/*
* %CopyrightBegin%
*
* Copyright Ericsson AB 2012-2013. All Rights Reserved.
*
* The contents of this file are subject to the Erlang Public License,
* Version 1.1, (the "License"); you may not use this file except in
* compliance with the License. You should have received a copy of the
* Erlang Public License along with this software. If not, it can be
* retrieved online at http://www.erlang.org/.
*
* Software distributed under the License is distributed on an "AS IS"
* basis, WITHOUT WARRANTY OF ANY KIND, either express or implied. See
* the License for the specific language governing rights and limitations
* under the License.
*
* %CopyrightEnd%
*/
/*
* Description: Process/Port table implementation.
*
* Author: Rickard Green
*/
#ifdef HAVE_CONFIG_H
# include "config.h"
#endif
#define ERTS_PTAB_WANT_BIF_IMPL__
#define ERTS_PTAB_WANT_DEBUG_FUNCS__
#include "erl_ptab.h"
#include "global.h"
#include "erl_binary.h"
typedef struct ErtsPTabListBifData_ ErtsPTabListBifData;
#define ERTS_PTAB_NEW_MAX_RESERVE_FAIL 1000
#define ERTS_PTAB_LIST_BIF_TAB_INSPECT_INDICES_PER_RED 25
#define ERTS_PTAB_LIST_BIF_TAB_CHUNK_SIZE 1000
#define ERTS_PTAB_LIST_BIF_MIN_START_REDS \
(ERTS_PTAB_LIST_BIF_TAB_CHUNK_SIZE \
/ ERTS_PTAB_LIST_BIF_TAB_INSPECT_INDICES_PER_RED)
#define ERTS_PTAB_LIST_BIF_TAB_FREE_DELETED_REDS 1
#define ERTS_PTAB_LIST_BIF_INSPECT_DELETED_PER_RED 10
#define ERTS_PTAB_LIST_INSPECT_DELETED_MAX_REDS \
(ERTS_PTAB_LIST_BIF_TAB_CHUNK_SIZE \
/ ERTS_PTAB_LIST_BIF_TAB_INSPECT_INDICES_PER_RED)
#define ERTS_PTAB_LIST_BIF_BUILD_RESULT_CONSES_PER_RED 75
#define ERTS_PTAB_LIST_DBG_DO_TRACE 0
#ifdef DEBUG
# define ERTS_PTAB_LIST_BIF_DEBUGLEVEL 100
#else
# define ERTS_PTAB_LIST_BIF_DEBUGLEVEL 0
#endif
#define ERTS_PTAB_LIST_DBGLVL_CHK_HALLOC 1
#define ERTS_PTAB_LIST_DBGLVL_CHK_FOUND_PIDS 5
#define ERTS_PTAB_LIST_DBGLVL_CHK_PIDS 10
#define ERTS_PTAB_LIST_DBGLVL_CHK_DEL_LIST 20
#define ERTS_PTAB_LIST_DBGLVL_CHK_RESLIST 20
#if ERTS_PTAB_LIST_BIF_DEBUGLEVEL == 0
# define ERTS_PTAB_LIST_ASSERT(EXP)
#else
# define ERTS_PTAB_LIST_ASSERT(EXP) \
((void) ((EXP) \
? 1 \
: (debug_ptab_list_assert_error(#EXP, \
__FILE__, \
__LINE__, \
__func__), \
0)))
#endif
#if ERTS_PTAB_LIST_BIF_DEBUGLEVEL >= ERTS_PTAB_LIST_DBGLVL_CHK_HALLOC
# define ERTS_PTAB_LIST_DBG_SAVE_HEAP_ALLOC(PTLBDP, HP, SZ) \
do { \
ERTS_PTAB_LIST_ASSERT(!(PTLBDP)->debug.heap); \
ERTS_PTAB_LIST_ASSERT(!(PTLBDP)->debug.heap_size); \
(PTLBDP)->debug.heap = (HP); \
(PTLBDP)->debug.heap_size = (SZ); \
} while (0)
# define ERTS_PTAB_LIST_DBG_VERIFY_HEAP_ALLOC_USED(PTLBDP, HP) \
do { \
ERTS_PTAB_LIST_ASSERT((PTLBDP)->debug.heap); \
ERTS_PTAB_LIST_ASSERT((PTLBDP)->debug.heap_size); \
ERTS_PTAB_LIST_ASSERT(((PTLBDP)->debug.heap \
+ (PTLBDP)->debug.heap_size) \
== (HP)); \
(PTLBDP)->debug.heap = NULL; \
(PTLBDP)->debug.heap_size = 0; \
} while (0)
# define ERTS_PTAB_LIST_DBG_HEAP_ALLOC_INIT(PTLBDP) \
do { \
(PTLBDP)->debug.heap = NULL; \
(PTLBDP)->debug.heap_size = 0; \
} while (0)
#else
# define ERTS_PTAB_LIST_DBG_SAVE_HEAP_ALLOC(PTLBDP, HP, SZ)
# define ERTS_PTAB_LIST_DBG_VERIFY_HEAP_ALLOC_USED(PTLBDP, HP)
# define ERTS_PTAB_LIST_DBG_HEAP_ALLOC_INIT(PTLBDP)
#endif
#if ERTS_PTAB_LIST_BIF_DEBUGLEVEL >= ERTS_PTAB_LIST_DBGLVL_CHK_RESLIST
# define ERTS_PTAB_LIST_DBG_CHK_RESLIST(R) \
debug_ptab_list_check_res_list((R))
#else
# define ERTS_PTAB_LIST_DBG_CHK_RESLIST(R)
#endif
#if ERTS_PTAB_LIST_BIF_DEBUGLEVEL >= ERTS_PTAB_LIST_DBGLVL_CHK_PIDS
# define ERTS_PTAB_LIST_DBG_SAVE_PIDS(PTLBDP) \
debug_ptab_list_save_all_pids((PTLBDP))
# define ERTS_PTAB_LIST_DBG_VERIFY_PIDS(PTLBDP) \
do { \
if (!(PTLBDP)->debug.correct_pids_verified) \
debug_ptab_list_verify_all_pids((PTLBDP)); \
} while (0)
# define ERTS_PTAB_LIST_DBG_CLEANUP_CHK_PIDS(PTLBDP) \
do { \
if ((PTLBDP)->debug.correct_pids) { \
erts_free(ERTS_ALC_T_PTAB_LIST_PIDS, \
(PTLBDP)->debug.correct_pids); \
(PTLBDP)->debug.correct_pids = NULL; \
} \
} while(0)
# define ERTS_PTAB_LIST_DBG_CHK_PIDS_INIT(PTLBDP) \
do { \
(PTLBDP)->debug.correct_pids_verified = 0; \
(PTLBDP)->debug.correct_pids = NULL; \
} while (0)
#else
# define ERTS_PTAB_LIST_DBG_SAVE_PIDS(PTLBDP)
# define ERTS_PTAB_LIST_DBG_VERIFY_PIDS(PTLBDP)
# define ERTS_PTAB_LIST_DBG_CLEANUP_CHK_PIDS(PTLBDP)
# define ERTS_PTAB_LIST_DBG_CHK_PIDS_INIT(PTLBDP)
#endif
#if ERTS_PTAB_LIST_BIF_DEBUGLEVEL >= ERTS_PTAB_LIST_DBGLVL_CHK_FOUND_PIDS
# define ERTS_PTAB_LIST_DBG_CHK_PID_FOUND(PTLBDP, PID, IC) \
debug_ptab_list_check_found_pid((PTLBDP), (PID), (IC), 1)
# define ERTS_PTAB_LIST_DBG_CHK_PID_NOT_FOUND(PTLBDP, PID, IC) \
debug_ptab_list_check_found_pid((PTLBDP), (PID), (IC), 0)
#else
# define ERTS_PTAB_LIST_DBG_CHK_PID_FOUND(PTLBDP, PID, IC)
# define ERTS_PTAB_LIST_DBG_CHK_PID_NOT_FOUND(PTLBDP, PID, IC)
#endif
#if ERTS_PTAB_LIST_BIF_DEBUGLEVEL >= ERTS_PTAB_LIST_DBGLVL_CHK_DEL_LIST
# define ERTS_PTAB_LIST_DBG_CHK_DEL_LIST(PTab) \
debug_ptab_list_check_del_list((PTab))
# define ERTS_PTAB_LIST_DBG_CHK_FREELIST(PTab, FL) \
debug_ptab_list_check_del_free_list((PTab), (FL))
#else
# define ERTS_PTAB_LIST_DBG_CHK_DEL_LIST(PTab)
# define ERTS_PTAB_LIST_DBG_CHK_FREELIST(PTab, FL)
#endif
#if ERTS_PTAB_LIST_BIF_DEBUGLEVEL == 0
#if ERTS_PTAB_LIST_DBG_DO_TRACE
# define ERTS_PTAB_LIST_DBG_INIT(P, PTLBDP) \
(PTLBDP)->debug.caller = (P)->common.id
# else
# define ERTS_PTAB_LIST_DBG_INIT(P, PTLBDP)
# endif
# define ERTS_PTAB_LIST_DBG_CLEANUP(PTLBDP)
#else
# define ERTS_PTAB_LIST_DBG_INIT(P, PTLBDP) \
do { \
(PTLBDP)->debug.caller = (P)->common.id; \
ERTS_PTAB_LIST_DBG_HEAP_ALLOC_INIT((PTLBDP)); \
ERTS_PTAB_LIST_DBG_CHK_PIDS_INIT((PTLBDP)); \
} while (0)
# define ERTS_PTAB_LIST_DBG_CLEANUP(PTLBDP) \
do { \
ERTS_PTAB_LIST_DBG_CLEANUP_CHK_PIDS((PTLBDP)); \
} while (0)
#endif
#if ERTS_PTAB_LIST_DBG_DO_TRACE
# define ERTS_PTAB_LIST_DBG_TRACE(PID, WHAT) \
erts_fprintf(stderr, "%T %s:%d:%s(): %s\n", \
(PID), __FILE__, __LINE__, __func__, #WHAT)
#else
# define ERTS_PTAB_LIST_DBG_TRACE(PID, WHAT)
#endif
#if ERTS_PTAB_LIST_BIF_DEBUGLEVEL != 0
static void debug_ptab_list_assert_error(char* expr,
const char* file,
int line,
const char *func);
#endif
#if ERTS_PTAB_LIST_BIF_DEBUGLEVEL >= ERTS_PTAB_LIST_DBGLVL_CHK_RESLIST
static void debug_ptab_list_check_res_list(Eterm list);
#endif
#if ERTS_PTAB_LIST_BIF_DEBUGLEVEL >= ERTS_PTAB_LIST_DBGLVL_CHK_PIDS
static void debug_ptab_list_save_all_pids(ErtsPTabListBifData *ptlbdp);
static void debug_ptab_list_verify_all_pids(ErtsPTabListBifData *ptlbdp);
#endif
#if ERTS_PTAB_LIST_BIF_DEBUGLEVEL >= ERTS_PTAB_LIST_DBGLVL_CHK_FOUND_PIDS
static void debug_ptab_list_check_found_pid(ErtsPTabListBifData *ptlbdp,
Eterm pid,
Uint64 ic,
int pid_should_be_found);
#endif
#if ERTS_PTAB_LIST_BIF_DEBUGLEVEL >= ERTS_PTAB_LIST_DBGLVL_CHK_DEL_LIST
static void debug_ptab_list_check_del_list(ErtsPTab *ptab);
static void debug_ptab_list_check_del_free_list(ErtsPTab *ptab,
ErtsPTabDeletedElement *ptdep);
#endif
struct ErtsPTabDeletedElement_ {
ErtsPTabDeletedElement *next;
ErtsPTabDeletedElement *prev;
int ix;
union {
struct {
Eterm id;
Uint64 inserted;
Uint64 deleted;
} element;
struct {
Uint64 interval;
} bif_invocation;
} u;
};
static Export ptab_list_continue_export;
typedef struct {
Uint64 interval;
} ErtsPTabListBifChunkInfo;
typedef enum {
INITIALIZING,
INSPECTING_TABLE,
INSPECTING_DELETED,
BUILDING_RESULT,
RETURN_RESULT
} ErtsPTabListBifState;
struct ErtsPTabListBifData_ {
ErtsPTab *ptab;
ErtsPTabListBifState state;
Eterm caller;
ErtsPTabListBifChunkInfo *chunk;
int tix;
int pid_ix;
int pid_sz;
Eterm *pid;
ErtsPTabDeletedElement *bif_invocation; /* Only used when > 1 chunk */
#if ERTS_PTAB_LIST_BIF_DEBUGLEVEL != 0 || ERTS_PTAB_LIST_DBG_DO_TRACE
struct {
Eterm caller;
#if ERTS_PTAB_LIST_BIF_DEBUGLEVEL >= ERTS_PTAB_LIST_DBGLVL_CHK_FOUND_PIDS
Uint64 *pid_started;
#endif
#if ERTS_PTAB_LIST_BIF_DEBUGLEVEL >= ERTS_PTAB_LIST_DBGLVL_CHK_HALLOC
Eterm *heap;
Uint heap_size;
#endif
#if ERTS_PTAB_LIST_BIF_DEBUGLEVEL >= ERTS_PTAB_LIST_DBGLVL_CHK_PIDS
int correct_pids_verified;
Eterm *correct_pids;
#endif
} debug;
#endif
};
#ifdef ARCH_32
static ERTS_INLINE Uint64
dw_aint_to_uint64(erts_dw_aint_t *dw)
{
#ifdef ETHR_SU_DW_NAINT_T__
return (Uint64) dw->dw_sint;
#else
Uint64 res;
res = (Uint64) ((Uint32) dw->sint[ERTS_DW_AINT_HIGH_WORD]);
res <<= 32;
res |= (Uint64) ((Uint32) dw->sint[ERTS_DW_AINT_LOW_WORD]);
return res;
#endif
}
static void
unint64_to_dw_aint(erts_dw_aint_t *dw, Uint64 val)
{
#ifdef ETHR_SU_DW_NAINT_T__
dw->dw_sint = (ETHR_SU_DW_NAINT_T__) val;
#else
dw->sint[ERTS_DW_AINT_LOW_WORD] = (erts_aint_t) (val & 0xffffffff);
dw->sint[ERTS_DW_AINT_HIGH_WORD] = (erts_aint_t) ((val >> 32) & 0xffffffff);
#endif
}
static ERTS_INLINE void
last_data_init_nob(ErtsPTab *ptab, Uint64 val)
{
erts_dw_aint_t dw;
unint64_to_dw_aint(&dw, val);
erts_smp_dw_atomic_init_nob(&ptab->vola.tile.last_data, &dw);
}
static ERTS_INLINE void
last_data_set_relb(ErtsPTab *ptab, Uint64 val)
{
erts_dw_aint_t dw;
unint64_to_dw_aint(&dw, val);
erts_smp_dw_atomic_set_relb(&ptab->vola.tile.last_data, &dw);
}
static ERTS_INLINE Uint64
last_data_read_nob(ErtsPTab *ptab)
{
erts_dw_aint_t dw;
erts_smp_dw_atomic_read_nob(&ptab->vola.tile.last_data, &dw);
return dw_aint_to_uint64(&dw);
}
static ERTS_INLINE Uint64
last_data_read_acqb(ErtsPTab *ptab)
{
erts_dw_aint_t dw;
erts_smp_dw_atomic_read_acqb(&ptab->vola.tile.last_data, &dw);
return dw_aint_to_uint64(&dw);
}
static ERTS_INLINE Uint64
last_data_cmpxchg_relb(ErtsPTab *ptab, Uint64 new, Uint64 exp)
{
erts_dw_aint_t dw_new, dw_xchg;
unint64_to_dw_aint(&dw_new, new);
unint64_to_dw_aint(&dw_xchg, exp);
if (erts_smp_dw_atomic_cmpxchg_relb(&ptab->vola.tile.last_data,
&dw_new,
&dw_xchg))
return exp;
else
return dw_aint_to_uint64(&dw_xchg);
}
#elif defined(ARCH_64)
union {
erts_smp_atomic_t pid_data;
char align[ERTS_CACHE_LINE_SIZE];
} last erts_align_attribute(ERTS_CACHE_LINE_SIZE);
static ERTS_INLINE void
last_data_init_nob(ErtsPTab *ptab, Uint64 val)
{
erts_smp_atomic_init_nob(&ptab->vola.tile.last_data, (erts_aint_t) val);
}
static ERTS_INLINE void
last_data_set_relb(ErtsPTab *ptab, Uint64 val)
{
erts_smp_atomic_set_relb(&ptab->vola.tile.last_data, (erts_aint_t) val);
}
static ERTS_INLINE Uint64
last_data_read_nob(ErtsPTab *ptab)
{
return (Uint64) erts_smp_atomic_read_nob(&ptab->vola.tile.last_data);
}
static ERTS_INLINE Uint64
last_data_read_acqb(ErtsPTab *ptab)
{
return (Uint64) erts_smp_atomic_read_acqb(&ptab->vola.tile.last_data);
}
static ERTS_INLINE Uint64
last_data_cmpxchg_relb(ErtsPTab *ptab, Uint64 new, Uint64 exp)
{
return (Uint64) erts_smp_atomic_cmpxchg_relb(&ptab->vola.tile.last_data,
(erts_aint_t) new,
(erts_aint_t) exp);
}
#else
# error "Not 64-bit, nor 32-bit architecture..."
#endif
static ERTS_INLINE int
last_data_cmp(Uint64 ld1, Uint64 ld2)
{
Uint64 ld1_wrap;
if (ld1 == ld2)
return 0;
ld1_wrap = ld1 + (((Uint64) 1) << 63);
if (ld1 < ld1_wrap)
return (ld1 < ld2 && ld2 < ld1_wrap) ? -1 : 1;
else
return (ld1_wrap <= ld2 && ld2 < ld1) ? 1 : -1;
}
#define ERTS_PTAB_LastData2EtermData(LD) \
((Eterm) ((LD) & ~(~((Uint64) 0) << ERTS_PTAB_ID_DATA_SIZE)))
static ERTS_INLINE Uint32
ix_to_free_id_data_ix(ErtsPTab *ptab, Uint32 ix)
{
Uint32 dix;
dix = ((ix & ptab->r.o.dix_cl_mask) << ptab->r.o.dix_cl_shift);
dix += ((ix >> ptab->r.o.dix_cli_shift) & ptab->r.o.dix_cli_mask);
ASSERT(0 <= dix && dix < ptab->r.o.max);
return dix;
}
UWord
erts_ptab_mem_size(ErtsPTab *ptab)
{
UWord size = ptab->r.o.max*sizeof(erts_smp_atomic_t);
if (ptab->r.o.free_id_data)
size += ptab->r.o.max*sizeof(erts_smp_atomic32_t);
return size;
}
void
erts_ptab_init_table(ErtsPTab *ptab,
ErtsAlcType_t atype,
void (*release_element)(void *),
ErtsPTabElementCommon *invalid_element,
int size,
UWord element_size,
char *name,
int legacy)
{
size_t tab_sz, alloc_sz;
Uint32 bits, cl, cli, ix, ix_per_cache_line, tab_cache_lines;
char *tab_end;
erts_smp_atomic_t *tab_entry;
erts_smp_rwmtx_opt_t rwmtx_opts = ERTS_SMP_RWMTX_OPT_DEFAULT_INITER;
rwmtx_opts.type = ERTS_SMP_RWMTX_TYPE_EXTREMELY_FREQUENT_READ;
rwmtx_opts.lived = ERTS_SMP_RWMTX_LONG_LIVED;
erts_smp_rwmtx_init_opt(&ptab->list.data.rwmtx, &rwmtx_opts, name);
erts_smp_atomic32_init_nob(&ptab->vola.tile.count, 0);
last_data_init_nob(ptab, ~((Uint64) 0));
/* A size that is a power of 2 is to prefer performance wise */
bits = erts_fit_in_bits_int32(size-1);
size = 1 << bits;
if (size > ERTS_PTAB_MAX_SIZE) {
size = ERTS_PTAB_MAX_SIZE;
bits = erts_fit_in_bits_int32((Sint32) size - 1);
}
ptab->r.o.element_size = element_size;
ptab->r.o.max = size;
tab_sz = ERTS_ALC_CACHE_LINE_ALIGN_SIZE(size*sizeof(erts_smp_atomic_t));
alloc_sz = tab_sz;
if (!legacy)
alloc_sz += ERTS_ALC_CACHE_LINE_ALIGN_SIZE(size*sizeof(erts_smp_atomic32_t));
ptab->r.o.tab = erts_alloc_permanent_cache_aligned(atype, alloc_sz);
tab_end = ((char *) ptab->r.o.tab) + tab_sz;
tab_entry = ptab->r.o.tab;
while (tab_end > ((char *) tab_entry)) {
erts_smp_atomic_init_nob(tab_entry, ERTS_AINT_NULL);
tab_entry++;
}
tab_cache_lines = tab_sz/ERTS_CACHE_LINE_SIZE;
ix_per_cache_line = (ERTS_CACHE_LINE_SIZE/sizeof(erts_smp_atomic_t));
ASSERT((ptab->r.o.max & (ptab->r.o.max - 1)) == 0); /* power of 2 */
ASSERT((ix_per_cache_line & (ix_per_cache_line - 1)) == 0); /* power of 2 */
ASSERT((tab_cache_lines & (tab_cache_lines - 1)) == 0); /* power of 2 */
ptab->r.o.pix_mask = (1 << bits) - 1;
ptab->r.o.pix_cl_mask = tab_cache_lines-1;
ptab->r.o.pix_cl_shift = erts_fit_in_bits_int32(ix_per_cache_line-1);
ptab->r.o.pix_cli_shift = erts_fit_in_bits_int32(ptab->r.o.pix_cl_mask);
ptab->r.o.pix_cli_mask = (1 << (bits - ptab->r.o.pix_cli_shift)) - 1;
ASSERT(ptab->r.o.pix_cl_shift + ptab->r.o.pix_cli_shift == bits);
ptab->r.o.invalid_element = invalid_element;
ptab->r.o.invalid_data = erts_ptab_id2data(ptab, invalid_element->id);
ptab->r.o.release_element = release_element;
if (legacy) {
ptab->r.o.free_id_data = NULL;
ptab->r.o.dix_cl_mask = 0;
ptab->r.o.dix_cl_shift = 0;
ptab->r.o.dix_cli_shift = 0;
ptab->r.o.dix_cli_mask = 0;
}
else {
tab_sz = ERTS_ALC_CACHE_LINE_ALIGN_SIZE(size*sizeof(erts_smp_atomic32_t));
ptab->r.o.free_id_data = (erts_smp_atomic32_t *) tab_end;
tab_cache_lines = tab_sz/ERTS_CACHE_LINE_SIZE;
ix_per_cache_line = (ERTS_CACHE_LINE_SIZE/sizeof(erts_smp_atomic32_t));
ptab->r.o.dix_cl_mask = tab_cache_lines-1;
ptab->r.o.dix_cl_shift = erts_fit_in_bits_int32(ix_per_cache_line-1);
ptab->r.o.dix_cli_shift = erts_fit_in_bits_int32(ptab->r.o.dix_cl_mask);
ptab->r.o.dix_cli_mask = (1 << (bits - ptab->r.o.dix_cli_shift)) - 1;
ASSERT((ix_per_cache_line & (ix_per_cache_line - 1)) == 0); /* power of 2 */
ASSERT((tab_cache_lines & (tab_cache_lines - 1)) == 0); /* power of 2 */
ASSERT(ptab->r.o.dix_cl_shift + ptab->r.o.dix_cli_shift == bits);
ix = 0;
for (cl = 0; cl < tab_cache_lines; cl++) {
for (cli = 0; cli < ix_per_cache_line; cli++) {
erts_smp_atomic32_init_nob(&ptab->r.o.free_id_data[ix],
cli*tab_cache_lines+cl);
ASSERT(erts_smp_atomic32_read_nob(&ptab->r.o.free_id_data[ix]) != ptab->r.o.invalid_data);
ix++;
}
}
erts_smp_atomic32_init_nob(&ptab->vola.tile.aid_ix, -1);
erts_smp_atomic32_init_nob(&ptab->vola.tile.fid_ix, -1);
}
erts_smp_interval_init(&ptab->list.data.interval);
ptab->list.data.deleted.start = NULL;
ptab->list.data.deleted.end = NULL;
ptab->list.data.chunks = (((ptab->r.o.max - 1)
/ ERTS_PTAB_LIST_BIF_TAB_CHUNK_SIZE)
+ 1);
if (size == ERTS_PTAB_MAX_SIZE) {
int pix;
/*
* We want a table size of a power of 2 which ERTS_PTAB_MAX_SIZE
* is. We only have ERTS_PTAB_MAX_SIZE-1 unique identifiers and
* we don't want to shrink the size to ERTS_PTAB_MAX_SIZE/2.
*
* In order to fix this, we insert a pointer from the table
* to the invalid_element, wich will be interpreted as a
* slot currently being modified. This way we will be able to
* have ERTS_PTAB_MAX_SIZE-1 valid elements in the table while
* still having a table size of the power of 2.
*/
erts_smp_atomic32_inc_nob(&ptab->vola.tile.count);
pix = erts_ptab_data2pix(ptab, ptab->r.o.invalid_data);
erts_smp_atomic_set_relb(&ptab->r.o.tab[pix],
(erts_aint_t) ptab->r.o.invalid_element);
}
}
int
erts_ptab_initialized(ErtsPTab *ptab)
{
return ptab->r.o.tab != NULL;
}
int
erts_ptab_new_element(ErtsPTab *ptab,
ErtsPTabElementCommon *ptab_el,
void *init_arg,
void (*init_ptab_el)(void *, Eterm))
{
Uint32 pix, ix, data;
erts_aint32_t count;
erts_aint_t invalid = (erts_aint_t) ptab->r.o.invalid_element;
erts_ptab_rlock(ptab);
count = erts_smp_atomic32_inc_read_acqb(&ptab->vola.tile.count);
if (count > ptab->r.o.max) {
while (1) {
erts_aint32_t act_count;
act_count = erts_smp_atomic32_cmpxchg_relb(&ptab->vola.tile.count,
count-1,
count);
if (act_count == count) {
erts_ptab_runlock(ptab);
return 0;
}
count = act_count;
if (count <= ptab->r.o.max)
break;
}
}
ptab_el->u.alive.started_interval
= erts_smp_current_interval_nob(erts_ptab_interval(ptab));
if (ptab->r.o.free_id_data) {
do {
ix = (Uint32) erts_smp_atomic32_inc_read_acqb(&ptab->vola.tile.aid_ix);
ix = ix_to_free_id_data_ix(ptab, ix);
data = erts_smp_atomic32_xchg_nob(&ptab->r.o.free_id_data[ix],
(erts_aint32_t)ptab->r.o.invalid_data);
}while ((Eterm)data == ptab->r.o.invalid_data);
init_ptab_el(init_arg, (Eterm) data);
#ifdef ERTS_SMP
erts_smp_atomic32_init_nob(&ptab_el->refc, 1);
#endif
pix = erts_ptab_data2pix(ptab, (Eterm) data);
#ifdef DEBUG
ASSERT(ERTS_AINT_NULL == erts_smp_atomic_xchg_relb(&ptab->r.o.tab[pix],
(erts_aint_t) ptab_el));
#else
erts_smp_atomic_set_relb(&ptab->r.o.tab[pix], (erts_aint_t) ptab_el);
#endif
erts_ptab_runlock(ptab);
}
else {
int rlocked = ERTS_PTAB_NEW_MAX_RESERVE_FAIL;
Uint64 ld, exp_ld;
/* Deprecated legacy algorithm... */
restart:
ptab_el->u.alive.started_interval
= erts_smp_current_interval_nob(erts_ptab_interval(ptab));
ld = last_data_read_acqb(ptab);
/* Reserve slot */
while (1) {
ld++;
pix = erts_ptab_data2pix(ptab, ERTS_PTAB_LastData2EtermData(ld));
if (erts_smp_atomic_read_nob(&ptab->r.o.tab[pix])
== ERTS_AINT_NULL) {
erts_aint_t val;
val = erts_smp_atomic_cmpxchg_relb(&ptab->r.o.tab[pix],
invalid,
ERTS_AINT_NULL);
if (ERTS_AINT_NULL == val)
break;
}
if (rlocked && --rlocked == 0) {
erts_ptab_runlock(ptab);
erts_ptab_rwlock(ptab);
goto restart;
}
}
data = ERTS_PTAB_LastData2EtermData(ld);
if (data == ptab->r.o.invalid_data) {
/* Do not use invalid data; fix it... */
ld += ptab->r.o.max;
ASSERT(pix == erts_ptab_data2pix(ptab,
ERTS_PTAB_LastData2EtermData(ld)));
data = ERTS_PTAB_LastData2EtermData(ld);
ASSERT(data != ptab->r.o.invalid_data);
}
exp_ld = last_data_read_nob(ptab);
/* Move last data forward */
while (1) {
Uint64 act_ld;
if (last_data_cmp(ld, exp_ld) < 0)
break;
act_ld = last_data_cmpxchg_relb(ptab, ld, exp_ld);
if (act_ld == exp_ld)
break;
exp_ld = act_ld;
}
init_ptab_el(init_arg, data);
#ifdef ERTS_SMP
erts_smp_atomic32_init_nob(&ptab_el->refc, 1);
#endif
/* Move into slot reserved */
#ifdef DEBUG
ASSERT(invalid == erts_smp_atomic_xchg_relb(&ptab->r.o.tab[pix],
(erts_aint_t) ptab_el));
#else
erts_smp_atomic_set_relb(&ptab->r.o.tab[pix], (erts_aint_t) ptab_el);
#endif
if (rlocked)
erts_ptab_runlock(ptab);
else
erts_ptab_rwunlock(ptab);
}
return 1;
}
static void
save_deleted_element(ErtsPTab *ptab, ErtsPTabElementCommon *ptab_el)
{
ErtsPTabDeletedElement *ptdep = erts_alloc(ERTS_ALC_T_PTAB_LIST_DEL,
sizeof(ErtsPTabDeletedElement));
ERTS_PTAB_LIST_ASSERT(ptab->list.data.deleted.start
&& ptab->list.data.deleted.end);
ERTS_SMP_LC_ASSERT(erts_smp_lc_ptab_is_rwlocked(ptab));
ERTS_PTAB_LIST_DBG_CHK_DEL_LIST(ptab);
ptdep->prev = ptab->list.data.deleted.end;
ptdep->next = NULL;
ptdep->ix = erts_ptab_id2pix(ptab, ptab_el->id);
ptdep->u.element.id = ptab_el->id;
ptdep->u.element.inserted = ptab_el->u.alive.started_interval;
ptdep->u.element.deleted =
erts_smp_current_interval_nob(erts_ptab_interval(ptab));
ptab->list.data.deleted.end->next = ptdep;
ptab->list.data.deleted.end = ptdep;
ERTS_PTAB_LIST_DBG_CHK_DEL_LIST(ptab);
ERTS_PTAB_LIST_ASSERT(ptdep->prev->ix >= 0
? (ptdep->u.element.deleted
>= ptdep->prev->u.element.deleted)
: (ptdep->u.element.deleted
>= ptdep->prev->u.bif_invocation.interval));
}
void
erts_ptab_delete_element(ErtsPTab *ptab,
ErtsPTabElementCommon *ptab_el)
{
int maybe_save;
Uint32 pix, ix, data;
pix = erts_ptab_id2pix(ptab, ptab_el->id);
/* *Need* to be an managed thread */
ERTS_SMP_LC_ASSERT(erts_thr_progress_is_managed_thread());
erts_ptab_rlock(ptab);
maybe_save = ptab->list.data.deleted.end != NULL;
if (maybe_save) {
erts_ptab_runlock(ptab);
erts_ptab_rwlock(ptab);
}
erts_smp_atomic_set_relb(&ptab->r.o.tab[pix], ERTS_AINT_NULL);
if (ptab->r.o.free_id_data) {
Uint32 prev_data;
/* Next data for this slot... */
data = (Uint32) erts_ptab_id2data(ptab, ptab_el->id);
data += ptab->r.o.max;
data &= ~(~((Uint32) 0) << ERTS_PTAB_ID_DATA_SIZE);
if (data == ptab->r.o.invalid_data) { /* make sure not invalid */
data += ptab->r.o.max;
data &= ~(~((Uint32) 0) << ERTS_PTAB_ID_DATA_SIZE);
}
ASSERT(data != ptab->r.o.invalid_data);
ASSERT(pix == erts_ptab_data2pix(ptab, data));
do {
ix = (Uint32) erts_smp_atomic32_inc_read_relb(&ptab->vola.tile.fid_ix);
ix = ix_to_free_id_data_ix(ptab, ix);
prev_data = erts_smp_atomic32_cmpxchg_nob(&ptab->r.o.free_id_data[ix],
data,
ptab->r.o.invalid_data);
}while ((Eterm)prev_data != ptab->r.o.invalid_data);
}
ASSERT(erts_smp_atomic32_read_nob(&ptab->vola.tile.count) > 0);
erts_smp_atomic32_dec_relb(&ptab->vola.tile.count);
if (!maybe_save)
erts_ptab_runlock(ptab);
else {
if (ptab->list.data.deleted.end)
save_deleted_element(ptab, ptab_el);
erts_ptab_rwunlock(ptab);
}
if (ptab->r.o.release_element)
erts_schedule_thr_prgr_later_cleanup_op(ptab->r.o.release_element,
(void *) ptab_el,
&ptab_el->u.release,
ptab->r.o.element_size);
}
/*
* erts_ptab_list() implements BIFs listing the content of the table,
* e.g. erlang:processes/0.
*/
static void cleanup_ptab_list_bif_data(Binary *bp);
static int ptab_list_bif_engine(Process *c_p, Eterm *res_accp, Binary *mbp);
BIF_RETTYPE
erts_ptab_list(Process *c_p, ErtsPTab *ptab)
{
/*
* A requirement: The list of identifiers returned should be a
* consistent snapshot of all elements existing
* in the table at some point in time during the
* execution of the BIF calling this function.
* Since elements might be deleted while the BIF
* is executing, we have to keep track of all
* deleted elements and add them to the result.
* We also ignore elements created after the BIF
* has begun executing.
*/
BIF_RETTYPE ret_val;
Eterm res_acc = NIL;
Binary *mbp = erts_create_magic_binary(sizeof(ErtsPTabListBifData),
cleanup_ptab_list_bif_data);
ErtsPTabListBifData *ptlbdp = ERTS_MAGIC_BIN_DATA(mbp);
ERTS_PTAB_LIST_DBG_TRACE(c_p->common.id, call);
ptlbdp->ptab = ptab;
ptlbdp->state = INITIALIZING;
ERTS_PTAB_LIST_DBG_INIT(c_p, ptlbdp);
if (ERTS_BIF_REDS_LEFT(c_p) >= ERTS_PTAB_LIST_BIF_MIN_START_REDS
&& ptab_list_bif_engine(c_p, &res_acc, mbp)) {
erts_bin_free(mbp);
ERTS_PTAB_LIST_DBG_CHK_RESLIST(res_acc);
ERTS_PTAB_LIST_DBG_TRACE(c_p->common.id, return);
ERTS_BIF_PREP_RET(ret_val, res_acc);
}
else {
Eterm *hp;
Eterm magic_bin;
ERTS_PTAB_LIST_DBG_CHK_RESLIST(res_acc);
hp = HAlloc(c_p, PROC_BIN_SIZE);
ERTS_PTAB_LIST_DBG_SAVE_HEAP_ALLOC(ptlbdp, hp, PROC_BIN_SIZE);
magic_bin = erts_mk_magic_binary_term(&hp, &MSO(c_p), mbp);
ERTS_PTAB_LIST_DBG_VERIFY_HEAP_ALLOC_USED(ptlbdp, hp);
ERTS_PTAB_LIST_DBG_TRACE(c_p->common.id, trap);
ERTS_BIF_PREP_YIELD2(ret_val,
&ptab_list_continue_export,
c_p,
res_acc,
magic_bin);
}
return ret_val;
}
static void
cleanup_ptab_list_bif_data(Binary *bp)
{
ErtsPTabListBifData *ptlbdp = ERTS_MAGIC_BIN_DATA(bp);
ErtsPTab *ptab = ptlbdp->ptab;
ERTS_PTAB_LIST_DBG_TRACE(ptlbdp->debug.caller, call);
if (ptlbdp->state != INITIALIZING) {
if (ptlbdp->chunk) {
erts_free(ERTS_ALC_T_PTAB_LIST_CNKI, ptlbdp->chunk);
ptlbdp->chunk = NULL;
}
if (ptlbdp->pid) {
erts_free(ERTS_ALC_T_PTAB_LIST_PIDS, ptlbdp->pid);
ptlbdp->pid = NULL;
}
#if ERTS_PTAB_LIST_BIF_DEBUGLEVEL >= ERTS_PTAB_LIST_DBGLVL_CHK_FOUND_PIDS
if (ptlbdp->debug.pid_started) {
erts_free(ERTS_ALC_T_PTAB_LIST_PIDS, ptlbdp->debug.pid_started);
ptlbdp->debug.pid_started = NULL;
}
#endif
if (ptlbdp->bif_invocation) {
ErtsPTabDeletedElement *ptdep;
erts_ptab_rwlock(ptab);
ERTS_PTAB_LIST_DBG_TRACE(ptlbdp->debug.caller, deleted_cleanup);
ptdep = ptlbdp->bif_invocation;
ptlbdp->bif_invocation = NULL;
ERTS_PTAB_LIST_DBG_CHK_DEL_LIST(ptab);
if (ptdep->prev) {
/*
* Only remove this bif invokation when we
* have preceding invokations.
*/
ptdep->prev->next = ptdep->next;
if (ptdep->next)
ptdep->next->prev = ptdep->prev;
else {
/*
* At the time of writing this branch cannot be
* reached. I don't want to remove this code though
* since it may be possible to reach this line
* in the future if the cleanup order in
* erts_do_exit_process() is changed. The ASSERT(0)
* is only here to make us aware that the reorder
* has happened. /rickard
*/
ASSERT(0);
ptab->list.data.deleted.end = ptdep->prev;
}
erts_free(ERTS_ALC_T_PTAB_LIST_DEL, ptdep);
}
else {
/*
* Free all elements until next bif invokation
* is found.
*/
ERTS_PTAB_LIST_ASSERT(ptab->list.data.deleted.start == ptdep);
do {
ErtsPTabDeletedElement *fptdep = ptdep;
ptdep = ptdep->next;
erts_free(ERTS_ALC_T_PTAB_LIST_DEL, fptdep);
} while (ptdep && ptdep->ix >= 0);
ptab->list.data.deleted.start = ptdep;
if (ptdep)
ptdep->prev = NULL;
else
ptab->list.data.deleted.end = NULL;
}
ERTS_PTAB_LIST_DBG_CHK_DEL_LIST(ptab);
erts_ptab_rwunlock(ptab);
}
}
ERTS_PTAB_LIST_DBG_TRACE(ptlbdp->debug.caller, return);
ERTS_PTAB_LIST_DBG_CLEANUP(ptlbdp);
}
static int
ptab_list_bif_engine(Process *c_p, Eterm *res_accp, Binary *mbp)
{
ErtsPTabListBifData *ptlbdp = ERTS_MAGIC_BIN_DATA(mbp);
ErtsPTab *ptab = ptlbdp->ptab;
int have_reds;
int reds;
int locked = 0;
do {
switch (ptlbdp->state) {
case INITIALIZING:
ptlbdp->chunk = erts_alloc(ERTS_ALC_T_PTAB_LIST_CNKI,
(sizeof(ErtsPTabListBifChunkInfo)
* ptab->list.data.chunks));
ptlbdp->tix = 0;
ptlbdp->pid_ix = 0;
erts_ptab_rwlock(ptab);
locked = 1;
ERTS_PTAB_LIST_DBG_TRACE(c_p->common.id, init);
ptlbdp->pid_sz = erts_ptab_count(ptab);
ptlbdp->pid = erts_alloc(ERTS_ALC_T_PTAB_LIST_PIDS,
sizeof(Eterm)*ptlbdp->pid_sz);
#if ERTS_PTAB_LIST_BIF_DEBUGLEVEL >= ERTS_PTAB_LIST_DBGLVL_CHK_FOUND_PIDS
ptlbdp->debug.pid_started
= erts_alloc(ERTS_ALC_T_PTAB_LIST_PIDS,
sizeof(Uint64)*ptlbdp->pid_sz);
#endif
ERTS_PTAB_LIST_DBG_SAVE_PIDS(ptlbdp);
if (ptab->list.data.chunks == 1)
ptlbdp->bif_invocation = NULL;
else {
/*
* We will have to access the table multiple times
* releasing the table lock in between chunks.
*/
ptlbdp->bif_invocation
= erts_alloc(ERTS_ALC_T_PTAB_LIST_DEL,
sizeof(ErtsPTabDeletedElement));
ptlbdp->bif_invocation->ix = -1;
ptlbdp->bif_invocation->u.bif_invocation.interval
= erts_smp_step_interval_nob(erts_ptab_interval(ptab));
ERTS_PTAB_LIST_DBG_CHK_DEL_LIST(ptab);
ptlbdp->bif_invocation->next = NULL;
if (ptab->list.data.deleted.end) {
ptlbdp->bif_invocation->prev = ptab->list.data.deleted.end;
ptab->list.data.deleted.end->next = ptlbdp->bif_invocation;
ERTS_PTAB_LIST_ASSERT(ptab->list.data.deleted.start);
}
else {
ptlbdp->bif_invocation->prev = NULL;
ptab->list.data.deleted.start = ptlbdp->bif_invocation;
}
ptab->list.data.deleted.end = ptlbdp->bif_invocation;
ERTS_PTAB_LIST_DBG_CHK_DEL_LIST(ptab);
}
ptlbdp->state = INSPECTING_TABLE;
/* Fall through */
case INSPECTING_TABLE: {
int ix = ptlbdp->tix;
int indices = ERTS_PTAB_LIST_BIF_TAB_CHUNK_SIZE;
int cix = ix / ERTS_PTAB_LIST_BIF_TAB_CHUNK_SIZE;
int end_ix = ix + indices;
Uint64 *invocation_interval_p;
ErtsPTabElementCommon *invalid_element;
invocation_interval_p
= (ptlbdp->bif_invocation
? &ptlbdp->bif_invocation->u.bif_invocation.interval
: NULL);
ERTS_PTAB_LIST_ASSERT(is_nil(*res_accp));
if (!locked) {
erts_ptab_rwlock(ptab);
locked = 1;
}
ERTS_SMP_LC_ASSERT(erts_smp_lc_ptab_is_rwlocked(ptab));
ERTS_PTAB_LIST_DBG_TRACE(p->common.id, insp_table);
if (cix != 0)
ptlbdp->chunk[cix].interval
= erts_smp_step_interval_nob(erts_ptab_interval(ptab));
else if (ptlbdp->bif_invocation)
ptlbdp->chunk[0].interval = *invocation_interval_p;
/* else: interval is irrelevant */
if (end_ix >= ptab->r.o.max) {
ERTS_PTAB_LIST_ASSERT(cix+1 == ptab->list.data.chunks);
end_ix = ptab->r.o.max;
indices = end_ix - ix;
/* What to do when done with this chunk */
ptlbdp->state = (ptab->list.data.chunks == 1
? BUILDING_RESULT
: INSPECTING_DELETED);
}
invalid_element = ptab->r.o.invalid_element;
for (; ix < end_ix; ix++) {
ErtsPTabElementCommon *el;
el = (ErtsPTabElementCommon *) erts_ptab_pix2intptr_nob(ptab,
ix);
if (el
&& el != invalid_element
&& (!invocation_interval_p
|| el->u.alive.started_interval < *invocation_interval_p)) {
ERTS_PTAB_LIST_ASSERT(erts_ptab_is_valid_id(el->id));
ptlbdp->pid[ptlbdp->pid_ix] = el->id;
#if ERTS_PTAB_LIST_BIF_DEBUGLEVEL >= ERTS_PTAB_LIST_DBGLVL_CHK_FOUND_PIDS
ptlbdp->debug.pid_started[ptlbdp->pid_ix]
= el->u.alive.started_interval;
#endif
ptlbdp->pid_ix++;
ERTS_PTAB_LIST_ASSERT(ptlbdp->pid_ix <= ptlbdp->pid_sz);
}
}
ptlbdp->tix = end_ix;
erts_ptab_rwunlock(ptab);
locked = 0;
reds = indices/ERTS_PTAB_LIST_BIF_TAB_INSPECT_INDICES_PER_RED;
BUMP_REDS(c_p, reds);
have_reds = ERTS_BIF_REDS_LEFT(c_p);
if (have_reds && ptlbdp->state == INSPECTING_TABLE) {
ix = ptlbdp->tix;
indices = ERTS_PTAB_LIST_BIF_TAB_CHUNK_SIZE;
end_ix = ix + indices;
if (end_ix > ptab->r.o.max) {
end_ix = ptab->r.o.max;
indices = end_ix - ix;
}
reds = indices/ERTS_PTAB_LIST_BIF_TAB_INSPECT_INDICES_PER_RED;
/* Pretend we have no reds left if we haven't got enough
reductions to complete next chunk */
if (reds > have_reds)
have_reds = 0;
}
break;
}
case INSPECTING_DELETED: {
int i;
int max_reds;
int free_deleted = 0;
Uint64 invocation_interval;
ErtsPTabDeletedElement *ptdep;
ErtsPTabDeletedElement *free_list = NULL;
ptdep = ptlbdp->bif_invocation;
ERTS_PTAB_LIST_ASSERT(ptdep);
invocation_interval = ptdep->u.bif_invocation.interval;
max_reds = have_reds = ERTS_BIF_REDS_LEFT(c_p);
if (max_reds > ERTS_PTAB_LIST_INSPECT_DELETED_MAX_REDS)
max_reds = ERTS_PTAB_LIST_INSPECT_DELETED_MAX_REDS;
reds = 0;
erts_ptab_rwlock(ptab);
ERTS_PTAB_LIST_DBG_TRACE(p->common.id, insp_term_procs);
ERTS_PTAB_LIST_DBG_CHK_DEL_LIST(ptab);
if (ptdep->prev)
ptdep->prev->next = ptdep->next;
else {
ERTS_PTAB_LIST_ASSERT(ptab->list.data.deleted.start == ptdep);
ptab->list.data.deleted.start = ptdep->next;
if (ptab->list.data.deleted.start
&& ptab->list.data.deleted.start->ix >= 0) {
free_list = ptab->list.data.deleted.start;
free_deleted = 1;
}
}
if (ptdep->next)
ptdep->next->prev = ptdep->prev;
else
ptab->list.data.deleted.end = ptdep->prev;
ptdep = ptdep->next;
i = 0;
while (reds < max_reds && ptdep) {
if (ptdep->ix < 0) {
if (free_deleted) {
ERTS_PTAB_LIST_ASSERT(free_list);
ERTS_PTAB_LIST_ASSERT(ptdep->prev);
ptdep->prev->next = NULL; /* end of free_list */
ptab->list.data.deleted.start = ptdep;
ptdep->prev = NULL;
free_deleted = 0;
}
}
else {
int cix = ptdep->ix/ERTS_PTAB_LIST_BIF_TAB_CHUNK_SIZE;
Uint64 chunk_interval = ptlbdp->chunk[cix].interval;
Eterm pid = ptdep->u.element.id;
ERTS_PTAB_LIST_ASSERT(erts_ptab_is_valid_id(pid));
if (ptdep->u.element.inserted < invocation_interval) {
if (ptdep->u.element.deleted < chunk_interval) {
ERTS_PTAB_LIST_DBG_CHK_PID_NOT_FOUND(
ptlbdp,
pid,
ptdep->u.element.inserted);
ptlbdp->pid[ptlbdp->pid_ix] = pid;
#if ERTS_PTAB_LIST_BIF_DEBUGLEVEL >= ERTS_PTAB_LIST_DBGLVL_CHK_FOUND_PIDS
ptlbdp->debug.pid_started[ptlbdp->pid_ix]
= ptdep->u.element.inserted;
#endif
ptlbdp->pid_ix++;
ERTS_PTAB_LIST_ASSERT(ptlbdp->pid_ix
<= ptlbdp->pid_sz);
}
else {
ERTS_PTAB_LIST_DBG_CHK_PID_FOUND(
ptlbdp,
pid,
ptdep->u.element.inserted);
}
}
else {
ERTS_PTAB_LIST_DBG_CHK_PID_NOT_FOUND(
ptlbdp,
pid,
ptdep->u.element.inserted);
}
i++;
if (i == ERTS_PTAB_LIST_BIF_INSPECT_DELETED_PER_RED) {
reds++;
i = 0;
}
if (free_deleted)
reds += ERTS_PTAB_LIST_BIF_TAB_FREE_DELETED_REDS;
}
ptdep = ptdep->next;
}
if (free_deleted) {
ERTS_PTAB_LIST_ASSERT(free_list);
ptab->list.data.deleted.start = ptdep;
if (!ptdep)
ptab->list.data.deleted.end = NULL;
else {
ERTS_PTAB_LIST_ASSERT(ptdep->prev);
ptdep->prev->next = NULL; /* end of free_list */
ptdep->prev = NULL;
}
}
if (!ptdep) {
/* Done */
ERTS_PTAB_LIST_ASSERT(ptlbdp->pid_ix == ptlbdp->pid_sz);
ptlbdp->state = BUILDING_RESULT;
ptlbdp->bif_invocation->next = free_list;
free_list = ptlbdp->bif_invocation;
ptlbdp->bif_invocation = NULL;
}
else {
/* Link in bif_invocation again where we left off */
ptlbdp->bif_invocation->prev = ptdep->prev;
ptlbdp->bif_invocation->next = ptdep;
ptdep->prev = ptlbdp->bif_invocation;
if (ptlbdp->bif_invocation->prev)
ptlbdp->bif_invocation->prev->next = ptlbdp->bif_invocation;
else {
ERTS_PTAB_LIST_ASSERT(ptab->list.data.deleted.start
== ptdep);
ptab->list.data.deleted.start = ptlbdp->bif_invocation;
}
}
ERTS_PTAB_LIST_DBG_CHK_DEL_LIST(ptab);
ERTS_PTAB_LIST_DBG_CHK_FREELIST(ptab, free_list);
erts_ptab_rwunlock(ptab);
/*
* We do the actual free of deleted structures now when we
* have released the table lock instead of when we encountered
* them. This since free() isn't for free and we don't want to
* unnecessarily block other schedulers.
*/
while (free_list) {
ptdep = free_list;
free_list = ptdep->next;
erts_free(ERTS_ALC_T_PTAB_LIST_DEL, ptdep);
}
have_reds -= reds;
if (have_reds < 0)
have_reds = 0;
BUMP_REDS(c_p, reds);
break;
}
case BUILDING_RESULT: {
int conses, ix, min_ix;
Eterm *hp;
Eterm res = *res_accp;
ERTS_PTAB_LIST_DBG_VERIFY_PIDS(ptlbdp);
ERTS_PTAB_LIST_DBG_CHK_RESLIST(res);
ERTS_PTAB_LIST_DBG_TRACE(p->common.id, begin_build_res);
have_reds = ERTS_BIF_REDS_LEFT(c_p);
conses = ERTS_PTAB_LIST_BIF_BUILD_RESULT_CONSES_PER_RED*have_reds;
min_ix = ptlbdp->pid_ix - conses;
if (min_ix < 0) {
min_ix = 0;
conses = ptlbdp->pid_ix;
}
if (conses) {
hp = HAlloc(c_p, conses*2);
ERTS_PTAB_LIST_DBG_SAVE_HEAP_ALLOC(ptlbdp, hp, conses*2);
for (ix = ptlbdp->pid_ix - 1; ix >= min_ix; ix--) {
ERTS_PTAB_LIST_ASSERT(erts_ptab_is_valid_id(ptlbdp->pid[ix]));
res = CONS(hp, ptlbdp->pid[ix], res);
hp += 2;
}
ERTS_PTAB_LIST_DBG_VERIFY_HEAP_ALLOC_USED(ptlbdp, hp);
}
ptlbdp->pid_ix = min_ix;
if (min_ix == 0)
ptlbdp->state = RETURN_RESULT;
else {
ptlbdp->pid_sz = min_ix;
ptlbdp->pid = erts_realloc(ERTS_ALC_T_PTAB_LIST_PIDS,
ptlbdp->pid,
sizeof(Eterm)*ptlbdp->pid_sz);
#if ERTS_PTAB_LIST_BIF_DEBUGLEVEL >= ERTS_PTAB_LIST_DBGLVL_CHK_FOUND_PIDS
ptlbdp->debug.pid_started
= erts_realloc(ERTS_ALC_T_PTAB_LIST_PIDS,
ptlbdp->debug.pid_started,
sizeof(Uint64) * ptlbdp->pid_sz);
#endif
}
reds = conses/ERTS_PTAB_LIST_BIF_BUILD_RESULT_CONSES_PER_RED;
BUMP_REDS(c_p, reds);
have_reds -= reds;
ERTS_PTAB_LIST_DBG_CHK_RESLIST(res);
ERTS_PTAB_LIST_DBG_TRACE(c_p->common.id, end_build_res);
*res_accp = res;
break;
}
case RETURN_RESULT:
cleanup_ptab_list_bif_data(mbp);
return 1;
default:
erl_exit(ERTS_ABORT_EXIT,
"%s:%d:ptab_list_bif_engine(): Invalid state: %d\n",
__FILE__, __LINE__, (int) ptlbdp->state);
}
} while (have_reds || ptlbdp->state == RETURN_RESULT);
return 0;
}
/*
* ptab_list_continue/2 is a hidden BIF that the original BIF traps to
* if there are too much work to do in one go.
*/
static BIF_RETTYPE ptab_list_continue(BIF_ALIST_2)
{
Eterm res_acc;
Binary *mbp;
/*
* This bif cannot be called from erlang code. It can only be
* trapped to from other BIFs; therefore, a bad argument
* is an internal error and should never occur...
*/
ERTS_PTAB_LIST_DBG_TRACE(BIF_P->common.id, call);
ERTS_PTAB_LIST_ASSERT(is_nil(BIF_ARG_1) || is_list(BIF_ARG_1));
res_acc = BIF_ARG_1;
ERTS_PTAB_LIST_ASSERT(ERTS_TERM_IS_MAGIC_BINARY(BIF_ARG_2));
mbp = ((ProcBin *) binary_val(BIF_ARG_2))->val;
ERTS_PTAB_LIST_ASSERT(ERTS_MAGIC_BIN_DESTRUCTOR(mbp)
== cleanup_ptab_list_bif_data);
ERTS_PTAB_LIST_ASSERT(
((ErtsPTabListBifData *) ERTS_MAGIC_BIN_DATA(mbp))->debug.caller
== BIF_P->common.id);
if (ptab_list_bif_engine(BIF_P, &res_acc, mbp)) {
ERTS_PTAB_LIST_DBG_TRACE(BIF_P->common.id, return);
BIF_RET(res_acc);
}
else {
ERTS_PTAB_LIST_DBG_TRACE(BIF_P->common.id, trap);
ERTS_BIF_YIELD2(&ptab_list_continue_export, BIF_P, res_acc, BIF_ARG_2);
}
}
void
erts_ptab_init(void)
{
/* ptab_list_continue/2 is a hidden BIF that the original BIF traps to. */
erts_init_trap_export(&ptab_list_continue_export,
am_erlang, am_ptab_list_continue, 2,
&ptab_list_continue);
}
/*
* Debug stuff
*/
static void assert_ptab_consistency(ErtsPTab *ptab)
{
#ifdef DEBUG
if (ptab->r.o.free_id_data) {
Uint32 ix, pix, data;
int free_pids = 0;
int null_slots = 0;
for (ix=0; ix < ptab->r.o.max; ix++) {
if (erts_smp_atomic32_read_nob(&ptab->r.o.free_id_data[ix]) != ptab->r.o.invalid_data) {
++free_pids;
data = erts_smp_atomic32_read_nob(&ptab->r.o.free_id_data[ix]);
pix = erts_ptab_data2pix(ptab, (Eterm) data);
ASSERT(erts_ptab_pix2intptr_nob(ptab, pix) == ERTS_AINT_NULL);
}
if (erts_smp_atomic_read_nob(&ptab->r.o.tab[ix]) == ERTS_AINT_NULL) {
++null_slots;
}
}
ASSERT(free_pids == null_slots);
ASSERT(free_pids == ptab->r.o.max - erts_smp_atomic32_read_nob(&ptab->vola.tile.count));
}
#endif
}
Sint
erts_ptab_test_next_id(ErtsPTab *ptab, int set, Uint next)
{
Uint64 ld;
Sint res;
Eterm data;
int first_pix = -1;
erts_ptab_rwlock(ptab);
assert_ptab_consistency(ptab);
if (ptab->r.o.free_id_data) {
Uint32 id_ix, dix;
if (set) {
Uint32 i, max_ix, num, stop_id_ix;
max_ix = ptab->r.o.max - 1;
num = next;
id_ix = (Uint32) erts_smp_atomic32_read_nob(&ptab->vola.tile.aid_ix);
for (i=0; i <= max_ix; ++i) {
Uint32 pix;
++num;
num &= ~(~((Uint32) 0) << ERTS_PTAB_ID_DATA_SIZE);
if (num == ptab->r.o.invalid_data) {
num += ptab->r.o.max;
num &= ~(~((Uint32) 0) << ERTS_PTAB_ID_DATA_SIZE);
}
pix = erts_ptab_data2pix(ptab, num);
if (ERTS_AINT_NULL == erts_ptab_pix2intptr_nob(ptab, pix)) {
++id_ix;
dix = ix_to_free_id_data_ix(ptab, id_ix);
erts_smp_atomic32_set_nob(&ptab->r.o.free_id_data[dix], num);
ASSERT(pix == erts_ptab_data2pix(ptab, num));
}
}
erts_smp_atomic32_set_nob(&ptab->vola.tile.fid_ix, id_ix);
/* Write invalid_data in rest of free_id_data[]: */
stop_id_ix = (1 + erts_smp_atomic32_read_nob(&ptab->vola.tile.aid_ix)) & max_ix;
while (1) {
id_ix = (id_ix+1) & max_ix;
if (id_ix == stop_id_ix)
break;
dix = ix_to_free_id_data_ix(ptab, id_ix);
erts_smp_atomic32_set_nob(&ptab->r.o.free_id_data[dix],
ptab->r.o.invalid_data);
}
}
id_ix = (Uint32) erts_smp_atomic32_read_nob(&ptab->vola.tile.aid_ix) + 1;
dix = ix_to_free_id_data_ix(ptab, id_ix);
res = (Sint) erts_smp_atomic32_read_nob(&ptab->r.o.free_id_data[dix]);
}
else {
/* Deprecated legacy algorithm... */
if (!set)
ld = last_data_read_nob(ptab);
else {
ld = (Uint64) next;
data = ERTS_PTAB_LastData2EtermData(ld);
if (ptab->r.o.invalid_data == data) {
ld += ptab->r.o.max;
ASSERT(erts_ptab_data2pix(ptab, data)
== erts_ptab_data2pix(ptab,
ERTS_PTAB_LastData2EtermData(ld)));
}
last_data_set_relb(ptab, ld);
}
while (1) {
int pix;
ld++;
pix = (int) (ld % ptab->r.o.max);
if (first_pix < 0)
first_pix = pix;
else if (pix == first_pix) {
res = -1;
break;
}
if (ERTS_AINT_NULL == erts_ptab_pix2intptr_nob(ptab, pix)) {
data = ERTS_PTAB_LastData2EtermData(ld);
if (ptab->r.o.invalid_data == data) {
ld += ptab->r.o.max;
ASSERT(erts_ptab_data2pix(ptab, data)
== erts_ptab_data2pix(ptab,
ERTS_PTAB_LastData2EtermData(ld)));
data = ERTS_PTAB_LastData2EtermData(ld);
}
res = data;
break;
}
}
}
assert_ptab_consistency(ptab);
erts_ptab_rwunlock(ptab);
return res;
}
static ERTS_INLINE ErtsPTabElementCommon *
ptab_pix2el(ErtsPTab *ptab, int ix)
{
ErtsPTabElementCommon *ptab_el;
ASSERT(0 <= ix && ix < ptab->r.o.max);
ptab_el = (ErtsPTabElementCommon *) erts_ptab_pix2intptr_nob(ptab, ix);
if (ptab_el == ptab->r.o.invalid_element)
return NULL;
else
return ptab_el;
}
Eterm
erts_debug_ptab_list(Process *c_p, ErtsPTab *ptab)
{
int i;
Uint need;
Eterm res;
Eterm* hp;
Eterm *hp_end;
erts_ptab_rwlock(ptab);
res = NIL;
need = erts_ptab_count(ptab) * 2;
hp = HAlloc(c_p, need); /* we need two heap words for each id */
hp_end = hp + need;
/* make the list by scanning bakward */
for (i = ptab->r.o.max-1; i >= 0; i--) {
ErtsPTabElementCommon *el = ptab_pix2el(ptab, i);
if (el) {
res = CONS(hp, el->id, res);
hp += 2;
}
}
erts_ptab_rwunlock(ptab);
HRelease(c_p, hp_end, hp);
return res;
}
Eterm
erts_debug_ptab_list_bif_info(Process *c_p, ErtsPTab *ptab)
{
ERTS_DECL_AM(ptab_list_bif_info);
Eterm elements[] = {
AM_ptab_list_bif_info,
make_small((Uint) ERTS_PTAB_LIST_BIF_MIN_START_REDS),
make_small((Uint) ptab->list.data.chunks),
make_small((Uint) ERTS_PTAB_LIST_BIF_TAB_CHUNK_SIZE),
make_small((Uint) ERTS_PTAB_LIST_BIF_TAB_INSPECT_INDICES_PER_RED),
make_small((Uint) ERTS_PTAB_LIST_BIF_TAB_FREE_DELETED_REDS),
make_small((Uint) ERTS_PTAB_LIST_BIF_INSPECT_DELETED_PER_RED),
make_small((Uint) ERTS_PTAB_LIST_INSPECT_DELETED_MAX_REDS),
make_small((Uint) ERTS_PTAB_LIST_BIF_BUILD_RESULT_CONSES_PER_RED),
make_small((Uint) ERTS_PTAB_LIST_BIF_DEBUGLEVEL)
};
Uint sz = 0;
Eterm *hp;
(void) erts_bld_tuplev(NULL, &sz, sizeof(elements)/sizeof(Eterm), elements);
hp = HAlloc(c_p, sz);
return erts_bld_tuplev(&hp, NULL, sizeof(elements)/sizeof(Eterm), elements);
}
#if ERTS_PTAB_LIST_BIF_DEBUGLEVEL >= ERTS_PTAB_LIST_DBGLVL_CHK_FOUND_PIDS
static void
debug_ptab_list_check_found_pid(ErtsPTabListBifData *ptlbdp,
Eterm pid,
Uint64 ic,
int pid_should_be_found)
{
int i;
for (i = 0; i < ptlbdp->pid_ix; i++) {
if (ptlbdp->pid[i] == pid && ptlbdp->debug.pid_started[i] == ic) {
ERTS_PTAB_LIST_ASSERT(pid_should_be_found);
return;
}
}
ERTS_PTAB_LIST_ASSERT(!pid_should_be_found);
}
#endif
#if ERTS_PTAB_LIST_BIF_DEBUGLEVEL >= ERTS_PTAB_LIST_DBGLVL_CHK_RESLIST
static void
debug_ptab_list_check_res_list(Eterm list)
{
while (is_list(list)) {
Eterm* consp = list_val(list);
Eterm hd = CAR(consp);
ERTS_PTAB_LIST_ASSERT(erts_ptab_is_valid_id(hd));
list = CDR(consp);
}
ERTS_PTAB_LIST_ASSERT(is_nil(list));
}
#endif
#if ERTS_PTAB_LIST_BIF_DEBUGLEVEL >= ERTS_PTAB_LIST_DBGLVL_CHK_PIDS
static void
debug_ptab_list_save_all_pids(ErtsPTabListBifData *ptlbdp)
{
int ix, tix, cpix;
ErtsPTab *ptab = ptlbdp->ptab;
ptlbdp->debug.correct_pids_verified = 0;
ptlbdp->debug.correct_pids = erts_alloc(ERTS_ALC_T_PTAB_LIST_PIDS,
sizeof(Eterm)*ptlbdp->pid_sz);
for (tix = 0, cpix = 0; tix < ptab->r.o.max; tix++) {
ErtsPTabElementCommon *el = ptab_pix2el(ptab, tix);
if (el) {
ERTS_PTAB_LIST_ASSERT(erts_ptab_is_valid_id(el->id));
ptlbdp->debug.correct_pids[cpix++] = el->id;
ERTS_PTAB_LIST_ASSERT(cpix <= ptlbdp->pid_sz);
}
}
ERTS_PTAB_LIST_ASSERT(cpix == ptlbdp->pid_sz);
for (ix = 0; ix < ptlbdp->pid_sz; ix++)
ptlbdp->pid[ix] = make_small(ix);
}
static void
debug_ptab_list_verify_all_pids(ErtsPTabListBifData *ptlbdp)
{
int ix, cpix;
ERTS_PTAB_LIST_ASSERT(ptlbdp->pid_ix == ptlbdp->pid_sz);
for (ix = 0; ix < ptlbdp->pid_sz; ix++) {
int found = 0;
Eterm pid = ptlbdp->pid[ix];
ERTS_PTAB_LIST_ASSERT(erts_ptab_is_valid_id(pid));
for (cpix = ix; cpix < ptlbdp->pid_sz; cpix++) {
if (ptlbdp->debug.correct_pids[cpix] == pid) {
ptlbdp->debug.correct_pids[cpix] = NIL;
found = 1;
break;
}
}
if (!found) {
for (cpix = 0; cpix < ix; cpix++) {
if (ptlbdp->debug.correct_pids[cpix] == pid) {
ptlbdp->debug.correct_pids[cpix] = NIL;
found = 1;
break;
}
}
}
ERTS_PTAB_LIST_ASSERT(found);
}
ptlbdp->debug.correct_pids_verified = 1;
erts_free(ERTS_ALC_T_PTAB_LIST_PIDS, ptlbdp->debug.correct_pids);
ptlbdp->debug.correct_pids = NULL;
}
#endif /* ERTS_PTAB_LIST_BIF_DEBUGLEVEL >= ERTS_PTAB_LIST_DBGLVL_CHK_PIDS */
#if ERTS_PTAB_LIST_BIF_DEBUGLEVEL >= ERTS_PTAB_LIST_DBGLVL_CHK_DEL_LIST
static void
debug_ptab_list_check_del_list(ErtsPTab *ptab)
{
ERTS_SMP_LC_ASSERT(erts_smp_lc_ptab_is_rwlocked(ptab));
if (!ptab->list.data.deleted.start)
ERTS_PTAB_LIST_ASSERT(!ptab->list.data.deleted.end);
else {
Uint64 curr_interval = erts_smp_current_interval_nob(erts_ptab_interval(ptab));
Uint64 *prev_x_interval_p = NULL;
ErtsPTabDeletedElement *ptdep;
for (ptdep = ptab->list.data.deleted.start;
ptdep;
ptdep = ptdep->next) {
if (!ptdep->prev)
ERTS_PTAB_LIST_ASSERT(ptab->list.data.deleted.start == ptdep);
else
ERTS_PTAB_LIST_ASSERT(ptdep->prev->next == ptdep);
if (!ptdep->next)
ERTS_PTAB_LIST_ASSERT(ptab->list.data.deleted.end == ptdep);
else
ERTS_PTAB_LIST_ASSERT(ptdep->next->prev == ptdep);
if (ptdep->ix < 0) {
Uint64 interval = ptdep->u.bif_invocation.interval;
ERTS_PTAB_LIST_ASSERT(interval <= curr_interval);
}
else {
Uint64 s_interval = ptdep->u.element.inserted;
Uint64 x_interval = ptdep->u.element.deleted;
ERTS_PTAB_LIST_ASSERT(s_interval <= x_interval);
if (prev_x_interval_p)
ERTS_PTAB_LIST_ASSERT(*prev_x_interval_p <= x_interval);
prev_x_interval_p = &ptdep->u.element.deleted;
ERTS_PTAB_LIST_ASSERT(
erts_ptab_is_valid_id(ptdep->u.element.id));
ERTS_PTAB_LIST_ASSERT(erts_ptab_id2pix(ptab,
ptdep->u.element.id)
== ptdep->ix);
}
}
}
}
static void
debug_ptab_list_check_del_free_list(ErtsPTab *ptab,
ErtsPTabDeletedElement *free_list)
{
if (ptab->list.data.deleted.start) {
ErtsPTabDeletedElement *fptdep;
ErtsPTabDeletedElement *ptdep;
for (fptdep = free_list; fptdep; fptdep = fptdep->next) {
for (ptdep = ptab->list.data.deleted.start;
ptdep;
ptdep = ptdep->next) {
ERTS_PTAB_LIST_ASSERT(fptdep != ptdep);
}
}
}
}
#endif
#if ERTS_PTAB_LIST_BIF_DEBUGLEVEL != 0
static void
debug_ptab_list_assert_error(char* expr, const char* file, int line, const char *func)
{
fflush(stdout);
erts_fprintf(stderr, "%s:%d:%s(): Assertion failed: %s\n",
(char *) file, line, (char *) func, expr);
fflush(stderr);
abort();
}
#endif
