/**************************************************************************\
MODULE: ZZ_pX
SUMMARY:
The class ZZ_pX implements polynomial arithmetic modulo p.
Polynomial arithmetic is implemented using the FFT, combined with the
Chinese Remainder Theorem. A more detailed description of the
techniques used here can be found in [Shoup, J. Symbolic
Comp. 20:363-397, 1995].
Small degree polynomials are multiplied either with classical
or Karatsuba algorithms.
\**************************************************************************/
#include <NTL/ZZ_p.h>
#include <NTL/vec_ZZ_p.h>
class ZZ_pX {
public:
ZZ_pX(); // initialize to 0
ZZ_pX(const ZZ_pX& a); // copy constructor
ZZ_pX& operator=(const ZZ_pX& a); // assignment
ZZ_pX& operator=(const ZZ_p& a); // assignment
ZZ_pX& operator=(const long a); // assignment
ZZ_pX(long i, const ZZ_p& c); // initialize to X^i*c
ZZ_pX(long i, long c);
~ZZ_pX(); // destructor
};
/**************************************************************************\
Comparison
\**************************************************************************/
long operator==(const ZZ_pX& a, const ZZ_pX& b);
long operator!=(const ZZ_pX& a, const ZZ_pX& b);
// PROMOTIONS: operators ==, != promote {long, ZZ_p} to ZZ_pX on (a, b).
long IsZero(const ZZ_pX& a); // test for 0
long IsOne(const ZZ_pX& a); // test for 1
/**************************************************************************\
Addition
\**************************************************************************/
// operator notation:
ZZ_pX operator+(const ZZ_pX& a, const ZZ_pX& b);
ZZ_pX operator-(const ZZ_pX& a, const ZZ_pX& b);
ZZ_pX operator-(const ZZ_pX& a); // unary -
ZZ_pX& operator+=(ZZ_pX& x, const ZZ_pX& a);
ZZ_pX& operator+=(ZZ_pX& x, const ZZ_p& a);
ZZ_pX& operator+=(ZZ_pX& x, long a);
ZZ_pX& operator-=(ZZ_pX& x, const ZZ_pX& a);
ZZ_pX& operator-=(ZZ_pX& x, const ZZ_p& a);
ZZ_pX& operator-=(ZZ_pX& x, long a);
ZZ_pX& operator++(ZZ_pX& x); // prefix
void operator++(ZZ_pX& x, int); // postfix
ZZ_pX& operator--(ZZ_pX& x); // prefix
void operator--(ZZ_pX& x, int); // postfix
// procedural versions:
void add(ZZ_pX& x, const ZZ_pX& a, const ZZ_pX& b); // x = a + b
void sub(ZZ_pX& x, const ZZ_pX& a, const ZZ_pX& b); // x = a - b
void negate(ZZ_pX& x, const ZZ_pX& a); // x = -a
// PROMOTIONS: binary +, - and procedures add, sub promote
// {long, ZZ_p} to ZZ_pX on (a, b).
/**************************************************************************\
Multiplication
\**************************************************************************/
// operator notation:
ZZ_pX operator*(const ZZ_pX& a, const ZZ_pX& b);
ZZ_pX& operator*=(ZZ_pX& x, const ZZ_pX& a);
ZZ_pX& operator*=(ZZ_pX& x, const ZZ_p& a);
ZZ_pX& operator*=(ZZ_pX& x, long a);
// procedural versions:
void mul(ZZ_pX& x, const ZZ_pX& a, const ZZ_pX& b); // x = a * b
void sqr(ZZ_pX& x, const ZZ_pX& a); // x = a^2
ZZ_pX sqr(const ZZ_pX& a);
// PROMOTIONS: operator * and procedure mul promote {long, ZZ_p} to ZZ_pX
// on (a, b).
void power(ZZ_pX& x, const ZZ_pX& a, long e); // x = a^e (e >= 0)
ZZ_pX power(const ZZ_pX& a, long e);
/**************************************************************************\
Shift Operations
LeftShift by n means multiplication by X^n
RightShift by n means division by X^n
A negative shift amount reverses the direction of the shift.
\**************************************************************************/
// operator notation:
ZZ_pX operator<<(const ZZ_pX& a, long n);
ZZ_pX operator>>(const ZZ_pX& a, long n);
ZZ_pX& operator<<=(ZZ_pX& x, long n);
ZZ_pX& operator>>=(ZZ_pX& x, long n);
// procedural versions:
void LeftShift(ZZ_pX& x, const ZZ_pX& a, long n);
ZZ_pX LeftShift(const ZZ_pX& a, long n);
void RightShift(ZZ_pX& x, const ZZ_pX& a, long n);
ZZ_pX RightShift(const ZZ_pX& a, long n);
/**************************************************************************\
Division
\**************************************************************************/
// operator notation:
ZZ_pX operator/(const ZZ_pX& a, const ZZ_pX& b);
ZZ_pX operator/(const ZZ_pX& a, const ZZ_p& b);
ZZ_pX operator/(const ZZ_pX& a, long b);
ZZ_pX& operator/=(ZZ_pX& x, const ZZ_pX& b);
ZZ_pX& operator/=(ZZ_pX& x, const ZZ_p& b);
ZZ_pX& operator/=(ZZ_pX& x, long b);
ZZ_pX operator%(const ZZ_pX& a, const ZZ_pX& b);
ZZ_pX& operator%=(ZZ_pX& x, const ZZ_pX& b);
// procedural versions:
void DivRem(ZZ_pX& q, ZZ_pX& r, const ZZ_pX& a, const ZZ_pX& b);
// q = a/b, r = a%b
void div(ZZ_pX& q, const ZZ_pX& a, const ZZ_pX& b);
void div(ZZ_pX& q, const ZZ_pX& a, const ZZ_p& b);
void div(ZZ_pX& q, const ZZ_pX& a, long b);
// q = a/b
void rem(ZZ_pX& r, const ZZ_pX& a, const ZZ_pX& b);
// r = a%b
long divide(ZZ_pX& q, const ZZ_pX& a, const ZZ_pX& b);
// if b | a, sets q = a/b and returns 1; otherwise returns 0
long divide(const ZZ_pX& a, const ZZ_pX& b);
// if b | a, sets q = a/b and returns 1; otherwise returns 0
/**************************************************************************\
GCD's
These routines are intended for use when p is prime.
\**************************************************************************/
void GCD(ZZ_pX& x, const ZZ_pX& a, const ZZ_pX& b);
ZZ_pX GCD(const ZZ_pX& a, const ZZ_pX& b);
// x = GCD(a, b), x is always monic (or zero if a==b==0).
void XGCD(ZZ_pX& d, ZZ_pX& s, ZZ_pX& t, const ZZ_pX& a, const ZZ_pX& b);
// d = gcd(a,b), a s + b t = d
// NOTE: A classical algorithm is used, switching over to a
// "half-GCD" algorithm for large degree
/**************************************************************************\
Input/Output
I/O format:
[a_0 a_1 ... a_n],
represents the polynomial a_0 + a_1*X + ... + a_n*X^n.
On output, all coefficients will be integers between 0 and p-1, and
a_n not zero (the zero polynomial is [ ]). On input, the coefficients
are arbitrary integers which are reduced modulo p, and leading zeros
stripped.
\**************************************************************************/
istream& operator>>(istream& s, ZZ_pX& x);
ostream& operator<<(ostream& s, const ZZ_pX& a);
/**************************************************************************\
Some utility routines
\**************************************************************************/
long deg(const ZZ_pX& a); // return deg(a); deg(0) == -1.
const ZZ_p& coeff(const ZZ_pX& a, long i);
// returns a read-only reference to the coefficient of X^i, or zero if
// i not in range
const ZZ_p& LeadCoeff(const ZZ_pX& a);
// read-only reference to leading term of a, or zero if a == 0
const ZZ_p& ConstTerm(const ZZ_pX& a);
// read-only reference to constant term of a, or zero if a == 0
void SetCoeff(ZZ_pX& x, long i, const ZZ_p& a);
void SetCoeff(ZZ_pX& x, long i, long a);
// makes coefficient of X^i equal to a; error is raised if i < 0
void SetCoeff(ZZ_pX& x, long i);
// makes coefficient of X^i equal to 1; error is raised if i < 0
void SetX(ZZ_pX& x); // x is set to the monomial X
long IsX(const ZZ_pX& a); // test if x = X
void diff(ZZ_pX& x, const ZZ_pX& a); // x = derivative of a
ZZ_pX diff(const ZZ_pX& a);
void MakeMonic(ZZ_pX& x);
// if x != 0 makes x into its monic associate; LeadCoeff(x) must be
// invertible in this case.
void reverse(ZZ_pX& x, const ZZ_pX& a, long hi);
ZZ_pX reverse(const ZZ_pX& a, long hi);
void reverse(ZZ_pX& x, const ZZ_pX& a);
ZZ_pX reverse(const ZZ_pX& a);
// x = reverse of a[0]..a[hi] (hi >= -1);
// hi defaults to deg(a) in second version
void VectorCopy(vec_ZZ_p& x, const ZZ_pX& a, long n);
vec_ZZ_p VectorCopy(const ZZ_pX& a, long n);
// x = copy of coefficient vector of a of length exactly n.
// input is truncated or padded with zeroes as appropriate.
/**************************************************************************\
Random Polynomials
\**************************************************************************/
void random(ZZ_pX& x, long n);
ZZ_pX random_ZZ_pX(long n);
// generate a random polynomial of degree < n
/**************************************************************************\
Polynomial Evaluation and related problems
\**************************************************************************/
void BuildFromRoots(ZZ_pX& x, const vec_ZZ_p& a);
ZZ_pX BuildFromRoots(const vec_ZZ_p& a);
// computes the polynomial (X-a[0]) ... (X-a[n-1]), where n = a.length()
void eval(ZZ_p& b, const ZZ_pX& f, const ZZ_p& a);
ZZ_p eval(const ZZ_pX& f, const ZZ_p& a);
// b = f(a)
void eval(vec_ZZ_p& b, const ZZ_pX& f, const vec_ZZ_p& a);
vec_ZZ_p eval(const ZZ_pX& f, const vec_ZZ_p& a);
// b.SetLength(a.length()). b[i] = f(a[i]) for 0 <= i < a.length()
void interpolate(ZZ_pX& f, const vec_ZZ_p& a, const vec_ZZ_p& b);
ZZ_pX interpolate(const vec_ZZ_p& a, const vec_ZZ_p& b);
// interpolates the polynomial f satisfying f(a[i]) = b[i]. p should
// be prime.
/**************************************************************************\
Arithmetic mod X^n
All routines require n >= 0, otherwise an error is raised.
\**************************************************************************/
void trunc(ZZ_pX& x, const ZZ_pX& a, long n); // x = a % X^n
ZZ_pX trunc(const ZZ_pX& a, long n);
void MulTrunc(ZZ_pX& x, const ZZ_pX& a, const ZZ_pX& b, long n);
ZZ_pX MulTrunc(const ZZ_pX& a, const ZZ_pX& b, long n);
// x = a * b % X^n
void SqrTrunc(ZZ_pX& x, const ZZ_pX& a, long n);
ZZ_pX SqrTrunc(const ZZ_pX& a, long n);
// x = a^2 % X^n
void InvTrunc(ZZ_pX& x, const ZZ_pX& a, long n);
ZZ_pX InvTrunc(const ZZ_pX& a, long n);
// computes x = a^{-1} % X^m. Must have ConstTerm(a) invertible.
/**************************************************************************\
Modular Arithmetic (without pre-conditioning)
Arithmetic mod f.
All inputs and outputs are polynomials of degree less than deg(f), and
deg(f) > 0.
NOTE: if you want to do many computations with a fixed f, use the
ZZ_pXModulus data structure and associated routines below for better
performance.
\**************************************************************************/
void MulMod(ZZ_pX& x, const ZZ_pX& a, const ZZ_pX& b, const ZZ_pX& f);
ZZ_pX MulMod(const ZZ_pX& a, const ZZ_pX& b, const ZZ_pX& f);
// x = (a * b) % f
void SqrMod(ZZ_pX& x, const ZZ_pX& a, const ZZ_pX& f);
ZZ_pX SqrMod(const ZZ_pX& a, const ZZ_pX& f);
// x = a^2 % f
void MulByXMod(ZZ_pX& x, const ZZ_pX& a, const ZZ_pX& f);
ZZ_pX MulByXMod(const ZZ_pX& a, const ZZ_pX& f);
// x = (a * X) mod f
void InvMod(ZZ_pX& x, const ZZ_pX& a, const ZZ_pX& f);
ZZ_pX InvMod(const ZZ_pX& a, const ZZ_pX& f);
// x = a^{-1} % f, error is a is not invertible
long InvModStatus(ZZ_pX& x, const ZZ_pX& a, const ZZ_pX& f);
// if (a, f) = 1, returns 0 and sets x = a^{-1} % f; otherwise,
// returns 1 and sets x = (a, f)
// for modular exponentiation, see below
/**************************************************************************\
Modular Arithmetic with Pre-Conditioning
If you need to do a lot of arithmetic modulo a fixed f, build a
ZZ_pXModulus F for f. This pre-computes information about f that
speeds up subsequent computations.
It is required that deg(f) > 0 and that LeadCoeff(f) is invertible.
As an example, the following routine computes the product modulo f of a vector
of polynomials.
#include <NTL/ZZ_pX.h>
void product(ZZ_pX& x, const vec_ZZ_pX& v, const ZZ_pX& f)
{
ZZ_pXModulus F(f);
ZZ_pX res;
res = 1;
long i;
for (i = 0; i < v.length(); i++)
MulMod(res, res, v[i], F);
x = res;
}
Note that automatic conversions are provided so that a ZZ_pX can
be used wherever a ZZ_pXModulus is required, and a ZZ_pXModulus
can be used wherever a ZZ_pX is required.
\**************************************************************************/
class ZZ_pXModulus {
public:
ZZ_pXModulus(); // initially in an unusable state
ZZ_pXModulus(const ZZ_pXModulus&); // copy
ZZ_pXModulus& operator=(const ZZ_pXModulus&); // assignment
~ZZ_pXModulus();
ZZ_pXModulus(const ZZ_pX& f); // initialize with f, deg(f) > 0
operator const ZZ_pX& () const;
// read-only access to f, implicit conversion operator
const ZZ_pX& val() const;
// read-only access to f, explicit notation
};
void build(ZZ_pXModulus& F, const ZZ_pX& f);
// pre-computes information about f and stores it in F.
// Note that the declaration ZZ_pXModulus F(f) is equivalent to
// ZZ_pXModulus F; build(F, f).
// In the following, f refers to the polynomial f supplied to the
// build routine, and n = deg(f).
long deg(const ZZ_pXModulus& F); // return n=deg(f)
void MulMod(ZZ_pX& x, const ZZ_pX& a, const ZZ_pX& b, const ZZ_pXModulus& F);
ZZ_pX MulMod(const ZZ_pX& a, const ZZ_pX& b, const ZZ_pXModulus& F);
// x = (a * b) % f; deg(a), deg(b) < n
void SqrMod(ZZ_pX& x, const ZZ_pX& a, const ZZ_pXModulus& F);
ZZ_pX SqrMod(const ZZ_pX& a, const ZZ_pXModulus& F);
// x = a^2 % f; deg(a) < n
void PowerMod(ZZ_pX& x, const ZZ_pX& a, const ZZ& e, const ZZ_pXModulus& F);
ZZ_pX PowerMod(const ZZ_pX& a, const ZZ& e, const ZZ_pXModulus& F);
void PowerMod(ZZ_pX& x, const ZZ_pX& a, long e, const ZZ_pXModulus& F);
ZZ_pX PowerMod(const ZZ_pX& a, long e, const ZZ_pXModulus& F);
// x = a^e % f; deg(a) < n (e may be negative)
void PowerXMod(ZZ_pX& x, const ZZ& e, const ZZ_pXModulus& F);
ZZ_pX PowerXMod(const ZZ& e, const ZZ_pXModulus& F);
void PowerXMod(ZZ_pX& x, long e, const ZZ_pXModulus& F);
ZZ_pX PowerXMod(long e, const ZZ_pXModulus& F);
// x = X^e % f (e may be negative)
void PowerXPlusAMod(ZZ_pX& x, const ZZ_p& a, const ZZ& e,
const ZZ_pXModulus& F);
ZZ_pX PowerXPlusAMod(const ZZ_p& a, const ZZ& e,
const ZZ_pXModulus& F);
void PowerXPlusAMod(ZZ_pX& x, const ZZ_p& a, long e,
const ZZ_pXModulus& F);
ZZ_pX PowerXPlusAMod(const ZZ_p& a, long e,
const ZZ_pXModulus& F);
// x = (X + a)^e % f (e may be negative)
void rem(ZZ_pX& x, const ZZ_pX& a, const ZZ_pXModulus& F);
// x = a % f
void DivRem(ZZ_pX& q, ZZ_pX& r, const ZZ_pX& a, const ZZ_pXModulus& F);
// q = a/f, r = a%f
void div(ZZ_pX& q, const ZZ_pX& a, const ZZ_pXModulus& F);
// q = a/f
// operator notation:
ZZ_pX operator/(const ZZ_pX& a, const ZZ_pXModulus& F);
ZZ_pX operator%(const ZZ_pX& a, const ZZ_pXModulus& F);
ZZ_pX& operator/=(ZZ_pX& x, const ZZ_pXModulus& F);
ZZ_pX& operator%=(ZZ_pX& x, const ZZ_pXModulus& F);
/**************************************************************************\
More Pre-Conditioning
If you need to compute a * b % f for a fixed b, but for many a's, it
is much more efficient to first build a ZZ_pXMultiplier B for b, and
then use the MulMod routine below.
Here is an example that multiplies each element of a vector by a fixed
polynomial modulo f.
#include <NTL/ZZ_pX.h>
void mul(vec_ZZ_pX& v, const ZZ_pX& b, const ZZ_pX& f)
{
ZZ_pXModulus F(f);
ZZ_pXMultiplier B(b, F);
long i;
for (i = 0; i < v.length(); i++)
MulMod(v[i], v[i], B, F);
}
\**************************************************************************/
class ZZ_pXMultiplier {
public:
ZZ_pXMultiplier(); // initially zero
ZZ_pXMultiplier(const ZZ_pX& b, const ZZ_pXModulus& F);
// initializes with b mod F, where deg(b) < deg(F)
ZZ_pXMultiplier(const ZZ_pXMultiplier&); // copy
ZZ_pXMultiplier& operator=(const ZZ_pXMultiplier&); // assignment
~ZZ_pXMultiplier();
const ZZ_pX& val() const; // read-only access to b
};
void build(ZZ_pXMultiplier& B, const ZZ_pX& b, const ZZ_pXModulus& F);
// pre-computes information about b and stores it in B; deg(b) <
// deg(F)
void MulMod(ZZ_pX& x, const ZZ_pX& a, const ZZ_pXMultiplier& B,
const ZZ_pXModulus& F);
// x = (a * b) % F; deg(a) < deg(F)
/**************************************************************************\
vectors of ZZ_pX's
\**************************************************************************/
NTL_vector_decl(ZZ_pX,vec_ZZ_pX)
// vec_ZZ_pX
NTL_eq_vector_decl(ZZ_pX,vec_ZZ_pX)
// == and !=
NTL_io_vector_decl(ZZ_pX,vec_ZZ_pX)
// I/O operators
/**************************************************************************\
Modular Composition
Modular composition is the problem of computing g(h) mod f for
polynomials f, g, and h.
The algorithm employed is that of Brent & Kung (Fast algorithms for
manipulating formal power series, JACM 25:581-595, 1978), which uses
O(n^{1/2}) modular polynomial multiplications, and O(n^2) scalar
operations.
\**************************************************************************/
void CompMod(ZZ_pX& x, const ZZ_pX& g, const ZZ_pX& h, const ZZ_pXModulus& F);
ZZ_pX CompMod(const ZZ_pX& g, const ZZ_pX& h,
const ZZ_pXModulus& F);
// x = g(h) mod f; deg(h) < n
void Comp2Mod(ZZ_pX& x1, ZZ_pX& x2, const ZZ_pX& g1, const ZZ_pX& g2,
const ZZ_pX& h, const ZZ_pXModulus& F);
// xi = gi(h) mod f (i=1,2); deg(h) < n.
void Comp3Mod(ZZ_pX& x1, ZZ_pX& x2, ZZ_pX& x3,
const ZZ_pX& g1, const ZZ_pX& g2, const ZZ_pX& g3,
const ZZ_pX& h, const ZZ_pXModulus& F);
// xi = gi(h) mod f (i=1..3); deg(h) < n.
/**************************************************************************\
Composition with Pre-Conditioning
If a single h is going to be used with many g's then you should build
a ZZ_pXArgument for h, and then use the compose routine below. The
routine build computes and stores h, h^2, ..., h^m mod f. After this
pre-computation, composing a polynomial of degree roughly n with h
takes n/m multiplies mod f, plus n^2 scalar multiplies. Thus,
increasing m increases the space requirement and the pre-computation
time, but reduces the composition time.
\**************************************************************************/
struct ZZ_pXArgument {
vec_ZZ_pX H;
};
void build(ZZ_pXArgument& H, const ZZ_pX& h, const ZZ_pXModulus& F, long m);
// Pre-Computes information about h. m > 0, deg(h) < n.
void CompMod(ZZ_pX& x, const ZZ_pX& g, const ZZ_pXArgument& H,
const ZZ_pXModulus& F);
ZZ_pX CompMod(const ZZ_pX& g, const ZZ_pXArgument& H,
const ZZ_pXModulus& F);
extern long ZZ_pXArgBound;
// Initially 0. If this is set to a value greater than zero, then
// composition routines will allocate a table of no than about
// ZZ_pXArgBound KB. Setting this value affects all compose routines
// and the power projection and minimal polynomial routines below,
// and indirectly affects many routines in ZZ_pXFactoring.
/**************************************************************************\
power projection routines
\**************************************************************************/
void project(ZZ_p& x, const ZZ_pVector& a, const ZZ_pX& b);
ZZ_p project(const ZZ_pVector& a, const ZZ_pX& b);
// x = inner product of a with coefficient vector of b
void ProjectPowers(vec_ZZ_p& x, const vec_ZZ_p& a, long k,
const ZZ_pX& h, const ZZ_pXModulus& F);
vec_ZZ_p ProjectPowers(const vec_ZZ_p& a, long k,
const ZZ_pX& h, const ZZ_pXModulus& F);
// Computes the vector
// project(a, 1), project(a, h), ..., project(a, h^{k-1} % f).
// This operation is the "transpose" of the modular composition operation.
void ProjectPowers(vec_ZZ_p& x, const vec_ZZ_p& a, long k,
const ZZ_pXArgument& H, const ZZ_pXModulus& F);
vec_ZZ_p ProjectPowers(const vec_ZZ_p& a, long k,
const ZZ_pXArgument& H, const ZZ_pXModulus& F);
// same as above, but uses a pre-computed ZZ_pXArgument
void UpdateMap(vec_ZZ_p& x, const vec_ZZ_p& a,
const ZZ_pXMultiplier& B, const ZZ_pXModulus& F);
vec_ZZ_p UpdateMap(const vec_ZZ_p& a,
const ZZ_pXMultiplier& B, const ZZ_pXModulus& F);
// Computes the vector
// project(a, b), project(a, (b*X)%f), ..., project(a, (b*X^{n-1})%f)
// Restriction: must have a.length() <= deg(F).
// This is "transposed" MulMod by B.
// Input may have "high order" zeroes stripped.
// Output will always have high order zeroes stripped.
/**************************************************************************\
Minimum Polynomials
These routines should be used with prime p.
All of these routines implement the algorithm from [Shoup, J. Symbolic
Comp. 17:371-391, 1994] and [Shoup, J. Symbolic Comp. 20:363-397,
1995], based on transposed modular composition and the
Berlekamp/Massey algorithm.
\**************************************************************************/
void MinPolySeq(ZZ_pX& h, const vec_ZZ_p& a, long m);
ZZ_pX MinPolySeq(const vec_ZZ_p& a, long m);
// computes the minimum polynomial of a linealy generated sequence; m
// is a bound on the degree of the polynomial; required: a.length() >=
// 2*m
void ProbMinPolyMod(ZZ_pX& h, const ZZ_pX& g, const ZZ_pXModulus& F, long m);
ZZ_pX ProbMinPolyMod(const ZZ_pX& g, const ZZ_pXModulus& F, long m);
void ProbMinPolyMod(ZZ_pX& h, const ZZ_pX& g, const ZZ_pXModulus& F);
ZZ_pX ProbMinPolyMod(const ZZ_pX& g, const ZZ_pXModulus& F);
// computes the monic minimal polynomial if (g mod f). m = a bound on
// the degree of the minimal polynomial; in the second version, this
// argument defaults to n. The algorithm is probabilistic, always
// returns a divisor of the minimal polynomial, and returns a proper
// divisor with probability at most m/p.
void MinPolyMod(ZZ_pX& h, const ZZ_pX& g, const ZZ_pXModulus& F, long m);
ZZ_pX MinPolyMod(const ZZ_pX& g, const ZZ_pXModulus& F, long m);
void MinPolyMod(ZZ_pX& h, const ZZ_pX& g, const ZZ_pXModulus& F);
ZZ_pX MinPolyMod(const ZZ_pX& g, const ZZ_pXModulus& F);
// same as above, but guarantees that result is correct
void IrredPolyMod(ZZ_pX& h, const ZZ_pX& g, const ZZ_pXModulus& F, long m);
ZZ_pX IrredPolyMod(const ZZ_pX& g, const ZZ_pXModulus& F, long m);
void IrredPolyMod(ZZ_pX& h, const ZZ_pX& g, const ZZ_pXModulus& F);
ZZ_pX IrredPolyMod(const ZZ_pX& g, const ZZ_pXModulus& F);
// same as above, but assumes that f is irreducible, or at least that
// the minimal poly of g is itself irreducible. The algorithm is
// deterministic (and is always correct).
/**************************************************************************\
Traces, norms, resultants
These routines should be used with prime p.
\**************************************************************************/
void TraceMod(ZZ_p& x, const ZZ_pX& a, const ZZ_pXModulus& F);
ZZ_p TraceMod(const ZZ_pX& a, const ZZ_pXModulus& F);
void TraceMod(ZZ_p& x, const ZZ_pX& a, const ZZ_pX& f);
ZZ_p TraceMod(const ZZ_pX& a, const ZZ_pXModulus& f);
// x = Trace(a mod f); deg(a) < deg(f)
void TraceVec(vec_ZZ_p& S, const ZZ_pX& f);
vec_ZZ_p TraceVec(const ZZ_pX& f);
// S[i] = Trace(X^i mod f), i = 0..deg(f)-1; 0 < deg(f)
// The above trace routines implement the asymptotically fast trace
// algorithm from [von zur Gathen and Shoup, Computational Complexity,
// 1992].
void NormMod(ZZ_p& x, const ZZ_pX& a, const ZZ_pX& f);
ZZ_p NormMod(const ZZ_pX& a, const ZZ_pX& f);
// x = Norm(a mod f); 0 < deg(f), deg(a) < deg(f)
void resultant(ZZ_p& x, const ZZ_pX& a, const ZZ_pX& b);
ZZ_p resultant(const ZZ_pX& a, const ZZ_pX& b);
// x = resultant(a, b)
void CharPolyMod(ZZ_pX& g, const ZZ_pX& a, const ZZ_pX& f);
ZZ_pX CharPolyMod(const ZZ_pX& a, const ZZ_pX& f);
// g = charcteristic polynomial of (a mod f); 0 < deg(f), deg(g) <
// deg(f); this routine works for arbitrary f; if f is irreducible,
// it is faster to use the IrredPolyMod routine, and then exponentiate
// if necessary (since in this case the CharPoly is just a power of
// the IrredPoly).
/**************************************************************************\
Miscellany
A ZZ_pX f is represented as a vec_ZZ_p, which can be accessed as
f.rep. The constant term is f.rep[0] and the leading coefficient is
f.rep[f.rep.length()-1], except if f is zero, in which case
f.rep.length() == 0. Note that the leading coefficient is always
nonzero (unless f is zero). One can freely access and modify f.rep,
but one should always ensure that the leading coefficient is nonzero,
which can be done by invoking f.normalize().
\**************************************************************************/
void clear(ZZ_pX& x) // x = 0
void set(ZZ_pX& x); // x = 1
void ZZ_pX::normalize();
// f.normalize() strips leading zeros from f.rep.
void ZZ_pX::SetMaxLength(long n);
// f.SetMaxLength(n) pre-allocate spaces for n coefficients. The
// polynomial that f represents is unchanged.
void ZZ_pX::kill();
// f.kill() sets f to 0 and frees all memory held by f; Equivalent to
// f.rep.kill().
ZZ_pX::ZZ_pX(INIT_SIZE_TYPE, long n);
// ZZ_pX(INIT_SIZE, n) initializes to zero, but space is pre-allocated
// for n coefficients
static const ZZ_pX& ZZ_pX::zero();
// ZZ_pX::zero() is a read-only reference to 0
void swap(ZZ_pX& x, ZZ_pX& y);
// swap x and y (via "pointer swapping")
distrib
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Mandriva
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2010.0
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i586
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media
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contrib-release
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by-pkgid
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