gcc/libcilkrts/runtime/reducer_impl.cpp

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/* reducer_impl.cpp -*-C++-*-
*
*************************************************************************
*
* @copyright
* Copyright (C) 2009-2013, Intel Corporation
* All rights reserved.
*
* @copyright
* Redistribution and use in source and binary forms, with or without
* modification, are permitted provided that the following conditions
* are met:
*
* * Redistributions of source code must retain the above copyright
* notice, this list of conditions and the following disclaimer.
* * Redistributions in binary form must reproduce the above copyright
* notice, this list of conditions and the following disclaimer in
* the documentation and/or other materials provided with the
* distribution.
* * Neither the name of Intel Corporation nor the names of its
* contributors may be used to endorse or promote products derived
* from this software without specific prior written permission.
*
* @copyright
* THIS SOFTWARE IS PROVIDED BY THE COPYRIGHT HOLDERS AND CONTRIBUTORS
* "AS IS" AND ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT
* LIMITED TO, THE IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR
* A PARTICULAR PURPOSE ARE DISCLAIMED. IN NO EVENT SHALL THE COPYRIGHT
* HOLDER OR CONTRIBUTORS BE LIABLE FOR ANY DIRECT, INDIRECT,
* INCIDENTAL, SPECIAL, EXEMPLARY, OR CONSEQUENTIAL DAMAGES (INCLUDING,
* BUT NOT LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS OR SERVICES; LOSS
* OF USE, DATA, OR PROFITS; OR BUSINESS INTERRUPTION) HOWEVER CAUSED
* AND ON ANY THEORY OF LIABILITY, WHETHER IN CONTRACT, STRICT
* LIABILITY, OR TORT (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY
* WAY OUT OF THE USE OF THIS SOFTWARE, EVEN IF ADVISED OF THE
* POSSIBILITY OF SUCH DAMAGE.
*
* Patents Pending, Intel Corporation.
**************************************************************************/
/**
* Support for reducers
*/
// ICL: Don't complain about conversion from pointer to same-sized integral type
// in hashfun. That's why we're using size_t
#ifdef _WIN32
# pragma warning(disable: 1684)
#endif
#include "reducer_impl.h"
#include "scheduler.h"
#include "bug.h"
#include "os.h"
#include "global_state.h"
#include "frame_malloc.h"
#include "cilk/hyperobject_base.h"
#include "cilktools/cilkscreen.h"
#include "internal/abi.h"
#if REDPAR_DEBUG > 0
#include <stdio.h>
#include <stdlib.h>
#endif
#define DBG if(0) // if(1) enables some internal checks
// Check that w is the currently executing worker. This method is a
// no-op unless the debug level is set high enough.
static inline void verify_current_wkr(__cilkrts_worker *w)
{
#if REDPAR_DEBUG >= 5
__cilkrts_worker* tmp = __cilkrts_get_tls_worker();
if (w != tmp) {
fprintf(stderr, "W=%d, actual=%d... missing a refresh....\n",
w->self,
tmp->self);
}
CILK_ASSERT(w == tmp); // __cilkrts_get_tls_worker());
#endif
}
// Suppress clang warning that the expression result is unused
#if defined(__clang__) && (! defined(__INTEL_COMPILER))
# pragma clang diagnostic push
# pragma clang diagnostic ignored "-Wunused-value"
#endif // __clang__
/// Helper class to disable and re-enable Cilkscreen
struct DisableCilkscreen
{
DisableCilkscreen () { __cilkscreen_disable_checking(); }
~DisableCilkscreen () { __cilkscreen_enable_checking(); }
};
/// Helper class to enable and re-disable Cilkscreen
struct EnableCilkscreen
{
EnableCilkscreen () { __cilkscreen_enable_checking(); }
~EnableCilkscreen () { __cilkscreen_disable_checking(); }
};
#if defined(__clang__) && (! defined(__INTEL_COMPILER))
# pragma clang diagnostic pop
#endif // __clang__
/**
* @brief Element for a hyperobject
*/
struct elem {
void *key; ///< Shared key for this hyperobject
__cilkrts_hyperobject_base *hb; ///< Base of the hyperobject.
void *view; ///< Strand-private view of this hyperobject
/// Destroy and deallocate the view object for this element and set view to
/// null.
void destroy();
/// Returns true if this element contains a leftmost view.
bool is_leftmost() const;
};
/** Bucket containing at most NMAX elements */
struct bucket {
/// Size of the array of elements for this bucket
size_t nmax;
/**
* We use the ``struct hack'' to allocate an array of variable
* dimension at the end of the struct. However, we allocate a
* total of NMAX+1 elements instead of NMAX. The last one always
* has key == 0, which we use as a termination criterion
*/
elem el[1];
};
/**
* Class that implements the map for reducers so we can find the
* view for a strand.
*/
struct cilkred_map {
/** Handy pointer to the global state */
global_state_t *g;
/** Number of elements in table */
size_t nelem;
/** Number of buckets */
size_t nbuckets;
/** Array of pointers to buckets */
bucket **buckets;
/** Set true if merging (for debugging purposes) */
bool merging;
/** Set true for leftmost reducer map */
bool is_leftmost;
/** @brief Return element mapped to 'key' or null if not found. */
elem *lookup(void *key);
/**
* @brief Insert key/value element into hash map without rehashing.
* Does not check for duplicate key.
*/
elem *insert_no_rehash(__cilkrts_worker *w,
void *key,
__cilkrts_hyperobject_base *hb,
void *value);
/**
* @brief Insert key/value element into hash map, rehashing if necessary.
* Does not check for duplicate key.
*/
inline elem *rehash_and_insert(__cilkrts_worker *w,
void *key,
__cilkrts_hyperobject_base *hb,
void *value);
/** @brief Grow bucket by one element, reallocating bucket if necessary */
static elem *grow(__cilkrts_worker *w, bucket **bp);
/** @brief Rehash a worker's reducer map */
void rehash(__cilkrts_worker *);
/**
* @brief Returns true if a rehash is needed due to the number of elements that
* have been inserted.
*/
inline bool need_rehash_p() const;
/** @brief Allocate and initialize the buckets */
void make_buckets(__cilkrts_worker *w, size_t nbuckets);
/**
* Specify behavior when the same key is present in both maps passed
* into merge().
*/
enum merge_kind
{
MERGE_UNORDERED, ///< Assertion fails
MERGE_INTO_LEFT, ///< Merges the argument from the right into the left
MERGE_INTO_RIGHT ///< Merges the argument from the left into the right
};
/**
* @brief Merge another reducer map into this one, destroying the other map in
* the process.
*/
__cilkrts_worker* merge(__cilkrts_worker *current_wkr,
cilkred_map *other_map,
enum merge_kind kind);
/** @brief check consistency of a reducer map */
void check(bool allow_null_view);
/** @brief Test whether the cilkred_map is empty */
bool is_empty() { return nelem == 0; }
};
static inline struct cilkred_map* install_new_reducer_map(__cilkrts_worker *w) {
cilkred_map *h;
h = __cilkrts_make_reducer_map(w);
w->reducer_map = h;
return h;
}
static size_t sizeof_bucket(size_t nmax)
{
bucket *b = 0;
return (sizeof(*b) + nmax * sizeof(b->el[0]));
}
static bucket *alloc_bucket(__cilkrts_worker *w, size_t nmax)
{
bucket *b = (bucket *)
__cilkrts_frame_malloc(w, sizeof_bucket(nmax));
b->nmax = nmax;
return b;
}
static void free_bucket(__cilkrts_worker *w, bucket **bp)
{
bucket *b = *bp;
if (b) {
__cilkrts_frame_free(w, b, sizeof_bucket(b->nmax));
*bp = 0;
}
}
/* round up nmax to fill a memory allocator block completely */
static size_t roundup(size_t nmax)
{
size_t sz = sizeof_bucket(nmax);
/* round up size to a full malloc block */
sz = __cilkrts_frame_malloc_roundup(sz);
/* invert sizeof_bucket() */
nmax = ((sz - sizeof(bucket)) / sizeof(elem));
return nmax;
}
static bool is_power_of_2(size_t n)
{
return (n & (n - 1)) == 0;
}
void cilkred_map::make_buckets(__cilkrts_worker *w,
size_t new_nbuckets)
{
nbuckets = new_nbuckets;
CILK_ASSERT(is_power_of_2(nbuckets));
#if defined __GNUC__ && defined __ICC
/* bug workaround -- suppress calls to _intel_fast_memset */
bucket *volatile*new_buckets = (bucket *volatile*)
#else
bucket **new_buckets = (bucket **)
#endif
__cilkrts_frame_malloc(w, nbuckets * sizeof(*(buckets)));
#if REDPAR_DEBUG >= 1
fprintf(stderr, "W=%d, desc=make_buckets, new_buckets=%p, new_nbuckets=%zd\n",
w->self, new_buckets, new_nbuckets);
#endif
for (size_t i = 0; i < new_nbuckets; ++i)
new_buckets[i] = 0;
#if defined __GNUC__ && defined __ICC
buckets = (bucket **)new_buckets;
#else
buckets = new_buckets;
#endif
nelem = 0;
}
static void free_buckets(__cilkrts_worker *w,
bucket **buckets,
size_t nbuckets)
{
size_t i;
#if REDPAR_DEBUG >= 1
verify_current_wkr(w);
fprintf(stderr, "W=%d, desc=free_buckets, buckets=%p, size=%zd\n",
w->self, buckets,
nbuckets * sizeof(*buckets));
#endif
for (i = 0; i < nbuckets; ++i)
free_bucket(w, buckets + i);
__cilkrts_frame_free(w, buckets, nbuckets * sizeof(*buckets));
}
static size_t minsz(size_t nelem)
{
return 1U + nelem + nelem / 8U;
}
static size_t nextsz(size_t nelem)
{
return 2 * nelem;
}
bool cilkred_map::need_rehash_p() const
{
return minsz(nelem) > nbuckets;
}
static inline size_t hashfun(const cilkred_map *h, void *key)
{
size_t k = (size_t) key;
k ^= k >> 21;
k ^= k >> 8;
k ^= k >> 3;
return k & (h->nbuckets - 1);
}
// Given a __cilkrts_hyperobject_base, return the key to that hyperobject in
// the reducer map.
static inline void* get_hyperobject_key(__cilkrts_hyperobject_base *hb)
{
// The current implementation uses the address of the lefmost view as the
// key.
return reinterpret_cast<char*>(hb) + hb->__view_offset;
}
// Given a hyperobject key, return a pointer to the leftmost object. In the
// current implementation, the address of the leftmost object IS the key, so
// this function is an effective noop.
static inline void* get_leftmost_view(void *key)
{
return key;
}
/* debugging support: check consistency of a reducer map */
void cilkred_map::check(bool allow_null_view)
{
size_t count = 0;
CILK_ASSERT(buckets);
for (size_t i = 0; i < nbuckets; ++i) {
bucket *b = buckets[i];
if (b)
for (elem *el = b->el; el->key; ++el) {
CILK_ASSERT(allow_null_view || el->view);
++count;
}
}
CILK_ASSERT(nelem == count);
/*global_reducer_map::check();*/
}
/* grow bucket by one element, reallocating bucket if necessary */
elem *cilkred_map::grow(__cilkrts_worker *w,
bucket **bp)
{
size_t i, nmax, nnmax;
bucket *b, *nb;
b = *bp;
if (b) {
nmax = b->nmax;
/* find empty element if any */
for (i = 0; i < nmax; ++i)
if (b->el[i].key == 0)
return &(b->el[i]);
/* do not use the last one even if empty */
} else {
nmax = 0;
}
verify_current_wkr(w);
/* allocate a new bucket */
nnmax = roundup(2 * nmax);
nb = alloc_bucket(w, nnmax);
/* copy old bucket into new */
for (i = 0; i < nmax; ++i)
nb->el[i] = b->el[i];
free_bucket(w, bp); *bp = nb;
/* zero out extra elements */
for (; i < nnmax; ++i)
nb->el[i].key = 0;
/* zero out the last one */
nb->el[i].key = 0;
return &(nb->el[nmax]);
}
elem *cilkred_map::insert_no_rehash(__cilkrts_worker *w,
void *key,
__cilkrts_hyperobject_base *hb,
void *view)
{
#if REDPAR_DEBUG >= 2
fprintf(stderr, "[W=%d, desc=insert_no_rehash, this_map=%p]\n",
w->self, this);
verify_current_wkr(w);
#endif
CILK_ASSERT((w == 0 && g == 0) || w->g == g);
CILK_ASSERT(key != 0);
CILK_ASSERT(view != 0);
elem *el = grow(w, &(buckets[hashfun(this, key)]));
#if REDPAR_DEBUG >= 3
fprintf(stderr, "[W=%d, this=%p, inserting key=%p, view=%p, el = %p]\n",
w->self, this, key, view, el);
#endif
el->key = key;
el->hb = hb;
el->view = view;
++nelem;
return el;
}
void cilkred_map::rehash(__cilkrts_worker *w)
{
#if REDPAR_DEBUG >= 1
fprintf(stderr, "[W=%d, desc=rehash, this_map=%p, g=%p, w->g=%p]\n",
w->self, this, g, w->g);
verify_current_wkr(w);
#endif
CILK_ASSERT((w == 0 && g == 0) || w->g == g);
size_t onbuckets = nbuckets;
size_t onelem = nelem;
bucket **obuckets = buckets;
size_t i;
bucket *b;
make_buckets(w, nextsz(nbuckets));
for (i = 0; i < onbuckets; ++i) {
b = obuckets[i];
if (b) {
elem *oel;
for (oel = b->el; oel->key; ++oel)
insert_no_rehash(w, oel->key, oel->hb, oel->view);
}
}
CILK_ASSERT(nelem == onelem);
free_buckets(w, obuckets, onbuckets);
}
elem *cilkred_map::rehash_and_insert(__cilkrts_worker *w,
void *key,
__cilkrts_hyperobject_base *hb,
void *view)
{
#if REDPAR_DEBUG >= 1
fprintf(stderr, "W=%d, this_map =%p, inserting key=%p, view=%p\n",
w->self, this, key, view);
verify_current_wkr(w);
#endif
if (need_rehash_p())
rehash(w);
return insert_no_rehash(w, key, hb, view);
}
elem *cilkred_map::lookup(void *key)
{
bucket *b = buckets[hashfun(this, key)];
if (b) {
elem *el;
for (el = b->el; el->key; ++el) {
if (el->key == key) {
CILK_ASSERT(el->view);
return el;
}
}
}
return 0;
}
void elem::destroy()
{
if (! is_leftmost()) {
// Call destroy_fn and deallocate_fn on the view, but not if it's the
// leftmost view.
cilk_c_monoid *monoid = &(hb->__c_monoid);
cilk_c_reducer_destroy_fn_t destroy_fn = monoid->destroy_fn;
cilk_c_reducer_deallocate_fn_t deallocate_fn = monoid->deallocate_fn;
destroy_fn((void*)hb, view);
deallocate_fn((void*)hb, view);
}
view = 0;
}
inline
bool elem::is_leftmost() const
{
// implementation uses the address of the leftmost view as the key, so if
// key == view, then this element refers to the leftmost view.
return key == view;
}
/* remove the reducer from the current reducer map. If the reducer
exists in maps other than the current one, the behavior is
undefined. */
extern "C"
CILK_EXPORT void __CILKRTS_STRAND_STALE(
__cilkrts_hyper_destroy(__cilkrts_hyperobject_base *hb))
{
// Disable Cilkscreen for the duration of this call. The destructor for
// this class will re-enable Cilkscreen when the method returns. This
// will prevent Cilkscreen from reporting apparent races in reducers
DisableCilkscreen x;
__cilkrts_worker* w = __cilkrts_get_tls_worker();
if (! w) {
// If no worker, then Cilk is not running and there is no reducer
// map. Do nothing. The reducer's destructor will take care of
// destroying the leftmost view.
return;
}
const char *UNSYNCED_REDUCER_MSG =
"Destroying a reducer while it is visible to unsynced child tasks, or\n"
"calling CILK_C_UNREGISTER_REDUCER() on an unregistered reducer.\n"
"Did you forget a _Cilk_sync or CILK_C_REGISTER_REDUCER()?";
cilkred_map* h = w->reducer_map;
if (NULL == h)
cilkos_error(UNSYNCED_REDUCER_MSG); // Does not return
if (h->merging) {
verify_current_wkr(w);
__cilkrts_bug("User error: hyperobject used by another hyperobject");
}
void* key = get_hyperobject_key(hb);
elem *el = h->lookup(key);
// Verify that the reducer is being destroyed from the leftmost strand for
// which the reducer is defined.
if (! (el && el->is_leftmost()))
cilkos_error(UNSYNCED_REDUCER_MSG);
#if REDPAR_DEBUG >= 3
fprintf(stderr, "[W=%d, key=%p, lookup in map %p, found el=%p, about to destroy]\n",
w->self, key, h, el);
#endif
// Remove the element from the hash bucket. Do not bother shrinking
// the bucket. Note that the destroy() function does not actually
// call the destructor for the leftmost view.
el->destroy();
do {
el[0] = el[1];
++el;
} while (el->key);
--h->nelem;
#if REDPAR_DEBUG >= 2
fprintf(stderr, "[W=%d, desc=hyper_destroy_finish, key=%p, w->reducer_map=%p]\n",
w->self, key, w->reducer_map);
#endif
}
extern "C"
CILK_EXPORT
void __cilkrts_hyper_create(__cilkrts_hyperobject_base *hb)
{
// This function registers the specified hyperobject in the current
// reducer map and registers the initial value of the hyperobject as the
// leftmost view of the reducer.
__cilkrts_worker *w = __cilkrts_get_tls_worker();
if (! w) {
// If there is no worker, then there is nothing to do: The iniitial
// value will automatically be used as the left-most view when we
// enter Cilk.
return;
}
// Disable Cilkscreen for the duration of this call. The destructor for
// this class will re-enable Cilkscreen when the method returns. This
// will prevent Cilkscreen from reporting apparent races in reducers
DisableCilkscreen x;
void* key = get_hyperobject_key(hb);
void* view = get_leftmost_view(key);
cilkred_map *h = w->reducer_map;
if (__builtin_expect(!h, 0)) {
h = install_new_reducer_map(w);
#if REDPAR_DEBUG >= 2
fprintf(stderr, "[W=%d, hb=%p, hyper_create, isntalled new map %p, view=%p]\n",
w->self, hb, h, view);
#endif
}
/* Must not exist. */
CILK_ASSERT(h->lookup(key) == NULL);
#if REDPAR_DEBUG >= 3
verify_current_wkr(w);
fprintf(stderr, "[W=%d, hb=%p, lookup in map %p of view %p, should be null]\n",
w->self, hb, h, view);
fprintf(stderr, "W=%d, h=%p, inserting key %p, view%p\n",
w->self,
h,
&(hb->__c_monoid),
view);
#endif
if (h->merging)
__cilkrts_bug("User error: hyperobject used by another hyperobject");
CILK_ASSERT(w->reducer_map == h);
// The address of the leftmost value is the same as the key for lookup.
(void) h->rehash_and_insert(w, view, hb, view);
}
extern "C"
CILK_EXPORT void* __CILKRTS_STRAND_PURE(
__cilkrts_hyper_lookup(__cilkrts_hyperobject_base *hb))
{
__cilkrts_worker* w = __cilkrts_get_tls_worker_fast();
void* key = get_hyperobject_key(hb);
if (! w)
return get_leftmost_view(key);
// Disable Cilkscreen for the duration of this call. This will
// prevent Cilkscreen from reporting apparent races in reducers
DisableCilkscreen dguard;
if (__builtin_expect(w->g->force_reduce, 0))
__cilkrts_promote_own_deque(w);
cilkred_map* h = w->reducer_map;
if (__builtin_expect(!h, 0)) {
h = install_new_reducer_map(w);
}
if (h->merging)
__cilkrts_bug("User error: hyperobject used by another hyperobject");
elem* el = h->lookup(key);
if (! el) {
/* lookup failed; insert a new default element */
void *rep;
{
/* re-enable cilkscreen while calling the constructor */
EnableCilkscreen eguard;
if (h->is_leftmost)
{
// This special case is called only if the reducer was not
// registered using __cilkrts_hyper_create, e.g., if this is a
// C reducer in global scope or if there is no bound worker.
rep = get_leftmost_view(key);
}
else
{
rep = hb->__c_monoid.allocate_fn((void*)hb,
hb->__view_size);
// TBD: Handle exception on identity function
hb->__c_monoid.identity_fn((void*)hb, rep);
}
}
#if REDPAR_DEBUG >= 3
fprintf(stderr, "W=%d, h=%p, inserting key %p, view%p\n",
w->self,
h,
&(hb->__c_monoid),
rep);
CILK_ASSERT(w->reducer_map == h);
#endif
el = h->rehash_and_insert(w, key, hb, rep);
}
return el->view;
}
extern "C" CILK_EXPORT
void* __cilkrts_hyperobject_alloc(void* ignore, std::size_t bytes)
{
return std::malloc(bytes);
}
extern "C" CILK_EXPORT
void __cilkrts_hyperobject_dealloc(void* ignore, void* view)
{
std::free(view);
}
/* No-op destroy function */
extern "C" CILK_EXPORT
void __cilkrts_hyperobject_noop_destroy(void* ignore, void* ignore2)
{
}
cilkred_map *__cilkrts_make_reducer_map(__cilkrts_worker *w)
{
CILK_ASSERT(w);
cilkred_map *h;
size_t nbuckets = 1; /* default value */
h = (cilkred_map *)__cilkrts_frame_malloc(w, sizeof(*h));
#if REDPAR_DEBUG >= 1
fprintf(stderr, "[W=%d, desc=make_reducer_frame_malloc_reducer_map, h=%p]\n",
w->self, h);
#endif
h->g = w ? w->g : 0;
h->make_buckets(w, nbuckets);
h->merging = false;
h->is_leftmost = false;
return h;
}
/* Destroy a reducer map. The map must have been allocated
from the worker's global context and should have been
allocated from the same worker. */
void __cilkrts_destroy_reducer_map(__cilkrts_worker *w, cilkred_map *h)
{
CILK_ASSERT((w == 0 && h->g == 0) || w->g == h->g);
verify_current_wkr(w);
/* the reducer map is allowed to contain el->view == NULL here (and
only here). We set el->view == NULL only when we know that the
map will be destroyed immediately afterwards. */
DBG h->check(/*allow_null_view=*/true);
bucket *b;
size_t i;
for (i = 0; i < h->nbuckets; ++i) {
b = h->buckets[i];
if (b) {
elem *el;
for (el = b->el; el->key; ++el) {
if (el->view)
el->destroy();
}
}
}
free_buckets(w, h->buckets, h->nbuckets);
#if REDPAR_DEBUG >= 1
fprintf(stderr, "W=%d, destroy_red_map, freeing map h=%p, size=%zd\n",
w->self, h, sizeof(*h));
#endif
__cilkrts_frame_free(w, h, sizeof(*h));
}
/* Set the specified reducer map as the leftmost map if is_leftmost is true,
otherwise, set it to not be the leftmost map. */
void __cilkrts_set_leftmost_reducer_map(cilkred_map *h, int is_leftmost)
{
h->is_leftmost = is_leftmost;
}
__cilkrts_worker* cilkred_map::merge(__cilkrts_worker *w,
cilkred_map *other_map,
enum merge_kind kind)
{
// Disable Cilkscreen while the we merge the maps. The destructor for
// the guard class will re-enable Cilkscreen when it goes out of scope.
// This will prevent Cilkscreen from reporting apparent races in between
// the reduce function and the reducer operations. The Cilk runtime
// guarantees that a pair of reducer maps will only be merged when no
// other strand will access them.
DisableCilkscreen guard;
#if REDPAR_DEBUG >= 2
fprintf(stderr, "[W=%d, desc=merge, this_map=%p, other_map=%p]\n",
w->self,
this, other_map);
#endif
// Remember the current stack frame.
__cilkrts_stack_frame *current_sf = w->current_stack_frame;
merging = true;
other_map->merging = true;
// Merging to the leftmost view is a special case because every leftmost
// element must be initialized before the merge.
CILK_ASSERT(!other_map->is_leftmost /* || kind == MERGE_UNORDERED */);
bool merge_to_leftmost = (this->is_leftmost
/* && !other_map->is_leftmost */);
DBG check(/*allow_null_view=*/false);
DBG other_map->check(/*allow_null_view=*/false);
for (size_t i = 0; i < other_map->nbuckets; ++i) {
bucket *b = other_map->buckets[i];
if (b) {
for (elem *other_el = b->el; other_el->key; ++other_el) {
/* Steal the value from the other map, which will be
destroyed at the end of this operation. */
void *other_view = other_el->view;
CILK_ASSERT(other_view);
void *key = other_el->key;
__cilkrts_hyperobject_base *hb = other_el->hb;
elem *this_el = lookup(key);
if (this_el == 0 && merge_to_leftmost) {
/* Initialize leftmost view before merging. */
void* leftmost = get_leftmost_view(key);
// leftmost == other_view can be true if the initial view
// was created in other than the leftmost strand of the
// spawn tree, but then made visible to subsequent strands
// (E.g., the reducer was allocated on the heap and the
// pointer was returned to the caller.) In such cases,
// parallel semantics says that syncing with earlier
// strands will always result in 'this_el' being null,
// thus propagating the initial view up the spawn tree
// until it reaches the leftmost strand. When synching
// with the leftmost strand, leftmost == other_view will be
// true and we must avoid reducing the initial view with
// itself.
if (leftmost != other_view)
this_el = rehash_and_insert(w, key, hb, leftmost);
}
if (this_el == 0) {
/* move object from other map into this one */
rehash_and_insert(w, key, hb, other_view);
other_el->view = 0;
continue; /* No element-level merge necessary */
}
/* The same key is present in both maps with values
A and B. Three choices: fail, A OP B, B OP A. */
switch (kind)
{
case MERGE_UNORDERED:
__cilkrts_bug("TLS Reducer race");
break;
case MERGE_INTO_RIGHT:
/* Swap elements in order to preserve object
identity */
other_el->view = this_el->view;
this_el->view = other_view;
/* FALL THROUGH */
case MERGE_INTO_LEFT: {
/* Stealing should be disabled during reduce
(even if force-reduce is enabled). */
#if DISABLE_PARALLEL_REDUCERS
__cilkrts_stack_frame * volatile *saved_protected_tail;
saved_protected_tail = __cilkrts_disallow_stealing(w, NULL);
#endif
{
CILK_ASSERT(current_sf->worker == w);
CILK_ASSERT(w->current_stack_frame == current_sf);
/* TBD: if reduce throws an exception we need to stop it
here. */
hb->__c_monoid.reduce_fn((void*)hb,
this_el->view,
other_el->view);
w = current_sf->worker;
#if REDPAR_DEBUG >= 2
verify_current_wkr(w);
CILK_ASSERT(w->current_stack_frame == current_sf);
#endif
}
#if DISABLE_PARALLEL_REDUCERS
/* Restore stealing */
__cilkrts_restore_stealing(w, saved_protected_tail);
#endif
} break;
}
}
}
}
this->is_leftmost = this->is_leftmost || other_map->is_leftmost;
merging = false;
other_map->merging = false;
verify_current_wkr(w);
__cilkrts_destroy_reducer_map(w, other_map);
return w;
}
/**
* Print routine for debugging the merging of reducer maps.
* A no-op unless REDPAR_DEBUG set high enough.
*/
static inline
void debug_map_merge(__cilkrts_worker *w,
cilkred_map *left_map,
cilkred_map *right_map,
__cilkrts_worker **final_wkr)
{
#if REDPAR_DEBUG >= 2
fprintf(stderr, "[W=%d, desc=finish_merge, left_map=%p, right_map=%p, w->reducer_map=%p, right_ans=%p, final_wkr=%d]\n",
w->self, left_map, right_map, w->reducer_map, right_map, (*final_wkr)->self);
#endif
}
/**
* merge RIGHT into LEFT;
* return whichever map allows for faster merge, and destroy the other one.
*
* *w_ptr should be the currently executing worker.
* *w_ptr may change during execution if the reduction is parallel.
*/
cilkred_map*
merge_reducer_maps(__cilkrts_worker **w_ptr,
cilkred_map *left_map,
cilkred_map *right_map)
{
__cilkrts_worker *w = *w_ptr;
if (!left_map) {
debug_map_merge(w, left_map, right_map, w_ptr);
return right_map;
}
if (!right_map) {
debug_map_merge(w, left_map, right_map, w_ptr);
return left_map;
}
/* Special case, if left_map is leftmost, then always merge into it.
For C reducers this forces lazy creation of the leftmost views. */
if (left_map->is_leftmost || left_map->nelem > right_map->nelem) {
*w_ptr = left_map->merge(w, right_map, cilkred_map::MERGE_INTO_LEFT);
debug_map_merge(*w_ptr, left_map, right_map, w_ptr);
return left_map;
} else {
*w_ptr = right_map->merge(w, left_map, cilkred_map::MERGE_INTO_RIGHT);
debug_map_merge(*w_ptr, left_map, right_map, w_ptr);
return right_map;
}
}
/**
* Merges RIGHT into LEFT, and then repeatedly calls
* merge_reducer_maps_helper() until (*w_ptr)->reducer_map is NULL.
*
* *w_ptr may change as reductions execute.
*/
cilkred_map*
repeated_merge_reducer_maps(__cilkrts_worker **w_ptr,
cilkred_map *left_map,
cilkred_map *right_map)
{
// Note: if right_map == NULL but w->reducer_map != NULL, then
// this loop will reduce w->reducer_map into left_map.
do {
left_map = merge_reducer_maps(w_ptr, left_map, right_map);
verify_current_wkr(*w_ptr);
// Pull any newly created reducer map and loop around again.
right_map = (*w_ptr)->reducer_map;
(*w_ptr)->reducer_map = NULL;
} while (right_map);
return left_map;
}
/* End reducer_impl.cpp */