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path: root/rts/ProfHeap.c
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/* ----------------------------------------------------------------------------
 *
 * (c) The GHC Team, 1998-2003
 *
 * Support for heap profiling
 *
 * --------------------------------------------------------------------------*/

#include "PosixSource.h"
#include "Rts.h"

#include "Capability.h"
#include "RtsFlags.h"
#include "RtsUtils.h"
#include "Profiling.h"
#include "ProfHeap.h"
#include "Stats.h"
#include "Hash.h"
#include "RetainerProfile.h"
#include "LdvProfile.h"
#include "Arena.h"
#include "Printer.h"
#include "Trace.h"
#include "sm/GCThread.h"

#include <fs_rts.h>
#include <string.h>

/* -----------------------------------------------------------------------------
 * era stores the current time period.  It is the same as the
 * number of censuses that have been performed.
 *
 * RESTRICTION:
 *   era must be no longer than LDV_SHIFT (15 or 30) bits.
 * Invariants:
 *   era is initialized to 1 in initHeapProfiling().
 *
 * max_era is initialized to 2^LDV_SHIFT in initHeapProfiling().
 * When era reaches max_era, the profiling stops because a closure can
 * store only up to (max_era - 1) as its creation or last use time.
 * -------------------------------------------------------------------------- */
unsigned int era;
static uint32_t max_era;

/* -----------------------------------------------------------------------------
 * Counters
 *
 * For most heap profiles each closure identity gets a simple count
 * of live words in the heap at each census.  However, if we're
 * selecting by biography, then we have to keep the various
 * lag/drag/void counters for each identity.
 * -------------------------------------------------------------------------- */
typedef struct _counter {
    const void *identity;
    union {
        ssize_t resid;
        struct {
            // Total sizes of:
            ssize_t prim;     // 'inherently used' closures
            ssize_t not_used; // 'never used' closures
            ssize_t used;     // 'used at least once' closures
            ssize_t void_total;  // 'destroyed without being used' closures
            ssize_t drag_total;  // 'used at least once and waiting to die'
        } ldv;
    } c;
    struct _counter *next;
} counter;

STATIC_INLINE void
initLDVCtr( counter *ctr )
{
    ctr->c.ldv.prim = 0;
    ctr->c.ldv.not_used = 0;
    ctr->c.ldv.used = 0;
    ctr->c.ldv.void_total = 0;
    ctr->c.ldv.drag_total = 0;
}

typedef struct {
    double      time;    // the time in MUT time when the census is made
    HashTable * hash;
    counter   * ctrs;
    Arena     * arena;

    // for LDV profiling, when just displaying by LDV
    ssize_t    prim;
    ssize_t    not_used;
    ssize_t    used;
    ssize_t    void_total;
    ssize_t    drag_total;
} Census;

static Census *censuses = NULL;
static uint32_t n_censuses = 0;

#if defined(PROFILING)
static void aggregateCensusInfo( void );
#endif

static void dumpCensus( Census *census );

static bool closureSatisfiesConstraints( const StgClosure* p );

/* ----------------------------------------------------------------------------
 * Find the "closure identity", which is a unique pointer representing
 * the band to which this closure's heap space is attributed in the
 * heap profile.
 * ------------------------------------------------------------------------- */
static const void *
closureIdentity( const StgClosure *p )
{
    switch (RtsFlags.ProfFlags.doHeapProfile) {

#if defined(PROFILING)
    case HEAP_BY_CCS:
        return p->header.prof.ccs;
    case HEAP_BY_MOD:
        return p->header.prof.ccs->cc->module;
    case HEAP_BY_DESCR:
        return GET_PROF_DESC(get_itbl(p));
    case HEAP_BY_TYPE:
        return GET_PROF_TYPE(get_itbl(p));
    case HEAP_BY_RETAINER:
        // AFAIK, the only closures in the heap which might not have a
        // valid retainer set are DEAD_WEAK closures.
        if (isRetainerSetFieldValid(p))
            return retainerSetOf(p);
        else
            return NULL;
#endif

    case HEAP_BY_CLOSURE_TYPE:
    {
        const StgInfoTable *info;
        info = get_itbl(p);
        switch (info->type) {
        case CONSTR:
        case CONSTR_1_0:
        case CONSTR_0_1:
        case CONSTR_2_0:
        case CONSTR_1_1:
        case CONSTR_0_2:
        case CONSTR_NOCAF:
            return GET_CON_DESC(itbl_to_con_itbl(info));
        default:
            return closure_type_names[info->type];
        }
    }

    default:
        barf("closureIdentity");
    }
}

/* --------------------------------------------------------------------------
 * Profiling type predicates
 * ----------------------------------------------------------------------- */
#if defined(PROFILING)
STATIC_INLINE bool
doingLDVProfiling( void )
{
    return (RtsFlags.ProfFlags.doHeapProfile == HEAP_BY_LDV
            || RtsFlags.ProfFlags.bioSelector != NULL);
}

bool
doingRetainerProfiling( void )
{
    return (RtsFlags.ProfFlags.doHeapProfile == HEAP_BY_RETAINER
            || RtsFlags.ProfFlags.retainerSelector != NULL);
}
#endif /* PROFILING */

// Processes a closure 'c' being destroyed whose size is 'size'.
// Make sure that LDV_recordDead() is not invoked on 'inherently used' closures
// such as TSO; they should not be involved in computing dragNew or voidNew.
//
// Even though era is checked in both LdvCensusForDead() and
// LdvCensusKillAll(), we still need to make sure that era is > 0 because
// LDV_recordDead() may be called from elsewhere in the runtime system. E.g.,
// when a thunk is replaced by an indirection object.

#if defined(PROFILING)
void
LDV_recordDead( const StgClosure *c, uint32_t size )
{
    const void *id;
    uint32_t t;
    counter *ctr;

    if (era > 0 && closureSatisfiesConstraints(c)) {
        size -= sizeofW(StgProfHeader);
        ASSERT(LDVW(c) != 0);
        if ((LDVW((c)) & LDV_STATE_MASK) == LDV_STATE_CREATE) {
            t = (LDVW((c)) & LDV_CREATE_MASK) >> LDV_SHIFT;
            if (t < era) {
                if (RtsFlags.ProfFlags.bioSelector == NULL) {
                    censuses[t].void_total   += size;
                    censuses[era].void_total -= size;
                    ASSERT(censuses[t].void_total < censuses[t].not_used);
                } else {
                    id = closureIdentity(c);
                    ctr = lookupHashTable(censuses[t].hash, (StgWord)id);
                    if (ctr == NULL)
                        barf("LDV_recordDead: Failed to find counter for closure %p", c);

                    ctr->c.ldv.void_total += size;
                    ctr = lookupHashTable(censuses[era].hash, (StgWord)id);
                    if (ctr == NULL) {
                        ctr = arenaAlloc(censuses[era].arena, sizeof(counter));
                        initLDVCtr(ctr);
                        insertHashTable(censuses[era].hash, (StgWord)id, ctr);
                        ctr->identity = id;
                        ctr->next = censuses[era].ctrs;
                        censuses[era].ctrs = ctr;
                    }
                    ctr->c.ldv.void_total -= size;
                }
            }
        } else {
            t = LDVW((c)) & LDV_LAST_MASK;
            if (t + 1 < era) {
                if (RtsFlags.ProfFlags.bioSelector == NULL) {
                    censuses[t+1].drag_total += size;
                    censuses[era].drag_total -= size;
                } else {
                    const void *id;
                    id = closureIdentity(c);
                    ctr = lookupHashTable(censuses[t+1].hash, (StgWord)id);
                    ASSERT( ctr != NULL );
                    ctr->c.ldv.drag_total += size;
                    ctr = lookupHashTable(censuses[era].hash, (StgWord)id);
                    if (ctr == NULL) {
                        ctr = arenaAlloc(censuses[era].arena, sizeof(counter));
                        initLDVCtr(ctr);
                        insertHashTable(censuses[era].hash, (StgWord)id, ctr);
                        ctr->identity = id;
                        ctr->next = censuses[era].ctrs;
                        censuses[era].ctrs = ctr;
                    }
                    ctr->c.ldv.drag_total -= size;
                }
            }
        }
    }
}
#endif

/* --------------------------------------------------------------------------
 * Initialize censuses[era];
 * ----------------------------------------------------------------------- */

STATIC_INLINE void
initEra(Census *census)
{
    census->hash  = allocHashTable();
    census->ctrs  = NULL;
    census->arena = newArena();

    census->not_used   = 0;
    census->used       = 0;
    census->prim       = 0;
    census->void_total = 0;
    census->drag_total = 0;
}

STATIC_INLINE void
freeEra(Census *census)
{
    arenaFree(census->arena);
    freeHashTable(census->hash, NULL);
}

/* --------------------------------------------------------------------------
 * Increases era by 1 and initialize census[era].
 * Reallocates gi[] and increases its size if needed.
 * ----------------------------------------------------------------------- */

static void
nextEra( void )
{
#if defined(PROFILING)
    if (doingLDVProfiling()) {
        era++;

        if (era == max_era) {
            errorBelch("Maximum number of censuses reached.");
            if (rtsConfig.rts_opts_suggestions == true) {
                if (rtsConfig.rts_opts_enabled == RtsOptsAll)  {
                    errorBelch("Use `+RTS -i' to reduce censuses.");
                } else  {
                    errorBelch("Relink with -rtsopts and "
                               "use `+RTS -i' to reduce censuses.");
                }
            }
            stg_exit(EXIT_FAILURE);
        }

        if (era == n_censuses) {
            n_censuses *= 2;
            censuses = stgReallocBytes(censuses, sizeof(Census) * n_censuses,
                                       "nextEra");
        }
    }
#endif /* PROFILING */

    initEra( &censuses[era] );
}

/* ----------------------------------------------------------------------------
 * Heap profiling by info table
 * ------------------------------------------------------------------------- */

#if !defined(PROFILING)
FILE *hp_file;
static char *hp_filename;

void freeProfiling (void)
{
}

void initProfiling (void)
{
    char *prog;

    prog = stgMallocBytes(strlen(prog_name) + 1, "initProfiling2");
    strcpy(prog, prog_name);
#if defined(mingw32_HOST_OS)
    // on Windows, drop the .exe suffix if there is one
    {
        char *suff;
        suff = strrchr(prog,'.');
        if (suff != NULL && !strcmp(suff,".exe")) {
            *suff = '\0';
        }
    }
#endif

  if (RtsFlags.ProfFlags.doHeapProfile) {
    /* Initialise the log file name */
    hp_filename = stgMallocBytes(strlen(prog) + 6, "hpFileName");
    sprintf(hp_filename, "%s.hp", prog);

    /* open the log file */
    if ((hp_file = __rts_fopen(hp_filename, "w")) == NULL) {
      debugBelch("Can't open profiling report file %s\n",
              hp_filename);
      RtsFlags.ProfFlags.doHeapProfile = 0;
      stgFree(prog);
      return;
    }
  }

  stgFree(prog);

  initHeapProfiling();
}

void endProfiling( void )
{
  endHeapProfiling();
}
#endif /* !PROFILING */

static void
printEscapedString(const char* string)
{
    for (const char* p = string; *p != '\0'; ++p) {
        if (*p == '\"') {
            // Escape every " as ""
            fputc('"', hp_file);
        }
        fputc(*p, hp_file);
    }
}

static void
printSample(bool beginSample, StgDouble sampleValue)
{
    fprintf(hp_file, "%s %f\n",
            (beginSample ? "BEGIN_SAMPLE" : "END_SAMPLE"),
            sampleValue);
    if (!beginSample) {
        fflush(hp_file);
    }
}

static void
dumpCostCentresToEventLog(void)
{
#if defined(PROFILING)
    CostCentre *cc, *next;
    for (cc = CC_LIST; cc != NULL; cc = next) {
        next = cc->link;
        traceHeapProfCostCentre(cc->ccID, cc->label, cc->module,
                                cc->srcloc, cc->is_caf);
    }
#endif
}

/* --------------------------------------------------------------------------
 * Initialize the heap profilier
 * ----------------------------------------------------------------------- */
uint32_t
initHeapProfiling(void)
{
    if (! RtsFlags.ProfFlags.doHeapProfile) {
        return 0;
    }

#if defined(PROFILING)
    if (doingLDVProfiling() && doingRetainerProfiling()) {
        errorBelch("cannot mix -hb and -hr");
        stg_exit(EXIT_FAILURE);
    }
#if defined(THREADED_RTS)
    // See #12019.
    if (doingLDVProfiling() && RtsFlags.ParFlags.nCapabilities > 1) {
        errorBelch("-hb cannot be used with multiple capabilities");
        stg_exit(EXIT_FAILURE);
    }
#endif
#endif

    // we only count eras if we're doing LDV profiling.  Otherwise era
    // is fixed at zero.
#if defined(PROFILING)
    if (doingLDVProfiling()) {
        era = 1;
    } else
#endif
    {
        era = 0;
    }

    // max_era = 2^LDV_SHIFT
    max_era = 1 << LDV_SHIFT;

    n_censuses = 32;
    censuses = stgMallocBytes(sizeof(Census) * n_censuses, "initHeapProfiling");

    initEra( &censuses[era] );

    /* initProfilingLogFile(); */
    fprintf(hp_file, "JOB \"");
    printEscapedString(prog_name);

#if defined(PROFILING)
    for (int i = 1; i < prog_argc; ++i) {
        fputc(' ', hp_file);
        printEscapedString(prog_argv[i]);
    }
    fprintf(hp_file, " +RTS");
    for (int i = 0; i < rts_argc; ++i) {
        fputc(' ', hp_file);
        printEscapedString(rts_argv[i]);
    }
#endif /* PROFILING */

    fprintf(hp_file, "\"\n" );

    fprintf(hp_file, "DATE \"%s\"\n", time_str());

    fprintf(hp_file, "SAMPLE_UNIT \"seconds\"\n");
    fprintf(hp_file, "VALUE_UNIT \"bytes\"\n");

    printSample(true, 0);
    printSample(false, 0);

#if defined(PROFILING)
    if (doingRetainerProfiling()) {
        initRetainerProfiling();
    }
#endif

    traceHeapProfBegin(0);
    dumpCostCentresToEventLog();

    return 0;
}

void
endHeapProfiling(void)
{
    StgDouble seconds;

    if (! RtsFlags.ProfFlags.doHeapProfile) {
        return;
    }

#if defined(PROFILING)
    if (doingRetainerProfiling()) {
        endRetainerProfiling();
    }
#endif

#if defined(PROFILING)
    if (doingLDVProfiling()) {
        uint32_t t;
        LdvCensusKillAll();
        aggregateCensusInfo();
        for (t = 1; t < era; t++) {
            dumpCensus( &censuses[t] );
        }
    }
#endif

#if defined(PROFILING)
    if (doingLDVProfiling()) {
        uint32_t t;
        if (RtsFlags.ProfFlags.bioSelector != NULL) {
            for (t = 1; t <= era; t++) {
                freeEra( &censuses[t] );
            }
        } else {
            freeEra( &censuses[era] );
        }
    } else {
        freeEra( &censuses[0] );
    }
#else
    freeEra( &censuses[0] );
#endif

    stgFree(censuses);

    seconds = mut_user_time();
    printSample(true, seconds);
    printSample(false, seconds);
    fclose(hp_file);
}



#if defined(PROFILING)
static size_t
buf_append(char *p, const char *q, char *end)
{
    int m;

    for (m = 0; p < end; p++, q++, m++) {
        *p = *q;
        if (*q == '\0') { break; }
    }
    return m;
}

static void
fprint_ccs(FILE *fp, CostCentreStack *ccs, uint32_t max_length)
{
    char buf[max_length+1], *p, *buf_end;

    // MAIN on its own gets printed as "MAIN", otherwise we ignore MAIN.
    if (ccs == CCS_MAIN) {
        fprintf(fp, "MAIN");
        return;
    }

    fprintf(fp, "(%" FMT_Int ")", ccs->ccsID);

    p = buf;
    buf_end = buf + max_length + 1;

    // keep printing components of the stack until we run out of space
    // in the buffer.  If we run out of space, end with "...".
    for (; ccs != NULL && ccs != CCS_MAIN; ccs = ccs->prevStack) {

        // CAF cost centres print as M.CAF, but we leave the module
        // name out of all the others to save space.
        if (!strcmp(ccs->cc->label,"CAF")) {
            p += buf_append(p, ccs->cc->module, buf_end);
            p += buf_append(p, ".CAF", buf_end);
        } else {
            p += buf_append(p, ccs->cc->label, buf_end);
            if (ccs->prevStack != NULL && ccs->prevStack != CCS_MAIN) {
                p += buf_append(p, "/", buf_end);
            }
        }

        if (p >= buf_end) {
            sprintf(buf+max_length-4, "...");
            break;
        }
    }
    fprintf(fp, "%s", buf);
}

bool
strMatchesSelector( const char* str, const char* sel )
{
   const char* p;
   // debugBelch("str_matches_selector %s %s\n", str, sel);
   while (1) {
       // Compare str against wherever we've got to in sel.
       p = str;
       while (*p != '\0' && *sel != ',' && *sel != '\0' && *p == *sel) {
           p++; sel++;
       }
       // Match if all of str used and have reached the end of a sel fragment.
       if (*p == '\0' && (*sel == ',' || *sel == '\0'))
           return true;

       // No match.  Advance sel to the start of the next elem.
       while (*sel != ',' && *sel != '\0') sel++;
       if (*sel == ',') sel++;

       /* Run out of sel ?? */
       if (*sel == '\0') return false;
   }
}

#endif /* PROFILING */

/* -----------------------------------------------------------------------------
 * Figure out whether a closure should be counted in this census, by
 * testing against all the specified constraints.
 * -------------------------------------------------------------------------- */
static bool
closureSatisfiesConstraints( const StgClosure* p )
{
#if !defined(PROFILING)
    (void)p;   /* keep gcc -Wall happy */
    return true;
#else
   bool b;

   // The CCS has a selected field to indicate whether this closure is
   // deselected by not being mentioned in the module, CC, or CCS
   // selectors.
   if (!p->header.prof.ccs->selected) {
       return false;
   }

   if (RtsFlags.ProfFlags.descrSelector) {
       b = strMatchesSelector( (GET_PROF_DESC(get_itbl((StgClosure *)p))),
                                 RtsFlags.ProfFlags.descrSelector );
       if (!b) return false;
   }
   if (RtsFlags.ProfFlags.typeSelector) {
       b = strMatchesSelector( (GET_PROF_TYPE(get_itbl((StgClosure *)p))),
                                RtsFlags.ProfFlags.typeSelector );
       if (!b) return false;
   }
   if (RtsFlags.ProfFlags.retainerSelector) {
       RetainerSet *rs;
       uint32_t i;
       // We must check that the retainer set is valid here.  One
       // reason it might not be valid is if this closure is a
       // a newly deceased weak pointer (i.e. a DEAD_WEAK), since
       // these aren't reached by the retainer profiler's traversal.
       if (isRetainerSetFieldValid((StgClosure *)p)) {
           rs = retainerSetOf((StgClosure *)p);
           if (rs != NULL) {
               for (i = 0; i < rs->num; i++) {
                   b = strMatchesSelector( rs->element[i]->cc->label,
                                           RtsFlags.ProfFlags.retainerSelector );
                   if (b) return true;
               }
           }
       }
       return false;
   }
   return true;
#endif /* PROFILING */
}

/* -----------------------------------------------------------------------------
 * Aggregate the heap census info for biographical profiling
 * -------------------------------------------------------------------------- */
#if defined(PROFILING)
static void
aggregateCensusInfo( void )
{
    HashTable *acc;
    uint32_t t;
    counter *c, *d, *ctrs;
    Arena *arena;

    if (!doingLDVProfiling()) return;

    // Aggregate the LDV counters when displaying by biography.
    if (RtsFlags.ProfFlags.doHeapProfile == HEAP_BY_LDV) {
        long void_total, drag_total;

        // Now we compute void_total and drag_total for each census
        // After the program has finished, the void_total field of
        // each census contains the count of words that were *created*
        // in this era and were eventually void.  Conversely, if a
        // void closure was destroyed in this era, it will be
        // represented by a negative count of words in void_total.
        //
        // To get the count of live words that are void at each
        // census, just propagate the void_total count forwards:

        void_total = 0;
        drag_total = 0;
        for (t = 1; t < era; t++) { // note: start at 1, not 0
            void_total += censuses[t].void_total;
            drag_total += censuses[t].drag_total;
            censuses[t].void_total = void_total;
            censuses[t].drag_total = drag_total;

            ASSERT( censuses[t].void_total <= censuses[t].not_used );
            // should be true because: void_total is the count of
            // live words that are void at this census, which *must*
            // be less than the number of live words that have not
            // been used yet.

            ASSERT( censuses[t].drag_total <= censuses[t].used );
            // similar reasoning as above.
        }

        return;
    }

    // otherwise... we're doing a heap profile that is restricted to
    // some combination of lag, drag, void or use.  We've kept all the
    // census info for all censuses so far, but we still need to
    // aggregate the counters forwards.

    arena = newArena();
    acc = allocHashTable();
    ctrs = NULL;

    for (t = 1; t < era; t++) {

        // first look through all the counters we're aggregating
        for (c = ctrs; c != NULL; c = c->next) {
            // if one of the totals is non-zero, then this closure
            // type must be present in the heap at this census time...
            d = lookupHashTable(censuses[t].hash, (StgWord)c->identity);

            if (d == NULL) {
                // if this closure identity isn't present in the
                // census for this time period, then our running
                // totals *must* be zero.
                ASSERT(c->c.ldv.void_total == 0 && c->c.ldv.drag_total == 0);

                // debugCCS(c->identity);
                // debugBelch(" census=%d void_total=%d drag_total=%d\n",
                //         t, c->c.ldv.void_total, c->c.ldv.drag_total);
            } else {
                d->c.ldv.void_total += c->c.ldv.void_total;
                d->c.ldv.drag_total += c->c.ldv.drag_total;
                c->c.ldv.void_total =  d->c.ldv.void_total;
                c->c.ldv.drag_total =  d->c.ldv.drag_total;

                ASSERT( c->c.ldv.void_total >= 0 );
                ASSERT( c->c.ldv.drag_total >= 0 );
            }
        }

        // now look through the counters in this census to find new ones
        for (c = censuses[t].ctrs; c != NULL; c = c->next) {
            d = lookupHashTable(acc, (StgWord)c->identity);
            if (d == NULL) {
                d = arenaAlloc( arena, sizeof(counter) );
                initLDVCtr(d);
                insertHashTable( acc, (StgWord)c->identity, d );
                d->identity = c->identity;
                d->next = ctrs;
                ctrs = d;
                d->c.ldv.void_total = c->c.ldv.void_total;
                d->c.ldv.drag_total = c->c.ldv.drag_total;
            }
            ASSERT( c->c.ldv.void_total >= 0 );
            ASSERT( c->c.ldv.drag_total >= 0 );
        }
    }

    freeHashTable(acc, NULL);
    arenaFree(arena);
}
#endif

/* -----------------------------------------------------------------------------
 * Print out the results of a heap census.
 * -------------------------------------------------------------------------- */
static void
dumpCensus( Census *census )
{
    counter *ctr;
    ssize_t count;

    printSample(true, census->time);
    traceHeapProfSampleBegin(era);

#if defined(PROFILING)
    /* change typecast to uint64_t to remove
     * print formatting warning. See #12636 */
    if (RtsFlags.ProfFlags.doHeapProfile == HEAP_BY_LDV) {
        fprintf(hp_file, "VOID\t%" FMT_Word64 "\n",
                (uint64_t)(census->void_total *
                                     sizeof(W_)));
        fprintf(hp_file, "LAG\t%" FMT_Word64 "\n",
                (uint64_t)((census->not_used - census->void_total) *
                                     sizeof(W_)));
        fprintf(hp_file, "USE\t%" FMT_Word64 "\n",
                (uint64_t)((census->used - census->drag_total) *
                                     sizeof(W_)));
        fprintf(hp_file, "INHERENT_USE\t%" FMT_Word64 "\n",
                (uint64_t)(census->prim * sizeof(W_)));
        fprintf(hp_file, "DRAG\t%" FMT_Word64 "\n",
                (uint64_t)(census->drag_total * sizeof(W_)));
        printSample(false, census->time);
        return;
    }
#endif

    for (ctr = census->ctrs; ctr != NULL; ctr = ctr->next) {

#if defined(PROFILING)
        if (RtsFlags.ProfFlags.bioSelector != NULL) {
            count = 0;
            if (strMatchesSelector("lag", RtsFlags.ProfFlags.bioSelector))
                count += ctr->c.ldv.not_used - ctr->c.ldv.void_total;
            if (strMatchesSelector("drag", RtsFlags.ProfFlags.bioSelector))
                count += ctr->c.ldv.drag_total;
            if (strMatchesSelector("void", RtsFlags.ProfFlags.bioSelector))
                count += ctr->c.ldv.void_total;
            if (strMatchesSelector("use", RtsFlags.ProfFlags.bioSelector))
                count += ctr->c.ldv.used - ctr->c.ldv.drag_total;
        } else
#endif
        {
            count = ctr->c.resid;
        }

        ASSERT( count >= 0 );

        if (count == 0) continue;

        switch (RtsFlags.ProfFlags.doHeapProfile) {
        case HEAP_BY_CLOSURE_TYPE:
            fprintf(hp_file, "%s", (char *)ctr->identity);
            traceHeapProfSampleString(0, (char *)ctr->identity,
                                      count * sizeof(W_));
            break;
        }

#if defined(PROFILING)
        switch (RtsFlags.ProfFlags.doHeapProfile) {
        case HEAP_BY_CCS:
            fprint_ccs(hp_file, (CostCentreStack *)ctr->identity,
                       RtsFlags.ProfFlags.ccsLength);
            traceHeapProfSampleCostCentre(0, (CostCentreStack *)ctr->identity,
                                          count * sizeof(W_));
            break;
        case HEAP_BY_MOD:
        case HEAP_BY_DESCR:
        case HEAP_BY_TYPE:
            fprintf(hp_file, "%s", (char *)ctr->identity);
            traceHeapProfSampleString(0, (char *)ctr->identity,
                                      count * sizeof(W_));
            break;
        case HEAP_BY_RETAINER:
        {
            RetainerSet *rs = (RetainerSet *)ctr->identity;

            // it might be the distinguished retainer set rs_MANY:
            if (rs == &rs_MANY) {
                fprintf(hp_file, "MANY");
                break;
            }

            // Mark this retainer set by negating its id, because it
            // has appeared in at least one census.  We print the
            // values of all such retainer sets into the log file at
            // the end.  A retainer set may exist but not feature in
            // any censuses if it arose as the intermediate retainer
            // set for some closure during retainer set calculation.
            if (rs->id > 0)
                rs->id = -(rs->id);

            // report in the unit of bytes: * sizeof(StgWord)
            printRetainerSetShort(hp_file, rs, RtsFlags.ProfFlags.ccsLength);
            break;
        }
        default:
            barf("dumpCensus; doHeapProfile");
        }
#endif

        fprintf(hp_file, "\t%" FMT_Word "\n", (W_)count * sizeof(W_));
    }

    traceHeapProfSampleEnd(era);
    printSample(false, census->time);
}


static void heapProfObject(Census *census, StgClosure *p, size_t size,
                           bool prim
#if !defined(PROFILING)
                           STG_UNUSED
#endif
                           )
{
    const void *identity;
    size_t real_size;
    counter *ctr;

            identity = NULL;

#if defined(PROFILING)
            // subtract the profiling overhead
            real_size = size - sizeofW(StgProfHeader);
#else
            real_size = size;
#endif

            if (closureSatisfiesConstraints((StgClosure*)p)) {
#if defined(PROFILING)
                if (RtsFlags.ProfFlags.doHeapProfile == HEAP_BY_LDV) {
                    if (prim)
                        census->prim += real_size;
                    else if ((LDVW(p) & LDV_STATE_MASK) == LDV_STATE_CREATE)
                        census->not_used += real_size;
                    else
                        census->used += real_size;
                } else
#endif
                {
                    identity = closureIdentity((StgClosure *)p);

                    if (identity != NULL) {
                        ctr = lookupHashTable(census->hash, (StgWord)identity);
                        if (ctr != NULL) {
#if defined(PROFILING)
                            if (RtsFlags.ProfFlags.bioSelector != NULL) {
                                if (prim)
                                    ctr->c.ldv.prim += real_size;
                                else if ((LDVW(p) & LDV_STATE_MASK) == LDV_STATE_CREATE)
                                    ctr->c.ldv.not_used += real_size;
                                else
                                    ctr->c.ldv.used += real_size;
                            } else
#endif
                            {
                                ctr->c.resid += real_size;
                            }
                        } else {
                            ctr = arenaAlloc( census->arena, sizeof(counter) );
                            initLDVCtr(ctr);
                            insertHashTable( census->hash, (StgWord)identity, ctr );
                            ctr->identity = identity;
                            ctr->next = census->ctrs;
                            census->ctrs = ctr;

#if defined(PROFILING)
                            if (RtsFlags.ProfFlags.bioSelector != NULL) {
                                if (prim)
                                    ctr->c.ldv.prim = real_size;
                                else if ((LDVW(p) & LDV_STATE_MASK) == LDV_STATE_CREATE)
                                    ctr->c.ldv.not_used = real_size;
                                else
                                    ctr->c.ldv.used = real_size;
                            } else
#endif
                            {
                                ctr->c.resid = real_size;
                            }
                        }
                    }
                }
            }
}

// Compact objects require special handling code because they
// are not stored consecutively in memory (rather, each object
// is a list of objects), and that would break the while loop
// below. But we know that each block holds at most one object
// so we don't need the loop.
//
// See Note [Compact Normal Forms] for details.
static void
heapCensusCompactList(Census *census, bdescr *bd)
{
    for (; bd != NULL; bd = bd->link) {
        StgCompactNFDataBlock *block = (StgCompactNFDataBlock*)bd->start;
        StgCompactNFData *str = block->owner;
        heapProfObject(census, (StgClosure*)str,
                       compact_nfdata_full_sizeW(str), true);
    }
}

/* -----------------------------------------------------------------------------
 * Code to perform a heap census.
 * -------------------------------------------------------------------------- */
static void
heapCensusChain( Census *census, bdescr *bd )
{
    StgPtr p;
    const StgInfoTable *info;
    size_t size;
    bool prim;

    for (; bd != NULL; bd = bd->link) {

        // HACK: pretend a pinned block is just one big ARR_WORDS
        // owned by CCS_PINNED.  These blocks can be full of holes due
        // to alignment constraints so we can't traverse the memory
        // and do a proper census.
        if (bd->flags & BF_PINNED) {
            StgClosure arr;
            SET_HDR(&arr, &stg_ARR_WORDS_info, CCS_PINNED);
            heapProfObject(census, &arr, bd->blocks * BLOCK_SIZE_W, true);
            continue;
        }

        p = bd->start;

        // When we shrink a large ARR_WORDS, we do not adjust the free pointer
        // of the associated block descriptor, thus introducing slop at the end
        // of the object.  This slop remains after GC, violating the assumption
        // of the loop below that all slop has been eliminated (#11627).
        // Consequently, we handle large ARR_WORDS objects as a special case.
        if (bd->flags & BF_LARGE
            && get_itbl((StgClosure *)p)->type == ARR_WORDS) {
            size = arr_words_sizeW((StgArrBytes *)p);
            prim = true;
            heapProfObject(census, (StgClosure *)p, size, prim);
            continue;
        }

        while (p < bd->free) {
            info = get_itbl((const StgClosure *)p);
            prim = false;

            switch (info->type) {

            case THUNK:
                size = thunk_sizeW_fromITBL(info);
                break;

            case THUNK_1_1:
            case THUNK_0_2:
            case THUNK_2_0:
                size = sizeofW(StgThunkHeader) + 2;
                break;

            case THUNK_1_0:
            case THUNK_0_1:
            case THUNK_SELECTOR:
                size = sizeofW(StgThunkHeader) + 1;
                break;

            case FUN:
            case BLACKHOLE:
            case BLOCKING_QUEUE:
            case FUN_1_0:
            case FUN_0_1:
            case FUN_1_1:
            case FUN_0_2:
            case FUN_2_0:
            case CONSTR:
            case CONSTR_NOCAF:
            case CONSTR_1_0:
            case CONSTR_0_1:
            case CONSTR_1_1:
            case CONSTR_0_2:
            case CONSTR_2_0:
                size = sizeW_fromITBL(info);
                break;

            case IND:
                // Special case/Delicate Hack: INDs don't normally
                // appear, since we're doing this heap census right
                // after GC.  However, GarbageCollect() also does
                // resurrectThreads(), which can update some
                // blackholes when it calls raiseAsync() on the
                // resurrected threads.  So we know that any IND will
                // be the size of a BLACKHOLE.
                size = BLACKHOLE_sizeW();
                break;

            case BCO:
                prim = true;
                size = bco_sizeW((StgBCO *)p);
                break;

            case MVAR_CLEAN:
            case MVAR_DIRTY:
            case TVAR:
            case WEAK:
            case PRIM:
            case MUT_PRIM:
            case MUT_VAR_CLEAN:
            case MUT_VAR_DIRTY:
                prim = true;
                size = sizeW_fromITBL(info);
                break;

            case AP:
                size = ap_sizeW((StgAP *)p);
                break;

            case PAP:
                size = pap_sizeW((StgPAP *)p);
                break;

            case AP_STACK:
                size = ap_stack_sizeW((StgAP_STACK *)p);
                break;

            case ARR_WORDS:
                prim = true;
                size = arr_words_sizeW((StgArrBytes*)p);
                break;

            case MUT_ARR_PTRS_CLEAN:
            case MUT_ARR_PTRS_DIRTY:
            case MUT_ARR_PTRS_FROZEN_CLEAN:
            case MUT_ARR_PTRS_FROZEN_DIRTY:
                prim = true;
                size = mut_arr_ptrs_sizeW((StgMutArrPtrs *)p);
                break;

            case SMALL_MUT_ARR_PTRS_CLEAN:
            case SMALL_MUT_ARR_PTRS_DIRTY:
            case SMALL_MUT_ARR_PTRS_FROZEN_CLEAN:
            case SMALL_MUT_ARR_PTRS_FROZEN_DIRTY:
                prim = true;
                size = small_mut_arr_ptrs_sizeW((StgSmallMutArrPtrs *)p);
                break;

            case TSO:
                prim = true;
#if defined(PROFILING)
                if (RtsFlags.ProfFlags.includeTSOs) {
                    size = sizeofW(StgTSO);
                    break;
                } else {
                    // Skip this TSO and move on to the next object
                    p += sizeofW(StgTSO);
                    continue;
                }
#else
                size = sizeofW(StgTSO);
                break;
#endif

            case STACK:
                prim = true;
#if defined(PROFILING)
                if (RtsFlags.ProfFlags.includeTSOs) {
                    size = stack_sizeW((StgStack*)p);
                    break;
                } else {
                    // Skip this TSO and move on to the next object
                    p += stack_sizeW((StgStack*)p);
                    continue;
                }
#else
                size = stack_sizeW((StgStack*)p);
                break;
#endif

            case TREC_CHUNK:
                prim = true;
                size = sizeofW(StgTRecChunk);
                break;

            case COMPACT_NFDATA:
                barf("heapCensus, found compact object in the wrong list");
                break;

            default:
                barf("heapCensus, unknown object: %d", info->type);
            }

            heapProfObject(census,(StgClosure*)p,size,prim);

            p += size;
        }
    }
}

void heapCensus (Time t)
{
  uint32_t g, n;
  Census *census;
  gen_workspace *ws;

  census = &censuses[era];
  census->time  = mut_user_time_until(t);

  // calculate retainer sets if necessary
#if defined(PROFILING)
  if (doingRetainerProfiling()) {
      retainerProfile();
  }
#endif

#if defined(PROFILING)
  stat_startHeapCensus();
#endif

  // Traverse the heap, collecting the census info
  for (g = 0; g < RtsFlags.GcFlags.generations; g++) {
      heapCensusChain( census, generations[g].blocks );
      // Are we interested in large objects?  might be
      // confusing to include the stack in a heap profile.
      heapCensusChain( census, generations[g].large_objects );
      heapCensusCompactList ( census, generations[g].compact_objects );

      for (n = 0; n < n_capabilities; n++) {
          ws = &gc_threads[n]->gens[g];
          heapCensusChain(census, ws->todo_bd);
          heapCensusChain(census, ws->part_list);
          heapCensusChain(census, ws->scavd_list);
      }
  }

  // dump out the census info
#if defined(PROFILING)
    // We can't generate any info for LDV profiling until
    // the end of the run...
    if (!doingLDVProfiling())
        dumpCensus( census );
#else
    dumpCensus( census );
#endif


  // free our storage, unless we're keeping all the census info for
  // future restriction by biography.
#if defined(PROFILING)
  if (RtsFlags.ProfFlags.bioSelector == NULL)
  {
      freeEra(census);
      census->hash = NULL;
      census->arena = NULL;
  }
#endif

  // we're into the next time period now
  nextEra();

#if defined(PROFILING)
  stat_endHeapCensus();
#endif
}