(a,n,r) { var i = Math.min(this.t+a.t,n); r.s = 0; // assumes a,this >= 0 r.t = i; while(i > 0) r[--i] = 0; var j; for(j = r.t-this.t; i < j; ++i) r[i+this.t] = this.am(0,a[i],r,i,0,this.t); for(j = Math.min(a.t,n); i < j; ++i) this.am(0,a[i],r,i,0,n-i); r.clamp(); } // (protected) r = "this * a" without lower n words, n > 0 // "this" should be the larger one if appropriate. function bnpMultiplyUpperTo(a,n,r) { --n; var i = r.t = this.t+a.t-n; r.s = 0; // assumes a,this >= 0 while(--i >= 0) r[i] = 0; for(i = Math.max(n-this.t,0); i < a.t; ++i) r[this.t+i-n] = this.am(n-i,a[i],r,0,0,this.t+i-n); r.clamp(); r.drShiftTo(1,r); } // Barrett modular reduction function Barrett(m) { // setup Barrett this.r2 = nbi(); this.q3 = nbi(); BigInteger.ONE.dlShiftTo(2*m.t,this.r2); this.mu = this.r2.divide(m); this.m = m; } function barrettConvert(x) { if(x.s < 0 || x.t > 2*this.m.t) return x.mod(this.m); else if(x.compareTo(this.m) < 0) return x; else { var r = nbi(); x.copyTo(r); this.reduce(r); return r; } } function barrettRevert(x) { return x; } // x = x mod m (HAC 14.42) function barrettReduce(x) { var self = this; x.drShiftTo(self.m.t-1,self.r2); if(x.t > self.m.t+1) { x.t = self.m.t+1; x.clamp(); } self.mu.multiplyUpperTo(self.r2,self.m.t+1,self.q3); self.m.multiplyLowerTo(self.q3,self.m.t+1,self.r2); while(x.compareTo(self.r2) < 0) x.dAddOffset(1,self.m.t+1); x.subTo(self.r2,x); while(x.compareTo(self.m) >= 0) x.subTo(self.m,x); } // r = x^2 mod m; x != r function barrettSqrTo(x,r) { x.squareTo(r); this.reduce(r); } // r = x*y mod m; x,y != r function barrettMulTo(x,y,r) { x.multiplyTo(y,r); this.reduce(r); } Barrett.prototype.convert = barrettConvert; Barrett.prototype.revert = barrettRevert; Barrett.prototype.reduce = barrettReduce; Barrett.prototype.mulTo = barrettMulTo; Barrett.prototype.sqrTo = barrettSqrTo; // (public) this^e % m (HAC 14.85) function bnModPow(e,m) { var i = e.bitLength(), k, r = nbv(1), z; if(i <= 0) return r; else if(i < 18) k = 1; else if(i < 48) k = 3; else if(i < 144) k = 4; else if(i < 768) k = 5; else k = 6; if(i < 8) z = new Classic(m); else if(m.isEven()) z = new Barrett(m); else z = new Montgomery(m); // precomputation var g = new Array(), n = 3, k1 = k-1, km = (1< 1) { var g2 = nbi(); z.sqrTo(g[1],g2); while(n <= km) { g[n] = nbi(); z.mulTo(g2,g[n-2],g[n]); n += 2; } } var j = e.t-1, w, is1 = true, r2 = nbi(), t; i = nbits(e[j])-1; while(j >= 0) { if(i >= k1) w = (e[j]>>(i-k1))&km; else { w = (e[j]&((1<<(i+1))-1))<<(k1-i); if(j > 0) w |= e[j-1]>>(this.DB+i-k1); } n = k; while((w&1) == 0) { w >>= 1; --n; } if((i -= n) < 0) { i += this.DB; --j; } if(is1) { // ret == 1, don't bother squaring or multiplying it g[w].copyTo(r); is1 = false; } else { while(n > 1) { z.sqrTo(r,r2); z.sqrTo(r2,r); n -= 2; } if(n > 0) z.sqrTo(r,r2); else { t = r; r = r2; r2 = t; } z.mulTo(r2,g[w],r); } while(j >= 0 && (e[j]&(1< 0) { x.rShiftTo(g,x); y.rShiftTo(g,y); } while(x.signum() > 0) { if((i = x.getLowestSetBit()) > 0) x.rShiftTo(i,x); if((i = y.getLowestSetBit()) > 0) y.rShiftTo(i,y); if(x.compareTo(y) >= 0) { x.subTo(y,x); x.rShiftTo(1,x); } else { y.subTo(x,y); y.rShiftTo(1,y); } } if(g > 0) y.lShiftTo(g,y); return y; } // (protected) this % n, n < 2^26 function bnpModInt(n) { if(n <= 0) return 0; var d = this.DV%n, r = (this.s<0)?n-1:0; if(this.t > 0) if(d == 0) r = this[0]%n; else for(var i = this.t-1; i >= 0; --i) r = (d*r+this[i])%n; return r; } // (public) 1/this % m (HAC 14.61) function bnModInverse(m) { var ac = m.isEven(); if((this.isEven() && ac) || m.signum() == 0) return BigInteger.ZERO; var u = m.clone(), v = this.clone(); var a = nbv(1), b = nbv(0), c = nbv(0), d = nbv(1); while(u.signum() != 0) { while(u.isEven()) { u.rShiftTo(1,u); if(ac) { if(!a.isEven() || !b.isEven()) { a.addTo(this,a); b.subTo(m,b); } a.rShiftTo(1,a); } else if(!b.isEven()) b.subTo(m,b); b.rShiftTo(1,b); } while(v.isEven()) { v.rShiftTo(1,v); if(ac) { if(!c.isEven() || !d.isEven()) { c.addTo(this,c); d.subTo(m,d); } c.rShiftTo(1,c); } else if(!d.isEven()) d.subTo(m,d); d.rShiftTo(1,d); } if(u.compareTo(v) >= 0) { u.subTo(v,u); if(ac) a.subTo(c,a); b.subTo(d,b); } else { v.subTo(u,v); if(ac) c.subTo(a,c); d.subTo(b,d); } } if(v.compareTo(BigInteger.ONE) != 0) return BigInteger.ZERO; if(d.compareTo(m) >= 0) return d.subtract(m); if(d.signum() < 0) d.addTo(m,d); else return d; if(d.signum() < 0) return d.add(m); else return d; } // protected proto.chunkSize = bnpChunkSize; proto.toRadix = bnpToRadix; proto.fromRadix = bnpFromRadix; proto.fromNumber = bnpFromNumber; proto.bitwiseTo = bnpBitwiseTo; proto.changeBit = bnpChangeBit; proto.addTo = bnpAddTo; proto.dMultiply = bnpDMultiply; proto.dAddOffset = bnpDAddOffset; proto.multiplyLowerTo = bnpMultiplyLowerTo; proto.multiplyUpperTo = bnpMultiplyUpperTo; proto.modInt = bnpModInt; // public proto.clone = bnClone; proto.intValue = bnIntValue; proto.byteValue = bnByteValue; proto.shortValue = bnShortValue; proto.signum = bnSigNum; proto.toByteArray = bnToByteArray; proto.equals = bnEquals; proto.min = bnMin; proto.max = bnMax; proto.and = bnAnd; proto.or = bnOr; proto.xor = bnXor; proto.andNot = bnAndNot; proto.not = bnNot; proto.shiftLeft = bnShiftLeft; proto.shiftRight = bnShiftRight; proto.getLowestSetBit = bnGetLowestSetBit; proto.bitCount = bnBitCount; proto.testBit = bnTestBit; proto.setBit = bnSetBit; proto.clearBit = bnClearBit; proto.flipBit = bnFlipBit; proto.add = bnAdd; proto.subtract = bnSubtract; proto.multiply = bnMultiply; proto.divide = bnDivide; proto.remainder = bnRemainder; proto.divideAndRemainder = bnDivideAndRemainder; proto.modPow = bnModPow; proto.modInverse = bnModInverse; proto.pow = bnPow; proto.gcd = bnGCD; // JSBN-specific extension proto.square = bnSquare; // BigInteger interfaces not implemented in jsbn: // BigInteger(int signum, byte[] magnitude) // double doubleValue() // float floatValue() // int hashCode() // long longValue() // static BigInteger valueOf(long val) // "constants" BigInteger.ZERO = nbv(0); BigInteger.ONE = nbv(1); BigInteger.valueOf = nbv; },{"assert":4}],2:[function(_dereq_,module,exports){ (function (Buffer){ // FIXME: Kind of a weird way to throw exceptions, consider removing var assert = _dereq_('assert') var BigInteger = _dereq_('./bigi') /** * Turns a byte array into a big integer. * * This function will interpret a byte array as a big integer in big * endian notation. */ BigInteger.fromByteArrayUnsigned = function(byteArray) { // BigInteger expects a DER integer conformant byte array if (byteArray[0] & 0x80) { return new BigInteger([0].concat(byteArray)) } return new BigInteger(byteArray) } /** * Returns a byte array representation of the big integer. * * This returns the absolute of the contained value in big endian * form. A value of zero results in an empty array. */ BigInteger.prototype.toByteArrayUnsigned = function() { var byteArray = this.toByteArray() return byteArray[0] === 0 ? byteArray.slice(1) : byteArray } BigInteger.fromDERInteger = function(byteArray) { return new BigInteger(byteArray) } /* * Converts BigInteger to a DER integer representation. * * The format for this value uses the most significant bit as a sign * bit. If the most significant bit is already set and the integer is * positive, a 0x00 is prepended. * * Examples: * * 0 => 0x00 * 1 => 0x01 * -1 => 0x81 * 127 => 0x7f * -127 => 0xff * 128 => 0x0080 * -128 => 0x80 * 255 => 0x00ff * -255 => 0xff * 16300 => 0x3fac * -16300 => 0xbfac * 62300 => 0x00f35c * -62300 => 0xf35c */ BigInteger.prototype.toDERInteger = BigInteger.prototype.toByteArray BigInteger.fromBuffer = function(buffer) { // BigInteger expects a DER integer conformant byte array if (buffer[0] & 0x80) { var byteArray = Array.prototype.slice.call(buffer) return new BigInteger([0].concat(byteArray)) } return new BigInteger(buffer) } BigInteger.fromHex = function(hex) { if (hex === '') return BigInteger.ZERO assert.equal(hex, hex.match(/^[A-Fa-f0-9]+/), 'Invalid hex string') assert.equal(hex.length % 2, 0, 'Incomplete hex') return new BigInteger(hex, 16) } BigInteger.prototype.toBuffer = function(size) { var byteArray = this.toByteArrayUnsigned() var zeros = [] var padding = size - byteArray.length while (zeros.length < padding) zeros.push(0) return new Buffer(zeros.concat(byteArray)) } BigInteger.prototype.toHex = function(size) { return this.toBuffer(size).toString('hex') } }).call(this,_dereq_("buffer").Buffer) },{"./bigi":1,"assert":4,"buffer":8}],3:[function(_dereq_,module,exports){ var BigInteger = _dereq_('./bigi') //addons _dereq_('./convert') module.exports = BigInteger },{"./bigi":1,"./convert":2}],4:[function(_dereq_,module,exports){ // http://wiki.commonjs.org/wiki/Unit_Testing/1.0 // // THIS IS NOT TESTED NOR LIKELY TO WORK OUTSIDE V8! // // Originally from narwhal.js (http://narwhaljs.org) // Copyright (c) 2009 Thomas Robinson <280north.com> // // Permission is hereby granted, free of charge, to any person obtaining a copy // of this software and associated documentation files (the 'Software'), to // deal in the Software without restriction, including without limitation the // rights to use, copy, modify, merge, publish, distribute, sublicense, and/or // sell copies of the Software, and to permit persons to whom the Software is // furnished to do so, subject to the following conditions: // // The above copyright notice and this permission notice shall be included in // all copies or substantial portions of the Software. // // THE SOFTWARE IS PROVIDED 'AS IS', WITHOUT WARRANTY OF ANY KIND, EXPRESS OR // IMPLIED, INCLUDING BUT NOT LIMITED TO THE WARRANTIES OF MERCHANTABILITY, // FITNESS FOR A PARTICULAR PURPOSE AND NONINFRINGEMENT. IN NO EVENT SHALL THE // AUTHORS BE LIABLE FOR ANY CLAIM, DAMAGES OR OTHER LIABILITY, WHETHER IN AN // ACTION OF CONTRACT, TORT OR OTHERWISE, ARISING FROM, OUT OF OR IN CONNECTION // WITH THE SOFTWARE OR THE USE OR OTHER DEALINGS IN THE SOFTWARE. // when used in node, this will actually load the util module we depend on // versus loading the builtin util module as happens otherwise // this is a bug in node module loading as far as I am concerned var util = _dereq_('util/'); var pSlice = Array.prototype.slice; var hasOwn = Object.prototype.hasOwnProperty; // 1. The assert module provides functions that throw // AssertionError's when particular conditions are not met. The // assert module must conform to the following interface. var assert = module.exports = ok; // 2. The AssertionError is defined in assert. // new assert.AssertionError({ message: message, // actual: actual, // expected: expected }) assert.AssertionError = function AssertionError(options) { this.name = 'AssertionError'; this.actual = options.actual; this.expected = options.expected; this.operator = options.operator; if (options.message) { this.message = options.message; this.generatedMessage = false; } else { this.message = getMessage(this); this.generatedMessage = true; } var stackStartFunction = options.stackStartFunction || fail; if (Error.captureStackTrace) { Error.captureStackTrace(this, stackStartFunction); } else { // non v8 browsers so we can have a stacktrace var err = new Error(); if (err.stack) { var out = err.stack; // try to strip useless frames var fn_name = stackStartFunction.name; var idx = out.indexOf('\n' + fn_name); if (idx >= 0) { // once we have located the function frame // we need to strip out everything before it (and its line) var next_line = out.indexOf('\n', idx + 1); out = out.substring(next_line + 1); } this.stack = out; } } }; // assert.AssertionError instanceof Error util.inherits(assert.AssertionError, Error); function replacer(key, value) { if (util.isUndefined(value)) { return '' + value; } if (util.isNumber(value) && (isNaN(value) || !isFinite(value))) { return value.toString(); } if (util.isFunction(value) || util.isRegExp(value)) { return value.toString(); } return value; } function truncate(s, n) { if (util.isString(s)) { return s.length < n ? s : s.slice(0, n); } else { return s; } } function getMessage(self) { return truncate(JSON.stringify(self.actual, replacer), 128) + ' ' + self.operator + ' ' + truncate(JSON.stringify(self.expected, replacer), 128); } // At present only the three keys mentioned above are used and // understood by the spec. Implementations or sub modules can pass // other keys to the AssertionError's constructor - they will be // ignored. // 3. All of the following functions must throw an AssertionError // when a corresponding condition is not met, with a message that // may be undefined if not provided. All assertion methods provide // both the actual and expected values to the assertion error for // display purposes. function fail(actual, expected, message, operator, stackStartFunction) { throw new assert.AssertionError({ message: message, actual: actual, expected: expected, operator: operator, stackStartFunction: stackStartFunction }); } // EXTENSION! allows for well behaved errors defined elsewhere. assert.fail = fail; // 4. Pure assertion tests whether a value is truthy, as determined // by !!guard. // assert.ok(guard, message_opt); // This statement is equivalent to assert.equal(true, !!guard, // message_opt);. To test strictly for the value true, use // assert.strictEqual(true, guard, message_opt);. function ok(value, message) { if (!value) fail(value, true, message, '==', assert.ok); } assert.ok = ok; // 5. The equality assertion tests shallow, coercive equality with // ==. // assert.equal(actual, expected, message_opt); assert.equal = function equal(actual, expected, message) { if (actual != expected) fail(actual, expected, message, '==', assert.equal); }; // 6. The non-equality assertion tests for whether two objects are not equal // with != assert.notEqual(actual, expected, message_opt); assert.notEqual = function notEqual(actual, expected, message) { if (actual == expected) { fail(actual, expected, message, '!=', assert.notEqual); } }; // 7. The equivalence assertion tests a deep equality relation. // assert.deepEqual(actual, expected, message_opt); assert.deepEqual = function deepEqual(actual, expected, message) { if (!_deepEqual(actual, expected)) { fail(actual, expected, message, 'deepEqual', assert.deepEqual); } }; function _deepEqual(actual, expected) { // 7.1. All identical values are equivalent, as determined by ===. if (actual === expected) { return true; } else if (util.isBuffer(actual) && util.isBuffer(expected)) { if (actual.length != expected.length) return false; for (var i = 0; i < actual.length; i++) { if (actual[i] !== expected[i]) return false; } return true; // 7.2. If the expected value is a Date object, the actual value is // equivalent if it is also a Date object that refers to the same time. } else if (util.isDate(actual) && util.isDate(expected)) { return actual.getTime() === expected.getTime(); // 7.3 If the expected value is a RegExp object, the actual value is // equivalent if it is also a RegExp object with the same source and // properties (`global`, `multiline`, `lastIndex`, `ignoreCase`). } else if (util.isRegExp(actual) && util.isRegExp(expected)) { return actual.source === expected.source && actual.global === expected.global && actual.multiline === expected.multiline && actual.lastIndex === expected.lastIndex && actual.ignoreCase === expected.ignoreCase; // 7.4. Other pairs that do not both pass typeof value == 'object', // equivalence is determined by ==. } else if (!util.isObject(actual) && !util.isObject(expected)) { return actual == expected; // 7.5 For all other Object pairs, including Array objects, equivalence is // determined by having the same number of owned properties (as verified // with Object.prototype.hasOwnProperty.call), the same set of keys // (although not necessarily the same order), equivalent values for every // corresponding key, and an identical 'prototype' property. Note: this // accounts for both named and indexed properties on Arrays. } else { return objEquiv(actual, expected); } } function isArguments(object) { return Object.prototype.toString.call(object) == '[object Arguments]'; } function objEquiv(a, b) { if (util.isNullOrUndefined(a) || util.isNullOrUndefined(b)) return false; // an identical 'prototype' property. if (a.prototype !== b.prototype) return false; //~~~I've managed to break Object.keys through screwy arguments passing. // Converting to array solves the problem. if (isArguments(a)) { if (!isArguments(b)) { return false; } a = pSlice.call(a); b = pSlice.call(b); return _deepEqual(a, b); } try { var ka = objectKeys(a), kb = objectKeys(b), key, i; } catch (e) {//happens when one is a string literal and the other isn't return false; } // having the same number of owned properties (keys incorporates // hasOwnProperty) if (ka.length != kb.length) return false; //the same set of keys (although not necessarily the same order), ka.sort(); kb.sort(); //~~~cheap key test for (i = ka.length - 1; i >= 0; i--) { if (ka[i] != kb[i]) return false; } //equivalent values for every corresponding key, and //~~~possibly expensive deep test for (i = ka.length - 1; i >= 0; i--) { key = ka[i]; if (!_deepEqual(a[key], b[key])) return false; } return true; } // 8. The non-equivalence assertion tests for any deep inequality. // assert.notDeepEqual(actual, expected, message_opt); assert.notDeepEqual = function notDeepEqual(actual, expected, message) { if (_deepEqual(actual, expected)) { fail(actual, expected, message, 'notDeepEqual', assert.notDeepEqual); } }; // 9. The strict equality assertion tests strict equality, as determined by ===. // assert.strictEqual(actual, expected, message_opt); assert.strictEqual = function strictEqual(actual, expected, message) { if (actual !== expected) { fail(actual, expected, message, '===', assert.strictEqual); } }; // 10. The strict non-equality assertion tests for strict inequality, as // determined by !==. assert.notStrictEqual(actual, expected, message_opt); assert.notStrictEqual = function notStrictEqual(actual, expected, message) { if (actual === expected) { fail(actual, expected, message, '!==', assert.notStrictEqual); } }; function expectedException(actual, expected) { if (!actual || !expected) { return false; } if (Object.prototype.toString.call(expected) == '[object RegExp]') { return expected.test(actual); } else if (actual instanceof expected) { return true; } else if (expected.call({}, actual) === true) { return true; } return false; } function _throws(shouldThrow, block, expected, message) { var actual; if (util.isString(expected)) { message = expected; expected = null; } try { block(); } catch (e) { actual = e; } message = (expected && expected.name ? ' (' + expected.name + ').' : '.') + (message ? ' ' + message : '.'); if (shouldThrow && !actual) { fail(actual, expected, 'Missing expected exception' + message); } if (!shouldThrow && expectedException(actual, expected)) { fail(actual, expected, 'Got unwanted exception' + message); } if ((shouldThrow && actual && expected && !expectedException(actual, expected)) || (!shouldThrow && actual)) { throw actual; } } // 11. Expected to throw an error: // assert.throws(block, Error_opt, message_opt); assert.throws = function(block, /*optional*/error, /*optional*/message) { _throws.apply(this, [true].concat(pSlice.call(arguments))); }; // EXTENSION! This is annoying to write outside this module. assert.doesNotThrow = function(block, /*optional*/message) { _throws.apply(this, [false].concat(pSlice.call(arguments))); }; assert.ifError = function(err) { if (err) {throw err;}}; var objectKeys = Object.keys || function (obj) { var keys = []; for (var key in obj) { if (hasOwn.call(obj, key)) keys.push(key); } return keys; }; },{"util/":6}],5:[function(_dereq_,module,exports){ module.exports = function isBuffer(arg) { return arg && typeof arg === 'object' && typeof arg.copy === 'function' && typeof arg.fill === 'function' && typeof arg.readUInt8 === 'function'; } },{}],6:[function(_dereq_,module,exports){ (function (process,global){ // Copyright Joyent, Inc. and other Node contributors. // // Permission is hereby granted, free of charge, to any person obtaining a // copy of this software and associated documentation files (the // "Software"), to deal in the Software without restriction, including // without limitation the rights to use, copy, modify, merge, publish, // distribute, sublicense, and/or sell copies of the Software, and to permit // persons to whom the Software is furnished to do so, subject to the // following conditions: // // The above copyright notice and this permission notice shall be included // in all copies or substantial portions of the Software. // // THE SOFTWARE IS PROVIDED "AS IS", WITHOUT WARRANTY OF ANY KIND, EXPRESS // OR IMPLIED, INCLUDING BUT NOT LIMITED TO THE WARRANTIES OF // MERCHANTABILITY, FITNESS FOR A PARTICULAR PURPOSE AND NONINFRINGEMENT. IN // NO EVENT SHALL THE AUTHORS OR COPYRIGHT HOLDERS BE LIABLE FOR ANY CLAIM, // DAMAGES OR OTHER LIABILITY, WHETHER IN AN ACTION OF CONTRACT, TORT OR // OTHERWISE, ARISING FROM, OUT OF OR IN CONNECTION WITH THE SOFTWARE OR THE // USE OR OTHER DEALINGS IN THE SOFTWARE. var formatRegExp = /%[sdj%]/g; exports.format = function(f) { if (!isString(f)) { var objects = []; for (var i = 0; i < arguments.length; i++) { objects.push(inspect(arguments[i])); } return objects.join(' '); } var i = 1; var args = arguments; var len = args.length; var str = String(f).replace(formatRegExp, function(x) { if (x === '%%') return '%'; if (i >= len) return x; switch (x) { case '%s': return String(args[i++]); case '%d': return Number(args[i++]); case '%j': try { return JSON.stringify(args[i++]); } catch (_) { return '[Circular]'; } default: return x; } }); for (var x = args[i]; i < len; x = args[++i]) { if (isNull(x) || !isObject(x)) { str += ' ' + x; } else { str += ' ' + inspect(x); } } return str; }; // Mark that a method should not be used. // Returns a modified function which warns once by default. // If --no-deprecation is set, then it is a no-op. exports.deprecate = function(fn, msg) { // Allow for deprecating things in the process of starting up. if (isUndefined(global.process)) { return function() { return exports.deprecate(fn, msg).apply(this, arguments); }; } if (process.noDeprecation === true) { return fn; } var warned = false; function deprecated() { if (!warned) { if (process.throwDeprecation) { throw new Error(msg); } else if (process.traceDeprecation) { console.trace(msg); } else { console.error(msg); } warned = true; } return fn.apply(this, arguments); } return deprecated; }; var debugs = {}; var debugEnviron; exports.debuglog = function(set) { if (isUndefined(debugEnviron)) debugEnviron = process.env.NODE_DEBUG || ''; set = set.toUpperCase(); if (!debugs[set]) { if (new RegExp('\\b' + set + '\\b', 'i').test(debugEnviron)) { var pid = process.pid; debugs[set] = function() { var msg = exports.format.apply(exports, arguments); console.error('%s %d: %s', set, pid, msg); }; } else { debugs[set] = function() {}; } } return debugs[set]; }; /** * Echos the value of a value. Trys to print the value out * in the best way possible given the different types. * * @param {Object} obj The object to print out. * @param {Object} opts Optional options object that alters the output. */ /* legacy: obj, showHidden, depth, colors*/ function inspect(obj, opts) { // default options var ctx = { seen: [], stylize: stylizeNoColor }; // legacy... if (arguments.length >= 3) ctx.depth = arguments[2]; if (arguments.length >= 4) ctx.colors = arguments[3]; if (isBoolean(opts)) { // legacy... ctx.showHidden = opts; } else if (opts) { // got an "options" object exports._extend(ctx, opts); } // set default options if (isUndefined(ctx.showHidden)) ctx.showHidden = false; if (isUndefined(ctx.depth)) ctx.depth = 2; if (isUndefined(ctx.colors)) ctx.colors = false; if (isUndefined(ctx.customInspect)) ctx.customInspect = true; if (ctx.colors) ctx.stylize = stylizeWithColor; return formatValue(ctx, obj, ctx.depth); } exports.inspect = inspect; // http://en.wikipedia.org/wiki/ANSI_escape_code#graphics inspect.colors = { 'bold' : [1, 22], 'italic' : [3, 23], 'underline' : [4, 24], 'inverse' : [7, 27], 'white' : [37, 39], 'grey' : [90, 39], 'black' : [30, 39], 'blue' : [34, 39], 'cyan' : [36, 39], 'green' : [32, 39], 'magenta' : [35, 39], 'red' : [31, 39], 'yellow' : [33, 39] }; // Don't use 'blue' not visible on cmd.exe inspect.styles = { 'special': 'cyan', 'number': 'yellow', 'boolean': 'yellow', 'undefined': 'grey', 'null': 'bold', 'string': 'green', 'date': 'magenta', // "name": intentionally not styling 'regexp': 'red' }; function stylizeWithColor(str, styleType) { var style = inspect.styles[styleType]; if (style) { return '\u001b[' + inspect.colors[style][0] + 'm' + str + '\u001b[' + inspect.colors[style][1] + 'm'; } else { return str; } } function stylizeNoColor(str, styleType) { return str; } function arrayToHash(array) { var hash = {}; array.forEach(function(val, idx) { hash[val] = true; }); return hash; } function formatValue(ctx, value, recurseTimes) { // Provide a hook for user-specified inspect functions. // Check that value is an object with an inspect function on it if (ctx.customInspect && value && isFunction(value.inspect) && // Filter out the util module, it's inspect function is special value.inspect !== exports.inspect && // Also filter out any prototype objects using the circular check. !(value.constructor && value.constructor.prototype === value)) { var ret = value.inspect(recurseTimes, ctx); if (!isString(ret)) { ret = formatValue(ctx, ret, recurseTimes); } return ret; } // Primitive types cannot have properties var primitive = formatPrimitive(ctx, value); if (primitive) { return primitive; } // Look up the keys of the object. var keys = Object.keys(value); var visibleKeys = arrayToHash(keys); if (ctx.showHidden) { keys = Object.getOwnPropertyNames(value); } // IE doesn't make error fields non-enumerable // http://msdn.microsoft.com/en-us/library/ie/dww52sbt(v=vs.94).aspx if (isError(value) && (keys.indexOf('message') >= 0 || keys.indexOf('description') >= 0)) { return formatError(value); } // Some type of object without properties can be shortcutted. if (keys.length === 0) { if (isFunction(value)) { var name = value.name ? ': ' + value.name : ''; return ctx.stylize('[Function' + name + ']', 'special'); } if (isRegExp(value)) { return ctx.stylize(RegExp.prototype.toString.call(value), 'regexp'); } if (isDate(value)) { return ctx.stylize(Date.prototype.toString.call(value), 'date'); } if (isError(value)) { return formatError(value); } } var base = '', array = false, braces = ['{', '}']; // Make Array say that they are Array if (isArray(value)) { array = true; braces = ['[', ']']; } // Make functions say that they are functions if (isFunction(value)) { var n = value.name ? ': ' + value.name : ''; base = ' [Function' + n + ']'; } // Make RegExps say that they are RegExps if (isRegExp(value)) { base = ' ' + RegExp.prototype.toString.call(value); } // Make dates with properties first say the date if (isDate(value)) { base = ' ' + Date.prototype.toUTCString.call(value); } // Make error with message first say the error if (isError(value)) { base = ' ' + formatError(value); } if (keys.length === 0 && (!array || value.length == 0)) { return braces[0] + base + braces[1]; } if (recurseTimes < 0) { if (isRegExp(value)) { return ctx.stylize(RegExp.prototype.toString.call(value), 'regexp'); } else { return ctx.stylize('[Object]', 'special'); } } ctx.seen.push(value); var output; if (array) { output = formatArray(ctx, value, recurseTimes, visibleKeys, keys); } else { output = keys.map(function(key) { return formatProperty(ctx, value, recurseTimes, visibleKeys, key, array); }); } ctx.seen.pop(); return reduceToSingleString(output, base, braces); } function formatPrimitive(ctx, value) { if (isUndefined(value)) return ctx.stylize('undefined', 'undefined'); if (isString(value)) { var simple = '\'' + JSON.stringify(value).replace(/^"|"$/g, '') .replace(/'/g, "\\'") .replace(/\\"/g, '"') + '\''; return ctx.stylize(simple, 'string'); } if (isNumber(value)) return ctx.stylize('' + value, 'number'); if (isBoolean(value)) return ctx.stylize('' + value, 'boolean'); // For some reason typeof null is "object", so special case here. if (isNull(value)) return ctx.stylize('null', 'null'); } function formatError(value) { return '[' + Error.prototype.toString.call(value) + ']'; } function formatArray(ctx, value, recurseTimes, visibleKeys, keys) { var output = []; for (var i = 0, l = value.length; i < l; ++i) { if (hasOwnProperty(value, String(i))) { output.push(formatProperty(ctx, value, recurseTimes, visibleKeys, String(i), true)); } else { output.push(''); } } keys.forEach(function(key) { if (!key.match(/^\d+$/)) { output.push(formatProperty(ctx, value, recurseTimes, visibleKeys, key, true)); } }); return output; } function formatProperty(ctx, value, recurseTimes, visibleKeys, key, array) { var name, str, desc; desc = Object.getOwnPropertyDescriptor(value, key) || { value: value[key] }; if (desc.get) { if (desc.set) { str = ctx.stylize('[Getter/Setter]', 'special'); } else { str = ctx.stylize('[Getter]', 'special'); } } else { if (desc.set) { str = ctx.stylize('[Setter]', 'special'); } } if (!hasOwnProperty(visibleKeys, key)) { name = '[' + key + ']'; } if (!str) { if (ctx.seen.indexOf(desc.value) < 0) { if (isNull(recurseTimes)) { str = formatValue(ctx, desc.value, null); } else { str = formatValue(ctx, desc.value, recurseTimes - 1); } if (str.indexOf('\n') > -1) { if (array) { str = str.split('\n').map(function(line) { return ' ' + line; }).join('\n').substr(2); } else { str = '\n' + str.split('\n').map(function(line) { return ' ' + line; }).join('\n'); } } } else { str = ctx.stylize('[Circular]', 'special'); } } if (isUndefined(name)) { if (array && key.match(/^\d+$/)) { return str; } name = JSON.stringify('' + key); if (name.match(/^"([a-zA-Z_][a-zA-Z_0-9]*)"$/)) { name = name.substr(1, name.length - 2); name = ctx.stylize(name, 'name'); } else { name = name.replace(/'/g, "\\'") .replace(/\\"/g, '"') .replace(/(^"|"$)/g, "'"); name = ctx.stylize(name, 'string'); } } return name + ': ' + str; } function reduceToSingleString(output, base, braces) { var numLinesEst = 0; var length = output.reduce(function(prev, cur) { numLinesEst++; if (cur.indexOf('\n') >= 0) numLinesEst++; return prev + cur.replace(/\u001b\[\d\d?m/g, '').length + 1; }, 0); if (length > 60) { return braces[0] + (base === '' ? '' : base + '\n ') + ' ' + output.join(',\n ') + ' ' + braces[1]; } return braces[0] + base + ' ' + output.join(', ') + ' ' + braces[1]; } // NOTE: These type checking functions intentionally don't use `instanceof` // because it is fragile and can be easily faked with `Object.create()`. function isArray(ar) { return Array.isArray(ar); } exports.isArray = isArray; function isBoolean(arg) { return typeof arg === 'boolean'; } exports.isBoolean = isBoolean; function isNull(arg) { return arg === null; } exports.isNull = isNull; function isNullOrUndefined(arg) { return arg == null; } exports.isNullOrUndefined = isNullOrUndefined; function isNumber(arg) { return typeof arg === 'number'; } exports.isNumber = isNumber; function isString(arg) { return typeof arg === 'string'; } exports.isString = isString; function isSymbol(arg) { return typeof arg === 'symbol'; } exports.isSymbol = isSymbol; function isUndefined(arg) { return arg === void 0; } exports.isUndefined = isUndefined; function isRegExp(re) { return isObject(re) && objectToString(re) === '[object RegExp]'; } exports.isRegExp = isRegExp; function isObject(arg) { return typeof arg === 'object' && arg !== null; } exports.isObject = isObject; function isDate(d) { return isObject(d) && objectToString(d) === '[object Date]'; } exports.isDate = isDate; function isError(e) { return isObject(e) && (objectToString(e) === '[object Error]' || e instanceof Error); } exports.isError = isError; function isFunction(arg) { return typeof arg === 'function'; } exports.isFunction = isFunction; function isPrimitive(arg) { return arg === null || typeof arg === 'boolean' || typeof arg === 'number' || typeof arg === 'string' || typeof arg === 'symbol' || // ES6 symbol typeof arg === 'undefined'; } exports.isPrimitive = isPrimitive; exports.isBuffer = _dereq_('./support/isBuffer'); function objectToString(o) { return Object.prototype.toString.call(o); } function pad(n) { return n < 10 ? '0' + n.toString(10) : n.toString(10); } var months = ['Jan', 'Feb', 'Mar', 'Apr', 'May', 'Jun', 'Jul', 'Aug', 'Sep', 'Oct', 'Nov', 'Dec']; // 26 Feb 16:19:34 function timestamp() { var d = new Date(); var time = [pad(d.getHours()), pad(d.getMinutes()), pad(d.getSeconds())].join(':'); return [d.getDate(), months[d.getMonth()], time].join(' '); } // log is just a thin wrapper to console.log that prepends a timestamp exports.log = function() { console.log('%s - %s', timestamp(), exports.format.apply(exports, arguments)); }; /** * Inherit the prototype methods from one constructor into another. * * The Function.prototype.inherits from lang.js rewritten as a standalone * function (not on Function.prototype). NOTE: If this file is to be loaded * during bootstrapping this function needs to be rewritten using some native * functions as prototype setup using normal JavaScript does not work as * expected during bootstrapping (see mirror.js in r114903). * * @param {function} ctor Constructor function which needs to inherit the * prototype. * @param {function} superCtor Constructor function to inherit prototype from. */ exports.inherits = _dereq_('inherits'); exports._extend = function(origin, add) { // Don't do anything if add isn't an object if (!add || !isObject(add)) return origin; var keys = Object.keys(add); var i = keys.length; while (i--) { origin[keys[i]] = add[keys[i]]; } return origin; }; function hasOwnProperty(obj, prop) { return Object.prototype.hasOwnProperty.call(obj, prop); } }).call(this,_dereq_("FWaASH"),typeof self !== "undefined" ? self : typeof window !== "undefined" ? window : {}) },{"./support/isBuffer":5,"FWaASH":12,"inherits":11}],7:[function(_dereq_,module,exports){ },{}],8:[function(_dereq_,module,exports){ /*! * The buffer module from node.js, for the browser. * * at author Feross Aboukhadijeh * at license MIT */ var base64 = _dereq_('base64-js') var ieee754 = _dereq_('ieee754') exports.Buffer = Buffer exports.SlowBuffer = Buffer exports.INSPECT_MAX_BYTES = 50 Buffer.poolSize = 8192 /** * If `Buffer._useTypedArrays`: * === true Use Uint8Array implementation (fastest) * === false Use Object implementation (compatible down to IE6) */ Buffer._useTypedArrays = (function () { // Detect if browser supports Typed Arrays. Supported browsers are IE 10+, Firefox 4+, // Chrome 7+, Safari 5.1+, Opera 11.6+, iOS 4.2+. If the browser does not support adding // properties to `Uint8Array` instances, then that's the same as no `Uint8Array` support // because we need to be able to add all the node Buffer API methods. This is an issue // in Firefox 4-29. Now fixed: https://bugzilla.mozilla.org/show_bug.cgi?id=695438 try { var buf = new ArrayBuffer(0) var arr = new Uint8Array(buf) arr.foo = function () { return 42 } return 42 === arr.foo() && typeof arr.subarray === 'function' // Chrome 9-10 lack `subarray` } catch (e) { return false } })() /** * Class: Buffer * ============= * * The Buffer constructor returns instances of `Uint8Array` that are augmented * with function properties for all the node `Buffer` API functions. We use * `Uint8Array` so that square bracket notation works as expected -- it returns * a single octet. * * By augmenting the instances, we can avoid modifying the `Uint8Array` * prototype. */ function Buffer (subject, encoding, noZero) { if (!(this instanceof Buffer)) return new Buffer(subject, encoding, noZero) var type = typeof subject if (encoding === 'base64' && type === 'string') { subject = base64clean(subject) } // Find the length var length if (type === 'number') length = coerce(subject) else if (type === 'string') length = Buffer.byteLength(subject, encoding) else if (type === 'object') length = coerce(subject.length) // assume that object is array-like else throw new Error('First argument needs to be a number, array or string.') var buf if (Buffer._useTypedArrays) { // Preferred: Return an augmented `Uint8Array` instance for best performance buf = Buffer._augment(new Uint8Array(length)) } else { // Fallback: Return THIS instance of Buffer (created by `new`) buf = this buf.length = length buf._isBuffer = true } var i if (Buffer._useTypedArrays && typeof subject.byteLength === 'number') { // Speed optimization -- use set if we're copying from a typed array buf._set(subject) } else if (isArrayish(subject)) { // Treat array-ish objects as a byte array if (Buffer.isBuffer(subject)) { for (i = 0; i < length; i++) buf[i] = subject.readUInt8(i) } else { for (i = 0; i < length; i++) buf[i] = ((subject[i] % 256) + 256) % 256 } } else if (type === 'string') { buf.write(subject, 0, encoding) } else if (type === 'number' && !Buffer._useTypedArrays && !noZero) { for (i = 0; i < length; i++) { buf[i] = 0 } } return buf } // STATIC METHODS // ============== Buffer.isEncoding = function (encoding) { switch (String(encoding).toLowerCase()) { case 'hex': case 'utf8': case 'utf-8': case 'ascii': case 'binary': case 'base64': case 'raw': case 'ucs2': case 'ucs-2': case 'utf16le': case 'utf-16le': return true default: return false } } Buffer.isBuffer = function (b) { return !!(b !== null && b !== undefined && b._isBuffer) } Buffer.byteLength = function (str, encoding) { var ret str = str.toString() switch (encoding || 'utf8') { case 'hex': ret = str.length / 2 break case 'utf8': case 'utf-8': ret = utf8ToBytes(str).length break case 'ascii': case 'binary': case 'raw': ret = str.length break case 'base64': ret = base64ToBytes(str).length break case 'ucs2': case 'ucs-2': case 'utf16le': case 'utf-16le': ret = str.length * 2 break default: throw new Error('Unknown encoding') } return ret } Buffer.concat = function (list, totalLength) { assert(isArray(list), 'Usage: Buffer.concat(list[, length])') if (list.length === 0) { return new Buffer(0) } else if (list.length === 1) { return list[0] } var i if (totalLength === undefined) { totalLength = 0 for (i = 0; i < list.length; i++) { totalLength += list[i].length } } var buf = new Buffer(totalLength) var pos = 0 for (i = 0; i < list.length; i++) { var item = list[i] item.copy(buf, pos) pos += item.length } return buf } Buffer.compare = function (a, b) { assert(Buffer.isBuffer(a) && Buffer.isBuffer(b), 'Arguments must be Buffers') var x = a.length var y = b.length for (var i = 0, len = Math.min(x, y); i < len && a[i] === b[i]; i++) {} if (i !== len) { x = a[i] y = b[i] } if (x < y) { return -1 } if (y < x) { return 1 } return 0 } // BUFFER INSTANCE METHODS // ======================= function hexWrite (buf, string, offset, length) { offset = Number(offset) || 0 var remaining = buf.length - offset if (!length) { length = remaining } else { length = Number(length) if (length > remaining) { length = remaining } } // must be an even number of digits var strLen = string.length assert(strLen % 2 === 0, 'Invalid hex string') if (length > strLen / 2) { length = strLen / 2 } for (var i = 0; i < length; i++) { var byte = parseInt(string.substr(i * 2, 2), 16) assert(!isNaN(byte), 'Invalid hex string') buf[offset + i] = byte } return i } function utf8Write (buf, string, offset, length) { var charsWritten = blitBuffer(utf8ToBytes(string), buf, offset, length) return charsWritten } function asciiWrite (buf, string, offset, length) { var charsWritten = blitBuffer(asciiToBytes(string), buf, offset, length) return charsWritten } function binaryWrite (buf, string, offset, length) { return asciiWrite(buf, string, offset, length) } function base64Write (buf, string, offset, length) { var charsWritten = blitBuffer(base64ToBytes(string), buf, offset, length) return charsWritten } function utf16leWrite (buf, string, offset, length) { var charsWritten = blitBuffer(utf16leToBytes(string), buf, offset, length) return charsWritten } Buffer.prototype.write = function (string, offset, length, encoding) { // Support both (string, offset, length, encoding) // and the legacy (string, encoding, offset, length) if (isFinite(offset)) { if (!isFinite(length)) { encoding = length length = undefined } } else { // legacy var swap = encoding encoding = offset offset = length length = swap } offset = Number(offset) || 0 var remaining = this.length - offset if (!length) { length = remaining } else { length = Number(length) if (length > remaining) { length = remaining } } encoding = String(encoding || 'utf8').toLowerCase() var ret switch (encoding) { case 'hex': ret = hexWrite(this, string, offset, length) break case 'utf8': case 'utf-8': ret = utf8Write(this, string, offset, length) break case 'ascii': ret = asciiWrite(this, string, offset, length) break case 'binary': ret = binaryWrite(this, string, offset, length) break case 'base64': ret = base64Write(this, string, offset, length) break case 'ucs2': case 'ucs-2': case 'utf16le': case 'utf-16le': ret = utf16leWrite(this, string, offset, length) break default: throw new Error('Unknown encoding') } return ret } Buffer.prototype.toString = function (encoding, start, end) { var self = this encoding = String(encoding || 'utf8').toLowerCase() start = Number(start) || 0 end = (end === undefined) ? self.length : Number(end) // Fastpath empty strings if (end === start) return '' var ret switch (encoding) { case 'hex': ret = hexSlice(self, start, end) break case 'utf8': case 'utf-8': ret = utf8Slice(self, start, end) break case 'ascii': ret = asciiSlice(self, start, end) break case 'binary': ret = binarySlice(self, start, end) break case 'base64': ret = base64Slice(self, start, end) break case 'ucs2': case 'ucs-2': case 'utf16le': case 'utf-16le': ret = utf16leSlice(self, start, end) break default: throw new Error('Unknown encoding') } return ret } Buffer.prototype.toJSON = function () { return { type: 'Buffer', data: Array.prototype.slice.call(this._arr || this, 0) } } Buffer.prototype.equals = function (b) { assert(Buffer.isBuffer(b), 'Argument must be a Buffer') return Buffer.compare(this, b) === 0 } Buffer.prototype.compare = function (b) { assert(Buffer.isBuffer(b), 'Argument must be a Buffer') return Buffer.compare(this, b) } // copy(targetBuffer, targetStart=0, sourceStart=0, sourceEnd=buffer.length) Buffer.prototype.copy = function (target, target_start, start, end) { var source = this if (!start) start = 0 if (!end && end !== 0) end = this.length if (!target_start) target_start = 0 // Copy 0 bytes; we're done if (end === start) return if (target.length === 0 || source.length === 0) return // Fatal error conditions assert(end >= start, 'sourceEnd < sourceStart') assert(target_start >= 0 && target_start < target.length, 'targetStart out of bounds') assert(start >= 0 && start < source.length, 'sourceStart out of bounds') assert(end >= 0 && end <= source.length, 'sourceEnd out of bounds') // Are we oob? if (end > this.length) end = this.length if (target.length - target_start < end - start) end = target.length - target_start + start var len = end - start if (len < 100 || !Buffer._useTypedArrays) { for (var i = 0; i < len; i++) { target[i + target_start] = this[i + start] } } else { target._set(this.subarray(start, start + len), target_start) } } function base64Slice (buf, start, end) { if (start === 0 && end === buf.length) { return base64.fromByteArray(buf) } else { return base64.fromByteArray(buf.slice(start, end)) } } function utf8Slice (buf, start, end) { var res = '' var tmp = '' end = Math.min(buf.length, end) for (var i = start; i < end; i++) { if (buf[i] <= 0x7F) { res += decodeUtf8Char(tmp) + String.fromCharCode(buf[i]) tmp = '' } else { tmp += '%' + buf[i].toString(16) } } return res + decodeUtf8Char(tmp) } function asciiSlice (buf, start, end) { var ret = '' end = Math.min(buf.length, end) for (var i = start; i < end; i++) { ret += String.fromCharCode(buf[i]) } return ret } function binarySlice (buf, start, end) { return asciiSlice(buf, start, end) } function hexSlice (buf, start, end) { var len = buf.length if (!start || start < 0) start = 0 if (!end || end < 0 || end > len) end = len var out = '' for (var i = start; i < end; i++) { out += toHex(buf[i]) } return out } function utf16leSlice (buf, start, end) { var bytes = buf.slice(start, end) var res = '' for (var i = 0; i < bytes.length; i += 2) { res += String.fromCharCode(bytes[i] + bytes[i + 1] * 256) } return res } Buffer.prototype.slice = function (start, end) { var len = this.length start = clamp(start, len, 0) end = clamp(end, len, len) if (Buffer._useTypedArrays) { return Buffer._augment(this.subarray(start, end)) } else { var sliceLen = end - start var newBuf = new Buffer(sliceLen, undefined, true) for (var i = 0; i < sliceLen; i++) { newBuf[i] = this[i + start] } return newBuf } } // `get` will be removed in Node 0.13+ Buffer.prototype.get = function (offset) { console.log('.get() is deprecated. Access using array indexes instead.') return this.readUInt8(offset) } // `set` will be removed in Node 0.13+ Buffer.prototype.set = function (v, offset) { console.log('.set() is deprecated. Access using array indexes instead.') return this.writeUInt8(v, offset) } Buffer.prototype.readUInt8 = function (offset, noAssert) { if (!noAssert) { assert(offset !== undefined && offset !== null, 'missing offset') assert(offset < this.length, 'Trying to read beyond buffer length') } if (offset >= this.length) return return this[offset] } function readUInt16 (buf, offset, littleEndian, noAssert) { if (!noAssert) { assert(typeof littleEndian === 'boolean', 'missing or invalid endian') assert(offset !== undefined && offset !== null, 'missing offset') assert(offset + 1 < buf.length, 'Trying to read beyond buffer length') } var len = buf.length if (offset >= len) return var val if (littleEndian) { val = buf[offset] if (offset + 1 < len) val |= buf[offset + 1] << 8 } else { val = buf[offset] << 8 if (offset + 1 < len) val |= buf[offset + 1] } return val } Buffer.prototype.readUInt16LE = function (offset, noAssert) { return readUInt16(this, offset, true, noAssert) } Buffer.prototype.readUInt16BE = function (offset, noAssert) { return readUInt16(this, offset, false, noAssert) } function readUInt32 (buf, offset, littleEndian, noAssert) { if (!noAssert) { assert(typeof littleEndian === 'boolean', 'missing or invalid endian') assert(offset !== undefined && offset !== null, 'missing offset') assert(offset + 3 < buf.length, 'Trying to read beyond buffer length') } var len = buf.length if (offset >= len) return var val if (littleEndian) { if (offset + 2 < len) val = buf[offset + 2] << 16 if (offset + 1 < len) val |= buf[offset + 1] << 8 val |= buf[offset] if (offset + 3 < len) val = val + (buf[offset + 3] << 24 >>> 0) } else { if (offset + 1 < len) val = buf[offset + 1] << 16 if (offset + 2 < len) val |= buf[offset + 2] << 8 if (offset + 3 < len) val |= buf[offset + 3] val = val + (buf[offset] << 24 >>> 0) } return val } Buffer.prototype.readUInt32LE = function (offset, noAssert) { return readUInt32(this, offset, true, noAssert) } Buffer.prototype.readUInt32BE = function (offset, noAssert) { return readUInt32(this, offset, false, noAssert) } Buffer.prototype.readInt8 = function (offset, noAssert) { if (!noAssert) { assert(offset !== undefined && offset !== null, 'missing offset') assert(offset < this.length, 'Trying to read beyond buffer length') } if (offset >= this.length) return var neg = this[offset] & 0x80 if (neg) return (0xff - this[offset] + 1) * -1 else return this[offset] } function readInt16 (buf, offset, littleEndian, noAssert) { if (!noAssert) { assert(typeof littleEndian === 'boolean', 'missing or invalid endian') assert(offset !== undefined && offset !== null, 'missing offset') assert(offset + 1 < buf.length, 'Trying to read beyond buffer length') } var len = buf.length if (offset >= len) return var val = readUInt16(buf, offset, littleEndian, true) var neg = val & 0x8000 if (neg) return (0xffff - val + 1) * -1 else return val } Buffer.prototype.readInt16LE = function (offset, noAssert) { return readInt16(this, offset, true, noAssert) } Buffer.prototype.readInt16BE = function (offset, noAssert) { return readInt16(this, offset, false, noAssert) } function readInt32 (buf, offset, littleEndian, noAssert) { if (!noAssert) { assert(typeof littleEndian === 'boolean', 'missing or invalid endian') assert(offset !== undefined && offset !== null, 'missing offset') assert(offset + 3 < buf.length, 'Trying to read beyond buffer length') } var len = buf.length if (offset >= len) return var val = readUInt32(buf, offset, littleEndian, true) var neg = val & 0x80000000 if (neg) return (0xffffffff - val + 1) * -1 else return val } Buffer.prototype.readInt32LE = function (offset, noAssert) { return readInt32(this, offset, true, noAssert) } Buffer.prototype.readInt32BE = function (offset, noAssert) { return readInt32(this, offset, false, noAssert) } function readFloat (buf, offset, littleEndian, noAssert) { if (!noAssert) { assert(typeof littleEndian === 'boolean', 'missing or invalid endian') assert(offset + 3 < buf.length, 'Trying to read beyond buffer length') } return ieee754.read(buf, offset, littleEndian, 23, 4) } Buffer.prototype.readFloatLE = function (offset, noAssert) { return readFloat(this, offset, true, noAssert) } Buffer.prototype.readFloatBE = function (offset, noAssert) { return readFloat(this, offset, false, noAssert) } function readDouble (buf, offset, littleEndian, noAssert) { if (!noAssert) { assert(typeof littleEndian === 'boolean', 'missing or invalid endian') assert(offset + 7 < buf.length, 'Trying to read beyond buffer length') } return ieee754.read(buf, offset, littleEndian, 52, 8) } Buffer.prototype.readDoubleLE = function (offset, noAssert) { return readDouble(this, offset, true, noAssert) } Buffer.prototype.readDoubleBE = function (offset, noAssert) { return readDouble(this, offset, false, noAssert) } Buffer.prototype.writeUInt8 = function (value, offset, noAssert) { if (!noAssert) { assert(value !== undefined && value !== null, 'missing value') assert(offset !== undefined && offset !== null, 'missing offset') assert(offset < this.length, 'trying to write beyond buffer length') verifuint(value, 0xff) } if (offset >= this.length) return this[offset] = value return offset + 1 } function writeUInt16 (buf, value, offset, littleEndian, noAssert) { if (!noAssert) { assert(value !== undefined && value !== null, 'missing value') assert(typeof littleEndian === 'boolean', 'missing or invalid endian') assert(offset !== undefined && offset !== null, 'missing offset') assert(offset + 1 < buf.length, 'trying to write beyond buffer length') verifuint(value, 0xffff) } var len = buf.length if (offset >= len) return for (var i = 0, j = Math.min(len - offset, 2); i < j; i++) { buf[offset + i] = (value & (0xff << (8 * (littleEndian ? i : 1 - i)))) >>> (littleEndian ? i : 1 - i) * 8 } return offset + 2 } Buffer.prototype.writeUInt16LE = function (value, offset, noAssert) { return writeUInt16(this, value, offset, true, noAssert) } Buffer.prototype.writeUInt16BE = function (value, offset, noAssert) { return writeUInt16(this, value, offset, false, noAssert) } function writeUInt32 (buf, value, offset, littleEndian, noAssert) { if (!noAssert) { assert(value !== undefined && value !== null, 'missing value') assert(typeof littleEndian === 'boolean', 'missing or invalid endian') assert(offset !== undefined && offset !== null, 'missing offset') assert(offset + 3 < buf.length, 'trying to write beyond buffer length') verifuint(value, 0xffffffff) } var len = buf.length if (offset >= len) return for (var i = 0, j = Math.min(len - offset, 4); i < j; i++) { buf[offset + i] = (value >>> (littleEndian ? i : 3 - i) * 8) & 0xff } return offset + 4 } Buffer.prototype.writeUInt32LE = function (value, offset, noAssert) { return writeUInt32(this, value, offset, true, noAssert) } Buffer.prototype.writeUInt32BE = function (value, offset, noAssert) { return writeUInt32(this, value, offset, false, noAssert) } Buffer.prototype.writeInt8 = function (value, offset, noAssert) { if (!noAssert) { assert(value !== undefined && value !== null, 'missing value') assert(offset !== undefined && offset !== null, 'missing offset') assert(offset < this.length, 'Trying to write beyond buffer length') verifsint(value, 0x7f, -0x80) } if (offset >= this.length) return if (value >= 0) this.writeUInt8(value, offset, noAssert) else this.writeUInt8(0xff + value + 1, offset, noAssert) return offset + 1 } function writeInt16 (buf, value, offset, littleEndian, noAssert) { if (!noAssert) { assert(value !== undefined && value !== null, 'missing value') assert(typeof littleEndian === 'boolean', 'missing or invalid endian') assert(offset !== undefined && offset !== null, 'missing offset') assert(offset + 1 < buf.length, 'Trying to write beyond buffer length') verifsint(value, 0x7fff, -0x8000) } var len = buf.length if (offset >= len) return if (value >= 0) writeUInt16(buf, value, offset, littleEndian, noAssert) else writeUInt16(buf, 0xffff + value + 1, offset, littleEndian, noAssert) return offset + 2 } Buffer.prototype.writeInt16LE = function (value, offset, noAssert) { return writeInt16(this, value, offset, true, noAssert) } Buffer.prototype.writeInt16BE = function (value, offset, noAssert) { return writeInt16(this, value, offset, false, noAssert) } function writeInt32 (buf, value, offset, littleEndian, noAssert) { if (!noAssert) { assert(value !== undefined && value !== null, 'missing value') assert(typeof littleEndian === 'boolean', 'missing or invalid endian') assert(offset !== undefined && offset !== null, 'missing offset') assert(offset + 3 < buf.length, 'Trying to write beyond buffer length') verifsint(value, 0x7fffffff, -0x80000000) } var len = buf.length if (offset >= len) return if (value >= 0) writeUInt32(buf, value, offset, littleEndian, noAssert) else writeUInt32(buf, 0xffffffff + value + 1, offset, littleEndian, noAssert) return offset + 4 } Buffer.prototype.writeInt32LE = function (value, offset, noAssert) { return writeInt32(this, value, offset, true, noAssert) } Buffer.prototype.writeInt32BE = function (value, offset, noAssert) { return writeInt32(this, value, offset, false, noAssert) } function writeFloat (buf, value, offset, littleEndian, noAssert) { if (!noAssert) { assert(value !== undefined && value !== null, 'missing value') assert(typeof littleEndian === 'boolean', 'missing or invalid endian') assert(offset !== undefined && offset !== null, 'missing offset') assert(offset + 3 < buf.length, 'Trying to write beyond buffer length') verifIEEE754(value, 3.4028234663852886e+38, -3.4028234663852886e+38) } var len = buf.length if (offset >= len) return ieee754.write(buf, value, offset, littleEndian, 23, 4) return offset + 4 } Buffer.prototype.writeFloatLE = function (value, offset, noAssert) { return writeFloat(this, value, offset, true, noAssert) } Buffer.prototype.writeFloatBE = function (value, offset, noAssert) { return writeFloat(this, value, offset, false, noAssert) } function writeDouble (buf, value, offset, littleEndian, noAssert) { if (!noAssert) { assert(value !== undefined && value !== null, 'missing value') assert(typeof littleEndian === 'boolean', 'missing or invalid endian') assert(offset !== undefined && offset !== null, 'missing offset') assert(offset + 7 < buf.length, 'Trying to write beyond buffer length') verifIEEE754(value, 1.7976931348623157E+308, -1.7976931348623157E+308) } var len = buf.length if (offset >= len) return ieee754.write(buf, value, offset, littleEndian, 52, 8) return offset + 8 } Buffer.prototype.writeDoubleLE = function (value, offset, noAssert) { return writeDouble(this, value, offset, true, noAssert) } Buffer.prototype.writeDoubleBE = function (value, offset, noAssert) { return writeDouble(this, value, offset, false, noAssert) } // fill(value, start=0, end=buffer.length) Buffer.prototype.fill = function (value, start, end) { if (!value) value = 0 if (!start) start = 0 if (!end) end = this.length assert(end >= start, 'end < start') // Fill 0 bytes; we're done if (end === start) return if (this.length === 0) return assert(start >= 0 && start < this.length, 'start out of bounds') assert(end >= 0 && end <= this.length, 'end out of bounds') var i if (typeof value === 'number') { for (i = start; i < end; i++) { this[i] = value } } else { var bytes = utf8ToBytes(value.toString()) var len = bytes.length for (i = start; i < end; i++) { this[i] = bytes[i % len] } } return this } Buffer.prototype.inspect = function () { var out = [] var len = this.length for (var i = 0; i < len; i++) { out[i] = toHex(this[i]) if (i === exports.INSPECT_MAX_BYTES) { out[i + 1] = '...' break } } return '' } /** * Creates a new `ArrayBuffer` with the *copied* memory of the buffer instance. * Added in Node 0.12. Only available in browsers that support ArrayBuffer. */ Buffer.prototype.toArrayBuffer = function () { if (typeof Uint8Array !== 'undefined') { if (Buffer._useTypedArrays) { return (new Buffer(this)).buffer } else { var buf = new Uint8Array(this.length) for (var i = 0, len = buf.length; i < len; i += 1) { buf[i] = this[i] } return buf.buffer } } else { throw new Error('Buffer.toArrayBuffer not supported in this browser') } } // HELPER FUNCTIONS // ================ var BP = Buffer.prototype /** * Augment a Uint8Array *instance* (not the Uint8Array class!) with Buffer methods */ Buffer._augment = function (arr) { arr._isBuffer = true // save reference to original Uint8Array get/set methods before overwriting arr._get = arr.get arr._set = arr.set // deprecated, will be removed in node 0.13+ arr.get = BP.get arr.set = BP.set arr.write = BP.write arr.toString = BP.toString arr.toLocaleString = BP.toString arr.toJSON = BP.toJSON arr.equals = BP.equals arr.compare = BP.compare arr.copy = BP.copy arr.slice = BP.slice arr.readUInt8 = BP.readUInt8 arr.readUInt16LE = BP.readUInt16LE arr.readUInt16BE = BP.readUInt16BE arr.readUInt32LE = BP.readUInt32LE arr.readUInt32BE = BP.readUInt32BE arr.readInt8 = BP.readInt8 arr.readInt16LE = BP.readInt16LE arr.readInt16BE = BP.readInt16BE arr.readInt32LE = BP.readInt32LE arr.readInt32BE = BP.readInt32BE arr.readFloatLE = BP.readFloatLE arr.readFloatBE = BP.readFloatBE arr.readDoubleLE = BP.readDoubleLE arr.readDoubleBE = BP.readDoubleBE arr.writeUInt8 = BP.writeUInt8 arr.writeUInt16LE = BP.writeUInt16LE arr.writeUInt16BE = BP.writeUInt16BE arr.writeUInt32LE = BP.writeUInt32LE arr.writeUInt32BE = BP.writeUInt32BE arr.writeInt8 = BP.writeInt8 arr.writeInt16LE = BP.writeInt16LE arr.writeInt16BE = BP.writeInt16BE arr.writeInt32LE = BP.writeInt32LE arr.writeInt32BE = BP.writeInt32BE arr.writeFloatLE = BP.writeFloatLE arr.writeFloatBE = BP.writeFloatBE arr.writeDoubleLE = BP.writeDoubleLE arr.writeDoubleBE = BP.writeDoubleBE arr.fill = BP.fill arr.inspect = BP.inspect arr.toArrayBuffer = BP.toArrayBuffer return arr } var INVALID_BASE64_RE = /[^+\/0-9A-z]/g function base64clean (str) { // Node strips out invalid characters like \n and \t from the string, base64-js does not str = stringtrim(str).replace(INVALID_BASE64_RE, '') // Node allows for non-padded base64 strings (missing trailing ===), base64-js does not while (str.length % 4 !== 0) { str = str + '=' } return str } function stringtrim (str) { if (str.trim) return str.trim() return str.replace(/^\s+|\s+$/g, '') } // slice(start, end) function clamp (index, len, defaultValue) { if (typeof index !== 'number') return defaultValue index = ~~index; // Coerce to integer. if (index >= len) return len if (index >= 0) return index index += len if (index >= 0) return index return 0 } function coerce (length) { // Coerce length to a number (possibly NaN), round up // in case it's fractional (e.g. 123.456) then do a // double negate to coerce a NaN to 0. Easy, right? length = ~~Math.ceil(+length) return length < 0 ? 0 : length } function isArray (subject) { return (Array.isArray || function (subject) { return Object.prototype.toString.call(subject) === '[object Array]' })(subject) } function isArrayish (subject) { return isArray(subject) || Buffer.isBuffer(subject) || subject && typeof subject === 'object' && typeof subject.length === 'number' } function toHex (n) { if (n < 16) return '0' + n.toString(16) return n.toString(16) } function utf8ToBytes (str) { var byteArray = [] for (var i = 0; i < str.length; i++) { var b = str.charCodeAt(i) if (b <= 0x7F) { byteArray.push(b) } else { var start = i if (b >= 0xD800 && b <= 0xDFFF) i++ var h = encodeURIComponent(str.slice(start, i+1)).substr(1).split('%') for (var j = 0; j < h.length; j++) { byteArray.push(parseInt(h[j], 16)) } } } return byteArray } function asciiToBytes (str) { var byteArray = [] for (var i = 0; i < str.length; i++) { // Node's code seems to be doing this and not & 0x7F.. byteArray.push(str.charCodeAt(i) & 0xFF) } return byteArray } function utf16leToBytes (str) { var c, hi, lo var byteArray = [] for (var i = 0; i < str.length; i++) { c = str.charCodeAt(i) hi = c >> 8 lo = c % 256 byteArray.push(lo) byteArray.push(hi) } return byteArray } function base64ToBytes (str) { return base64.toByteArray(str) } function blitBuffer (src, dst, offset, length) { for (var i = 0; i < length; i++) { if ((i + offset >= dst.length) || (i >= src.length)) break dst[i + offset] = src[i] } return i } function decodeUtf8Char (str) { try { return decodeURIComponent(str) } catch (err) { return String.fromCharCode(0xFFFD) // UTF 8 invalid char } } /* * We have to make sure that the value is a valid integer. This means that it * is non-negative. It has no fractional component and that it does not * exceed the maximum allowed value. */ function verifuint (value, max) { assert(typeof value === 'number', 'cannot write a non-number as a number') assert(value >= 0, 'specified a negative value for writing an unsigned value') assert(value <= max, 'value is larger than maximum value for type') assert(Math.floor(value) === value, 'value has a fractional component') } function verifsint (value, max, min) { assert(typeof value === 'number', 'cannot write a non-number as a number') assert(value <= max, 'value larger than maximum allowed value') assert(value >= min, 'value smaller than minimum allowed value') assert(Math.floor(value) === value, 'value has a fractional component') } function verifIEEE754 (value, max, min) { assert(typeof value === 'number', 'cannot write a non-number as a number') assert(value <= max, 'value larger than maximum allowed value') assert(value >= min, 'value smaller than minimum allowed value') } function assert (test, message) { if (!test) throw new Error(message || 'Failed assertion') } },{"base64-js":9,"ieee754":10}],9:[function(_dereq_,module,exports){ var lookup = 'ABCDEFGHIJKLMNOPQRSTUVWXYZabcdefghijklmnopqrstuvwxyz0123456789+/'; ;(function (exports) { 'use strict'; var Arr = (typeof Uint8Array !== 'undefined') ? Uint8Array : Array var PLUS = '+'.charCodeAt(0) var SLASH = '/'.charCodeAt(0) var NUMBER = '0'.charCodeAt(0) var LOWER = 'a'.charCodeAt(0) var UPPER = 'A'.charCodeAt(0) function decode (elt) { var code = elt.charCodeAt(0) if (code === PLUS) return 62 // '+' if (code === SLASH) return 63 // '/' if (code < NUMBER) return -1 //no match if (code < NUMBER + 10) return code - NUMBER + 26 + 26 if (code < UPPER + 26) return code - UPPER if (code < LOWER + 26) return code - LOWER + 26 } function b64ToByteArray (b64) { var i, j, l, tmp, placeHolders, arr if (b64.length % 4 > 0) { throw new Error('Invalid string. Length must be a multiple of 4') } // the number of equal signs (place holders) // if there are two placeholders, than the two characters before it // represent one byte // if there is only one, then the three characters before it represent 2 bytes // this is just a cheap hack to not do indexOf twice var len = b64.length placeHolders = '=' === b64.charAt(len - 2) ? 2 : '=' === b64.charAt(len - 1) ? 1 : 0 // base64 is 4/3 + up to two characters of the original data arr = new Arr(b64.length * 3 / 4 - placeHolders) // if there are placeholders, only get up to the last complete 4 chars l = placeHolders > 0 ? b64.length - 4 : b64.length var L = 0 function push (v) { arr[L++] = v } for (i = 0, j = 0; i < l; i += 4, j += 3) { tmp = (decode(b64.charAt(i)) << 18) | (decode(b64.charAt(i + 1)) << 12) | (decode(b64.charAt(i + 2)) << 6) | decode(b64.charAt(i + 3)) push((tmp & 0xFF0000) >> 16) push((tmp & 0xFF00) >> 8) push(tmp & 0xFF) } if (placeHolders === 2) { tmp = (decode(b64.charAt(i)) << 2) | (decode(b64.charAt(i + 1)) >> 4) push(tmp & 0xFF) } else if (placeHolders === 1) { tmp = (decode(b64.charAt(i)) << 10) | (decode(b64.charAt(i + 1)) << 4) | (decode(b64.charAt(i + 2)) >> 2) push((tmp >> 8) & 0xFF) push(tmp & 0xFF) } return arr } function uint8ToBase64 (uint8) { var i, extraBytes = uint8.length % 3, // if we have 1 byte left, pad 2 bytes output = "", temp, length function encode (num) { return lookup.charAt(num) } function tripletToBase64 (num) { return encode(num >> 18 & 0x3F) + encode(num >> 12 & 0x3F) + encode(num >> 6 & 0x3F) + encode(num & 0x3F) } // go through the array every three bytes, we'll deal with trailing stuff later for (i = 0, length = uint8.length - extraBytes; i < length; i += 3) { temp = (uint8[i] << 16) + (uint8[i + 1] << 8) + (uint8[i + 2]) output += tripletToBase64(temp) } // pad the end with zeros, but make sure to not forget the extra bytes switch (extraBytes) { case 1: temp = uint8[uint8.length - 1] output += encode(temp >> 2) output += encode((temp << 4) & 0x3F) output += '==' break case 2: temp = (uint8[uint8.length - 2] << 8) + (uint8[uint8.length - 1]) output += encode(temp >> 10) output += encode((temp >> 4) & 0x3F) output += encode((temp << 2) & 0x3F) output += '=' break } return output } exports.toByteArray = b64ToByteArray exports.fromByteArray = uint8ToBase64 }(typeof exports === 'undefined' ? (this.base64js = {}) : exports)) },{}],10:[function(_dereq_,module,exports){ exports.read = function(buffer, offset, isLE, mLen, nBytes) { var e, m, eLen = nBytes * 8 - mLen - 1, eMax = (1 << eLen) - 1, eBias = eMax >> 1, nBits = -7, i = isLE ? (nBytes - 1) : 0, d = isLE ? -1 : 1, s = buffer[offset + i]; i += d; e = s & ((1 << (-nBits)) - 1); s >>= (-nBits); nBits += eLen; for (; nBits > 0; e = e * 256 + buffer[offset + i], i += d, nBits -= 8){}; m = e & ((1 << (-nBits)) - 1); e >>= (-nBits); nBits += mLen; for (; nBits > 0; m = m * 256 + buffer[offset + i], i += d, nBits -= 8){}; if (e === 0) { e = 1 - eBias; } else if (e === eMax) { return m ? NaN : ((s ? -1 : 1) * Infinity); } else { m = m + Math.pow(2, mLen); e = e - eBias; } return (s ? -1 : 1) * m * Math.pow(2, e - mLen); }; exports.write = function(buffer, value, offset, isLE, mLen, nBytes) { var e, m, c, eLen = nBytes * 8 - mLen - 1, eMax = (1 << eLen) - 1, eBias = eMax >> 1, rt = (mLen === 23 ? Math.pow(2, -24) - Math.pow(2, -77) : 0), i = isLE ? 0 : (nBytes - 1), d = isLE ? 1 : -1, s = value < 0 || (value === 0 && 1 / value < 0) ? 1 : 0; value = Math.abs(value); if (isNaN(value) || value === Infinity) { m = isNaN(value) ? 1 : 0; e = eMax; } else { e = Math.floor(Math.log(value) / Math.LN2); if (value * (c = Math.pow(2, -e)) < 1) { e--; c *= 2; } if (e + eBias >= 1) { value += rt / c; } else { value += rt * Math.pow(2, 1 - eBias); } if (value * c >= 2) { e++; c /= 2; } if (e + eBias >= eMax) { m = 0; e = eMax; } else if (e + eBias >= 1) { m = (value * c - 1) * Math.pow(2, mLen); e = e + eBias; } else { m = value * Math.pow(2, eBias - 1) * Math.pow(2, mLen); e = 0; } } for (; mLen >= 8; buffer[offset + i] = m & 0xff, i += d, m /= 256, mLen -= 8){}; e = (e << mLen) | m; eLen += mLen; for (; eLen > 0; buffer[offset + i] = e & 0xff, i += d, e /= 256, eLen -= 8){}; buffer[offset + i - d] |= s * 128; }; },{}],11:[function(_dereq_,module,exports){ if (typeof Object.create === 'function') { // implementation from standard node.js 'util' module module.exports = function inherits(ctor, superCtor) { ctor.super_ = superCtor ctor.prototype = Object.create(superCtor.prototype, { constructor: { value: ctor, enumerable: false, writable: true, configurable: true } }); }; } else { // old school shim for old browsers module.exports = function inherits(ctor, superCtor) { ctor.super_ = superCtor var TempCtor = function () {} TempCtor.prototype = superCtor.prototype ctor.prototype = new TempCtor() ctor.prototype.constructor = ctor } } },{}],12:[function(_dereq_,module,exports){ // shim for using process in browser var process = module.exports = {}; process.nextTick = (function () { var canSetImmediate = typeof window !== 'undefined' && window.setImmediate; var canPost = typeof window !== 'undefined' && window.postMessage && window.addEventListener ; if (canSetImmediate) { return function (f) { return window.setImmediate(f) }; } if (canPost) { var queue = []; window.addEventListener('message', function (ev) { var source = ev.source; if ((source === window || source === null) && ev.data === 'process-tick') { ev.stopPropagation(); if (queue.length > 0) { var fn = queue.shift(); fn(); } } }, true); return function nextTick(fn) { queue.push(fn); window.postMessage('process-tick', '*'); }; } return function nextTick(fn) { setTimeout(fn, 0); }; })(); process.title = 'browser'; process.browser = true; process.env = {}; process.argv = []; function noop() {} process.on = noop; process.addListener = noop; process.once = noop; process.off = noop; process.removeListener = noop; process.removeAllListeners = noop; process.emit = noop; process.binding = function (name) { throw new Error('process.binding is not supported'); } // TODO(shtylman) process.cwd = function () { return '/' }; process.chdir = function (dir) { throw new Error('process.chdir is not supported'); }; },{}],13:[function(_dereq_,module,exports){ module.exports=_dereq_(5) },{}],14:[function(_dereq_,module,exports){ module.exports=_dereq_(6) },{"./support/isBuffer":13,"FWaASH":12,"inherits":11}],15:[function(_dereq_,module,exports){ (function (Buffer){ // Base58 encoding/decoding // Originally written by Mike Hearn for BitcoinJ // Copyright (c) 2011 Google Inc // Ported to JavaScript by Stefan Thomas // Merged Buffer refactorings from base58-native by Stephen Pair // Copyright (c) 2013 BitPay Inc var assert = _dereq_('assert') var BigInteger = _dereq_('bigi') var ALPHABET = '123456789ABCDEFGHJKLMNPQRSTUVWXYZabcdefghijkmnopqrstuvwxyz' var ALPHABET_BUF = new Buffer(ALPHABET, 'ascii') var ALPHABET_MAP = {} for(var i = 0; i < ALPHABET.length; i++) { ALPHABET_MAP[ALPHABET.charAt(i)] = BigInteger.valueOf(i) } var BASE = new BigInteger('58') function encode(buffer) { var bi = BigInteger.fromBuffer(buffer) var result = new Buffer(buffer.length << 1) var i = result.length - 1 while (bi.signum() > 0) { var remainder = bi.mod(BASE) bi = bi.divide(BASE) result[i] = ALPHABET_BUF[remainder.intValue()] i-- } // deal with leading zeros var j = 0 while (buffer[j] === 0) { result[i] = ALPHABET_BUF[0] j++ i-- } return result.slice(i + 1, result.length).toString('ascii') } function decode(string) { if (string.length === 0) return new Buffer(0) var num = BigInteger.ZERO for (var i = 0; i < string.length; i++) { num = num.multiply(BASE) var figure = ALPHABET_MAP[string.charAt(i)] assert.notEqual(figure, undefined, 'Non-base58 character') num = num.add(figure) } // deal with leading zeros var j = 0 while ((j < string.length) && (string[j] === ALPHABET[0])) { j++ } var buffer = num.toBuffer() var leadingZeros = new Buffer(j) leadingZeros.fill(0) return Buffer.concat([leadingZeros, buffer]) } module.exports = { encode: encode, decode: decode } }).call(this,_dereq_("buffer").Buffer) },{"assert":4,"bigi":3,"buffer":8}],16:[function(_dereq_,module,exports){ (function (Buffer){ var createHash = _dereq_('sha.js') var md5 = toConstructor(_dereq_('./md5')) var rmd160 = toConstructor(_dereq_('ripemd160')) function toConstructor (fn) { return function () { var buffers = [] var m= { update: function (data, enc) { if(!Buffer.isBuffer(data)) data = new Buffer(data, enc) buffers.push(data) return this }, digest: function (enc) { var buf = Buffer.concat(buffers) var r = fn(buf) buffers = null return enc ? r.toString(enc) : r } } return m } } module.exports = function (alg) { if('md5' === alg) return new md5() if('rmd160' === alg) return new rmd160() return createHash(alg) } }).call(this,_dereq_("buffer").Buffer) },{"./md5":20,"buffer":8,"ripemd160":21,"sha.js":23}],17:[function(_dereq_,module,exports){ (function (Buffer){ var createHash = _dereq_('./create-hash') var blocksize = 64 var zeroBuffer = new Buffer(blocksize); zeroBuffer.fill(0) module.exports = Hmac function Hmac (alg, key) { if(!(this instanceof Hmac)) return new Hmac(alg, key) this._opad = opad this._alg = alg key = this._key = !Buffer.isBuffer(key) ? new Buffer(key) : key if(key.length > blocksize) { key = createHash(alg).update(key).digest() } else if(key.length < blocksize) { key = Buffer.concat([key, zeroBuffer], blocksize) } var ipad = this._ipad = new Buffer(blocksize) var opad = this._opad = new Buffer(blocksize) for(var i = 0; i < blocksize; i++) { ipad[i] = key[i] ^ 0x36 opad[i] = key[i] ^ 0x5C } this._hash = createHash(alg).update(ipad) } Hmac.prototype.update = function (data, enc) { this._hash.update(data, enc) return this } Hmac.prototype.digest = function (enc) { var h = this._hash.digest() return createHash(this._alg).update(this._opad).update(h).digest(enc) } }).call(this,_dereq_("buffer").Buffer) },{"./create-hash":16,"buffer":8}],18:[function(_dereq_,module,exports){ (function (Buffer){ var intSize = 4; var zeroBuffer = new Buffer(intSize); zeroBuffer.fill(0); var chrsz = 8; function toArray(buf, bigEndian) { if ((buf.length % intSize) !== 0) { var len = buf.length + (intSize - (buf.length % intSize)); buf = Buffer.concat([buf, zeroBuffer], len); } var arr = []; var fn = bigEndian ? buf.readInt32BE : buf.readInt32LE; for (var i = 0; i < buf.length; i += intSize) { arr.push(fn.call(buf, i)); } return arr; } function toBuffer(arr, size, bigEndian) { var buf = new Buffer(size); var fn = bigEndian ? buf.writeInt32BE : buf.writeInt32LE; for (var i = 0; i < arr.length; i++) { fn.call(buf, arr[i], i * 4, true); } return buf; } function hash(buf, fn, hashSize, bigEndian) { if (!Buffer.isBuffer(buf)) buf = new Buffer(buf); var arr = fn(toArray(buf, bigEndian), buf.length * chrsz); return toBuffer(arr, hashSize, bigEndian); } module.exports = { hash: hash }; }).call(this,_dereq_("buffer").Buffer) },{"buffer":8}],19:[function(_dereq_,module,exports){ (function (Buffer){ var rng = _dereq_('./rng') function error () { var m = [].slice.call(arguments).join(' ') throw new Error([ m, 'we accept pull requests', 'http://github.com/dominictarr/crypto-browserify' ].join('\n')) } exports.createHash = _dereq_('./create-hash') exports.createHmac = _dereq_('./create-hmac') exports.randomBytes = function(size, callback) { if (callback && callback.call) { try { callback.call(this, undefined, new Buffer(rng(size))) } catch (err) { callback(err) } } else { return new Buffer(rng(size)) } } function each(a, f) { for(var i in a) f(a[i], i) } exports.getHashes = function () { return ['sha1', 'sha256', 'md5', 'rmd160'] } var p = _dereq_('./pbkdf2')(exports.createHmac) exports.pbkdf2 = p.pbkdf2 exports.pbkdf2Sync = p.pbkdf2Sync // the least I can do is make error messages for the rest of the node.js/crypto api. each(['createCredentials' , 'createCipher' , 'createCipheriv' , 'createDecipher' , 'createDecipheriv' , 'createSign' , 'createVerify' , 'createDiffieHellman' ], function (name) { exports[name] = function () { error('sorry,', name, 'is not implemented yet') } }) }).call(this,_dereq_("buffer").Buffer) },{"./create-hash":16,"./create-hmac":17,"./pbkdf2":27,"./rng":28,"buffer":8}],20:[function(_dereq_,module,exports){ /* * A JavaScript implementation of the RSA Data Security, Inc. MD5 Message * Digest Algorithm, as defined in RFC 1321. * Version 2.1 Copyright (C) Paul Johnston 1999 - 2002. * Other contributors: Greg Holt, Andrew Kepert, Ydnar, Lostinet * Distributed under the BSD License * See http://pajhome.org.uk/crypt/md5 for more info. */ var helpers = _dereq_('./helpers'); /* * Calculate the MD5 of an array of little-endian words, and a bit length */ function core_md5(x, len) { /* append padding */ x[len >> 5] |= 0x80 << ((len) % 32); x[(((len + 64) >>> 9) << 4) + 14] = len; var a = 1732584193; var b = -271733879; var c = -1732584194; var d = 271733878; for(var i = 0; i < x.length; i += 16) { var olda = a; var oldb = b; var oldc = c; var oldd = d; a = md5_ff(a, b, c, d, x[i+ 0], 7 , -680876936); d = md5_ff(d, a, b, c, x[i+ 1], 12, -389564586); c = md5_ff(c, d, a, b, x[i+ 2], 17, 606105819); b = md5_ff(b, c, d, a, x[i+ 3], 22, -1044525330); a = md5_ff(a, b, c, d, x[i+ 4], 7 , -176418897); d = md5_ff(d, a, b, c, x[i+ 5], 12, 1200080426); c = md5_ff(c, d, a, b, x[i+ 6], 17, -1473231341); b = md5_ff(b, c, d, a, x[i+ 7], 22, -45705983); a = md5_ff(a, b, c, d, x[i+ 8], 7 , 1770035416); d = md5_ff(d, a, b, c, x[i+ 9], 12, -1958414417); c = md5_ff(c, d, a, b, x[i+10], 17, -42063); b = md5_ff(b, c, d, a, x[i+11], 22, -1990404162); a = md5_ff(a, b, c, d, x[i+12], 7 , 1804603682); d = md5_ff(d, a, b, c, x[i+13], 12, -40341101); c = md5_ff(c, d, a, b, x[i+14], 17, -1502002290); b = md5_ff(b, c, d, a, x[i+15], 22, 1236535329); a = md5_gg(a, b, c, d, x[i+ 1], 5 , -165796510); d = md5_gg(d, a, b, c, x[i+ 6], 9 , -1069501632); c = md5_gg(c, d, a, b, x[i+11], 14, 643717713); b = md5_gg(b, c, d, a, x[i+ 0], 20, -373897302); a = md5_gg(a, b, c, d, x[i+ 5], 5 , -701558691); d = md5_gg(d, a, b, c, x[i+10], 9 , 38016083); c = md5_gg(c, d, a, b, x[i+15], 14, -660478335); b = md5_gg(b, c, d, a, x[i+ 4], 20, -405537848); a = md5_gg(a, b, c, d, x[i+ 9], 5 , 568446438); d = md5_gg(d, a, b, c, x[i+14], 9 , -1019803690); c = md5_gg(c, d, a, b, x[i+ 3], 14, -187363961); b = md5_gg(b, c, d, a, x[i+ 8], 20, 1163531501); a = md5_gg(a, b, c, d, x[i+13], 5 , -1444681467); d = md5_gg(d, a, b, c, x[i+ 2], 9 , -51403784); c = md5_gg(c, d, a, b, x[i+ 7], 14, 1735328473); b = md5_gg(b, c, d, a, x[i+12], 20, -1926607734); a = md5_hh(a, b, c, d, x[i+ 5], 4 , -378558); d = md5_hh(d, a, b, c, x[i+ 8], 11, -2022574463); c = md5_hh(c, d, a, b, x[i+11], 16, 1839030562); b = md5_hh(b, c, d, a, x[i+14], 23, -35309556); a = md5_hh(a, b, c, d, x[i+ 1], 4 , -1530992060); d = md5_hh(d, a, b, c, x[i+ 4], 11, 1272893353); c = md5_hh(c, d, a, b, x[i+ 7], 16, -155497632); b = md5_hh(b, c, d, a, x[i+10], 23, -1094730640); a = md5_hh(a, b, c, d, x[i+13], 4 , 681279174); d = md5_hh(d, a, b, c, x[i+ 0], 11, -358537222); c = md5_hh(c, d, a, b, x[i+ 3], 16, -722521979); b = md5_hh(b, c, d, a, x[i+ 6], 23, 76029189); a = md5_hh(a, b, c, d, x[i+ 9], 4 , -640364487); d = md5_hh(d, a, b, c, x[i+12], 11, -421815835); c = md5_hh(c, d, a, b, x[i+15], 16, 530742520); b = md5_hh(b, c, d, a, x[i+ 2], 23, -995338651); a = md5_ii(a, b, c, d, x[i+ 0], 6 , -198630844); d = md5_ii(d, a, b, c, x[i+ 7], 10, 1126891415); c = md5_ii(c, d, a, b, x[i+14], 15, -1416354905); b = md5_ii(b, c, d, a, x[i+ 5], 21, -57434055); a = md5_ii(a, b, c, d, x[i+12], 6 , 1700485571); d = md5_ii(d, a, b, c, x[i+ 3], 10, -1894986606); c = md5_ii(c, d, a, b, x[i+10], 15, -1051523); b = md5_ii(b, c, d, a, x[i+ 1], 21, -2054922799); a = md5_ii(a, b, c, d, x[i+ 8], 6 , 1873313359); d = md5_ii(d, a, b, c, x[i+15], 10, -30611744); c = md5_ii(c, d, a, b, x[i+ 6], 15, -1560198380); b = md5_ii(b, c, d, a, x[i+13], 21, 1309151649); a = md5_ii(a, b, c, d, x[i+ 4], 6 , -145523070); d = md5_ii(d, a, b, c, x[i+11], 10, -1120210379); c = md5_ii(c, d, a, b, x[i+ 2], 15, 718787259); b = md5_ii(b, c, d, a, x[i+ 9], 21, -343485551); a = safe_add(a, olda); b = safe_add(b, oldb); c = safe_add(c, oldc); d = safe_add(d, oldd); } return Array(a, b, c, d); } /* * These functions implement the four basic operations the algorithm uses. */ function md5_cmn(q, a, b, x, s, t) { return safe_add(bit_rol(safe_add(safe_add(a, q), safe_add(x, t)), s),b); } function md5_ff(a, b, c, d, x, s, t) { return md5_cmn((b & c) | ((~b) & d), a, b, x, s, t); } function md5_gg(a, b, c, d, x, s, t) { return md5_cmn((b & d) | (c & (~d)), a, b, x, s, t); } function md5_hh(a, b, c, d, x, s, t) { return md5_cmn(b ^ c ^ d, a, b, x, s, t); } function md5_ii(a, b, c, d, x, s, t) { return md5_cmn(c ^ (b | (~d)), a, b, x, s, t); } /* * Add integers, wrapping at 2^32. This uses 16-bit operations internally * to work around bugs in some JS interpreters. */ function safe_add(x, y) { var lsw = (x & 0xFFFF) + (y & 0xFFFF); var msw = (x >> 16) + (y >> 16) + (lsw >> 16); return (msw << 16) | (lsw & 0xFFFF); } /* * Bitwise rotate a 32-bit number to the left. */ function bit_rol(num, cnt) { return (num << cnt) | (num >>> (32 - cnt)); } module.exports = function md5(buf) { return helpers.hash(buf, core_md5, 16); }; },{"./helpers":18}],21:[function(_dereq_,module,exports){ (function (Buffer){ module.exports = ripemd160 /* CryptoJS v3.1.2 code.google.com/p/crypto-js (c) 2009-2013 by Jeff Mott. All rights reserved. code.google.com/p/crypto-js/wiki/License */ /** @preserve (c) 2012 by Cédric Mesnil. All rights reserved. Redistribution and use in source and binary forms, with or without modification, are permitted provided that the following conditions are met: - Redistributions of source code must retain the above copyright notice, this list of conditions and the following disclaimer. - Redistributions in binary form must reproduce the above copyright notice, this list of conditions and the following disclaimer in the documentation and/or other materials provided with the distribution. THIS SOFTWARE IS PROVIDED BY THE COPYRIGHT HOLDERS AND CONTRIBUTORS "AS IS" AND ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR PURPOSE ARE DISCLAIMED. IN NO EVENT SHALL THE COPYRIGHT HOLDER OR CONTRIBUTORS BE LIABLE FOR ANY DIRECT, INDIRECT, INCIDENTAL, SPECIAL, EXEMPLARY, OR CONSEQUENTIAL DAMAGES (INCLUDING, BUT NOT LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS OR SERVICES; LOSS OF USE, DATA, OR PROFITS; OR BUSINESS INTERRUPTION) HOWEVER CAUSED AND ON ANY THEORY OF LIABILITY, WHETHER IN CONTRACT, STRICT LIABILITY, OR TORT (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY OUT OF THE USE OF THIS SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF SUCH DAMAGE. */ // Constants table var zl = [ 0, 1, 2, 3, 4, 5, 6, 7, 8, 9, 10, 11, 12, 13, 14, 15, 7, 4, 13, 1, 10, 6, 15, 3, 12, 0, 9, 5, 2, 14, 11, 8, 3, 10, 14, 4, 9, 15, 8, 1, 2, 7, 0, 6, 13, 11, 5, 12, 1, 9, 11, 10, 0, 8, 12, 4, 13, 3, 7, 15, 14, 5, 6, 2, 4, 0, 5, 9, 7, 12, 2, 10, 14, 1, 3, 8, 11, 6, 15, 13]; var zr = [ 5, 14, 7, 0, 9, 2, 11, 4, 13, 6, 15, 8, 1, 10, 3, 12, 6, 11, 3, 7, 0, 13, 5, 10, 14, 15, 8, 12, 4, 9, 1, 2, 15, 5, 1, 3, 7, 14, 6, 9, 11, 8, 12, 2, 10, 0, 4, 13, 8, 6, 4, 1, 3, 11, 15, 0, 5, 12, 2, 13, 9, 7, 10, 14, 12, 15, 10, 4, 1, 5, 8, 7, 6, 2, 13, 14, 0, 3, 9, 11]; var sl = [ 11, 14, 15, 12, 5, 8, 7, 9, 11, 13, 14, 15, 6, 7, 9, 8, 7, 6, 8, 13, 11, 9, 7, 15, 7, 12, 15, 9, 11, 7, 13, 12, 11, 13, 6, 7, 14, 9, 13, 15, 14, 8, 13, 6, 5, 12, 7, 5, 11, 12, 14, 15, 14, 15, 9, 8, 9, 14, 5, 6, 8, 6, 5, 12, 9, 15, 5, 11, 6, 8, 13, 12, 5, 12, 13, 14, 11, 8, 5, 6 ]; var sr = [ 8, 9, 9, 11, 13, 15, 15, 5, 7, 7, 8, 11, 14, 14, 12, 6, 9, 13, 15, 7, 12, 8, 9, 11, 7, 7, 12, 7, 6, 15, 13, 11, 9, 7, 15, 11, 8, 6, 6, 14, 12, 13, 5, 14, 13, 13, 7, 5, 15, 5, 8, 11, 14, 14, 6, 14, 6, 9, 12, 9, 12, 5, 15, 8, 8, 5, 12, 9, 12, 5, 14, 6, 8, 13, 6, 5, 15, 13, 11, 11 ]; var hl = [ 0x00000000, 0x5A827999, 0x6ED9EBA1, 0x8F1BBCDC, 0xA953FD4E]; var hr = [ 0x50A28BE6, 0x5C4DD124, 0x6D703EF3, 0x7A6D76E9, 0x00000000]; var bytesToWords = function (bytes) { var words = []; for (var i = 0, b = 0; i < bytes.length; i++, b += 8) { words[b >>> 5] |= bytes[i] << (24 - b % 32); } return words; }; var wordsToBytes = function (words) { var bytes = []; for (var b = 0; b < words.length * 32; b += 8) { bytes.push((words[b >>> 5] >>> (24 - b % 32)) & 0xFF); } return bytes; }; var processBlock = function (H, M, offset) { // Swap endian for (var i = 0; i < 16; i++) { var offset_i = offset + i; var M_offset_i = M[offset_i]; // Swap M[offset_i] = ( (((M_offset_i << 8) | (M_offset_i >>> 24)) & 0x00ff00ff) | (((M_offset_i << 24) | (M_offset_i >>> 8)) & 0xff00ff00) ); } // Working variables var al, bl, cl, dl, el; var ar, br, cr, dr, er; ar = al = H[0]; br = bl = H[1]; cr = cl = H[2]; dr = dl = H[3]; er = el = H[4]; // Computation var t; for (var i = 0; i < 80; i += 1) { t = (al + M[offset+zl[i]])|0; if (i<16){ t += f1(bl,cl,dl) + hl[0]; } else if (i<32) { t += f2(bl,cl,dl) + hl[1]; } else if (i<48) { t += f3(bl,cl,dl) + hl[2]; } else if (i<64) { t += f4(bl,cl,dl) + hl[3]; } else {// if (i<80) { t += f5(bl,cl,dl) + hl[4]; } t = t|0; t = rotl(t,sl[i]); t = (t+el)|0; al = el; el = dl; dl = rotl(cl, 10); cl = bl; bl = t; t = (ar + M[offset+zr[i]])|0; if (i<16){ t += f5(br,cr,dr) + hr[0]; } else if (i<32) { t += f4(br,cr,dr) + hr[1]; } else if (i<48) { t += f3(br,cr,dr) + hr[2]; } else if (i<64) { t += f2(br,cr,dr) + hr[3]; } else {// if (i<80) { t += f1(br,cr,dr) + hr[4]; } t = t|0; t = rotl(t,sr[i]) ; t = (t+er)|0; ar = er; er = dr; dr = rotl(cr, 10); cr = br; br = t; } // Intermediate hash value t = (H[1] + cl + dr)|0; H[1] = (H[2] + dl + er)|0; H[2] = (H[3] + el + ar)|0; H[3] = (H[4] + al + br)|0; H[4] = (H[0] + bl + cr)|0; H[0] = t; }; function f1(x, y, z) { return ((x) ^ (y) ^ (z)); } function f2(x, y, z) { return (((x)&(y)) | ((~x)&(z))); } function f3(x, y, z) { return (((x) | (~(y))) ^ (z)); } function f4(x, y, z) { return (((x) & (z)) | ((y)&(~(z)))); } function f5(x, y, z) { return ((x) ^ ((y) |(~(z)))); } function rotl(x,n) { return (x<>>(32-n)); } function ripemd160(message) { var H = [0x67452301, 0xEFCDAB89, 0x98BADCFE, 0x10325476, 0xC3D2E1F0]; if (typeof message == 'string') message = new Buffer(message, 'utf8'); var m = bytesToWords(message); var nBitsLeft = message.length * 8; var nBitsTotal = message.length * 8; // Add padding m[nBitsLeft >>> 5] |= 0x80 << (24 - nBitsLeft % 32); m[(((nBitsLeft + 64) >>> 9) << 4) + 14] = ( (((nBitsTotal << 8) | (nBitsTotal >>> 24)) & 0x00ff00ff) | (((nBitsTotal << 24) | (nBitsTotal >>> 8)) & 0xff00ff00) ); for (var i=0 ; i>> 24)) & 0x00ff00ff) | (((H_i << 24) | (H_i >>> 8)) & 0xff00ff00); } var digestbytes = wordsToBytes(H); return new Buffer(digestbytes); } }).call(this,_dereq_("buffer").Buffer) },{"buffer":8}],22:[function(_dereq_,module,exports){ var u = _dereq_('./util') var write = u.write var fill = u.zeroFill module.exports = function (Buffer) { //prototype class for hash functions function Hash (blockSize, finalSize) { this._block = new Buffer(blockSize) //new Uint32Array(blockSize/4) this._finalSize = finalSize this._blockSize = blockSize this._len = 0 this._s = 0 } Hash.prototype.init = function () { this._s = 0 this._len = 0 } function lengthOf(data, enc) { if(enc == null) return data.byteLength || data.length if(enc == 'ascii' || enc == 'binary') return data.length if(enc == 'hex') return data.length/2 if(enc == 'base64') return data.length/3 } Hash.prototype.update = function (data, enc) { var bl = this._blockSize //I'd rather do this with a streaming encoder, like the opposite of //http://nodejs.org/api/string_decoder.html var length if(!enc && 'string' === typeof data) enc = 'utf8' if(enc) { if(enc === 'utf-8') enc = 'utf8' if(enc === 'base64' || enc === 'utf8') data = new Buffer(data, enc), enc = null length = lengthOf(data, enc) } else length = data.byteLength || data.length var l = this._len += length var s = this._s = (this._s || 0) var f = 0 var buffer = this._block while(s < l) { var t = Math.min(length, f + bl) write(buffer, data, enc, s%bl, f, t) var ch = (t - f); s += ch; f += ch if(!(s%bl)) this._update(buffer) } this._s = s return this } Hash.prototype.digest = function (enc) { var bl = this._blockSize var fl = this._finalSize var len = this._len*8 var x = this._block var bits = len % (bl*8) //add end marker, so that appending 0's creats a different hash. x[this._len % bl] = 0x80 fill(this._block, this._len % bl + 1) if(bits >= fl*8) { this._update(this._block) u.zeroFill(this._block, 0) } //TODO: handle case where the bit length is > Math.pow(2, 29) x.writeInt32BE(len, fl + 4) //big endian var hash = this._update(this._block) || this._hash() if(enc == null) return hash return hash.toString(enc) } Hash.prototype._update = function () { throw new Error('_update must be implemented by subclass') } return Hash } },{"./util":26}],23:[function(_dereq_,module,exports){ var exports = module.exports = function (alg) { var Alg = exports[alg] if(!Alg) throw new Error(alg + ' is not supported (we accept pull requests)') return new Alg() } var Buffer = _dereq_('buffer').Buffer var Hash = _dereq_('./hash')(Buffer) exports.sha = exports.sha1 = _dereq_('./sha1')(Buffer, Hash) exports.sha256 = _dereq_('./sha256')(Buffer, Hash) },{"./hash":22,"./sha1":24,"./sha256":25,"buffer":8}],24:[function(_dereq_,module,exports){ /* * A JavaScript implementation of the Secure Hash Algorithm, SHA-1, as defined * in FIPS PUB 180-1 * Version 2.1a Copyright Paul Johnston 2000 - 2002. * Other contributors: Greg Holt, Andrew Kepert, Ydnar, Lostinet * Distributed under the BSD License * See http://pajhome.org.uk/crypt/md5 for details. */ module.exports = function (Buffer, Hash) { var inherits = _dereq_('util').inherits inherits(Sha1, Hash) var A = 0|0 var B = 4|0 var C = 8|0 var D = 12|0 var E = 16|0 var BE = false var LE = true var W = new Int32Array(80) var POOL = [] function Sha1 () { if(POOL.length) return POOL.pop().init() if(!(this instanceof Sha1)) return new Sha1() this._w = W Hash.call(this, 16*4, 14*4) this._h = null this.init() } Sha1.prototype.init = function () { this._a = 0x67452301 this._b = 0xefcdab89 this._c = 0x98badcfe this._d = 0x10325476 this._e = 0xc3d2e1f0 Hash.prototype.init.call(this) return this } Sha1.prototype._POOL = POOL // assume that array is a Uint32Array with length=16, // and that if it is the last block, it already has the length and the 1 bit appended. var isDV = new Buffer(1) instanceof DataView function readInt32BE (X, i) { return isDV ? X.getInt32(i, false) : X.readInt32BE(i) } Sha1.prototype._update = function (array) { var X = this._block var h = this._h var a, b, c, d, e, _a, _b, _c, _d, _e a = _a = this._a b = _b = this._b c = _c = this._c d = _d = this._d e = _e = this._e var w = this._w for(var j = 0; j < 80; j++) { var W = w[j] = j < 16 //? X.getInt32(j*4, false) //? readInt32BE(X, j*4) //*/ X.readInt32BE(j*4) //*/ ? X.readInt32BE(j*4) : rol(w[j - 3] ^ w[j - 8] ^ w[j - 14] ^ w[j - 16], 1) var t = add( add(rol(a, 5), sha1_ft(j, b, c, d)), add(add(e, W), sha1_kt(j)) ); e = d d = c c = rol(b, 30) b = a a = t } this._a = add(a, _a) this._b = add(b, _b) this._c = add(c, _c) this._d = add(d, _d) this._e = add(e, _e) } Sha1.prototype._hash = function () { if(POOL.length < 100) POOL.push(this) var H = new Buffer(20) //console.log(this._a|0, this._b|0, this._c|0, this._d|0, this._e|0) H.writeInt32BE(this._a|0, A) H.writeInt32BE(this._b|0, B) H.writeInt32BE(this._c|0, C) H.writeInt32BE(this._d|0, D) H.writeInt32BE(this._e|0, E) return H } /* * Perform the appropriate triplet combination function for the current * iteration */ function sha1_ft(t, b, c, d) { if(t < 20) return (b & c) | ((~b) & d); if(t < 40) return b ^ c ^ d; if(t < 60) return (b & c) | (b & d) | (c & d); return b ^ c ^ d; } /* * Determine the appropriate additive constant for the current iteration */ function sha1_kt(t) { return (t < 20) ? 1518500249 : (t < 40) ? 1859775393 : (t < 60) ? -1894007588 : -899497514; } /* * Add integers, wrapping at 2^32. This uses 16-bit operations internally * to work around bugs in some JS interpreters. * //dominictarr: this is 10 years old, so maybe this can be dropped?) * */ function add(x, y) { return (x + y ) | 0 //lets see how this goes on testling. // var lsw = (x & 0xFFFF) + (y & 0xFFFF); // var msw = (x >> 16) + (y >> 16) + (lsw >> 16); // return (msw << 16) | (lsw & 0xFFFF); } /* * Bitwise rotate a 32-bit number to the left. */ function rol(num, cnt) { return (num << cnt) | (num >>> (32 - cnt)); } return Sha1 } },{"util":14}],25:[function(_dereq_,module,exports){ /** * A JavaScript implementation of the Secure Hash Algorithm, SHA-256, as defined * in FIPS 180-2 * Version 2.2-beta Copyright Angel Marin, Paul Johnston 2000 - 2009. * Other contributors: Greg Holt, Andrew Kepert, Ydnar, Lostinet * */ var inherits = _dereq_('util').inherits var BE = false var LE = true var u = _dereq_('./util') module.exports = function (Buffer, Hash) { var K = [ 0x428A2F98, 0x71374491, 0xB5C0FBCF, 0xE9B5DBA5, 0x3956C25B, 0x59F111F1, 0x923F82A4, 0xAB1C5ED5, 0xD807AA98, 0x12835B01, 0x243185BE, 0x550C7DC3, 0x72BE5D74, 0x80DEB1FE, 0x9BDC06A7, 0xC19BF174, 0xE49B69C1, 0xEFBE4786, 0x0FC19DC6, 0x240CA1CC, 0x2DE92C6F, 0x4A7484AA, 0x5CB0A9DC, 0x76F988DA, 0x983E5152, 0xA831C66D, 0xB00327C8, 0xBF597FC7, 0xC6E00BF3, 0xD5A79147, 0x06CA6351, 0x14292967, 0x27B70A85, 0x2E1B2138, 0x4D2C6DFC, 0x53380D13, 0x650A7354, 0x766A0ABB, 0x81C2C92E, 0x92722C85, 0xA2BFE8A1, 0xA81A664B, 0xC24B8B70, 0xC76C51A3, 0xD192E819, 0xD6990624, 0xF40E3585, 0x106AA070, 0x19A4C116, 0x1E376C08, 0x2748774C, 0x34B0BCB5, 0x391C0CB3, 0x4ED8AA4A, 0x5B9CCA4F, 0x682E6FF3, 0x748F82EE, 0x78A5636F, 0x84C87814, 0x8CC70208, 0x90BEFFFA, 0xA4506CEB, 0xBEF9A3F7, 0xC67178F2 ] inherits(Sha256, Hash) var W = new Array(64) var POOL = [] function Sha256() { // Closure compiler warning - this code lacks side effects - thus commented out // if(POOL.length) { // return POOL.shift().init() // } //this._data = new Buffer(32) this.init() this._w = W //new Array(64) Hash.call(this, 16*4, 14*4) }; Sha256.prototype.init = function () { this._a = 0x6a09e667|0 this._b = 0xbb67ae85|0 this._c = 0x3c6ef372|0 this._d = 0xa54ff53a|0 this._e = 0x510e527f|0 this._f = 0x9b05688c|0 this._g = 0x1f83d9ab|0 this._h = 0x5be0cd19|0 this._len = this._s = 0 return this } var safe_add = function(x, y) { var lsw = (x & 0xFFFF) + (y & 0xFFFF); var msw = (x >> 16) + (y >> 16) + (lsw >> 16); return (msw << 16) | (lsw & 0xFFFF); } function S (X, n) { return (X >>> n) | (X << (32 - n)); } function R (X, n) { return (X >>> n); } function Ch (x, y, z) { return ((x & y) ^ ((~x) & z)); } function Maj (x, y, z) { return ((x & y) ^ (x & z) ^ (y & z)); } function Sigma0256 (x) { return (S(x, 2) ^ S(x, 13) ^ S(x, 22)); } function Sigma1256 (x) { return (S(x, 6) ^ S(x, 11) ^ S(x, 25)); } function Gamma0256 (x) { return (S(x, 7) ^ S(x, 18) ^ R(x, 3)); } function Gamma1256 (x) { return (S(x, 17) ^ S(x, 19) ^ R(x, 10)); } Sha256.prototype._update = function(m) { var M = this._block var W = this._w var a, b, c, d, e, f, g, h var T1, T2 a = this._a | 0 b = this._b | 0 c = this._c | 0 d = this._d | 0 e = this._e | 0 f = this._f | 0 g = this._g | 0 h = this._h | 0 for (var j = 0; j < 64; j++) { var w = W[j] = j < 16 ? M.readInt32BE(j * 4) : Gamma1256(W[j - 2]) + W[j - 7] + Gamma0256(W[j - 15]) + W[j - 16] T1 = h + Sigma1256(e) + Ch(e, f, g) + K[j] + w T2 = Sigma0256(a) + Maj(a, b, c); h = g; g = f; f = e; e = d + T1; d = c; c = b; b = a; a = T1 + T2; } this._a = (a + this._a) | 0 this._b = (b + this._b) | 0 this._c = (c + this._c) | 0 this._d = (d + this._d) | 0 this._e = (e + this._e) | 0 this._f = (f + this._f) | 0 this._g = (g + this._g) | 0 this._h = (h + this._h) | 0 }; Sha256.prototype._hash = function () { if(POOL.length < 10) POOL.push(this) var H = new Buffer(32) H.writeInt32BE(this._a, 0) H.writeInt32BE(this._b, 4) H.writeInt32BE(this._c, 8) H.writeInt32BE(this._d, 12) H.writeInt32BE(this._e, 16) H.writeInt32BE(this._f, 20) H.writeInt32BE(this._g, 24) H.writeInt32BE(this._h, 28) return H } return Sha256 } },{"./util":26,"util":14}],26:[function(_dereq_,module,exports){ exports.write = write exports.zeroFill = zeroFill exports.toString = toString function write (buffer, string, enc, start, from, to, LE) { var l = (to - from) if(enc === 'ascii' || enc === 'binary') { for( var i = 0; i < l; i++) { buffer[start + i] = string.charCodeAt(i + from) } } else if(enc == null) { for( var i = 0; i < l; i++) { buffer[start + i] = string[i + from] } } else if(enc === 'hex') { for(var i = 0; i < l; i++) { var j = from + i buffer[start + i] = parseInt(string[j*2] + string[(j*2)+1], 16) } } else if(enc === 'base64') { throw new Error('base64 encoding not yet supported') } else throw new Error(enc +' encoding not yet supported') } //always fill to the end! function zeroFill(buf, from) { for(var i = from; i < buf.length; i++) buf[i] = 0 } },{}],27:[function(_dereq_,module,exports){ (function (Buffer){ // JavaScript PBKDF2 Implementation // Based on http://git.io/qsv2zw // Licensed under LGPL v3 // Copyright (c) 2013 jduncanator var blocksize = 64 var zeroBuffer = new Buffer(blocksize); zeroBuffer.fill(0) module.exports = function (createHmac, exports) { exports = exports || {} exports.pbkdf2 = function(password, salt, iterations, keylen, cb) { if('function' !== typeof cb) throw new Error('No callback provided to pbkdf2'); setTimeout(function () { cb(null, exports.pbkdf2Sync(password, salt, iterations, keylen)) }) } exports.pbkdf2Sync = function(key, salt, iterations, keylen) { if('number' !== typeof iterations) throw new TypeError('Iterations not a number') if(iterations < 0) throw new TypeError('Bad iterations') if('number' !== typeof keylen) throw new TypeError('Key length not a number') if(keylen < 0) throw new TypeError('Bad key length') //stretch key to the correct length that hmac wants it, //otherwise this will happen every time hmac is called //twice per iteration. var key = !Buffer.isBuffer(key) ? new Buffer(key) : key if(key.length > blocksize) { key = createHash(alg).update(key).digest() } else if(key.length < blocksize) { key = Buffer.concat([key, zeroBuffer], blocksize) } var HMAC; var cplen, p = 0, i = 1, itmp = new Buffer(4), digtmp; var out = new Buffer(keylen); out.fill(0); while(keylen) { if(keylen > 20) cplen = 20; else cplen = keylen; /* We are unlikely to ever use more than 256 blocks (5120 bits!) * but just in case... */ itmp[0] = (i >> 24) & 0xff; itmp[1] = (i >> 16) & 0xff; itmp[2] = (i >> 8) & 0xff; itmp[3] = i & 0xff; HMAC = createHmac('sha1', key); HMAC.update(salt) HMAC.update(itmp); digtmp = HMAC.digest(); digtmp.copy(out, p, 0, cplen); for(var j = 1; j < iterations; j++) { HMAC = createHmac('sha1', key); HMAC.update(digtmp); digtmp = HMAC.digest(); for(var k = 0; k < cplen; k++) { out[k] ^= digtmp[k]; } } keylen -= cplen; i++; p += cplen; } return out; } return exports } }).call(this,_dereq_("buffer").Buffer) },{"buffer":8}],28:[function(_dereq_,module,exports){ (function (Buffer){ // Original code adapted from Robert Kieffer. // details at https://github.com/broofa/node-uuid (function() { var _global = this; var mathRNG, whatwgRNG; // NOTE: Math.random() does not guarantee "cryptographic quality" mathRNG = function(size) { var bytes = new Buffer(size); var r; for (var i = 0, r; i < size; i++) { if ((i & 0x03) == 0) r = Math.random() * 0x100000000; bytes[i] = r >>> ((i & 0x03) << 3) & 0xff; } return bytes; } if (_global.crypto && crypto.getRandomValues) { whatwgRNG = function(size) { var bytes = new Buffer(size); //in browserify, this is an extended Uint8Array crypto.getRandomValues(bytes); return bytes; } } module.exports = whatwgRNG || mathRNG; }()) }).call(this,_dereq_("buffer").Buffer) },{"buffer":8}],29:[function(_dereq_,module,exports){ ;(function (root, factory, undef) { if (typeof exports === "object") { // CommonJS module.exports = exports = factory(_dereq_("./core"), _dereq_("./enc-base64"), _dereq_("./md5"), _dereq_("./evpkdf"), _dereq_("./cipher-core")); } else if (typeof define === "function" && define.amd) { // AMD define(["./core", "./enc-base64", "./md5", "./evpkdf", "./cipher-core"], factory); } else { // Global (browser) factory(root.CryptoJS); } }(this, function (CryptoJS) { (function () { // Shortcuts var C = CryptoJS; var C_lib = C.lib; var BlockCipher = C_lib.BlockCipher; var C_algo = C.algo; // Lookup tables var SBOX = []; var INV_SBOX = []; var SUB_MIX_0 = []; var SUB_MIX_1 = []; var SUB_MIX_2 = []; var SUB_MIX_3 = []; var INV_SUB_MIX_0 = []; var INV_SUB_MIX_1 = []; var INV_SUB_MIX_2 = []; var INV_SUB_MIX_3 = []; // Compute lookup tables (function () { // Compute double table var d = []; for (var i = 0; i < 256; i++) { if (i < 128) { d[i] = i << 1; } else { d[i] = (i << 1) ^ 0x11b; } } // Walk GF(2^8) var x = 0; var xi = 0; for (var i = 0; i < 256; i++) { // Compute sbox var sx = xi ^ (xi << 1) ^ (xi << 2) ^ (xi << 3) ^ (xi << 4); sx = (sx >>> 8) ^ (sx & 0xff) ^ 0x63; SBOX[x] = sx; INV_SBOX[sx] = x; // Compute multiplication var x2 = d[x]; var x4 = d[x2]; var x8 = d[x4]; // Compute sub bytes, mix columns tables var t = (d[sx] * 0x101) ^ (sx * 0x1010100); SUB_MIX_0[x] = (t << 24) | (t >>> 8); SUB_MIX_1[x] = (t << 16) | (t >>> 16); SUB_MIX_2[x] = (t << 8) | (t >>> 24); SUB_MIX_3[x] = t; // Compute inv sub bytes, inv mix columns tables var t = (x8 * 0x1010101) ^ (x4 * 0x10001) ^ (x2 * 0x101) ^ (x * 0x1010100); INV_SUB_MIX_0[sx] = (t << 24) | (t >>> 8); INV_SUB_MIX_1[sx] = (t << 16) | (t >>> 16); INV_SUB_MIX_2[sx] = (t << 8) | (t >>> 24); INV_SUB_MIX_3[sx] = t; // Compute next counter if (!x) { x = xi = 1; } else { x = x2 ^ d[d[d[x8 ^ x2]]]; xi ^= d[d[xi]]; } } }()); // Precomputed Rcon lookup var RCON = [0x00, 0x01, 0x02, 0x04, 0x08, 0x10, 0x20, 0x40, 0x80, 0x1b, 0x36]; /** * AES block cipher algorithm. */ var AES = C_algo.AES = BlockCipher.extend({ _doReset: function () { // Shortcuts var key = this._key; var keyWords = key.words; var keySize = key.sigBytes / 4; // Compute number of rounds var nRounds = this._nRounds = keySize + 6 // Compute number of key schedule rows var ksRows = (nRounds + 1) * 4; // Compute key schedule var keySchedule = this._keySchedule = []; for (var ksRow = 0; ksRow < ksRows; ksRow++) { if (ksRow < keySize) { keySchedule[ksRow] = keyWords[ksRow]; } else { var t = keySchedule[ksRow - 1]; if (!(ksRow % keySize)) { // Rot word t = (t << 8) | (t >>> 24); // Sub word t = (SBOX[t >>> 24] << 24) | (SBOX[(t >>> 16) & 0xff] << 16) | (SBOX[(t >>> 8) & 0xff] << 8) | SBOX[t & 0xff]; // Mix Rcon t ^= RCON[(ksRow / keySize) | 0] << 24; } else if (keySize > 6 && ksRow % keySize == 4) { // Sub word t = (SBOX[t >>> 24] << 24) | (SBOX[(t >>> 16) & 0xff] << 16) | (SBOX[(t >>> 8) & 0xff] << 8) | SBOX[t & 0xff]; } keySchedule[ksRow] = keySchedule[ksRow - keySize] ^ t; } } // Compute inv key schedule var invKeySchedule = this._invKeySchedule = []; for (var invKsRow = 0; invKsRow < ksRows; invKsRow++) { var ksRow = ksRows - invKsRow; if (invKsRow % 4) { var t = keySchedule[ksRow]; } else { var t = keySchedule[ksRow - 4]; } if (invKsRow < 4 || ksRow <= 4) { invKeySchedule[invKsRow] = t; } else { invKeySchedule[invKsRow] = INV_SUB_MIX_0[SBOX[t >>> 24]] ^ INV_SUB_MIX_1[SBOX[(t >>> 16) & 0xff]] ^ INV_SUB_MIX_2[SBOX[(t >>> 8) & 0xff]] ^ INV_SUB_MIX_3[SBOX[t & 0xff]]; } } }, encryptBlock: function (M, offset) { this._doCryptBlock(M, offset, this._keySchedule, SUB_MIX_0, SUB_MIX_1, SUB_MIX_2, SUB_MIX_3, SBOX); }, decryptBlock: function (M, offset) { // Swap 2nd and 4th rows var t = M[offset + 1]; M[offset + 1] = M[offset + 3]; M[offset + 3] = t; this._doCryptBlock(M, offset, this._invKeySchedule, INV_SUB_MIX_0, INV_SUB_MIX_1, INV_SUB_MIX_2, INV_SUB_MIX_3, INV_SBOX); // Inv swap 2nd and 4th rows var t = M[offset + 1]; M[offset + 1] = M[offset + 3]; M[offset + 3] = t; }, _doCryptBlock: function (M, offset, keySchedule, SUB_MIX_0, SUB_MIX_1, SUB_MIX_2, SUB_MIX_3, SBOX) { // Shortcut var nRounds = this._nRounds; // Get input, add round key var s0 = M[offset] ^ keySchedule[0]; var s1 = M[offset + 1] ^ keySchedule[1]; var s2 = M[offset + 2] ^ keySchedule[2]; var s3 = M[offset + 3] ^ keySchedule[3]; // Key schedule row counter var ksRow = 4; // Rounds for (var round = 1; round < nRounds; round++) { // Shift rows, sub bytes, mix columns, add round key var t0 = SUB_MIX_0[s0 >>> 24] ^ SUB_MIX_1[(s1 >>> 16) & 0xff] ^ SUB_MIX_2[(s2 >>> 8) & 0xff] ^ SUB_MIX_3[s3 & 0xff] ^ keySchedule[ksRow++]; var t1 = SUB_MIX_0[s1 >>> 24] ^ SUB_MIX_1[(s2 >>> 16) & 0xff] ^ SUB_MIX_2[(s3 >>> 8) & 0xff] ^ SUB_MIX_3[s0 & 0xff] ^ keySchedule[ksRow++]; var t2 = SUB_MIX_0[s2 >>> 24] ^ SUB_MIX_1[(s3 >>> 16) & 0xff] ^ SUB_MIX_2[(s0 >>> 8) & 0xff] ^ SUB_MIX_3[s1 & 0xff] ^ keySchedule[ksRow++]; var t3 = SUB_MIX_0[s3 >>> 24] ^ SUB_MIX_1[(s0 >>> 16) & 0xff] ^ SUB_MIX_2[(s1 >>> 8) & 0xff] ^ SUB_MIX_3[s2 & 0xff] ^ keySchedule[ksRow++]; // Update state s0 = t0; s1 = t1; s2 = t2; s3 = t3; } // Shift rows, sub bytes, add round key var t0 = ((SBOX[s0 >>> 24] << 24) | (SBOX[(s1 >>> 16) & 0xff] << 16) | (SBOX[(s2 >>> 8) & 0xff] << 8) | SBOX[s3 & 0xff]) ^ keySchedule[ksRow++]; var t1 = ((SBOX[s1 >>> 24] << 24) | (SBOX[(s2 >>> 16) & 0xff] << 16) | (SBOX[(s3 >>> 8) & 0xff] << 8) | SBOX[s0 & 0xff]) ^ keySchedule[ksRow++]; var t2 = ((SBOX[s2 >>> 24] << 24) | (SBOX[(s3 >>> 16) & 0xff] << 16) | (SBOX[(s0 >>> 8) & 0xff] << 8) | SBOX[s1 & 0xff]) ^ keySchedule[ksRow++]; var t3 = ((SBOX[s3 >>> 24] << 24) | (SBOX[(s0 >>> 16) & 0xff] << 16) | (SBOX[(s1 >>> 8) & 0xff] << 8) | SBOX[s2 & 0xff]) ^ keySchedule[ksRow++]; // Set output M[offset] = t0; M[offset + 1] = t1; M[offset + 2] = t2; M[offset + 3] = t3; }, keySize: 256/32 }); /** * Shortcut functions to the cipher's object interface. * * @example * * var ciphertext = CryptoJS.AES.encrypt(message, key, cfg); * var plaintext = CryptoJS.AES.decrypt(ciphertext, key, cfg); */ C.AES = BlockCipher._createHelper(AES); }()); return CryptoJS.AES; })); },{"./cipher-core":30,"./core":31,"./enc-base64":32,"./evpkdf":34,"./md5":39}],30:[function(_dereq_,module,exports){ ;(function (root, factory) { if (typeof exports === "object") { // CommonJS module.exports = exports = factory(_dereq_("./core")); } else if (typeof define === "function" && define.amd) { // AMD define(["./core"], factory); } else { // Global (browser) factory(root.CryptoJS); } }(this, function (CryptoJS) { /** * Cipher core components. */ CryptoJS.lib.Cipher || (function (undefined) { // Shortcuts var C = CryptoJS; var C_lib = C.lib; var Base = C_lib.Base; var WordArray = C_lib.WordArray; var BufferedBlockAlgorithm = C_lib.BufferedBlockAlgorithm; var C_enc = C.enc; var Utf8 = C_enc.Utf8; var Base64 = C_enc.Base64; var C_algo = C.algo; var EvpKDF = C_algo.EvpKDF; /** * Abstract base cipher template. * * @property {number} keySize This cipher's key size. Default: 4 (128 bits) * @property {number} ivSize This cipher's IV size. Default: 4 (128 bits) * @property {number} _ENC_XFORM_MODE A constant representing encryption mode. * @property {number} _DEC_XFORM_MODE A constant representing decryption mode. */ var Cipher = C_lib.Cipher = BufferedBlockAlgorithm.extend({ /** * Configuration options. * * @property {WordArray} iv The IV to use for this operation. */ cfg: Base.extend(), /** * Creates this cipher in encryption mode. * * @param {WordArray} key The key. * @param {Object} cfg (Optional) The configuration options to use for this operation. * * @return {Cipher} A cipher instance. * * @static * * @example * * var cipher = CryptoJS.algo.AES.createEncryptor(keyWordArray, { iv: ivWordArray }); */ createEncryptor: function (key, cfg) { return this.create(this._ENC_XFORM_MODE, key, cfg); }, /** * Creates this cipher in decryption mode. * * @param {WordArray} key The key. * @param {Object} cfg (Optional) The configuration options to use for this operation. * * @return {Cipher} A cipher instance. * * @static * * @example * * var cipher = CryptoJS.algo.AES.createDecryptor(keyWordArray, { iv: ivWordArray }); */ createDecryptor: function (key, cfg) { return this.create(this._DEC_XFORM_MODE, key, cfg); }, /** * Initializes a newly created cipher. * * @param {number} xformMode Either the encryption or decryption transormation mode constant. * @param {WordArray} key The key. * @param {Object} cfg (Optional) The configuration options to use for this operation. * * @example * * var cipher = CryptoJS.algo.AES.create(CryptoJS.algo.AES._ENC_XFORM_MODE, keyWordArray, { iv: ivWordArray }); */ init: function (xformMode, key, cfg) { // Apply config defaults this.cfg = this.cfg.extend(cfg); // Store transform mode and key this._xformMode = xformMode; this._key = key; // Set initial values this.reset(); }, /** * Resets this cipher to its initial state. * * @example * * cipher.reset(); */ reset: function () { // Reset data buffer BufferedBlockAlgorithm.reset.call(this); // Perform concrete-cipher logic this._doReset(); }, /** * Adds data to be encrypted or decrypted. * * @param {WordArray|string} dataUpdate The data to encrypt or decrypt. * * @return {WordArray} The data after processing. * * @example * * var encrypted = cipher.process('data'); * var encrypted = cipher.process(wordArray); */ process: function (dataUpdate) { // Append this._append(dataUpdate); // Process available blocks return this._process(); }, /** * Finalizes the encryption or decryption process. * Note that the finalize operation is effectively a destructive, read-once operation. * * @param {WordArray|string} dataUpdate The final data to encrypt or decrypt. * * @return {WordArray} The data after final processing. * * @example * * var encrypted = cipher.finalize(); * var encrypted = cipher.finalize('data'); * var encrypted = cipher.finalize(wordArray); */ finalize: function (dataUpdate) { // Final data update if (dataUpdate) { this._append(dataUpdate); } // Perform concrete-cipher logic var finalProcessedData = this._doFinalize(); return finalProcessedData; }, keySize: 128/32, ivSize: 128/32, _ENC_XFORM_MODE: 1, _DEC_XFORM_MODE: 2, /** * Creates shortcut functions to a cipher's object interface. * * @param {Cipher} cipher The cipher to create a helper for. * * @return {Object} An object with encrypt and decrypt shortcut functions. * * @static * * @example * * var AES = CryptoJS.lib.Cipher._createHelper(CryptoJS.algo.AES); */ _createHelper: (function () { function selectCipherStrategy(key) { if (typeof key == 'string') { return PasswordBasedCipher; } else { return SerializableCipher; } } return function (cipher) { return { encrypt: function (message, key, cfg) { return selectCipherStrategy(key).encrypt(cipher, message, key, cfg); }, decrypt: function (ciphertext, key, cfg) { return selectCipherStrategy(key).decrypt(cipher, ciphertext, key, cfg); } }; }; }()) }); /** * Abstract base stream cipher template. * * @property {number} blockSize The number of 32-bit words this cipher operates on. Default: 1 (32 bits) */ var StreamCipher = C_lib.StreamCipher = Cipher.extend({ _doFinalize: function () { // Process partial blocks var finalProcessedBlocks = this._process(!!'flush'); return finalProcessedBlocks; }, blockSize: 1 }); /** * Mode namespace. */ var C_mode = C.mode = {}; /** * Abstract base block cipher mode template. */ var BlockCipherMode = C_lib.BlockCipherMode = Base.extend({ /** * Creates this mode for encryption. * * @param {Cipher} cipher A block cipher instance. * @param {Array} iv The IV words. * * @static * * @example * * var mode = CryptoJS.mode.CBC.createEncryptor(cipher, iv.words); */ createEncryptor: function (cipher, iv) { return this.Encryptor.create(cipher, iv); }, /** * Creates this mode for decryption. * * @param {Cipher} cipher A block cipher instance. * @param {Array} iv The IV words. * * @static * * @example * * var mode = CryptoJS.mode.CBC.createDecryptor(cipher, iv.words); */ createDecryptor: function (cipher, iv) { return this.Decryptor.create(cipher, iv); }, /** * Initializes a newly created mode. * * @param {Cipher} cipher A block cipher instance. * @param {Array} iv The IV words. * * @example * * var mode = CryptoJS.mode.CBC.Encryptor.create(cipher, iv.words); */ init: function (cipher, iv) { this._cipher = cipher; this._iv = iv; } }); /** * Cipher Block Chaining mode. */ var CBC = C_mode.CBC = (function () { /** * Abstract base CBC mode. */ var CBC = BlockCipherMode.extend(); /** * CBC encryptor. */ CBC.Encryptor = CBC.extend({ /** * Processes the data block at offset. * * @param {Array} words The data words to operate on. * @param {number} offset The offset where the block starts. * * @example * * mode.processBlock(data.words, offset); */ processBlock: function (words, offset) { // Shortcuts var cipher = this._cipher; var blockSize = cipher.blockSize; // XOR and encrypt xorBlock.call(this, words, offset, blockSize); cipher.encryptBlock(words, offset); // Remember this block to use with next block this._prevBlock = words.slice(offset, offset + blockSize); } }); /** * CBC decryptor. */ CBC.Decryptor = CBC.extend({ /** * Processes the data block at offset. * * @param {Array} words The data words to operate on. * @param {number} offset The offset where the block starts. * * @example * * mode.processBlock(data.words, offset); */ processBlock: function (words, offset) { // Shortcuts var cipher = this._cipher; var blockSize = cipher.blockSize; // Remember this block to use with next block var thisBlock = words.slice(offset, offset + blockSize); // Decrypt and XOR cipher.decryptBlock(words, offset); xorBlock.call(this, words, offset, blockSize); // This block becomes the previous block this._prevBlock = thisBlock; } }); function xorBlock(words, offset, blockSize) { // Shortcut var iv = this._iv; // Choose mixing block if (iv) { var block = iv; // Remove IV for subsequent blocks this._iv = undefined; } else { var block = this._prevBlock; } // XOR blocks for (var i = 0; i < blockSize; i++) { words[offset + i] ^= block[i]; } } return CBC; }()); /** * Padding namespace. */ var C_pad = C.pad = {}; /** * PKCS #5/7 padding strategy. */ var Pkcs7 = C_pad.Pkcs7 = { /** * Pads data using the algorithm defined in PKCS #5/7. * * @param {WordArray} data The data to pad. * @param {number} blockSize The multiple that the data should be padded to. * * @static * * @example * * CryptoJS.pad.Pkcs7.pad(wordArray, 4); */ pad: function (data, blockSize) { // Shortcut var blockSizeBytes = blockSize * 4; // Count padding bytes var nPaddingBytes = blockSizeBytes - data.sigBytes % blockSizeBytes; // Create padding word var paddingWord = (nPaddingBytes << 24) | (nPaddingBytes << 16) | (nPaddingBytes << 8) | nPaddingBytes; // Create padding var paddingWords = []; for (var i = 0; i < nPaddingBytes; i += 4) { paddingWords.push(paddingWord); } var padding = WordArray.create(paddingWords, nPaddingBytes); // Add padding data.concat(padding); }, /** * Unpads data that had been padded using the algorithm defined in PKCS #5/7. * * @param {WordArray} data The data to unpad. * * @static * * @example * * CryptoJS.pad.Pkcs7.unpad(wordArray); */ unpad: function (data) { // Get number of padding bytes from last byte var nPaddingBytes = data.words[(data.sigBytes - 1) >>> 2] & 0xff; // Remove padding data.sigBytes -= nPaddingBytes; } }; /** * Abstract base block cipher template. * * @property {number} blockSize The number of 32-bit words this cipher operates on. Default: 4 (128 bits) */ var BlockCipher = C_lib.BlockCipher = Cipher.extend({ /** * Configuration options. * * @property {Mode} mode The block mode to use. Default: CBC * @property {Padding} padding The padding strategy to use. Default: Pkcs7 */ cfg: Cipher.cfg.extend({ mode: CBC, padding: Pkcs7 }), reset: function () { // Reset cipher Cipher.reset.call(this); // Shortcuts var cfg = this.cfg; var iv = cfg.iv; var mode = cfg.mode; // Reset block mode if (this._xformMode == this._ENC_XFORM_MODE) { var modeCreator = mode.createEncryptor; } else /* if (this._xformMode == this._DEC_XFORM_MODE) */ { var modeCreator = mode.createDecryptor; // Keep at least one block in the buffer for unpadding this._minBufferSize = 1; } this._mode = modeCreator.call(mode, this, iv && iv.words); }, _doProcessBlock: function (words, offset) { this._mode.processBlock(words, offset); }, _doFinalize: function () { // Shortcut var padding = this.cfg.padding; // Finalize if (this._xformMode == this._ENC_XFORM_MODE) { // Pad data padding.pad(this._data, this.blockSize); // Process final blocks var finalProcessedBlocks = this._process(!!'flush'); } else /* if (this._xformMode == this._DEC_XFORM_MODE) */ { // Process final blocks var finalProcessedBlocks = this._process(!!'flush'); // Unpad data padding.unpad(finalProcessedBlocks); } return finalProcessedBlocks; }, blockSize: 128/32 }); /** * A collection of cipher parameters. * * @property {WordArray} ciphertext The raw ciphertext. * @property {WordArray} key The key to this ciphertext. * @property {WordArray} iv The IV used in the ciphering operation. * @property {WordArray} salt The salt used with a key derivation function. * @property {Cipher} algorithm The cipher algorithm. * @property {Mode} mode The block mode used in the ciphering operation. * @property {Padding} padding The padding scheme used in the ciphering operation. * @property {number} blockSize The block size of the cipher. * @property {Format} formatter The default formatting strategy to convert this cipher params object to a string. */ var CipherParams = C_lib.CipherParams = Base.extend({ /** * Initializes a newly created cipher params object. * * @param {Object} cipherParams An object with any of the possible cipher parameters. * * @example * * var cipherParams = CryptoJS.lib.CipherParams.create({ * ciphertext: ciphertextWordArray, * key: keyWordArray, * iv: ivWordArray, * salt: saltWordArray, * algorithm: CryptoJS.algo.AES, * mode: CryptoJS.mode.CBC, * padding: CryptoJS.pad.PKCS7, * blockSize: 4, * formatter: CryptoJS.format.OpenSSL * }); */ init: function (cipherParams) { this.mixIn(cipherParams); }, /** * Converts this cipher params object to a string. * * @param {Format} formatter (Optional) The formatting strategy to use. * * @return {string} The stringified cipher params. * * @throws Error If neither the formatter nor the default formatter is set. * * @example * * var string = cipherParams + ''; * var string = cipherParams.toString(); * var string = cipherParams.toString(CryptoJS.format.OpenSSL); */ toString: function (formatter) { return (formatter || this.formatter).stringify(this); } }); /** * Format namespace. */ var C_format = C.format = {}; /** * OpenSSL formatting strategy. */ var OpenSSLFormatter = C_format.OpenSSL = { /** * Converts a cipher params object to an OpenSSL-compatible string. * * @param {CipherParams} cipherParams The cipher params object. * * @return {string} The OpenSSL-compatible string. * * @static * * @example * * var openSSLString = CryptoJS.format.OpenSSL.stringify(cipherParams); */ stringify: function (cipherParams) { // Shortcuts var ciphertext = cipherParams.ciphertext; var salt = cipherParams.salt; // Format if (salt) { var wordArray = WordArray.create([0x53616c74, 0x65645f5f]).concat(salt).concat(ciphertext); } else { var wordArray = ciphertext; } return wordArray.toString(Base64); }, /** * Converts an OpenSSL-compatible string to a cipher params object. * * @param {string} openSSLStr The OpenSSL-compatible string. * * @return {CipherParams} The cipher params object. * * @static * * @example * * var cipherParams = CryptoJS.format.OpenSSL.parse(openSSLString); */ parse: function (openSSLStr) { // Parse base64 var ciphertext = Base64.parse(openSSLStr); // Shortcut var ciphertextWords = ciphertext.words; // Test for salt if (ciphertextWords[0] == 0x53616c74 && ciphertextWords[1] == 0x65645f5f) { // Extract salt var salt = WordArray.create(ciphertextWords.slice(2, 4)); // Remove salt from ciphertext ciphertextWords.splice(0, 4); ciphertext.sigBytes -= 16; } return CipherParams.create({ ciphertext: ciphertext, salt: salt }); } }; /** * A cipher wrapper that returns ciphertext as a serializable cipher params object. */ var SerializableCipher = C_lib.SerializableCipher = Base.extend({ /** * Configuration options. * * @property {Formatter} format The formatting strategy to convert cipher param objects to and from a string. Default: OpenSSL */ cfg: Base.extend({ format: OpenSSLFormatter }), /** * Encrypts a message. * * @param {Cipher} cipher The cipher algorithm to use. * @param {WordArray|string} message The message to encrypt. * @param {WordArray} key The key. * @param {Object} cfg (Optional) The configuration options to use for this operation. * * @return {CipherParams} A cipher params object. * * @static * * @example * * var ciphertextParams = CryptoJS.lib.SerializableCipher.encrypt(CryptoJS.algo.AES, message, key); * var ciphertextParams = CryptoJS.lib.SerializableCipher.encrypt(CryptoJS.algo.AES, message, key, { iv: iv }); * var ciphertextParams = CryptoJS.lib.SerializableCipher.encrypt(CryptoJS.algo.AES, message, key, { iv: iv, format: CryptoJS.format.OpenSSL }); */ encrypt: function (cipher, message, key, cfg) { // Apply config defaults cfg = this.cfg.extend(cfg); // Encrypt var encryptor = cipher.createEncryptor(key, cfg); var ciphertext = encryptor.finalize(message); // Shortcut var cipherCfg = encryptor.cfg; // Create and return serializable cipher params return CipherParams.create({ ciphertext: ciphertext, key: key, iv: cipherCfg.iv, algorithm: cipher, mode: cipherCfg.mode, padding: cipherCfg.padding, blockSize: cipher.blockSize, formatter: cfg.format }); }, /** * Decrypts serialized ciphertext. * * @param {Cipher} cipher The cipher algorithm to use. * @param {CipherParams|string} ciphertext The ciphertext to decrypt. * @param {WordArray} key The key. * @param {Object} cfg (Optional) The configuration options to use for this operation. * * @return {WordArray} The plaintext. * * @static * * @example * * var plaintext = CryptoJS.lib.SerializableCipher.decrypt(CryptoJS.algo.AES, formattedCiphertext, key, { iv: iv, format: CryptoJS.format.OpenSSL }); * var plaintext = CryptoJS.lib.SerializableCipher.decrypt(CryptoJS.algo.AES, ciphertextParams, key, { iv: iv, format: CryptoJS.format.OpenSSL }); */ decrypt: function (cipher, ciphertext, key, cfg) { // Apply config defaults cfg = this.cfg.extend(cfg); // Convert string to CipherParams ciphertext = this._parse(ciphertext, cfg.format); // Decrypt var plaintext = cipher.createDecryptor(key, cfg).finalize(ciphertext.ciphertext); return plaintext; }, /** * Converts serialized ciphertext to CipherParams, * else assumed CipherParams already and returns ciphertext unchanged. * * @param {CipherParams|string} ciphertext The ciphertext. * @param {Formatter} format The formatting strategy to use to parse serialized ciphertext. * * @return {CipherParams} The unserialized ciphertext. * * @static * * @example * * var ciphertextParams = CryptoJS.lib.SerializableCipher._parse(ciphertextStringOrParams, format); */ _parse: function (ciphertext, format) { if (typeof ciphertext == 'string') { return format.parse(ciphertext, this); } else { return ciphertext; } } }); /** * Key derivation function namespace. */ var C_kdf = C.kdf = {}; /** * OpenSSL key derivation function. */ var OpenSSLKdf = C_kdf.OpenSSL = { /** * Derives a key and IV from a password. * * @param {string} password The password to derive from. * @param {number} keySize The size in words of the key to generate. * @param {number} ivSize The size in words of the IV to generate. * @param {WordArray|string} salt (Optional) A 64-bit salt to use. If omitted, a salt will be generated randomly. * * @return {CipherParams} A cipher params object with the key, IV, and salt. * * @static * * @example * * var derivedParams = CryptoJS.kdf.OpenSSL.execute('Password', 256/32, 128/32); * var derivedParams = CryptoJS.kdf.OpenSSL.execute('Password', 256/32, 128/32, 'saltsalt'); */ execute: function (password, keySize, ivSize, salt) { // Generate random salt if (!salt) { salt = WordArray.random(64/8); } // Derive key and IV var key = EvpKDF.create({ keySize: keySize + ivSize }).compute(password, salt); // Separate key and IV var iv = WordArray.create(key.words.slice(keySize), ivSize * 4); key.sigBytes = keySize * 4; // Return params return CipherParams.create({ key: key, iv: iv, salt: salt }); } }; /** * A serializable cipher wrapper that derives the key from a password, * and returns ciphertext as a serializable cipher params object. */ var PasswordBasedCipher = C_lib.PasswordBasedCipher = SerializableCipher.extend({ /** * Configuration options. * * @property {KDF} kdf The key derivation function to use to generate a key and IV from a password. Default: OpenSSL */ cfg: SerializableCipher.cfg.extend({ kdf: OpenSSLKdf }), /** * Encrypts a message using a password. * * @param {Cipher} cipher The cipher algorithm to use. * @param {WordArray|string} message The message to encrypt. * @param {string} password The password. * @param {Object} cfg (Optional) The configuration options to use for this operation. * * @return {CipherParams} A cipher params object. * * @static * * @example * * var ciphertextParams = CryptoJS.lib.PasswordBasedCipher.encrypt(CryptoJS.algo.AES, message, 'password'); * var ciphertextParams = CryptoJS.lib.PasswordBasedCipher.encrypt(CryptoJS.algo.AES, message, 'password', { format: CryptoJS.format.OpenSSL }); */ encrypt: function (cipher, message, password, cfg) { // Apply config defaults cfg = this.cfg.extend(cfg); // Derive key and other params var derivedParams = cfg.kdf.execute(password, cipher.keySize, cipher.ivSize); // Add IV to config cfg.iv = derivedParams.iv; // Encrypt var ciphertext = SerializableCipher.encrypt.call(this, cipher, message, derivedParams.key, cfg); // Mix in derived params ciphertext.mixIn(derivedParams); return ciphertext; }, /** * Decrypts serialized ciphertext using a password. * * @param {Cipher} cipher The cipher algorithm to use. * @param {CipherParams|string} ciphertext The ciphertext to decrypt. * @param {string} password The password. * @param {Object} cfg (Optional) The configuration options to use for this operation. * * @return {WordArray} The plaintext. * * @static * * @example * * var plaintext = CryptoJS.lib.PasswordBasedCipher.decrypt(CryptoJS.algo.AES, formattedCiphertext, 'password', { format: CryptoJS.format.OpenSSL }); * var plaintext = CryptoJS.lib.PasswordBasedCipher.decrypt(CryptoJS.algo.AES, ciphertextParams, 'password', { format: CryptoJS.format.OpenSSL }); */ decrypt: function (cipher, ciphertext, password, cfg) { // Apply config defaults cfg = this.cfg.extend(cfg); // Convert string to CipherParams ciphertext = this._parse(ciphertext, cfg.format); // Derive key and other params var derivedParams = cfg.kdf.execute(password, cipher.keySize, cipher.ivSize, ciphertext.salt); // Add IV to config cfg.iv = derivedParams.iv; // Decrypt var plaintext = SerializableCipher.decrypt.call(this, cipher, ciphertext, derivedParams.key, cfg); return plaintext; } }); }()); })); },{"./core":31}],31:[function(_dereq_,module,exports){ ;(function (root, factory) { if (typeof exports === "object") { // CommonJS module.exports = exports = factory(); } else if (typeof define === "function" && define.amd) { // AMD define([], factory); } else { // Global (browser) root.CryptoJS = factory(); } }(this, function () { /** * CryptoJS core components. */ var CryptoJS = CryptoJS || (function (Math, undefined) { /** * CryptoJS namespace. */ var C = {}; /** * Library namespace. */ var C_lib = C.lib = {}; /** * Base object for prototypal inheritance. */ var Base = C_lib.Base = (function () { function F() {} return { /** * Creates a new object that inherits from this object. * * @param {Object} overrides Properties to copy into the new object. * * @return {Object} The new object. * * @static * * @example * * var MyType = CryptoJS.lib.Base.extend({ * field: 'value', * * method: function () { * } * }); */ extend: function (overrides) { // Spawn F.prototype = this; var subtype = new F(); // Augment if (overrides) { subtype.mixIn(overrides); } // Create default initializer if (!subtype.hasOwnProperty('init')) { subtype.init = function () { subtype.$super.init.apply(this, arguments); }; } // Initializer's prototype is the subtype object subtype.init.prototype = subtype; // Reference supertype subtype.$super = this; return subtype; }, /** * Extends this object and runs the init method. * Arguments to create() will be passed to init(). * * @return {Object} The new object. * * @static * * @example * * var instance = MyType.create(); */ create: function () { var instance = this.extend(); instance.init.apply(instance, arguments); return instance; }, /** * Initializes a newly created object. * Override this method to add some logic when your objects are created. * * @example * * var MyType = CryptoJS.lib.Base.extend({ * init: function () { * // ... * } * }); */ init: function () { }, /** * Copies properties into this object. * * @param {Object} properties The properties to mix in. * * @example * * MyType.mixIn({ * field: 'value' * }); */ mixIn: function (properties) { for (var propertyName in properties) { if (properties.hasOwnProperty(propertyName)) { this[propertyName] = properties[propertyName]; } } // IE won't copy toString using the loop above if (properties.hasOwnProperty('toString')) { this.toString = properties.toString; } }, /** * Creates a copy of this object. * * @return {Object} The clone. * * @example * * var clone = instance.clone(); */ clone: function () { return this.init.prototype.extend(this); } }; }()); /** * An array of 32-bit words. * * @property {Array} words The array of 32-bit words. * @property {number} sigBytes The number of significant bytes in this word array. */ var WordArray = C_lib.WordArray = Base.extend({ /** * Initializes a newly created word array. * * @param {Array} words (Optional) An array of 32-bit words. * @param {number} sigBytes (Optional) The number of significant bytes in the words. * * @example * * var wordArray = CryptoJS.lib.WordArray.create(); * var wordArray = CryptoJS.lib.WordArray.create([0x00010203, 0x04050607]); * var wordArray = CryptoJS.lib.WordArray.create([0x00010203, 0x04050607], 6); */ init: function (words, sigBytes) { words = this.words = words || []; if (sigBytes != undefined) { this.sigBytes = sigBytes; } else { this.sigBytes = words.length * 4; } }, /** * Converts this word array to a string. * * @param {Encoder} encoder (Optional) The encoding strategy to use. Default: CryptoJS.enc.Hex * * @return {string} The stringified word array. * * @example * * var string = wordArray + ''; * var string = wordArray.toString(); * var string = wordArray.toString(CryptoJS.enc.Utf8); */ toString: function (encoder) { return (encoder || Hex).stringify(this); }, /** * Concatenates a word array to this word array. * * @param {WordArray} wordArray The word array to append. * * @return {WordArray} This word array. * * @example * * wordArray1.concat(wordArray2); */ concat: function (wordArray) { // Shortcuts var thisWords = this.words; var thatWords = wordArray.words; var thisSigBytes = this.sigBytes; var thatSigBytes = wordArray.sigBytes; // Clamp excess bits this.clamp(); // Concat if (thisSigBytes % 4) { // Copy one byte at a time for (var i = 0; i < thatSigBytes; i++) { var thatByte = (thatWords[i >>> 2] >>> (24 - (i % 4) * 8)) & 0xff; thisWords[(thisSigBytes + i) >>> 2] |= thatByte << (24 - ((thisSigBytes + i) % 4) * 8); } } else if (thatWords.length > 0xffff) { // Copy one word at a time for (var i = 0; i < thatSigBytes; i += 4) { thisWords[(thisSigBytes + i) >>> 2] = thatWords[i >>> 2]; } } else { // Copy all words at once thisWords.push.apply(thisWords, thatWords); } this.sigBytes += thatSigBytes; // Chainable return this; }, /** * Removes insignificant bits. * * @example * * wordArray.clamp(); */ clamp: function () { // Shortcuts var words = this.words; var sigBytes = this.sigBytes; // Clamp words[sigBytes >>> 2] &= 0xffffffff << (32 - (sigBytes % 4) * 8); words.length = Math.ceil(sigBytes / 4); }, /** * Creates a copy of this word array. * * @return {WordArray} The clone. * * @example * * var clone = wordArray.clone(); */ clone: function () { var clone = Base.clone.call(this); clone.words = this.words.slice(0); return clone; }, /** * Creates a word array filled with random bytes. * * @param {number} nBytes The number of random bytes to generate. * * @return {WordArray} The random word array. * * @static * * @example * * var wordArray = CryptoJS.lib.WordArray.random(16); */ random: function (nBytes) { var words = []; for (var i = 0; i < nBytes; i += 4) { words.push((Math.random() * 0x100000000) | 0); } return new WordArray.init(words, nBytes); } }); /** * Encoder namespace. */ var C_enc = C.enc = {}; /** * Hex encoding strategy. */ var Hex = C_enc.Hex = { /** * Converts a word array to a hex string. * * @param {WordArray} wordArray The word array. * * @return {string} The hex string. * * @static * * @example * * var hexString = CryptoJS.enc.Hex.stringify(wordArray); */ stringify: function (wordArray) { // Shortcuts var words = wordArray.words; var sigBytes = wordArray.sigBytes; // Convert var hexChars = []; for (var i = 0; i < sigBytes; i++) { var bite = (words[i >>> 2] >>> (24 - (i % 4) * 8)) & 0xff; hexChars.push((bite >>> 4).toString(16)); hexChars.push((bite & 0x0f).toString(16)); } return hexChars.join(''); }, /** * Converts a hex string to a word array. * * @param {string} hexStr The hex string. * * @return {WordArray} The word array. * * @static * * @example * * var wordArray = CryptoJS.enc.Hex.parse(hexString); */ parse: function (hexStr) { // Shortcut var hexStrLength = hexStr.length; // Convert var words = []; for (var i = 0; i < hexStrLength; i += 2) { words[i >>> 3] |= parseInt(hexStr.substr(i, 2), 16) << (24 - (i % 8) * 4); } return new WordArray.init(words, hexStrLength / 2); } }; /** * Latin1 encoding strategy. */ var Latin1 = C_enc.Latin1 = { /** * Converts a word array to a Latin1 string. * * @param {WordArray} wordArray The word array. * * @return {string} The Latin1 string. * * @static * * @example * * var latin1String = CryptoJS.enc.Latin1.stringify(wordArray); */ stringify: function (wordArray) { // Shortcuts var words = wordArray.words; var sigBytes = wordArray.sigBytes; // Convert var latin1Chars = []; for (var i = 0; i < sigBytes; i++) { var bite = (words[i >>> 2] >>> (24 - (i % 4) * 8)) & 0xff; latin1Chars.push(String.fromCharCode(bite)); } return latin1Chars.join(''); }, /** * Converts a Latin1 string to a word array. * * @param {string} latin1Str The Latin1 string. * * @return {WordArray} The word array. * * @static * * @example * * var wordArray = CryptoJS.enc.Latin1.parse(latin1String); */ parse: function (latin1Str) { // Shortcut var latin1StrLength = latin1Str.length; // Convert var words = []; for (var i = 0; i < latin1StrLength; i++) { words[i >>> 2] |= (latin1Str.charCodeAt(i) & 0xff) << (24 - (i % 4) * 8); } return new WordArray.init(words, latin1StrLength); } }; /** * UTF-8 encoding strategy. */ var Utf8 = C_enc.Utf8 = { /** * Converts a word array to a UTF-8 string. * * @param {WordArray} wordArray The word array. * * @return {string} The UTF-8 string. * * @static * * @example * * var utf8String = CryptoJS.enc.Utf8.stringify(wordArray); */ stringify: function (wordArray) { try { return decodeURIComponent(escape(Latin1.stringify(wordArray))); } catch (e) { throw new Error('Malformed UTF-8 data'); } }, /** * Converts a UTF-8 string to a word array. * * @param {string} utf8Str The UTF-8 string. * * @return {WordArray} The word array. * * @static * * @example * * var wordArray = CryptoJS.enc.Utf8.parse(utf8String); */ parse: function (utf8Str) { return Latin1.parse(unescape(encodeURIComponent(utf8Str))); } }; /** * Abstract buffered block algorithm template. * * The property blockSize must be implemented in a concrete subtype. * * @property {number} _minBufferSize The number of blocks that should be kept unprocessed in the buffer. Default: 0 */ var BufferedBlockAlgorithm = C_lib.BufferedBlockAlgorithm = Base.extend({ /** * Resets this block algorithm's data buffer to its initial state. * * @example * * bufferedBlockAlgorithm.reset(); */ reset: function () { // Initial values this._data = new WordArray.init(); this._nDataBytes = 0; }, /** * Adds new data to this block algorithm's buffer. * * @param {WordArray|string} data The data to append. Strings are converted to a WordArray using UTF-8. * * @example * * bufferedBlockAlgorithm._append('data'); * bufferedBlockAlgorithm._append(wordArray); */ _append: function (data) { // Convert string to WordArray, else assume WordArray already if (typeof data == 'string') { data = Utf8.parse(data); } // Append this._data.concat(data); this._nDataBytes += data.sigBytes; }, /** * Processes available data blocks. * * This method invokes _doProcessBlock(offset), which must be implemented by a concrete subtype. * * @param {boolean} doFlush Whether all blocks and partial blocks should be processed. * * @return {WordArray} The processed data. * * @example * * var processedData = bufferedBlockAlgorithm._process(); * var processedData = bufferedBlockAlgorithm._process(!!'flush'); */ _process: function (doFlush) { // Shortcuts var data = this._data; var dataWords = data.words; var dataSigBytes = data.sigBytes; var blockSize = this.blockSize; var blockSizeBytes = blockSize * 4; // Count blocks ready var nBlocksReady = dataSigBytes / blockSizeBytes; if (doFlush) { // Round up to include partial blocks nBlocksReady = Math.ceil(nBlocksReady); } else { // Round down to include only full blocks, // less the number of blocks that must remain in the buffer nBlocksReady = Math.max((nBlocksReady | 0) - this._minBufferSize, 0); } // Count words ready var nWordsReady = nBlocksReady * blockSize; // Count bytes ready var nBytesReady = Math.min(nWordsReady * 4, dataSigBytes); // Process blocks if (nWordsReady) { for (var offset = 0; offset < nWordsReady; offset += blockSize) { // Perform concrete-algorithm logic this._doProcessBlock(dataWords, offset); } // Remove processed words var processedWords = dataWords.splice(0, nWordsReady); data.sigBytes -= nBytesReady; } // Return processed words return new WordArray.init(processedWords, nBytesReady); }, /** * Creates a copy of this object. * * @return {Object} The clone. * * @example * * var clone = bufferedBlockAlgorithm.clone(); */ clone: function () { var clone = Base.clone.call(this); clone._data = this._data.clone(); return clone; }, _minBufferSize: 0 }); /** * Abstract hasher template. * * @property {number} blockSize The number of 32-bit words this hasher operates on. Default: 16 (512 bits) */ var Hasher = C_lib.Hasher = BufferedBlockAlgorithm.extend({ /** * Configuration options. */ cfg: Base.extend(), /** * Initializes a newly created hasher. * * @param {Object} cfg (Optional) The configuration options to use for this hash computation. * * @example * * var hasher = CryptoJS.algo.SHA256.create(); */ init: function (cfg) { // Apply config defaults this.cfg = this.cfg.extend(cfg); // Set initial values this.reset(); }, /** * Resets this hasher to its initial state. * * @example * * hasher.reset(); */ reset: function () { // Reset data buffer BufferedBlockAlgorithm.reset.call(this); // Perform concrete-hasher logic this._doReset(); }, /** * Updates this hasher with a message. * * @param {WordArray|string} messageUpdate The message to append. * * @return {Hasher} This hasher. * * @example * * hasher.update('message'); * hasher.update(wordArray); */ update: function (messageUpdate) { // Append this._append(messageUpdate); // Update the hash this._process(); // Chainable return this; }, /** * Finalizes the hash computation. * Note that the finalize operation is effectively a destructive, read-once operation. * * @param {WordArray|string} messageUpdate (Optional) A final message update. * * @return {WordArray} The hash. * * @example * * var hash = hasher.finalize(); * var hash = hasher.finalize('message'); * var hash = hasher.finalize(wordArray); */ finalize: function (messageUpdate) { // Final message update if (messageUpdate) { this._append(messageUpdate); } // Perform concrete-hasher logic var hash = this._doFinalize(); return hash; }, blockSize: 512/32, /** * Creates a shortcut function to a hasher's object interface. * * @param {Hasher} hasher The hasher to create a helper for. * * @return {Function} The shortcut function. * * @static * * @example * * var SHA256 = CryptoJS.lib.Hasher._createHelper(CryptoJS.algo.SHA256); */ _createHelper: function (hasher) { return function (message, cfg) { return new hasher.init(cfg).finalize(message); }; }, /** * Creates a shortcut function to the HMAC's object interface. * * @param {Hasher} hasher The hasher to use in this HMAC helper. * * @return {Function} The shortcut function. * * @static * * @example * * var HmacSHA256 = CryptoJS.lib.Hasher._createHmacHelper(CryptoJS.algo.SHA256); */ _createHmacHelper: function (hasher) { return function (message, key) { return new C_algo.HMAC.init(hasher, key).finalize(message); }; } }); /** * Algorithm namespace. */ var C_algo = C.algo = {}; return C; }(Math)); return CryptoJS; })); },{}],32:[function(_dereq_,module,exports){ ;(function (root, factory) { if (typeof exports === "object") { // CommonJS module.exports = exports = factory(_dereq_("./core")); } else if (typeof define === "function" && define.amd) { // AMD define(["./core"], factory); } else { // Global (browser) factory(root.CryptoJS); } }(this, function (CryptoJS) { (function () { // Shortcuts var C = CryptoJS; var C_lib = C.lib; var WordArray = C_lib.WordArray; var C_enc = C.enc; /** * Base64 encoding strategy. */ var Base64 = C_enc.Base64 = { /** * Converts a word array to a Base64 string. * * @param {WordArray} wordArray The word array. * * @return {string} The Base64 string. * * @static * * @example * * var base64String = CryptoJS.enc.Base64.stringify(wordArray); */ stringify: function (wordArray) { // Shortcuts var words = wordArray.words; var sigBytes = wordArray.sigBytes; var map = this._map; // Clamp excess bits wordArray.clamp(); // Convert var base64Chars = []; for (var i = 0; i < sigBytes; i += 3) { var byte1 = (words[i >>> 2] >>> (24 - (i % 4) * 8)) & 0xff; var byte2 = (words[(i + 1) >>> 2] >>> (24 - ((i + 1) % 4) * 8)) & 0xff; var byte3 = (words[(i + 2) >>> 2] >>> (24 - ((i + 2) % 4) * 8)) & 0xff; var triplet = (byte1 << 16) | (byte2 << 8) | byte3; for (var j = 0; (j < 4) && (i + j * 0.75 < sigBytes); j++) { base64Chars.push(map.charAt((triplet >>> (6 * (3 - j))) & 0x3f)); } } // Add padding var paddingChar = map.charAt(64); if (paddingChar) { while (base64Chars.length % 4) { base64Chars.push(paddingChar); } } return base64Chars.join(''); }, /** * Converts a Base64 string to a word array. * * @param {string} base64Str The Base64 string. * * @return {WordArray} The word array. * * @static * * @example * * var wordArray = CryptoJS.enc.Base64.parse(base64String); */ parse: function (base64Str) { // Shortcuts var base64StrLength = base64Str.length; var map = this._map; // Ignore padding var paddingChar = map.charAt(64); if (paddingChar) { var paddingIndex = base64Str.indexOf(paddingChar); if (paddingIndex != -1) { base64StrLength = paddingIndex; } } // Convert var words = []; var nBytes = 0; for (var i = 0; i < base64StrLength; i++) { if (i % 4) { var bits1 = map.indexOf(base64Str.charAt(i - 1)) << ((i % 4) * 2); var bits2 = map.indexOf(base64Str.charAt(i)) >>> (6 - (i % 4) * 2); words[nBytes >>> 2] |= (bits1 | bits2) << (24 - (nBytes % 4) * 8); nBytes++; } } return WordArray.create(words, nBytes); }, _map: 'ABCDEFGHIJKLMNOPQRSTUVWXYZabcdefghijklmnopqrstuvwxyz0123456789+/=' }; }()); return CryptoJS.enc.Base64; })); },{"./core":31}],33:[function(_dereq_,module,exports){ ;(function (root, factory) { if (typeof exports === "object") { // CommonJS module.exports = exports = factory(_dereq_("./core")); } else if (typeof define === "function" && define.amd) { // AMD define(["./core"], factory); } else { // Global (browser) factory(root.CryptoJS); } }(this, function (CryptoJS) { (function () { // Shortcuts var C = CryptoJS; var C_lib = C.lib; var WordArray = C_lib.WordArray; var C_enc = C.enc; /** * UTF-16 BE encoding strategy. */ var Utf16BE = C_enc.Utf16 = C_enc.Utf16BE = { /** * Converts a word array to a UTF-16 BE string. * * @param {WordArray} wordArray The word array. * * @return {string} The UTF-16 BE string. * * @static * * @example * * var utf16String = CryptoJS.enc.Utf16.stringify(wordArray); */ stringify: function (wordArray) { // Shortcuts var words = wordArray.words; var sigBytes = wordArray.sigBytes; // Convert var utf16Chars = []; for (var i = 0; i < sigBytes; i += 2) { var codePoint = (words[i >>> 2] >>> (16 - (i % 4) * 8)) & 0xffff; utf16Chars.push(String.fromCharCode(codePoint)); } return utf16Chars.join(''); }, /** * Converts a UTF-16 BE string to a word array. * * @param {string} utf16Str The UTF-16 BE string. * * @return {WordArray} The word array. * * @static * * @example * * var wordArray = CryptoJS.enc.Utf16.parse(utf16String); */ parse: function (utf16Str) { // Shortcut var utf16StrLength = utf16Str.length; // Convert var words = []; for (var i = 0; i < utf16StrLength; i++) { words[i >>> 1] |= utf16Str.charCodeAt(i) << (16 - (i % 2) * 16); } return WordArray.create(words, utf16StrLength * 2); } }; /** * UTF-16 LE encoding strategy. */ C_enc.Utf16LE = { /** * Converts a word array to a UTF-16 LE string. * * @param {WordArray} wordArray The word array. * * @return {string} The UTF-16 LE string. * * @static * * @example * * var utf16Str = CryptoJS.enc.Utf16LE.stringify(wordArray); */ stringify: function (wordArray) { // Shortcuts var words = wordArray.words; var sigBytes = wordArray.sigBytes; // Convert var utf16Chars = []; for (var i = 0; i < sigBytes; i += 2) { var codePoint = swapEndian((words[i >>> 2] >>> (16 - (i % 4) * 8)) & 0xffff); utf16Chars.push(String.fromCharCode(codePoint)); } return utf16Chars.join(''); }, /** * Converts a UTF-16 LE string to a word array. * * @param {string} utf16Str The UTF-16 LE string. * * @return {WordArray} The word array. * * @static * * @example * * var wordArray = CryptoJS.enc.Utf16LE.parse(utf16Str); */ parse: function (utf16Str) { // Shortcut var utf16StrLength = utf16Str.length; // Convert var words = []; for (var i = 0; i < utf16StrLength; i++) { words[i >>> 1] |= swapEndian(utf16Str.charCodeAt(i) << (16 - (i % 2) * 16)); } return WordArray.create(words, utf16StrLength * 2); } }; function swapEndian(word) { return ((word << 8) & 0xff00ff00) | ((word >>> 8) & 0x00ff00ff); } }()); return CryptoJS.enc.Utf16; })); },{"./core":31}],34:[function(_dereq_,module,exports){ ;(function (root, factory, undef) { if (typeof exports === "object") { // CommonJS module.exports = exports = factory(_dereq_("./core"), _dereq_("./sha1"), _dereq_("./hmac")); } else if (typeof define === "function" && define.amd) { // AMD define(["./core", "./sha1", "./hmac"], factory); } else { // Global (browser) factory(root.CryptoJS); } }(this, function (CryptoJS) { (function () { // Shortcuts var C = CryptoJS; var C_lib = C.lib; var Base = C_lib.Base; var WordArray = C_lib.WordArray; var C_algo = C.algo; var MD5 = C_algo.MD5; /** * This key derivation function is meant to conform with EVP_BytesToKey. * www.openssl.org/docs/crypto/EVP_BytesToKey.html */ var EvpKDF = C_algo.EvpKDF = Base.extend({ /** * Configuration options. * * @property {number} keySize The key size in words to generate. Default: 4 (128 bits) * @property {Hasher} hasher The hash algorithm to use. Default: MD5 * @property {number} iterations The number of iterations to perform. Default: 1 */ cfg: Base.extend({ keySize: 128/32, hasher: MD5, iterations: 1 }), /** * Initializes a newly created key derivation function. * * @param {Object} cfg (Optional) The configuration options to use for the derivation. * * @example * * var kdf = CryptoJS.algo.EvpKDF.create(); * var kdf = CryptoJS.algo.EvpKDF.create({ keySize: 8 }); * var kdf = CryptoJS.algo.EvpKDF.create({ keySize: 8, iterations: 1000 }); */ init: function (cfg) { this.cfg = this.cfg.extend(cfg); }, /** * Derives a key from a password. * * @param {WordArray|string} password The password. * @param {WordArray|string} salt A salt. * * @return {WordArray} The derived key. * * @example * * var key = kdf.compute(password, salt); */ compute: function (password, salt) { // Shortcut var cfg = this.cfg; // Init hasher var hasher = cfg.hasher.create(); // Initial values var derivedKey = WordArray.create(); // Shortcuts var derivedKeyWords = derivedKey.words; var keySize = cfg.keySize; var iterations = cfg.iterations; // Generate key while (derivedKeyWords.length < keySize) { if (block) { hasher.update(block); } var block = hasher.update(password).finalize(salt); hasher.reset(); // Iterations for (var i = 1; i < iterations; i++) { block = hasher.finalize(block); hasher.reset(); } derivedKey.concat(block); } derivedKey.sigBytes = keySize * 4; return derivedKey; } }); /** * Derives a key from a password. * * @param {WordArray|string} password The password. * @param {WordArray|string} salt A salt. * @param {Object} cfg (Optional) The configuration options to use for this computation. * * @return {WordArray} The derived key. * * @static * * @example * * var key = CryptoJS.EvpKDF(password, salt); * var key = CryptoJS.EvpKDF(password, salt, { keySize: 8 }); * var key = CryptoJS.EvpKDF(password, salt, { keySize: 8, iterations: 1000 }); */ C.EvpKDF = function (password, salt, cfg) { return EvpKDF.create(cfg).compute(password, salt); }; }()); return CryptoJS.EvpKDF; })); },{"./core":31,"./hmac":36,"./sha1":55}],35:[function(_dereq_,module,exports){ ;(function (root, factory, undef) { if (typeof exports === "object") { // CommonJS module.exports = exports = factory(_dereq_("./core"), _dereq_("./cipher-core")); } else if (typeof define === "function" && define.amd) { // AMD define(["./core", "./cipher-core"], factory); } else { // Global (browser) factory(root.CryptoJS); } }(this, function (CryptoJS) { (function (undefined) { // Shortcuts var C = CryptoJS; var C_lib = C.lib; var CipherParams = C_lib.CipherParams; var C_enc = C.enc; var Hex = C_enc.Hex; var C_format = C.format; var HexFormatter = C_format.Hex = { /** * Converts the ciphertext of a cipher params object to a hexadecimally encoded string. * * @param {CipherParams} cipherParams The cipher params object. * * @return {string} The hexadecimally encoded string. * * @static * * @example * * var hexString = CryptoJS.format.Hex.stringify(cipherParams); */ stringify: function (cipherParams) { return cipherParams.ciphertext.toString(Hex); }, /** * Converts a hexadecimally encoded ciphertext string to a cipher params object. * * @param {string} input The hexadecimally encoded string. * * @return {CipherParams} The cipher params object. * * @static * * @example * * var cipherParams = CryptoJS.format.Hex.parse(hexString); */ parse: function (input) { var ciphertext = Hex.parse(input); return CipherParams.create({ ciphertext: ciphertext }); } }; }()); return CryptoJS.format.Hex; })); },{"./cipher-core":30,"./core":31}],36:[function(_dereq_,module,exports){ ;(function (root, factory) { if (typeof exports === "object") { // CommonJS module.exports = exports = factory(_dereq_("./core")); } else if (typeof define === "function" && define.amd) { // AMD define(["./core"], factory); } else { // Global (browser) factory(root.CryptoJS); } }(this, function (CryptoJS) { (function () { // Shortcuts var C = CryptoJS; var C_lib = C.lib; var Base = C_lib.Base; var C_enc = C.enc; var Utf8 = C_enc.Utf8; var C_algo = C.algo; /** * HMAC algorithm. */ var HMAC = C_algo.HMAC = Base.extend({ /** * Initializes a newly created HMAC. * * @param {Hasher} hasher The hash algorithm to use. * @param {WordArray|string} key The secret key. * * @example * * var hmacHasher = CryptoJS.algo.HMAC.create(CryptoJS.algo.SHA256, key); */ init: function (hasher, key) { // Init hasher hasher = this._hasher = new hasher.init(); // Convert string to WordArray, else assume WordArray already if (typeof key == 'string') { key = Utf8.parse(key); } // Shortcuts var hasherBlockSize = hasher.blockSize; var hasherBlockSizeBytes = hasherBlockSize * 4; // Allow arbitrary length keys if (key.sigBytes > hasherBlockSizeBytes) { key = hasher.finalize(key); } // Clamp excess bits key.clamp(); // Clone key for inner and outer pads var oKey = this._oKey = key.clone(); var iKey = this._iKey = key.clone(); // Shortcuts var oKeyWords = oKey.words; var iKeyWords = iKey.words; // XOR keys with pad constants for (var i = 0; i < hasherBlockSize; i++) { oKeyWords[i] ^= 0x5c5c5c5c; iKeyWords[i] ^= 0x36363636; } oKey.sigBytes = iKey.sigBytes = hasherBlockSizeBytes; // Set initial values this.reset(); }, /** * Resets this HMAC to its initial state. * * @example * * hmacHasher.reset(); */ reset: function () { // Shortcut var hasher = this._hasher; // Reset hasher.reset(); hasher.update(this._iKey); }, /** * Updates this HMAC with a message. * * @param {WordArray|string} messageUpdate The message to append. * * @return {HMAC} This HMAC instance. * * @example * * hmacHasher.update('message'); * hmacHasher.update(wordArray); */ update: function (messageUpdate) { this._hasher.update(messageUpdate); // Chainable return this; }, /** * Finalizes the HMAC computation. * Note that the finalize operation is effectively a destructive, read-once operation. * * @param {WordArray|string} messageUpdate (Optional) A final message update. * * @return {WordArray} The HMAC. * * @example * * var hmac = hmacHasher.finalize(); * var hmac = hmacHasher.finalize('message'); * var hmac = hmacHasher.finalize(wordArray); */ finalize: function (messageUpdate) { // Shortcut var hasher = this._hasher; // Compute HMAC var innerHash = hasher.finalize(messageUpdate); hasher.reset(); var hmac = hasher.finalize(this._oKey.clone().concat(innerHash)); return hmac; } }); }()); })); },{"./core":31}],37:[function(_dereq_,module,exports){ ;(function (root, factory, undef) { if (typeof exports === "object") { // CommonJS module.exports = exports = factory(_dereq_("./core"), _dereq_("./x64-core"), _dereq_("./lib-typedarrays"), _dereq_("./enc-utf16"), _dereq_("./enc-base64"), _dereq_("./md5"), _dereq_("./sha1"), _dereq_("./sha256"), _dereq_("./sha224"), _dereq_("./sha512"), _dereq_("./sha384"), _dereq_("./sha3"), _dereq_("./ripemd160"), _dereq_("./hmac"), _dereq_("./pbkdf2"), _dereq_("./evpkdf"), _dereq_("./cipher-core"), _dereq_("./mode-cfb"), _dereq_("./mode-ctr"), _dereq_("./mode-ctr-gladman"), _dereq_("./mode-ofb"), _dereq_("./mode-ecb"), _dereq_("./pad-ansix923"), _dereq_("./pad-iso10126"), _dereq_("./pad-iso97971"), _dereq_("./pad-zeropadding"), _dereq_("./pad-nopadding"), _dereq_("./format-hex"), _dereq_("./aes"), _dereq_("./tripledes"), _dereq_("./rc4"), _dereq_("./rabbit"), _dereq_("./rabbit-legacy")); } else if (typeof define === "function" && define.amd) { // AMD define(["./core", "./x64-core", "./lib-typedarrays", "./enc-utf16", "./enc-base64", "./md5", "./sha1", "./sha256", "./sha224", "./sha512", "./sha384", "./sha3", "./ripemd160", "./hmac", "./pbkdf2", "./evpkdf", "./cipher-core", "./mode-cfb", "./mode-ctr", "./mode-ctr-gladman", "./mode-ofb", "./mode-ecb", "./pad-ansix923", "./pad-iso10126", "./pad-iso97971", "./pad-zeropadding", "./pad-nopadding", "./format-hex", "./aes", "./tripledes", "./rc4", "./rabbit", "./rabbit-legacy"], factory); } else { // Global (browser) factory(root.CryptoJS); } }(this, function (CryptoJS) { return CryptoJS; })); },{"./aes":29,"./cipher-core":30,"./core":31,"./enc-base64":32,"./enc-utf16":33,"./evpkdf":34,"./format-hex":35,"./hmac":36,"./lib-typedarrays":38,"./md5":39,"./mode-cfb":40,"./mode-ctr":42,"./mode-ctr-gladman":41,"./mode-ecb":43,"./mode-ofb":44,"./pad-ansix923":45,"./pad-iso10126":46,"./pad-iso97971":47,"./pad-nopadding":48,"./pad-zeropadding":49,"./pbkdf2":50,"./rabbit":52,"./rabbit-legacy":51,"./rc4":53,"./ripemd160":54,"./sha1":55,"./sha224":56,"./sha256":57,"./sha3":58,"./sha384":59,"./sha512":60,"./tripledes":61,"./x64-core":62}],38:[function(_dereq_,module,exports){ ;(function (root, factory) { if (typeof exports === "object") { // CommonJS module.exports = exports = factory(_dereq_("./core")); } else if (typeof define === "function" && define.amd) { // AMD define(["./core"], factory); } else { // Global (browser) factory(root.CryptoJS); } }(this, function (CryptoJS) { (function () { // Check if typed arrays are supported if (typeof ArrayBuffer != 'function') { return; } // Shortcuts var C = CryptoJS; var C_lib = C.lib; var WordArray = C_lib.WordArray; // Reference original init var superInit = WordArray.init; // Augment WordArray.init to handle typed arrays var subInit = WordArray.init = function (typedArray) { // Convert buffers to uint8 if (typedArray instanceof ArrayBuffer) { typedArray = new Uint8Array(typedArray); } // Convert other array views to uint8 if ( typedArray instanceof Int8Array || typedArray instanceof Uint8ClampedArray || typedArray instanceof Int16Array || typedArray instanceof Uint16Array || typedArray instanceof Int32Array || typedArray instanceof Uint32Array || typedArray instanceof Float32Array || typedArray instanceof Float64Array ) { typedArray = new Uint8Array(typedArray.buffer, typedArray.byteOffset, typedArray.byteLength); } // Handle Uint8Array if (typedArray instanceof Uint8Array) { // Shortcut var typedArrayByteLength = typedArray.byteLength; // Extract bytes var words = []; for (var i = 0; i < typedArrayByteLength; i++) { words[i >>> 2] |= typedArray[i] << (24 - (i % 4) * 8); } // Initialize this word array superInit.call(this, words, typedArrayByteLength); } else { // Else call normal init superInit.apply(this, arguments); } }; subInit.prototype = WordArray; }()); return CryptoJS.lib.WordArray; })); },{"./core":31}],39:[function(_dereq_,module,exports){ ;(function (root, factory) { if (typeof exports === "object") { // CommonJS module.exports = exports = factory(_dereq_("./core")); } else if (typeof define === "function" && define.amd) { // AMD define(["./core"], factory); } else { // Global (browser) factory(root.CryptoJS); } }(this, function (CryptoJS) { (function (Math) { // Shortcuts var C = CryptoJS; var C_lib = C.lib; var WordArray = C_lib.WordArray; var Hasher = C_lib.Hasher; var C_algo = C.algo; // Constants table var T = []; // Compute constants (function () { for (var i = 0; i < 64; i++) { T[i] = (Math.abs(Math.sin(i + 1)) * 0x100000000) | 0; } }()); /** * MD5 hash algorithm. */ var MD5 = C_algo.MD5 = Hasher.extend({ _doReset: function () { this._hash = new WordArray.init([ 0x67452301, 0xefcdab89, 0x98badcfe, 0x10325476 ]); }, _doProcessBlock: function (M, offset) { // Swap endian for (var i = 0; i < 16; i++) { // Shortcuts var offset_i = offset + i; var M_offset_i = M[offset_i]; M[offset_i] = ( (((M_offset_i << 8) | (M_offset_i >>> 24)) & 0x00ff00ff) | (((M_offset_i << 24) | (M_offset_i >>> 8)) & 0xff00ff00) ); } // Shortcuts var H = this._hash.words; var M_offset_0 = M[offset + 0]; var M_offset_1 = M[offset + 1]; var M_offset_2 = M[offset + 2]; var M_offset_3 = M[offset + 3]; var M_offset_4 = M[offset + 4]; var M_offset_5 = M[offset + 5]; var M_offset_6 = M[offset + 6]; var M_offset_7 = M[offset + 7]; var M_offset_8 = M[offset + 8]; var M_offset_9 = M[offset + 9]; var M_offset_10 = M[offset + 10]; var M_offset_11 = M[offset + 11]; var M_offset_12 = M[offset + 12]; var M_offset_13 = M[offset + 13]; var M_offset_14 = M[offset + 14]; var M_offset_15 = M[offset + 15]; // Working varialbes var a = H[0]; var b = H[1]; var c = H[2]; var d = H[3]; // Computation a = FF(a, b, c, d, M_offset_0, 7, T[0]); d = FF(d, a, b, c, M_offset_1, 12, T[1]); c = FF(c, d, a, b, M_offset_2, 17, T[2]); b = FF(b, c, d, a, M_offset_3, 22, T[3]); a = FF(a, b, c, d, M_offset_4, 7, T[4]); d = FF(d, a, b, c, M_offset_5, 12, T[5]); c = FF(c, d, a, b, M_offset_6, 17, T[6]); b = FF(b, c, d, a, M_offset_7, 22, T[7]); a = FF(a, b, c, d, M_offset_8, 7, T[8]); d = FF(d, a, b, c, M_offset_9, 12, T[9]); c = FF(c, d, a, b, M_offset_10, 17, T[10]); b = FF(b, c, d, a, M_offset_11, 22, T[11]); a = FF(a, b, c, d, M_offset_12, 7, T[12]); d = FF(d, a, b, c, M_offset_13, 12, T[13]); c = FF(c, d, a, b, M_offset_14, 17, T[14]); b = FF(b, c, d, a, M_offset_15, 22, T[15]); a = GG(a, b, c, d, M_offset_1, 5, T[16]); d = GG(d, a, b, c, M_offset_6, 9, T[17]); c = GG(c, d, a, b, M_offset_11, 14, T[18]); b = GG(b, c, d, a, M_offset_0, 20, T[19]); a = GG(a, b, c, d, M_offset_5, 5, T[20]); d = GG(d, a, b, c, M_offset_10, 9, T[21]); c = GG(c, d, a, b, M_offset_15, 14, T[22]); b = GG(b, c, d, a, M_offset_4, 20, T[23]); a = GG(a, b, c, d, M_offset_9, 5, T[24]); d = GG(d, a, b, c, M_offset_14, 9, T[25]); c = GG(c, d, a, b, M_offset_3, 14, T[26]); b = GG(b, c, d, a, M_offset_8, 20, T[27]); a = GG(a, b, c, d, M_offset_13, 5, T[28]); d = GG(d, a, b, c, M_offset_2, 9, T[29]); c = GG(c, d, a, b, M_offset_7, 14, T[30]); b = GG(b, c, d, a, M_offset_12, 20, T[31]); a = HH(a, b, c, d, M_offset_5, 4, T[32]); d = HH(d, a, b, c, M_offset_8, 11, T[33]); c = HH(c, d, a, b, M_offset_11, 16, T[34]); b = HH(b, c, d, a, M_offset_14, 23, T[35]); a = HH(a, b, c, d, M_offset_1, 4, T[36]); d = HH(d, a, b, c, M_offset_4, 11, T[37]); c = HH(c, d, a, b, M_offset_7, 16, T[38]); b = HH(b, c, d, a, M_offset_10, 23, T[39]); a = HH(a, b, c, d, M_offset_13, 4, T[40]); d = HH(d, a, b, c, M_offset_0, 11, T[41]); c = HH(c, d, a, b, M_offset_3, 16, T[42]); b = HH(b, c, d, a, M_offset_6, 23, T[43]); a = HH(a, b, c, d, M_offset_9, 4, T[44]); d = HH(d, a, b, c, M_offset_12, 11, T[45]); c = HH(c, d, a, b, M_offset_15, 16, T[46]); b = HH(b, c, d, a, M_offset_2, 23, T[47]); a = II(a, b, c, d, M_offset_0, 6, T[48]); d = II(d, a, b, c, M_offset_7, 10, T[49]); c = II(c, d, a, b, M_offset_14, 15, T[50]); b = II(b, c, d, a, M_offset_5, 21, T[51]); a = II(a, b, c, d, M_offset_12, 6, T[52]); d = II(d, a, b, c, M_offset_3, 10, T[53]); c = II(c, d, a, b, M_offset_10, 15, T[54]); b = II(b, c, d, a, M_offset_1, 21, T[55]); a = II(a, b, c, d, M_offset_8, 6, T[56]); d = II(d, a, b, c, M_offset_15, 10, T[57]); c = II(c, d, a, b, M_offset_6, 15, T[58]); b = II(b, c, d, a, M_offset_13, 21, T[59]); a = II(a, b, c, d, M_offset_4, 6, T[60]); d = II(d, a, b, c, M_offset_11, 10, T[61]); c = II(c, d, a, b, M_offset_2, 15, T[62]); b = II(b, c, d, a, M_offset_9, 21, T[63]); // Intermediate hash value H[0] = (H[0] + a) | 0; H[1] = (H[1] + b) | 0; H[2] = (H[2] + c) | 0; H[3] = (H[3] + d) | 0; }, _doFinalize: function () { // Shortcuts var data = this._data; var dataWords = data.words; var nBitsTotal = this._nDataBytes * 8; var nBitsLeft = data.sigBytes * 8; // Add padding dataWords[nBitsLeft >>> 5] |= 0x80 << (24 - nBitsLeft % 32); var nBitsTotalH = Math.floor(nBitsTotal / 0x100000000); var nBitsTotalL = nBitsTotal; dataWords[(((nBitsLeft + 64) >>> 9) << 4) + 15] = ( (((nBitsTotalH << 8) | (nBitsTotalH >>> 24)) & 0x00ff00ff) | (((nBitsTotalH << 24) | (nBitsTotalH >>> 8)) & 0xff00ff00) ); dataWords[(((nBitsLeft + 64) >>> 9) << 4) + 14] = ( (((nBitsTotalL << 8) | (nBitsTotalL >>> 24)) & 0x00ff00ff) | (((nBitsTotalL << 24) | (nBitsTotalL >>> 8)) & 0xff00ff00) ); data.sigBytes = (dataWords.length + 1) * 4; // Hash final blocks this._process(); // Shortcuts var hash = this._hash; var H = hash.words; // Swap endian for (var i = 0; i < 4; i++) { // Shortcut var H_i = H[i]; H[i] = (((H_i << 8) | (H_i >>> 24)) & 0x00ff00ff) | (((H_i << 24) | (H_i >>> 8)) & 0xff00ff00); } // Return final computed hash return hash; }, clone: function () { var clone = Hasher.clone.call(this); clone._hash = this._hash.clone(); return clone; } }); function FF(a, b, c, d, x, s, t) { var n = a + ((b & c) | (~b & d)) + x + t; return ((n << s) | (n >>> (32 - s))) + b; } function GG(a, b, c, d, x, s, t) { var n = a + ((b & d) | (c & ~d)) + x + t; return ((n << s) | (n >>> (32 - s))) + b; } function HH(a, b, c, d, x, s, t) { var n = a + (b ^ c ^ d) + x + t; return ((n << s) | (n >>> (32 - s))) + b; } function II(a, b, c, d, x, s, t) { var n = a + (c ^ (b | ~d)) + x + t; return ((n << s) | (n >>> (32 - s))) + b; } /** * Shortcut function to the hasher's object interface. * * @param {WordArray|string} message The message to hash. * * @return {WordArray} The hash. * * @static * * @example * * var hash = CryptoJS.MD5('message'); * var hash = CryptoJS.MD5(wordArray); */ C.MD5 = Hasher._createHelper(MD5); /** * Shortcut function to the HMAC's object interface. * * @param {WordArray|string} message The message to hash. * @param {WordArray|string} key The secret key. * * @return {WordArray} The HMAC. * * @static * * @example * * var hmac = CryptoJS.HmacMD5(message, key); */ C.HmacMD5 = Hasher._createHmacHelper(MD5); }(Math)); return CryptoJS.MD5; })); },{"./core":31}],40:[function(_dereq_,module,exports){ ;(function (root, factory, undef) { if (typeof exports === "object") { // CommonJS module.exports = exports = factory(_dereq_("./core"), _dereq_("./cipher-core")); } else if (typeof define === "function" && define.amd) { // AMD define(["./core", "./cipher-core"], factory); } else { // Global (browser) factory(root.CryptoJS); } }(this, function (CryptoJS) { /** * Cipher Feedback block mode. */ CryptoJS.mode.CFB = (function () { var CFB = CryptoJS.lib.BlockCipherMode.extend(); CFB.Encryptor = CFB.extend({ processBlock: function (words, offset) { // Shortcuts var cipher = this._cipher; var blockSize = cipher.blockSize; generateKeystreamAndEncrypt.call(this, words, offset, blockSize, cipher); // Remember this block to use with next block this._prevBlock = words.slice(offset, offset + blockSize); } }); CFB.Decryptor = CFB.extend({ processBlock: function (words, offset) { // Shortcuts var cipher = this._cipher; var blockSize = cipher.blockSize; // Remember this block to use with next block var thisBlock = words.slice(offset, offset + blockSize); generateKeystreamAndEncrypt.call(this, words, offset, blockSize, cipher); // This block becomes the previous block this._prevBlock = thisBlock; } }); function generateKeystreamAndEncrypt(words, offset, blockSize, cipher) { // Shortcut var iv = this._iv; // Generate keystream if (iv) { var keystream = iv.slice(0); // Remove IV for subsequent blocks this._iv = undefined; } else { var keystream = this._prevBlock; } cipher.encryptBlock(keystream, 0); // Encrypt for (var i = 0; i < blockSize; i++) { words[offset + i] ^= keystream[i]; } } return CFB; }()); return CryptoJS.mode.CFB; })); },{"./cipher-core":30,"./core":31}],41:[function(_dereq_,module,exports){ ;(function (root, factory, undef) { if (typeof exports === "object") { // CommonJS module.exports = exports = factory(_dereq_("./core"), _dereq_("./cipher-core")); } else if (typeof define === "function" && define.amd) { // AMD define(["./core", "./cipher-core"], factory); } else { // Global (browser) factory(root.CryptoJS); } }(this, function (CryptoJS) { /** @preserve * Counter block mode compatible with Dr Brian Gladman fileenc.c * derived from CryptoJS.mode.CTR * Jan Hruby jhruby.web@gmail.com */ CryptoJS.mode.CTRGladman = (function () { var CTRGladman = CryptoJS.lib.BlockCipherMode.extend(); function incWord(word) { if (((word >> 24) & 0xff) === 0xff) { //overflow var b1 = (word >> 16)&0xff; var b2 = (word >> 8)&0xff; var b3 = word & 0xff; if (b1 === 0xff) // overflow b1 { b1 = 0; if (b2 === 0xff) { b2 = 0; if (b3 === 0xff) { b3 = 0; } else { ++b3; } } else { ++b2; } } else { ++b1; } word = 0; word += (b1 << 16); word += (b2 << 8); word += b3; } else { word += (0x01 << 24); } return word; } function incCounter(counter) { if ((counter[0] = incWord(counter[0])) === 0) { // encr_data in fileenc.c from Dr Brian Gladman's counts only with DWORD j < 8 counter[1] = incWord(counter[1]); } return counter; } var Encryptor = CTRGladman.Encryptor = CTRGladman.extend({ processBlock: function (words, offset) { // Shortcuts var cipher = this._cipher var blockSize = cipher.blockSize; var iv = this._iv; var counter = this._counter; // Generate keystream if (iv) { counter = this._counter = iv.slice(0); // Remove IV for subsequent blocks this._iv = undefined; } incCounter(counter); var keystream = counter.slice(0); cipher.encryptBlock(keystream, 0); // Encrypt for (var i = 0; i < blockSize; i++) { words[offset + i] ^= keystream[i]; } } }); CTRGladman.Decryptor = Encryptor; return CTRGladman; }()); return CryptoJS.mode.CTRGladman; })); },{"./cipher-core":30,"./core":31}],42:[function(_dereq_,module,exports){ ;(function (root, factory, undef) { if (typeof exports === "object") { // CommonJS module.exports = exports = factory(_dereq_("./core"), _dereq_("./cipher-core")); } else if (typeof define === "function" && define.amd) { // AMD define(["./core", "./cipher-core"], factory); } else { // Global (browser) factory(root.CryptoJS); } }(this, function (CryptoJS) { /** * Counter block mode. */ CryptoJS.mode.CTR = (function () { var CTR = CryptoJS.lib.BlockCipherMode.extend(); var Encryptor = CTR.Encryptor = CTR.extend({ processBlock: function (words, offset) { // Shortcuts var cipher = this._cipher var blockSize = cipher.blockSize; var iv = this._iv; var counter = this._counter; // Generate keystream if (iv) { counter = this._counter = iv.slice(0); // Remove IV for subsequent blocks this._iv = undefined; } var keystream = counter.slice(0); cipher.encryptBlock(keystream, 0); // Increment counter counter[blockSize - 1] = (counter[blockSize - 1] + 1) | 0 // Encrypt for (var i = 0; i < blockSize; i++) { words[offset + i] ^= keystream[i]; } } }); CTR.Decryptor = Encryptor; return CTR; }()); return CryptoJS.mode.CTR; })); },{"./cipher-core":30,"./core":31}],43:[function(_dereq_,module,exports){ ;(function (root, factory, undef) { if (typeof exports === "object") { // CommonJS module.exports = exports = factory(_dereq_("./core"), _dereq_("./cipher-core")); } else if (typeof define === "function" && define.amd) { // AMD define(["./core", "./cipher-core"], factory); } else { // Global (browser) factory(root.CryptoJS); } }(this, function (CryptoJS) { /** * Electronic Codebook block mode. */ CryptoJS.mode.ECB = (function () { var ECB = CryptoJS.lib.BlockCipherMode.extend(); ECB.Encryptor = ECB.extend({ processBlock: function (words, offset) { this._cipher.encryptBlock(words, offset); } }); ECB.Decryptor = ECB.extend({ processBlock: function (words, offset) { this._cipher.decryptBlock(words, offset); } }); return ECB; }()); return CryptoJS.mode.ECB; })); },{"./cipher-core":30,"./core":31}],44:[function(_dereq_,module,exports){ ;(function (root, factory, undef) { if (typeof exports === "object") { // CommonJS module.exports = exports = factory(_dereq_("./core"), _dereq_("./cipher-core")); } else if (typeof define === "function" && define.amd) { // AMD define(["./core", "./cipher-core"], factory); } else { // Global (browser) factory(root.CryptoJS); } }(this, function (CryptoJS) { /** * Output Feedback block mode. */ CryptoJS.mode.OFB = (function () { var OFB = CryptoJS.lib.BlockCipherMode.extend(); var Encryptor = OFB.Encryptor = OFB.extend({ processBlock: function (words, offset) { // Shortcuts var cipher = this._cipher var blockSize = cipher.blockSize; var iv = this._iv; var keystream = this._keystream; // Generate keystream if (iv) { keystream = this._keystream = iv.slice(0); // Remove IV for subsequent blocks this._iv = undefined; } cipher.encryptBlock(keystream, 0); // Encrypt for (var i = 0; i < blockSize; i++) { words[offset + i] ^= keystream[i]; } } }); OFB.Decryptor = Encryptor; return OFB; }()); return CryptoJS.mode.OFB; })); },{"./cipher-core":30,"./core":31}],45:[function(_dereq_,module,exports){ ;(function (root, factory, undef) { if (typeof exports === "object") { // CommonJS module.exports = exports = factory(_dereq_("./core"), _dereq_("./cipher-core")); } else if (typeof define === "function" && define.amd) { // AMD define(["./core", "./cipher-core"], factory); } else { // Global (browser) factory(root.CryptoJS); } }(this, function (CryptoJS) { /** * ANSI X.923 padding strategy. */ CryptoJS.pad.AnsiX923 = { pad: function (data, blockSize) { // Shortcuts var dataSigBytes = data.sigBytes; var blockSizeBytes = blockSize * 4; // Count padding bytes var nPaddingBytes = blockSizeBytes - dataSigBytes % blockSizeBytes; // Compute last byte position var lastBytePos = dataSigBytes + nPaddingBytes - 1; // Pad data.clamp(); data.words[lastBytePos >>> 2] |= nPaddingBytes << (24 - (lastBytePos % 4) * 8); data.sigBytes += nPaddingBytes; }, unpad: function (data) { // Get number of padding bytes from last byte var nPaddingBytes = data.words[(data.sigBytes - 1) >>> 2] & 0xff; // Remove padding data.sigBytes -= nPaddingBytes; } }; return CryptoJS.pad.Ansix923; })); },{"./cipher-core":30,"./core":31}],46:[function(_dereq_,module,exports){ ;(function (root, factory, undef) { if (typeof exports === "object") { // CommonJS module.exports = exports = factory(_dereq_("./core"), _dereq_("./cipher-core")); } else if (typeof define === "function" && define.amd) { // AMD define(["./core", "./cipher-core"], factory); } else { // Global (browser) factory(root.CryptoJS); } }(this, function (CryptoJS) { /** * ISO 10126 padding strategy. */ CryptoJS.pad.Iso10126 = { pad: function (data, blockSize) { // Shortcut var blockSizeBytes = blockSize * 4; // Count padding bytes var nPaddingBytes = blockSizeBytes - data.sigBytes % blockSizeBytes; // Pad data.concat(CryptoJS.lib.WordArray.random(nPaddingBytes - 1)). concat(CryptoJS.lib.WordArray.create([nPaddingBytes << 24], 1)); }, unpad: function (data) { // Get number of padding bytes from last byte var nPaddingBytes = data.words[(data.sigBytes - 1) >>> 2] & 0xff; // Remove padding data.sigBytes -= nPaddingBytes; } }; return CryptoJS.pad.Iso10126; })); },{"./cipher-core":30,"./core":31}],47:[function(_dereq_,module,exports){ ;(function (root, factory, undef) { if (typeof exports === "object") { // CommonJS module.exports = exports = factory(_dereq_("./core"), _dereq_("./cipher-core")); } else if (typeof define === "function" && define.amd) { // AMD define(["./core", "./cipher-core"], factory); } else { // Global (browser) factory(root.CryptoJS); } }(this, function (CryptoJS) { /** * ISO/IEC 9797-1 Padding Method 2. */ CryptoJS.pad.Iso97971 = { pad: function (data, blockSize) { // Add 0x80 byte data.concat(CryptoJS.lib.WordArray.create([0x80000000], 1)); // Zero pad the rest CryptoJS.pad.ZeroPadding.pad(data, blockSize); }, unpad: function (data) { // Remove zero padding CryptoJS.pad.ZeroPadding.unpad(data); // Remove one more byte -- the 0x80 byte data.sigBytes--; } }; return CryptoJS.pad.Iso97971; })); },{"./cipher-core":30,"./core":31}],48:[function(_dereq_,module,exports){ ;(function (root, factory, undef) { if (typeof exports === "object") { // CommonJS module.exports = exports = factory(_dereq_("./core"), _dereq_("./cipher-core")); } else if (typeof define === "function" && define.amd) { // AMD define(["./core", "./cipher-core"], factory); } else { // Global (browser) factory(root.CryptoJS); } }(this, function (CryptoJS) { /** * A noop padding strategy. */ CryptoJS.pad.NoPadding = { pad: function () { }, unpad: function () { } }; return CryptoJS.pad.NoPadding; })); },{"./cipher-core":30,"./core":31}],49:[function(_dereq_,module,exports){ ;(function (root, factory, undef) { if (typeof exports === "object") { // CommonJS module.exports = exports = factory(_dereq_("./core"), _dereq_("./cipher-core")); } else if (typeof define === "function" && define.amd) { // AMD define(["./core", "./cipher-core"], factory); } else { // Global (browser) factory(root.CryptoJS); } }(this, function (CryptoJS) { /** * Zero padding strategy. */ CryptoJS.pad.ZeroPadding = { pad: function (data, blockSize) { // Shortcut var blockSizeBytes = blockSize * 4; // Pad data.clamp(); data.sigBytes += blockSizeBytes - ((data.sigBytes % blockSizeBytes) || blockSizeBytes); }, unpad: function (data) { // Shortcut var dataWords = data.words; // Unpad var i = data.sigBytes - 1; while (!((dataWords[i >>> 2] >>> (24 - (i % 4) * 8)) & 0xff)) { i--; } data.sigBytes = i + 1; } }; return CryptoJS.pad.ZeroPadding; })); },{"./cipher-core":30,"./core":31}],50:[function(_dereq_,module,exports){ ;(function (root, factory, undef) { if (typeof exports === "object") { // CommonJS module.exports = exports = factory(_dereq_("./core"), _dereq_("./sha1"), _dereq_("./hmac")); } else if (typeof define === "function" && define.amd) { // AMD define(["./core", "./sha1", "./hmac"], factory); } else { // Global (browser) factory(root.CryptoJS); } }(this, function (CryptoJS) { (function () { // Shortcuts var C = CryptoJS; var C_lib = C.lib; var Base = C_lib.Base; var WordArray = C_lib.WordArray; var C_algo = C.algo; var SHA1 = C_algo.SHA1; var HMAC = C_algo.HMAC; /** * Password-Based Key Derivation Function 2 algorithm. */ var PBKDF2 = C_algo.PBKDF2 = Base.extend({ /** * Configuration options. * * @property {number} keySize The key size in words to generate. Default: 4 (128 bits) * @property {Hasher} hasher The hasher to use. Default: SHA1 * @property {number} iterations The number of iterations to perform. Default: 1 */ cfg: Base.extend({ keySize: 128/32, hasher: SHA1, iterations: 1 }), /** * Initializes a newly created key derivation function. * * @param {Object} cfg (Optional) The configuration options to use for the derivation. * * @example * * var kdf = CryptoJS.algo.PBKDF2.create(); * var kdf = CryptoJS.algo.PBKDF2.create({ keySize: 8 }); * var kdf = CryptoJS.algo.PBKDF2.create({ keySize: 8, iterations: 1000 }); */ init: function (cfg) { this.cfg = this.cfg.extend(cfg); }, /** * Computes the Password-Based Key Derivation Function 2. * * @param {WordArray|string} password The password. * @param {WordArray|string} salt A salt. * * @return {WordArray} The derived key. * * @example * * var key = kdf.compute(password, salt); */ compute: function (password, salt) { // Shortcut var cfg = this.cfg; // Init HMAC var hmac = HMAC.create(cfg.hasher, password); // Initial values var derivedKey = WordArray.create(); var blockIndex = WordArray.create([0x00000001]); // Shortcuts var derivedKeyWords = derivedKey.words; var blockIndexWords = blockIndex.words; var keySize = cfg.keySize; var iterations = cfg.iterations; // Generate key while (derivedKeyWords.length < keySize) { var block = hmac.update(salt).finalize(blockIndex); hmac.reset(); // Shortcuts var blockWords = block.words; var blockWordsLength = blockWords.length; // Iterations var intermediate = block; for (var i = 1; i < iterations; i++) { intermediate = hmac.finalize(intermediate); hmac.reset(); // Shortcut var intermediateWords = intermediate.words; // XOR intermediate with block for (var j = 0; j < blockWordsLength; j++) { blockWords[j] ^= intermediateWords[j]; } } derivedKey.concat(block); blockIndexWords[0]++; } derivedKey.sigBytes = keySize * 4; return derivedKey; } }); /** * Computes the Password-Based Key Derivation Function 2. * * @param {WordArray|string} password The password. * @param {WordArray|string} salt A salt. * @param {Object} cfg (Optional) The configuration options to use for this computation. * * @return {WordArray} The derived key. * * @static * * @example * * var key = CryptoJS.PBKDF2(password, salt); * var key = CryptoJS.PBKDF2(password, salt, { keySize: 8 }); * var key = CryptoJS.PBKDF2(password, salt, { keySize: 8, iterations: 1000 }); */ C.PBKDF2 = function (password, salt, cfg) { return PBKDF2.create(cfg).compute(password, salt); }; }()); return CryptoJS.PBKDF2; })); },{"./core":31,"./hmac":36,"./sha1":55}],51:[function(_dereq_,module,exports){ ;(function (root, factory, undef) { if (typeof exports === "object") { // CommonJS module.exports = exports = factory(_dereq_("./core"), _dereq_("./enc-base64"), _dereq_("./md5"), _dereq_("./evpkdf"), _dereq_("./cipher-core")); } else if (typeof define === "function" && define.amd) { // AMD define(["./core", "./enc-base64", "./md5", "./evpkdf", "./cipher-core"], factory); } else { // Global (browser) factory(root.CryptoJS); } }(this, function (CryptoJS) { (function () { // Shortcuts var C = CryptoJS; var C_lib = C.lib; var StreamCipher = C_lib.StreamCipher; var C_algo = C.algo; // Reusable objects var S = []; var C_ = []; var G = []; /** * Rabbit stream cipher algorithm. * * This is a legacy version that neglected to convert the key to little-endian. * This error doesn't affect the cipher's security, * but it does affect its compatibility with other implementations. */ var RabbitLegacy = C_algo.RabbitLegacy = StreamCipher.extend({ _doReset: function () { // Shortcuts var K = this._key.words; var iv = this.cfg.iv; // Generate initial state values var X = this._X = [ K[0], (K[3] << 16) | (K[2] >>> 16), K[1], (K[0] << 16) | (K[3] >>> 16), K[2], (K[1] << 16) | (K[0] >>> 16), K[3], (K[2] << 16) | (K[1] >>> 16) ]; // Generate initial counter values var C = this._C = [ (K[2] << 16) | (K[2] >>> 16), (K[0] & 0xffff0000) | (K[1] & 0x0000ffff), (K[3] << 16) | (K[3] >>> 16), (K[1] & 0xffff0000) | (K[2] & 0x0000ffff), (K[0] << 16) | (K[0] >>> 16), (K[2] & 0xffff0000) | (K[3] & 0x0000ffff), (K[1] << 16) | (K[1] >>> 16), (K[3] & 0xffff0000) | (K[0] & 0x0000ffff) ]; // Carry bit this._b = 0; // Iterate the system four times for (var i = 0; i < 4; i++) { nextState.call(this); } // Modify the counters for (var i = 0; i < 8; i++) { C[i] ^= X[(i + 4) & 7]; } // IV setup if (iv) { // Shortcuts var IV = iv.words; var IV_0 = IV[0]; var IV_1 = IV[1]; // Generate four subvectors var i0 = (((IV_0 << 8) | (IV_0 >>> 24)) & 0x00ff00ff) | (((IV_0 << 24) | (IV_0 >>> 8)) & 0xff00ff00); var i2 = (((IV_1 << 8) | (IV_1 >>> 24)) & 0x00ff00ff) | (((IV_1 << 24) | (IV_1 >>> 8)) & 0xff00ff00); var i1 = (i0 >>> 16) | (i2 & 0xffff0000); var i3 = (i2 << 16) | (i0 & 0x0000ffff); // Modify counter values C[0] ^= i0; C[1] ^= i1; C[2] ^= i2; C[3] ^= i3; C[4] ^= i0; C[5] ^= i1; C[6] ^= i2; C[7] ^= i3; // Iterate the system four times for (var i = 0; i < 4; i++) { nextState.call(this); } } }, _doProcessBlock: function (M, offset) { // Shortcut var X = this._X; // Iterate the system nextState.call(this); // Generate four keystream words S[0] = X[0] ^ (X[5] >>> 16) ^ (X[3] << 16); S[1] = X[2] ^ (X[7] >>> 16) ^ (X[5] << 16); S[2] = X[4] ^ (X[1] >>> 16) ^ (X[7] << 16); S[3] = X[6] ^ (X[3] >>> 16) ^ (X[1] << 16); for (var i = 0; i < 4; i++) { // Swap endian S[i] = (((S[i] << 8) | (S[i] >>> 24)) & 0x00ff00ff) | (((S[i] << 24) | (S[i] >>> 8)) & 0xff00ff00); // Encrypt M[offset + i] ^= S[i]; } }, blockSize: 128/32, ivSize: 64/32 }); function nextState() { // Shortcuts var X = this._X; var C = this._C; // Save old counter values for (var i = 0; i < 8; i++) { C_[i] = C[i]; } // Calculate new counter values C[0] = (C[0] + 0x4d34d34d + this._b) | 0; C[1] = (C[1] + 0xd34d34d3 + ((C[0] >>> 0) < (C_[0] >>> 0) ? 1 : 0)) | 0; C[2] = (C[2] + 0x34d34d34 + ((C[1] >>> 0) < (C_[1] >>> 0) ? 1 : 0)) | 0; C[3] = (C[3] + 0x4d34d34d + ((C[2] >>> 0) < (C_[2] >>> 0) ? 1 : 0)) | 0; C[4] = (C[4] + 0xd34d34d3 + ((C[3] >>> 0) < (C_[3] >>> 0) ? 1 : 0)) | 0; C[5] = (C[5] + 0x34d34d34 + ((C[4] >>> 0) < (C_[4] >>> 0) ? 1 : 0)) | 0; C[6] = (C[6] + 0x4d34d34d + ((C[5] >>> 0) < (C_[5] >>> 0) ? 1 : 0)) | 0; C[7] = (C[7] + 0xd34d34d3 + ((C[6] >>> 0) < (C_[6] >>> 0) ? 1 : 0)) | 0; this._b = (C[7] >>> 0) < (C_[7] >>> 0) ? 1 : 0; // Calculate the g-values for (var i = 0; i < 8; i++) { var gx = X[i] + C[i]; // Construct high and low argument for squaring var ga = gx & 0xffff; var gb = gx >>> 16; // Calculate high and low result of squaring var gh = ((((ga * ga) >>> 17) + ga * gb) >>> 15) + gb * gb; var gl = (((gx & 0xffff0000) * gx) | 0) + (((gx & 0x0000ffff) * gx) | 0); // High XOR low G[i] = gh ^ gl; } // Calculate new state values X[0] = (G[0] + ((G[7] << 16) | (G[7] >>> 16)) + ((G[6] << 16) | (G[6] >>> 16))) | 0; X[1] = (G[1] + ((G[0] << 8) | (G[0] >>> 24)) + G[7]) | 0; X[2] = (G[2] + ((G[1] << 16) | (G[1] >>> 16)) + ((G[0] << 16) | (G[0] >>> 16))) | 0; X[3] = (G[3] + ((G[2] << 8) | (G[2] >>> 24)) + G[1]) | 0; X[4] = (G[4] + ((G[3] << 16) | (G[3] >>> 16)) + ((G[2] << 16) | (G[2] >>> 16))) | 0; X[5] = (G[5] + ((G[4] << 8) | (G[4] >>> 24)) + G[3]) | 0; X[6] = (G[6] + ((G[5] << 16) | (G[5] >>> 16)) + ((G[4] << 16) | (G[4] >>> 16))) | 0; X[7] = (G[7] + ((G[6] << 8) | (G[6] >>> 24)) + G[5]) | 0; } /** * Shortcut functions to the cipher's object interface. * * @example * * var ciphertext = CryptoJS.RabbitLegacy.encrypt(message, key, cfg); * var plaintext = CryptoJS.RabbitLegacy.decrypt(ciphertext, key, cfg); */ C.RabbitLegacy = StreamCipher._createHelper(RabbitLegacy); }()); return CryptoJS.RabbitLegacy; })); },{"./cipher-core":30,"./core":31,"./enc-base64":32,"./evpkdf":34,"./md5":39}],52:[function(_dereq_,module,exports){ ;(function (root, factory, undef) { if (typeof exports === "object") { // CommonJS module.exports = exports = factory(_dereq_("./core"), _dereq_("./enc-base64"), _dereq_("./md5"), _dereq_("./evpkdf"), _dereq_("./cipher-core")); } else if (typeof define === "function" && define.amd) { // AMD define(["./core", "./enc-base64", "./md5", "./evpkdf", "./cipher-core"], factory); } else { // Global (browser) factory(root.CryptoJS); } }(this, function (CryptoJS) { (function () { // Shortcuts var C = CryptoJS; var C_lib = C.lib; var StreamCipher = C_lib.StreamCipher; var C_algo = C.algo; // Reusable objects var S = []; var C_ = []; var G = []; /** * Rabbit stream cipher algorithm */ var Rabbit = C_algo.Rabbit = StreamCipher.extend({ _doReset: function () { // Shortcuts var K = this._key.words; var iv = this.cfg.iv; // Swap endian for (var i = 0; i < 4; i++) { K[i] = (((K[i] << 8) | (K[i] >>> 24)) & 0x00ff00ff) | (((K[i] << 24) | (K[i] >>> 8)) & 0xff00ff00); } // Generate initial state values var X = this._X = [ K[0], (K[3] << 16) | (K[2] >>> 16), K[1], (K[0] << 16) | (K[3] >>> 16), K[2], (K[1] << 16) | (K[0] >>> 16), K[3], (K[2] << 16) | (K[1] >>> 16) ]; // Generate initial counter values var C = this._C = [ (K[2] << 16) | (K[2] >>> 16), (K[0] & 0xffff0000) | (K[1] & 0x0000ffff), (K[3] << 16) | (K[3] >>> 16), (K[1] & 0xffff0000) | (K[2] & 0x0000ffff), (K[0] << 16) | (K[0] >>> 16), (K[2] & 0xffff0000) | (K[3] & 0x0000ffff), (K[1] << 16) | (K[1] >>> 16), (K[3] & 0xffff0000) | (K[0] & 0x0000ffff) ]; // Carry bit this._b = 0; // Iterate the system four times for (var i = 0; i < 4; i++) { nextState.call(this); } // Modify the counters for (var i = 0; i < 8; i++) { C[i] ^= X[(i + 4) & 7]; } // IV setup if (iv) { // Shortcuts var IV = iv.words; var IV_0 = IV[0]; var IV_1 = IV[1]; // Generate four subvectors var i0 = (((IV_0 << 8) | (IV_0 >>> 24)) & 0x00ff00ff) | (((IV_0 << 24) | (IV_0 >>> 8)) & 0xff00ff00); var i2 = (((IV_1 << 8) | (IV_1 >>> 24)) & 0x00ff00ff) | (((IV_1 << 24) | (IV_1 >>> 8)) & 0xff00ff00); var i1 = (i0 >>> 16) | (i2 & 0xffff0000); var i3 = (i2 << 16) | (i0 & 0x0000ffff); // Modify counter values C[0] ^= i0; C[1] ^= i1; C[2] ^= i2; C[3] ^= i3; C[4] ^= i0; C[5] ^= i1; C[6] ^= i2; C[7] ^= i3; // Iterate the system four times for (var i = 0; i < 4; i++) { nextState.call(this); } } }, _doProcessBlock: function (M, offset) { // Shortcut var X = this._X; // Iterate the system nextState.call(this); // Generate four keystream words S[0] = X[0] ^ (X[5] >>> 16) ^ (X[3] << 16); S[1] = X[2] ^ (X[7] >>> 16) ^ (X[5] << 16); S[2] = X[4] ^ (X[1] >>> 16) ^ (X[7] << 16); S[3] = X[6] ^ (X[3] >>> 16) ^ (X[1] << 16); for (var i = 0; i < 4; i++) { // Swap endian S[i] = (((S[i] << 8) | (S[i] >>> 24)) & 0x00ff00ff) | (((S[i] << 24) | (S[i] >>> 8)) & 0xff00ff00); // Encrypt M[offset + i] ^= S[i]; } }, blockSize: 128/32, ivSize: 64/32 }); function nextState() { // Shortcuts var X = this._X; var C = this._C; // Save old counter values for (var i = 0; i < 8; i++) { C_[i] = C[i]; } // Calculate new counter values C[0] = (C[0] + 0x4d34d34d + this._b) | 0; C[1] = (C[1] + 0xd34d34d3 + ((C[0] >>> 0) < (C_[0] >>> 0) ? 1 : 0)) | 0; C[2] = (C[2] + 0x34d34d34 + ((C[1] >>> 0) < (C_[1] >>> 0) ? 1 : 0)) | 0; C[3] = (C[3] + 0x4d34d34d + ((C[2] >>> 0) < (C_[2] >>> 0) ? 1 : 0)) | 0; C[4] = (C[4] + 0xd34d34d3 + ((C[3] >>> 0) < (C_[3] >>> 0) ? 1 : 0)) | 0; C[5] = (C[5] + 0x34d34d34 + ((C[4] >>> 0) < (C_[4] >>> 0) ? 1 : 0)) | 0; C[6] = (C[6] + 0x4d34d34d + ((C[5] >>> 0) < (C_[5] >>> 0) ? 1 : 0)) | 0; C[7] = (C[7] + 0xd34d34d3 + ((C[6] >>> 0) < (C_[6] >>> 0) ? 1 : 0)) | 0; this._b = (C[7] >>> 0) < (C_[7] >>> 0) ? 1 : 0; // Calculate the g-values for (var i = 0; i < 8; i++) { var gx = X[i] + C[i]; // Construct high and low argument for squaring var ga = gx & 0xffff; var gb = gx >>> 16; // Calculate high and low result of squaring var gh = ((((ga * ga) >>> 17) + ga * gb) >>> 15) + gb * gb; var gl = (((gx & 0xffff0000) * gx) | 0) + (((gx & 0x0000ffff) * gx) | 0); // High XOR low G[i] = gh ^ gl; } // Calculate new state values X[0] = (G[0] + ((G[7] << 16) | (G[7] >>> 16)) + ((G[6] << 16) | (G[6] >>> 16))) | 0; X[1] = (G[1] + ((G[0] << 8) | (G[0] >>> 24)) + G[7]) | 0; X[2] = (G[2] + ((G[1] << 16) | (G[1] >>> 16)) + ((G[0] << 16) | (G[0] >>> 16))) | 0; X[3] = (G[3] + ((G[2] << 8) | (G[2] >>> 24)) + G[1]) | 0; X[4] = (G[4] + ((G[3] << 16) | (G[3] >>> 16)) + ((G[2] << 16) | (G[2] >>> 16))) | 0; X[5] = (G[5] + ((G[4] << 8) | (G[4] >>> 24)) + G[3]) | 0; X[6] = (G[6] + ((G[5] << 16) | (G[5] >>> 16)) + ((G[4] << 16) | (G[4] >>> 16))) | 0; X[7] = (G[7] + ((G[6] << 8) | (G[6] >>> 24)) + G[5]) | 0; } /** * Shortcut functions to the cipher's object interface. * * @example * * var ciphertext = CryptoJS.Rabbit.encrypt(message, key, cfg); * var plaintext = CryptoJS.Rabbit.decrypt(ciphertext, key, cfg); */ C.Rabbit = StreamCipher._createHelper(Rabbit); }()); return CryptoJS.Rabbit; })); },{"./cipher-core":30,"./core":31,"./enc-base64":32,"./evpkdf":34,"./md5":39}],53:[function(_dereq_,module,exports){ ;(function (root, factory, undef) { if (typeof exports === "object") { // CommonJS module.exports = exports = factory(_dereq_("./core"), _dereq_("./enc-base64"), _dereq_("./md5"), _dereq_("./evpkdf"), _dereq_("./cipher-core")); } else if (typeof define === "function" && define.amd) { // AMD define(["./core", "./enc-base64", "./md5", "./evpkdf", "./cipher-core"], factory); } else { // Global (browser) factory(root.CryptoJS); } }(this, function (CryptoJS) { (function () { // Shortcuts var C = CryptoJS; var C_lib = C.lib; var StreamCipher = C_lib.StreamCipher; var C_algo = C.algo; /** * RC4 stream cipher algorithm. */ var RC4 = C_algo.RC4 = StreamCipher.extend({ _doReset: function () { // Shortcuts var key = this._key; var keyWords = key.words; var keySigBytes = key.sigBytes; // Init sbox var S = this._S = []; for (var i = 0; i < 256; i++) { S[i] = i; } // Key setup for (var i = 0, j = 0; i < 256; i++) { var keyByteIndex = i % keySigBytes; var keyByte = (keyWords[keyByteIndex >>> 2] >>> (24 - (keyByteIndex % 4) * 8)) & 0xff; j = (j + S[i] + keyByte) % 256; // Swap var t = S[i]; S[i] = S[j]; S[j] = t; } // Counters this._i = this._j = 0; }, _doProcessBlock: function (M, offset) { M[offset] ^= generateKeystreamWord.call(this); }, keySize: 256/32, ivSize: 0 }); function generateKeystreamWord() { // Shortcuts var S = this._S; var i = this._i; var j = this._j; // Generate keystream word var keystreamWord = 0; for (var n = 0; n < 4; n++) { i = (i + 1) % 256; j = (j + S[i]) % 256; // Swap var t = S[i]; S[i] = S[j]; S[j] = t; keystreamWord |= S[(S[i] + S[j]) % 256] << (24 - n * 8); } // Update counters this._i = i; this._j = j; return keystreamWord; } /** * Shortcut functions to the cipher's object interface. * * @example * * var ciphertext = CryptoJS.RC4.encrypt(message, key, cfg); * var plaintext = CryptoJS.RC4.decrypt(ciphertext, key, cfg); */ C.RC4 = StreamCipher._createHelper(RC4); /** * Modified RC4 stream cipher algorithm. */ var RC4Drop = C_algo.RC4Drop = RC4.extend({ /** * Configuration options. * * @property {number} drop The number of keystream words to drop. Default 192 */ cfg: RC4.cfg.extend({ drop: 192 }), _doReset: function () { RC4._doReset.call(this); // Drop for (var i = this.cfg.drop; i > 0; i--) { generateKeystreamWord.call(this); } } }); /** * Shortcut functions to the cipher's object interface. * * @example * * var ciphertext = CryptoJS.RC4Drop.encrypt(message, key, cfg); * var plaintext = CryptoJS.RC4Drop.decrypt(ciphertext, key, cfg); */ C.RC4Drop = StreamCipher._createHelper(RC4Drop); }()); return CryptoJS.RC4; })); },{"./cipher-core":30,"./core":31,"./enc-base64":32,"./evpkdf":34,"./md5":39}],54:[function(_dereq_,module,exports){ ;(function (root, factory) { if (typeof exports === "object") { // CommonJS module.exports = exports = factory(_dereq_("./core")); } else if (typeof define === "function" && define.amd) { // AMD define(["./core"], factory); } else { // Global (browser) factory(root.CryptoJS); } }(this, function (CryptoJS) { /** @preserve (c) 2012 by Cédric Mesnil. All rights reserved. Redistribution and use in source and binary forms, with or without modification, are permitted provided that the following conditions are met: - Redistributions of source code must retain the above copyright notice, this list of conditions and the following disclaimer. - Redistributions in binary form must reproduce the above copyright notice, this list of conditions and the following disclaimer in the documentation and/or other materials provided with the distribution. THIS SOFTWARE IS PROVIDED BY THE COPYRIGHT HOLDERS AND CONTRIBUTORS "AS IS" AND ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR PURPOSE ARE DISCLAIMED. IN NO EVENT SHALL THE COPYRIGHT HOLDER OR CONTRIBUTORS BE LIABLE FOR ANY DIRECT, INDIRECT, INCIDENTAL, SPECIAL, EXEMPLARY, OR CONSEQUENTIAL DAMAGES (INCLUDING, BUT NOT LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS OR SERVICES; LOSS OF USE, DATA, OR PROFITS; OR BUSINESS INTERRUPTION) HOWEVER CAUSED AND ON ANY THEORY OF LIABILITY, WHETHER IN CONTRACT, STRICT LIABILITY, OR TORT (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY OUT OF THE USE OF THIS SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF SUCH DAMAGE. */ (function (Math) { // Shortcuts var C = CryptoJS; var C_lib = C.lib; var WordArray = C_lib.WordArray; var Hasher = C_lib.Hasher; var C_algo = C.algo; // Constants table var _zl = WordArray.create([ 0, 1, 2, 3, 4, 5, 6, 7, 8, 9, 10, 11, 12, 13, 14, 15, 7, 4, 13, 1, 10, 6, 15, 3, 12, 0, 9, 5, 2, 14, 11, 8, 3, 10, 14, 4, 9, 15, 8, 1, 2, 7, 0, 6, 13, 11, 5, 12, 1, 9, 11, 10, 0, 8, 12, 4, 13, 3, 7, 15, 14, 5, 6, 2, 4, 0, 5, 9, 7, 12, 2, 10, 14, 1, 3, 8, 11, 6, 15, 13]); var _zr = WordArray.create([ 5, 14, 7, 0, 9, 2, 11, 4, 13, 6, 15, 8, 1, 10, 3, 12, 6, 11, 3, 7, 0, 13, 5, 10, 14, 15, 8, 12, 4, 9, 1, 2, 15, 5, 1, 3, 7, 14, 6, 9, 11, 8, 12, 2, 10, 0, 4, 13, 8, 6, 4, 1, 3, 11, 15, 0, 5, 12, 2, 13, 9, 7, 10, 14, 12, 15, 10, 4, 1, 5, 8, 7, 6, 2, 13, 14, 0, 3, 9, 11]); var _sl = WordArray.create([ 11, 14, 15, 12, 5, 8, 7, 9, 11, 13, 14, 15, 6, 7, 9, 8, 7, 6, 8, 13, 11, 9, 7, 15, 7, 12, 15, 9, 11, 7, 13, 12, 11, 13, 6, 7, 14, 9, 13, 15, 14, 8, 13, 6, 5, 12, 7, 5, 11, 12, 14, 15, 14, 15, 9, 8, 9, 14, 5, 6, 8, 6, 5, 12, 9, 15, 5, 11, 6, 8, 13, 12, 5, 12, 13, 14, 11, 8, 5, 6 ]); var _sr = WordArray.create([ 8, 9, 9, 11, 13, 15, 15, 5, 7, 7, 8, 11, 14, 14, 12, 6, 9, 13, 15, 7, 12, 8, 9, 11, 7, 7, 12, 7, 6, 15, 13, 11, 9, 7, 15, 11, 8, 6, 6, 14, 12, 13, 5, 14, 13, 13, 7, 5, 15, 5, 8, 11, 14, 14, 6, 14, 6, 9, 12, 9, 12, 5, 15, 8, 8, 5, 12, 9, 12, 5, 14, 6, 8, 13, 6, 5, 15, 13, 11, 11 ]); var _hl = WordArray.create([ 0x00000000, 0x5A827999, 0x6ED9EBA1, 0x8F1BBCDC, 0xA953FD4E]); var _hr = WordArray.create([ 0x50A28BE6, 0x5C4DD124, 0x6D703EF3, 0x7A6D76E9, 0x00000000]); /** * RIPEMD160 hash algorithm. */ var RIPEMD160 = C_algo.RIPEMD160 = Hasher.extend({ _doReset: function () { this._hash = WordArray.create([0x67452301, 0xEFCDAB89, 0x98BADCFE, 0x10325476, 0xC3D2E1F0]); }, _doProcessBlock: function (M, offset) { // Swap endian for (var i = 0; i < 16; i++) { // Shortcuts var offset_i = offset + i; var M_offset_i = M[offset_i]; // Swap M[offset_i] = ( (((M_offset_i << 8) | (M_offset_i >>> 24)) & 0x00ff00ff) | (((M_offset_i << 24) | (M_offset_i >>> 8)) & 0xff00ff00) ); } // Shortcut var H = this._hash.words; var hl = _hl.words; var hr = _hr.words; var zl = _zl.words; var zr = _zr.words; var sl = _sl.words; var sr = _sr.words; // Working variables var al, bl, cl, dl, el; var ar, br, cr, dr, er; ar = al = H[0]; br = bl = H[1]; cr = cl = H[2]; dr = dl = H[3]; er = el = H[4]; // Computation var t; for (var i = 0; i < 80; i += 1) { t = (al + M[offset+zl[i]])|0; if (i<16){ t += f1(bl,cl,dl) + hl[0]; } else if (i<32) { t += f2(bl,cl,dl) + hl[1]; } else if (i<48) { t += f3(bl,cl,dl) + hl[2]; } else if (i<64) { t += f4(bl,cl,dl) + hl[3]; } else {// if (i<80) { t += f5(bl,cl,dl) + hl[4]; } t = t|0; t = rotl(t,sl[i]); t = (t+el)|0; al = el; el = dl; dl = rotl(cl, 10); cl = bl; bl = t; t = (ar + M[offset+zr[i]])|0; if (i<16){ t += f5(br,cr,dr) + hr[0]; } else if (i<32) { t += f4(br,cr,dr) + hr[1]; } else if (i<48) { t += f3(br,cr,dr) + hr[2]; } else if (i<64) { t += f2(br,cr,dr) + hr[3]; } else {// if (i<80) { t += f1(br,cr,dr) + hr[4]; } t = t|0; t = rotl(t,sr[i]) ; t = (t+er)|0; ar = er; er = dr; dr = rotl(cr, 10); cr = br; br = t; } // Intermediate hash value t = (H[1] + cl + dr)|0; H[1] = (H[2] + dl + er)|0; H[2] = (H[3] + el + ar)|0; H[3] = (H[4] + al + br)|0; H[4] = (H[0] + bl + cr)|0; H[0] = t; }, _doFinalize: function () { // Shortcuts var data = this._data; var dataWords = data.words; var nBitsTotal = this._nDataBytes * 8; var nBitsLeft = data.sigBytes * 8; // Add padding dataWords[nBitsLeft >>> 5] |= 0x80 << (24 - nBitsLeft % 32); dataWords[(((nBitsLeft + 64) >>> 9) << 4) + 14] = ( (((nBitsTotal << 8) | (nBitsTotal >>> 24)) & 0x00ff00ff) | (((nBitsTotal << 24) | (nBitsTotal >>> 8)) & 0xff00ff00) ); data.sigBytes = (dataWords.length + 1) * 4; // Hash final blocks this._process(); // Shortcuts var hash = this._hash; var H = hash.words; // Swap endian for (var i = 0; i < 5; i++) { // Shortcut var H_i = H[i]; // Swap H[i] = (((H_i << 8) | (H_i >>> 24)) & 0x00ff00ff) | (((H_i << 24) | (H_i >>> 8)) & 0xff00ff00); } // Return final computed hash return hash; }, clone: function () { var clone = Hasher.clone.call(this); clone._hash = this._hash.clone(); return clone; } }); function f1(x, y, z) { return ((x) ^ (y) ^ (z)); } function f2(x, y, z) { return (((x)&(y)) | ((~x)&(z))); } function f3(x, y, z) { return (((x) | (~(y))) ^ (z)); } function f4(x, y, z) { return (((x) & (z)) | ((y)&(~(z)))); } function f5(x, y, z) { return ((x) ^ ((y) |(~(z)))); } function rotl(x,n) { return (x<>>(32-n)); } /** * Shortcut function to the hasher's object interface. * * @param {WordArray|string} message The message to hash. * * @return {WordArray} The hash. * * @static * * @example * * var hash = CryptoJS.RIPEMD160('message'); * var hash = CryptoJS.RIPEMD160(wordArray); */ C.RIPEMD160 = Hasher._createHelper(RIPEMD160); /** * Shortcut function to the HMAC's object interface. * * @param {WordArray|string} message The message to hash. * @param {WordArray|string} key The secret key. * * @return {WordArray} The HMAC. * * @static * * @example * * var hmac = CryptoJS.HmacRIPEMD160(message, key); */ C.HmacRIPEMD160 = Hasher._createHmacHelper(RIPEMD160); }(Math)); return CryptoJS.RIPEMD160; })); },{"./core":31}],55:[function(_dereq_,module,exports){ ;(function (root, factory) { if (typeof exports === "object") { // CommonJS module.exports = exports = factory(_dereq_("./core")); } else if (typeof define === "function" && define.amd) { // AMD define(["./core"], factory); } else { // Global (browser) factory(root.CryptoJS); } }(this, function (CryptoJS) { (function () { // Shortcuts var C = CryptoJS; var C_lib = C.lib; var WordArray = C_lib.WordArray; var Hasher = C_lib.Hasher; var C_algo = C.algo; // Reusable object var W = []; /** * SHA-1 hash algorithm. */ var SHA1 = C_algo.SHA1 = Hasher.extend({ _doReset: function () { this._hash = new WordArray.init([ 0x67452301, 0xefcdab89, 0x98badcfe, 0x10325476, 0xc3d2e1f0 ]); }, _doProcessBlock: function (M, offset) { // Shortcut var H = this._hash.words; // Working variables var a = H[0]; var b = H[1]; var c = H[2]; var d = H[3]; var e = H[4]; // Computation for (var i = 0; i < 80; i++) { if (i < 16) { W[i] = M[offset + i] | 0; } else { var n = W[i - 3] ^ W[i - 8] ^ W[i - 14] ^ W[i - 16]; W[i] = (n << 1) | (n >>> 31); } var t = ((a << 5) | (a >>> 27)) + e + W[i]; if (i < 20) { t += ((b & c) | (~b & d)) + 0x5a827999; } else if (i < 40) { t += (b ^ c ^ d) + 0x6ed9eba1; } else if (i < 60) { t += ((b & c) | (b & d) | (c & d)) - 0x70e44324; } else /* if (i < 80) */ { t += (b ^ c ^ d) - 0x359d3e2a; } e = d; d = c; c = (b << 30) | (b >>> 2); b = a; a = t; } // Intermediate hash value H[0] = (H[0] + a) | 0; H[1] = (H[1] + b) | 0; H[2] = (H[2] + c) | 0; H[3] = (H[3] + d) | 0; H[4] = (H[4] + e) | 0; }, _doFinalize: function () { // Shortcuts var data = this._data; var dataWords = data.words; var nBitsTotal = this._nDataBytes * 8; var nBitsLeft = data.sigBytes * 8; // Add padding dataWords[nBitsLeft >>> 5] |= 0x80 << (24 - nBitsLeft % 32); dataWords[(((nBitsLeft + 64) >>> 9) << 4) + 14] = Math.floor(nBitsTotal / 0x100000000); dataWords[(((nBitsLeft + 64) >>> 9) << 4) + 15] = nBitsTotal; data.sigBytes = dataWords.length * 4; // Hash final blocks this._process(); // Return final computed hash return this._hash; }, clone: function () { var clone = Hasher.clone.call(this); clone._hash = this._hash.clone(); return clone; } }); /** * Shortcut function to the hasher's object interface. * * @param {WordArray|string} message The message to hash. * * @return {WordArray} The hash. * * @static * * @example * * var hash = CryptoJS.SHA1('message'); * var hash = CryptoJS.SHA1(wordArray); */ C.SHA1 = Hasher._createHelper(SHA1); /** * Shortcut function to the HMAC's object interface. * * @param {WordArray|string} message The message to hash. * @param {WordArray|string} key The secret key. * * @return {WordArray} The HMAC. * * @static * * @example * * var hmac = CryptoJS.HmacSHA1(message, key); */ C.HmacSHA1 = Hasher._createHmacHelper(SHA1); }()); return CryptoJS.SHA1; })); },{"./core":31}],56:[function(_dereq_,module,exports){ ;(function (root, factory, undef) { if (typeof exports === "object") { // CommonJS module.exports = exports = factory(_dereq_("./core"), _dereq_("./sha256")); } else if (typeof define === "function" && define.amd) { // AMD define(["./core", "./sha256"], factory); } else { // Global (browser) factory(root.CryptoJS); } }(this, function (CryptoJS) { (function () { // Shortcuts var C = CryptoJS; var C_lib = C.lib; var WordArray = C_lib.WordArray; var C_algo = C.algo; var SHA256 = C_algo.SHA256; /** * SHA-224 hash algorithm. */ var SHA224 = C_algo.SHA224 = SHA256.extend({ _doReset: function () { this._hash = new WordArray.init([ 0xc1059ed8, 0x367cd507, 0x3070dd17, 0xf70e5939, 0xffc00b31, 0x68581511, 0x64f98fa7, 0xbefa4fa4 ]); }, _doFinalize: function () { var hash = SHA256._doFinalize.call(this); hash.sigBytes -= 4; return hash; } }); /** * Shortcut function to the hasher's object interface. * * @param {WordArray|string} message The message to hash. * * @return {WordArray} The hash. * * @static * * @example * * var hash = CryptoJS.SHA224('message'); * var hash = CryptoJS.SHA224(wordArray); */ C.SHA224 = SHA256._createHelper(SHA224); /** * Shortcut function to the HMAC's object interface. * * @param {WordArray|string} message The message to hash. * @param {WordArray|string} key The secret key. * * @return {WordArray} The HMAC. * * @static * * @example * * var hmac = CryptoJS.HmacSHA224(message, key); */ C.HmacSHA224 = SHA256._createHmacHelper(SHA224); }()); return CryptoJS.SHA224; })); },{"./core":31,"./sha256":57}],57:[function(_dereq_,module,exports){ ;(function (root, factory) { if (typeof exports === "object") { // CommonJS module.exports = exports = factory(_dereq_("./core")); } else if (typeof define === "function" && define.amd) { // AMD define(["./core"], factory); } else { // Global (browser) factory(root.CryptoJS); } }(this, function (CryptoJS) { (function (Math) { // Shortcuts var C = CryptoJS; var C_lib = C.lib; var WordArray = C_lib.WordArray; var Hasher = C_lib.Hasher; var C_algo = C.algo; // Initialization and round constants tables var H = []; var K = []; // Compute constants (function () { function isPrime(n) { var sqrtN = Math.sqrt(n); for (var factor = 2; factor <= sqrtN; factor++) { if (!(n % factor)) { return false; } } return true; } function getFractionalBits(n) { return ((n - (n | 0)) * 0x100000000) | 0; } var n = 2; var nPrime = 0; while (nPrime < 64) { if (isPrime(n)) { if (nPrime < 8) { H[nPrime] = getFractionalBits(Math.pow(n, 1 / 2)); } K[nPrime] = getFractionalBits(Math.pow(n, 1 / 3)); nPrime++; } n++; } }()); // Reusable object var W = []; /** * SHA-256 hash algorithm. */ var SHA256 = C_algo.SHA256 = Hasher.extend({ _doReset: function () { this._hash = new WordArray.init(H.slice(0)); }, _doProcessBlock: function (M, offset) { // Shortcut var H = this._hash.words; // Working variables var a = H[0]; var b = H[1]; var c = H[2]; var d = H[3]; var e = H[4]; var f = H[5]; var g = H[6]; var h = H[7]; // Computation for (var i = 0; i < 64; i++) { if (i < 16) { W[i] = M[offset + i] | 0; } else { var gamma0x = W[i - 15]; var gamma0 = ((gamma0x << 25) | (gamma0x >>> 7)) ^ ((gamma0x << 14) | (gamma0x >>> 18)) ^ (gamma0x >>> 3); var gamma1x = W[i - 2]; var gamma1 = ((gamma1x << 15) | (gamma1x >>> 17)) ^ ((gamma1x << 13) | (gamma1x >>> 19)) ^ (gamma1x >>> 10); W[i] = gamma0 + W[i - 7] + gamma1 + W[i - 16]; } var ch = (e & f) ^ (~e & g); var maj = (a & b) ^ (a & c) ^ (b & c); var sigma0 = ((a << 30) | (a >>> 2)) ^ ((a << 19) | (a >>> 13)) ^ ((a << 10) | (a >>> 22)); var sigma1 = ((e << 26) | (e >>> 6)) ^ ((e << 21) | (e >>> 11)) ^ ((e << 7) | (e >>> 25)); var t1 = h + sigma1 + ch + K[i] + W[i]; var t2 = sigma0 + maj; h = g; g = f; f = e; e = (d + t1) | 0; d = c; c = b; b = a; a = (t1 + t2) | 0; } // Intermediate hash value H[0] = (H[0] + a) | 0; H[1] = (H[1] + b) | 0; H[2] = (H[2] + c) | 0; H[3] = (H[3] + d) | 0; H[4] = (H[4] + e) | 0; H[5] = (H[5] + f) | 0; H[6] = (H[6] + g) | 0; H[7] = (H[7] + h) | 0; }, _doFinalize: function () { // Shortcuts var data = this._data; var dataWords = data.words; var nBitsTotal = this._nDataBytes * 8; var nBitsLeft = data.sigBytes * 8; // Add padding dataWords[nBitsLeft >>> 5] |= 0x80 << (24 - nBitsLeft % 32); dataWords[(((nBitsLeft + 64) >>> 9) << 4) + 14] = Math.floor(nBitsTotal / 0x100000000); dataWords[(((nBitsLeft + 64) >>> 9) << 4) + 15] = nBitsTotal; data.sigBytes = dataWords.length * 4; // Hash final blocks this._process(); // Return final computed hash return this._hash; }, clone: function () { var clone = Hasher.clone.call(this); clone._hash = this._hash.clone(); return clone; } }); /** * Shortcut function to the hasher's object interface. * * @param {WordArray|string} message The message to hash. * * @return {WordArray} The hash. * * @static * * @example * * var hash = CryptoJS.SHA256('message'); * var hash = CryptoJS.SHA256(wordArray); */ C.SHA256 = Hasher._createHelper(SHA256); /** * Shortcut function to the HMAC's object interface. * * @param {WordArray|string} message The message to hash. * @param {WordArray|string} key The secret key. * * @return {WordArray} The HMAC. * * @static * * @example * * var hmac = CryptoJS.HmacSHA256(message, key); */ C.HmacSHA256 = Hasher._createHmacHelper(SHA256); }(Math)); return CryptoJS.SHA256; })); },{"./core":31}],58:[function(_dereq_,module,exports){ ;(function (root, factory, undef) { if (typeof exports === "object") { // CommonJS module.exports = exports = factory(_dereq_("./core"), _dereq_("./x64-core")); } else if (typeof define === "function" && define.amd) { // AMD define(["./core", "./x64-core"], factory); } else { // Global (browser) factory(root.CryptoJS); } }(this, function (CryptoJS) { (function (Math) { // Shortcuts var C = CryptoJS; var C_lib = C.lib; var WordArray = C_lib.WordArray; var Hasher = C_lib.Hasher; var C_x64 = C.x64; var X64Word = C_x64.Word; var C_algo = C.algo; // Constants tables var RHO_OFFSETS = []; var PI_INDEXES = []; var ROUND_CONSTANTS = []; // Compute Constants (function () { // Compute rho offset constants var x = 1, y = 0; for (var t = 0; t < 24; t++) { RHO_OFFSETS[x + 5 * y] = ((t + 1) * (t + 2) / 2) % 64; var newX = y % 5; var newY = (2 * x + 3 * y) % 5; x = newX; y = newY; } // Compute pi index constants for (var x = 0; x < 5; x++) { for (var y = 0; y < 5; y++) { PI_INDEXES[x + 5 * y] = y + ((2 * x + 3 * y) % 5) * 5; } } // Compute round constants var LFSR = 0x01; for (var i = 0; i < 24; i++) { var roundConstantMsw = 0; var roundConstantLsw = 0; for (var j = 0; j < 7; j++) { if (LFSR & 0x01) { var bitPosition = (1 << j) - 1; if (bitPosition < 32) { roundConstantLsw ^= 1 << bitPosition; } else /* if (bitPosition >= 32) */ { roundConstantMsw ^= 1 << (bitPosition - 32); } } // Compute next LFSR if (LFSR & 0x80) { // Primitive polynomial over GF(2): x^8 + x^6 + x^5 + x^4 + 1 LFSR = (LFSR << 1) ^ 0x71; } else { LFSR <<= 1; } } ROUND_CONSTANTS[i] = X64Word.create(roundConstantMsw, roundConstantLsw); } }()); // Reusable objects for temporary values var T = []; (function () { for (var i = 0; i < 25; i++) { T[i] = X64Word.create(); } }()); /** * SHA-3 hash algorithm. */ var SHA3 = C_algo.SHA3 = Hasher.extend({ /** * Configuration options. * * @property {number} outputLength * The desired number of bits in the output hash. * Only values permitted are: 224, 256, 384, 512. * Default: 512 */ cfg: Hasher.cfg.extend({ outputLength: 512 }), _doReset: function () { var state = this._state = [] for (var i = 0; i < 25; i++) { state[i] = new X64Word.init(); } this.blockSize = (1600 - 2 * this.cfg.outputLength) / 32; }, _doProcessBlock: function (M, offset) { // Shortcuts var state = this._state; var nBlockSizeLanes = this.blockSize / 2; // Absorb for (var i = 0; i < nBlockSizeLanes; i++) { // Shortcuts var M2i = M[offset + 2 * i]; var M2i1 = M[offset + 2 * i + 1]; // Swap endian M2i = ( (((M2i << 8) | (M2i >>> 24)) & 0x00ff00ff) | (((M2i << 24) | (M2i >>> 8)) & 0xff00ff00) ); M2i1 = ( (((M2i1 << 8) | (M2i1 >>> 24)) & 0x00ff00ff) | (((M2i1 << 24) | (M2i1 >>> 8)) & 0xff00ff00) ); // Absorb message into state var lane = state[i]; lane.high ^= M2i1; lane.low ^= M2i; } // Rounds for (var round = 0; round < 24; round++) { // Theta for (var x = 0; x < 5; x++) { // Mix column lanes var tMsw = 0, tLsw = 0; for (var y = 0; y < 5; y++) { var lane = state[x + 5 * y]; tMsw ^= lane.high; tLsw ^= lane.low; } // Temporary values var Tx = T[x]; Tx.high = tMsw; Tx.low = tLsw; } for (var x = 0; x < 5; x++) { // Shortcuts var Tx4 = T[(x + 4) % 5]; var Tx1 = T[(x + 1) % 5]; var Tx1Msw = Tx1.high; var Tx1Lsw = Tx1.low; // Mix surrounding columns var tMsw = Tx4.high ^ ((Tx1Msw << 1) | (Tx1Lsw >>> 31)); var tLsw = Tx4.low ^ ((Tx1Lsw << 1) | (Tx1Msw >>> 31)); for (var y = 0; y < 5; y++) { var lane = state[x + 5 * y]; lane.high ^= tMsw; lane.low ^= tLsw; } } // Rho Pi for (var laneIndex = 1; laneIndex < 25; laneIndex++) { // Shortcuts var lane = state[laneIndex]; var laneMsw = lane.high; var laneLsw = lane.low; var rhoOffset = RHO_OFFSETS[laneIndex]; // Rotate lanes if (rhoOffset < 32) { var tMsw = (laneMsw << rhoOffset) | (laneLsw >>> (32 - rhoOffset)); var tLsw = (laneLsw << rhoOffset) | (laneMsw >>> (32 - rhoOffset)); } else /* if (rhoOffset >= 32) */ { var tMsw = (laneLsw << (rhoOffset - 32)) | (laneMsw >>> (64 - rhoOffset)); var tLsw = (laneMsw << (rhoOffset - 32)) | (laneLsw >>> (64 - rhoOffset)); } // Transpose lanes var TPiLane = T[PI_INDEXES[laneIndex]]; TPiLane.high = tMsw; TPiLane.low = tLsw; } // Rho pi at x = y = 0 var T0 = T[0]; var state0 = state[0]; T0.high = state0.high; T0.low = state0.low; // Chi for (var x = 0; x < 5; x++) { for (var y = 0; y < 5; y++) { // Shortcuts var laneIndex = x + 5 * y; var lane = state[laneIndex]; var TLane = T[laneIndex]; var Tx1Lane = T[((x + 1) % 5) + 5 * y]; var Tx2Lane = T[((x + 2) % 5) + 5 * y]; // Mix rows lane.high = TLane.high ^ (~Tx1Lane.high & Tx2Lane.high); lane.low = TLane.low ^ (~Tx1Lane.low & Tx2Lane.low); } } // Iota var lane = state[0]; var roundConstant = ROUND_CONSTANTS[round]; lane.high ^= roundConstant.high; lane.low ^= roundConstant.low;; } }, _doFinalize: function () { // Shortcuts var data = this._data; var dataWords = data.words; var nBitsTotal = this._nDataBytes * 8; var nBitsLeft = data.sigBytes * 8; var blockSizeBits = this.blockSize * 32; // Add padding dataWords[nBitsLeft >>> 5] |= 0x1 << (24 - nBitsLeft % 32); dataWords[((Math.ceil((nBitsLeft + 1) / blockSizeBits) * blockSizeBits) >>> 5) - 1] |= 0x80; data.sigBytes = dataWords.length * 4; // Hash final blocks this._process(); // Shortcuts var state = this._state; var outputLengthBytes = this.cfg.outputLength / 8; var outputLengthLanes = outputLengthBytes / 8; // Squeeze var hashWords = []; for (var i = 0; i < outputLengthLanes; i++) { // Shortcuts var lane = state[i]; var laneMsw = lane.high; var laneLsw = lane.low; // Swap endian laneMsw = ( (((laneMsw << 8) | (laneMsw >>> 24)) & 0x00ff00ff) | (((laneMsw << 24) | (laneMsw >>> 8)) & 0xff00ff00) ); laneLsw = ( (((laneLsw << 8) | (laneLsw >>> 24)) & 0x00ff00ff) | (((laneLsw << 24) | (laneLsw >>> 8)) & 0xff00ff00) ); // Squeeze state to retrieve hash hashWords.push(laneLsw); hashWords.push(laneMsw); } // Return final computed hash return new WordArray.init(hashWords, outputLengthBytes); }, clone: function () { var clone = Hasher.clone.call(this); var state = clone._state = this._state.slice(0); for (var i = 0; i < 25; i++) { state[i] = state[i].clone(); } return clone; } }); /** * Shortcut function to the hasher's object interface. * * @param {WordArray|string} message The message to hash. * * @return {WordArray} The hash. * * @static * * @example * * var hash = CryptoJS.SHA3('message'); * var hash = CryptoJS.SHA3(wordArray); */ C.SHA3 = Hasher._createHelper(SHA3); /** * Shortcut function to the HMAC's object interface. * * @param {WordArray|string} message The message to hash. * @param {WordArray|string} key The secret key. * * @return {WordArray} The HMAC. * * @static * * @example * * var hmac = CryptoJS.HmacSHA3(message, key); */ C.HmacSHA3 = Hasher._createHmacHelper(SHA3); }(Math)); return CryptoJS.SHA3; })); },{"./core":31,"./x64-core":62}],59:[function(_dereq_,module,exports){ ;(function (root, factory, undef) { if (typeof exports === "object") { // CommonJS module.exports = exports = factory(_dereq_("./core"), _dereq_("./x64-core"), _dereq_("./sha512")); } else if (typeof define === "function" && define.amd) { // AMD define(["./core", "./x64-core", "./sha512"], factory); } else { // Global (browser) factory(root.CryptoJS); } }(this, function (CryptoJS) { (function () { // Shortcuts var C = CryptoJS; var C_x64 = C.x64; var X64Word = C_x64.Word; var X64WordArray = C_x64.WordArray; var C_algo = C.algo; var SHA512 = C_algo.SHA512; /** * SHA-384 hash algorithm. */ var SHA384 = C_algo.SHA384 = SHA512.extend({ _doReset: function () { this._hash = new X64WordArray.init([ new X64Word.init(0xcbbb9d5d, 0xc1059ed8), new X64Word.init(0x629a292a, 0x367cd507), new X64Word.init(0x9159015a, 0x3070dd17), new X64Word.init(0x152fecd8, 0xf70e5939), new X64Word.init(0x67332667, 0xffc00b31), new X64Word.init(0x8eb44a87, 0x68581511), new X64Word.init(0xdb0c2e0d, 0x64f98fa7), new X64Word.init(0x47b5481d, 0xbefa4fa4) ]); }, _doFinalize: function () { var hash = SHA512._doFinalize.call(this); hash.sigBytes -= 16; return hash; } }); /** * Shortcut function to the hasher's object interface. * * @param {WordArray|string} message The message to hash. * * @return {WordArray} The hash. * * @static * * @example * * var hash = CryptoJS.SHA384('message'); * var hash = CryptoJS.SHA384(wordArray); */ C.SHA384 = SHA512._createHelper(SHA384); /** * Shortcut function to the HMAC's object interface. * * @param {WordArray|string} message The message to hash. * @param {WordArray|string} key The secret key. * * @return {WordArray} The HMAC. * * @static * * @example * * var hmac = CryptoJS.HmacSHA384(message, key); */ C.HmacSHA384 = SHA512._createHmacHelper(SHA384); }()); return CryptoJS.SHA384; })); },{"./core":31,"./sha512":60,"./x64-core":62}],60:[function(_dereq_,module,exports){ ;(function (root, factory, undef) { if (typeof exports === "object") { // CommonJS module.exports = exports = factory(_dereq_("./core"), _dereq_("./x64-core")); } else if (typeof define === "function" && define.amd) { // AMD define(["./core", "./x64-core"], factory); } else { // Global (browser) factory(root.CryptoJS); } }(this, function (CryptoJS) { (function () { // Shortcuts var C = CryptoJS; var C_lib = C.lib; var Hasher = C_lib.Hasher; var C_x64 = C.x64; var X64Word = C_x64.Word; var X64WordArray = C_x64.WordArray; var C_algo = C.algo; function X64Word_create() { return X64Word.create.apply(X64Word, arguments); } // Constants var K = [ X64Word_create(0x428a2f98, 0xd728ae22), X64Word_create(0x71374491, 0x23ef65cd), X64Word_create(0xb5c0fbcf, 0xec4d3b2f), X64Word_create(0xe9b5dba5, 0x8189dbbc), X64Word_create(0x3956c25b, 0xf348b538), X64Word_create(0x59f111f1, 0xb605d019), X64Word_create(0x923f82a4, 0xaf194f9b), X64Word_create(0xab1c5ed5, 0xda6d8118), X64Word_create(0xd807aa98, 0xa3030242), X64Word_create(0x12835b01, 0x45706fbe), X64Word_create(0x243185be, 0x4ee4b28c), X64Word_create(0x550c7dc3, 0xd5ffb4e2), X64Word_create(0x72be5d74, 0xf27b896f), X64Word_create(0x80deb1fe, 0x3b1696b1), X64Word_create(0x9bdc06a7, 0x25c71235), X64Word_create(0xc19bf174, 0xcf692694), X64Word_create(0xe49b69c1, 0x9ef14ad2), X64Word_create(0xefbe4786, 0x384f25e3), X64Word_create(0x0fc19dc6, 0x8b8cd5b5), X64Word_create(0x240ca1cc, 0x77ac9c65), X64Word_create(0x2de92c6f, 0x592b0275), X64Word_create(0x4a7484aa, 0x6ea6e483), X64Word_create(0x5cb0a9dc, 0xbd41fbd4), X64Word_create(0x76f988da, 0x831153b5), X64Word_create(0x983e5152, 0xee66dfab), X64Word_create(0xa831c66d, 0x2db43210), X64Word_create(0xb00327c8, 0x98fb213f), X64Word_create(0xbf597fc7, 0xbeef0ee4), X64Word_create(0xc6e00bf3, 0x3da88fc2), X64Word_create(0xd5a79147, 0x930aa725), X64Word_create(0x06ca6351, 0xe003826f), X64Word_create(0x14292967, 0x0a0e6e70), X64Word_create(0x27b70a85, 0x46d22ffc), X64Word_create(0x2e1b2138, 0x5c26c926), X64Word_create(0x4d2c6dfc, 0x5ac42aed), X64Word_create(0x53380d13, 0x9d95b3df), X64Word_create(0x650a7354, 0x8baf63de), X64Word_create(0x766a0abb, 0x3c77b2a8), X64Word_create(0x81c2c92e, 0x47edaee6), X64Word_create(0x92722c85, 0x1482353b), X64Word_create(0xa2bfe8a1, 0x4cf10364), X64Word_create(0xa81a664b, 0xbc423001), X64Word_create(0xc24b8b70, 0xd0f89791), X64Word_create(0xc76c51a3, 0x0654be30), X64Word_create(0xd192e819, 0xd6ef5218), X64Word_create(0xd6990624, 0x5565a910), X64Word_create(0xf40e3585, 0x5771202a), X64Word_create(0x106aa070, 0x32bbd1b8), X64Word_create(0x19a4c116, 0xb8d2d0c8), X64Word_create(0x1e376c08, 0x5141ab53), X64Word_create(0x2748774c, 0xdf8eeb99), X64Word_create(0x34b0bcb5, 0xe19b48a8), X64Word_create(0x391c0cb3, 0xc5c95a63), X64Word_create(0x4ed8aa4a, 0xe3418acb), X64Word_create(0x5b9cca4f, 0x7763e373), X64Word_create(0x682e6ff3, 0xd6b2b8a3), X64Word_create(0x748f82ee, 0x5defb2fc), X64Word_create(0x78a5636f, 0x43172f60), X64Word_create(0x84c87814, 0xa1f0ab72), X64Word_create(0x8cc70208, 0x1a6439ec), X64Word_create(0x90befffa, 0x23631e28), X64Word_create(0xa4506ceb, 0xde82bde9), X64Word_create(0xbef9a3f7, 0xb2c67915), X64Word_create(0xc67178f2, 0xe372532b), X64Word_create(0xca273ece, 0xea26619c), X64Word_create(0xd186b8c7, 0x21c0c207), X64Word_create(0xeada7dd6, 0xcde0eb1e), X64Word_create(0xf57d4f7f, 0xee6ed178), X64Word_create(0x06f067aa, 0x72176fba), X64Word_create(0x0a637dc5, 0xa2c898a6), X64Word_create(0x113f9804, 0xbef90dae), X64Word_create(0x1b710b35, 0x131c471b), X64Word_create(0x28db77f5, 0x23047d84), X64Word_create(0x32caab7b, 0x40c72493), X64Word_create(0x3c9ebe0a, 0x15c9bebc), X64Word_create(0x431d67c4, 0x9c100d4c), X64Word_create(0x4cc5d4be, 0xcb3e42b6), X64Word_create(0x597f299c, 0xfc657e2a), X64Word_create(0x5fcb6fab, 0x3ad6faec), X64Word_create(0x6c44198c, 0x4a475817) ]; // Reusable objects var W = []; (function () { for (var i = 0; i < 80; i++) { W[i] = X64Word_create(); } }()); /** * SHA-512 hash algorithm. */ var SHA512 = C_algo.SHA512 = Hasher.extend({ _doReset: function () { this._hash = new X64WordArray.init([ new X64Word.init(0x6a09e667, 0xf3bcc908), new X64Word.init(0xbb67ae85, 0x84caa73b), new X64Word.init(0x3c6ef372, 0xfe94f82b), new X64Word.init(0xa54ff53a, 0x5f1d36f1), new X64Word.init(0x510e527f, 0xade682d1), new X64Word.init(0x9b05688c, 0x2b3e6c1f), new X64Word.init(0x1f83d9ab, 0xfb41bd6b), new X64Word.init(0x5be0cd19, 0x137e2179) ]); }, _doProcessBlock: function (M, offset) { // Shortcuts var H = this._hash.words; var H0 = H[0]; var H1 = H[1]; var H2 = H[2]; var H3 = H[3]; var H4 = H[4]; var H5 = H[5]; var H6 = H[6]; var H7 = H[7]; var H0h = H0.high; var H0l = H0.low; var H1h = H1.high; var H1l = H1.low; var H2h = H2.high; var H2l = H2.low; var H3h = H3.high; var H3l = H3.low; var H4h = H4.high; var H4l = H4.low; var H5h = H5.high; var H5l = H5.low; var H6h = H6.high; var H6l = H6.low; var H7h = H7.high; var H7l = H7.low; // Working variables var ah = H0h; var al = H0l; var bh = H1h; var bl = H1l; var ch = H2h; var cl = H2l; var dh = H3h; var dl = H3l; var eh = H4h; var el = H4l; var fh = H5h; var fl = H5l; var gh = H6h; var gl = H6l; var hh = H7h; var hl = H7l; // Rounds for (var i = 0; i < 80; i++) { // Shortcut var Wi = W[i]; // Extend message if (i < 16) { var Wih = Wi.high = M[offset + i * 2] | 0; var Wil = Wi.low = M[offset + i * 2 + 1] | 0; } else { // Gamma0 var gamma0x = W[i - 15]; var gamma0xh = gamma0x.high; var gamma0xl = gamma0x.low; var gamma0h = ((gamma0xh >>> 1) | (gamma0xl << 31)) ^ ((gamma0xh >>> 8) | (gamma0xl << 24)) ^ (gamma0xh >>> 7); var gamma0l = ((gamma0xl >>> 1) | (gamma0xh << 31)) ^ ((gamma0xl >>> 8) | (gamma0xh << 24)) ^ ((gamma0xl >>> 7) | (gamma0xh << 25)); // Gamma1 var gamma1x = W[i - 2]; var gamma1xh = gamma1x.high; var gamma1xl = gamma1x.low; var gamma1h = ((gamma1xh >>> 19) | (gamma1xl << 13)) ^ ((gamma1xh << 3) | (gamma1xl >>> 29)) ^ (gamma1xh >>> 6); var gamma1l = ((gamma1xl >>> 19) | (gamma1xh << 13)) ^ ((gamma1xl << 3) | (gamma1xh >>> 29)) ^ ((gamma1xl >>> 6) | (gamma1xh << 26)); // W[i] = gamma0 + W[i - 7] + gamma1 + W[i - 16] var Wi7 = W[i - 7]; var Wi7h = Wi7.high; var Wi7l = Wi7.low; var Wi16 = W[i - 16]; var Wi16h = Wi16.high; var Wi16l = Wi16.low; var Wil = gamma0l + Wi7l; var Wih = gamma0h + Wi7h + ((Wil >>> 0) < (gamma0l >>> 0) ? 1 : 0); var Wil = Wil + gamma1l; var Wih = Wih + gamma1h + ((Wil >>> 0) < (gamma1l >>> 0) ? 1 : 0); var Wil = Wil + Wi16l; var Wih = Wih + Wi16h + ((Wil >>> 0) < (Wi16l >>> 0) ? 1 : 0); Wi.high = Wih; Wi.low = Wil; } var chh = (eh & fh) ^ (~eh & gh); var chl = (el & fl) ^ (~el & gl); var majh = (ah & bh) ^ (ah & ch) ^ (bh & ch); var majl = (al & bl) ^ (al & cl) ^ (bl & cl); var sigma0h = ((ah >>> 28) | (al << 4)) ^ ((ah << 30) | (al >>> 2)) ^ ((ah << 25) | (al >>> 7)); var sigma0l = ((al >>> 28) | (ah << 4)) ^ ((al << 30) | (ah >>> 2)) ^ ((al << 25) | (ah >>> 7)); var sigma1h = ((eh >>> 14) | (el << 18)) ^ ((eh >>> 18) | (el << 14)) ^ ((eh << 23) | (el >>> 9)); var sigma1l = ((el >>> 14) | (eh << 18)) ^ ((el >>> 18) | (eh << 14)) ^ ((el << 23) | (eh >>> 9)); // t1 = h + sigma1 + ch + K[i] + W[i] var Ki = K[i]; var Kih = Ki.high; var Kil = Ki.low; var t1l = hl + sigma1l; var t1h = hh + sigma1h + ((t1l >>> 0) < (hl >>> 0) ? 1 : 0); var t1l = t1l + chl; var t1h = t1h + chh + ((t1l >>> 0) < (chl >>> 0) ? 1 : 0); var t1l = t1l + Kil; var t1h = t1h + Kih + ((t1l >>> 0) < (Kil >>> 0) ? 1 : 0); var t1l = t1l + Wil; var t1h = t1h + Wih + ((t1l >>> 0) < (Wil >>> 0) ? 1 : 0); // t2 = sigma0 + maj var t2l = sigma0l + majl; var t2h = sigma0h + majh + ((t2l >>> 0) < (sigma0l >>> 0) ? 1 : 0); // Update working variables hh = gh; hl = gl; gh = fh; gl = fl; fh = eh; fl = el; el = (dl + t1l) | 0; eh = (dh + t1h + ((el >>> 0) < (dl >>> 0) ? 1 : 0)) | 0; dh = ch; dl = cl; ch = bh; cl = bl; bh = ah; bl = al; al = (t1l + t2l) | 0; ah = (t1h + t2h + ((al >>> 0) < (t1l >>> 0) ? 1 : 0)) | 0; } // Intermediate hash value H0l = H0.low = (H0l + al); H0.high = (H0h + ah + ((H0l >>> 0) < (al >>> 0) ? 1 : 0)); H1l = H1.low = (H1l + bl); H1.high = (H1h + bh + ((H1l >>> 0) < (bl >>> 0) ? 1 : 0)); H2l = H2.low = (H2l + cl); H2.high = (H2h + ch + ((H2l >>> 0) < (cl >>> 0) ? 1 : 0)); H3l = H3.low = (H3l + dl); H3.high = (H3h + dh + ((H3l >>> 0) < (dl >>> 0) ? 1 : 0)); H4l = H4.low = (H4l + el); H4.high = (H4h + eh + ((H4l >>> 0) < (el >>> 0) ? 1 : 0)); H5l = H5.low = (H5l + fl); H5.high = (H5h + fh + ((H5l >>> 0) < (fl >>> 0) ? 1 : 0)); H6l = H6.low = (H6l + gl); H6.high = (H6h + gh + ((H6l >>> 0) < (gl >>> 0) ? 1 : 0)); H7l = H7.low = (H7l + hl); H7.high = (H7h + hh + ((H7l >>> 0) < (hl >>> 0) ? 1 : 0)); }, _doFinalize: function () { // Shortcuts var data = this._data; var dataWords = data.words; var nBitsTotal = this._nDataBytes * 8; var nBitsLeft = data.sigBytes * 8; // Add padding dataWords[nBitsLeft >>> 5] |= 0x80 << (24 - nBitsLeft % 32); dataWords[(((nBitsLeft + 128) >>> 10) << 5) + 30] = Math.floor(nBitsTotal / 0x100000000); dataWords[(((nBitsLeft + 128) >>> 10) << 5) + 31] = nBitsTotal; data.sigBytes = dataWords.length * 4; // Hash final blocks this._process(); // Convert hash to 32-bit word array before returning var hash = this._hash.toX32(); // Return final computed hash return hash; }, clone: function () { var clone = Hasher.clone.call(this); clone._hash = this._hash.clone(); return clone; }, blockSize: 1024/32 }); /** * Shortcut function to the hasher's object interface. * * @param {WordArray|string} message The message to hash. * * @return {WordArray} The hash. * * @static * * @example * * var hash = CryptoJS.SHA512('message'); * var hash = CryptoJS.SHA512(wordArray); */ C.SHA512 = Hasher._createHelper(SHA512); /** * Shortcut function to the HMAC's object interface. * * @param {WordArray|string} message The message to hash. * @param {WordArray|string} key The secret key. * * @return {WordArray} The HMAC. * * @static * * @example * * var hmac = CryptoJS.HmacSHA512(message, key); */ C.HmacSHA512 = Hasher._createHmacHelper(SHA512); }()); return CryptoJS.SHA512; })); },{"./core":31,"./x64-core":62}],61:[function(_dereq_,module,exports){ ;(function (root, factory, undef) { if (typeof exports === "object") { // CommonJS module.exports = exports = factory(_dereq_("./core"), _dereq_("./enc-base64"), _dereq_("./md5"), _dereq_("./evpkdf"), _dereq_("./cipher-core")); } else if (typeof define === "function" && define.amd) { // AMD define(["./core", "./enc-base64", "./md5", "./evpkdf", "./cipher-core"], factory); } else { // Global (browser) factory(root.CryptoJS); } }(this, function (CryptoJS) { (function () { // Shortcuts var C = CryptoJS; var C_lib = C.lib; var WordArray = C_lib.WordArray; var BlockCipher = C_lib.BlockCipher; var C_algo = C.algo; // Permuted Choice 1 constants var PC1 = [ 57, 49, 41, 33, 25, 17, 9, 1, 58, 50, 42, 34, 26, 18, 10, 2, 59, 51, 43, 35, 27, 19, 11, 3, 60, 52, 44, 36, 63, 55, 47, 39, 31, 23, 15, 7, 62, 54, 46, 38, 30, 22, 14, 6, 61, 53, 45, 37, 29, 21, 13, 5, 28, 20, 12, 4 ]; // Permuted Choice 2 constants var PC2 = [ 14, 17, 11, 24, 1, 5, 3, 28, 15, 6, 21, 10, 23, 19, 12, 4, 26, 8, 16, 7, 27, 20, 13, 2, 41, 52, 31, 37, 47, 55, 30, 40, 51, 45, 33, 48, 44, 49, 39, 56, 34, 53, 46, 42, 50, 36, 29, 32 ]; // Cumulative bit shift constants var BIT_SHIFTS = [1, 2, 4, 6, 8, 10, 12, 14, 15, 17, 19, 21, 23, 25, 27, 28]; // SBOXes and round permutation constants var SBOX_P = [ { 0x0: 0x808200, 0x10000000: 0x8000, 0x20000000: 0x808002, 0x30000000: 0x2, 0x40000000: 0x200, 0x50000000: 0x808202, 0x60000000: 0x800202, 0x70000000: 0x800000, 0x80000000: 0x202, 0x90000000: 0x800200, 0xa0000000: 0x8200, 0xb0000000: 0x808000, 0xc0000000: 0x8002, 0xd0000000: 0x800002, 0xe0000000: 0x0, 0xf0000000: 0x8202, 0x8000000: 0x0, 0x18000000: 0x808202, 0x28000000: 0x8202, 0x38000000: 0x8000, 0x48000000: 0x808200, 0x58000000: 0x200, 0x68000000: 0x808002, 0x78000000: 0x2, 0x88000000: 0x800200, 0x98000000: 0x8200, 0xa8000000: 0x808000, 0xb8000000: 0x800202, 0xc8000000: 0x800002, 0xd8000000: 0x8002, 0xe8000000: 0x202, 0xf8000000: 0x800000, 0x1: 0x8000, 0x10000001: 0x2, 0x20000001: 0x808200, 0x30000001: 0x800000, 0x40000001: 0x808002, 0x50000001: 0x8200, 0x60000001: 0x200, 0x70000001: 0x800202, 0x80000001: 0x808202, 0x90000001: 0x808000, 0xa0000001: 0x800002, 0xb0000001: 0x8202, 0xc0000001: 0x202, 0xd0000001: 0x800200, 0xe0000001: 0x8002, 0xf0000001: 0x0, 0x8000001: 0x808202, 0x18000001: 0x808000, 0x28000001: 0x800000, 0x38000001: 0x200, 0x48000001: 0x8000, 0x58000001: 0x800002, 0x68000001: 0x2, 0x78000001: 0x8202, 0x88000001: 0x8002, 0x98000001: 0x800202, 0xa8000001: 0x202, 0xb8000001: 0x808200, 0xc8000001: 0x800200, 0xd8000001: 0x0, 0xe8000001: 0x8200, 0xf8000001: 0x808002 }, { 0x0: 0x40084010, 0x1000000: 0x4000, 0x2000000: 0x80000, 0x3000000: 0x40080010, 0x4000000: 0x40000010, 0x5000000: 0x40084000, 0x6000000: 0x40004000, 0x7000000: 0x10, 0x8000000: 0x84000, 0x9000000: 0x40004010, 0xa000000: 0x40000000, 0xb000000: 0x84010, 0xc000000: 0x80010, 0xd000000: 0x0, 0xe000000: 0x4010, 0xf000000: 0x40080000, 0x800000: 0x40004000, 0x1800000: 0x84010, 0x2800000: 0x10, 0x3800000: 0x40004010, 0x4800000: 0x40084010, 0x5800000: 0x40000000, 0x6800000: 0x80000, 0x7800000: 0x40080010, 0x8800000: 0x80010, 0x9800000: 0x0, 0xa800000: 0x4000, 0xb800000: 0x40080000, 0xc800000: 0x40000010, 0xd800000: 0x84000, 0xe800000: 0x40084000, 0xf800000: 0x4010, 0x10000000: 0x0, 0x11000000: 0x40080010, 0x12000000: 0x40004010, 0x13000000: 0x40084000, 0x14000000: 0x40080000, 0x15000000: 0x10, 0x16000000: 0x84010, 0x17000000: 0x4000, 0x18000000: 0x4010, 0x19000000: 0x80000, 0x1a000000: 0x80010, 0x1b000000: 0x40000010, 0x1c000000: 0x84000, 0x1d000000: 0x40004000, 0x1e000000: 0x40000000, 0x1f000000: 0x40084010, 0x10800000: 0x84010, 0x11800000: 0x80000, 0x12800000: 0x40080000, 0x13800000: 0x4000, 0x14800000: 0x40004000, 0x15800000: 0x40084010, 0x16800000: 0x10, 0x17800000: 0x40000000, 0x18800000: 0x40084000, 0x19800000: 0x40000010, 0x1a800000: 0x40004010, 0x1b800000: 0x80010, 0x1c800000: 0x0, 0x1d800000: 0x4010, 0x1e800000: 0x40080010, 0x1f800000: 0x84000 }, { 0x0: 0x104, 0x100000: 0x0, 0x200000: 0x4000100, 0x300000: 0x10104, 0x400000: 0x10004, 0x500000: 0x4000004, 0x600000: 0x4010104, 0x700000: 0x4010000, 0x800000: 0x4000000, 0x900000: 0x4010100, 0xa00000: 0x10100, 0xb00000: 0x4010004, 0xc00000: 0x4000104, 0xd00000: 0x10000, 0xe00000: 0x4, 0xf00000: 0x100, 0x80000: 0x4010100, 0x180000: 0x4010004, 0x280000: 0x0, 0x380000: 0x4000100, 0x480000: 0x4000004, 0x580000: 0x10000, 0x680000: 0x10004, 0x780000: 0x104, 0x880000: 0x4, 0x980000: 0x100, 0xa80000: 0x4010000, 0xb80000: 0x10104, 0xc80000: 0x10100, 0xd80000: 0x4000104, 0xe80000: 0x4010104, 0xf80000: 0x4000000, 0x1000000: 0x4010100, 0x1100000: 0x10004, 0x1200000: 0x10000, 0x1300000: 0x4000100, 0x1400000: 0x100, 0x1500000: 0x4010104, 0x1600000: 0x4000004, 0x1700000: 0x0, 0x1800000: 0x4000104, 0x1900000: 0x4000000, 0x1a00000: 0x4, 0x1b00000: 0x10100, 0x1c00000: 0x4010000, 0x1d00000: 0x104, 0x1e00000: 0x10104, 0x1f00000: 0x4010004, 0x1080000: 0x4000000, 0x1180000: 0x104, 0x1280000: 0x4010100, 0x1380000: 0x0, 0x1480000: 0x10004, 0x1580000: 0x4000100, 0x1680000: 0x100, 0x1780000: 0x4010004, 0x1880000: 0x10000, 0x1980000: 0x4010104, 0x1a80000: 0x10104, 0x1b80000: 0x4000004, 0x1c80000: 0x4000104, 0x1d80000: 0x4010000, 0x1e80000: 0x4, 0x1f80000: 0x10100 }, { 0x0: 0x80401000, 0x10000: 0x80001040, 0x20000: 0x401040, 0x30000: 0x80400000, 0x40000: 0x0, 0x50000: 0x401000, 0x60000: 0x80000040, 0x70000: 0x400040, 0x80000: 0x80000000, 0x90000: 0x400000, 0xa0000: 0x40, 0xb0000: 0x80001000, 0xc0000: 0x80400040, 0xd0000: 0x1040, 0xe0000: 0x1000, 0xf0000: 0x80401040, 0x8000: 0x80001040, 0x18000: 0x40, 0x28000: 0x80400040, 0x38000: 0x80001000, 0x48000: 0x401000, 0x58000: 0x80401040, 0x68000: 0x0, 0x78000: 0x80400000, 0x88000: 0x1000, 0x98000: 0x80401000, 0xa8000: 0x400000, 0xb8000: 0x1040, 0xc8000: 0x80000000, 0xd8000: 0x400040, 0xe8000: 0x401040, 0xf8000: 0x80000040, 0x100000: 0x400040, 0x110000: 0x401000, 0x120000: 0x80000040, 0x130000: 0x0, 0x140000: 0x1040, 0x150000: 0x80400040, 0x160000: 0x80401000, 0x170000: 0x80001040, 0x180000: 0x80401040, 0x190000: 0x80000000, 0x1a0000: 0x80400000, 0x1b0000: 0x401040, 0x1c0000: 0x80001000, 0x1d0000: 0x400000, 0x1e0000: 0x40, 0x1f0000: 0x1000, 0x108000: 0x80400000, 0x118000: 0x80401040, 0x128000: 0x0, 0x138000: 0x401000, 0x148000: 0x400040, 0x158000: 0x80000000, 0x168000: 0x80001040, 0x178000: 0x40, 0x188000: 0x80000040, 0x198000: 0x1000, 0x1a8000: 0x80001000, 0x1b8000: 0x80400040, 0x1c8000: 0x1040, 0x1d8000: 0x80401000, 0x1e8000: 0x400000, 0x1f8000: 0x401040 }, { 0x0: 0x80, 0x1000: 0x1040000, 0x2000: 0x40000, 0x3000: 0x20000000, 0x4000: 0x20040080, 0x5000: 0x1000080, 0x6000: 0x21000080, 0x7000: 0x40080, 0x8000: 0x1000000, 0x9000: 0x20040000, 0xa000: 0x20000080, 0xb000: 0x21040080, 0xc000: 0x21040000, 0xd000: 0x0, 0xe000: 0x1040080, 0xf000: 0x21000000, 0x800: 0x1040080, 0x1800: 0x21000080, 0x2800: 0x80, 0x3800: 0x1040000, 0x4800: 0x40000, 0x5800: 0x20040080, 0x6800: 0x21040000, 0x7800: 0x20000000, 0x8800: 0x20040000, 0x9800: 0x0, 0xa800: 0x21040080, 0xb800: 0x1000080, 0xc800: 0x20000080, 0xd800: 0x21000000, 0xe800: 0x1000000, 0xf800: 0x40080, 0x10000: 0x40000, 0x11000: 0x80, 0x12000: 0x20000000, 0x13000: 0x21000080, 0x14000: 0x1000080, 0x15000: 0x21040000, 0x16000: 0x20040080, 0x17000: 0x1000000, 0x18000: 0x21040080, 0x19000: 0x21000000, 0x1a000: 0x1040000, 0x1b000: 0x20040000, 0x1c000: 0x40080, 0x1d000: 0x20000080, 0x1e000: 0x0, 0x1f000: 0x1040080, 0x10800: 0x21000080, 0x11800: 0x1000000, 0x12800: 0x1040000, 0x13800: 0x20040080, 0x14800: 0x20000000, 0x15800: 0x1040080, 0x16800: 0x80, 0x17800: 0x21040000, 0x18800: 0x40080, 0x19800: 0x21040080, 0x1a800: 0x0, 0x1b800: 0x21000000, 0x1c800: 0x1000080, 0x1d800: 0x40000, 0x1e800: 0x20040000, 0x1f800: 0x20000080 }, { 0x0: 0x10000008, 0x100: 0x2000, 0x200: 0x10200000, 0x300: 0x10202008, 0x400: 0x10002000, 0x500: 0x200000, 0x600: 0x200008, 0x700: 0x10000000, 0x800: 0x0, 0x900: 0x10002008, 0xa00: 0x202000, 0xb00: 0x8, 0xc00: 0x10200008, 0xd00: 0x202008, 0xe00: 0x2008, 0xf00: 0x10202000, 0x80: 0x10200000, 0x180: 0x10202008, 0x280: 0x8, 0x380: 0x200000, 0x480: 0x202008, 0x580: 0x10000008, 0x680: 0x10002000, 0x780: 0x2008, 0x880: 0x200008, 0x980: 0x2000, 0xa80: 0x10002008, 0xb80: 0x10200008, 0xc80: 0x0, 0xd80: 0x10202000, 0xe80: 0x202000, 0xf80: 0x10000000, 0x1000: 0x10002000, 0x1100: 0x10200008, 0x1200: 0x10202008, 0x1300: 0x2008, 0x1400: 0x200000, 0x1500: 0x10000000, 0x1600: 0x10000008, 0x1700: 0x202000, 0x1800: 0x202008, 0x1900: 0x0, 0x1a00: 0x8, 0x1b00: 0x10200000, 0x1c00: 0x2000, 0x1d00: 0x10002008, 0x1e00: 0x10202000, 0x1f00: 0x200008, 0x1080: 0x8, 0x1180: 0x202000, 0x1280: 0x200000, 0x1380: 0x10000008, 0x1480: 0x10002000, 0x1580: 0x2008, 0x1680: 0x10202008, 0x1780: 0x10200000, 0x1880: 0x10202000, 0x1980: 0x10200008, 0x1a80: 0x2000, 0x1b80: 0x202008, 0x1c80: 0x200008, 0x1d80: 0x0, 0x1e80: 0x10000000, 0x1f80: 0x10002008 }, { 0x0: 0x100000, 0x10: 0x2000401, 0x20: 0x400, 0x30: 0x100401, 0x40: 0x2100401, 0x50: 0x0, 0x60: 0x1, 0x70: 0x2100001, 0x80: 0x2000400, 0x90: 0x100001, 0xa0: 0x2000001, 0xb0: 0x2100400, 0xc0: 0x2100000, 0xd0: 0x401, 0xe0: 0x100400, 0xf0: 0x2000000, 0x8: 0x2100001, 0x18: 0x0, 0x28: 0x2000401, 0x38: 0x2100400, 0x48: 0x100000, 0x58: 0x2000001, 0x68: 0x2000000, 0x78: 0x401, 0x88: 0x100401, 0x98: 0x2000400, 0xa8: 0x2100000, 0xb8: 0x100001, 0xc8: 0x400, 0xd8: 0x2100401, 0xe8: 0x1, 0xf8: 0x100400, 0x100: 0x2000000, 0x110: 0x100000, 0x120: 0x2000401, 0x130: 0x2100001, 0x140: 0x100001, 0x150: 0x2000400, 0x160: 0x2100400, 0x170: 0x100401, 0x180: 0x401, 0x190: 0x2100401, 0x1a0: 0x100400, 0x1b0: 0x1, 0x1c0: 0x0, 0x1d0: 0x2100000, 0x1e0: 0x2000001, 0x1f0: 0x400, 0x108: 0x100400, 0x118: 0x2000401, 0x128: 0x2100001, 0x138: 0x1, 0x148: 0x2000000, 0x158: 0x100000, 0x168: 0x401, 0x178: 0x2100400, 0x188: 0x2000001, 0x198: 0x2100000, 0x1a8: 0x0, 0x1b8: 0x2100401, 0x1c8: 0x100401, 0x1d8: 0x400, 0x1e8: 0x2000400, 0x1f8: 0x100001 }, { 0x0: 0x8000820, 0x1: 0x20000, 0x2: 0x8000000, 0x3: 0x20, 0x4: 0x20020, 0x5: 0x8020820, 0x6: 0x8020800, 0x7: 0x800, 0x8: 0x8020000, 0x9: 0x8000800, 0xa: 0x20800, 0xb: 0x8020020, 0xc: 0x820, 0xd: 0x0, 0xe: 0x8000020, 0xf: 0x20820, 0x80000000: 0x800, 0x80000001: 0x8020820, 0x80000002: 0x8000820, 0x80000003: 0x8000000, 0x80000004: 0x8020000, 0x80000005: 0x20800, 0x80000006: 0x20820, 0x80000007: 0x20, 0x80000008: 0x8000020, 0x80000009: 0x820, 0x8000000a: 0x20020, 0x8000000b: 0x8020800, 0x8000000c: 0x0, 0x8000000d: 0x8020020, 0x8000000e: 0x8000800, 0x8000000f: 0x20000, 0x10: 0x20820, 0x11: 0x8020800, 0x12: 0x20, 0x13: 0x800, 0x14: 0x8000800, 0x15: 0x8000020, 0x16: 0x8020020, 0x17: 0x20000, 0x18: 0x0, 0x19: 0x20020, 0x1a: 0x8020000, 0x1b: 0x8000820, 0x1c: 0x8020820, 0x1d: 0x20800, 0x1e: 0x820, 0x1f: 0x8000000, 0x80000010: 0x20000, 0x80000011: 0x800, 0x80000012: 0x8020020, 0x80000013: 0x20820, 0x80000014: 0x20, 0x80000015: 0x8020000, 0x80000016: 0x8000000, 0x80000017: 0x8000820, 0x80000018: 0x8020820, 0x80000019: 0x8000020, 0x8000001a: 0x8000800, 0x8000001b: 0x0, 0x8000001c: 0x20800, 0x8000001d: 0x820, 0x8000001e: 0x20020, 0x8000001f: 0x8020800 } ]; // Masks that select the SBOX input var SBOX_MASK = [ 0xf8000001, 0x1f800000, 0x01f80000, 0x001f8000, 0x0001f800, 0x00001f80, 0x000001f8, 0x8000001f ]; /** * DES block cipher algorithm. */ var DES = C_algo.DES = BlockCipher.extend({ _doReset: function () { // Shortcuts var key = this._key; var keyWords = key.words; // Select 56 bits according to PC1 var keyBits = []; for (var i = 0; i < 56; i++) { var keyBitPos = PC1[i] - 1; keyBits[i] = (keyWords[keyBitPos >>> 5] >>> (31 - keyBitPos % 32)) & 1; } // Assemble 16 subkeys var subKeys = this._subKeys = []; for (var nSubKey = 0; nSubKey < 16; nSubKey++) { // Create subkey var subKey = subKeys[nSubKey] = []; // Shortcut var bitShift = BIT_SHIFTS[nSubKey]; // Select 48 bits according to PC2 for (var i = 0; i < 24; i++) { // Select from the left 28 key bits subKey[(i / 6) | 0] |= keyBits[((PC2[i] - 1) + bitShift) % 28] << (31 - i % 6); // Select from the right 28 key bits subKey[4 + ((i / 6) | 0)] |= keyBits[28 + (((PC2[i + 24] - 1) + bitShift) % 28)] << (31 - i % 6); } // Since each subkey is applied to an expanded 32-bit input, // the subkey can be broken into 8 values scaled to 32-bits, // which allows the key to be used without expansion subKey[0] = (subKey[0] << 1) | (subKey[0] >>> 31); for (var i = 1; i < 7; i++) { subKey[i] = subKey[i] >>> ((i - 1) * 4 + 3); } subKey[7] = (subKey[7] << 5) | (subKey[7] >>> 27); } // Compute inverse subkeys var invSubKeys = this._invSubKeys = []; for (var i = 0; i < 16; i++) { invSubKeys[i] = subKeys[15 - i]; } }, encryptBlock: function (M, offset) { this._doCryptBlock(M, offset, this._subKeys); }, decryptBlock: function (M, offset) { this._doCryptBlock(M, offset, this._invSubKeys); }, _doCryptBlock: function (M, offset, subKeys) { // Get input this._lBlock = M[offset]; this._rBlock = M[offset + 1]; // Initial permutation exchangeLR.call(this, 4, 0x0f0f0f0f); exchangeLR.call(this, 16, 0x0000ffff); exchangeRL.call(this, 2, 0x33333333); exchangeRL.call(this, 8, 0x00ff00ff); exchangeLR.call(this, 1, 0x55555555); // Rounds for (var round = 0; round < 16; round++) { // Shortcuts var subKey = subKeys[round]; var lBlock = this._lBlock; var rBlock = this._rBlock; // Feistel function var f = 0; for (var i = 0; i < 8; i++) { f |= SBOX_P[i][((rBlock ^ subKey[i]) & SBOX_MASK[i]) >>> 0]; } this._lBlock = rBlock; this._rBlock = lBlock ^ f; } // Undo swap from last round var t = this._lBlock; this._lBlock = this._rBlock; this._rBlock = t; // Final permutation exchangeLR.call(this, 1, 0x55555555); exchangeRL.call(this, 8, 0x00ff00ff); exchangeRL.call(this, 2, 0x33333333); exchangeLR.call(this, 16, 0x0000ffff); exchangeLR.call(this, 4, 0x0f0f0f0f); // Set output M[offset] = this._lBlock; M[offset + 1] = this._rBlock; }, keySize: 64/32, ivSize: 64/32, blockSize: 64/32 }); // Swap bits across the left and right words function exchangeLR(offset, mask) { var t = ((this._lBlock >>> offset) ^ this._rBlock) & mask; this._rBlock ^= t; this._lBlock ^= t << offset; } function exchangeRL(offset, mask) { var t = ((this._rBlock >>> offset) ^ this._lBlock) & mask; this._lBlock ^= t; this._rBlock ^= t << offset; } /** * Shortcut functions to the cipher's object interface. * * @example * * var ciphertext = CryptoJS.DES.encrypt(message, key, cfg); * var plaintext = CryptoJS.DES.decrypt(ciphertext, key, cfg); */ C.DES = BlockCipher._createHelper(DES); /** * Triple-DES block cipher algorithm. */ var TripleDES = C_algo.TripleDES = BlockCipher.extend({ _doReset: function () { // Shortcuts var key = this._key; var keyWords = key.words; // Create DES instances this._des1 = DES.createEncryptor(WordArray.create(keyWords.slice(0, 2))); this._des2 = DES.createEncryptor(WordArray.create(keyWords.slice(2, 4))); this._des3 = DES.createEncryptor(WordArray.create(keyWords.slice(4, 6))); }, encryptBlock: function (M, offset) { this._des1.encryptBlock(M, offset); this._des2.decryptBlock(M, offset); this._des3.encryptBlock(M, offset); }, decryptBlock: function (M, offset) { this._des3.decryptBlock(M, offset); this._des2.encryptBlock(M, offset); this._des1.decryptBlock(M, offset); }, keySize: 192/32, ivSize: 64/32, blockSize: 64/32 }); /** * Shortcut functions to the cipher's object interface. * * @example * * var ciphertext = CryptoJS.TripleDES.encrypt(message, key, cfg); * var plaintext = CryptoJS.TripleDES.decrypt(ciphertext, key, cfg); */ C.TripleDES = BlockCipher._createHelper(TripleDES); }()); return CryptoJS.TripleDES; })); },{"./cipher-core":30,"./core":31,"./enc-base64":32,"./evpkdf":34,"./md5":39}],62:[function(_dereq_,module,exports){ ;(function (root, factory) { if (typeof exports === "object") { // CommonJS module.exports = exports = factory(_dereq_("./core")); } else if (typeof define === "function" && define.amd) { // AMD define(["./core"], factory); } else { // Global (browser) factory(root.CryptoJS); } }(this, function (CryptoJS) { (function (undefined) { // Shortcuts var C = CryptoJS; var C_lib = C.lib; var Base = C_lib.Base; var X32WordArray = C_lib.WordArray; /** * x64 namespace. */ var C_x64 = C.x64 = {}; /** * A 64-bit word. */ var X64Word = C_x64.Word = Base.extend({ /** * Initializes a newly created 64-bit word. * * @param {number} high The high 32 bits. * @param {number} low The low 32 bits. * * @example * * var x64Word = CryptoJS.x64.Word.create(0x00010203, 0x04050607); */ init: function (high, low) { this.high = high; this.low = low; } /** * Bitwise NOTs this word. * * @return {X64Word} A new x64-Word object after negating. * * @example * * var negated = x64Word.not(); */ // not: function () { // var high = ~this.high; // var low = ~this.low; // return X64Word.create(high, low); // }, /** * Bitwise ANDs this word with the passed word. * * @param {X64Word} word The x64-Word to AND with this word. * * @return {X64Word} A new x64-Word object after ANDing. * * @example * * var anded = x64Word.and(anotherX64Word); */ // and: function (word) { // var high = this.high & word.high; // var low = this.low & word.low; // return X64Word.create(high, low); // }, /** * Bitwise ORs this word with the passed word. * * @param {X64Word} word The x64-Word to OR with this word. * * @return {X64Word} A new x64-Word object after ORing. * * @example * * var ored = x64Word.or(anotherX64Word); */ // or: function (word) { // var high = this.high | word.high; // var low = this.low | word.low; // return X64Word.create(high, low); // }, /** * Bitwise XORs this word with the passed word. * * @param {X64Word} word The x64-Word to XOR with this word. * * @return {X64Word} A new x64-Word object after XORing. * * @example * * var xored = x64Word.xor(anotherX64Word); */ // xor: function (word) { // var high = this.high ^ word.high; // var low = this.low ^ word.low; // return X64Word.create(high, low); // }, /** * Shifts this word n bits to the left. * * @param {number} n The number of bits to shift. * * @return {X64Word} A new x64-Word object after shifting. * * @example * * var shifted = x64Word.shiftL(25); */ // shiftL: function (n) { // if (n < 32) { // var high = (this.high << n) | (this.low >>> (32 - n)); // var low = this.low << n; // } else { // var high = this.low << (n - 32); // var low = 0; // } // return X64Word.create(high, low); // }, /** * Shifts this word n bits to the right. * * @param {number} n The number of bits to shift. * * @return {X64Word} A new x64-Word object after shifting. * * @example * * var shifted = x64Word.shiftR(7); */ // shiftR: function (n) { // if (n < 32) { // var low = (this.low >>> n) | (this.high << (32 - n)); // var high = this.high >>> n; // } else { // var low = this.high >>> (n - 32); // var high = 0; // } // return X64Word.create(high, low); // }, /** * Rotates this word n bits to the left. * * @param {number} n The number of bits to rotate. * * @return {X64Word} A new x64-Word object after rotating. * * @example * * var rotated = x64Word.rotL(25); */ // rotL: function (n) { // return this.shiftL(n).or(this.shiftR(64 - n)); // }, /** * Rotates this word n bits to the right. * * @param {number} n The number of bits to rotate. * * @return {X64Word} A new x64-Word object after rotating. * * @example * * var rotated = x64Word.rotR(7); */ // rotR: function (n) { // return this.shiftR(n).or(this.shiftL(64 - n)); // }, /** * Adds this word with the passed word. * * @param {X64Word} word The x64-Word to add with this word. * * @return {X64Word} A new x64-Word object after adding. * * @example * * var added = x64Word.add(anotherX64Word); */ // add: function (word) { // var low = (this.low + word.low) | 0; // var carry = (low >>> 0) < (this.low >>> 0) ? 1 : 0; // var high = (this.high + word.high + carry) | 0; // return X64Word.create(high, low); // } }); /** * An array of 64-bit words. * * @property {Array} words The array of CryptoJS.x64.Word objects. * @property {number} sigBytes The number of significant bytes in this word array. */ var X64WordArray = C_x64.WordArray = Base.extend({ /** * Initializes a newly created word array. * * @param {Array} words (Optional) An array of CryptoJS.x64.Word objects. * @param {number} sigBytes (Optional) The number of significant bytes in the words. * * @example * * var wordArray = CryptoJS.x64.WordArray.create(); * * var wordArray = CryptoJS.x64.WordArray.create([ * CryptoJS.x64.Word.create(0x00010203, 0x04050607), * CryptoJS.x64.Word.create(0x18191a1b, 0x1c1d1e1f) * ]); * * var wordArray = CryptoJS.x64.WordArray.create([ * CryptoJS.x64.Word.create(0x00010203, 0x04050607), * CryptoJS.x64.Word.create(0x18191a1b, 0x1c1d1e1f) * ], 10); */ init: function (words, sigBytes) { words = this.words = words || []; if (sigBytes != undefined) { this.sigBytes = sigBytes; } else { this.sigBytes = words.length * 8; } }, /** * Converts this 64-bit word array to a 32-bit word array. * * @return {CryptoJS.lib.WordArray} This word array's data as a 32-bit word array. * * @example * * var x32WordArray = x64WordArray.toX32(); */ toX32: function () { // Shortcuts var x64Words = this.words; var x64WordsLength = x64Words.length; // Convert var x32Words = []; for (var i = 0; i < x64WordsLength; i++) { var x64Word = x64Words[i]; x32Words.push(x64Word.high); x32Words.push(x64Word.low); } return X32WordArray.create(x32Words, this.sigBytes); }, /** * Creates a copy of this word array. * * @return {X64WordArray} The clone. * * @example * * var clone = x64WordArray.clone(); */ clone: function () { var clone = Base.clone.call(this); // Clone "words" array var words = clone.words = this.words.slice(0); // Clone each X64Word object var wordsLength = words.length; for (var i = 0; i < wordsLength; i++) { words[i] = words[i].clone(); } return clone; } }); }()); return CryptoJS; })); },{"./core":31}],63:[function(_dereq_,module,exports){ var assert = _dereq_('assert') var BigInteger = _dereq_('bigi') var Point = _dereq_('./point') function Curve(p, a, b, Gx, Gy, n, h) { this.p = p this.a = a this.b = b this.G = Point.fromAffine(this, Gx, Gy) this.n = n this.h = h this.infinity = new Point(this, null, null, BigInteger.ZERO) // result caching this.pOverFour = p.add(BigInteger.ONE).shiftRight(2) } Curve.prototype.pointFromX = function(isOdd, x) { var alpha = x.pow(3).add(this.a.multiply(x)).add(this.b).mod(this.p) var beta = alpha.modPow(this.pOverFour, this.p) var y = beta if (beta.isEven() ^ !isOdd) { y = this.p.subtract(y) // -y % p } return Point.fromAffine(this, x, y) } Curve.prototype.isInfinity = function(Q) { if (Q === this.infinity) return true return Q.z.signum() === 0 && Q.y.signum() !== 0 } Curve.prototype.isOnCurve = function(Q) { if (this.isInfinity(Q)) return true var x = Q.affineX var y = Q.affineY var a = this.a var b = this.b var p = this.p // Check that xQ and yQ are integers in the interval [0, p - 1] if (x.signum() < 0 || x.compareTo(p) >= 0) return false if (y.signum() < 0 || y.compareTo(p) >= 0) return false // and check that y^2 = x^3 + ax + b (mod p) var lhs = y.square().mod(p) var rhs = x.pow(3).add(a.multiply(x)).add(b).mod(p) return lhs.equals(rhs) } /** * Validate an elliptic curve point. * * See SEC 1, section 3.2.2.1: Elliptic Curve Public Key Validation Primitive */ Curve.prototype.validate = function(Q) { // Check Q != O assert(!this.isInfinity(Q), 'Point is at infinity') assert(this.isOnCurve(Q), 'Point is not on the curve') // Check nQ = O (where Q is a scalar multiple of G) var nQ = Q.multiply(this.n) assert(this.isInfinity(nQ), 'Point is not a scalar multiple of G') return true } module.exports = Curve },{"./point":67,"assert":4,"bigi":3}],64:[function(_dereq_,module,exports){ module.exports={ "secp128r1": { "p": "fffffffdffffffffffffffffffffffff", "a": "fffffffdfffffffffffffffffffffffc", "b": "e87579c11079f43dd824993c2cee5ed3", "n": "fffffffe0000000075a30d1b9038a115", "h": "01", "Gx": "161ff7528b899b2d0c28607ca52c5b86", "Gy": "cf5ac8395bafeb13c02da292dded7a83" }, "secp160k1": { "p": "fffffffffffffffffffffffffffffffeffffac73", "a": "00", "b": "07", "n": "0100000000000000000001b8fa16dfab9aca16b6b3", "h": "01", "Gx": "3b4c382ce37aa192a4019e763036f4f5dd4d7ebb", "Gy": "938cf935318fdced6bc28286531733c3f03c4fee" }, "secp160r1": { "p": "ffffffffffffffffffffffffffffffff7fffffff", "a": "ffffffffffffffffffffffffffffffff7ffffffc", "b": "1c97befc54bd7a8b65acf89f81d4d4adc565fa45", "n": "0100000000000000000001f4c8f927aed3ca752257", "h": "01", "Gx": "4a96b5688ef573284664698968c38bb913cbfc82", "Gy": "23a628553168947d59dcc912042351377ac5fb32" }, "secp192k1": { "p": "fffffffffffffffffffffffffffffffffffffffeffffee37", "a": "00", "b": "03", "n": "fffffffffffffffffffffffe26f2fc170f69466a74defd8d", "h": "01", "Gx": "db4ff10ec057e9ae26b07d0280b7f4341da5d1b1eae06c7d", "Gy": "9b2f2f6d9c5628a7844163d015be86344082aa88d95e2f9d" }, "secp192r1": { "p": "fffffffffffffffffffffffffffffffeffffffffffffffff", "a": "fffffffffffffffffffffffffffffffefffffffffffffffc", "b": "64210519e59c80e70fa7e9ab72243049feb8deecc146b9b1", "n": "ffffffffffffffffffffffff99def836146bc9b1b4d22831", "h": "01", "Gx": "188da80eb03090f67cbf20eb43a18800f4ff0afd82ff1012", "Gy": "07192b95ffc8da78631011ed6b24cdd573f977a11e794811" }, "secp224r1": { "p": "ffffffffffffffffffffffffffffffff000000000000000000000001", "a": "fffffffffffffffffffffffffffffffefffffffffffffffffffffffe", "b": "b4050a850c04b3abf54132565044b0b7d7bfd8ba270b39432355ffb4", "n": "ffffffffffffffffffffffffffff16a2e0b8f03e13dd29455c5c2a3d", "h": "01", "Gx": "b70e0cbd6bb4bf7f321390b94a03c1d356c21122343280d6115c1d21", "Gy": "bd376388b5f723fb4c22dfe6cd4375a05a07476444d5819985007e34" }, "secp256k1": { "p": "fffffffffffffffffffffffffffffffffffffffffffffffffffffffefffffc2f", "a": "00", "b": "07", "n": "fffffffffffffffffffffffffffffffebaaedce6af48a03bbfd25e8cd0364141", "h": "01", "Gx": "79be667ef9dcbbac55a06295ce870b07029bfcdb2dce28d959f2815b16f81798", "Gy": "483ada7726a3c4655da4fbfc0e1108a8fd17b448a68554199c47d08ffb10d4b8" }, "secp256r1": { "p": "ffffffff00000001000000000000000000000000ffffffffffffffffffffffff", "a": "ffffffff00000001000000000000000000000000fffffffffffffffffffffffc", "b": "5ac635d8aa3a93e7b3ebbd55769886bc651d06b0cc53b0f63bce3c3e27d2604b", "n": "ffffffff00000000ffffffffffffffffbce6faada7179e84f3b9cac2fc632551", "h": "01", "Gx": "6b17d1f2e12c4247f8bce6e563a440f277037d812deb33a0f4a13945d898c296", "Gy": "4fe342e2fe1a7f9b8ee7eb4a7c0f9e162bce33576b315ececbb6406837bf51f5" } } },{}],65:[function(_dereq_,module,exports){ var Point = _dereq_('./point') var Curve = _dereq_('./curve') var getCurveByName = _dereq_('./names') module.exports = { Curve: Curve, Point: Point, getCurveByName: getCurveByName } },{"./curve":63,"./names":66,"./point":67}],66:[function(_dereq_,module,exports){ var BigInteger = _dereq_('bigi') var curves = _dereq_('./curves') var Curve = _dereq_('./curve') function getCurveByName(name) { var curve = curves[name] if (!curve) return null var p = new BigInteger(curve.p, 16) var a = new BigInteger(curve.a, 16) var b = new BigInteger(curve.b, 16) var n = new BigInteger(curve.n, 16) var h = new BigInteger(curve.h, 16) var Gx = new BigInteger(curve.Gx, 16) var Gy = new BigInteger(curve.Gy, 16) return new Curve(p, a, b, Gx, Gy, n, h) } module.exports = getCurveByName },{"./curve":63,"./curves":64,"bigi":3}],67:[function(_dereq_,module,exports){ (function (Buffer){ var assert = _dereq_('assert') var BigInteger = _dereq_('bigi') var THREE = BigInteger.valueOf(3) function Point(curve, x, y, z) { assert.notStrictEqual(z, undefined, 'Missing Z coordinate') this.curve = curve this.x = x this.y = y this.z = z this._zInv = null this.compressed = true } Object.defineProperty(Point.prototype, 'zInv', { get: function() { if (this._zInv === null) { this._zInv = this.z.modInverse(this.curve.p) } return this._zInv } }) Object.defineProperty(Point.prototype, 'affineX', { get: function() { return this.x.multiply(this.zInv).mod(this.curve.p) } }) Object.defineProperty(Point.prototype, 'affineY', { get: function() { return this.y.multiply(this.zInv).mod(this.curve.p) } }) Point.fromAffine = function(curve, x, y) { return new Point(curve, x, y, BigInteger.ONE) } Point.prototype.equals = function(other) { if (other === this) return true if (this.curve.isInfinity(this)) return this.curve.isInfinity(other) if (this.curve.isInfinity(other)) return this.curve.isInfinity(this) // u = Y2 * Z1 - Y1 * Z2 var u = other.y.multiply(this.z).subtract(this.y.multiply(other.z)).mod(this.curve.p) if (u.signum() !== 0) return false // v = X2 * Z1 - X1 * Z2 var v = other.x.multiply(this.z).subtract(this.x.multiply(other.z)).mod(this.curve.p) return v.signum() === 0 } Point.prototype.negate = function() { var y = this.curve.p.subtract(this.y) return new Point(this.curve, this.x, y, this.z) } Point.prototype.add = function(b) { if (this.curve.isInfinity(this)) return b if (this.curve.isInfinity(b)) return this var x1 = this.x var y1 = this.y var x2 = b.x var y2 = b.y // u = Y2 * Z1 - Y1 * Z2 var u = y2.multiply(this.z).subtract(y1.multiply(b.z)).mod(this.curve.p) // v = X2 * Z1 - X1 * Z2 var v = x2.multiply(this.z).subtract(x1.multiply(b.z)).mod(this.curve.p) if (v.signum() === 0) { if (u.signum() === 0) { return this.twice() // this == b, so double } return this.curve.infinity // this = -b, so infinity } var v2 = v.square() var v3 = v2.multiply(v) var x1v2 = x1.multiply(v2) var zu2 = u.square().multiply(this.z) // x3 = v * (z2 * (z1 * u^2 - 2 * x1 * v^2) - v^3) var x3 = zu2.subtract(x1v2.shiftLeft(1)).multiply(b.z).subtract(v3).multiply(v).mod(this.curve.p) // y3 = z2 * (3 * x1 * u * v^2 - y1 * v^3 - z1 * u^3) + u * v^3 var y3 = x1v2.multiply(THREE).multiply(u).subtract(y1.multiply(v3)).subtract(zu2.multiply(u)).multiply(b.z).add(u.multiply(v3)).mod(this.curve.p) // z3 = v^3 * z1 * z2 var z3 = v3.multiply(this.z).multiply(b.z).mod(this.curve.p) return new Point(this.curve, x3, y3, z3) } Point.prototype.twice = function() { if (this.curve.isInfinity(this)) return this if (this.y.signum() === 0) return this.curve.infinity var x1 = this.x var y1 = this.y var y1z1 = y1.multiply(this.z) var y1sqz1 = y1z1.multiply(y1).mod(this.curve.p) var a = this.curve.a // w = 3 * x1^2 + a * z1^2 var w = x1.square().multiply(THREE) if (a.signum() !== 0) { w = w.add(this.z.square().multiply(a)) } w = w.mod(this.curve.p) // x3 = 2 * y1 * z1 * (w^2 - 8 * x1 * y1^2 * z1) var x3 = w.square().subtract(x1.shiftLeft(3).multiply(y1sqz1)).shiftLeft(1).multiply(y1z1).mod(this.curve.p) // y3 = 4 * y1^2 * z1 * (3 * w * x1 - 2 * y1^2 * z1) - w^3 var y3 = w.multiply(THREE).multiply(x1).subtract(y1sqz1.shiftLeft(1)).shiftLeft(2).multiply(y1sqz1).subtract(w.pow(3)).mod(this.curve.p) // z3 = 8 * (y1 * z1)^3 var z3 = y1z1.pow(3).shiftLeft(3).mod(this.curve.p) return new Point(this.curve, x3, y3, z3) } // Simple NAF (Non-Adjacent Form) multiplication algorithm // TODO: modularize the multiplication algorithm Point.prototype.multiply = function(k) { if (this.curve.isInfinity(this)) return this if (k.signum() === 0) return this.curve.infinity var e = k var h = e.multiply(THREE) var neg = this.negate() var R = this for (var i = h.bitLength() - 2; i > 0; --i) { R = R.twice() var hBit = h.testBit(i) var eBit = e.testBit(i) if (hBit != eBit) { R = R.add(hBit ? this : neg) } } return R } // Compute this*j + x*k (simultaneous multiplication) Point.prototype.multiplyTwo = function(j, x, k) { var i if (j.bitLength() > k.bitLength()) i = j.bitLength() - 1 else i = k.bitLength() - 1 var R = this.curve.infinity var both = this.add(x) while (i >= 0) { R = R.twice() var jBit = j.testBit(i) var kBit = k.testBit(i) if (jBit) { if (kBit) { R = R.add(both) } else { R = R.add(this) } } else { if (kBit) { R = R.add(x) } } --i } return R } Point.prototype.getEncoded = function(compressed) { if (compressed == undefined) compressed = this.compressed if (this.curve.isInfinity(this)) return new Buffer('00', 'hex') // Infinity point encoded is simply '00' var x = this.affineX var y = this.affineY var buffer // Determine size of q in bytes var byteLength = Math.floor((this.curve.p.bitLength() + 7) / 8) // 0x02/0x03 | X if (compressed) { buffer = new Buffer(1 + byteLength) buffer.writeUInt8(y.isEven() ? 0x02 : 0x03, 0) // 0x04 | X | Y } else { buffer = new Buffer(1 + byteLength + byteLength) buffer.writeUInt8(0x04, 0) y.toBuffer(byteLength).copy(buffer, 1 + byteLength) } x.toBuffer(byteLength).copy(buffer, 1) return buffer } Point.decodeFrom = function(curve, buffer) { var type = buffer.readUInt8(0) var compressed = (type !== 4) var x = BigInteger.fromBuffer(buffer.slice(1, 33)) var byteLength = Math.floor((curve.p.bitLength() + 7) / 8) var Q if (compressed) { assert.equal(buffer.length, byteLength + 1, 'Invalid sequence length') assert(type === 0x02 || type === 0x03, 'Invalid sequence tag') var isOdd = (type === 0x03) Q = curve.pointFromX(isOdd, x) } else { assert.equal(buffer.length, 1 + byteLength + byteLength, 'Invalid sequence length') var y = BigInteger.fromBuffer(buffer.slice(1 + byteLength)) Q = Point.fromAffine(curve, x, y) } Q.compressed = compressed return Q } Point.prototype.toString = function () { if (this.curve.isInfinity(this)) return '(INFINITY)' return '(' + this.affineX.toString() + ',' + this.affineY.toString() + ')' } module.exports = Point }).call(this,_dereq_("buffer").Buffer) },{"assert":4,"bigi":3,"buffer":8}],68:[function(_dereq_,module,exports){ (function (process,Buffer){ // Closure compiler error - result of 'not' operator not being used //!function(globals){ (function(globals){ 'use strict' //*** UMD BEGIN if (typeof define !== 'undefined' && define.amd) { //require.js / AMD define([], function() { return secureRandom }) } else if (typeof module !== 'undefined' && module.exports) { //CommonJS module.exports = secureRandom } else { //script / browser globals.secureRandom = secureRandom } //*** UMD END //options.type is the only valid option function secureRandom(count, options) { options = options || {type: 'Array'} //we check for process.pid to prevent browserify from tricking us if (typeof process != 'undefined' && typeof process.pid == 'number') { return nodeRandom(count, options) } else { var crypto = window.crypto || window.msCrypto if (!crypto) throw new Error("Your browser does not support window.crypto.") return browserRandom(count, options) } } function nodeRandom(count, options) { var crypto = _dereq_('crypto') var buf = crypto.randomBytes(count) switch (options.type) { case 'Array': return [].slice.call(buf) case 'Buffer': return buf case 'Uint8Array': var arr = new Uint8Array(count) for (var i = 0; i < count; ++i) { arr[i] = buf.readUInt8(i) } return arr default: throw new Error(options.type + " is unsupported.") } } function browserRandom(count, options) { var nativeArr = new Uint8Array(count) var crypto = window.crypto || window.msCrypto crypto.getRandomValues(nativeArr) switch (options.type) { case 'Array': return [].slice.call(nativeArr) case 'Buffer': try { var b = new Buffer(1) } catch(e) { throw new Error('Buffer not supported in this environment. Use Node.js or Browserify for browser support.')} return new Buffer(nativeArr) case 'Uint8Array': return nativeArr default: throw new Error(options.type + " is unsupported.") } } secureRandom.randomArray = function(byteCount) { return secureRandom(byteCount, {type: 'Array'}) } secureRandom.randomUint8Array = function(byteCount) { return secureRandom(byteCount, {type: 'Uint8Array'}) } secureRandom.randomBuffer = function(byteCount) { return secureRandom(byteCount, {type: 'Buffer'}) } })(this); }).call(this,_dereq_("FWaASH"),_dereq_("buffer").Buffer) },{"FWaASH":12,"buffer":8,"crypto":7}],69:[function(_dereq_,module,exports){ (function (Buffer){ var assert = _dereq_('assert') var base58check = _dereq_('./base58check') var networks = _dereq_('./networks') var scripts = _dereq_('./scripts') function findScriptTypeByVersion(version) { for (var networkName in networks) { var network = networks[networkName] if (version === network.pubKeyHash) return 'pubkeyhash' if (version === network.scriptHash) return 'scripthash' } } function Address(hash, version) { assert(Buffer.isBuffer(hash), 'Expected Buffer, got ' + hash) assert.strictEqual(hash.length, 20, 'Invalid hash length') assert.strictEqual(version & 0xff, version, 'Invalid version byte') this.hash = hash this.version = version } // Import functions Address.fromBase58Check = function(string) { var payload = base58check.decode(string) var version = payload.readUInt8(0) var hash = payload.slice(1) return new Address(hash, version) } Address.fromOutputScript = function(script, network) { network = network || networks.bitcoin var type = scripts.classifyOutput(script) if (type === 'pubkeyhash') return new Address(script.chunks[2], network.pubKeyHash) if (type === 'scripthash') return new Address(script.chunks[1], network.scriptHash) assert(false, type + ' has no matching Address') } // Export functions Address.prototype.toBase58Check = function () { var payload = new Buffer(21) payload.writeUInt8(this.version, 0) this.hash.copy(payload, 1) return base58check.encode(payload) } Address.prototype.toOutputScript = function() { var scriptType = findScriptTypeByVersion(this.version) if (scriptType === 'pubkeyhash') return scripts.pubKeyHashOutput(this.hash) if (scriptType === 'scripthash') return scripts.scriptHashOutput(this.hash) assert(false, this.toString() + ' has no matching Script') } Address.prototype.toString = Address.prototype.toBase58Check module.exports = Address }).call(this,_dereq_("buffer").Buffer) },{"./base58check":70,"./networks":81,"./scripts":84,"assert":4,"buffer":8}],70:[function(_dereq_,module,exports){ (function (Buffer){ // https://en.bitcoin.it/wiki/Base58Check_encoding var assert = _dereq_('assert') var base58 = _dereq_('bs58') var crypto = _dereq_('./crypto') // Encode a buffer as a base58-check-encoded string function encode(payload) { var checksum = crypto.hash256(payload).slice(0, 4) return base58.encode(Buffer.concat([ payload, checksum ])) } // Decode a base58-check-encoded string to a buffer function decode(string) { var buffer = base58.decode(string) var payload = buffer.slice(0, -4) var checksum = buffer.slice(-4) var newChecksum = crypto.hash256(payload).slice(0, 4) assert.deepEqual(newChecksum, checksum, 'Invalid checksum') return payload } module.exports = { encode: encode, decode: decode } }).call(this,_dereq_("buffer").Buffer) },{"./crypto":73,"assert":4,"bs58":15,"buffer":8}],71:[function(_dereq_,module,exports){ var assert = _dereq_('assert') var opcodes = _dereq_('./opcodes') // https://github.com/feross/buffer/blob/master/index.js#L1127 function verifuint(value, max) { assert(typeof value === 'number', 'cannot write a non-number as a number') assert(value >= 0, 'specified a negative value for writing an unsigned value') assert(value <= max, 'value is larger than maximum value for type') assert(Math.floor(value) === value, 'value has a fractional component') } function pushDataSize(i) { return i < opcodes.OP_PUSHDATA1 ? 1 : i < 0xff ? 2 : i < 0xffff ? 3 : 5 } function readPushDataInt(buffer, offset) { var opcode = buffer.readUInt8(offset) var number, size // ~6 bit if (opcode < opcodes.OP_PUSHDATA1) { number = opcode size = 1 // 8 bit } else if (opcode === opcodes.OP_PUSHDATA1) { number = buffer.readUInt8(offset + 1) size = 2 // 16 bit } else if (opcode === opcodes.OP_PUSHDATA2) { number = buffer.readUInt16LE(offset + 1) size = 3 // 32 bit } else { assert.equal(opcode, opcodes.OP_PUSHDATA4, 'Unexpected opcode') number = buffer.readUInt32LE(offset + 1) size = 5 } return { opcode: opcode, number: number, size: size } } function readUInt64LE(buffer, offset) { var a = buffer.readUInt32LE(offset) var b = buffer.readUInt32LE(offset + 4) b *= 0x100000000 verifuint(b + a, 0x001fffffffffffff) return b + a } function readVarInt(buffer, offset) { var t = buffer.readUInt8(offset) var number, size // 8 bit if (t < 253) { number = t size = 1 // 16 bit } else if (t < 254) { number = buffer.readUInt16LE(offset + 1) size = 3 // 32 bit } else if (t < 255) { number = buffer.readUInt32LE(offset + 1) size = 5 // 64 bit } else { number = readUInt64LE(buffer, offset + 1) size = 9 } return { number: number, size: size } } function writePushDataInt(buffer, number, offset) { var size = pushDataSize(number) // ~6 bit if (size === 1) { buffer.writeUInt8(number, offset) // 8 bit } else if (size === 2) { buffer.writeUInt8(opcodes.OP_PUSHDATA1, offset) buffer.writeUInt8(number, offset + 1) // 16 bit } else if (size === 3) { buffer.writeUInt8(opcodes.OP_PUSHDATA2, offset) buffer.writeUInt16LE(number, offset + 1) // 32 bit } else { buffer.writeUInt8(opcodes.OP_PUSHDATA4, offset) buffer.writeUInt32LE(number, offset + 1) } return size } function writeUInt64LE(buffer, value, offset) { verifuint(value, 0x001fffffffffffff) buffer.writeInt32LE(value & -1, offset) buffer.writeUInt32LE(Math.floor(value / 0x100000000), offset + 4) } function varIntSize(i) { return i < 253 ? 1 : i < 0x10000 ? 3 : i < 0x100000000 ? 5 : 9 } function writeVarInt(buffer, number, offset) { var size = varIntSize(number) // 8 bit if (size === 1) { buffer.writeUInt8(number, offset) // 16 bit } else if (size === 3) { buffer.writeUInt8(253, offset) buffer.writeUInt16LE(number, offset + 1) // 32 bit } else if (size === 5) { buffer.writeUInt8(254, offset) buffer.writeUInt32LE(number, offset + 1) // 64 bit } else { buffer.writeUInt8(255, offset) writeUInt64LE(buffer, number, offset + 1) } return size } module.exports = { pushDataSize: pushDataSize, readPushDataInt: readPushDataInt, readUInt64LE: readUInt64LE, readVarInt: readVarInt, varIntSize: varIntSize, writePushDataInt: writePushDataInt, writeUInt64LE: writeUInt64LE, writeVarInt: writeVarInt } },{"./opcodes":82,"assert":4}],72:[function(_dereq_,module,exports){ (function (Buffer){ var assert = _dereq_('assert') var Crypto = _dereq_('crypto-js') var WordArray = Crypto.lib.WordArray function bufferToWordArray(buffer) { assert(Buffer.isBuffer(buffer), 'Expected Buffer, got', buffer) var words = [] for (var i = 0, b = 0; i < buffer.length; i++, b += 8) { words[b >>> 5] |= buffer[i] << (24 - b % 32) } return new WordArray.init(words, buffer.length) } function wordArrayToBuffer(wordArray) { assert(Array.isArray(wordArray.words), 'Expected WordArray, got' + wordArray) var words = wordArray.words var buffer = new Buffer(words.length * 4) words.forEach(function(value, i) { buffer.writeInt32BE(value & -1, i * 4) }) return buffer } module.exports = { bufferToWordArray: bufferToWordArray, wordArrayToBuffer: wordArrayToBuffer } }).call(this,_dereq_("buffer").Buffer) },{"assert":4,"buffer":8,"crypto-js":37}],73:[function(_dereq_,module,exports){ (function (Buffer){ // Crypto, crypto, where art thou crypto var assert = _dereq_('assert') var CryptoJS = _dereq_('crypto-js') var crypto = _dereq_('crypto') var convert = _dereq_('./convert') function hash160(buffer) { return ripemd160(sha256(buffer)) } function hash256(buffer) { return sha256(sha256(buffer)) } function ripemd160(buffer) { return crypto.createHash('rmd160').update(buffer).digest() } function sha1(buffer) { return crypto.createHash('sha1').update(buffer).digest() } function sha256(buffer) { return crypto.createHash('sha256').update(buffer).digest() } // FIXME: Name not consistent with others function HmacSHA256(buffer, secret) { return crypto.createHmac('sha256', secret).update(buffer).digest() } function HmacSHA512(data, secret) { assert(Buffer.isBuffer(data), 'Expected Buffer for data, got ' + data) assert(Buffer.isBuffer(secret), 'Expected Buffer for secret, got ' + secret) var dataWords = convert.bufferToWordArray(data) var secretWords = convert.bufferToWordArray(secret) var hash = CryptoJS.HmacSHA512(dataWords, secretWords) return convert.wordArrayToBuffer(hash) } module.exports = { ripemd160: ripemd160, sha1: sha1, sha256: sha256, hash160: hash160, hash256: hash256, HmacSHA256: HmacSHA256, HmacSHA512: HmacSHA512 } }).call(this,_dereq_("buffer").Buffer) },{"./convert":72,"assert":4,"buffer":8,"crypto":19,"crypto-js":37}],74:[function(_dereq_,module,exports){ (function (Buffer){ var assert = _dereq_('assert') var crypto = _dereq_('./crypto') var BigInteger = _dereq_('bigi') var ECSignature = _dereq_('./ecsignature') var Point = _dereq_('ecurve').Point // https://tools.ietf.org/html/rfc6979#section-3.2 function deterministicGenerateK(curve, hash, d) { assert(Buffer.isBuffer(hash), 'Hash must be a Buffer, not ' + hash) assert.equal(hash.length, 32, 'Hash must be 256 bit') assert(d instanceof BigInteger, 'Private key must be a BigInteger') var x = d.toBuffer(32) var k = new Buffer(32) var v = new Buffer(32) // Step B v.fill(1) // Step C k.fill(0) // Step D k = crypto.HmacSHA256(Buffer.concat([v, new Buffer([0]), x, hash]), k) // Step E v = crypto.HmacSHA256(v, k) // Step F k = crypto.HmacSHA256(Buffer.concat([v, new Buffer([1]), x, hash]), k) // Step G v = crypto.HmacSHA256(v, k) // Step H1/H2a, ignored as tlen === qlen (256 bit) // Step H2b v = crypto.HmacSHA256(v, k) var T = BigInteger.fromBuffer(v) // Step H3, repeat until T is within the interval [1, n - 1] while ((T.signum() <= 0) || (T.compareTo(curve.n) >= 0)) { k = crypto.HmacSHA256(Buffer.concat([v, new Buffer([0])]), k) v = crypto.HmacSHA256(v, k) T = BigInteger.fromBuffer(v) } return T } function sign(curve, hash, d) { var k = deterministicGenerateK(curve, hash, d) var n = curve.n var G = curve.G var Q = G.multiply(k) var e = BigInteger.fromBuffer(hash) var r = Q.affineX.mod(n) assert.notEqual(r.signum(), 0, 'Invalid R value') var s = k.modInverse(n).multiply(e.add(d.multiply(r))).mod(n) assert.notEqual(s.signum(), 0, 'Invalid S value') var N_OVER_TWO = n.shiftRight(1) // enforce low S values, see bip62: 'low s values in signatures' if (s.compareTo(N_OVER_TWO) > 0) { s = n.subtract(s) } return new ECSignature(r, s) } function verify(curve, hash, signature, Q) { var e = BigInteger.fromBuffer(hash) return verifyRaw(curve, e, signature, Q) } function verifyRaw(curve, e, signature, Q) { var n = curve.n var G = curve.G var r = signature.r var s = signature.s if (r.signum() === 0 || r.compareTo(n) >= 0) return false if (s.signum() === 0 || s.compareTo(n) >= 0) return false var c = s.modInverse(n) var u1 = e.multiply(c).mod(n) var u2 = r.multiply(c).mod(n) var point = G.multiplyTwo(u1, Q, u2) var v = point.affineX.mod(n) return v.equals(r) } /** * Recover a public key from a signature. * * See SEC 1: Elliptic Curve Cryptography, section 4.1.6, "Public * Key Recovery Operation". * * http://www.secg.org/download/aid-780/sec1-v2.pdf */ function recoverPubKey(curve, e, signature, i) { assert.strictEqual(i & 3, i, 'Recovery param is more than two bits') var r = signature.r var s = signature.s // A set LSB signifies that the y-coordinate is odd var isYOdd = i & 1 // The more significant bit specifies whether we should use the // first or second candidate key. var isSecondKey = i >> 1 var n = curve.n var G = curve.G // 1.1 Let x = r + jn var x = isSecondKey ? r.add(n) : r var R = curve.pointFromX(isYOdd, x) // 1.4 Check that nR is at infinity var nR = R.multiply(n) assert(curve.isInfinity(nR), 'nR is not a valid curve point') // Compute -e from e var eNeg = e.negate().mod(n) // 1.6.1 Compute Q = r^-1 (sR - eG) // Q = r^-1 (sR + -eG) var rInv = r.modInverse(n) var Q = R.multiplyTwo(s, G, eNeg).multiply(rInv) curve.validate(Q) return Q } /** * Calculate pubkey extraction parameter. * * When extracting a pubkey from a signature, we have to * distinguish four different cases. Rather than putting this * burden on the verifier, Bitcoin includes a 2-bit value with the * signature. * * This function simply tries all four cases and returns the value * that resulted in a successful pubkey recovery. */ function calcPubKeyRecoveryParam(curve, e, signature, Q) { for (var i = 0; i < 4; i++) { var Qprime = recoverPubKey(curve, e, signature, i) // 1.6.2 Verify Q if (Qprime.equals(Q)) { return i } } throw new Error('Unable to find valid recovery factor') } module.exports = { calcPubKeyRecoveryParam: calcPubKeyRecoveryParam, deterministicGenerateK: deterministicGenerateK, recoverPubKey: recoverPubKey, sign: sign, verify: verify, verifyRaw: verifyRaw } }).call(this,_dereq_("buffer").Buffer) },{"./crypto":73,"./ecsignature":77,"assert":4,"bigi":3,"buffer":8,"ecurve":65}],75:[function(_dereq_,module,exports){ (function (Buffer){ var assert = _dereq_('assert') var base58check = _dereq_('./base58check') var ecdsa = _dereq_('./ecdsa') var networks = _dereq_('./networks') var secureRandom = _dereq_('secure-random') var BigInteger = _dereq_('bigi') var ECPubKey = _dereq_('./ecpubkey') var ecurve = _dereq_('ecurve') var curve = ecurve.getCurveByName('secp256k1') function ECKey(d, compressed) { assert(d.signum() > 0, 'Private key must be greater than 0') assert(d.compareTo(curve.n) < 0, 'Private key must be less than the curve order') var Q = curve.G.multiply(d) this.d = d this.pub = new ECPubKey(Q, compressed) } // Static constructors ECKey.fromWIF = function(string) { var payload = base58check.decode(string) var compressed = false // Ignore the version byte payload = payload.slice(1) if (payload.length === 33) { assert.strictEqual(payload[32], 0x01, 'Invalid compression flag') // Truncate the compression flag payload = payload.slice(0, -1) compressed = true } assert.equal(payload.length, 32, 'Invalid WIF payload length') var d = BigInteger.fromBuffer(payload) return new ECKey(d, compressed) } ECKey.makeRandom = function(compressed, rng) { rng = rng || secureRandom.randomBuffer var buffer = rng(32) assert(Buffer.isBuffer(buffer), 'Expected Buffer, got ' + buffer) var d = BigInteger.fromBuffer(buffer) d = d.mod(curve.n) return new ECKey(d, compressed) } // Export functions ECKey.prototype.toWIF = function(network) { network = network || networks.bitcoin var bufferLen = this.pub.compressed ? 34 : 33 var buffer = new Buffer(bufferLen) buffer.writeUInt8(network.wif, 0) this.d.toBuffer(32).copy(buffer, 1) if (this.pub.compressed) { buffer.writeUInt8(0x01, 33) } return base58check.encode(buffer) } // Operations ECKey.prototype.sign = function(hash) { return ecdsa.sign(curve, hash, this.d) } module.exports = ECKey }).call(this,_dereq_("buffer").Buffer) },{"./base58check":70,"./ecdsa":74,"./ecpubkey":76,"./networks":81,"assert":4,"bigi":3,"buffer":8,"ecurve":65,"secure-random":68}],76:[function(_dereq_,module,exports){ (function (Buffer){ var assert = _dereq_('assert') var crypto = _dereq_('./crypto') var ecdsa = _dereq_('./ecdsa') var networks = _dereq_('./networks') var Address = _dereq_('./address') var ecurve = _dereq_('ecurve') var curve = ecurve.getCurveByName('secp256k1') function ECPubKey(Q, compressed) { assert(Q instanceof ecurve.Point, 'Expected Point, got ' + Q) if (compressed == undefined) compressed = true assert.strictEqual(typeof compressed, 'boolean', 'Expected boolean, got ' + compressed) this.compressed = compressed this.Q = Q } // Static constructors ECPubKey.fromBuffer = function(buffer) { var Q = ecurve.Point.decodeFrom(curve, buffer) return new ECPubKey(Q, Q.compressed) } ECPubKey.fromHex = function(hex) { return ECPubKey.fromBuffer(new Buffer(hex, 'hex')) } // Operations ECPubKey.prototype.getAddress = function(network) { network = network || networks.bitcoin return new Address(crypto.hash160(this.toBuffer()), network.pubKeyHash) } ECPubKey.prototype.verify = function(hash, signature) { return ecdsa.verify(curve, hash, signature, this.Q) } // Export functions ECPubKey.prototype.toBuffer = function() { return this.Q.getEncoded(this.compressed) } ECPubKey.prototype.toHex = function() { return this.toBuffer().toString('hex') } module.exports = ECPubKey }).call(this,_dereq_("buffer").Buffer) },{"./address":69,"./crypto":73,"./ecdsa":74,"./networks":81,"assert":4,"buffer":8,"ecurve":65}],77:[function(_dereq_,module,exports){ (function (Buffer){ var assert = _dereq_('assert') var BigInteger = _dereq_('bigi') function ECSignature(r, s) { assert(r instanceof BigInteger, 'Expected BigInteger, got ' + r) assert(s instanceof BigInteger, 'Expected BigInteger, got ' + s) this.r = r this.s = s } // Import operations ECSignature.parseCompact = function(buffer) { assert.equal(buffer.length, 65, 'Invalid signature length') var i = buffer.readUInt8(0) - 27 // At most 3 bits assert.equal(i, i & 7, 'Invalid signature parameter') var compressed = !!(i & 4) // Recovery param only i = i & 3 var r = BigInteger.fromBuffer(buffer.slice(1, 33)) var s = BigInteger.fromBuffer(buffer.slice(33)) return { compressed: compressed, i: i, signature: new ECSignature(r, s) } } ECSignature.fromDER = function(buffer) { assert.equal(buffer.readUInt8(0), 0x30, 'Not a DER sequence') assert.equal(buffer.readUInt8(1), buffer.length - 2, 'Invalid sequence length') assert.equal(buffer.readUInt8(2), 0x02, 'Expected a DER integer') var rLen = buffer.readUInt8(3) assert(rLen > 0, 'R length is zero') var offset = 4 + rLen assert.equal(buffer.readUInt8(offset), 0x02, 'Expected a DER integer (2)') var sLen = buffer.readUInt8(offset + 1) assert(sLen > 0, 'S length is zero') var rB = buffer.slice(4, offset) var sB = buffer.slice(offset + 2) offset += 2 + sLen if (rLen > 1 && rB.readUInt8(0) === 0x00) { assert(rB.readUInt8(1) & 0x80, 'R value excessively padded') } if (sLen > 1 && sB.readUInt8(0) === 0x00) { assert(sB.readUInt8(1) & 0x80, 'S value excessively padded') } assert.equal(offset, buffer.length, 'Invalid DER encoding') var r = BigInteger.fromDERInteger(rB) var s = BigInteger.fromDERInteger(sB) assert(r.signum() >= 0, 'R value is negative') assert(s.signum() >= 0, 'S value is negative') return new ECSignature(r, s) } // FIXME: 0x00, 0x04, 0x80 are SIGHASH_* boundary constants, importing Transaction causes a circular dependency ECSignature.parseScriptSignature = function(buffer) { var hashType = buffer.readUInt8(buffer.length - 1) var hashTypeMod = hashType & ~0x80 assert(hashTypeMod > 0x00 && hashTypeMod < 0x04, 'Invalid hashType') return { signature: ECSignature.fromDER(buffer.slice(0, -1)), hashType: hashType } } // Export operations ECSignature.prototype.toCompact = function(i, compressed) { if (compressed) i += 4 i += 27 var buffer = new Buffer(65) buffer.writeUInt8(i, 0) this.r.toBuffer(32).copy(buffer, 1) this.s.toBuffer(32).copy(buffer, 33) return buffer } ECSignature.prototype.toDER = function() { var rBa = this.r.toDERInteger() var sBa = this.s.toDERInteger() var sequence = [] sequence.push(0x02) // INTEGER sequence.push(rBa.length) sequence = sequence.concat(rBa) sequence.push(0x02) // INTEGER sequence.push(sBa.length) sequence = sequence.concat(sBa) sequence.unshift(sequence.length) sequence.unshift(0x30) // SEQUENCE return new Buffer(sequence) } ECSignature.prototype.toScriptSignature = function(hashType) { var hashTypeBuffer = new Buffer(1) hashTypeBuffer.writeUInt8(hashType, 0) return Buffer.concat([this.toDER(), hashTypeBuffer]) } module.exports = ECSignature }).call(this,_dereq_("buffer").Buffer) },{"assert":4,"bigi":3,"buffer":8}],78:[function(_dereq_,module,exports){ (function (Buffer){ var assert = _dereq_('assert') var base58check = _dereq_('./base58check') var crypto = _dereq_('./crypto') var networks = _dereq_('./networks') var BigInteger = _dereq_('bigi') var ECKey = _dereq_('./eckey') var ECPubKey = _dereq_('./ecpubkey') var ecurve = _dereq_('ecurve') var curve = ecurve.getCurveByName('secp256k1') function findBIP32ParamsByVersion(version) { for (var name in networks) { var network = networks[name] for (var type in network.bip32) { if (version != network.bip32[type]) continue return { isPrivate: (type === 'private'), network: network } } } assert(false, 'Could not find version ' + version.toString(16)) } function HDNode(K, chainCode, network) { network = network || networks.bitcoin assert(Buffer.isBuffer(chainCode), 'Expected Buffer, got ' + chainCode) assert(network.bip32, 'Unknown BIP32 constants for network') this.chainCode = chainCode this.depth = 0 this.index = 0 this.network = network if (K instanceof BigInteger) { this.privKey = new ECKey(K, true) this.pubKey = this.privKey.pub } else { this.pubKey = new ECPubKey(K, true) } } HDNode.MASTER_SECRET = new Buffer('Bitcoin seed') HDNode.HIGHEST_BIT = 0x80000000 HDNode.LENGTH = 78 HDNode.fromSeedBuffer = function(seed, network) { var I = crypto.HmacSHA512(seed, HDNode.MASTER_SECRET) var IL = I.slice(0, 32) var IR = I.slice(32) // In case IL is 0 or >= n, the master key is invalid // This is handled by `new ECKey` in the HDNode constructor var pIL = BigInteger.fromBuffer(IL) return new HDNode(pIL, IR, network) } HDNode.fromSeedHex = function(hex, network) { return HDNode.fromSeedBuffer(new Buffer(hex, 'hex'), network) } HDNode.fromBase58 = function(string) { return HDNode.fromBuffer(base58check.decode(string)) } HDNode.fromBuffer = function(buffer) { assert.strictEqual(buffer.length, HDNode.LENGTH, 'Invalid buffer length') // 4 byte: version bytes var version = buffer.readUInt32BE(0) var params = findBIP32ParamsByVersion(version) // 1 byte: depth: 0x00 for master nodes, 0x01 for level-1 descendants, ... var depth = buffer.readUInt8(4) // 4 bytes: the fingerprint of the parent's key (0x00000000 if master key) var parentFingerprint = buffer.readUInt32BE(5) if (depth === 0) { assert.strictEqual(parentFingerprint, 0x00000000, 'Invalid parent fingerprint') } // 4 bytes: child number. This is the number i in xi = xpar/i, with xi the key being serialized. // This is encoded in MSB order. (0x00000000 if master key) var index = buffer.readUInt32BE(9) assert(depth > 0 || index === 0, 'Invalid index') // 32 bytes: the chain code var chainCode = buffer.slice(13, 45) var hd // 33 bytes: private key data (0x00 + k) if (params.isPrivate) { assert.strictEqual(buffer.readUInt8(45), 0x00, 'Invalid private key') var data = buffer.slice(46, 78) var d = BigInteger.fromBuffer(data) hd = new HDNode(d, chainCode, params.network) // 33 bytes: public key data (0x02 + X or 0x03 + X) } else { var data = buffer.slice(45, 78) var Q = ecurve.Point.decodeFrom(curve, data) assert.equal(Q.compressed, true, 'Invalid public key') // Verify that the X coordinate in the public point corresponds to a point on the curve. // If not, the extended public key is invalid. curve.validate(Q) hd = new HDNode(Q, chainCode, params.network) } hd.depth = depth hd.index = index hd.parentFingerprint = parentFingerprint return hd } HDNode.fromHex = function(hex) { return HDNode.fromBuffer(new Buffer(hex, 'hex')) } HDNode.prototype.getIdentifier = function() { return crypto.hash160(this.pubKey.toBuffer()) } HDNode.prototype.getFingerprint = function() { return this.getIdentifier().slice(0, 4) } HDNode.prototype.getAddress = function() { return this.pubKey.getAddress(this.network) } HDNode.prototype.toBase58 = function(isPrivate) { return base58check.encode(this.toBuffer(isPrivate)) } HDNode.prototype.toBuffer = function(isPrivate) { if (isPrivate == undefined) isPrivate = !!this.privKey // Version var version = isPrivate ? this.network.bip32.private : this.network.bip32.public var buffer = new Buffer(HDNode.LENGTH) // 4 bytes: version bytes buffer.writeUInt32BE(version, 0) // Depth // 1 byte: depth: 0x00 for master nodes, 0x01 for level-1 descendants, .... buffer.writeUInt8(this.depth, 4) // 4 bytes: the fingerprint of the parent's key (0x00000000 if master key) var fingerprint = (this.depth === 0) ? 0x00000000 : this.parentFingerprint buffer.writeUInt32BE(fingerprint, 5) // 4 bytes: child number. This is the number i in xi = xpar/i, with xi the key being serialized. // This is encoded in Big endian. (0x00000000 if master key) buffer.writeUInt32BE(this.index, 9) // 32 bytes: the chain code this.chainCode.copy(buffer, 13) // 33 bytes: the public key or private key data if (isPrivate) { assert(this.privKey, 'Missing private key') // 0x00 + k for private keys buffer.writeUInt8(0, 45) this.privKey.d.toBuffer(32).copy(buffer, 46) } else { // X9.62 encoding for public keys this.pubKey.toBuffer().copy(buffer, 45) } return buffer } HDNode.prototype.toHex = function(isPrivate) { return this.toBuffer(isPrivate).toString('hex') } // https://github.com/bitcoin/bips/blob/master/bip-0032.mediawiki#child-key-derivation-ckd-functions HDNode.prototype.derive = function(index) { var isHardened = index >= HDNode.HIGHEST_BIT var indexBuffer = new Buffer(4) indexBuffer.writeUInt32BE(index, 0) var data // Hardened child if (isHardened) { assert(this.privKey, 'Could not derive hardened child key') // data = 0x00 || ser256(kpar) || ser32(index) data = Buffer.concat([ this.privKey.d.toBuffer(33), indexBuffer ]) // Normal child } else { // data = serP(point(kpar)) || ser32(index) // = serP(Kpar) || ser32(index) data = Buffer.concat([ this.pubKey.toBuffer(), indexBuffer ]) } var I = crypto.HmacSHA512(data, this.chainCode) var IL = I.slice(0, 32) var IR = I.slice(32) var pIL = BigInteger.fromBuffer(IL) // In case parse256(IL) >= n, proceed with the next value for i if (pIL.compareTo(curve.n) >= 0) { return this.derive(index + 1) } // Private parent key -> private child key var hd if (this.privKey) { // ki = parse256(IL) + kpar (mod n) var ki = pIL.add(this.privKey.d).mod(curve.n) // In case ki == 0, proceed with the next value for i if (ki.signum() === 0) { return this.derive(index + 1) } hd = new HDNode(ki, IR, this.network) // Public parent key -> public child key } else { // Ki = point(parse256(IL)) + Kpar // = G*IL + Kpar var Ki = curve.G.multiply(pIL).add(this.pubKey.Q) // In case Ki is the point at infinity, proceed with the next value for i if (curve.isInfinity(Ki)) { return this.derive(index + 1) } hd = new HDNode(Ki, IR, this.network) } hd.depth = this.depth + 1 hd.index = index hd.parentFingerprint = this.getFingerprint().readUInt32BE(0) return hd } HDNode.prototype.deriveHardened = function(index) { // Only derives hardened private keys by default return this.derive(index + HDNode.HIGHEST_BIT) } HDNode.prototype.toString = HDNode.prototype.toBase58 module.exports = HDNode }).call(this,_dereq_("buffer").Buffer) },{"./base58check":70,"./crypto":73,"./eckey":75,"./ecpubkey":76,"./networks":81,"assert":4,"bigi":3,"buffer":8,"ecurve":65}],79:[function(_dereq_,module,exports){ module.exports = { Address: _dereq_('./address'), base58check: _dereq_('./base58check'), bufferutils: _dereq_('./bufferutils'), convert: _dereq_('./convert'), crypto: _dereq_('./crypto'), ecdsa: _dereq_('./ecdsa'), ECKey: _dereq_('./eckey'), ECPubKey: _dereq_('./ecpubkey'), ECSignature: _dereq_('./ecsignature'), Message: _dereq_('./message'), opcodes: _dereq_('./opcodes'), HDNode: _dereq_('./hdnode'), Script: _dereq_('./script'), scripts: _dereq_('./scripts'), Transaction: _dereq_('./transaction'), networks: _dereq_('./networks'), Wallet: _dereq_('./wallet') } },{"./address":69,"./base58check":70,"./bufferutils":71,"./convert":72,"./crypto":73,"./ecdsa":74,"./eckey":75,"./ecpubkey":76,"./ecsignature":77,"./hdnode":78,"./message":80,"./networks":81,"./opcodes":82,"./script":83,"./scripts":84,"./transaction":85,"./wallet":86}],80:[function(_dereq_,module,exports){ (function (Buffer){ /// Implements Bitcoin's feature for signing arbitrary messages. var Address = _dereq_('./address') var BigInteger = _dereq_('bigi') var bufferutils = _dereq_('./bufferutils') var crypto = _dereq_('./crypto') var ecdsa = _dereq_('./ecdsa') var networks = _dereq_('./networks') var Address = _dereq_('./address') var ECPubKey = _dereq_('./ecpubkey') var ECSignature = _dereq_('./ecsignature') var ecurve = _dereq_('ecurve') var ecparams = ecurve.getCurveByName('secp256k1') function magicHash(message, network) { var magicPrefix = new Buffer(network.magicPrefix) var messageBuffer = new Buffer(message) var lengthBuffer = new Buffer(bufferutils.varIntSize(messageBuffer.length)) bufferutils.writeVarInt(lengthBuffer, messageBuffer.length, 0) var buffer = Buffer.concat([magicPrefix, lengthBuffer, messageBuffer]) return crypto.hash256(buffer) } function sign(privKey, message, network) { network = network || networks.bitcoin var hash = magicHash(message, network) var signature = privKey.sign(hash) var e = BigInteger.fromBuffer(hash) var i = ecdsa.calcPubKeyRecoveryParam(ecparams, e, signature, privKey.pub.Q) return signature.toCompact(i, privKey.pub.compressed) } // TODO: network could be implied from address function verify(address, signatureBuffer, message, network) { if (address instanceof Address) { address = address.toString() } network = network || networks.bitcoin var hash = magicHash(message, network) var parsed = ECSignature.parseCompact(signatureBuffer) var e = BigInteger.fromBuffer(hash) var Q = ecdsa.recoverPubKey(ecparams, e, parsed.signature, parsed.i) var pubKey = new ECPubKey(Q, parsed.compressed) return pubKey.getAddress(network).toString() === address } module.exports = { magicHash: magicHash, sign: sign, verify: verify } }).call(this,_dereq_("buffer").Buffer) },{"./address":69,"./bufferutils":71,"./crypto":73,"./ecdsa":74,"./ecpubkey":76,"./ecsignature":77,"./networks":81,"bigi":3,"buffer":8,"ecurve":65}],81:[function(_dereq_,module,exports){ // https://en.bitcoin.it/wiki/List_of_address_prefixes // Dogecoin BIP32 is a proposed standard: https://bitcointalk.org/index.php?topic=409731 var networks = { bitcoin: { magicPrefix: '\x18Bitcoin Signed Message:\n', bip32: { public: 0x0488b21e, private: 0x0488ade4 }, pubKeyHash: 0x00, scriptHash: 0x05, wif: 0x80, dustThreshold: 546, // https://github.com/bitcoin/bitcoin/blob/v0.9.2/src/core.h#L151-L162 feePerKb: 10000, // https://github.com/bitcoin/bitcoin/blob/v0.9.2/src/main.cpp#L53 estimateFee: estimateFee('bitcoin') }, dogecoin: { magicPrefix: '\x19Dogecoin Signed Message:\n', bip32: { public: 0x02facafd, private: 0x02fac398 }, pubKeyHash: 0x1e, scriptHash: 0x16, wif: 0x9e, dustThreshold: 0, // https://github.com/dogecoin/dogecoin/blob/v1.7.1/src/core.h#L155-L160 dustSoftThreshold: 100000000, // https://github.com/dogecoin/dogecoin/blob/v1.7.1/src/main.h#L62 feePerKb: 100000000, // https://github.com/dogecoin/dogecoin/blob/v1.7.1/src/main.cpp#L58 estimateFee: estimateFee('dogecoin') }, litecoin: { magicPrefix: '\x19Litecoin Signed Message:\n', bip32: { public: 0x019da462, private: 0x019d9cfe }, pubKeyHash: 0x30, scriptHash: 0x05, wif: 0xb0, dustThreshold: 0, // https://github.com/litecoin-project/litecoin/blob/v0.8.7.2/src/main.cpp#L360-L365 dustSoftThreshold: 100000, // https://github.com/litecoin-project/litecoin/blob/v0.8.7.2/src/main.h#L53 feePerKb: 100000, // https://github.com/litecoin-project/litecoin/blob/v0.8.7.2/src/main.cpp#L56 estimateFee: estimateFee('litecoin') }, testnet: { magicPrefix: '\x18Bitcoin Signed Message:\n', bip32: { public: 0x043587cf, private: 0x04358394 }, pubKeyHash: 0x6f, scriptHash: 0xc4, wif: 0xef, dustThreshold: 546, feePerKb: 10000, estimateFee: estimateFee('testnet') } } function estimateFee(type) { return function(tx) { var network = networks[type] var baseFee = network.feePerKb var byteSize = tx.toBuffer().length var fee = baseFee * Math.ceil(byteSize / 1000) if (network.dustSoftThreshold == undefined) return fee tx.outs.forEach(function(e){ if (e.value < network.dustSoftThreshold) { fee += baseFee } }) return fee } } module.exports = networks },{}],82:[function(_dereq_,module,exports){ module.exports = { // push value OP_FALSE : 0, OP_0 : 0, OP_PUSHDATA1 : 76, OP_PUSHDATA2 : 77, OP_PUSHDATA4 : 78, OP_1NEGATE : 79, OP_RESERVED : 80, OP_1 : 81, OP_TRUE : 81, OP_2 : 82, OP_3 : 83, OP_4 : 84, OP_5 : 85, OP_6 : 86, OP_7 : 87, OP_8 : 88, OP_9 : 89, OP_10 : 90, OP_11 : 91, OP_12 : 92, OP_13 : 93, OP_14 : 94, OP_15 : 95, OP_16 : 96, // control OP_NOP : 97, OP_VER : 98, OP_IF : 99, OP_NOTIF : 100, OP_VERIF : 101, OP_VERNOTIF : 102, OP_ELSE : 103, OP_ENDIF : 104, OP_VERIFY : 105, OP_RETURN : 106, // stack ops OP_TOALTSTACK : 107, OP_FROMALTSTACK : 108, OP_2DROP : 109, OP_2DUP : 110, OP_3DUP : 111, OP_2OVER : 112, OP_2ROT : 113, OP_2SWAP : 114, OP_IFDUP : 115, OP_DEPTH : 116, OP_DROP : 117, OP_DUP : 118, OP_NIP : 119, OP_OVER : 120, OP_PICK : 121, OP_ROLL : 122, OP_ROT : 123, OP_SWAP : 124, OP_TUCK : 125, // splice ops OP_CAT : 126, OP_SUBSTR : 127, OP_LEFT : 128, OP_RIGHT : 129, OP_SIZE : 130, // bit logic OP_INVERT : 131, OP_AND : 132, OP_OR : 133, OP_XOR : 134, OP_EQUAL : 135, OP_EQUALVERIFY : 136, OP_RESERVED1 : 137, OP_RESERVED2 : 138, // numeric OP_1ADD : 139, OP_1SUB : 140, OP_2MUL : 141, OP_2DIV : 142, OP_NEGATE : 143, OP_ABS : 144, OP_NOT : 145, OP_0NOTEQUAL : 146, OP_ADD : 147, OP_SUB : 148, OP_MUL : 149, OP_DIV : 150, OP_MOD : 151, OP_LSHIFT : 152, OP_RSHIFT : 153, OP_BOOLAND : 154, OP_BOOLOR : 155, OP_NUMEQUAL : 156, OP_NUMEQUALVERIFY : 157, OP_NUMNOTEQUAL : 158, OP_LESSTHAN : 159, OP_GREATERTHAN : 160, OP_LESSTHANOREQUAL : 161, OP_GREATERTHANOREQUAL : 162, OP_MIN : 163, OP_MAX : 164, OP_WITHIN : 165, // crypto OP_RIPEMD160 : 166, OP_SHA1 : 167, OP_SHA256 : 168, OP_HASH160 : 169, OP_HASH256 : 170, OP_CODESEPARATOR : 171, OP_CHECKSIG : 172, OP_CHECKSIGVERIFY : 173, OP_CHECKMULTISIG : 174, OP_CHECKMULTISIGVERIFY : 175, // expansion OP_NOP1 : 176, OP_NOP2 : 177, OP_NOP3 : 178, OP_NOP4 : 179, OP_NOP5 : 180, OP_NOP6 : 181, OP_NOP7 : 182, OP_NOP8 : 183, OP_NOP9 : 184, OP_NOP10 : 185, // template matching params OP_PUBKEYHASH : 253, OP_PUBKEY : 254, OP_INVALIDOPCODE : 255 } },{}],83:[function(_dereq_,module,exports){ (function (Buffer){ var assert = _dereq_('assert') var bufferutils = _dereq_('./bufferutils') var crypto = _dereq_('./crypto') var opcodes = _dereq_('./opcodes') function Script(buffer, chunks) { assert(Buffer.isBuffer(buffer), 'Expected Buffer, got ' + buffer) assert(Array.isArray(chunks), 'Expected Array, got ' + chunks) this.buffer = buffer this.chunks = chunks } // Import operations Script.fromASM = function(asm) { var strChunks = asm.split(' ') var chunks = strChunks.map(function(strChunk) { if (strChunk in opcodes) { return opcodes[strChunk] } else { return new Buffer(strChunk, 'hex') } }) return Script.fromChunks(chunks) } Script.fromBuffer = function(buffer) { var chunks = [] var i = 0 while (i < buffer.length) { var opcode = buffer.readUInt8(i) if ((opcode > opcodes.OP_0) && (opcode <= opcodes.OP_PUSHDATA4)) { var d = bufferutils.readPushDataInt(buffer, i) i += d.size var data = buffer.slice(i, i + d.number) i += d.number chunks.push(data) } else { chunks.push(opcode) i += 1 } } return new Script(buffer, chunks) } Script.fromChunks = function(chunks) { assert(Array.isArray(chunks), 'Expected Array, got ' + chunks) var bufferSize = chunks.reduce(function(accum, chunk) { if (Buffer.isBuffer(chunk)) { return accum + bufferutils.pushDataSize(chunk.length) + chunk.length } return accum + 1 }, 0.0) var buffer = new Buffer(bufferSize) var offset = 0 chunks.forEach(function(chunk) { if (Buffer.isBuffer(chunk)) { offset += bufferutils.writePushDataInt(buffer, chunk.length, offset) chunk.copy(buffer, offset) offset += chunk.length } else { buffer.writeUInt8(chunk, offset) offset += 1 } }) assert.equal(offset, buffer.length, 'Could not decode chunks') return new Script(buffer, chunks) } Script.fromHex = function(hex) { return Script.fromBuffer(new Buffer(hex, 'hex')) } // Constants Script.EMPTY = Script.fromChunks([]) // Operations Script.prototype.getHash = function() { return crypto.hash160(this.buffer) } // FIXME: doesn't work for data chunks, maybe time to use buffertools.compare... Script.prototype.without = function(needle) { return Script.fromChunks(this.chunks.filter(function(op) { return op !== needle })) } // Export operations var reverseOps = [] for (var op in opcodes) { var code = opcodes[op] reverseOps[code] = op } Script.prototype.toASM = function() { return this.chunks.map(function(chunk) { if (Buffer.isBuffer(chunk)) { return chunk.toString('hex') } else { return reverseOps[chunk] } }).join(' ') } Script.prototype.toBuffer = function() { return this.buffer } Script.prototype.toHex = function() { return this.toBuffer().toString('hex') } module.exports = Script }).call(this,_dereq_("buffer").Buffer) },{"./bufferutils":71,"./crypto":73,"./opcodes":82,"assert":4,"buffer":8}],84:[function(_dereq_,module,exports){ (function (Buffer){ var assert = _dereq_('assert') var opcodes = _dereq_('./opcodes') // FIXME: use ECPubKey, currently the circular dependency breaks everything. // // Solutions: // * Remove ECPubKey.getAddress // - Minimal change, but likely unpopular // * Move all script related functionality out of Address // - Means a lot of changes to Transaction/Wallet // * Ignore it (existing solution) // * Some form of hackery with commonjs // var ecurve = _dereq_('ecurve') var curve = ecurve.getCurveByName('secp256k1') var ECSignature = _dereq_('./ecsignature') var Script = _dereq_('./script') function classifyOutput(script) { assert(script instanceof Script, 'Expected Script, got ', script) if (isPubKeyHashOutput.call(script)) { return 'pubkeyhash' } else if (isScriptHashOutput.call(script)) { return 'scripthash' } else if (isMultisigOutput.call(script)) { return 'multisig' } else if (isPubKeyOutput.call(script)) { return 'pubkey' } else if (isNulldataOutput.call(script)) { return 'nulldata' } else { return 'nonstandard' } } function classifyInput(script) { assert(script instanceof Script, 'Expected Script, got ', script) if (isPubKeyHashInput.call(script)) { return 'pubkeyhash' } else if (isScriptHashInput.call(script)) { return 'scripthash' } else if (isMultisigInput.call(script)) { return 'multisig' } else if (isPubKeyInput.call(script)) { return 'pubkey' } else { return 'nonstandard' } } function isCanonicalPubKey(buffer) { if (!Buffer.isBuffer(buffer)) return false try { // FIXME: boo ecurve.Point.decodeFrom(curve, buffer) } catch (e) { if (!(e.message.match(/Invalid sequence (length|tag)/))) throw e return false } return true } function isCanonicalSignature(buffer) { if (!Buffer.isBuffer(buffer)) return false try { ECSignature.parseScriptSignature(buffer) } catch(e) { if (!(e.message.match(/Not a DER sequence|Invalid sequence length|Expected a DER integer|R length is zero|S length is zero|R value excessively padded|S value excessively padded|R value is negative|S value is negative|Invalid hashType/))) throw e return false } return true } function isPubKeyHashInput() { return this.chunks.length === 2 && isCanonicalSignature(this.chunks[0]) && isCanonicalPubKey(this.chunks[1]) } function isPubKeyHashOutput() { return this.chunks.length === 5 && this.chunks[0] === opcodes.OP_DUP && this.chunks[1] === opcodes.OP_HASH160 && Buffer.isBuffer(this.chunks[2]) && this.chunks[2].length === 20 && this.chunks[3] === opcodes.OP_EQUALVERIFY && this.chunks[4] === opcodes.OP_CHECKSIG } function isPubKeyInput() { return this.chunks.length === 1 && isCanonicalSignature(this.chunks[0]) } function isPubKeyOutput() { return this.chunks.length === 2 && isCanonicalPubKey(this.chunks[0]) && this.chunks[1] === opcodes.OP_CHECKSIG } function isScriptHashInput() { if (this.chunks.length < 2) return false var lastChunk = this.chunks[this.chunks.length - 1] if (!Buffer.isBuffer(lastChunk)) return false var scriptSig = Script.fromChunks(this.chunks.slice(0, -1)) var scriptPubKey = Script.fromBuffer(lastChunk) return classifyInput(scriptSig) === classifyOutput(scriptPubKey) } function isScriptHashOutput() { return this.chunks.length === 3 && this.chunks[0] === opcodes.OP_HASH160 && Buffer.isBuffer(this.chunks[1]) && this.chunks[1].length === 20 && this.chunks[2] === opcodes.OP_EQUAL } function isMultisigInput() { return this.chunks[0] === opcodes.OP_0 && this.chunks.slice(1).every(isCanonicalSignature) } function isMultisigOutput() { if (this.chunks < 4) return false if (this.chunks[this.chunks.length - 1] !== opcodes.OP_CHECKMULTISIG) return false var mOp = this.chunks[0] if (mOp === opcodes.OP_0) return false if (mOp < opcodes.OP_1) return false if (mOp > opcodes.OP_16) return false var nOp = this.chunks[this.chunks.length - 2] if (nOp === opcodes.OP_0) return false if (nOp < opcodes.OP_1) return false if (nOp > opcodes.OP_16) return false var m = mOp - (opcodes.OP_1 - 1) var n = nOp - (opcodes.OP_1 - 1) if (n < m) return false var pubKeys = this.chunks.slice(1, -2) if (n < pubKeys.length) return false return pubKeys.every(isCanonicalPubKey) } function isNulldataOutput() { return this.chunks[0] === opcodes.OP_RETURN } // Standard Script Templates // {pubKey} OP_CHECKSIG function pubKeyOutput(pubKey) { return Script.fromChunks([ pubKey.toBuffer(), opcodes.OP_CHECKSIG ]) } // OP_DUP OP_HASH160 {pubKeyHash} OP_EQUALVERIFY OP_CHECKSIG function pubKeyHashOutput(hash) { assert(Buffer.isBuffer(hash), 'Expected Buffer, got ' + hash) return Script.fromChunks([ opcodes.OP_DUP, opcodes.OP_HASH160, hash, opcodes.OP_EQUALVERIFY, opcodes.OP_CHECKSIG ]) } // OP_HASH160 {scriptHash} OP_EQUAL function scriptHashOutput(hash) { assert(Buffer.isBuffer(hash), 'Expected Buffer, got ' + hash) return Script.fromChunks([ opcodes.OP_HASH160, hash, opcodes.OP_EQUAL ]) } // m [pubKeys ...] n OP_CHECKMULTISIG function multisigOutput(m, pubKeys) { assert(Array.isArray(pubKeys), 'Expected Array, got ' + pubKeys) assert(pubKeys.length >= m, 'Not enough pubKeys provided') var pubKeyBuffers = pubKeys.map(function(pubKey) { return pubKey.toBuffer() }) var n = pubKeys.length return Script.fromChunks([].concat( (opcodes.OP_1 - 1) + m, pubKeyBuffers, (opcodes.OP_1 - 1) + n, opcodes.OP_CHECKMULTISIG )) } // {signature} function pubKeyInput(signature) { assert(Buffer.isBuffer(signature), 'Expected Buffer, got ' + signature) return Script.fromChunks([signature]) } // {signature} {pubKey} function pubKeyHashInput(signature, pubKey) { assert(Buffer.isBuffer(signature), 'Expected Buffer, got ' + signature) return Script.fromChunks([signature, pubKey.toBuffer()]) } // {serialized scriptPubKey script} function scriptHashInput(scriptSig, scriptPubKey) { return Script.fromChunks([].concat( scriptSig.chunks, scriptPubKey.toBuffer() )) } // OP_0 [signatures ...] function multisigInput(signatures, scriptPubKey) { if (scriptPubKey) { assert(isMultisigOutput.call(scriptPubKey)) var m = scriptPubKey.chunks[0] var k = m - (opcodes.OP_1 - 1) assert(k <= signatures.length, 'Not enough signatures provided') } return Script.fromChunks([].concat(opcodes.OP_0, signatures)) } module.exports = { classifyInput: classifyInput, classifyOutput: classifyOutput, multisigInput: multisigInput, multisigOutput: multisigOutput, pubKeyHashInput: pubKeyHashInput, pubKeyHashOutput: pubKeyHashOutput, pubKeyInput: pubKeyInput, pubKeyOutput: pubKeyOutput, scriptHashInput: scriptHashInput, scriptHashOutput: scriptHashOutput } }).call(this,_dereq_("buffer").Buffer) },{"./ecsignature":77,"./opcodes":82,"./script":83,"assert":4,"buffer":8,"ecurve":65}],85:[function(_dereq_,module,exports){ (function (Buffer){ var assert = _dereq_('assert') var bufferutils = _dereq_('./bufferutils') var crypto = _dereq_('./crypto') var opcodes = _dereq_('./opcodes') var scripts = _dereq_('./scripts') var Address = _dereq_('./address') var ECKey = _dereq_('./eckey') var ECSignature = _dereq_('./ecsignature') var Script = _dereq_('./script') Transaction.DEFAULT_SEQUENCE = 0xffffffff Transaction.SIGHASH_ALL = 0x01 Transaction.SIGHASH_NONE = 0x02 Transaction.SIGHASH_SINGLE = 0x03 Transaction.SIGHASH_ANYONECANPAY = 0x80 function Transaction() { this.version = 1 this.locktime = 0 this.ins = [] this.outs = [] } /** * Create a new txin. * * Can be called with any of: * * - A transaction and an index * - A transaction hash and an index * * Note that this method does not sign the created input. */ Transaction.prototype.addInput = function(tx, index, sequence) { if (sequence == undefined) sequence = Transaction.DEFAULT_SEQUENCE var hash if (typeof tx === 'string') { hash = new Buffer(tx, 'hex') // TxId hex is big-endian, we need little-endian Array.prototype.reverse.call(hash) } else if (tx instanceof Transaction) { hash = tx.getHash() } else { hash = tx } assert(Buffer.isBuffer(hash), 'Expected Transaction, txId or txHash, got ' + tx) assert.equal(hash.length, 32, 'Expected hash length of 32, got ' + hash.length) assert.equal(typeof index, 'number', 'Expected number index, got ' + index) return (this.ins.push({ hash: hash, index: index, script: Script.EMPTY, sequence: sequence }) - 1) } /** * Create a new txout. * * Can be called with: * * - A base58 address string and a value * - An Address object and a value * - A scriptPubKey Script and a value */ Transaction.prototype.addOutput = function(scriptPubKey, value) { // Attempt to get a valid address if it's a base58 address string if (typeof scriptPubKey === 'string') { scriptPubKey = Address.fromBase58Check(scriptPubKey) } // Attempt to get a valid script if it's an Address object if (scriptPubKey instanceof Address) { var address = scriptPubKey scriptPubKey = address.toOutputScript() } return (this.outs.push({ script: scriptPubKey, value: value, }) - 1) } Transaction.prototype.toBuffer = function () { var txInSize = this.ins.reduce(function(a, x) { return a + (40 + bufferutils.varIntSize(x.script.buffer.length) + x.script.buffer.length) }, 0) var txOutSize = this.outs.reduce(function(a, x) { return a + (8 + bufferutils.varIntSize(x.script.buffer.length) + x.script.buffer.length) }, 0) var buffer = new Buffer( 8 + bufferutils.varIntSize(this.ins.length) + bufferutils.varIntSize(this.outs.length) + txInSize + txOutSize ) var offset = 0 function writeSlice(slice) { slice.copy(buffer, offset) offset += slice.length } function writeUInt32(i) { buffer.writeUInt32LE(i, offset) offset += 4 } function writeUInt64(i) { bufferutils.writeUInt64LE(buffer, i, offset) offset += 8 } function writeVarInt(i) { var n = bufferutils.writeVarInt(buffer, i, offset) offset += n } writeUInt32(this.version) writeVarInt(this.ins.length) this.ins.forEach(function(txin) { writeSlice(txin.hash) writeUInt32(txin.index) writeVarInt(txin.script.buffer.length) writeSlice(txin.script.buffer) writeUInt32(txin.sequence) }) writeVarInt(this.outs.length) this.outs.forEach(function(txout) { writeUInt64(txout.value) writeVarInt(txout.script.buffer.length) writeSlice(txout.script.buffer) }) writeUInt32(this.locktime) return buffer } Transaction.prototype.toHex = function() { return this.toBuffer().toString('hex') } /** * Hash transaction for signing a specific input. * * Bitcoin uses a different hash for each signed transaction input. This * method copies the transaction, makes the necessary changes based on the * hashType, serializes and finally hashes the result. This hash can then be * used to sign the transaction input in question. */ Transaction.prototype.hashForSignature = function(prevOutScript, inIndex, hashType) { assert(inIndex >= 0, 'Invalid vin index') assert(inIndex < this.ins.length, 'Invalid vin index') assert(prevOutScript instanceof Script, 'Invalid Script object') var txTmp = this.clone() var hashScript = prevOutScript.without(opcodes.OP_CODESEPARATOR) // Blank out other inputs' signatures txTmp.ins.forEach(function(txin) { txin.script = Script.EMPTY }) txTmp.ins[inIndex].script = hashScript var hashTypeModifier = hashType & 0x1f if (hashTypeModifier === Transaction.SIGHASH_NONE) { assert(false, 'SIGHASH_NONE not yet supported') } else if (hashTypeModifier === Transaction.SIGHASH_SINGLE) { assert(false, 'SIGHASH_SINGLE not yet supported') } if (hashType & Transaction.SIGHASH_ANYONECANPAY) { assert(false, 'SIGHASH_ANYONECANPAY not yet supported') } var hashTypeBuffer = new Buffer(4) hashTypeBuffer.writeInt32LE(hashType, 0) var buffer = Buffer.concat([txTmp.toBuffer(), hashTypeBuffer]) return crypto.hash256(buffer) } Transaction.prototype.getHash = function () { return crypto.hash256(this.toBuffer()) } Transaction.prototype.getId = function () { var buffer = this.getHash() // Big-endian is used for TxHash Array.prototype.reverse.call(buffer) return buffer.toString('hex') } Transaction.prototype.clone = function () { var newTx = new Transaction() newTx.version = this.version newTx.locktime = this.locktime newTx.ins = this.ins.map(function(txin) { return { hash: txin.hash, index: txin.index, script: txin.script, sequence: txin.sequence } }) newTx.outs = this.outs.map(function(txout) { return { script: txout.script, value: txout.value } }) return newTx } Transaction.fromBuffer = function(buffer) { var offset = 0 function readSlice(n) { offset += n return buffer.slice(offset - n, offset) } function readUInt32() { var i = buffer.readUInt32LE(offset) offset += 4 return i } function readUInt64() { var i = bufferutils.readUInt64LE(buffer, offset) offset += 8 return i } function readVarInt() { var vi = bufferutils.readVarInt(buffer, offset) offset += vi.size return vi.number } var tx = new Transaction() tx.version = readUInt32() var vinLen = readVarInt() for (var i = 0; i < vinLen; ++i) { var hash = readSlice(32) var vout = readUInt32() var scriptLen = readVarInt() var script = readSlice(scriptLen) var sequence = readUInt32() tx.ins.push({ hash: hash, index: vout, script: Script.fromBuffer(script), sequence: sequence }) } var voutLen = readVarInt() for (i = 0; i < voutLen; ++i) { var value = readUInt64() var scriptLen = readVarInt() var script = readSlice(scriptLen) tx.outs.push({ value: value, script: Script.fromBuffer(script) }) } tx.locktime = readUInt32() assert.equal(offset, buffer.length, 'Transaction has unexpected data') return tx } Transaction.fromHex = function(hex) { return Transaction.fromBuffer(new Buffer(hex, 'hex')) } /** * Signs a pubKeyHash output at some index with the given key */ Transaction.prototype.sign = function(index, privKey, hashType) { var prevOutScript = privKey.pub.getAddress().toOutputScript() var signature = this.signInput(index, prevOutScript, privKey, hashType) // FIXME: Assumed prior TX was pay-to-pubkey-hash var scriptSig = scripts.pubKeyHashInput(signature, privKey.pub) this.setInputScript(index, scriptSig) } Transaction.prototype.signInput = function(index, prevOutScript, privKey, hashType) { hashType = hashType || Transaction.SIGHASH_ALL var hash = this.hashForSignature(prevOutScript, index, hashType) var signature = privKey.sign(hash) return signature.toScriptSignature(hashType) } Transaction.prototype.setInputScript = function(index, script) { this.ins[index].script = script } // FIXME: could be validateInput(index, prevTxOut, pub) Transaction.prototype.validateInput = function(index, prevOutScript, pubKey, buffer) { var parsed = ECSignature.parseScriptSignature(buffer) var hash = this.hashForSignature(prevOutScript, index, parsed.hashType) return pubKey.verify(hash, parsed.signature) } module.exports = Transaction }).call(this,_dereq_("buffer").Buffer) },{"./address":69,"./bufferutils":71,"./crypto":73,"./eckey":75,"./ecsignature":77,"./opcodes":82,"./script":83,"./scripts":84,"assert":4,"buffer":8}],86:[function(_dereq_,module,exports){ (function (Buffer){ var assert = _dereq_('assert') var networks = _dereq_('./networks') var rng = _dereq_('secure-random') var Address = _dereq_('./address') var HDNode = _dereq_('./hdnode') var Transaction = _dereq_('./transaction') function Wallet(seed, network) { network = network || networks.bitcoin // Stored in a closure to make accidental serialization less likely var masterkey = null var me = this var accountZero = null var internalAccount = null var externalAccount = null // Addresses this.addresses = [] this.changeAddresses = [] // Transaction output data this.outputs = {} // Make a new master key this.newMasterKey = function(seed) { seed = seed || new Buffer(rng(32)) masterkey = HDNode.fromSeedBuffer(seed, network) // HD first-level child derivation method should be hardened // See https://bitcointalk.org/index.php?topic=405179.msg4415254#msg4415254 accountZero = masterkey.deriveHardened(0) externalAccount = accountZero.derive(0) internalAccount = accountZero.derive(1) me.addresses = [] me.changeAddresses = [] me.outputs = {} } this.newMasterKey(seed) this.generateAddress = function() { var key = externalAccount.derive(this.addresses.length) this.addresses.push(key.getAddress().toString()) return this.addresses[this.addresses.length - 1] } this.generateChangeAddress = function() { var key = internalAccount.derive(this.changeAddresses.length) this.changeAddresses.push(key.getAddress().toString()) return this.changeAddresses[this.changeAddresses.length - 1] } this.getBalance = function() { return this.getUnspentOutputs().reduce(function(memo, output){ return memo + output.value }, 0) } this.getUnspentOutputs = function() { var utxo = [] for(var key in this.outputs){ var output = this.outputs[key] if(!output.to) utxo.push(outputToUnspentOutput(output)) } return utxo } this.setUnspentOutputs = function(utxo) { var outputs = {} utxo.forEach(function(uo){ validateUnspentOutput(uo) var o = unspentOutputToOutput(uo) outputs[o.from] = o }) this.outputs = outputs } function outputToUnspentOutput(output){ var hashAndIndex = output.from.split(":") return { hash: hashAndIndex[0], outputIndex: parseInt(hashAndIndex[1]), address: output.address, value: output.value, pending: output.pending } } function unspentOutputToOutput(o) { var hash = o.hash var key = hash + ":" + o.outputIndex return { from: key, address: o.address, value: o.value, pending: o.pending } } function validateUnspentOutput(uo) { var missingField if (isNullOrUndefined(uo.hash)) { missingField = "hash" } var requiredKeys = ['outputIndex', 'address', 'value'] requiredKeys.forEach(function (key) { if (isNullOrUndefined(uo[key])){ missingField = key } }) if (missingField) { var message = [ 'Invalid unspent output: key', missingField, 'is missing.', 'A valid unspent output must contain' ] message.push(requiredKeys.join(', ')) message.push("and hash") throw new Error(message.join(' ')) } } function isNullOrUndefined(value) { return value == undefined } this.processPendingTx = function(tx){ processTx(tx, true) } this.processConfirmedTx = function(tx){ processTx(tx, false) } function processTx(tx, isPending) { var txid = tx.getId() tx.outs.forEach(function(txOut, i) { var address try { address = Address.fromOutputScript(txOut.script, network).toString() } catch(e) { if (!(e.message.match(/has no matching Address/))) throw e } if (isMyAddress(address)) { var output = txid + ':' + i me.outputs[output] = { from: output, value: txOut.value, address: address, pending: isPending } } }) tx.ins.forEach(function(txIn, i) { // copy and convert to big-endian hex var txinId = new Buffer(txIn.hash) Array.prototype.reverse.call(txinId) txinId = txinId.toString('hex') var output = txinId + ':' + txIn.index if (!(output in me.outputs)) return if (isPending) { me.outputs[output].to = txid + ':' + i me.outputs[output].pending = true } else { delete me.outputs[output] } }) } this.createTx = function(to, value, fixedFee, changeAddress) { assert(value > network.dustThreshold, value + ' must be above dust threshold (' + network.dustThreshold + ' Satoshis)') var utxos = getCandidateOutputs(value) var accum = 0 var subTotal = value var addresses = [] var tx = new Transaction() tx.addOutput(to, value) for (var i = 0; i < utxos.length; ++i) { var utxo = utxos[i] addresses.push(utxo.address) var outpoint = utxo.from.split(':') tx.addInput(outpoint[0], parseInt(outpoint[1])) var fee = fixedFee == undefined ? estimateFeePadChangeOutput(tx) : fixedFee accum += utxo.value subTotal = value + fee if (accum >= subTotal) { var change = accum - subTotal if (change > network.dustThreshold) { tx.addOutput(changeAddress || getChangeAddress(), change) } break } } assert(accum >= subTotal, 'Not enough funds (incl. fee): ' + accum + ' < ' + subTotal) this.signWith(tx, addresses) return tx } function getCandidateOutputs() { var unspent = [] for (var key in me.outputs) { var output = me.outputs[key] if (!output.pending) unspent.push(output) } var sortByValueDesc = unspent.sort(function(o1, o2){ return o2.value - o1.value }) return sortByValueDesc } function estimateFeePadChangeOutput(tx) { var tmpTx = tx.clone() tmpTx.addOutput(getChangeAddress(), network.dustSoftThreshold || 0) return network.estimateFee(tmpTx) } function getChangeAddress() { if(me.changeAddresses.length === 0) me.generateChangeAddress(); return me.changeAddresses[me.changeAddresses.length - 1] } this.signWith = function(tx, addresses) { assert.equal(tx.ins.length, addresses.length, 'Number of addresses must match number of transaction inputs') addresses.forEach(function(address, i) { var key = me.getPrivateKeyForAddress(address) tx.sign(i, key) }) return tx } this.getMasterKey = function() { return masterkey } this.getAccountZero = function() { return accountZero } this.getInternalAccount = function() { return internalAccount } this.getExternalAccount = function() { return externalAccount } this.getPrivateKey = function(index) { return externalAccount.derive(index).privKey } this.getInternalPrivateKey = function(index) { return internalAccount.derive(index).privKey } this.getPrivateKeyForAddress = function(address) { var index if((index = this.addresses.indexOf(address)) > -1) { return this.getPrivateKey(index) } else if((index = this.changeAddresses.indexOf(address)) > -1) { return this.getInternalPrivateKey(index) } else { throw new Error('Unknown address. Make sure the address is from the keychain and has been generated.') } } function isReceiveAddress(address){ return me.addresses.indexOf(address) > -1 } function isChangeAddress(address){ return me.changeAddresses.indexOf(address) > -1 } function isMyAddress(address) { return isReceiveAddress(address) || isChangeAddress(address) } } module.exports = Wallet }).call(this,_dereq_("buffer").Buffer) },{"./address":69,"./hdnode":78,"./networks":81,"./transaction":85,"assert":4,"buffer":8,"secure-random":68}]},{},[79]) (79) });