includes/clientside/static/libbigint.js
author Dan
Sun, 04 May 2008 21:57:48 -0400
changeset 541 acb7e23b6ffa
parent 436 242353360e37
permissions -rw-r--r--
Massive commit with various changes. Added user ranks system (no admin interface yet) and ability for users to have custom user titles. Made cron framework accept fractions of hours through floating-point intervals. Modifed ACL editor to use miniPrompt framework for close confirmation box. Made avatar system use a special page as opposed to fetching the files directly for caching reasons.

////////////////////////////////////////////////////////////////////////////////////////
// Big Integer Library v. 5.1
// Created 2000, last modified 2007
// Leemon Baird
// www.leemon.com
//
// Version history:
//
// v 5.1  8 Oct 2007 
//   - renamed inverseModInt_ to inverseModInt since it doesn't change its parameters
//   - added functions GCD and randBigInt, which call GCD_ and randBigInt_
//   - fixed a bug found by Rob Visser (see comment with his name below)
//   - improved comments
//
// This file is public domain.   You can use it for any purpose without restriction.
// I do not guarantee that it is correct, so use it at your own risk.  If you use 
// it for something interesting, I'd appreciate hearing about it.  If you find 
// any bugs or make any improvements, I'd appreciate hearing about those too.
// It would also be nice if my name and address were left in the comments.
// But none of that is required.
//
// This code defines a bigInt library for arbitrary-precision integers.
// A bigInt is an array of integers storing the value in chunks of bpe bits, 
// little endian (buff[0] is the least significant word).
// Negative bigInts are stored two's complement.
// Some functions assume their parameters have at least one leading zero element.
// Functions with an underscore at the end of the name have unpredictable behavior in case of overflow, 
// so the caller must make sure the arrays must be big enough to hold the answer.
// For each function where a parameter is modified, that same 
// variable must not be used as another argument too.
// So, you cannot square x by doing multMod_(x,x,n).  
// You must use squareMod_(x,n) instead, or do y=dup(x); multMod_(x,y,n).
//
// These functions are designed to avoid frequent dynamic memory allocation in the inner loop.
// For most functions, if it needs a BigInt as a local variable it will actually use
// a global, and will only allocate to it only when it's not the right size.  This ensures
// that when a function is called repeatedly with same-sized parameters, it only allocates
// memory on the first call.
//
// Note that for cryptographic purposes, the calls to Math.random() must 
// be replaced with calls to a better pseudorandom number generator.
//
// In the following, "bigInt" means a bigInt with at least one leading zero element,
// and "integer" means a nonnegative integer less than radix.  In some cases, integer 
// can be negative.  Negative bigInts are 2s complement.
// 
// The following functions do not modify their inputs.
// Those returning a bigInt, string, or Array will dynamically allocate memory for that value.
// Those returning a boolean will return the integer 0 (false) or 1 (true).
// Those returning boolean or int will not allocate memory except possibly on the first time they're called with a given parameter size.
// 
// bigInt  add(x,y)               //return (x+y) for bigInts x and y.  
// bigInt  addInt(x,n)            //return (x+n) where x is a bigInt and n is an integer.
// string  bigInt2str(x,base)     //return a string form of bigInt x in a given base, with 2 <= base <= 95
// int     bitSize(x)             //return how many bits long the bigInt x is, not counting leading zeros
// bigInt  dup(x)                 //return a copy of bigInt x
// boolean equals(x,y)            //is the bigInt x equal to the bigint y?
// boolean equalsInt(x,y)         //is bigint x equal to integer y?
// bigInt  expand(x,n)            //return a copy of x with at least n elements, adding leading zeros if needed
// Array   findPrimes(n)          //return array of all primes less than integer n
// bigInt  GCD(x,y)               //return greatest common divisor of bigInts x and y (each with same number of elements).
// boolean greater(x,y)           //is x>y?  (x and y are nonnegative bigInts)
// boolean greaterShift(x,y,shift)//is (x <<(shift*bpe)) > y?
// bigInt  int2bigInt(t,n,m)      //return a bigInt equal to integer t, with at least n bits and m array elements
// bigInt  inverseMod(x,n)        //return (x**(-1) mod n) for bigInts x and n.  If no inverse exists, it returns null
// int     inverseModInt(x,n)     //return x**(-1) mod n, for integers x and n.  Return 0 if there is no inverse
// boolean isZero(x)              //is the bigInt x equal to zero?
// boolean millerRabin(x,b)       //does one round of Miller-Rabin base integer b say that bigInt x is possibly prime (as opposed to definitely composite)?
// bigInt  mod(x,n)               //return a new bigInt equal to (x mod n) for bigInts x and n.
// int     modInt(x,n)            //return x mod n for bigInt x and integer n.
// bigInt  mult(x,y)              //return x*y for bigInts x and y. This is faster when y<x.
// bigInt  multMod(x,y,n)         //return (x*y mod n) for bigInts x,y,n.  For greater speed, let y<x.
// boolean negative(x)            //is bigInt x negative?
// bigInt  powMod(x,y,n)          //return (x**y mod n) where x,y,n are bigInts and ** is exponentiation.  0**0=1. Faster for odd n.
// bigInt  randBigInt(n,s)        //return an n-bit random BigInt (n>=1).  If s=1, then the most significant of those n bits is set to 1.
// bigInt  randTruePrime(k)       //return a new, random, k-bit, true prime bigInt using Maurer's algorithm.
// bigInt  str2bigInt(s,b,n,m)    //return a bigInt for number represented in string s in base b with at least n bits and m array elements
// bigInt  sub(x,y)               //return (x-y) for bigInts x and y.  Negative answers will be 2s complement
// bigInt  bigint_trim(x,k)              //return a copy of x with exactly k leading zero elements
//
//
// The following functions each have a non-underscored version, which most users should call instead.
// These functions each write to a single parameter, and the caller is responsible for ensuring the array 
// passed in is large enough to hold the result. 
//
// void    addInt_(x,n)          //do x=x+n where x is a bigInt and n is an integer
// void    add_(x,y)             //do x=x+y for bigInts x and y
// void    copy_(x,y)            //do x=y on bigInts x and y
// void    copyInt_(x,n)         //do x=n on bigInt x and integer n
// void    GCD_(x,y)             //set x to the greatest common divisor of bigInts x and y, (y is destroyed).  (This never overflows its array).
// boolean inverseMod_(x,n)      //do x=x**(-1) mod n, for bigInts x and n. Returns 1 (0) if inverse does (doesn't) exist
// void    mod_(x,n)             //do x=x mod n for bigInts x and n. (This never overflows its array).
// void    mult_(x,y)            //do x=x*y for bigInts x and y.
// void    multMod_(x,y,n)       //do x=x*y  mod n for bigInts x,y,n.
// void    powMod_(x,y,n)        //do x=x**y mod n, where x,y,n are bigInts (n is odd) and ** is exponentiation.  0**0=1.
// void    randBigInt_(b,n,s)    //do b = an n-bit random BigInt. if s=1, then nth bit (most significant bit) is set to 1. n>=1.
// void    randTruePrime_(ans,k) //do ans = a random k-bit true random prime (not just probable prime) with 1 in the msb.
// void    sub_(x,y)             //do x=x-y for bigInts x and y. Negative answers will be 2s complement.
//
// The following functions do NOT have a non-underscored version. 
// They each write a bigInt result to one or more parameters.  The caller is responsible for
// ensuring the arrays passed in are large enough to hold the results. 
//
// void addShift_(x,y,ys)       //do x=x+(y<<(ys*bpe))
// void carry_(x)               //do carries and borrows so each element of the bigInt x fits in bpe bits.
// void divide_(x,y,q,r)        //divide x by y giving quotient q and remainder r
// int  divInt_(x,n)            //do x=floor(x/n) for bigInt x and integer n, and return the remainder. (This never overflows its array).
// int  eGCD_(x,y,d,a,b)        //sets a,b,d to positive bigInts such that d = GCD_(x,y) = a*x-b*y
// void halve_(x)               //do x=floor(|x|/2)*sgn(x) for bigInt x in 2's complement.  (This never overflows its array).
// void leftShift_(x,n)         //left shift bigInt x by n bits.  n<bpe.
// void linComb_(x,y,a,b)       //do x=a*x+b*y for bigInts x and y and integers a and b
// void linCombShift_(x,y,b,ys) //do x=x+b*(y<<(ys*bpe)) for bigInts x and y, and integers b and ys
// void mont_(x,y,n,np)         //Montgomery multiplication (see comments where the function is defined)
// void multInt_(x,n)           //do x=x*n where x is a bigInt and n is an integer.
// void rightShift_(x,n)        //right shift bigInt x by n bits.  0 <= n < bpe. (This never overflows its array).
// void squareMod_(x,n)         //do x=x*x  mod n for bigInts x,n
// void subShift_(x,y,ys)       //do x=x-(y<<(ys*bpe)). Negative answers will be 2s complement.
//
// The following functions are based on algorithms from the _Handbook of Applied Cryptography_
//    powMod_()           = algorithm 14.94, Montgomery exponentiation
//    eGCD_,inverseMod_() = algorithm 14.61, Binary extended GCD_
//    GCD_()              = algorothm 14.57, Lehmer's algorithm
//    mont_()             = algorithm 14.36, Montgomery multiplication
//    divide_()           = algorithm 14.20  Multiple-precision division
//    squareMod_()        = algorithm 14.16  Multiple-precision squaring
//    randTruePrime_()    = algorithm  4.62, Maurer's algorithm
//    millerRabin()       = algorithm  4.24, Miller-Rabin algorithm
//
// Profiling shows:
//     randTruePrime_() spends:
//         10% of its time in calls to powMod_()
//         85% of its time in calls to millerRabin()
//     millerRabin() spends:
//         99% of its time in calls to powMod_()   (always with a base of 2)
//     powMod_() spends:
//         94% of its time in calls to mont_()  (almost always with x==y)
//
// This suggests there are several ways to speed up this library slightly:
//     - convert powMod_ to use a Montgomery form of k-ary window (or maybe a Montgomery form of sliding window)
//         -- this should especially focus on being fast when raising 2 to a power mod n
//     - convert randTruePrime_() to use a minimum r of 1/3 instead of 1/2 with the appropriate change to the test
//     - tune the parameters in randTruePrime_(), including c, m, and recLimit
//     - speed up the single loop in mont_() that takes 95% of the runtime, perhaps by reducing checking
//       within the loop when all the parameters are the same length.
//
// There are several ideas that look like they wouldn't help much at all:
//     - replacing trial division in randTruePrime_() with a sieve (that speeds up something taking almost no time anyway)
//     - increase bpe from 15 to 30 (that would help if we had a 32*32->64 multiplier, but not with JavaScript's 32*32->32)
//     - speeding up mont_(x,y,n,np) when x==y by doing a non-modular, non-Montgomery square
//       followed by a Montgomery reduction.  The intermediate answer will be twice as long as x, so that
//       method would be slower.  This is unfortunate because the code currently spends almost all of its time
//       doing mont_(x,x,...), both for randTruePrime_() and powMod_().  A faster method for Montgomery squaring
//       would have a large impact on the speed of randTruePrime_() and powMod_().  HAC has a couple of poorly-worded
//       sentences that seem to imply it's faster to do a non-modular square followed by a single
//       Montgomery reduction, but that's obviously wrong.
////////////////////////////////////////////////////////////////////////////////////////

//globals
bpe=0;         //bits stored per array element
mask=0;        //AND this with an array element to chop it down to bpe bits
radix=mask+1;  //equals 2^bpe.  A single 1 bit to the left of the last bit of mask.

//the digits for converting to different bases
digitsStr='0123456789ABCDEFGHIJKLMNOPQRSTUVWXYZabcdefghijklmnopqrstuvwxyz_=!@#$%^&*()[]{}|;:,.<>/?`~ \\\'\"+-';

//initialize the global variables
for (bpe=0; (1<<(bpe+1)) > (1<<bpe); bpe++);  //bpe=number of bits in the mantissa on this platform
bpe>>=1;                   //bpe=number of bits in one element of the array representing the bigInt
mask=(1<<bpe)-1;           //AND the mask with an integer to get its bpe least significant bits
radix=mask+1;              //2^bpe.  a single 1 bit to the left of the first bit of mask
one=int2bigInt(1,1,1);     //constant used in powMod_()

//the following global variables are scratchpad memory to 
//reduce dynamic memory allocation in the inner loop
t=new Array(0);
ss=t;       //used in mult_()
s0=t;       //used in multMod_(), squareMod_() 
s1=t;       //used in powMod_(), multMod_(), squareMod_() 
s2=t;       //used in powMod_(), multMod_()
s3=t;       //used in powMod_()
s4=t; s5=t; //used in mod_()
s6=t;       //used in bigInt2str()
s7=t;       //used in powMod_()
T=t;        //used in GCD_()
sa=t;       //used in mont_()
mr_x1=t; mr_r=t; mr_a=t;                                      //used in millerRabin()
eg_v=t; eg_u=t; eg_A=t; eg_B=t; eg_C=t; eg_D=t;               //used in eGCD_(), inverseMod_()
md_q1=t; md_q2=t; md_q3=t; md_r=t; md_r1=t; md_r2=t; md_tt=t; //used in mod_()

primes=t; pows=t; s_i=t; s_i2=t; s_R=t; s_rm=t; s_q=t; s_n1=t; 
  s_a=t; s_r2=t; s_n=t; s_b=t; s_d=t; s_x1=t; s_x2=t, s_aa=t; //used in randTruePrime_()

////////////////////////////////////////////////////////////////////////////////////////

//return array of all primes less than integer n
function findPrimes(n) {
  var i,s,p,ans;
  s=new Array(n);
  for (i=0;i<n;i++)
    s[i]=0;
  s[0]=2;
  p=0;    //first p elements of s are primes, the rest are a sieve
  for(;s[p]<n;) {                  //s[p] is the pth prime
    for(i=s[p]*s[p]; i<n; i+=s[p]) //mark multiples of s[p]
      s[i]=1;
    p++;
    s[p]=s[p-1]+1;
    for(; s[p]<n && s[s[p]]; s[p]++); //find next prime (where s[p]==0)
  }
  ans=new Array(p);
  for(i=0;i<p;i++)
    ans[i]=s[i];
  return ans;
}

//does a single round of Miller-Rabin base b consider x to be a possible prime?
//x is a bigInt, and b is an integer
function millerRabin(x,b) {
  var i,j,k,s;

  if (mr_x1.length!=x.length) {
    mr_x1=dup(x);
    mr_r=dup(x);
    mr_a=dup(x);
  }

  copyInt_(mr_a,b);
  copy_(mr_r,x);
  copy_(mr_x1,x);

  addInt_(mr_r,-1);
  addInt_(mr_x1,-1);

  //s=the highest power of two that divides mr_r
  k=0;
  for (i=0;i<mr_r.length;i++)
    for (j=1;j<mask;j<<=1)
      if (x[i] & j) {
        s=(k<mr_r.length+bpe ? k : 0); 
         i=mr_r.length;
         j=mask;
      } else
        k++;

  if (s)                
    rightShift_(mr_r,s);

  powMod_(mr_a,mr_r,x);

  if (!equalsInt(mr_a,1) && !equals(mr_a,mr_x1)) {
    j=1;
    while (j<=s-1 && !equals(mr_a,mr_x1)) {
      squareMod_(mr_a,x);
      if (equalsInt(mr_a,1)) {
        return 0;
      }
      j++;
    }
    if (!equals(mr_a,mr_x1)) {
      return 0;
    }
  }
  return 1;  
}

//returns how many bits long the bigInt is, not counting leading zeros.
function bitSize(x) {
  var j,z,w;
  for (j=x.length-1; (x[j]==0) && (j>0); j--);
  for (z=0,w=x[j]; w; (w>>=1),z++);
  z+=bpe*j;
  return z;
}

//return a copy of x with at least n elements, adding leading zeros if needed
function expand(x,n) {
  var ans=int2bigInt(0,(x.length>n ? x.length : n)*bpe,0);
  copy_(ans,x);
  return ans;
}

//return a k-bit true random prime using Maurer's algorithm.
function randTruePrime(k) {
  var ans=int2bigInt(0,k,0);
  randTruePrime_(ans,k);
  return bigint_trim(ans,1);
}

//return a new bigInt equal to (x mod n) for bigInts x and n.
function mod(x,n) {
  var ans=dup(x);
  mod_(ans,n);
  return bigint_trim(ans,1);
}

//return (x+n) where x is a bigInt and n is an integer.
function addInt(x,n) {
  var ans=expand(x,x.length+1);
  addInt_(ans,n);
  return bigint_trim(ans,1);
}

//return x*y for bigInts x and y. This is faster when y<x.
function mult(x,y) {
  var ans=expand(x,x.length+y.length);
  mult_(ans,y);
  return bigint_trim(ans,1);
}

//return (x**y mod n) where x,y,n are bigInts and ** is exponentiation.  0**0=1. Faster for odd n.
function powMod(x,y,n) {
  var ans=expand(x,n.length);  
  powMod_(ans,bigint_trim(y,2),bigint_trim(n,2),0);  //this should work without the trim, but doesn't
  return bigint_trim(ans,1);
}

//return (x-y) for bigInts x and y.  Negative answers will be 2s complement
function sub(x,y) {
  var ans=expand(x,(x.length>y.length ? x.length+1 : y.length+1)); 
  sub_(ans,y);
  return bigint_trim(ans,1);
}

//return (x+y) for bigInts x and y.  
function add(x,y) {
  var ans=expand(x,(x.length>y.length ? x.length+1 : y.length+1)); 
  add_(ans,y);
  return bigint_trim(ans,1);
}

//return (x**(-1) mod n) for bigInts x and n.  If no inverse exists, it returns null
function inverseMod(x,n) {
  var ans=expand(x,n.length); 
  var s;
  s=inverseMod_(ans,n);
  return s ? bigint_trim(ans,1) : null;
}

//return (x*y mod n) for bigInts x,y,n.  For greater speed, let y<x.
function multMod(x,y,n) {
  var ans=expand(x,n.length);
  multMod_(ans,y,n);
  return bigint_trim(ans,1);
}

//generate a k-bit true random prime using Maurer's algorithm,
//and put it into ans.  The bigInt ans must be large enough to hold it.
function randTruePrime_(ans,k) {
  var c,m,pm,dd,j,r,B,divisible,z,zz,recSize;

  if (primes.length==0)
    primes=findPrimes(30000);  //check for divisibility by primes <=30000

  if (pows.length==0) {
    pows=new Array(512);
    for (j=0;j<512;j++) {
      pows[j]=Math.pow(2,j/511.-1.);
    }
  }

  //c and m should be tuned for a particular machine and value of k, to maximize speed
  c=0.1;  //c=0.1 in HAC
  m=20;   //generate this k-bit number by first recursively generating a number that has between k/2 and k-m bits
  recLimit=20; //stop recursion when k <=recLimit.  Must have recLimit >= 2

  if (s_i2.length!=ans.length) {
    s_i2=dup(ans);
    s_R =dup(ans);
    s_n1=dup(ans);
    s_r2=dup(ans);
    s_d =dup(ans);
    s_x1=dup(ans);
    s_x2=dup(ans);
    s_b =dup(ans);
    s_n =dup(ans);
    s_i =dup(ans);
    s_rm=dup(ans);
    s_q =dup(ans);
    s_a =dup(ans);
    s_aa=dup(ans);
  }

  if (k <= recLimit) {  //generate small random primes by trial division up to its square root
    pm=(1<<((k+2)>>1))-1; //pm is binary number with all ones, just over sqrt(2^k)
    copyInt_(ans,0);
    for (dd=1;dd;) {
      dd=0;
      ans[0]= 1 | (1<<(k-1)) | Math.floor(Math.random()*(1<<k));  //random, k-bit, odd integer, with msb 1
      for (j=1;(j<primes.length) && ((primes[j]&pm)==primes[j]);j++) { //trial division by all primes 3...sqrt(2^k)
        if (0==(ans[0]%primes[j])) {
          dd=1;
          break;
        }
      }
    }
    carry_(ans);
    return;
  }

  B=c*k*k;    //try small primes up to B (or all the primes[] array if the largest is less than B).
  if (k>2*m)  //generate this k-bit number by first recursively generating a number that has between k/2 and k-m bits
    for (r=1; k-k*r<=m; )
      r=pows[Math.floor(Math.random()*512)];   //r=Math.pow(2,Math.random()-1);
  else
    r=.5;

  //simulation suggests the more complex algorithm using r=.333 is only slightly faster.

  recSize=Math.floor(r*k)+1;

  randTruePrime_(s_q,recSize);
  copyInt_(s_i2,0);
  s_i2[Math.floor((k-2)/bpe)] |= (1<<((k-2)%bpe));   //s_i2=2^(k-2)
  divide_(s_i2,s_q,s_i,s_rm);                        //s_i=floor((2^(k-1))/(2q))

  z=bitSize(s_i);

  for (;;) {
    for (;;) {  //generate z-bit numbers until one falls in the range [0,s_i-1]
      randBigInt_(s_R,z,0);
      if (greater(s_i,s_R))
        break;
    }                //now s_R is in the range [0,s_i-1]
    addInt_(s_R,1);  //now s_R is in the range [1,s_i]
    add_(s_R,s_i);   //now s_R is in the range [s_i+1,2*s_i]

    copy_(s_n,s_q);
    mult_(s_n,s_R); 
    multInt_(s_n,2);
    addInt_(s_n,1);    //s_n=2*s_R*s_q+1
    
    copy_(s_r2,s_R);
    multInt_(s_r2,2);  //s_r2=2*s_R

    //check s_n for divisibility by small primes up to B
    for (divisible=0,j=0; (j<primes.length) && (primes[j]<B); j++)
      if (modInt(s_n,primes[j])==0) {
        divisible=1;
        break;
      }      

    if (!divisible)    //if it passes small primes check, then try a single Miller-Rabin base 2
      if (!millerRabin(s_n,2)) //this line represents 75% of the total runtime for randTruePrime_ 
        divisible=1;

    if (!divisible) {  //if it passes that test, continue checking s_n
      addInt_(s_n,-3);
      for (j=s_n.length-1;(s_n[j]==0) && (j>0); j--);  //strip leading zeros
      for (zz=0,w=s_n[j]; w; (w>>=1),zz++);
      zz+=bpe*j;                             //zz=number of bits in s_n, ignoring leading zeros
      for (;;) {  //generate z-bit numbers until one falls in the range [0,s_n-1]
        randBigInt_(s_a,zz,0);
        if (greater(s_n,s_a))
          break;
      }                //now s_a is in the range [0,s_n-1]
      addInt_(s_n,3);  //now s_a is in the range [0,s_n-4]
      addInt_(s_a,2);  //now s_a is in the range [2,s_n-2]
      copy_(s_b,s_a);
      copy_(s_n1,s_n);
      addInt_(s_n1,-1);
      powMod_(s_b,s_n1,s_n);   //s_b=s_a^(s_n-1) modulo s_n
      addInt_(s_b,-1);
      if (isZero(s_b)) {
        copy_(s_b,s_a);
        powMod_(s_b,s_r2,s_n);
        addInt_(s_b,-1);
        copy_(s_aa,s_n);
        copy_(s_d,s_b);
        GCD_(s_d,s_n);  //if s_b and s_n are relatively prime, then s_n is a prime
        if (equalsInt(s_d,1)) {
          copy_(ans,s_aa);
          return;     //if we've made it this far, then s_n is absolutely guaranteed to be prime
        }
      }
    }
  }
}

//Return an n-bit random BigInt (n>=1).  If s=1, then the most significant of those n bits is set to 1.
function randBigInt(n,s) {
  var a,b;
  a=Math.floor((n-1)/bpe)+2; //# array elements to hold the BigInt with a leading 0 element
  b=int2bigInt(0,0,a);
  randBigInt_(b,n,s);
  return b;
}

//Set b to an n-bit random BigInt.  If s=1, then the most significant of those n bits is set to 1.
//Array b must be big enough to hold the result. Must have n>=1
function randBigInt_(b,n,s) {
  var i,a;
  for (i=0;i<b.length;i++)
    b[i]=0;
  a=Math.floor((n-1)/bpe)+1; //# array elements to hold the BigInt
  for (i=0;i<a;i++) {
    b[i]=Math.floor(Math.random()*(1<<(bpe-1)));
  }
  b[a-1] &= (2<<((n-1)%bpe))-1;
  if (s==1)
    b[a-1] |= (1<<((n-1)%bpe));
}

//Return the greatest common divisor of bigInts x and y (each with same number of elements).
function GCD(x,y) {
  var xc,yc;
  xc=dup(x);
  yc=dup(y);
  GCD_(xc,yc);
  return xc;
}

//set x to the greatest common divisor of bigInts x and y (each with same number of elements).
//y is destroyed.
function GCD_(x,y) {
  var i,xp,yp,A,B,C,D,q,sing;
  if (T.length!=x.length)
    T=dup(x);

  sing=1;
  while (sing) { //while y has nonzero elements other than y[0]
    sing=0;
    for (i=1;i<y.length;i++) //check if y has nonzero elements other than 0
      if (y[i]) {
        sing=1;
        break;
      }
    if (!sing) break; //quit when y all zero elements except possibly y[0]

    for (i=x.length;!x[i] && i>=0;i--);  //find most significant element of x
    xp=x[i];
    yp=y[i];
    A=1; B=0; C=0; D=1;
    while ((yp+C) && (yp+D)) {
      q =Math.floor((xp+A)/(yp+C));
      qp=Math.floor((xp+B)/(yp+D));
      if (q!=qp)
        break;
      t= A-q*C;   A=C;   C=t;    //  do (A,B,xp, C,D,yp) = (C,D,yp, A,B,xp) - q*(0,0,0, C,D,yp)      
      t= B-q*D;   B=D;   D=t;
      t=xp-q*yp; xp=yp; yp=t;
    }
    if (B) {
      copy_(T,x);
      linComb_(x,y,A,B); //x=A*x+B*y
      linComb_(y,T,D,C); //y=D*y+C*T
    } else {
      mod_(x,y);
      copy_(T,x);
      copy_(x,y);
      copy_(y,T);
    } 
  }
  if (y[0]==0)
    return;
  t=modInt(x,y[0]);
  copyInt_(x,y[0]);
  y[0]=t;
  while (y[0]) {
    x[0]%=y[0];
    t=x[0]; x[0]=y[0]; y[0]=t;
  }
}

//do x=x**(-1) mod n, for bigInts x and n.
//If no inverse exists, it sets x to zero and returns 0, else it returns 1.
//The x array must be at least as large as the n array.
function inverseMod_(x,n) {
  var k=1+2*Math.max(x.length,n.length);

  if(!(x[0]&1)  && !(n[0]&1)) {  //if both inputs are even, then inverse doesn't exist
    copyInt_(x,0);
    return 0;
  }

  if (eg_u.length!=k) {
    eg_u=new Array(k);
    eg_v=new Array(k);
    eg_A=new Array(k);
    eg_B=new Array(k);
    eg_C=new Array(k);
    eg_D=new Array(k);
  }

  copy_(eg_u,x);
  copy_(eg_v,n);
  copyInt_(eg_A,1);
  copyInt_(eg_B,0);
  copyInt_(eg_C,0);
  copyInt_(eg_D,1);
  for (;;) {
    while(!(eg_u[0]&1)) {  //while eg_u is even
      halve_(eg_u);
      if (!(eg_A[0]&1) && !(eg_B[0]&1)) { //if eg_A==eg_B==0 mod 2
        halve_(eg_A);
        halve_(eg_B);      
      } else {
        add_(eg_A,n);  halve_(eg_A);
        sub_(eg_B,x);  halve_(eg_B);
      }
    }

    while (!(eg_v[0]&1)) {  //while eg_v is even
      halve_(eg_v);
      if (!(eg_C[0]&1) && !(eg_D[0]&1)) { //if eg_C==eg_D==0 mod 2
        halve_(eg_C);
        halve_(eg_D);      
      } else {
        add_(eg_C,n);  halve_(eg_C);
        sub_(eg_D,x);  halve_(eg_D);
      }
    }

    if (!greater(eg_v,eg_u)) { //eg_v <= eg_u
      sub_(eg_u,eg_v);
      sub_(eg_A,eg_C);
      sub_(eg_B,eg_D);
    } else {                   //eg_v > eg_u
      sub_(eg_v,eg_u);
      sub_(eg_C,eg_A);
      sub_(eg_D,eg_B);
    }
  
    if (equalsInt(eg_u,0)) {
      if (negative(eg_C)) //make sure answer is nonnegative
        add_(eg_C,n);
      copy_(x,eg_C);

      if (!equalsInt(eg_v,1)) { //if GCD_(x,n)!=1, then there is no inverse
        copyInt_(x,0);
        return 0;
      }
      return 1;
    }
  }
}

//return x**(-1) mod n, for integers x and n.  Return 0 if there is no inverse
function inverseModInt(x,n) {
  var a=1,b=0,t;
  for (;;) {
    if (x==1) return a;
    if (x==0) return 0;
    b-=a*Math.floor(n/x);
    n%=x;

    if (n==1) return b; //to avoid negatives, change this b to n-b, and each -= to +=
    if (n==0) return 0;
    a-=b*Math.floor(x/n);
    x%=n;
  }
}

//this deprecated function is for backward compatibility only. 
function inverseModInt_(x,n) {
   return inverseModInt(x,n);
}


//Given positive bigInts x and y, change the bigints v, a, and b to positive bigInts such that:
//     v = GCD_(x,y) = a*x-b*y
//The bigInts v, a, b, must have exactly as many elements as the larger of x and y.
function eGCD_(x,y,v,a,b) {
  var g=0;
  var k=Math.max(x.length,y.length);
  if (eg_u.length!=k) {
    eg_u=new Array(k);
    eg_A=new Array(k);
    eg_B=new Array(k);
    eg_C=new Array(k);
    eg_D=new Array(k);
  }
  while(!(x[0]&1)  && !(y[0]&1)) {  //while x and y both even
    halve_(x);
    halve_(y);
    g++;
  }
  copy_(eg_u,x);
  copy_(v,y);
  copyInt_(eg_A,1);
  copyInt_(eg_B,0);
  copyInt_(eg_C,0);
  copyInt_(eg_D,1);
  for (;;) {
    while(!(eg_u[0]&1)) {  //while u is even
      halve_(eg_u);
      if (!(eg_A[0]&1) && !(eg_B[0]&1)) { //if A==B==0 mod 2
        halve_(eg_A);
        halve_(eg_B);      
      } else {
        add_(eg_A,y);  halve_(eg_A);
        sub_(eg_B,x);  halve_(eg_B);
      }
    }

    while (!(v[0]&1)) {  //while v is even
      halve_(v);
      if (!(eg_C[0]&1) && !(eg_D[0]&1)) { //if C==D==0 mod 2
        halve_(eg_C);
        halve_(eg_D);      
      } else {
        add_(eg_C,y);  halve_(eg_C);
        sub_(eg_D,x);  halve_(eg_D);
      }
    }

    if (!greater(v,eg_u)) { //v<=u
      sub_(eg_u,v);
      sub_(eg_A,eg_C);
      sub_(eg_B,eg_D);
    } else {                //v>u
      sub_(v,eg_u);
      sub_(eg_C,eg_A);
      sub_(eg_D,eg_B);
    }
    if (equalsInt(eg_u,0)) {
      if (negative(eg_C)) {   //make sure a (C)is nonnegative
        add_(eg_C,y);
        sub_(eg_D,x);
      }
      multInt_(eg_D,-1);  ///make sure b (D) is nonnegative
      copy_(a,eg_C);
      copy_(b,eg_D);
      leftShift_(v,g);
      return;
    }
  }
}


//is bigInt x negative?
function negative(x) {
  return ((x[x.length-1]>>(bpe-1))&1);
}


//is (x << (shift*bpe)) > y?
//x and y are nonnegative bigInts
//shift is a nonnegative integer
function greaterShift(x,y,shift) {
  var kx=x.length, ky=y.length;
  k=((kx+shift)<ky) ? (kx+shift) : ky;
  for (i=ky-1-shift; i<kx && i>=0; i++) 
    if (x[i]>0)
      return 1; //if there are nonzeros in x to the left of the first column of y, then x is bigger
  for (i=kx-1+shift; i<ky; i++)
    if (y[i]>0)
      return 0; //if there are nonzeros in y to the left of the first column of x, then x is not bigger
  for (i=k-1; i>=shift; i--)
    if      (x[i-shift]>y[i]) return 1;
    else if (x[i-shift]<y[i]) return 0;
  return 0;
}

//is x > y? (x and y both nonnegative)
function greater(x,y) {
  var i;
  var k=(x.length<y.length) ? x.length : y.length;

  for (i=x.length;i<y.length;i++)
    if (y[i])
      return 0;  //y has more digits

  for (i=y.length;i<x.length;i++)
    if (x[i])
      return 1;  //x has more digits

  for (i=k-1;i>=0;i--)
    if (x[i]>y[i])
      return 1;
    else if (x[i]<y[i])
      return 0;
  return 0;
}

//divide x by y giving quotient q and remainder r.  (q=floor(x/y),  r=x mod y).  All 4 are bigints.
//x must have at least one leading zero element.
//y must be nonzero.
//q and r must be arrays that are exactly the same length as x. (Or q can have more).
//Must have x.length >= y.length >= 2.
function divide_(x,y,q,r) {
  var kx, ky;
  var i,j,y1,y2,c,a,b;
  copy_(r,x);
  for (ky=y.length;y[ky-1]==0;ky--); //ky is number of elements in y, not including leading zeros

  //normalize: ensure the most significant element of y has its highest bit set  
  b=y[ky-1];
  for (a=0; b; a++)
    b>>=1;  
  a=bpe-a;  //a is how many bits to shift so that the high order bit of y is leftmost in its array element
  leftShift_(y,a);  //multiply both by 1<<a now, then divide both by that at the end
  leftShift_(r,a);

  //Rob Visser discovered a bug: the following line was originally just before the normalization.
  for (kx=r.length;r[kx-1]==0 && kx>ky;kx--); //kx is number of elements in normalized x, not including leading zeros

  copyInt_(q,0);                      // q=0
  while (!greaterShift(y,r,kx-ky)) {  // while (leftShift_(y,kx-ky) <= r) {
    subShift_(r,y,kx-ky);             //   r=r-leftShift_(y,kx-ky)
    q[kx-ky]++;                       //   q[kx-ky]++;
  }                                   // }

  for (i=kx-1; i>=ky; i--) {
    if (r[i]==y[ky-1])
      q[i-ky]=mask;
    else
      q[i-ky]=Math.floor((r[i]*radix+r[i-1])/y[ky-1]);	

    //The following for(;;) loop is equivalent to the commented while loop, 
    //except that the uncommented version avoids overflow.
    //The commented loop comes from HAC, which assumes r[-1]==y[-1]==0
    //  while (q[i-ky]*(y[ky-1]*radix+y[ky-2]) > r[i]*radix*radix+r[i-1]*radix+r[i-2])
    //    q[i-ky]--;    
    for (;;) {
      y2=(ky>1 ? y[ky-2] : 0)*q[i-ky];
      c=y2>>bpe;
      y2=y2 & mask;
      y1=c+q[i-ky]*y[ky-1];
      c=y1>>bpe;
      y1=y1 & mask;

      if (c==r[i] ? y1==r[i-1] ? y2>(i>1 ? r[i-2] : 0) : y1>r[i-1] : c>r[i]) 
        q[i-ky]--;
      else
        break;
    }

    linCombShift_(r,y,-q[i-ky],i-ky);    //r=r-q[i-ky]*leftShift_(y,i-ky)
    if (negative(r)) {
      addShift_(r,y,i-ky);         //r=r+leftShift_(y,i-ky)
      q[i-ky]--;
    }
  }

  rightShift_(y,a);  //undo the normalization step
  rightShift_(r,a);  //undo the normalization step
}

//do carries and borrows so each element of the bigInt x fits in bpe bits.
function carry_(x) {
  var i,k,c,b;
  k=x.length;
  c=0;
  for (i=0;i<k;i++) {
    c+=x[i];
    b=0;
    if (c<0) {
      b=-(c>>bpe);
      c+=b*radix;
    }
    x[i]=c & mask;
    c=(c>>bpe)-b;
  }
}

//return x mod n for bigInt x and integer n.
function modInt(x,n) {
  var i,c=0;
  for (i=x.length-1; i>=0; i--)
    c=(c*radix+x[i])%n;
  return c;
}

//convert the integer t into a bigInt with at least the given number of bits.
//the returned array stores the bigInt in bpe-bit chunks, little endian (buff[0] is least significant word)
//Pad the array with leading zeros so that it has at least minSize elements.
//There will always be at least one leading 0 element.
function int2bigInt(t,bits,minSize) {   
  var i,k;
  k=Math.ceil(bits/bpe)+1;
  k=minSize>k ? minSize : k;
  buff=new Array(k);
  copyInt_(buff,t);
  return buff;
}

//return the bigInt given a string representation in a given base.  
//Pad the array with leading zeros so that it has at least minSize elements.
//If base=-1, then it reads in a space-separated list of array elements in decimal.
//The array will always have at least one leading zero, unless base=-1.
function str2bigInt(s,base,minSize) {
  var d, i, j, x, y, kk;
  var k=s.length;
  if (base==-1) { //comma-separated list of array elements in decimal
    x=new Array(0);
    for (;;) {
      y=new Array(x.length+1);
      for (i=0;i<x.length;i++)
        y[i+1]=x[i];
      y[0]=parseInt(s,10);
      x=y;
      d=s.indexOf(',',0);
      if (d<1) 
        break;
      s=s.substring(d+1);
      if (s.length==0)
        break;
    }
    if (x.length<minSize) {
      y=new Array(minSize);
      copy_(y,x);
      return y;
    }
    return x;
  }

  x=int2bigInt(0,base*k,0);
  for (i=0;i<k;i++) {
    d=digitsStr.indexOf(s.substring(i,i+1),0);
    if (base<=36 && d>=36)  //convert lowercase to uppercase if base<=36
      d-=26;
    if (d<base && d>=0) {   //ignore illegal characters
      multInt_(x,base);
      addInt_(x,d);
    }
  }

  for (k=x.length;k>0 && !x[k-1];k--); //strip off leading zeros
  k=minSize>k+1 ? minSize : k+1;
  y=new Array(k);
  kk=k<x.length ? k : x.length;
  for (i=0;i<kk;i++)
    y[i]=x[i];
  for (;i<k;i++)
    y[i]=0;
  return y;
}

//is bigint x equal to integer y?
//y must have less than bpe bits
function equalsInt(x,y) {
  var i;
  if (x[0]!=y)
    return 0;
  for (i=1;i<x.length;i++)
    if (x[i])
      return 0;
  return 1;
}

//are bigints x and y equal?
//this works even if x and y are different lengths and have arbitrarily many leading zeros
function equals(x,y) {
  var i;
  var k=x.length<y.length ? x.length : y.length;
  for (i=0;i<k;i++)
    if (x[i]!=y[i])
      return 0;
  if (x.length>y.length) {
    for (;i<x.length;i++)
      if (x[i])
        return 0;
  } else {
    for (;i<y.length;i++)
      if (y[i])
        return 0;
  }
  return 1;
}

//is the bigInt x equal to zero?
function isZero(x) {
  var i;
  for (i=0;i<x.length;i++)
    if (x[i])
      return 0;
  return 1;
}

//convert a bigInt into a string in a given base, from base 2 up to base 95.
//Base -1 prints the contents of the array representing the number.
function bigInt2str(x,base) {
  var i,t,s="";

  if (s6.length!=x.length) 
    s6=dup(x);
  else
    copy_(s6,x);

  if (base==-1) { //return the list of array contents
    for (i=x.length-1;i>0;i--)
      s+=x[i]+',';
    s+=x[0];
  }
  else { //return it in the given base
    while (!isZero(s6)) {
      t=divInt_(s6,base);  //t=s6 % base; s6=floor(s6/base);
      s=digitsStr.substring(t,t+1)+s;
    }
  }
  if (s.length==0)
    s="0";
  return s;
}

//returns a duplicate of bigInt x
function dup(x) {
  var i;
  buff=new Array(x.length);
  copy_(buff,x);
  return buff;
}

//do x=y on bigInts x and y.  x must be an array at least as big as y (not counting the leading zeros in y).
function copy_(x,y) {
  var i;
  var k=x.length<y.length ? x.length : y.length;
  for (i=0;i<k;i++)
    x[i]=y[i];
  for (i=k;i<x.length;i++)
    x[i]=0;
}

//do x=y on bigInt x and integer y.  
function copyInt_(x,n) {
  var i,c;
  for (c=n,i=0;i<x.length;i++) {
    x[i]=c & mask;
    c>>=bpe;
  }
}

//do x=x+n where x is a bigInt and n is an integer.
//x must be large enough to hold the result.
function addInt_(x,n) {
  var i,k,c,b;
  x[0]+=n;
  k=x.length;
  c=0;
  for (i=0;i<k;i++) {
    c+=x[i];
    b=0;
    if (c<0) {
      b=-(c>>bpe);
      c+=b*radix;
    }
    x[i]=c & mask;
    c=(c>>bpe)-b;
    if (!c) return; //stop carrying as soon as the carry_ is zero
  }
}

//right shift bigInt x by n bits.  0 <= n < bpe.
function rightShift_(x,n) {
  var i;
  var k=Math.floor(n/bpe);
  if (k) {
    for (i=0;i<x.length-k;i++) //right shift x by k elements
      x[i]=x[i+k];
    for (;i<x.length;i++)
      x[i]=0;
    n%=bpe;
  }
  for (i=0;i<x.length-1;i++) {
    x[i]=mask & ((x[i+1]<<(bpe-n)) | (x[i]>>n));
  }
  x[i]>>=n;
}

//do x=floor(|x|/2)*sgn(x) for bigInt x in 2's complement
function halve_(x) {
  var i;
  for (i=0;i<x.length-1;i++) {
    x[i]=mask & ((x[i+1]<<(bpe-1)) | (x[i]>>1));
  }
  x[i]=(x[i]>>1) | (x[i] & (radix>>1));  //most significant bit stays the same
}

//left shift bigInt x by n bits.
function leftShift_(x,n) {
  var i;
  var k=Math.floor(n/bpe);
  if (k) {
    for (i=x.length; i>=k; i--) //left shift x by k elements
      x[i]=x[i-k];
    for (;i>=0;i--)
      x[i]=0;  
    n%=bpe;
  }
  if (!n)
    return;
  for (i=x.length-1;i>0;i--) {
    x[i]=mask & ((x[i]<<n) | (x[i-1]>>(bpe-n)));
  }
  x[i]=mask & (x[i]<<n);
}

//do x=x*n where x is a bigInt and n is an integer.
//x must be large enough to hold the result.
function multInt_(x,n) {
  var i,k,c,b;
  if (!n)
    return;
  k=x.length;
  c=0;
  for (i=0;i<k;i++) {
    c+=x[i]*n;
    b=0;
    if (c<0) {
      b=-(c>>bpe);
      c+=b*radix;
    }
    x[i]=c & mask;
    c=(c>>bpe)-b;
  }
}

//do x=floor(x/n) for bigInt x and integer n, and return the remainder
function divInt_(x,n) {
  var i,r=0,s;
  for (i=x.length-1;i>=0;i--) {
    s=r*radix+x[i];
    x[i]=Math.floor(s/n);
    r=s%n;
  }
  return r;
}

//do the linear combination x=a*x+b*y for bigInts x and y, and integers a and b.
//x must be large enough to hold the answer.
function linComb_(x,y,a,b) {
  var i,c,k,kk;
  k=x.length<y.length ? x.length : y.length;
  kk=x.length;
  for (c=0,i=0;i<k;i++) {
    c+=a*x[i]+b*y[i];
    x[i]=c & mask;
    c>>=bpe;
  }
  for (i=k;i<kk;i++) {
    c+=a*x[i];
    x[i]=c & mask;
    c>>=bpe;
  }
}

//do the linear combination x=a*x+b*(y<<(ys*bpe)) for bigInts x and y, and integers a, b and ys.
//x must be large enough to hold the answer.
function linCombShift_(x,y,b,ys) {
  var i,c,k,kk;
  k=x.length<ys+y.length ? x.length : ys+y.length;
  kk=x.length;
  for (c=0,i=ys;i<k;i++) {
    c+=x[i]+b*y[i-ys];
    x[i]=c & mask;
    c>>=bpe;
  }
  for (i=k;c && i<kk;i++) {
    c+=x[i];
    x[i]=c & mask;
    c>>=bpe;
  }
}

//do x=x+(y<<(ys*bpe)) for bigInts x and y, and integers a,b and ys.
//x must be large enough to hold the answer.
function addShift_(x,y,ys) {
  var i,c,k,kk;
  k=x.length<ys+y.length ? x.length : ys+y.length;
  kk=x.length;
  for (c=0,i=ys;i<k;i++) {
    c+=x[i]+y[i-ys];
    x[i]=c & mask;
    c>>=bpe;
  }
  for (i=k;c && i<kk;i++) {
    c+=x[i];
    x[i]=c & mask;
    c>>=bpe;
  }
}

//do x=x-(y<<(ys*bpe)) for bigInts x and y, and integers a,b and ys.
//x must be large enough to hold the answer.
function subShift_(x,y,ys) {
  var i,c,k,kk;
  k=x.length<ys+y.length ? x.length : ys+y.length;
  kk=x.length;
  for (c=0,i=ys;i<k;i++) {
    c+=x[i]-y[i-ys];
    x[i]=c & mask;
    c>>=bpe;
  }
  for (i=k;c && i<kk;i++) {
    c+=x[i];
    x[i]=c & mask;
    c>>=bpe;
  }
}

//do x=x-y for bigInts x and y.
//x must be large enough to hold the answer.
//negative answers will be 2s complement
function sub_(x,y) {
  var i,c,k,kk;
  k=x.length<y.length ? x.length : y.length;
  for (c=0,i=0;i<k;i++) {
    c+=x[i]-y[i];
    x[i]=c & mask;
    c>>=bpe;
  }
  for (i=k;c && i<x.length;i++) {
    c+=x[i];
    x[i]=c & mask;
    c>>=bpe;
  }
}

//do x=x+y for bigInts x and y.
//x must be large enough to hold the answer.
function add_(x,y) {
  var i,c,k,kk;
  k=x.length<y.length ? x.length : y.length;
  for (c=0,i=0;i<k;i++) {
    c+=x[i]+y[i];
    x[i]=c & mask;
    c>>=bpe;
  }
  for (i=k;c && i<x.length;i++) {
    c+=x[i];
    x[i]=c & mask;
    c>>=bpe;
  }
}

//do x=x*y for bigInts x and y.  This is faster when y<x.
function mult_(x,y) {
  var i;
  if (ss.length!=2*x.length)
    ss=new Array(2*x.length);
  copyInt_(ss,0);
  for (i=0;i<y.length;i++)
    if (y[i])
      linCombShift_(ss,x,y[i],i);   //ss=1*ss+y[i]*(x<<(i*bpe))
  copy_(x,ss);
}

//do x=x mod n for bigInts x and n.
function mod_(x,n) {
  if (s4.length!=x.length)
    s4=dup(x);
  else
    copy_(s4,x);
  if (s5.length!=x.length)
    s5=dup(x);  
  divide_(s4,n,s5,x);  //x = remainder of s4 / n
}

//do x=x*y mod n for bigInts x,y,n.
//for greater speed, let y<x.
function multMod_(x,y,n) {
  var i;
  if (s0.length!=2*x.length)
    s0=new Array(2*x.length);
  copyInt_(s0,0);
  for (i=0;i<y.length;i++)
    if (y[i])
      linCombShift_(s0,x,y[i],i);   //s0=1*s0+y[i]*(x<<(i*bpe))
  mod_(s0,n);
  copy_(x,s0);
}

//do x=x*x mod n for bigInts x,n.
function squareMod_(x,n) {
  var i,j,d,c,kx,kn,k;
  for (kx=x.length; kx>0 && !x[kx-1]; kx--);  //ignore leading zeros in x
  k=kx>n.length ? 2*kx : 2*n.length; //k=# elements in the product, which is twice the elements in the larger of x and n
  if (s0.length!=k) 
    s0=new Array(k);
  copyInt_(s0,0);
  for (i=0;i<kx;i++) {
    c=s0[2*i]+x[i]*x[i];
    s0[2*i]=c & mask;
    c>>=bpe;
    for (j=i+1;j<kx;j++) {
      c=s0[i+j]+2*x[i]*x[j]+c;
      s0[i+j]=(c & mask);
      c>>=bpe;
    }
    s0[i+kx]=c;
  }
  mod_(s0,n);
  copy_(x,s0);
}

//return x with exactly k leading zero elements
function bigint_trim(x,k) {
  var i,y;
  for (i=x.length; i>0 && !x[i-1]; i--);
  y=new Array(i+k);
  copy_(y,x);
  return y;
}

//do x=x**y mod n, where x,y,n are bigInts and ** is exponentiation.  0**0=1.
//this is faster when n is odd.  x usually needs to have as many elements as n.
function powMod_(x,y,n) {
  var k1,k2,kn,np;
  if(s7.length!=n.length)
    s7=dup(n);

  //for even modulus, use a simple square-and-multiply algorithm,
  //rather than using the more complex Montgomery algorithm.
  if ((n[0]&1)==0) {
    copy_(s7,x);
    copyInt_(x,1);
    while(!equalsInt(y,0)) {
      if (y[0]&1)
        multMod_(x,s7,n);
      divInt_(y,2);
      squareMod_(s7,n); 
    }
    return;
  }

  //calculate np from n for the Montgomery multiplications
  copyInt_(s7,0);
  for (kn=n.length;kn>0 && !n[kn-1];kn--);
  np=radix-inverseModInt(modInt(n,radix),radix);
  s7[kn]=1;
  multMod_(x ,s7,n);   // x = x * 2**(kn*bp) mod n

  if (s3.length!=x.length)
    s3=dup(x);
  else
    copy_(s3,x);

  for (k1=y.length-1;k1>0 & !y[k1]; k1--);  //k1=first nonzero element of y
  if (y[k1]==0) {  //anything to the 0th power is 1
    copyInt_(x,1);
    return;
  }
  for (k2=1<<(bpe-1);k2 && !(y[k1] & k2); k2>>=1);  //k2=position of first 1 bit in y[k1]
  for (;;) {
    if (!(k2>>=1)) {  //look at next bit of y
      k1--;
      if (k1<0) {
        mont_(x,one,n,np);
        return;
      }
      k2=1<<(bpe-1);
    }    
    mont_(x,x,n,np);

    if (k2 & y[k1]) //if next bit is a 1
      mont_(x,s3,n,np);
  }
}    

//do x=x*y*Ri mod n for bigInts x,y,n, 
//  where Ri = 2**(-kn*bpe) mod n, and kn is the 
//  number of elements in the n array, not 
//  counting leading zeros.  
//x must be large enough to hold the answer.
//It's OK if x and y are the same variable.
//must have:
//  x,y < n
//  n is odd
//  np = -(n^(-1)) mod radix
function mont_(x,y,n,np) {
  var i,j,c,ui,t;
  var kn=n.length;
  var ky=y.length;

  if (sa.length!=kn)
    sa=new Array(kn);

  for (;kn>0 && n[kn-1]==0;kn--); //ignore leading zeros of n
  //this function sometimes gives wrong answers when the next line is uncommented
  //for (;ky>0 && y[ky-1]==0;ky--); //ignore leading zeros of y

  copyInt_(sa,0);

  //the following loop consumes 95% of the runtime for randTruePrime_() and powMod_() for large keys
  for (i=0; i<kn; i++) {
    t=sa[0]+x[i]*y[0];
    ui=((t & mask) * np) & mask;  //the inner "& mask" is needed on Macintosh MSIE, but not windows MSIE
    c=(t+ui*n[0]) >> bpe;
    t=x[i];

    //do sa=(sa+x[i]*y+ui*n)/b   where b=2**bpe
    for (j=1;j<ky;j++) { 
      c+=sa[j]+t*y[j]+ui*n[j];
      sa[j-1]=c & mask;
      c>>=bpe;
    }    
    for (;j<kn;j++) { 
      c+=sa[j]+ui*n[j];
      sa[j-1]=c & mask;
      c>>=bpe;
    }    
    sa[j-1]=c & mask;
  }

  if (!greater(n,sa))
    sub_(sa,n);
  copy_(x,sa);
}