static void rehash(sd_hash_t* a_this)
{
size_t i;
int h, size;
sd_hash_iter_t** tab;
sd_hash_iter_t* p;
sd_hash_iter_t* q;
size = SD_HASH_GROWTAB * a_this->size;
tab = sd_calloc(size, sizeof(*tab));
if (tab == 0) return;
for (i = 0; i < a_this->size; i++) {
for (p = a_this->tab[i]; p; p = q) {
q = p->__next;
h = hindex(p->__hkey,
size);
p->__next = tab[h];
tab[h] = p;
if (p->__next != 0) p->__next->__prev = p;
p->__prev = 0;
}
}
free(a_this->tab);
a_this->tab = tab;
a_this->size = size;
}
extern void sd_hash_iter_del(sd_hash_iter_t* a_this)
{
if (a_this == 0) return;
if (a_this->hash->ops->data_free != 0)
a_this->hash->ops->data_free(a_this->data);
a_this->data = 0;
if (a_this->hash->ops->key_free != 0)
a_this->hash->ops->key_free(a_this->key);
a_this->key = 0;
if (a_this->__foreach == 1) {
a_this->__foreach = 0;
return;
}
if (a_this->__next != 0) a_this->__next->__prev = a_this->__prev;
if (a_this->__prev != 0)
a_this->__prev->__next = a_this->__next;
else
a_this->hash->tab[hindex(a_this->__hkey, a_this->hash->size)] =
a_this->__next;
a_this->hash->nelem--;
free(a_this);
}
extern sd_hash_iter_t* sd_hash_lookadd(sd_hash_t* a_this, const void* a_key)
{
int h;
sd_hash_iter_t* p;
if (a_this == 0 || a_key == 0) return 0;
if ((p = sd_hash_lookup(a_this, a_key)) != 0) return p;
if ((p = sd_calloc(1, sizeof(*p))) == 0) return 0;
if (a_this->ops->key_dup != 0)
p->key = a_this->ops->key_dup(a_key);
else
p->key = (void*) a_key;
p->hash = a_this;
p->__hkey = a_this->ops->hash(a_key);
if (a_this->nelem > SD_HASH_FULLTAB * a_this->size) rehash(a_this);
h = hindex(p->__hkey,
a_this->size);
p->__next = a_this->tab[h];
a_this->tab[h] = p;
if (p->__next != 0) p->__next->__prev = p;
a_this->nelem++;
return p;
}
std::size_t grid::save(FILE* fp) const {
std::size_t cnt = 0;
auto foo = std::fwrite;
{
static hpx::mutex mtx;
std::lock_guard < hpx::mutex > lock(mtx);
cnt += foo(&scaling_factor, sizeof(real), 1, fp) * sizeof(real);
cnt += foo(&max_level, sizeof(integer), 1, fp) * sizeof(integer);
cnt += foo(&Acons, sizeof(real), 1, fp) * sizeof(real);
cnt += foo(&Bcons, sizeof(integer), 1, fp) * sizeof(integer);
}
cnt += foo(&is_leaf, sizeof(bool), 1, fp) * sizeof(bool);
cnt += foo(&is_root, sizeof(bool), 1, fp) * sizeof(bool);
for (integer f = 0; f != NF; ++f) {
for (integer i = H_BW; i < H_NX - H_BW; ++i) {
for (integer j = H_BW; j < H_NX - H_BW; ++j) {
const integer iii = hindex(i, j, H_BW);
cnt += foo(&(U[f][iii]), sizeof(real), INX, fp) * sizeof(real);
}
}
}
for (integer i = 0; i < G_NX; ++i) {
for (integer j = 0; j < G_NX; ++j) {
for (integer k = 0; k < G_NX; ++k) {
const integer iii = gindex(i, j, k);
cnt += foo(&(G[iii][0]), sizeof(real), NGF, fp) * sizeof(real);
}
}
}
cnt += foo(U_out.data(), sizeof(real), U_out.size(), fp) * sizeof(real);
return cnt;
}
extern void sd_hash_del(sd_hash_t* a_this, const void* a_key)
{
int h;
sd_hash_iter_t* p;
h = hindex(a_this->ops->hash(a_key), a_this->size);
for (p = a_this->tab[h]; p != 0; p = p->__next)
if (a_this->ops->compare(a_key, p->key) == 0) break;
if (p == 0) return;
sd_hash_iter_del(p);
}
extern sd_hash_iter_t* sd_hash_lookup(sd_hash_t* a_this, const void* a_key)
{
int h;
sd_hash_iter_t* p;
if (a_this == 0 || a_key == 0) return 0;
h = hindex(a_this->ops->hash(a_key), a_this->size);
for (p = a_this->tab[h]; p != 0; p = p->__next)
if (a_this->ops->compare(a_key, p->key) == 0) {
return p;
}
return 0;
}
extern sd_hash_iter_t* sd_hash_iter_next(sd_hash_iter_t* a_this)
{
int h;
size_t i;
if (a_this == 0) return 0;
if (a_this->__next != 0) return a_this->__next;
h = hindex(a_this->__hkey, a_this->hash->size);
for (i = h + 1; i < a_this->hash->size; i++)
if (a_this->hash->tab[i])
return a_this->hash->tab[i];
return 0;
}
extern sd_hash_iter_t* sd_hash_iter_prev(sd_hash_iter_t* a_this)
{
int h, i;
sd_hash_iter_t* p;
if (a_this == 0) return 0;
if (a_this->__prev != 0) return a_this->__prev;
h = hindex(a_this->__hkey, a_this->hash->size);
for (i = h - 1; i > 0; i--)
for (p = a_this->hash->tab[i]; p; p = p->__next)
if (p->__next == 0)
return p;
return 0;
}
// Compute a heuristic estimate. TODO: reimplement jumpsa and write a
// test for the new way of combining lookups.
int pancake::h(short H)
{
int ans = 0; // to be returned
int val = 0; // aux variable for heuristic values
m_jump=0; // by default, don't jump
m_target.first=0; // reset target cause we don't have one yet
m_target.second=0;
// no pdb
if(!m_f || m_pdb==NULL)
return 0;
uint32 mask = 0;
uint8 cost = 0;
char ol = (pdb_type_ == OL)?1:0; // at least one lookup when using OL
for (int d = 0; d <= dual_lookups_; ++d){
if (d) this->dual();
for (int y = 0; y <= sym_lookups_; ++y){
if (y) {this->sym(y-1); cost = m_syms[y-1].m_cost;}
else cost = 0;
for (int o = 0; o < ord_lookups_ + ol; ++o){
// watch(o); watch(hord_masks_[o]);
mask = (pdb_type_ == ORD)?hord_masks_[o]:0;
// watch(mask);
// TODO: mark necessary jumps for DIDA*
// watch(hindex(mask));
val = m_pdb[hindex(mask)] - cost;
ans = max(ans, val);
if (ans > H) break;
}
// revert sym
if(y) this->sym(y-1);
if (ans > H) break;
}
// revert dual
if(d) this->dual();
if (ans > H) break;
}
return ans;
}
grid::output_list_type grid::get_output_list(bool analytic) const {
auto& V = TLS_V();
compute_primitives();
output_list_type rc;
const integer vertex_order[8] = { 0, 1, 3, 2, 4, 5, 7, 6 };
std::set<node_point>& node_list = rc.nodes;
std::vector<zone_int_type>& zone_list = rc.zones;
std::array < std::vector<real>, NF + NGF + NPF > &data = rc.data;
std::array < std::vector<real>, NF > &A = rc.analytic;
for (integer field = 0; field != NF + NGF + NPF; ++field) {
data[field].reserve(INX * INX * INX);
if (analytic) {
A[field].reserve(INX * INX * INX);
}
}
const integer this_bw = H_BW;
zone_list.reserve(std::pow(H_NX - 2 * this_bw, NDIM) * NCHILD);
for (integer i = this_bw; i != H_NX - this_bw; ++i) {
for (integer j = this_bw; j != H_NX - this_bw; ++j) {
for (integer k = this_bw; k != H_NX - this_bw; ++k) {
const integer iii = hindex(i, j, k);
const integer iiig = gindex(i - H_BW, j - H_BW, k - H_BW);
#ifdef EQ_ONLY
if (!(std::abs(X[ZDIM][iii]) < dx) && !(std::abs(X[YDIM][iii]) < dx)) {
continue;
}
#endif
for (integer ci = 0; ci != NVERTEX; ++ci) {
const integer vi = vertex_order[ci];
const integer xi = (vi >> 0) & 1;
const integer yi = (vi >> 1) & 1;
const integer zi = (vi >> 2) & 1;
node_point this_x;
this_x.pt[XDIM] = X[XDIM][iii] + (real(xi) - HALF) * dx;
this_x.pt[YDIM] = X[YDIM][iii] + (real(yi) - HALF) * dx;
this_x.pt[ZDIM] = X[ZDIM][iii] + (real(zi) - HALF) * dx;
auto iter = node_list.find(this_x);
integer index;
if (iter != node_list.end()) {
index = iter->index;
} else {
index = node_list.size();
this_x.index = index;
node_list.insert(this_x);
}
zone_list.push_back(index);
}
if (analytic) {
for (integer field = 0; field != NF; ++field) {
A[field].push_back(Ua[field][iii]);
}
}
for (integer field = 0; field != NF; ++field) {
data[field].push_back(U[field][iii]);
}
for (integer field = 0; field != NGF; ++field) {
data[field + NF].push_back(G[iiig][field]);
}
data[NGF + NF + 0].push_back(V[vx_i][iii]);
data[NGF + NF + 1].push_back(V[vy_i][iii]);
data[NGF + NF + 2].push_back(V[vz_i][iii]);
if (V[egas_i][iii] * V[rho_i][iii] < de_switch2 * U[egas_i][iii]) {
data[NGF + NF + 3].push_back(std::pow(V[tau_i][iii], fgamma) / V[rho_i][iii]);
} else {
data[NGF + NF + 3].push_back(V[egas_i][iii]);
}
data[NGF + NF + 4].push_back(V[zz_i][iii]);
}
}
}
return rc;
}
