Retro68/gcc/libcilkrts/runtime/record-replay.cpp

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/* record-replay.cpp -*-C++-*-
*
*************************************************************************
*
* Copyright (C) 2012-2016, Intel Corporation
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* All rights reserved.
*
* 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.
*
* 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.
*
* *********************************************************************
*
* PLEASE NOTE: This file is a downstream copy of a file mainitained in
* a repository at cilkplus.org. Changes made to this file that are not
* submitted through the contribution process detailed at
* http://www.cilkplus.org/submit-cilk-contribution will be lost the next
* time that a new version is released. Changes only submitted to the
* GNU compiler collection or posted to the git repository at
* https://bitbucket.org/intelcilkruntime/intel-cilk-runtime.git are
* not tracked.
*
* We welcome your contributions to this open source project. Thank you
* for your assistance in helping us improve Cilk Plus.
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*
**************************************************************************/
/*
* Implementation of the record/replay functionality for Cilk Plus
*/
#include <cstring>
#include <vector>
#include <stdlib.h>
// clang is really strict about printf formats, so use the annoying integer
// printf macros. Unfortunately they're not available on Windows (or on VxWorks)
#if defined(_WIN32) || defined(_WRS_KERNEL)
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#define PRIu64 "llu"
#else
#define __STDC_FORMAT_MACROS 1
#include <inttypes.h>
#endif
#include "record-replay.h"
#include "bug.h"
#include "internal/abi.h"
#include "local_state.h"
#include "full_frame.h"
#include "global_state.h"
#include "cilk_malloc.h"
#include "os.h" // for cilkos_error()
#if RECORD_ON_REPLAY
#pragma message ("*** Record on Replay is enabled!")
#endif
// Defined to write sequence number to the logs. Note that you cannot
// diff logs with sequence numbers because the numbers may increment in
// different orders.
//#define INCLUDE_SEQUENCE_NUMBER 1
const int PED_VERSION = 1; // Log recording version
// Log types
enum ped_type_t
{
ped_type_unknown,
ped_type_steal,
ped_type_sync,
ped_type_orphaned,
ped_type_last // Flags end of the list
};
// Log type strings
#define PED_TYPE_STR_STEAL "Steal"
#define PED_TYPE_STR_SYNC "Sync"
#define PED_TYPE_STR_WORKERS "Workers"
#define PED_TYPE_STR_ORPHANED "Orphaned"
#define PED_TYPE_SIZE 16 // Buffer size for the type of pedigree. Must
// hold largest pedigree record type string.
#define PEDIGREE_BUFF_SIZE 512 // Buffer size for the string representation
// of a pedigree.
/**
* Data we store for a replay log entry
*/
typedef struct replay_entry_t
{
uint64_t *m_reverse_pedigree; /**< Reverse pedigree for replay log entry */
ped_type_t m_type; /**< Type of replay log entry */
int16_t m_pedigree_len; /**< Number of terms in reverse pedigree */
int16_t m_value; /**< Victim for STEALs, 0 if matching steal found for ORPHANs */
/**
* Load data read from the log into the entry
*/
bool load(const char *type, const char *pedigee_str, int32_t value1, int32_t value2)
{
// Convert the type into an enum
if (0 == strcmp(type, PED_TYPE_STR_STEAL))
{
m_type = ped_type_steal;
m_value = (int16_t)value1; // Victim
}
else
{
m_value = -1; // Victim not valid
if (0 == strcmp(type, PED_TYPE_STR_SYNC))
m_type = ped_type_sync;
else if (0 == strcmp(type, PED_TYPE_STR_ORPHANED))
m_type = ped_type_orphaned;
else
{
m_type = ped_type_unknown;
return false;
}
}
// Parse the pedigree
m_pedigree_len = 0;
const char *p = pedigee_str;
char *end;
uint64_t temp_pedigree[PEDIGREE_BUFF_SIZE/2];
while(1)
{
temp_pedigree[m_pedigree_len++] = (uint64_t)strtol(p, &end, 10);
if ('\0' == *end)
break;
p = end + 1;
}
// Allocate memory to hold the pedigree.
// Copy the pedigree in reverse order since that's the order we'll
// traverse it
m_reverse_pedigree =
(uint64_t *)__cilkrts_malloc(sizeof(int64_t) * m_pedigree_len);
for (int n = 0; n < m_pedigree_len; n++)
m_reverse_pedigree[n] = temp_pedigree[(m_pedigree_len - 1) - n];
return true;
}
/**
* Match this entry against the data supplied. This includes walking the
* pedigree from the specified node.
*/
bool match (ped_type_t type, const __cilkrts_pedigree *node, int victim = -1)
{
int i = 0;
// If the type isn't what they're seeking, we don't have a match
if (type != m_type)
return false;
// If we're looking for a STEAL, then the victim must match
if ((type == ped_type_steal) && (victim != m_value))
return false;
// Compare the current pedigree against what was recorded
while ((NULL != node) && (i < m_pedigree_len))
{
// If we've got a pedigree rank difference, then we don't have
// a match
if (node->rank != m_reverse_pedigree[i])
return false;
node = node->parent;
i++;
}
// Make sure we exhausted both the pedigree chain and the recorded
// pedigree
return ((NULL == node) && (i == m_pedigree_len));
}
/**
* Advance to the next entry, skipping any ORPHANED records we didn't see
* a matching STEAL for
*/
replay_entry_t *next_entry()
{
replay_entry_t *entry = this;
// You can't go beyond the end
if (ped_type_last == entry->m_type)
return entry;
// Advance to the next entry
entry++;
// Skip any ORPHANED records that don't have a matching steal. We
// initialized the value field to -1 for ORPHANED. After loading all
// the log data, we iterated through all the STEAL records setting the
// matching ORPHANED record's value field to 0. So if an ORPHANED
// record's value field is still -1, it doesn't have a matching STEAL
// record, and I don't know why we chose not to return from the
// spawned function.
while ((ped_type_orphaned == entry->m_type) && (-1 == entry->m_value))
{
entry++;
}
return entry;
}
/**
* Release any allocated resources
*/
void unload()
{
__cilkrts_free(m_reverse_pedigree);
m_reverse_pedigree = NULL;
}
} replay_entry_t;
__CILKRTS_BEGIN_EXTERN_C
/**
* Walk the pedigree and generate a string representation with underscores
* between terms. Currently does a recursive walk to generate a forward
* pedigree.
*
* @param p The buffer that is to be filled. Assumed to be PEDIGREE_BUFF_SIZE
* characters long
* @param pnode The initial pedigree term to be written.
*
* @return A pointer into the pedigree string buffer after a term has been
* written.
*/
static
char * walk_pedigree_nodes(char *p, const __cilkrts_pedigree *pnode)
{
CILK_ASSERT(pnode);
if (pnode->parent)
{
p = walk_pedigree_nodes(p, pnode->parent);
p += cilk_snprintf_s(p, PEDIGREE_BUFF_SIZE, "%s", (char *)"_");
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}
return p + cilk_snprintf_l(p, PEDIGREE_BUFF_SIZE, "%" PRIu64, pnode->rank);
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}
/**
* Write a record to a replay log file.
*
* @param w The worker we're writing the pedigree for.
* @param type The type of the pedigree record, as a string
* @param initial_node The initial pedigree node to be written, or NULL if
* there is no pedigree for this record type.
* @param i1 First integer value to be written to the record.
* @param i2 Second integer value to be written to the record. Only applies
* to STEAL records. Defaults to -1 (unused). The second value is always
* written to make parsing easier.
*/
static
void write_to_replay_log (__cilkrts_worker *w, const char *type,
const __cilkrts_pedigree *initial_node,
int i1 = -1, int i2 = -1)
{
char pedigree[PEDIGREE_BUFF_SIZE];
// If we don't have an initial pedigree node, just use "0" to fill the slot
if (NULL == initial_node)
cilk_strcpy_s(pedigree, PEDIGREE_BUFF_SIZE, "0");
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else
walk_pedigree_nodes(pedigree, initial_node);
#ifndef INCLUDE_SEQUENCE_NUMBER
// Simply write the record
fprintf(w->l->record_replay_fptr, "%s %s %d %d\n",
type, pedigree, i1, i2);
#else
// Write the record with a sequence number. The sequence number should
// always be the last term, and ignored on read
static long volatile seq_num = 0;
long write_num;
// Atomic increment functions are compiler/OS-specific
#ifdef _WIN32
write_num = _InterlockedIncrement(&seq_num);
#else /* GCC */
write_num = __sync_add_and_fetch(&seq_num, 1);
#endif // _WIN32
fprintf(w->l->record_replay_fptr, "%s %s %d %d %ld\n",
type, pedigree, i1, i2, write_num);
#endif // INCLUDE_SEQUENCE_NUMBER
fflush(w->l->record_replay_fptr);
}
/**
* Record data for a successful steal.
*
* The pedigree for a STEAL record is the pedigree of the stolen frame.
*
* @note It's assumed that replay_record_steal() has already checked that we're
* recording a log and that the record/replay functionality has not been
* compiled out.
*
* @param w The worker stealing a frame.
* @param victim_id The ID of the worker which had it's frame stolen.
*/
void replay_record_steal_internal(__cilkrts_worker *w, int32_t victim_id)
{
// Follow the pedigree chain using worker's stack frame
CILK_ASSERT(w->l->next_frame_ff);
CILK_ASSERT(w->l->next_frame_ff->call_stack);
// Record steal: STEAL pedigree victim_id thief_id
write_to_replay_log (w, PED_TYPE_STR_STEAL,
&(w->l->next_frame_ff->call_stack->parent_pedigree),
victim_id);
}
/**
* Record data for the worker that continues from a sync
*
* The pedigree for a SYNC record is the pedigree at the sync.
*
* @note It's assumed that replay_record_sync() has already checked that we're
* recording a log and that the record/replay functionality has not been
* compiled out.
*
* @param w The worker continuing from a sync.
*/
void replay_record_sync_internal(__cilkrts_worker *w)
{
// Record sync: SYNC pedigree last_worker_id
write_to_replay_log (w, PED_TYPE_STR_SYNC, &w->pedigree);
}
/**
* Record the pedigree of an attempt to return to a stolen parent
*
* The pedigree for an ORPHANED record is the pedigree of our parent
*
* @note It's assumed that replay_record_orphaned() has already checked that
* we're recording a log and that the record/replay functionality has not
* been compiled out.
*
* @param w The worker continuing noting that it has been orphaned.
*/
void replay_record_orphaned_internal(__cilkrts_worker *w)
{
// Record steal: ORPHANED pedigree self
write_to_replay_log (w, PED_TYPE_STR_ORPHANED, w->pedigree.parent);
}
/**
* Attempt to match a SYNC record. We have a match when this worker was
* recorded returning from the current call to __cilkrts_sync() with the
* same pedigree and this was the worker that continued from the sync, since
* it was the last to sync.
*
* If we find a match, the caller is expected to stall it is the last worker
* to reach a sync so it will be the worker to continue from the sync.
*
* @note It's assumed that replay_match_sync_pedigree() has already returned
* if we're not replaying a log, or if record/replay functionality has
* been compiled out.
*
* @param w The worker we're checking to see if we've got a match
*/
int replay_match_sync_pedigree_internal(__cilkrts_worker *w)
{
// Return true if we have a match
if (w->l->replay_list_entry->match(ped_type_sync, &w->pedigree))
return 1;
else
return 0;
}
/**
* Advance to the next log entry from a SYNC record. Consume the current
* SYNC record on this worker and advance to the next one.
*
* @note It's assumed that replay_advance_from_sync() has already returned if
* we're not replaying a log, or if record/replay functionality has been
* compiled out.
*
* @param w The worker whose replay log we're advancing.
*/
void replay_advance_from_sync_internal (__cilkrts_worker *w)
{
// The current replay entry must be a SYNC
CILK_ASSERT(ped_type_sync == w->l->replay_list_entry->m_type);
// Advance to the next entry
w->l->replay_list_entry = w->l->replay_list_entry->next_entry();
}
/**
* Called from random_steal() to override the ID of the randomly chosen victim
* worker which this worker will attempt to steal from. Returns the worker id
* of the next victim this worker was recorded stealing from, or -1 if the
* next record in the log is not a STEAL.
*
* @note This call does NOT attempt to match the pedigree. That will be done
* by replay_match_victim_pedigree() after random_steal() has locked the victim
* worker.
*
* @param w The __cilkrts_worker we're executing on. The worker's replay log
* is checked for a STEAL record. If we've got one, the stolen worker ID is
* returned.
*
* @return -1 if the next record is not a STEAL
* @return recorded stolen worker ID if we've got a matching STEAL record
*/
int replay_get_next_recorded_victim_internal(__cilkrts_worker *w)
{
// If the next record isn't a STEAL, abort the attempt to steal work
if (ped_type_steal != w->l->replay_list_entry->m_type)
return -1;
// Return the victim's worker ID from the STEAL record. We'll check
// the pedigree after random_steal has locked the victim worker.
return w->l->replay_list_entry->m_value;
}
/**
* Called from random_steal() to determine if we have a STEAL record that
* matches the pedigree at the head of the victim worker. If we do have a
* match, the STEAL record is consumed.
*
* @note It's assumed that replay_match_victim_pedigree() has already returned if
* we're not replaying a log, or if record/replay functionality has been
* compiled out.
*
* @return 1 if we have a match
* @return 0 if the current replay record isn't a STEAL record, or the victim
* isn't correct, or the pedigree doesn't match.
*/
int replay_match_victim_pedigree_internal(__cilkrts_worker *w, __cilkrts_worker *victim)
{
// If we don't have a match, return 0
if (! w->l->replay_list_entry->match(ped_type_steal,
&((*victim->head)->parent_pedigree),
victim->self))
return 0;
// Consume this entry
w->l->replay_list_entry = w->l->replay_list_entry->next_entry();
// Return success
return 1;
}
/**
* If the frame we're about to return to was recorded as being stolen,
* stall until it is.
*
* @note It's assumed that replay_wait_for_steal_if_parent_was_stolen() has
* already returned if we're not replaying a log, or if record/replay
* functionality has been compiled out.
*
* @param w The worker we're executing on.
*/
void replay_wait_for_steal_if_parent_was_stolen_internal(__cilkrts_worker *w)
{
// If our parent wasn't recorded orphanen, return now
if (! w->l->replay_list_entry->match (ped_type_orphaned,
w->pedigree.parent))
return;
// Stall until our parent is stolen. Note that we're comparing head
// and tail, not head and exc. The steal is not completed until tail
// is modified.
while (!((w->tail - 1) < w->head))
__cilkrts_sleep();
// Consume the entry
w->l->replay_list_entry = w->l->replay_list_entry->next_entry();
}
/**
* Allocate memory for the list of logged events.
*
* This function will read through the file and count the number of records
* so it can estimate how big a buffer to allocate for the array or replay
* entries. It will then rewind the file to the beginning so it can be
* loaded into memory.
*
* @param w The worker we're loading the file for.
* @param f The file of replay data we're scanning.
*/
static
void allocate_replay_list(__cilkrts_worker *w, FILE *f)
{
// Count the number of entries - yeah, it's a hack, but it lets me
// allocate the space all at once instead of in chunks
char buf[1024];
int entries = 1; // Include "LAST" node
while (! feof(f))
{
if (fgets(buf, 1024, f))
{
// Skip the Workers record - should only be in file for Worker 0
if (0 != strncmp(PED_TYPE_STR_WORKERS, buf, sizeof(PED_TYPE_STR_WORKERS)-1))
entries++;
}
}
w->l->replay_list_root =
(replay_entry_t *)__cilkrts_malloc(entries * sizeof(replay_entry_t));
w->l->replay_list_root[entries - 1].m_type = ped_type_last;
// Reset the file to the beginning
rewind(f);
}
/**
* Load the replay log for a worker into memory.
*
* @param w The worker we're loading the replay for.
*/
static
void load_recorded_log(__cilkrts_worker *w)
{
char ped_type[PED_TYPE_SIZE];
char ped_str[PEDIGREE_BUFF_SIZE];
int32_t i1 = -1, i2 = -1;
int fret;
char local_replay_file_name[512];
FILE *f;
// Open the log for reading
cilk_snprintf_si(local_replay_file_name, sizeof(local_replay_file_name),
"%s%d.cilklog", w->g->record_replay_file_name, w->self);
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f = fopen(local_replay_file_name, "r");
// Make sure we found a log!
CILK_ASSERT (NULL != f);
// Initialize the replay_list
allocate_replay_list(w, f);
replay_entry_t *entry = w->l->replay_list_root;
// Read the data out and add it to our tables
while (! feof(f))
{
#ifndef INCLUDE_SEQUENCE_NUMBER
fret = fscanf(f, "%s %s %d %d\n", ped_type, ped_str, &i1, &i2);
if(EOF == fret)
break;
// We must have read 4 fields
CILK_ASSERT(4 == fret);
#else
int32_t write_num;
fret = fscanf(f, "%s %s %d %d %d\n", ped_type, ped_str,
&i1, &i2, &write_num);
if(EOF == fret)
break;
// We must have read 5 fields
CILK_ASSERT(5 == fret);
#endif // INCLUDE_SEQUENCE_NUMBER
// Load the data into the entry
if (0 == strcmp(ped_type, PED_TYPE_STR_WORKERS))
{
// Verify we're replaying with the same number of workers we recorded with
if (i1 != w->g->P)
{
// Fatal error - does not return
cilkos_error("Cannot continue replay: number of workers(%d) doesn't match "
"that from the recording(%d).\n", w->g->P, i1);
}
// Verify that we understand this version of the pedigree file
if (PED_VERSION != i2)
{
// Fatal error - does not return
cilkos_error("Pedigree file version %d doesn't match current "
"version %d - cannot continue.\n",
i2, PED_VERSION);
}
}
else
{
entry->load(ped_type, ped_str, i1, i2);
entry++;
}
}
// Make sure we've filled the allocated memory. We initialized the last
// entry in
CILK_ASSERT(ped_type_last == entry->m_type);
w->l->replay_list_entry = w->l->replay_list_root;
// Close the log and return
fclose(f);
}
/**
* Scan a recorded log to match STEALs againsted ORPHANED records.
*
* @param g Cilk Runtime global state. Passed to access the worker array so
* we can scan a worker's ORPHANED entries for one that matches a STEAL entry.
* @param entry The root of a replay_list for a worker.
*/
static
void scan_for_matching_steals(global_state_t *g, replay_entry_t *entry)
{
// Iterate over all of the entries
while (ped_type_last != entry->m_type)
{
// Look for STEALs. That will tell us which worker the frame was
// stolen from
if (ped_type_steal == entry->m_type)
{
bool found = false;
// Validate the worker ID and make sure we've got a list
CILK_ASSERT((entry->m_value >= 0) && (entry->m_value < g->total_workers));
replay_entry_t *victim_entry = g->workers[entry->m_value]->l->replay_list_root;
CILK_ASSERT(NULL != victim_entry);
// Scan the victim's list for the matching ORPHANED record
while ((ped_type_last != victim_entry->m_type) && ! found)
{
if (ped_type_orphaned == victim_entry->m_type)
{
if (entry->m_pedigree_len == victim_entry->m_pedigree_len)
{
if (0 == memcmp(entry->m_reverse_pedigree,
victim_entry->m_reverse_pedigree,
entry->m_pedigree_len * sizeof(int64_t)))
{
// Note that this ORPHANED record has a matching steal
victim_entry->m_value = 0;
found = true;
}
}
}
victim_entry++;
}
}
entry++;
}
}
/*
* Initialize per-worker data for record or replay - See record-replay.h
* for full routine header.
*/
void replay_init_workers(global_state_t *g)
{
int i;
char worker_file_name[512];
// If we're not recording or replaying a log, we're done. All of the
// fields in the global_state_t or local_state_t are already initialized
// to default values.
if (RECORD_REPLAY_NONE == g->record_or_replay)
return;
// If we're replaying a log, read each worker's log and construct the
// in-memory log
if (REPLAY_LOG == g->record_or_replay)
{
// Read all of the data
for (i = 0; i < g->total_workers; ++i)
{
// This function will also initialize and fill the worker's
// replay list
load_recorded_log(g->workers[i]);
}
// Scan for orphans with no matching steal. Mark them so they'll be
// skipped as we advance through the log.
for (i = 0; i < g->total_workers; ++i)
{
scan_for_matching_steals(g, g->workers[i]->l->replay_list_root);
}
// If we're recording the logs while replaying, create the log files.
// This will only be used for debugging. Create the logs in the
// current directory. It should be as good a place as any...
#if RECORD_ON_REPLAY
for(i = 0; i < g->total_workers; ++i)
{
__cilkrts_worker *w = g->workers[i];
cilk_snprintf_i(worker_file_name, sizeof(worker_file_name),
"replay_log_%d.cilklog", w->self);
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w->l->record_replay_fptr = fopen(worker_file_name, "w+");
CILK_ASSERT(NULL != w->l->record_replay_fptr);
}
// Record the number of workers, file version in Worker 0's file
write_to_replay_log (g->workers[0], PED_TYPE_STR_WORKERS, NULL, g->P, PED_VERSION);
#endif // RECORD_ON_REPLAY
}
// If we're recording, create the log files
if (RECORD_LOG == g->record_or_replay)
{
for(i = 0; i < g->total_workers; ++i)
{
__cilkrts_worker *w = g->workers[i];
cilk_snprintf_si(worker_file_name, sizeof(worker_file_name),
"%s%d.cilklog", g->record_replay_file_name, w->self);
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w->l->record_replay_fptr = fopen(worker_file_name, "w+");
CILK_ASSERT(NULL != w->l->record_replay_fptr);
}
// Record the number of workers, file version in Worker 0's file
write_to_replay_log (g->workers[0], PED_TYPE_STR_WORKERS, NULL, g->P, PED_VERSION);
}
}
/*
* Do any necessary cleanup for the logs - See record-replay.h for full
* routine header.
*/
void replay_term(global_state_t *g)
{
// Free memory for the record/replay log file name, if we've got one
if (g->record_replay_file_name)
__cilkrts_free(g->record_replay_file_name);
// Per-worker cleanup
for(int i = 0; i < g->total_workers; ++i)
{
__cilkrts_worker *w = g->workers[i];
// Close the log files, if we've opened them
if(w->l->record_replay_fptr)
fclose(w->l->record_replay_fptr);
if (w->l->replay_list_root)
{
// We should have consumed the entire list
CILK_ASSERT(ped_type_last == w->l->replay_list_entry->m_type);
replay_entry_t *entry = w->l->replay_list_root;
while (ped_type_last != entry->m_type)
{
// Free the pedigree memory for each entry
entry->unload();
entry++;
}
__cilkrts_free(w->l->replay_list_root);
w->l->replay_list_root = NULL;
w->l->replay_list_entry = NULL;
}
}
}
__CILKRTS_END_EXTERN_C