Example #1
0
// find the suffix array SA of s[0..n-1] in {1..K}^n
// require s[n]=s[n+1]=s[n+2]=0, n>=2
void suffixArray(int* s, int* SA, uint32_t n, uint32_t K) {
  uint32_t n0=(n+2)/3, n1=(n+1)/3, n2=n/3, n02=n0+n2;
  int* s12  = new int[n02 + 3];  s12[n02]= s12[n02+1]= s12[n02+2]=0;
  int* SA12 = new int[n02 + 3]; SA12[n02]=SA12[n02+1]=SA12[n02+2]=0;
  int* s0   = new int[n0];
  int* SA0  = new int[n0];

  // generate positions of mod 1 and mod  2 suffixes
  // the "+(n0-n1)" adds a dummy mod 1 suffix if n%3 == 1
  for (uint32_t i=0, j=0;  i < n+(n0-n1);  i++) if (i%3 != 0) s12[j++] = i;

  // lsb radix sort the mod 1 and mod 2 triples
  radixPass(s12 , SA12, s+2, n02, K);
  radixPass(SA12, s12 , s+1, n02, K);
  radixPass(s12 , SA12, s  , n02, K);

  // find lexicographic names of triples
  int name = 0, c0 = -1, c1 = -1, c2 = -1;
  for (uint32_t i = 0;  i < n02;  i++) {
    if (s[SA12[i]] != c0 || s[SA12[i]+1] != c1 || s[SA12[i]+2] != c2) {
      name++;  c0 = s[SA12[i]];  c1 = s[SA12[i]+1];  c2 = s[SA12[i]+2];
    }
    if (SA12[i] % 3 == 1) { s12[SA12[i]/3]      = name; } // left half
    else                  { s12[SA12[i]/3 + n0] = name; } // right half
  }

  // recurse if names are not yet unique
  if (name < n02) {
    suffixArray(s12, SA12, n02, name);
    // store unique names in s12 using the suffix array
    for (uint32_t i = 0;  i < n02;  i++) s12[SA12[i]] = i + 1;
  } else // generate the suffix array of s12 directly
    for (uint32_t i = 0;  i < n02;  i++) SA12[s12[i] - 1] = i;

  // stably sort the mod 0 suffixes from SA12 by their first character
  for (uint32_t i=0, j=0;  i < n02;  i++) if (SA12[i] < n0) s0[j++] = 3*SA12[i];
  radixPass(s0, SA0, s, n0, K);

  // merge sorted SA0 suffixes and sorted SA12 suffixes
  for (uint32_t p=0,  t=n0-n1,  k=0;  k < n;  k++) {
#define GetI() (SA12[t] < n0 ? SA12[t] * 3 + 1 : (SA12[t] - n0) * 3 + 2)
    int i = GetI(); // pos of current offset 12 suffix
    int j = SA0[p]; // pos of current offset 0  suffix
    if (SA12[t] < n0 ?
        leq(s[i],       s12[SA12[t] + n0], s[j],       s12[j/3]) :
        leq(s[i],s[i+1],s12[SA12[t]-n0+1], s[j],s[j+1],s12[j/3+n0]))
    { // suffix from SA12 is smaller
      SA[k] = i;  t++;
      if (t == n02) { // done --- only SA0 suffixes left
        for (k++;  p < n0;  p++, k++) SA[k] = SA0[p];
      }
    } else {
      SA[k] = j;  p++;
      if (p == n0)  { // done --- only SA12 suffixes left
        for (k++;  t < n02;  t++, k++) SA[k] = GetI();
      }
    }
  }
  delete [] s12; delete [] SA12; delete [] SA0; delete [] s0;
}
	void suffixArray(VI &T, VI &SA, int n, int K) {
		int n0 = (n + 2) / 3, n1 = (n + 1) / 3, n2 = n / 3, n02 = n0 + n2;
		VI R(n02+3), SA12(n02+3), R0(n0), SA0(n0);
		for (int i = 0, j = 0; i < n + (n0 - n1); i++)
			if (i % 3 != 0)
				R[j++] = i;
		radixPass(R, SA12, T.begin() + 2, n02, K);
		radixPass(SA12, R, T.begin() + 1, n02, K);
		radixPass(R, SA12, T.begin(), n02, K);
		int name = 0, c0 = -1, c1 = -1, c2 = -1;
		for (int i = 0; i < n02; i++) {
			if (T[SA12[i]] != c0 || T[SA12[i] + 1] != c1 || T[SA12[i] + 2] != c2) {
				name++;
				c0 = T[SA12[i]];
				c1 = T[SA12[i] + 1];
				c2 = T[SA12[i] + 2];
			}
			if (SA12[i] % 3 == 1) {
				R[SA12[i] / 3] = name;
			}
			else {
				R[SA12[i] / 3 + n0] = name;
			}
		}
		if (name < n02) {
			suffixArray(R, SA12, n02, name);
			for (int i = 0; i < n02; i++)
				R[SA12[i]] = i + 1;
		} else
			for (int i = 0; i < n02; i++)
				SA12[R[i] - 1] = i;
		for (int i = 0, j = 0; i < n02; i++)
			if (SA12[i] < n0)
				R0[j++] = 3 * SA12[i];
		radixPass(R0, SA0, T.begin(), n0, K);
		for (int p = 0, t = n0 - n1, k = 0; k < n; k++) {
#define GetI() (SA12[t] < n0 ? SA12[t] * 3 + 1 : (SA12[t] - n0) * 3 + 2)
			int i = GetI(); // pos of current offset 12 suffix
			int j = SA0[p]; // pos of current offset 0 suffix
			if (SA12[t] < n0 ? // different compares for mod 1 and mod 2 suffixes
				leq(T[i], R[SA12[t] + n0], T[j], R[j / 3]) :
				leq(T[i], T[i + 1], R[SA12[t] - n0 + 1], T[j], T[j + 1], R[j / 3 + n0])) { // suffix from SA12 is smaller
				SA[k] = i;
				t++;
				if (t == n02) // done --- only SA0 suffixes left
					for (k++; p < n0; p++, k++)
						SA[k] = SA0[p];
			} else { // suffix from SA0 is smaller
				SA[k] = j;
				p++;
				if (p == n0) // done --- only SA12 suffixes left
					for (k++; t < n02; t++, k++)
						SA[k] = GetI();
			}
		}
	}
    static void increment(pointer& x,pointer bbegin,pointer bbend)
    {
        std::less_equal<pointer> leq;

        x=x->next();
        if(leq(bbegin,x)&&leq(x,bbend)) { /* bucket node */
            do {
                ++x;
            } while(x->next()==x);
            x=x->next();
        }
    }
Example #4
0
  static void increment(
    hashed_index_node_impl*& x,
    hashed_index_node_impl* bbegin,hashed_index_node_impl* bbend)
  {
    std::less_equal<hashed_index_node_impl*> leq;

    x=x->next();
    if(leq(bbegin,x)&&leq(x,bbend)){ /* bucket node */
      do{
        ++x;
      }while(x->next()==x);
      x=x->next();
    }
  }
Example #5
0
static void sift_down(struct heap *h, size_t i) {
    while( L(i) < h->n ) {
        size_t l = L(i);
        size_t r = R(i);
        size_t j = l;
        if( r < h->n && leq(h, r, l) ) {
            j = r;
        }
        if( leq(h, i, j) ) {
            break;
        }
        swap(h, i, j);
        i = j;
    }
}
int ChunkView::findWaypoint( const Vector3& inpt, float girth ) const
{
	static Vector3 lastPt( 0.f, 0.f, 0.f );
	static uint32 nextToSkip = 0;
	if (lastPt != inpt)	{ lastPt = inpt; nextToSkip = 0; }
	int toSkip = nextToSkip++;

	Vector2 pt(inpt.x, inpt.z);

	// do a brute force search for the polygon
	uint i, j;
	for (i = 0; i < polygons_.size(); i++)
	{
		const PolygonDef & p = polygons_[i];
		if (!p.vertices.size()) continue;
		if (!this->equivGirth( i, girth )) continue;

		Vector2 av, bv;
		bv = p.vertices.back().position;
		for (j = 0; j < p.vertices.size(); j++)
		{
			av = bv;
			bv = p.vertices[j].position;

			LineEq leq( av, bv );
			if (leq.isInFrontOf( pt )) break;
		}

		if (j == p.vertices.size() && toSkip--==0) return i;
	}

	nextToSkip = 0;
	return -1;
}
static int
callback (struct dl_phdr_info *info, size_t size, void *ptr)
{
  static int last_adds = 0, last_subs = 0;
  intptr_t cmd = (intptr_t) ptr;

  printf ("  size = %Zu\n", size);
  if (size < (offsetof (struct dl_phdr_info, dlpi_subs)
	      + sizeof (info->dlpi_subs)))
    {
      fprintf (stderr, "dl_iterate_phdr failed to pass dlpi_adds/dlpi_subs\n");
      exit (5);
    }

  printf ("  dlpi_adds = %Lu dlpi_subs = %Lu\n",
	  info->dlpi_adds, info->dlpi_subs);

  switch (cmd)
    {
    case SET:
      break;

    case ADD:
      if (leq (info->dlpi_adds, last_adds))
	{
	  fprintf (stderr, "dlpi_adds failed to get incremented!\n");
	  exit (3);
	}
      break;

    case REMOVE:
      if (leq (info->dlpi_subs, last_subs))
	{
	  fprintf (stderr, "dlpi_subs failed to get incremented!\n");
	  exit (4);
	}
      break;
    }
  last_adds = info->dlpi_adds;
  last_subs = info->dlpi_subs;
  return -1;
}
Example #8
0
// returns true if there is an intersection with the face, else returns false
int testLinePlaneIntersection(GLfloat* la, GLfloat* lb, GLfloat* p0, GLfloat* p1, GLfloat* p2)
{
	// returns true for indices where intersection occurs
	GLfloat a1=la[0]-lb[0], b1=la[1]-lb[1], c1=la[2]-lb[2];
	GLfloat a2=p1[0]-p0[0], b2=p1[1]-p0[1], c2=p1[2]-p0[2];
	GLfloat a3=p2[0]-p0[0], b3=p2[1]-p0[1], c3=p2[2]-p0[2];
	GLfloat l1=la[0]-p0[0], l2=la[1]-p0[1], l3=la[2]-p0[2];
	
	GLfloat denom=(a1*b2*c3 - a1*b3*c2 - a2*b1*c3 + a2*b3*c1 + a3*b1*c2 - a3*b2*c1);
	
	if (fabs(denom)<1e-6) return 0; 
	// if you can't find an intersection because there is no solution, return notFacesSeen=0 ==> you are never blocked
	
	GLfloat num1= (a2*b3*l3 - a3*b2*l3 - a2*c3*l2 + a3*c2*l2 + b2*c3*l1 - b3*c2*l1);
	GLfloat num2=-(a1*b3*l3 - a3*b1*l3 - a1*c3*l2 + a3*c1*l2 + b1*c3*l1 - b3*c1*l1);
	GLfloat num3= (a1*b2*l3 - a2*b1*l3 - a1*c2*l2 + a2*c1*l2 + b1*c2*l1 - b2*c1*l1);
	
	GLfloat t1=num1/denom, t2=num2/denom, t3=num3/denom;
	
	return geq(t1,0) & leq(t1,1) & geq(t2,0) & geq(t3,0) & leq(t3,1) & leq(t2,1) & leq(t2+t3,1);
}
Example #9
0
bool IndexedBestFSStateSet::add(State *state){
	// Ensure we're larger than any state in waiting. Pop any states smaller

	//std::cout<<"Checking waiting"<<std::endl;

	bool skipVisited = false;
	for(waitingIter it = _waiting.begin(); it != _waiting.end();){
		if(this->less(it.item(), state)){
			_waiting.remove(it++);
			this->_countRemove++;
			skipVisited = true;
		} else {
			if(this->leq(state, it.item()))
				return false;
			it++;
		}
	}

	//std::cout<<"Doing visited check"<<std::endl;

	// Perform visited check
	if(!skipVisited){
		int is = state->stateIndex(*_net);
		for(visitIter it = _visited.begin(); it != _visited.end();){
			int iv = it->first;

			if(is <= iv){
				// Check we are not smaller then existing states
				if(leq(state, it->second))
					return false;
			}
			it++;
		}
	}

	//std::cout<<"Doing heuristic distance"<<std::endl;

	// Calculate priority and add state
	PQL::DistanceContext context(*this->_net,
								 _distanceStrategy,
								 state->marking(),
								 state->intValuation(),
								 state->boolValuation(),
								 _dm);
	double d = _query->distance(context);

	//std::cout<<"Pushing state to waiting"<<std::endl;

	_waiting.push(d, state);
	return true;
}
Example #10
0
void suffix_array(int *s, int *SA, int n, int K, int level = 0) {
    int n0 = (n+2)/3, n1 = (n+1)/3, n2 = n/3, n02 = n0+n2; 
    int *s12 = pool[level][0], *SA12 = pool[level][1];
    int *s0 = pool[level][2], *SA0 = pool[level][3];
    s12[n02] = s12[n02+1] = s12[n02+2] = 0; SA12[n02] = SA12[n02+1] = SA12[n02+2] = 0;
    for (int i = 0, j = 0; i < n+(n0-n1); i++) { if (i % 3 != 0) { s12[j++] = i; } }
    radix(s12, SA12, s+2, n02, K);
    radix(SA12, s12, s+1, n02, K);
    radix(s12, SA12, s+0, n02, K);
    int name = 0, c0 = -1, c1 = -1, c2 = -1;
    for (int i = 0; i < n02; i++) {
        if (s[SA12[i]] != c0 || s[SA12[i]+1] != c1 || s[SA12[i]+2] != c2)
        { name++; c0 = s[SA12[i]]; c1 = s[SA12[i]+1]; c2 = s[SA12[i]+2]; }
        if (SA12[i] % 3 == 1) { s12[SA12[i]/3] = name; }
        else { s12[SA12[i]/3 + n0] = name; }
    }
    if (name < n02) {
        suffix_array(s12, SA12, n02, name, level+1);
        for (int i = 0; i < n02; i++) { s12[SA12[i]] = i + 1; }
    } else {
        for (int i = 0; i < n02; i++) { SA12[s12[i]-1] = i; }
    }
    for (int i = 0, j = 0; i < n02; i++) { if (SA12[i] < n0) { s0[j++] = 3*SA12[i]; } }
    radix(s0, SA0, s, n0, K);
    for (int p = 0, t = n0-n1, k = 0; k < n; k++) {
        int i = GetI(); int j = SA0[p];
        if (SA12[t] < n0 ? leq(s[i], s12[SA12[t] + n0], s[j], s12[j/3])
                : leq(s[i], s[i+1], s12[SA12[t]-n0+1], s[j], s[j+1], s12[j/3+n0])) {
            SA[k] = i; t++;
            if (t == n02) { for (k++; p < n0; p++, k++) { SA[k] = SA0[p]; } }
        } else { 
            SA[k] = j; p++; 
            if (p == n0) { for (k++; t < n02; t++, k++) { SA[k] = GetI(); } }
        }
    } 
}
// find the suffix array SA of T[0..n-1] in {1..K}^n
// require T[n] = T[n+1] = T[n+2] = 0, n >= 2
void suffixArray(int* T, int* SA, int n, int K) {
    int n0 = (n + 2) / 3, n1 = (n + 1) / 3, n2 = n / 3, n02 = n0 + n2;
    int* R = new int[n02 + 3];
    R[n02] = R[n02 + 1] = R[n02 + 2] = 0;
    int* SA12 = new int[n02 + 3]; SA12[n02] = SA12[n02 + 1] = SA12[n02 + 2] = 0;
    int* R0 = new int[n0];
    int* SA0 = new int[n0];

    //******* Step 0: Construct sample ********
    // generate positions of mod 1 and mod 2 suffixes
    // the "+(n0-n1)" adds a dummy mod 1 suffix if n%3 == 1
    for (int i = 0, j = 0; i < n + (n0 - n1); i++) if (i%3 != 0) R[j++] = i;

    //******* Step 1: Sort sample suffixes ********
    // lsb radix sort the mod 1 and mod 2 triples
    radixPass(R, SA12, T + 2, n02, K);
    radixPass(SA12, R, T + 1, n02, K);
    radixPass(R, SA12, T, n02, K);

    // find lexicographic names of triples and
    // write them to correct places in R
    int name = 0, c0 = -1, c1 = -1, c2 = -1;
    for (int i = 0; i < n02; i++) {
        if (T[SA12[i]] != c0 || T[SA12[i] + 1] != c1 || T[SA12[i] + 2] != c2) {
            name++;
            c0 = T[SA12[i]];
            c1 = T[SA12[i] + 1];
            c2 = T[SA12[i] + 2];
        }
        if (SA12[i] % 3 == 1) {
            R[SA12[i] / 3] = name; // write to R1
        } else {
            R[SA12[i] / 3 + n0] = name; // write to R2
        }
    }

    // recurse if names are not yet unique
    if (name < n02) {
        suffixArray(R, SA12, n02, name);
        // store unique names in R using the suffix array
        for (int i = 0; i < n02; i++) R[SA12[i]] = i + 1;
    } else // generate the suffix array of R directly
        for (int i = 0; i < n02; i++) SA12[R[i] - 1] = i;

    //******* Step 2: Sort nonsample suffixes ********
    // stably sort the mod 0 suffixes from SA12 by their first character
    for (int i = 0, j = 0; i < n02; i++) if (SA12[i] < n0) R0[j++] = 3 * SA12[i];
    radixPass(R0, SA0, T, n0, K);

    //******* Step 3: Merge ********
    // merge sorted SA0 suffixes and sorted SA12 suffixes
    for (int p = 0, t = n0 - n1, k = 0; k < n; k++) {
        #define GetI() (SA12[t] < n0 ? SA12[t] * 3 + 1 : (SA12[t] - n0) * 3 + 2)
        int i = GetI(); // pos of current offset 12 suffix
        int j = SA0[p]; // pos of current offset 0 suffix
        if (SA12[t] < n0 ? // different compares for mod 1 and mod 2 suffixes
        leq(T[i], R[SA12[t] + n0], T[j], R[j / 3]) :
        leq(T[i], T[i+1], R[SA12[t] - n0 + 1], T[j], T[j + 1], R[j / 3 + n0])) {
            // suffix from SA12 is smaller
            SA[k] = i;
            t++;
            if (t == n02) // done --- only SA0 suffixes left
                for (k++; p < n0; p++, k++) SA[k] = SA0[p];
        } else { // suffix from SA0 is smaller
            SA[k] = j;
            p++;
            if (p == n0) // done --- only SA12 suffixes left
                for (k++; t < n02; t++, k++) SA[k] = GetI();
        }
    }
    delete [] R; delete [] SA12; delete [] SA0; delete [] R0;
}
Example #12
0
// and triples
inline bool leq(int a1, int a2, int a3, int b1, int b2, int b3) {
    return(a1 < b1 || a1 == b1 && leq(a2,a3, b2,b3));
} // and triples
Example #13
0
	static bool gt(int c, int d)
	{
		return ff::not(leq(c, d));
	};
Example #14
0
static void sift_up(struct heap *h, size_t i) {
    for(; i && leq(h, i, P(i)); i = P(i) ) {
        swap(h, i, P(i));
    }
}
Example #15
0
void executeInstruction()
{
    switch(ir.op)
    {
    case 1:
        lit();
        break;
    case 2:
        opr();
        break;
    case 3:
        lod();
        break;
    case 4:
        sto();
        break;
    case 5:
        cal();
        break;
    case 6:
        inc();
        break;
    case 7:
        jmp();
        break;
    case 8:
        jpc();
        break;
    case 9:
        sio();
    default:
        break;

    }

    void opr()
{
    switch ( ir.m)
    {
        //rtn
        case 0:
            ret();
            break;
        //neg
        case 1:
            neg();
            break;
       //add
        case 2:
            add();
            break;
       //sub
        case 3:
            sub();
            break;
        //mul
        case 4:
            mul();
            break;
        //div
        case 5:
            divid();
            break;
        //odd
        case 6:
            odd();
            break;
        //mod
        case 7:
            mod();
            break;
        //eql
        case 8:
            eql();
            break;
        //neq
        case 9:
            neq();
            break;
        //lss
        case 10:
            lss();
            break;
        //leq
        case 11:
            leq();
            break;
        //gtr
        case 12:
            gtr();
            break;
        //geq
        case 13:
            geq();
            break;

        default:
            fprintf(output, "OP code input was invalid. ");
            halt = 1;
            break;
    }
}

}
Example #16
0
int main () {
  unsigned char bytes[256];
  int i;

  /* Table 2.  Double-precision floating-point arithmetic.  */
  deq (__aeabi_dadd (dzero, done), done);
  deq (__aeabi_dadd (done, done), dtwo);
  deq (__aeabi_ddiv (dminus_four, dminus_two), dtwo);
  deq (__aeabi_ddiv (dminus_two, dtwo), dminus_one);
  deq (__aeabi_dmul (dtwo, dtwo), dfour);
  deq (__aeabi_dmul (dminus_one, dminus_two), dtwo);
  deq (__aeabi_dneg (dminus_one), done);
  deq (__aeabi_dneg (dfour), dminus_four);
  deq (__aeabi_drsub (done, dzero), dminus_one);
  deq (__aeabi_drsub (dtwo, dminus_two), dminus_four);
  deq (__aeabi_dsub (dzero, done), dminus_one);
  deq (__aeabi_dsub (dminus_two, dtwo), dminus_four);

  /* Table 3.  Double-precision floating-point comparisons.  */
  ieq (__aeabi_dcmpeq (done, done), 1);
  ieq (__aeabi_dcmpeq (done, dzero), 0);
  ieq (__aeabi_dcmpeq (dNaN, dzero), 0);
  ieq (__aeabi_dcmpeq (dNaN, dNaN), 0);

  ieq (__aeabi_dcmplt (dzero, done), 1);
  ieq (__aeabi_dcmplt (done, dzero), 0);
  ieq (__aeabi_dcmplt (dzero, dzero), 0);
  ieq (__aeabi_dcmplt (dzero, dNaN), 0);
  ieq (__aeabi_dcmplt (dNaN, dNaN), 0);

  ieq (__aeabi_dcmple (dzero, done), 1);
  ieq (__aeabi_dcmple (done, dzero), 0);
  ieq (__aeabi_dcmple (dzero, dzero), 1);
  ieq (__aeabi_dcmple (dzero, dNaN), 0);
  ieq (__aeabi_dcmple (dNaN, dNaN), 0);

  ieq (__aeabi_dcmpge (dzero, done), 0);
  ieq (__aeabi_dcmpge (done, dzero), 1);
  ieq (__aeabi_dcmpge (dzero, dzero), 1);
  ieq (__aeabi_dcmpge (dzero, dNaN), 0);
  ieq (__aeabi_dcmpge (dNaN, dNaN), 0);

  ieq (__aeabi_dcmpgt (dzero, done), 0);
  ieq (__aeabi_dcmpgt (done, dzero), 1);
  ieq (__aeabi_dcmplt (dzero, dzero), 0);
  ieq (__aeabi_dcmpgt (dzero, dNaN), 0);
  ieq (__aeabi_dcmpgt (dNaN, dNaN), 0);

  ieq (__aeabi_dcmpun (done, done), 0);
  ieq (__aeabi_dcmpun (done, dzero), 0);
  ieq (__aeabi_dcmpun (dNaN, dzero), 1);
  ieq (__aeabi_dcmpun (dNaN, dNaN), 1);

  /* Table 4.  Single-precision floating-point arithmetic.  */
  feq (__aeabi_fadd (fzero, fone), fone);
  feq (__aeabi_fadd (fone, fone), ftwo);
  feq (__aeabi_fdiv (fminus_four, fminus_two), ftwo);
  feq (__aeabi_fdiv (fminus_two, ftwo), fminus_one);
  feq (__aeabi_fmul (ftwo, ftwo), ffour);
  feq (__aeabi_fmul (fminus_one, fminus_two), ftwo);
  feq (__aeabi_fneg (fminus_one), fone);
  feq (__aeabi_fneg (ffour), fminus_four);
  feq (__aeabi_frsub (fone, fzero), fminus_one);
  feq (__aeabi_frsub (ftwo, fminus_two), fminus_four);
  feq (__aeabi_fsub (fzero, fone), fminus_one);
  feq (__aeabi_fsub (fminus_two, ftwo), fminus_four);

  /* Table 5.  Single-precision floating-point comparisons.  */
  ieq (__aeabi_fcmpeq (fone, fone), 1);
  ieq (__aeabi_fcmpeq (fone, fzero), 0);
  ieq (__aeabi_fcmpeq (fNaN, fzero), 0);
  ieq (__aeabi_fcmpeq (fNaN, fNaN), 0);

  ieq (__aeabi_fcmplt (fzero, fone), 1);
  ieq (__aeabi_fcmplt (fone, fzero), 0);
  ieq (__aeabi_fcmplt (fzero, fzero), 0);
  ieq (__aeabi_fcmplt (fzero, fNaN), 0);
  ieq (__aeabi_fcmplt (fNaN, fNaN), 0);

  ieq (__aeabi_fcmple (fzero, fone), 1);
  ieq (__aeabi_fcmple (fone, fzero), 0);
  ieq (__aeabi_fcmple (fzero, fzero), 1);
  ieq (__aeabi_fcmple (fzero, fNaN), 0);
  ieq (__aeabi_fcmple (fNaN, fNaN), 0);

  ieq (__aeabi_fcmpge (fzero, fone), 0);
  ieq (__aeabi_fcmpge (fone, fzero), 1);
  ieq (__aeabi_fcmpge (fzero, fzero), 1);
  ieq (__aeabi_fcmpge (fzero, fNaN), 0);
  ieq (__aeabi_fcmpge (fNaN, fNaN), 0);

  ieq (__aeabi_fcmpgt (fzero, fone), 0);
  ieq (__aeabi_fcmpgt (fone, fzero), 1);
  ieq (__aeabi_fcmplt (fzero, fzero), 0);
  ieq (__aeabi_fcmpgt (fzero, fNaN), 0);
  ieq (__aeabi_fcmpgt (fNaN, fNaN), 0);

  ieq (__aeabi_fcmpun (fone, fone), 0);
  ieq (__aeabi_fcmpun (fone, fzero), 0);
  ieq (__aeabi_fcmpun (fNaN, fzero), 1);
  ieq (__aeabi_fcmpun (fNaN, fNaN), 1);

  /* Table 6.  Floating-point to integer conversions.  */
  ieq (__aeabi_d2iz (dminus_one), -1);
  ueq (__aeabi_d2uiz (done), 1);
  leq (__aeabi_d2lz (dminus_two), -2LL);
  uleq (__aeabi_d2ulz (dfour), 4LL);
  ieq (__aeabi_f2iz (fminus_one), -1);
  ueq (__aeabi_f2uiz (fone), 1);
  leq (__aeabi_f2lz (fminus_two), -2LL);
  uleq (__aeabi_f2ulz (ffour), 4LL);

  /* Table 7.  Conversions between floating types.  */
  feq (__aeabi_d2f (dtwo), ftwo);
  deq (__aeabi_f2d (fminus_four), dminus_four);

  /* Table 8.  Integer to floating-point conversions.  */
  deq (__aeabi_i2d (-1), dminus_one);
  deq (__aeabi_ui2d (2), dtwo);
  deq (__aeabi_l2d (-1), dminus_one);
  deq (__aeabi_ul2d (2ULL), dtwo);
  feq (__aeabi_i2f (-1), fminus_one);
  feq (__aeabi_ui2f (2), ftwo);
  feq (__aeabi_l2f (-1), fminus_one);
  feq (__aeabi_ul2f (2ULL), ftwo);

  /* Table 9.  Long long functions.  */
  leq (__aeabi_lmul (4LL, -1LL), -4LL);
  leq (__aeabi_llsl (2LL, 1), 4LL);
  leq (__aeabi_llsr (-1LL, 63), 1);
  leq (__aeabi_lasr (-1LL, 63), -1);
  ieq (__aeabi_lcmp (0LL, 1LL), -1);
  ieq (__aeabi_lcmp (0LL, 0LL), 0);
  ieq (__aeabi_lcmp (1LL, 0LL), 1);
  ieq (__aeabi_ulcmp (0LL, 1LL), -1);
  ieq (__aeabi_ulcmp (0LL, 0LL), 0);
  ieq (__aeabi_ulcmp (1LL, 0LL), 1);

  ieq (__aeabi_idiv (-550, 11), -50);
  ueq (__aeabi_uidiv (4000000000U, 1000000U), 4000U);

  for (i = 0; i < 256; i++)
    bytes[i] = i;

#ifdef __ARMEB__
  ieq (__aeabi_uread4 (bytes + 1), 0x01020304U);
  leq (__aeabi_uread8 (bytes + 3), 0x030405060708090aLL);
  ieq (__aeabi_uwrite4 (0x66778899U, bytes + 5), 0x66778899U);
  leq (__aeabi_uwrite8 (0x2030405060708090LL, bytes + 15),
       0x2030405060708090LL);
#else
  ieq (__aeabi_uread4 (bytes + 1), 0x04030201U);
  leq (__aeabi_uread8 (bytes + 3), 0x0a09080706050403LL);
  ieq (__aeabi_uwrite4 (0x99887766U, bytes + 5), 0x99887766U);
  leq (__aeabi_uwrite8 (0x9080706050403020LL, bytes + 15),
       0x9080706050403020LL);
#endif

  for (i = 0; i < 4; i++)
    ieq (bytes[5 + i], (6 + i) * 0x11);

  for (i = 0; i < 8; i++)
    ieq (bytes[15 + i], (2 + i) * 0x10);

  exit (0);		
}
Example #17
0
	inline bool leq(int a1, int a2, int a3, int b1, int b2, int b3) {
		return (a1 < b1 || (a1 == b1 && leq(a2, a3, b2, b3)));
	}
Example #18
0
relation_t pdbm_relationWithMinDBM(const PDBM pdbm1, cindex_t dim,
                                   const mingraph_t pdbm2, raw_t *dbm2)
{
    assert(pdbm1 && pdbm2 && dim && dbm2);

    raw_t    *dbm1   = pdbm_matrix(pdbm1);
    int32_t  cost1   = pdbm_cost(pdbm1);
    int32_t  *rates1 = pdbm_rates(pdbm1);

    int32_t c, d;

    /* We know how the cost and the rates are encoded in a mingraph:
     * see writeToMinDBMWithOffset and readFromMinDBM. 
     */
    int32_t       cost2   = pdbm2[0];
    const int32_t *rates2 = pdbm2 + 2;

    /* dbm_relationWithMinDBM will in some cases unpack pdbm2 into
     * dbm2. In order to detect whether this has happened, we set the
     * first entry of dbm2 to -1. If dbm_relationWithMinDBM did indeed
     * unpack pdbm2, this entry will have a different value
     * afterwards.
     */
    dbm2[0] = -1;

    switch (dbm_relationWithMinDBM(dbm1, dim, pdbm2 + dim + 2, dbm2))
    {
    case base_SUPERSET:
        /* pdbm2 is smaller. Check whether it is also the most
         * expensive: This is the case when the difference between
         * pdbm2 and pdbm1 is always non-negative (the infimum is not
         * smaller than 0).
         */
         if (dbm2[0] == -1)
         {
            dbm_readFromMinDBM(dbm2, pdbm2 + dim + 2);
         }
        cost1 = costAtOtherOffset(dbm1, rates1, cost1, dbm2, dim);
        if (cost1 <= cost2 
            && (leq(rates1, rates1 + dim, rates2)
                || infOfDiff(dbm2, dim, cost2, rates2, cost1, rates1) >= 0))
        {
            return base_SUPERSET;
        }
        else
        {
            return base_DIFFERENT;
        }

    case base_SUBSET:
        /* pdbm2 is bigger. Check whether it is also the cheapest:
         * This is the case when the difference between pdbm1 and
         * pdbm2 is always non-negative (the infimum is not smaller
         * than 0).
         */
        if (dbm2[0] == -1)
        {
            dbm_readFromMinDBM(dbm2, pdbm2 + dim + 2);
        }
        cost2 = costAtOtherOffset(dbm2, rates2, cost2, dbm1, dim);
        if (cost2 <= cost1
            && (leq(rates2, rates2 + dim, rates1)
                || infOfDiff(dbm1, dim, cost1, rates1, cost2, rates2) >= 0))
        {
            return base_SUBSET;
        }
        else
        {
            return base_DIFFERENT;
        }

    case base_EQUAL:
        /* Both have the same size. We need to compare the planes to
         * see which one is cheaper.
         */

        /* Do sound and cheap comparison first.
         */
        c = cost1 <= cost2 && leq(rates1, rates1 + dim, rates2);
        d = cost2 <= cost1 && leq(rates2, rates2 + dim, rates1);

        if (c & d)
        {
            return base_EQUAL;
        }
        else if (c)
        {
            return base_SUPERSET;
        }
        else if (d)
        {
            return base_SUBSET;
        }        

        /* The planes are incomparable, so we need to do the
         * subtraction. Notice that priced zones are not canonical,
         * so the two zones can in fact be equal even though the rates
         * are different.  Therefore we must also check for the
         * situation where both infima are zero.
         *
         * Notice that dbm1 equals dbm2, hence we do not need to
         * unpacked dbm2.
         */
        c = infOfDiff(dbm1, dim, cost2, rates2, cost1, rates1);
        if (c > 0)
        {
            /* Early return to avoid unnecessary computation of the
             * second subtraction.
             */
            return base_SUPERSET;
        }
        
        d = infOfDiff(dbm1, dim, cost1, rates1, cost2, rates2);
        if (c == 0 && d == 0)
        {
            return base_EQUAL;
        }
        if (c >= 0)
        {
            return base_SUPERSET;
        }
        if (d >= 0)
        {
            return base_SUBSET;
        }
        return base_DIFFERENT;

    default:
        return base_DIFFERENT;
    }
}
Example #19
0
relation_t pdbm_relation(const PDBM pdbm1, const PDBM pdbm2, cindex_t dim)
{
    assert(pdbm1 && pdbm2 && dim);

    raw_t   *dbm1   = pdbm_matrix(pdbm1);
    raw_t   *dbm2   = pdbm_matrix(pdbm2);
    int32_t *rates1 = pdbm_rates(pdbm1);
    int32_t *rates2 = pdbm_rates(pdbm2);
    int32_t cost1   = pdbm_cost(pdbm1);
    int32_t cost2   = pdbm_cost(pdbm2);

    int32_t c, d;

    switch (dbm_relation(dbm1, dbm2, dim))
    {
    case base_SUPERSET:
        /* pdbm2 is smaller. Check whether it is also the most
         * expensive: This is the case when the difference between
         * pdbm2 and pdbm1 is always non-negative (the infimum is not
         * smaller than 0).
         */
        cost1 = costAtOtherOffset(dbm1, rates1, cost1, dbm2, dim);
        if (cost1 <= cost2 
            && (leq(rates1, rates1 + dim, rates2)
                || infOfDiff(dbm2, dim, cost2, rates2, cost1, rates1) >= 0))
        {
            return base_SUPERSET;
        }
        else
        {
            return base_DIFFERENT;
        }

    case base_SUBSET:
        /* pdbm2 is bigger. Check whether it is also the cheapest:
         * This is the case when the difference between pdbm1 and
         * pdbm2 is always non-negative (the infimum is not smaller
         * than 0).
         */
        cost2 = costAtOtherOffset(dbm2, rates2, cost2, dbm1, dim);
        if (cost2 <= cost1
            && (leq(rates2, rates2 + dim, rates1)
                || infOfDiff(dbm1, dim, cost1, rates1, cost2, rates2) >= 0))
        {
            return base_SUBSET;
        }
        else
        {
            return base_DIFFERENT;
        }

    case base_EQUAL:
        /* Both have the same size. We need to compare the planes to
         * see which one is cheaper.
         */

        /* Do sound and cheap comparison first.
         */
        /* This test is not sound when the zone is reduced to a single point
         */
//        c = cost1 <= cost2 && leq(rates1, rates1 + dim, rates2);
//        d = cost2 <= cost1 && leq(rates2, rates2 + dim, rates1);
//
//        if (c & d)
//        {
//            return base_EQUAL;
//        }
//        else if (c)
//        {
//            return base_SUPERSET;
//        }
//        else if (d)
//        {
//            return base_SUBSET;
//        }

        /* The planes are incomparable, so we need to do the
         * subtraction. Notice that priced zones are not canonical,
         * so the two zones can in fact be equal even though the rates
         * are different.  Therefore we must also check for the
         * situation where both infima are zero.
         *
         * Notice that dbm1 equals dbm2, hence we do not need to
         * unpack dbm2.
         */
        c = infOfDiff(dbm1, dim, cost2, rates2, cost1, rates1);
        if (c > 0)
        {
            /* Early return to avoid unnecessary computation of the
             * second subtraction.
             */
            return base_SUPERSET;
        }
        
        d = infOfDiff(dbm1, dim, cost1, rates1, cost2, rates2);

        if (c == 0 && d == 0)
        {
            return base_EQUAL;
        }
        if (c >= 0)
        {
            return base_SUPERSET;
        }
        if (d >= 0)
        {
            return base_SUBSET;
        }
        return base_DIFFERENT;

    default:
        return base_DIFFERENT;
    }
}
Example #20
0
void opr()
{
    switch ( ir.m)
    {
        //rtn
        case 0:
            ret();
            break;
        //neg
        case 1:
            neg();
            break;
       //add
        case 2:
            add();
            break;
       //sub
        case 3:
            sub();
            break;
        //mul
        case 4:
            mul();
            break;
        //div
        case 5:
            divid();
            break;
        //odd
        case 6:
            odd();
            break;
        //mod
        case 7:
            mod();
            break;
        //eql
        case 8:
            eql();
            break;
        //neq
        case 9:
            neq();
            break;
        //lss
        case 10:
            lss();
            break;
        //leq
        case 11:
            leq();
            break;
        //gtr
        case 12:
            gtr();
            break;
        //geq
        case 13:
            geq();
            break;

        default:
            fprintf(output, "OP code input was invalid. ");
            sio3();
    }
}
Example #21
0
CompileOutput *Compiler::Compile(AMXRef amx) {
  Prepare(amx);

  Disassembler disasm(amx);
  Instruction instr;
  bool error = false;

  while (!error && disasm.Decode(instr, error)) {
    if (!Process(instr)) {
      error = true;
      break;
    }

    switch (instr.opcode().GetId()) {
      case OP_LOAD_PRI:
        load_pri(instr.operand());
        break;
      case OP_LOAD_ALT:
        load_alt(instr.operand());
        break;
      case OP_LOAD_S_PRI:
        load_s_pri(instr.operand());
        break;
      case OP_LOAD_S_ALT:
        load_s_alt(instr.operand());
        break;
      case OP_LREF_PRI:
        lref_pri(instr.operand());
        break;
      case OP_LREF_ALT:
        lref_alt(instr.operand());
        break;
      case OP_LREF_S_PRI:
        lref_s_pri(instr.operand());
        break;
      case OP_LREF_S_ALT:
        lref_s_alt(instr.operand());
        break;
      case OP_LOAD_I:
        load_i();
        break;
      case OP_LODB_I:
        lodb_i(instr.operand());
        break;
      case OP_CONST_PRI:
        const_pri(instr.operand());
        break;
      case OP_CONST_ALT:
        const_alt(instr.operand());
        break;
      case OP_ADDR_PRI:
        addr_pri(instr.operand());
        break;
      case OP_ADDR_ALT:
        addr_alt(instr.operand());
        break;
      case OP_STOR_PRI:
        stor_pri(instr.operand());
        break;
      case OP_STOR_ALT:
        stor_alt(instr.operand());
        break;
      case OP_STOR_S_PRI:
        stor_s_pri(instr.operand());
        break;
      case OP_STOR_S_ALT:
        stor_s_alt(instr.operand());
        break;
      case OP_SREF_PRI:
        sref_pri(instr.operand());
        break;
      case OP_SREF_ALT:
        sref_alt(instr.operand());
        break;
      case OP_SREF_S_PRI:
        sref_s_pri(instr.operand());
        break;
      case OP_SREF_S_ALT:
        sref_s_alt(instr.operand());
        break;
      case OP_STOR_I:
        stor_i();
        break;
      case OP_STRB_I:
        strb_i(instr.operand());
        break;
      case OP_LIDX:
        lidx();
        break;
      case OP_LIDX_B:
        lidx_b(instr.operand());
        break;
      case OP_IDXADDR:
        idxaddr();
        break;
      case OP_IDXADDR_B:
        idxaddr_b(instr.operand());
        break;
      case OP_ALIGN_PRI:
        align_pri(instr.operand());
        break;
      case OP_ALIGN_ALT:
        align_alt(instr.operand());
        break;
      case OP_LCTRL:
        lctrl(instr.operand(), instr.address() + instr.size());
        break;
      case OP_SCTRL:
        sctrl(instr.operand());
        break;
      case OP_MOVE_PRI:
        move_pri();
        break;
      case OP_MOVE_ALT:
        move_alt();
        break;
      case OP_XCHG:
        xchg();
        break;
      case OP_PUSH_PRI:
        push_pri();
        break;
      case OP_PUSH_ALT:
        push_alt();
        break;
      case OP_PUSH_C:
        push_c(instr.operand());
        break;
      case OP_PUSH:
        push(instr.operand());
        break;
      case OP_PUSH_S:
        push_s(instr.operand());
        break;
      case OP_POP_PRI:
        pop_pri();
        break;
      case OP_POP_ALT:
        pop_alt();
        break;
      case OP_STACK: // value
        stack(instr.operand());
        break;
      case OP_HEAP:
        heap(instr.operand());
        break;
      case OP_PROC:
        proc();
        break;
      case OP_RET:
        ret();
        break;
      case OP_RETN:
        retn();
        break;
      case OP_JUMP_PRI:
        jump_pri();
        break;
      case OP_CALL:
      case OP_JUMP:
      case OP_JZER:
      case OP_JNZ:
      case OP_JEQ:
      case OP_JNEQ:
      case OP_JLESS:
      case OP_JLEQ:
      case OP_JGRTR:
      case OP_JGEQ:
      case OP_JSLESS:
      case OP_JSLEQ:
      case OP_JSGRTR:
      case OP_JSGEQ: {
        cell dest = instr.operand() - reinterpret_cast<cell>(amx.code());
        switch (instr.opcode().GetId()) {
          case OP_CALL:
            call(dest);
            break;
          case OP_JUMP:
            jump(dest);
            break;
          case OP_JZER:
            jzer(dest);
            break;
          case OP_JNZ:
            jnz(dest);
            break;
          case OP_JEQ:
            jeq(dest);
            break;
          case OP_JNEQ:
            jneq(dest);
            break;
          case OP_JLESS:
            jless(dest);
            break;
          case OP_JLEQ:
            jleq(dest);
            break;
          case OP_JGRTR:
            jgrtr(dest);
            break;
          case OP_JGEQ:
            jgeq(dest);
            break;
          case OP_JSLESS:
            jsless(dest);
            break;
          case OP_JSLEQ:
            jsleq(dest);
            break;
          case OP_JSGRTR:
            jsgrtr(dest);
            break;
          case OP_JSGEQ:
            jsgeq(dest);
            break;
        }
        break;
      }
      case OP_SHL:
        shl();
        break;
      case OP_SHR:
        shr();
        break;
      case OP_SSHR:
        sshr();
        break;
      case OP_SHL_C_PRI:
        shl_c_pri(instr.operand());
        break;
      case OP_SHL_C_ALT:
        shl_c_alt(instr.operand());
        break;
      case OP_SHR_C_PRI:
        shr_c_pri(instr.operand());
        break;
      case OP_SHR_C_ALT:
        shr_c_alt(instr.operand());
        break;
      case OP_SMUL:
        smul();
        break;
      case OP_SDIV:
        sdiv();
        break;
      case OP_SDIV_ALT:
        sdiv_alt();
        break;
      case OP_UMUL:
        umul();
        break;
      case OP_UDIV:
        udiv();
        break;
      case OP_UDIV_ALT:
        udiv_alt();
        break;
      case OP_ADD:
        add();
        break;
      case OP_SUB:
        sub();
        break;
      case OP_SUB_ALT:
        sub_alt();
        break;
      case OP_AND:
        and_();
        break;
      case OP_OR:
        or_();
        break;
      case OP_XOR:
        xor_();
        break;
      case OP_NOT:
        not_();
        break;
      case OP_NEG:
        neg();
        break;
      case OP_INVERT:
        invert();
        break;
      case OP_ADD_C:
        add_c(instr.operand());
        break;
      case OP_SMUL_C:
        smul_c(instr.operand());
        break;
      case OP_ZERO_PRI:
        zero_pri();
        break;
      case OP_ZERO_ALT:
        zero_alt();
        break;
      case OP_ZERO:
        zero(instr.operand());
        break;
      case OP_ZERO_S:
        zero_s(instr.operand());
        break;
      case OP_SIGN_PRI:
        sign_pri();
        break;
      case OP_SIGN_ALT:
        sign_alt();
        break;
      case OP_EQ:
        eq();
        break;
      case OP_NEQ:
        neq();
        break;
      case OP_LESS:
        less();
        break;
      case OP_LEQ:
        leq();
        break;
      case OP_GRTR:
        grtr();
        break;
      case OP_GEQ:
        geq();
        break;
      case OP_SLESS:
        sless();
        break;
      case OP_SLEQ:
        sleq();
        break;
      case OP_SGRTR:
        sgrtr();
        break;
      case OP_SGEQ:
        sgeq();
        break;
      case OP_EQ_C_PRI:
        eq_c_pri(instr.operand());
        break;
      case OP_EQ_C_ALT:
        eq_c_alt(instr.operand());
        break;
      case OP_INC_PRI:
        inc_pri();
        break;
      case OP_INC_ALT:
        inc_alt();
        break;
      case OP_INC:
        inc(instr.operand());
        break;
      case OP_INC_S:
        inc_s(instr.operand());
        break;
      case OP_INC_I:
        inc_i();
        break;
      case OP_DEC_PRI:
        dec_pri();
        break;
      case OP_DEC_ALT:
        dec_alt();
        break;
      case OP_DEC:
        dec(instr.operand());
        break;
      case OP_DEC_S:
        dec_s(instr.operand());
        break;
      case OP_DEC_I:
        dec_i();
        break;
      case OP_MOVS:
        movs(instr.operand());
        break;
      case OP_CMPS:
        cmps(instr.operand());
        break;
      case OP_FILL:
        fill(instr.operand());
        break;
      case OP_HALT:
        halt(instr.operand());
        break;
      case OP_BOUNDS:
        bounds(instr.operand());
        break;
      case OP_SYSREQ_PRI:
        sysreq_pri();
        break;
      case OP_SYSREQ_C: {
        const char *name = amx.GetNativeName(instr.operand());
        if (name == 0) {
          error = true;
        } else {
          sysreq_c(instr.operand(), name);
        }
        break;
      }
      case OP_SYSREQ_D: {
        const char *name = amx.GetNativeName(amx.FindNative(instr.operand()));
        if (name == 0) {
          error = true;
        } else {
          sysreq_d(instr.operand(), name);
        }
        break;
      }
      case OP_SWITCH:
        switch_(CaseTable(amx, instr.operand()));
        break;
      case OP_CASETBL:
        casetbl();
        break;
      case OP_SWAP_PRI:
        swap_pri();
        break;
      case OP_SWAP_ALT:
        swap_alt();
        break;
      case OP_PUSH_ADR:
        push_adr(instr.operand());
        break;
      case OP_NOP:
        nop();
        break;
      case OP_BREAK:
        break_();
        break;
    default:
      error = true;
    }
  }

  if (error && error_handler_ != 0) {
    error_handler_->Execute(instr);
  }

  return Finish(error);
}