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To speed up my bignum divisons i need to speed up operation y=x^2 for bigints which are represented as dynamic arrays of unsigned DWORDs To be clear:

DWORD x[n+1]={ LSW,......,MSW };
  • where n+1 is number of used DWORDs
  • so value of number x = x[0]+x[1]<<32 + ... x[N]<<32*(n)

The question is: How to compute y=x^2 as fast as possible without precision loss ? - using C++ and with integer arithmetics (32bit with Carry) at disposal.

My current aproach is applying multiplication y=x*x and avoid multiple multiplication. for example:

x =  x[0]+x[1]<<32 + ... x[n]<<32*(n)

for simplicity let me rewrite it:


where index represent the adress inside array, so:


y0     =x0*x0
y1     =x1*x0+x0*x1
y2     =x2*x0+x1*x1+x0*x2
y3     =x3*x0+x2*x1+x1*x2
y(2n-3)=xn(n-2)*x(n  )+x(n-1)*x(n-1)+x(n  )*x(n-2) 
y(2n-2)=xn(n-1)*x(n  )+x(n  )*x(n-1) 
y(2n-1)=xn(n  )*x(n  )

after closer look is clear that almost all xi*xj appears twice (not the first and last one) which means that N*N multiplications can be replaced by (N+1)*(N/2) multiplications. P.S. 32bit*32bit=64bit so the result of every mul+add operation is handled as 64+1 bit.

is there a better way to compute this fast ? All i found during searches are sqrts algorithms not sqr...

[edit1: fast sqr]

!!! beware that all numbers in my code are MSW first,... not as in above test (there are LSW first for simplicity of equations otherwise it would be an index mess)

current functional fsqr implementation

void arbnum::sqr(const arbnum &x)
    // O((N+1)*N/2)
    arbnum c;
    DWORD h,l;
    int N,nx,nc,i,i0,i1,k;
    for (i=0;i<=nc;i++) c.dat[i]=0;
    for (i=1;i<N;i++)
     for (i0=0;(i0<=nx)&&(i0<=i);i0++)
        if (i0>=i1) break;
        if (i1> nx) continue;
        h=x.dat[nx-i0]; if (!h) continue;
        l=x.dat[nx-i1]; if (!l) continue;
        alu.mul(h,l,h,l);                       k=nc-i;
        if (k>=0) alu.add(c.dat[k],c.dat[k],l); k--;
        if (k>=0) alu.adc(c.dat[k],c.dat[k],h); k--;
        for (;(alu.cy)&&(k>=0);k--) alu.inc(c.dat[k]);
    for (i=0;i<=N;i+=2)
        h=x.dat[nx-i0]; if (!h) continue;
        alu.mul(h,l,h,h);                       k=nc-i;
        if (k>=0) alu.add(c.dat[k],c.dat[k],l); k--;
        if (k>=0) alu.adc(c.dat[k],c.dat[k],h); k--;
        for (;(alu.cy)&&(k>=0);k--) alu.inc(c.dat[k]);

[edit1: use of Karatsuba multiplication]

(thanks to Calpis)

i implemented karatsuba multiplication, but the results are massively slower even than by use of simple O(N^2) multiplication. probably because of that horrible recursion that i cant see any way to avoid. Its trade off must be at really large numbers (bigger than hundreds of digits) ... but even than there is a lot of memory transfers. is there any way to avoid recursion calls (non recursive variant,... almost all recursive algorithms can be done that way) still will try to tweak things up and see what happens (avoid normalizations, etc..., also could have some silly mistake in code). Anyway after solving karatsuba for case x*x there is not much performance gain.

[edit2:] optimized code for karatsuba implementation:

void arbnum::_mul_karatsuba(DWORD *z,DWORD *x,DWORD *y,int n)
    // z[2n]=x[n]*y[n]; n=2^m
    int i;    for (i=0;i<n;i++) if (x[i]) { i=-1; break; }
    if (i< 0) for (i=0;i<n;i++) if (y[i]) { i=-1; break; }
    if (i>=0){for (i=0;i<n+n;i++) z[i]=0; return; }     // 0.? = 0
    if (n==1) { alu.mul(z[0],z[1],x[0],y[0]); return; }
    if (n< 1) return;
    int n2=n>>1;
    _mul_karatsuba(z+n,x+n2,y+n2,n2);                   // z0 = x0.y0
    _mul_karatsuba(z  ,x   ,y   ,n2);                   // z2 = x1.y1
    DWORD *q=new DWORD[n<<1],*q0,*q1,*qq; BYTE cx,cy;
    if (q==NULL) { _error(_arbnum_error_NotEnoughMemory); return; }
    #define _add { alu.add(qq[i],q0[i],q1[i]); for (i--;i>=0;i--) alu.adc(qq[i],q0[i],q1[i]); } // qq=q0+q1 ...[i..0]
    #define _sub { alu.sub(qq[i],q0[i],q1[i]); for (i--;i>=0;i--) alu.sbc(qq[i],q0[i],q1[i]); } // qq=q0-q1 ...[i..0]
    qq=q;    q0=x+n2; q1=x;   i=n2-1; _add; cx=alu.cy;  // =x0+x1
    qq=q+n2; q0=y+n2; q1=y;   i=n2-1; _add; cy=alu.cy;  // =y0+y1
    _mul_karatsuba(q+n,q+n2,q,n2);                      // =(x0+x1)(y0+y1) mod ((2^N)-1)
    if (cx) { qq=q+n; q0=qq; q1=q+n2; i=n2-1; _add; }   // +=cx*(y0+y1)<<n2
    if (cy) { qq=q+n; q0=qq; q1=q   ; i=n2-1; _add; }   // +=cy*(x0+x1)<<n2
    qq=q+n;  q0=qq;   q1=z+n; i=n-1;  _sub;             // -=z0
    qq=q+n;  q0=qq;   q1=z;   i=n-1;  _sub;             // -=z2
    qq=z+n2; q0=qq;   q1=q+n; i=n-1;  _add;             // z1=(x0+x1)(y0+y1)-z0-z2
    for (i=n2-1;i>=0;i--) if (alu.cy) alu.inc(z[i]); else break;
    delete q;
    #undef _add
    #undef _sub
void arbnum::mul_karatsuba(const arbnum &x,const arbnum &y)
    // O(3*(N)^log2(3)) ~ O(3*(N^1.585))
    int s=x.sig*y.sig;
    arbnum a,b; a=x; b=y; a.sig=+1; b.sig=+1;
    int i,n;
    for (n=1;(n<a.siz)||(n<b.siz);n<<=1);
    _alloc(n+n); for (i=0;i<siz;i++) dat[i]=0;
//  _normalize();

performance test for y=x^2 looped 1000x times, 0.9

x=0.98765588997654321000000009876... | 98*32 bits
sqr [ 213.989 ms ] ... O((N+1)*N/2) fast sqr
mul1[ 363.472 ms ] ... O(N^2) classic multiplication
mul2[ 349.384 ms ] ... O(3*(N^log2(3))) optimized karatsuba multiplication
mul3[ 9345.127 ms] ... O(3*(N^log2(3))) unoptimized karatsuba multiplication

x=0.98765588997654321000... | 195*32 bits
sqr [ 883.01 ms ]
mul1[ 1427.02 ms ]
mul2[ 1089.84 ms ]

x=0.98765588997654321000... | 389*32 bits
sqr [ 3189.19 ms ]
mul1[ 5553.23 ms ]
mul2[ 3159.07 ms ]

after optimizations for karatsuba the code is massively faster then before. still for smaller numbers is slightly less then half speed of my O(N^2) multiplication. for bigger numbers is faster with the ratio given by the complexities of booth multiplications. The treshold for multiplication is around 32*98bits and for sqr around 32*389 bits so if the sum of input bits cross this treshold then karatsuba multiplication will be used for speed up multiplication and that goes similar for sqr too.

btw. optimizations included:

  • minimize heap trashing by too big recursion argument
  • avoidance of any bignum aritmetics (+,-) 32bit ALU with carry is used instead.
  • ignoring 0*y or x*0 or 0*0 cases
  • reformatting input x,y number sizes to power of two to avoid reallocating
  • implement modulo multiplication for z1=(x0+x1)*(y0+y1) to minimize recursion

[edit3:] Modified Schönhage-Strassen multiplication to sqr implementation:

I have tested use of FTT and NTT transforms to speed up sqr computation. The results are these:

  1. FTT

    • lose accuracy and therefore need high precision complex numbers
    • this actualy slow things down considerably so no speed up is present.
    • result is not precise (can be wrongly rounded)
    • FTT is unusable
  2. NTT

    • NTT is finite field DFT and so no accuracy loss occur
    • need of modular arithmetics on unsigned integers: modpow,modmul,modadd,modsub
    • i use DWORD (32bit unsigned integer numbers)
    • NTT input/otput vector size is limited because of overflow issues !!! For 32bit modular arithmetics is N limited to (2^32)/(max(input[])^2) so bigint must be divided to smaller chunks (i use BYTES so max size of bigint processed is (2^32)/((2^8)^2)=2^16 Bytes=2^14 DWORDs=16384 DWORDs)
    • sqr use only 1xNTT + 1xINTT insted of 2xNTT + 1xINTT for multiplication
    • NTT usage is too slow and the treshold number size is too large for practical use in my implementation (for mul an also for sqr), is possible that is even over the overflow limit so 64bit modular arithmetics should be used which can slow things down even more.
    • NTT is for my purposes also unusable

some measurements:

a = 0.98765588997654321000 | 389*32 bits
looped 1x times
sqr1[ 3.177 ms ] fast sqr
sqr2[ 720.419 ms ] NTT sqr
mul1[ 5.588 ms ] simpe mul
mul2[ 3.172 ms ] karatsuba mul
mul3[ 1053.382 ms ] NTT mul

my implementation:

void arbnum::sqr_NTT(const arbnum &x)
    // O(N*log(N)*(log(log(N)))) - 1x NTT
    // Schönhage-Strassen sqr
    // to prevent NTT overflow: n <= 48K * 8bit -> result siz <= 12K * 32bit -> x.siz+y.siz <= 12K !!!
    int i,j,k,n;
    int s=x.sig*x.sig,exp0=x.exp+x.exp-((x.siz+x.siz)<<5)+2;
    i=x.siz; for (n=1;n<i;n<<=1);
    if (n+n>0x3000) { _error(_arbnum_error_TooBigNumber); zero(); return; }
    DWORD *xx,*yy,q,qq;
    xx=new DWORD[n+n];
    #ifdef _mmap_h
    if (xx) mmap_new(xx,(n+n)<<2);
    if (xx==NULL) { _error(_arbnum_error_NotEnoughMemory); zero(); return; }
    // zero padding (and split DWORDs to BYTEs)
    for (i--,k=0;i>=0;i--)
        xx[k]=q&0xFF; k++; q>>=8;
        xx[k]=q&0xFF; k++; q>>=8;
        xx[k]=q&0xFF; k++; q>>=8;
        xx[k]=q&0xFF; k++;
        } for (;k<n;k++) xx[k]=0;
    fourier_NTT ntt;
    ntt.NTT(yy,xx,n);   // init NTT for n
    // convolution
    for (i=0;i<n;i++) yy[i]=modmul(yy[i],yy[i],ntt.p);
    q=0; for (i=0,j=0;i<n;i++) { qq=xx[i]; q+=qq&0xFF;  yy[n-i-1]=q&0xFF; q>>=8; qq>>=8; q+=qq; }
    // merge WORDs to DWORDs and copy them to result
    for (i=0,j=0;i<siz;i++)
        q =(yy[j]<<24)&0xFF000000; j++;
        q|=(yy[j]<<16)&0x00FF0000; j++;
        q|=(yy[j]<< 8)&0x0000FF00; j++;
        q|=(yy[j]    )&0x000000FF; j++;
    #ifdef _mmap_h
    if (xx) mmap_del(xx);
    delete xx;
//  _normalize();


for smaller numbers is the best option my fast sqr approach, after treshold is karatsuba multiplication better. But i still think there should be something trivial which we have overlooked has anyone any other ideas?

[Edit: 4 NTT optimization]

after massively-intense optimizations (mostly NTT) here: modular arithmetics and NTT (finite field DFT) optimizations

some values have changed:

a = 0.98765588997654321000 | 1553*32bits
looped 10x times
mul2[ 28.585 ms ] karatsuba mul
mul3[ 26.311 ms ] NTT mul

So now NTT multiplication is finally faster then karatsuba after about 1500*32bit treshold


a = 0.99991970486 | 1553*32 bits
looped: 10x
sqr1[  58.656 ms ] fast sqr     
sqr2[  13.447 ms ] NTT sqr      
mul1[ 102.563 ms ] simpe mul    
mul2[  28.916 ms ] karatsuba mul Error
mul3[  19.470 ms ] NTT mul      
  • I found out that mine Karatsuba (over/under)flows the LSB of each DWORD segment of bignum
  • when I research will update the code ...
  • Also after further NTT optimizations the tresholds changed
  • so for NTT sqr it is 310*32=9920 bit of operand
  • and for NTT mul it is 1396*32=44672 bit of result (sum of bits of operands)
share|improve this question
My question is why you decided to implement your own bignum implementation? The GNU Multiple Precision Arithmetic Library is the probably one of the most common bignum libraries in use, and it should be pretty optimal with all its operations. –  Joachim Pileborg Aug 27 '13 at 12:27
I am using my own bignum libs for compatibility reasons. Porting all code to different libraries is more time costly than it could seem at first look (and sometimes not even possible because of compiler incompatibilities especial with gcc code). I am currently just tweaking things up,... all runs as it should but more speed is always wanted :) –  Spektre Aug 27 '13 at 12:43
P.S. for NTT use i strongly recommend that NTT is computed in 4x higher precision than input values (so for 8bit numbers you need to convert them to 32bit numbers) to get the compromise between max array size an speed –  Spektre Sep 2 '13 at 14:56

2 Answers 2

up vote 1 down vote accepted

If I understand your algorithm correctly, it seems O(n^2) where n is the number of digits.

Have you looked at Karatsuba Algorithm? It speeds up multiplication using the divide and conquer approach. It may be worth taking a look at.

share|improve this answer
nice this speeds up things a lot... because of x=y ... hard to assume complexity before encoding it. –  Spektre Aug 27 '13 at 18:50
on the other hand, solving karatsuba for x*x come to the same result as my approach :( i will try if more recursive approach is better ... my compexity now goes from O(n^2) to ~O(0.5*N^2) but according that page should be lower –  Spektre Aug 27 '13 at 19:05
OK i have checked the karatsuba algorithm. It is fine for speed up multiplications but for x^2 is applicable only for really big numbers. I think there should be something simple and much faster than general multiplication out there. –  Spektre Aug 29 '13 at 11:35
i successfully tested Schönhage–Strassen multiplication, with FFT there are problems with rounding and is little bit slow due to complex numbers, i am new to NTT , but have finally get it to work now i have to implement fast NTT and select word size (tested on decadic strings only for now) using Schönhage–Strassen for sqr should be 1/3 faster than multiplication (1xNTT is removed) so i am curious how much fast my implementation will be when finished. –  Spektre Aug 31 '13 at 11:40
I have tested the NTT too, but the result is not good. so my fast sqr and yours karatsuba wins the race. I have accepted your answer. –  Spektre Sep 2 '13 at 14:47

If you're looking to write a new better exponent you might have to write it in assembly. This is the code from golang.


share|improve this answer
i am mostly using borland C++ compiler ... assembly functions are slower than normal C++ implementation (not shore why, perhaps state push/pop), i am searching only for x^2, for pows i am using exp2,log2 but anyway nice asm code –  Spektre Aug 27 '13 at 18:38

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