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|
/* -----------------------------------------------------------------------------
*
* (c) The GHC Team, 2015-2016
*
* Support for compact regions. See Note [Compact Normal Forms] in
* rts/sm/CNF.c
*
* ---------------------------------------------------------------------------*/
#include "Cmm.h"
#include "sm/ShouldCompact.h"
import CLOSURE base_GHCziIOziException_cannotCompactFunction_closure;
import CLOSURE base_GHCziIOziException_cannotCompactMutable_closure;
import CLOSURE base_GHCziIOziException_cannotCompactPinned_closure;
#if !defined(UnregisterisedCompiler)
import CLOSURE g0;
import CLOSURE large_alloc_lim;
#endif
//
// Allocate space for a new object in the compact region. We first try
// the fast method using the hp/hpLim fields of StgCompactNFData, and
// if that fails we fall back to calling allocateForCompact() which
// will append a new block if necessary.
//
#define ALLOCATE(compact,sizeW,p,to, tag) \
hp = StgCompactNFData_hp(compact); \
if (hp + WDS(sizeW) <= StgCompactNFData_hpLim(compact)) { \
to = hp; \
StgCompactNFData_hp(compact) = hp + WDS(sizeW); \
} else { \
("ptr" to) = ccall allocateForCompact( \
MyCapability() "ptr", compact "ptr", sizeW); \
} \
if (StgCompactNFData_hash(compact) != NULL) { \
ccall insertCompactHash(MyCapability(), compact, p, tag | to); \
}
//
// Look up a pointer in the hash table if we're doing sharing.
//
#define CHECK_HASH() \
hash = StgCompactNFData_hash(compact); \
if (hash != NULL) { \
("ptr" hashed) = ccall lookupHashTable(hash "ptr", p "ptr"); \
if (hashed != NULL) { \
P_[pp] = hashed; \
return (); \
} \
}
//
// Evacuate and copy an object and its transitive closure into a
// compact. This function is called recursively as we traverse the
// data structure. It takes the location to store the address of the
// compacted object as an argument, so that it can be tail-recursive.
//
// N.B. No memory barrier (see Note [Heap memory barriers] in SMP.h) is needed
// here since this is essentially an allocation of a new object which won't
// be visible to other cores until after we return.
stg_compactAddWorkerzh (
P_ compact, // The Compact# object
P_ p, // The object to compact
W_ pp) // Where to store a pointer to the compacted object
{
W_ type, info, should, hash, hp, tag;
P_ p;
P_ hashed;
again: MAYBE_GC(again);
STK_CHK_GEN();
eval:
tag = GETTAG(p);
p = UNTAG(p);
info = %INFO_PTR(p);
type = TO_W_(%INFO_TYPE(%STD_INFO(info)));
switch [0 .. N_CLOSURE_TYPES] type {
// Unevaluated things must be evaluated first:
case
THUNK,
THUNK_1_0,
THUNK_0_1,
THUNK_2_0,
THUNK_1_1,
THUNK_0_2,
THUNK_STATIC,
AP,
AP_STACK,
BLACKHOLE,
THUNK_SELECTOR : {
(P_ evald) = call %ENTRY_CODE(info) (p);
p = evald;
goto eval;
}
// Follow indirections:
case IND, IND_STATIC: {
p = StgInd_indirectee(p);
goto eval;
}
// Mutable things are not allowed:
case
MVAR_CLEAN,
MVAR_DIRTY,
TVAR,
MUT_ARR_PTRS_CLEAN,
MUT_ARR_PTRS_DIRTY,
MUT_ARR_PTRS_CLEAN,
MUT_VAR_CLEAN,
MUT_VAR_DIRTY,
WEAK,
PRIM,
MUT_PRIM,
TSO,
STACK,
TREC_CHUNK,
WHITEHOLE,
SMALL_MUT_ARR_PTRS_CLEAN,
SMALL_MUT_ARR_PTRS_DIRTY,
COMPACT_NFDATA: {
jump stg_raisezh(base_GHCziIOziException_cannotCompactMutable_closure);
}
// We shouldn't see any functions, if this data structure was NFData.
case
FUN,
FUN_1_0,
FUN_0_1,
FUN_2_0,
FUN_1_1,
FUN_0_2,
FUN_STATIC,
BCO,
PAP,
CONTINUATION: {
jump stg_raisezh(base_GHCziIOziException_cannotCompactFunction_closure);
}
case ARR_WORDS: {
(should) = ccall shouldCompact(compact "ptr", p "ptr");
if (should == SHOULDCOMPACT_IN_CNF) { P_[pp] = p; return(); }
if (should == SHOULDCOMPACT_PINNED) {
jump stg_raisezh(base_GHCziIOziException_cannotCompactPinned_closure);
}
CHECK_HASH();
P_ to;
W_ size;
size = SIZEOF_StgArrBytes + StgArrBytes_bytes(p);
ALLOCATE(compact, ROUNDUP_BYTES_TO_WDS(size), p, to, tag);
P_[pp] = to;
prim %memcpy(to, p, size, 1);
return();
}
case
MUT_ARR_PTRS_FROZEN_DIRTY,
MUT_ARR_PTRS_FROZEN_CLEAN: {
(should) = ccall shouldCompact(compact "ptr", p "ptr");
if (should == SHOULDCOMPACT_IN_CNF) { P_[pp] = p; return(); }
CHECK_HASH();
W_ i, size, cards, ptrs;
size = SIZEOF_StgMutArrPtrs + WDS(StgMutArrPtrs_size(p));
ptrs = StgMutArrPtrs_ptrs(p);
cards = SIZEOF_StgMutArrPtrs + WDS(ptrs);
ALLOCATE(compact, BYTES_TO_WDS(size), p, to, tag);
P_[pp] = tag | to;
SET_HDR(to, StgHeader_info(p), StgHeader_ccs(p));
StgMutArrPtrs_ptrs(to) = ptrs;
StgMutArrPtrs_size(to) = StgMutArrPtrs_size(p);
prim %memcpy(to + cards, p + cards , size - cards, 1);
i = 0;
loop0:
if (i < ptrs) ( likely: True ) {
W_ q;
q = to + SIZEOF_StgMutArrPtrs + WDS(i);
call stg_compactAddWorkerzh(
compact, P_[p + SIZEOF_StgMutArrPtrs + WDS(i)], q);
i = i + 1;
goto loop0;
}
return();
}
case
SMALL_MUT_ARR_PTRS_FROZEN_DIRTY,
SMALL_MUT_ARR_PTRS_FROZEN_CLEAN: {
(should) = ccall shouldCompact(compact "ptr", p "ptr");
if (should == SHOULDCOMPACT_IN_CNF) { P_[pp] = p; return(); }
CHECK_HASH();
W_ i, ptrs;
ptrs = StgSmallMutArrPtrs_ptrs(p);
ALLOCATE(compact, BYTES_TO_WDS(SIZEOF_StgSmallMutArrPtrs) + ptrs, p, to, tag);
P_[pp] = tag | to;
SET_HDR(to, StgHeader_info(p), StgHeader_ccs(p));
StgSmallMutArrPtrs_ptrs(to) = ptrs;
i = 0;
loop1:
if (i < ptrs) ( likely: True ) {
W_ q;
q = to + SIZEOF_StgSmallMutArrPtrs + WDS(i);
call stg_compactAddWorkerzh(
compact, P_[p + SIZEOF_StgSmallMutArrPtrs + WDS(i)], q);
i = i + 1;
goto loop1;
}
return();
}
// Everything else we should copy and evaluate the components:
case
CONSTR,
CONSTR_1_0,
CONSTR_2_0,
CONSTR_1_1: {
(should) = ccall shouldCompact(compact "ptr", p "ptr");
if (should == SHOULDCOMPACT_IN_CNF) { P_[pp] = tag | p; return(); }
constructor:
CHECK_HASH();
W_ i, ptrs, nptrs, size;
P_ to;
ptrs = TO_W_(%INFO_PTRS(%STD_INFO(info)));
nptrs = TO_W_(%INFO_NPTRS(%STD_INFO(info)));
size = BYTES_TO_WDS(SIZEOF_StgHeader) + ptrs + nptrs;
ALLOCATE(compact, size, p, to, tag);
P_[pp] = tag | to;
SET_HDR(to, StgHeader_info(p), StgHeader_ccs(p));
// First, copy the non-pointers
if (nptrs > 0) {
i = ptrs;
loop2:
StgClosure_payload(to,i) = StgClosure_payload(p,i);
i = i + 1;
if (i < ptrs + nptrs) ( likely: True ) goto loop2;
}
// Next, recursively compact and copy the pointers
if (ptrs == 0) { return(); }
i = 0;
loop3:
W_ q;
q = to + SIZEOF_StgHeader + OFFSET_StgClosure_payload + WDS(i);
// Tail-call the last one. This means we don't build up a deep
// stack when compacting lists.
if (i == ptrs - 1) {
jump stg_compactAddWorkerzh(compact, StgClosure_payload(p,i), q);
}
call stg_compactAddWorkerzh(compact, StgClosure_payload(p,i), q);
i = i + 1;
goto loop3;
}
// these might be static closures that we can avoid copying into
// the compact if they don't refer to CAFs.
case
CONSTR_0_1,
CONSTR_0_2,
CONSTR_NOCAF: {
(should) = ccall shouldCompact(compact "ptr", p "ptr");
if (should == SHOULDCOMPACT_IN_CNF ||
should == SHOULDCOMPACT_STATIC) { P_[pp] = tag | p; return(); }
goto constructor;
}}
ccall barf("stg_compactWorkerzh", NULL);
}
//
// compactAddWithSharing#
// :: State# RealWorld
// -> Compact#
// -> a
// -> (# State# RealWorld, a #)
//
stg_compactAddWithSharingzh (P_ compact, P_ p)
{
W_ hash;
ASSERT(StgCompactNFData_hash(compact) == NULL);
(hash) = ccall allocHashTable();
StgCompactNFData_hash(compact) = hash;
// Note [compactAddWorker result]
// ~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~
// compactAddWorker needs somewhere to store the result - this is
// so that it can be tail-recursive. It must be an address that
// doesn't move during GC, so we can't use heap or stack.
// Therefore we have a special field in the StgCompactNFData
// object to hold the final result of compaction.
W_ pp;
pp = compact + SIZEOF_StgHeader + OFFSET_StgCompactNFData_result;
call stg_compactAddWorkerzh(compact, p, pp);
ccall freeHashTable(StgCompactNFData_hash(compact), NULL);
StgCompactNFData_hash(compact) = NULL;
#if defined(DEBUG)
ccall verifyCompact(compact);
#endif
return (P_[pp]);
}
//
// compactAdd#
// :: State# RealWorld
// -> Compact#
// -> a
// -> (# State# RealWorld, a #)
//
stg_compactAddzh (P_ compact, P_ p)
{
ASSERT(StgCompactNFData_hash(compact) == NULL);
W_ pp; // See Note [compactAddWorker result]
pp = compact + SIZEOF_StgHeader + OFFSET_StgCompactNFData_result;
call stg_compactAddWorkerzh(compact, p, pp);
#if defined(DEBUG)
ccall verifyCompact(compact);
#endif
return (P_[pp]);
}
stg_compactSizzezh (P_ compact)
{
return (StgCompactNFData_totalW(compact) * SIZEOF_W);
}
stg_compactNewzh ( W_ size )
{
P_ str;
again: MAYBE_GC(again);
("ptr" str) = ccall compactNew(MyCapability() "ptr", size);
return (str);
}
stg_compactResizzezh ( P_ str, W_ new_size )
{
again: MAYBE_GC(again);
ccall compactResize(MyCapability() "ptr", str "ptr", new_size);
return ();
}
stg_compactContainszh ( P_ str, P_ val )
{
W_ rval;
(rval) = ccall compactContains(str "ptr", val "ptr");
return (rval);
}
stg_compactContainsAnyzh ( P_ val )
{
W_ rval;
(rval) = ccall compactContains(0 "ptr", val "ptr");
return (rval);
}
stg_compactGetFirstBlockzh ( P_ str )
{
/* W_, not P_, because it is not a gc pointer */
W_ block;
W_ bd;
W_ size;
block = str - SIZEOF_StgCompactNFDataBlock::W_;
ASSERT(StgCompactNFDataBlock_owner(block) == str);
// We have to save Hp back to the nursery, otherwise the size will
// be wrong.
bd = Bdescr(StgCompactNFData_nursery(str));
bdescr_free(bd) = StgCompactNFData_hp(str);
bd = Bdescr(str);
size = bdescr_free(bd) - bdescr_start(bd);
ASSERT(size <= TO_W_(bdescr_blocks(bd)) * BLOCK_SIZE);
return (block, size);
}
stg_compactGetNextBlockzh ( P_ str, W_ block )
{
/* str is a pointer to the closure holding the Compact#
it is there primarily to keep everything reachable from
the GC: by having it on the stack of type P_, the GC will
see all the blocks as live (any pointer in the Compact#
keeps it alive), and will not collect the block
We don't run a GC inside this primop, but it could
happen right after, or we could be preempted.
str is also useful for debugging, as it can be casted
to a useful C struct from the gdb command line and all
blocks can be inspected
*/
W_ bd;
W_ next_block;
W_ size;
next_block = StgCompactNFDataBlock_next(block);
if (next_block == 0::W_) {
return (0::W_, 0::W_);
}
ASSERT(StgCompactNFDataBlock_owner(next_block) == str ||
StgCompactNFDataBlock_owner(next_block) == NULL);
bd = Bdescr(next_block);
size = bdescr_free(bd) - bdescr_start(bd);
ASSERT(size <= TO_W_(bdescr_blocks(bd)) * BLOCK_SIZE);
return (next_block, size);
}
stg_compactAllocateBlockzh ( W_ size, W_ previous )
{
W_ actual_block;
again: MAYBE_GC(again);
("ptr" actual_block) = ccall compactAllocateBlock(MyCapability(),
size,
previous "ptr");
return (actual_block);
}
stg_compactFixupPointerszh ( W_ first_block, W_ root )
{
W_ str;
P_ gcstr;
W_ ok;
str = first_block + SIZEOF_StgCompactNFDataBlock::W_;
(ok) = ccall compactFixupPointers (str "ptr", root "ptr");
// Now we can let the GC know about str, because it was linked
// into the generation list and the book-keeping pointers are
// guaranteed to be valid
// (this is true even if the fixup phase failed)
gcstr = str;
return (gcstr, ok);
}
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