/* -----------------------------------------------------------------------------
*
* (c) The GHC Team, 1998-2002
*
* Stable names and stable pointers.
*
* ---------------------------------------------------------------------------*/
#include "PosixSource.h"
#include "Rts.h"
#include "RtsAPI.h"
#include "Hash.h"
#include "RtsUtils.h"
#include "Trace.h"
#include "Stable.h"
/* Comment from ADR's implementation in old RTS:
This files (together with @ghc/runtime/storage/PerformIO.lhc@ and a
small change in @HpOverflow.lc@) consists of the changes in the
runtime system required to implement "Stable Pointers". But we're
getting a bit ahead of ourselves --- what is a stable pointer and what
is it used for?
When Haskell calls C, it normally just passes over primitive integers,
floats, bools, strings, etc. This doesn't cause any problems at all
for garbage collection because the act of passing them makes a copy
from the heap, stack or wherever they are onto the C-world stack.
However, if we were to pass a heap object such as a (Haskell) @String@
and a garbage collection occured before we finished using it, we'd run
into problems since the heap object might have been moved or even
deleted.
So, if a C call is able to cause a garbage collection or we want to
store a pointer to a heap object between C calls, we must be careful
when passing heap objects. Our solution is to keep a table of all
objects we've given to the C-world and to make sure that the garbage
collector collects these objects --- updating the table as required to
make sure we can still find the object.
Of course, all this rather begs the question: why would we want to
pass a boxed value?
One very good reason is to preserve laziness across the language
interface. Rather than evaluating an integer or a string because it
{\em might\/} be required by the C function, we can wait until the C
function actually wants the value and then force an evaluation.
Another very good reason (the motivating reason!) is that the C code
might want to execute an object of sort $IO ()$ for the side-effects
it will produce. For example, this is used when interfacing to an X
widgets library to allow a direct implementation of callbacks.
The @makeStablePointer :: a -> IO (StablePtr a)@ function
converts a value into a stable pointer. It is part of the @PrimIO@
monad, because we want to be sure we don't allocate one twice by
accident, and then only free one of the copies.
\begin{verbatim}
makeStablePtr# :: a -> State# RealWorld -> (# RealWorld, a #)
freeStablePtr# :: StablePtr# a -> State# RealWorld -> State# RealWorld
deRefStablePtr# :: StablePtr# a -> State# RealWorld ->
(# State# RealWorld, a #)
\end{verbatim}
There may be additional functions on the C side to allow evaluation,
application, etc of a stable pointer.
*/
snEntry *stable_ptr_table = NULL;
static snEntry *stable_ptr_free = NULL;
static unsigned int SPT_size = 0;
#ifdef THREADED_RTS
static Mutex stable_mutex;
#endif
static void enlargeStablePtrTable(void);
/* This hash table maps Haskell objects to stable names, so that every
* call to lookupStableName on a given object will return the same
* stable name.
*
* OLD COMMENTS about reference counting follow. The reference count
* in a stable name entry is now just a counter.
*
* Reference counting
* ------------------
* A plain stable name entry has a zero reference count, which means
* the entry will dissappear when the object it points to is
* unreachable. For stable pointers, we need an entry that sticks
* around and keeps the object it points to alive, so each stable name
* entry has an associated reference count.
*
* A stable pointer has a weighted reference count N attached to it
* (actually in its upper 5 bits), which represents the weight
* 2^(N-1). The stable name entry keeps a 32-bit reference count, which
* represents any weight between 1 and 2^32 (represented as zero).
* When the weight is 2^32, the stable name table owns "all" of the
* stable pointers to this object, and the entry can be garbage
* collected if the object isn't reachable.
*
* A new stable pointer is given the weight log2(W/2), where W is the
* weight stored in the table entry. The new weight in the table is W
* - 2^log2(W/2).
*
* A stable pointer can be "split" into two stable pointers, by
* dividing the weight by 2 and giving each pointer half.
* When freeing a stable pointer, the weight of the pointer is added
* to the weight stored in the table entry.
* */
static HashTable *addrToStableHash = NULL;
#define INIT_SPT_SIZE 64
STATIC_INLINE void
initFreeList(snEntry *table, nat n, snEntry *free)
{
snEntry *p;
for (p = table + n - 1; p >= table; p--) {
p->addr = (P_)free;
p->old = NULL;
p->ref = 0;
p->sn_obj = NULL;
free = p;
}
stable_ptr_free = table;
}
void
initStablePtrTable(void)
{
if (SPT_size > 0)
return;
SPT_size = INIT_SPT_SIZE;
stable_ptr_table = stgMallocBytes(SPT_size * sizeof(snEntry),
"initStablePtrTable");
/* we don't use index 0 in the stable name table, because that
* would conflict with the hash table lookup operations which
* return NULL if an entry isn't found in the hash table.
*/
initFreeList(stable_ptr_table+1,INIT_SPT_SIZE-1,NULL);
addrToStableHash = allocHashTable();
#ifdef THREADED_RTS
initMutex(&stable_mutex);
#endif
}
void
exitStablePtrTable(void)
{
if (addrToStableHash)
freeHashTable(addrToStableHash, NULL);
addrToStableHash = NULL;
if (stable_ptr_table)
stgFree(stable_ptr_table);
stable_ptr_table = NULL;
SPT_size = 0;
#ifdef THREADED_RTS
closeMutex(&stable_mutex);
#endif
}
/*
* get at the real stuff...remove indirections.
* It untags pointers before dereferencing and
* retags the real stuff with its tag (if there
* is any) when returning.
*
* ToDo: move to a better home.
*/
static
StgClosure*
removeIndirections(StgClosure* p)
{
StgWord tag = GET_CLOSURE_TAG(p);
StgClosure* q = UNTAG_CLOSURE(p);
while (get_itbl(q)->type == IND ||
get_itbl(q)->type == IND_STATIC ||
get_itbl(q)->type == IND_PERM) {
q = ((StgInd *)q)->indirectee;
tag = GET_CLOSURE_TAG(q);
q = UNTAG_CLOSURE(q);
}
return TAG_CLOSURE(tag,q);
}
static StgWord
lookupStableName_(StgPtr p)
{
StgWord sn;
void* sn_tmp;
if (stable_ptr_free == NULL) {
enlargeStablePtrTable();
}
/* removing indirections increases the likelihood
* of finding a match in the stable name hash table.
*/
p = (StgPtr)removeIndirections((StgClosure*)p);
// register the untagged pointer. This just makes things simpler.
p = (StgPtr)UNTAG_CLOSURE((StgClosure*)p);
sn_tmp = lookupHashTable(addrToStableHash,(W_)p);
sn = (StgWord)sn_tmp;
if (sn != 0) {
ASSERT(stable_ptr_table[sn].addr == p);
debugTrace(DEBUG_stable, "cached stable name %ld at %p",sn,p);
return sn;
} else {
sn = stable_ptr_free - stable_ptr_table;
stable_ptr_free = (snEntry*)(stable_ptr_free->addr);
stable_ptr_table[sn].ref = 0;
stable_ptr_table[sn].addr = p;
stable_ptr_table[sn].sn_obj = NULL;
/* debugTrace(DEBUG_stable, "new stable name %d at %p\n",sn,p); */
/* add the new stable name to the hash table */
insertHashTable(addrToStableHash, (W_)p, (void *)sn);
return sn;
}
}
StgWord
lookupStableName(StgPtr p)
{
StgWord res;
initStablePtrTable();
ACQUIRE_LOCK(&stable_mutex);
res = lookupStableName_(p);
RELEASE_LOCK(&stable_mutex);
return res;
}
STATIC_INLINE void
freeStableName(snEntry *sn)
{
ASSERT(sn->sn_obj == NULL);
if (sn->addr != NULL) {
removeHashTable(addrToStableHash, (W_)sn->addr, NULL);
}
sn->addr = (P_)stable_ptr_free;
stable_ptr_free = sn;
}
StgStablePtr
getStablePtr(StgPtr p)
{
StgWord sn;
initStablePtrTable();
ACQUIRE_LOCK(&stable_mutex);
sn = lookupStableName_(p);
stable_ptr_table[sn].ref++;
RELEASE_LOCK(&stable_mutex);
return (StgStablePtr)(sn);
}
void
freeStablePtr(StgStablePtr sp)
{
snEntry *sn;
initStablePtrTable();
ACQUIRE_LOCK(&stable_mutex);
sn = &stable_ptr_table[(StgWord)sp];
ASSERT((StgWord)sp < SPT_size && sn->addr != NULL && sn->ref > 0);
sn->ref--;
// If this entry has no StableName attached, then just free it
// immediately. This is important; it might be a while before the
// next major GC which actually collects the entry.
if (sn->sn_obj == NULL && sn->ref == 0) {
freeStableName(sn);
}
RELEASE_LOCK(&stable_mutex);
}
static void
enlargeStablePtrTable(void)
{
nat old_SPT_size = SPT_size;
// 2nd and subsequent times
SPT_size *= 2;
stable_ptr_table =
stgReallocBytes(stable_ptr_table,
SPT_size * sizeof(snEntry),
"enlargeStablePtrTable");
initFreeList(stable_ptr_table + old_SPT_size, old_SPT_size, NULL);
}
/* -----------------------------------------------------------------------------
* We must lock the StablePtr table during GC, to prevent simultaneous
* calls to freeStablePtr().
* -------------------------------------------------------------------------- */
void
stablePtrPreGC(void)
{
ACQUIRE_LOCK(&stable_mutex);
}
void
stablePtrPostGC(void)
{
RELEASE_LOCK(&stable_mutex);
}
/* -----------------------------------------------------------------------------
* Treat stable pointers as roots for the garbage collector.
*
* A stable pointer is any stable name entry with a ref > 0. We'll
* take the opportunity to zero the "keep" flags at the same time.
* -------------------------------------------------------------------------- */
void
markStablePtrTable(evac_fn evac, void *user)
{
snEntry *p, *end_stable_ptr_table;
StgPtr q;
end_stable_ptr_table = &stable_ptr_table[SPT_size];
// Mark all the stable *pointers* (not stable names).
// _starting_ at index 1; index 0 is unused.
for (p = stable_ptr_table+1; p < end_stable_ptr_table; p++) {
q = p->addr;
// Internal pointers are free slots. If q == NULL, it's a
// stable name where the object has been GC'd, but the
// StableName object (sn_obj) is still alive.
if (q && (q < (P_)stable_ptr_table || q >= (P_)end_stable_ptr_table)) {
// save the current addr away: we need to be able to tell
// whether the objects moved in order to be able to update
// the hash table later.
p->old = p->addr;
// if the ref is non-zero, treat addr as a root
if (p->ref != 0) {
evac(user, (StgClosure **)&p->addr);
}
}
}
}
/* -----------------------------------------------------------------------------
* Thread the stable pointer table for compacting GC.
*
* Here we must call the supplied evac function for each pointer into
* the heap from the stable pointer table, because the compacting
* collector may move the object it points to.
* -------------------------------------------------------------------------- */
void
threadStablePtrTable( evac_fn evac, void *user )
{
snEntry *p, *end_stable_ptr_table;
StgPtr q;
end_stable_ptr_table = &stable_ptr_table[SPT_size];
for (p = stable_ptr_table+1; p < end_stable_ptr_table; p++) {
if (p->sn_obj != NULL) {
evac(user, (StgClosure **)&p->sn_obj);
}
q = p->addr;
if (q && (q < (P_)stable_ptr_table || q >= (P_)end_stable_ptr_table)) {
evac(user, (StgClosure **)&p->addr);
}
}
}
/* -----------------------------------------------------------------------------
* Garbage collect any dead entries in the stable pointer table.
*
* A dead entry has:
*
* - a zero reference count
* - a dead sn_obj
*
* Both of these conditions must be true in order to re-use the stable
* name table entry. We can re-use stable name table entries for live
* heap objects, as long as the program has no StableName objects that
* refer to the entry.
* -------------------------------------------------------------------------- */
void
gcStablePtrTable( void )
{
snEntry *p, *end_stable_ptr_table;
StgPtr q;
end_stable_ptr_table = &stable_ptr_table[SPT_size];
// NOTE: _starting_ at index 1; index 0 is unused.
for (p = stable_ptr_table + 1; p < end_stable_ptr_table; p++) {
// Update the pointer to the StableName object, if there is one
if (p->sn_obj != NULL) {
p->sn_obj = isAlive(p->sn_obj);
}
// Internal pointers are free slots. If q == NULL, it's a
// stable name where the object has been GC'd, but the
// StableName object (sn_obj) is still alive.
q = p->addr;
if (q && (q < (P_)stable_ptr_table || q >= (P_)end_stable_ptr_table)) {
// StableNames only:
if (p->ref == 0) {
if (p->sn_obj == NULL) {
// StableName object is dead
freeStableName(p);
debugTrace(DEBUG_stable, "GC'd Stable name %ld",
(long)(p - stable_ptr_table));
continue;
} else {
p->addr = (StgPtr)isAlive((StgClosure *)p->addr);
debugTrace(DEBUG_stable,
"stable name %ld still alive at %p, ref %ld\n",
(long)(p - stable_ptr_table), p->addr, p->ref);
}
}
}
}
}
/* -----------------------------------------------------------------------------
* Update the StablePtr/StableName hash table
*
* The boolean argument 'full' indicates that a major collection is
* being done, so we might as well throw away the hash table and build
* a new one. For a minor collection, we just re-hash the elements
* that changed.
* -------------------------------------------------------------------------- */
void
updateStablePtrTable(rtsBool full)
{
snEntry *p, *end_stable_ptr_table;
if (full && addrToStableHash != NULL) {
freeHashTable(addrToStableHash,NULL);
addrToStableHash = allocHashTable();
}
end_stable_ptr_table = &stable_ptr_table[SPT_size];
// NOTE: _starting_ at index 1; index 0 is unused.
for (p = stable_ptr_table + 1; p < end_stable_ptr_table; p++) {
if (p->addr == NULL) {
if (p->old != NULL) {
// The target has been garbage collected. Remove its
// entry from the hash table.
removeHashTable(addrToStableHash, (W_)p->old, NULL);
p->old = NULL;
}
}
else if (p->addr < (P_)stable_ptr_table
|| p->addr >= (P_)end_stable_ptr_table) {
// Target still alive, Re-hash this stable name
if (full) {
insertHashTable(addrToStableHash, (W_)p->addr,
(void *)(p - stable_ptr_table));
} else if (p->addr != p->old) {
removeHashTable(addrToStableHash, (W_)p->old, NULL);
insertHashTable(addrToStableHash, (W_)p->addr,
(void *)(p - stable_ptr_table));
}
}
}
}