poly-le-k.c
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/* poly-le-k(C, X, k) == sum(C . X) <= k */
static int fd_poly_le_k_filter(fd_constraint this)
{
int k;
int min, max;
int terms = this->nvariables;
int *mins, *maxs;
int i;
#ifdef CONSTRAINT_TEMPS
int *base;
assert(!fd__constraint_data_valid(this));
if (!constraint_memory[this->index])
constraint_memory[this->index] = malloc((2 * terms + 2) * sizeof(int));
base = constraint_memory[this->index];
mins = base + 2;
maxs = mins + terms;
#else
mins = alloca(terms * sizeof(*mins));
maxs = alloca(terms * sizeof(*maxs));
#endif
k = this->constants[terms];
// sum the minima and the maxima of the terms
min = max = 0;
for (i = 0; i < terms; ++i)
{
int vl, vh;
if (this->constants[i] > 0)
{
vl = mins[i] = _fd_var_min(VAR(this, i));
vh = maxs[i] = _fd_var_max(VAR(this, i));
}
else
{
vl = maxs[i] = _fd_var_max(VAR(this, i));
vh = mins[i] = _fd_var_min(VAR(this, i));
}
min += this->constants[i] * vl;
max += this->constants[i] * vh;
}
if (min > k)
return FD_NOSOLUTION;
if (max <= k)
{
fd__constraint_set_entailed(this);
}
else if (min == k)
{
for (i = 0; i < terms; ++i)
{
int c = this->constants[i];
if (c == 0 || mins[i] == maxs[i]) continue;
if (c > 0)
{
_fd_var_del_gt(mins[i], VAR(this, i));
// check needed for when variables occur more than once
// and with opposite signs
if (fd_domain_empty(VAR(this, i)))
return FD_NOSOLUTION;
_fd_revise_connected(this, VAR(this, i));
maxs[i] = mins[i];
}
else
{
_fd_var_del_lt(maxs[i], VAR(this, i));
// check needed for when variables occur more than once
// and with opposite signs
if (fd_domain_empty(VAR(this, i)))
return FD_NOSOLUTION;
_fd_revise_connected(this, VAR(this, i));
mins[i] = maxs[i];
}
}
max = min;
fd__constraint_set_entailed(this);
}
else // max > k
{
// bounds domain filtering
for (i = 0; i < terms; ++i)
{
int c = this->constants[i];
int imin = mins[i];
int imax = maxs[i];
if (c > 0)
{
// enforce min(sum{j!=i}(c[j] * x[j])) + c[i] * max[i] <= k
if (min + (imax - imin) * c > k)
{
// max[i] = floor((k - min) / c[i]) + min[i]
imax = (k - min) / c + imin;
_fd_var_del_gt(imax, VAR(this, i));
if (fd_domain_empty(VAR(this, i)))
return FD_NOSOLUTION;
_fd_revise_connected(this, VAR(this, i));
max -= (maxs[i] - imax) * c;
maxs[i] = imax;
}
}
else // c < 0 (does nothing if c is 0)
{
// enforce min(sum{j!=i}(c[j] * x[j])) + c[i] * min[i] <= k
if (min + (imin - imax) * c > k)
{
// min[i] = ceil((k - min) / c[i]) + max[i]
imin = (k - min) / c + imax;
_fd_var_del_lt(imin, VAR(this, i));
if (fd_domain_empty(VAR(this, i)))
return FD_NOSOLUTION;
_fd_revise_connected(this, VAR(this, i));
max -= (mins[i] - imin) * c;
mins[i] = imin;
}
}
}
if (max <= k)
fd__constraint_set_entailed(this);
}
#ifdef CONSTRAINT_TEMPS
// save values
*base = min;
*(base + 1) = max;
fd__constraint_remember(this);
#endif
return FD_OK;
}
static int fd_poly_le_k_propagate2(fd_constraint this, fd_int culprit)
{
#ifdef CONSTRAINT_TEMPS
int k;
int min, max;
int terms = this->nvariables;
int *mins, *maxs;
int i;
int *base;
int x, c;
int nmin, nmin_x, nmax, nmax_x;
if (!fd__constraint_data_valid(this))
return fd_poly_le_k_filter(this); // ignores culprit
// bounds filtering
base = constraint_memory[this->index];
mins = base + 2;
maxs = mins + terms;
min = *base;
max = *(base + 1);
k = this->constants[terms];
// find the (first) term where the culprit appears
for (x = 0; culprit != VAR(this, x); ++x)
;
nmin_x = _fd_var_min(VAR(this, x));
nmax_x = _fd_var_max(VAR(this, x));
if (nmin_x == mins[x] && nmax_x == maxs[x])
return FD_OK;
nmin = min;
nmax = max;
do
{
c = this->constants[x];
if (c > 0)
{
nmin = nmin + (nmin_x - mins[x]) * c;
nmax = nmax - (maxs[x] - nmax_x) * c;
}
else if (c < 0)
{
nmin = nmin - (maxs[x] - nmax_x) * c;
nmax = nmax + (nmin_x - mins[x]) * c;
}
if (nmin > k)
return FD_NOSOLUTION;
mins[x] = nmin_x;
maxs[x] = nmax_x;
// search for the next term where the culprit appears
while (++x < terms && culprit != VAR(this, x))
;
}
while (x < terms);
if (nmin == min && nmax == max)
return FD_OK;
if (nmax <= k)
{
fd__constraint_set_entailed(this);
}
else if (nmin == k)
{
for (i = 0; i < terms; ++i)
{
int c = this->constants[i];
if (c == 0 || mins[i] == maxs[i]) continue;
if (c > 0)
{
fd_update_domain_and_check(del_gt, mins[i], VAR(this, i));
maxs[i] = mins[i];
}
else
{
fd_update_domain_and_check(del_lt, maxs[i], VAR(this, i));
mins[i] = maxs[i];
}
}
nmax = nmin;
fd__constraint_set_entailed(this);
}
else if (nmin > min) // nmax > k
{
// bounds domain propagation
for (i = 0; i < terms; ++i)
{
int c = this->constants[i];
int imin = mins[i];
int imax = maxs[i];
if (c > 0)
{
// enforce min(sum{j!=i}(c[j] * x[j])) + c[i] * max[i] <= k
if (nmin + (imax - imin) * c > k)
{
// max[i] = floor((k - nmin) / c[i]) + min[i]
imax = (k - nmin) / c + imin;
fd_update_domain_and_check(del_gt, imax, VAR(this, i));
nmax -= (maxs[i] - imax) * c;
maxs[i] = imax;
}
}
else // c < 0 (does nothing if c is 0)
{
// enforce min(sum{j!=i}(c[j] * x[j])) + c[i] * min[i] <= k
if (nmin + (imin - imax) * c > k)
{
// min[i] = ceil((k - nmin) / c[i]) + max[i]
imin = (k - nmin) / c + imax;
fd_update_domain_and_check(del_lt, imin, VAR(this, i));
nmax -= (mins[i] - imin) * c;
mins[i] = imin;
}
}
}
if (nmax <= k)
fd__constraint_set_entailed(this);
}
*base = nmin;
*(base + 1) = nmax;
return FD_OK;
#else /* CONSTRAINT_TEMPS */
return fd_poly_le_k_filter(this); // ignores culprit
#endif /* CONSTRAINT_TEMPS */
}
fd_constraint fd_poly_le_k(int cs[], fd_int xs[], int nterms, int k)
{
fd_constraint c = fd__constraint_new(nterms, nterms + 1);
int i;
if (c)
{
for (i = 0; i < nterms; ++i)
c->variables[i] = FD_INT2C_VAR(xs[i]);
for (i = 0; i < nterms; ++i)
c->constants[i] = cs[i];
c->constants[nterms] = k;
c->kind = FD_CONSTR_POLY_LE_K;
for (i = 0; i < c->nvariables; ++i)
_fd_var_add_constraint(VAR(c, i), c);
_fd_add_constraint(c);
}
return c;
}