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[Faustine.git] / interpretor / preprocessor / faust-0.9.47mr3 / compiler / normalize / aterm.cpp

#include "aterm.hh"
#include "ppsig.hh"
//static void collectMulTerms (Tree& coef, map<Tree,int>& M, Tree t, bool invflag=false);

#undef TRACE

using namespace std;

typedef map<Tree,mterm> SM;

aterm::aterm ()            
{}


/**
 * create a aterm from a tree expression
 */
aterm::aterm (Tree t)
{
        #ifdef TRACE
        cerr << "aterm::aterm (" << ppsig(t)<< ")" << endl;
        #endif
        *this += t;
        #ifdef TRACE
    cerr << "aterm::aterm (" << ppsig(t)<< ") : -> " << *this << endl;
        #endif
}
        

/**
 * Add two terms trying to simplify the result 
 */
static Tree simplifyingAdd(Tree t1, Tree t2)
{
        assert(t1!=0);
        assert(t2!=0);

        if (isNum(t1) && isNum(t2)) {
                return addNums(t1,t2);

        } else if (isZero(t1)) {
                return t2;

        } else if (isZero(t2)) {
                return t1;

        } else if (t1 <= t2) {
                return sigAdd(t1, t2);

        } else {
                return sigAdd(t2, t1);
        }
}

/**
 * return the corresponding normalized expression tree
 */

Tree aterm::normalizedTree() const
{
        // store positive and negative tems by order and sign
        // positive terms are stored in P[]
        // negative terms are inverted (made positive) and stored in N[]
        Tree P[4], N[4];
        
        // prepare
        for (int order = 0; order < 4; order++)         P[order] = N[order] = tree(0);
        
        // sum by order and sign
        for (SM::const_iterator p = fSig2MTerms.begin(); p != fSig2MTerms.end(); p++) {
                const mterm& m = p->second;     
                if (m.isNegative()) {
                        Tree t = m.normalizedTree(false, true);
                        int order = getSigOrder(t);
                        N[order] = simplifyingAdd(N[order],t);
                } else {
                        Tree t = m.normalizedTree();
                        int order = getSigOrder(t);
                        P[order] = simplifyingAdd(P[order],t);
                }
        }
        
        // combine sums
        Tree SUM = tree(0);
        for (int order = 0; order < 4; order++) {
                if (!isZero(P[order]))  {
                        SUM = simplifyingAdd(SUM,P[order]);
                }
                if (!isZero(N[order]))  {       // we have to substract
                        if (isZero(SUM) && (order < 3)) {
                                // we postpone substraction
                                N[order+1] = simplifyingAdd(N[order], N[order+1]);
                        } else {
                                SUM = sigSub(SUM, N[order]);
                        }
                }
        }
        
        assert(SUM);
        return SUM;
}
        

/**
 * print an aterm in a human readable format
 */
ostream& aterm::print(ostream& dst) const
{
    if (fSig2MTerms.empty()) {
        dst << "AZERO";
    } else {
        const char* sep = "";
        for (SM::const_iterator p = fSig2MTerms.begin(); p != fSig2MTerms.end(); p++) {
                dst << sep << p->second;
                sep = " + ";
        }
    }
 
        return dst;
}


/**
 * Add in place an additive expression tree Go down t recursively looking 
 * for additions and substractions
 */
const aterm& aterm::operator += (Tree t)
{
        int             op;
        Tree    x,y;

        assert(t!=0);

        if (isSigBinOp(t, &op, x, y) && (op == kAdd)) {
                *this += x;
                *this += y;

        } else if (isSigBinOp(t, &op, x, y) && (op == kSub)) {
                *this += x;
                *this -= y;

        } else {
                mterm m(t);
                *this += m;
        }
    return *this;
}


/**
 * Substract in place an additive expression tree Go down t recursively looking 
 * for additions and substractions
 */
const aterm& aterm::operator -= (Tree t)
{
        int             op;
        Tree    x,y;

        assert(t!=0);

        if (isSigBinOp(t, &op, x, y) && (op == kAdd)) {
                *this -= x;
                *this -= y;

        } else if (isSigBinOp(t, &op, x, y) && (op == kSub)) {
                *this -= x;
                *this += y;

        } else {
                mterm m(t);
                *this -= m;
        }
    return *this;
}


/**
 * Add in place an mterm
 */
const aterm& aterm::operator += (const mterm& m)
{
        #ifdef TRACE
    cerr << *this << " aterm::+= " << m << endl;
        #endif
        Tree sig = m.signatureTree();
        #ifdef TRACE
    cerr << "signature " << *sig << endl;
        #endif
        SM::const_iterator p = fSig2MTerms.find(sig);
        if (p == fSig2MTerms.end()) {
                // its a new mterm
                fSig2MTerms.insert(make_pair(sig,m));
        } else {
                fSig2MTerms[sig] += m;
        }
        return *this;
}


/**
 * Substract in place an mterm
 */
const aterm& aterm::operator -= (const mterm& m)
{
    //cerr << *this << " aterm::-= " << m << endl;
        Tree sig = m.signatureTree();
    //cerr << "signature " << *sig << endl;
        SM::const_iterator p = fSig2MTerms.find(sig);
        if (p == fSig2MTerms.end()) {
                // its a new mterm
                fSig2MTerms.insert(make_pair(sig,m*mterm(-1)));
        } else {
                fSig2MTerms[sig] -= m;
        }
        return *this;
}
        
mterm aterm::greatestDivisor() const
{
        int maxComplexity = 0;
        mterm maxGCD(1);
        
        for (SM::const_iterator p1 = fSig2MTerms.begin(); p1 != fSig2MTerms.end(); p1++) {
                for (SM::const_iterator p2 = p1; p2 != fSig2MTerms.end(); p2++) {
                        if (p2 != p1) {
                                mterm g = gcd(p1->second,p2->second);
                                if (g.complexity()>maxComplexity) {
                                        maxComplexity = g.complexity();
                                        maxGCD = g;
                                }
                        }
                }
        }
        //cerr << "greatestDivisor of " << *this << " is " << maxGCD << endl;
        return maxGCD;
}

/**
 * reorganize the aterm by factorizing d
 */
aterm aterm::factorize(const mterm& d)
{
        //cerr << "factorize : " << *this << " with " << d << endl;
        aterm A;
        aterm Q;
        
        // separate the multiple of m from the others
        for (SM::const_iterator p1 = fSig2MTerms.begin(); p1 != fSig2MTerms.end(); p1++) {
                mterm t = p1->second;
                if (t.hasDivisor(d)) {
                        mterm q = t/d;
                        //cerr << "q = " << q << endl;
                        Q += q;
                        //cerr << "step Q = " << Q << endl;
                } else {
                        A += t;
                        //cerr << "step A = " << A << endl;
                }
        }
        
        // combines the two parts
        //cerr << "d.normalizedTree() " << ppsig(d.normalizedTree()) << endl;
        //cerr << "Q.normalizedTree() " << ppsig(Q.normalizedTree()) << endl;
        //Tree tt = sigMul(d.normalizedTree(), Q.normalizedTree());
        //cerr << "tt " << *tt << endl;
        
        //Tree ttt = sigAdd(
        A += sigMul(d.normalizedTree(), Q.normalizedTree());
        //cerr << "Final A = " << A << endl;
        //cerr << "Final Tree " << *(A.normalizedTree()) << endl;
        return A;
}