/* * %CopyrightBegin% * * Copyright Ericsson AB 1996-2009. 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% */ #ifdef HAVE_CONFIG_H # include "config.h" #endif #include "sys.h" #include "erl_vm.h" #include "global.h" #include "erl_process.h" #include "erl_gc.h" #include "erl_nmgc.h" #include "big.h" #include "erl_binary.h" #include "erl_bits.h" #ifdef HYBRID MA_STACK_DECLARE(src); MA_STACK_DECLARE(dst); MA_STACK_DECLARE(offset); #endif void init_copy(void) { #ifdef HYBRID MA_STACK_ALLOC(src); MA_STACK_ALLOC(dst); MA_STACK_ALLOC(offset); #endif } /* * Copy object "obj" to process p. */ Eterm copy_object(Eterm obj, Process* to) { Uint size = size_object(obj); Eterm* hp = HAlloc(to, size); Eterm res; res = copy_struct(obj, size, &hp, &to->off_heap); #ifdef DEBUG if (eq(obj, res) == 0) { erl_exit(ERTS_ABORT_EXIT, "copy not equal to source\n"); } #endif return res; } /* * Return the "flat" size of the object. */ Uint size_object(Eterm obj) { Uint sum = 0; Eterm* ptr; int arity; DECLARE_ESTACK(s); for (;;) { switch (primary_tag(obj)) { case TAG_PRIMARY_LIST: sum += 2; ptr = list_val(obj); obj = *ptr++; if (!IS_CONST(obj)) { ESTACK_PUSH(s, obj); } obj = *ptr; break; case TAG_PRIMARY_BOXED: { Eterm hdr = *boxed_val(obj); ASSERT(is_header(hdr)); switch (hdr & _TAG_HEADER_MASK) { case ARITYVAL_SUBTAG: ptr = tuple_val(obj); arity = header_arity(hdr); sum += arity + 1; if (arity == 0) { /* Empty tuple -- unusual. */ goto size_common; } while (arity-- > 1) { obj = *++ptr; if (!IS_CONST(obj)) { ESTACK_PUSH(s, obj); } } obj = *++ptr; break; case FUN_SUBTAG: { Eterm* bptr = fun_val(obj); ErlFunThing* funp = (ErlFunThing *) bptr; unsigned eterms = 1 /* creator */ + funp->num_free; unsigned sz = thing_arityval(hdr); sum += 1 /* header */ + sz + eterms; bptr += 1 /* header */ + sz; while (eterms-- > 1) { obj = *bptr++; if (!IS_CONST(obj)) { ESTACK_PUSH(s, obj); } } obj = *bptr; break; } case SUB_BINARY_SUBTAG: { Eterm real_bin; Uint offset; /* Not used. */ Uint bitsize; Uint bitoffs; Uint extra_bytes; Eterm hdr; ERTS_GET_REAL_BIN(obj, real_bin, offset, bitoffs, bitsize); if ((bitsize + bitoffs) > 8) { sum += ERL_SUB_BIN_SIZE; extra_bytes = 2; } else if ((bitsize + bitoffs) > 0) { sum += ERL_SUB_BIN_SIZE; extra_bytes = 1; } else { extra_bytes = 0; } hdr = *binary_val(real_bin); if (thing_subtag(hdr) == REFC_BINARY_SUBTAG) { sum += PROC_BIN_SIZE; } else { sum += heap_bin_size(binary_size(obj)+extra_bytes); } goto size_common; } break; case BIN_MATCHSTATE_SUBTAG: erl_exit(ERTS_ABORT_EXIT, "size_object: matchstate term not allowed"); default: sum += thing_arityval(hdr) + 1; /* Fall through */ size_common: if (ESTACK_ISEMPTY(s)) { DESTROY_ESTACK(s); return sum; } obj = ESTACK_POP(s); break; } } break; case TAG_PRIMARY_IMMED1: if (ESTACK_ISEMPTY(s)) { DESTROY_ESTACK(s); return sum; } obj = ESTACK_POP(s); break; default: erl_exit(ERTS_ABORT_EXIT, "size_object: bad tag for %#x\n", obj); } } } /* * Copy a structure to a heap. */ Eterm copy_struct(Eterm obj, Uint sz, Eterm** hpp, ErlOffHeap* off_heap) { char* hstart; Uint hsize; Eterm* htop; Eterm* hbot; Eterm* hp; Eterm* objp; Eterm* tp; Eterm res; Eterm elem; Eterm* tailp; Eterm* argp; Eterm* const_tuple; Eterm hdr; int i; #ifdef DEBUG Eterm org_obj = obj; Uint org_sz = sz; #endif if (IS_CONST(obj)) return obj; hp = htop = *hpp; hbot = htop + sz; hstart = (char *)htop; hsize = (char*) hbot - hstart; const_tuple = 0; /* Copy the object onto the heap */ switch (primary_tag(obj)) { case TAG_PRIMARY_LIST: argp = &res; goto L_copy_list; case TAG_PRIMARY_BOXED: argp = &res; goto L_copy_boxed; default: erl_exit(ERTS_ABORT_EXIT, "%s, line %d: Internal error in copy_struct: 0x%08x\n", __FILE__, __LINE__,obj); } L_copy: while (hp != htop) { obj = *hp; switch (primary_tag(obj)) { case TAG_PRIMARY_IMMED1: hp++; break; case TAG_PRIMARY_LIST: objp = list_val(obj); if (in_area(objp,hstart,hsize)) { hp++; break; } argp = hp++; /* Fall through */ L_copy_list: tailp = argp; while (is_list(obj)) { objp = list_val(obj); tp = tailp; elem = *objp; if (IS_CONST(elem)) { *(hbot-2) = elem; tailp = hbot-1; hbot -= 2; } else { *htop = elem; tailp = htop+1; htop += 2; } *tp = make_list(tailp - 1); obj = *(objp+1); } switch (primary_tag(obj)) { case TAG_PRIMARY_IMMED1: *tailp = obj; goto L_copy; case TAG_PRIMARY_BOXED: argp = tailp; goto L_copy_boxed; default: erl_exit(ERTS_ABORT_EXIT, "%s, line %d: Internal error in copy_struct: 0x%08x\n", __FILE__, __LINE__,obj); } case TAG_PRIMARY_BOXED: if (in_area(boxed_val(obj),hstart,hsize)) { hp++; break; } argp = hp++; L_copy_boxed: objp = boxed_val(obj); hdr = *objp; switch (hdr & _TAG_HEADER_MASK) { case ARITYVAL_SUBTAG: { int const_flag = 1; /* assume constant tuple */ i = arityval(hdr); *argp = make_tuple(htop); tp = htop; /* tp is pointer to new arity value */ *htop++ = *objp++; /* copy arity value */ while (i--) { elem = *objp++; if (!IS_CONST(elem)) { const_flag = 0; } *htop++ = elem; } if (const_flag) { const_tuple = tp; /* this is the latest const_tuple */ } } break; case REFC_BINARY_SUBTAG: { ProcBin* pb; pb = (ProcBin *) objp; if (pb->flags) { erts_emasculate_writable_binary(pb); } i = thing_arityval(*objp) + 1; hbot -= i; tp = hbot; while (i--) { *tp++ = *objp++; } *argp = make_binary(hbot); pb = (ProcBin*) hbot; erts_refc_inc(&pb->val->refc, 2); pb->next = off_heap->mso; pb->flags = 0; off_heap->mso = pb; off_heap->overhead += pb->size / sizeof(Eterm); } break; case SUB_BINARY_SUBTAG: { ErlSubBin* sb = (ErlSubBin *) objp; Eterm real_bin = sb->orig; Uint bit_offset = sb->bitoffs; Uint bit_size = sb -> bitsize; Uint offset = sb->offs; size_t size = sb->size; Uint extra_bytes; Uint real_size; if ((bit_size + bit_offset) > 8) { extra_bytes = 2; } else if ((bit_size + bit_offset) > 0) { extra_bytes = 1; } else { extra_bytes = 0; } real_size = size+extra_bytes; objp = binary_val(real_bin); if (thing_subtag(*objp) == HEAP_BINARY_SUBTAG) { ErlHeapBin* from = (ErlHeapBin *) objp; ErlHeapBin* to; i = heap_bin_size(real_size); hbot -= i; to = (ErlHeapBin *) hbot; to->thing_word = header_heap_bin(real_size); to->size = real_size; sys_memcpy(to->data, ((byte *)from->data)+offset, real_size); } else { ProcBin* from = (ProcBin *) objp; ProcBin* to; ASSERT(thing_subtag(*objp) == REFC_BINARY_SUBTAG); if (from->flags) { erts_emasculate_writable_binary(from); } hbot -= PROC_BIN_SIZE; to = (ProcBin *) hbot; to->thing_word = HEADER_PROC_BIN; to->size = real_size; to->val = from->val; erts_refc_inc(&to->val->refc, 2); to->bytes = from->bytes + offset; to->next = off_heap->mso; to->flags = 0; off_heap->mso = to; off_heap->overhead += to->size / sizeof(Eterm); } *argp = make_binary(hbot); if (extra_bytes != 0) { ErlSubBin* res; hbot -= ERL_SUB_BIN_SIZE; res = (ErlSubBin *) hbot; res->thing_word = HEADER_SUB_BIN; res->size = size; res->bitsize = bit_size; res->bitoffs = bit_offset; res->offs = 0; res->is_writable = 0; res->orig = *argp; *argp = make_binary(hbot); } break; } break; case FUN_SUBTAG: { ErlFunThing* funp = (ErlFunThing *) objp; i = thing_arityval(hdr) + 2 + funp->num_free; tp = htop; while (i--) { *htop++ = *objp++; } #ifndef HYBRID /* FIND ME! */ funp = (ErlFunThing *) tp; funp->next = off_heap->funs; off_heap->funs = funp; erts_refc_inc(&funp->fe->refc, 2); #endif *argp = make_fun(tp); } break; case EXTERNAL_PID_SUBTAG: case EXTERNAL_PORT_SUBTAG: case EXTERNAL_REF_SUBTAG: { ExternalThing *etp = (ExternalThing *) htop; i = thing_arityval(hdr) + 1; tp = htop; while (i--) { *htop++ = *objp++; } etp->next = off_heap->externals; off_heap->externals = etp; erts_refc_inc(&etp->node->refc, 2); *argp = make_external(tp); } break; case BIN_MATCHSTATE_SUBTAG: erl_exit(ERTS_ABORT_EXIT, "copy_struct: matchstate term not allowed"); default: i = thing_arityval(hdr)+1; hbot -= i; tp = hbot; *argp = make_boxed(hbot); while (i--) { *tp++ = *objp++; } } break; case TAG_PRIMARY_HEADER: if (header_is_thing(obj) || hp == const_tuple) { hp += header_arity(obj) + 1; } else { hp++; } break; } } #ifdef DEBUG if (htop != hbot) erl_exit(ERTS_ABORT_EXIT, "Internal error in copy_struct() when copying %T:" " htop=%p != hbot=%p (sz=%bpu)\n", org_obj, htop, hbot, org_sz); #else if (htop > hbot) { erl_exit(ERTS_ABORT_EXIT, "Internal error in copy_struct(): htop, hbot overrun\n"); } #endif *hpp = (Eterm *) (hstart+hsize); return res; } #ifdef HYBRID #ifdef BM_MESSAGE_SIZES # define BM_ADD(var,val) (var) += (val); #else # define BM_ADD(var,val) #endif #ifdef DEBUG # define CLEARMEM(PTR,SIZE) memset(PTR,0,SIZE*sizeof(Eterm)) #else # define CLEARMEM(PTR,SIZE) #endif #ifdef INCREMENTAL #define GlobalAlloc(p, need, hp) \ do { \ Uint n = (need); \ BM_ADD(words_copied,n); \ BM_SWAP_TIMER(copy,system); \ /* If a new collection cycle is started during copy, the message * \ * will end up in the old generation and all allocations * \ * thereafter must go directly into the old generation. */ \ if (alloc_old) { \ erts_incremental_gc((p),n,&dest,1); \ (hp) = erts_inc_alloc(n); \ } else { \ (hp) = IncAlloc((p),n,&dest,1); \ if (ma_gc_flags & GC_CYCLE_START) { \ alloc_old = 1; \ global_htop = global_heap; \ (hp) = erts_inc_alloc(n); \ } \ } \ CLEARMEM((hp),(n)); \ BM_SWAP_TIMER(system,copy); \ } while(0) #else /* no INCREMELNTAL */ #define GlobalAlloc(p, need, hp) \ do { \ Uint n = (need); \ total_need += n; \ if (total_need >= global_heap_sz) \ erl_exit(ERTS_ABORT_EXIT, "Copying a message (%d words) larger than the nursery simply won't work...\n", total_need); \ if (global_hend - n < global_htop) { \ BM_SWAP_TIMER(copy,system); \ erts_global_garbage_collect((p),total_need,NULL,0); \ BM_SWAP_TIMER(system,copy); \ total_need = 0; \ ma_src_top = 0; \ ma_dst_top = 0; \ ma_offset_top = 0; \ goto copy_start; \ } \ (hp) = global_htop; \ global_htop += n; \ BM_ADD(words_copied,n); \ } while(0) #endif /* INCREMENTAL */ /* Copy a message to the message area. */ Eterm copy_struct_lazy(Process *from, Eterm orig, Uint offs) { Eterm obj; Eterm dest; #ifdef INCREMENTAL int alloc_old = 0; #else int total_need = 0; #endif VERBOSE(DEBUG_MESSAGES, ("COPY START; %T is sending a message @ 0x%016x\n%T\n", from->id, orig, orig)); #ifndef INCREMENTAL copy_start: #endif MA_STACK_PUSH(src,orig); MA_STACK_PUSH(dst,&dest); MA_STACK_PUSH(offset,offs); while (ma_src_top > 0) { obj = MA_STACK_POP(src); /* copy_struct_lazy should never be called with something that * do not need to be copied. Within the loop, nothing that do * not need copying should be placed in the src-stack. */ ASSERT(!NO_COPY(obj)); switch (primary_tag(obj)) { case TAG_PRIMARY_LIST: { Eterm *hp; Eterm *objp; GlobalAlloc(from,2,hp); objp = list_val(obj); MA_STACK_UPDATE(dst,MA_STACK_POP(offset),make_list(hp)); MA_STACK_POP(dst); /* TODO: Byt ordningen nedan så att CDR pushas först. */ if (NO_COPY(*objp)) { hp[0] = *objp; #ifdef INCREMENTAL if (ptr_within(ptr_val(*objp),inc_fromspc,inc_fromend)) INC_STORE(gray,hp,2); #endif } else { MA_STACK_PUSH(src,*objp); MA_STACK_PUSH(dst,hp); MA_STACK_PUSH(offset,0); } objp++; if (NO_COPY(*objp)) { hp[1] = *objp; #ifdef INCREMENTAL if (ptr_within(ptr_val(*objp),inc_fromspc,inc_fromend)) INC_STORE(gray,hp,2); #endif } else { MA_STACK_PUSH(src,*objp); MA_STACK_PUSH(dst,hp); MA_STACK_PUSH(offset,1); } continue; } case TAG_PRIMARY_BOXED: { Eterm *objp = boxed_val(obj); switch (*objp & _TAG_HEADER_MASK) { case ARITYVAL_SUBTAG: { Uint ari = arityval(*objp); Uint i; Eterm *hp; GlobalAlloc(from,ari + 1,hp); /* A GC above might invalidate the value of objp */ objp = boxed_val(obj); MA_STACK_UPDATE(dst,MA_STACK_POP(offset),make_tuple(hp)); MA_STACK_POP(dst); *hp = *objp++; for (i = 1; i <= ari; i++) { switch (primary_tag(*objp)) { case TAG_PRIMARY_LIST: case TAG_PRIMARY_BOXED: if (NO_COPY(*objp)) { hp[i] = *objp; #ifdef INCREMENTAL if (ptr_within(ptr_val(*objp), inc_fromspc,inc_fromend)) INC_STORE(gray,hp,BOXED_NEED(hp,*hp)); #endif objp++; } else { MA_STACK_PUSH(src,*objp++); MA_STACK_PUSH(dst,hp); MA_STACK_PUSH(offset,i); } break; default: hp[i] = *objp++; } } continue; } case REFC_BINARY_SUBTAG: { ProcBin *pb; Uint i = thing_arityval(*objp) + 1; Eterm *hp; GlobalAlloc(from,i,hp); /* A GC above might invalidate the value of objp */ objp = boxed_val(obj); MA_STACK_UPDATE(dst,MA_STACK_POP(offset),make_binary(hp)); MA_STACK_POP(dst); pb = (ProcBin*) hp; while (i--) { *hp++ = *objp++; } erts_refc_inc(&pb->val->refc, 2); pb->next = erts_global_offheap.mso; erts_global_offheap.mso = pb; erts_global_offheap.overhead += pb->size / sizeof(Eterm); continue; } case FUN_SUBTAG: { ErlFunThing *funp = (ErlFunThing*) objp; Uint i = thing_arityval(*objp) + 1; Uint j = i + 1 + funp->num_free; Uint k = i; Eterm *hp, *hp_start; GlobalAlloc(from,j,hp); /* A GC above might invalidate the value of objp */ objp = boxed_val(obj); hp_start = hp; MA_STACK_UPDATE(dst,MA_STACK_POP(offset),make_fun(hp)); MA_STACK_POP(dst); funp = (ErlFunThing*) hp; while (i--) { *hp++ = *objp++; } #ifndef HYBRID // FIND ME! funp->next = erts_global_offheap.funs; erts_global_offheap.funs = funp; erts_refc_inc(&funp->fe->refc, 2); #endif for (i = k; i < j; i++) { switch (primary_tag(*objp)) { case TAG_PRIMARY_LIST: case TAG_PRIMARY_BOXED: if (NO_COPY(*objp)) { #ifdef INCREMENTAL if (ptr_within(ptr_val(*objp), inc_fromspc,inc_fromend)) INC_STORE(gray,hp,BOXED_NEED(hp,*hp)); #endif *hp++ = *objp++; } else { MA_STACK_PUSH(src,*objp++); MA_STACK_PUSH(dst,hp_start); MA_STACK_PUSH(offset,i); hp++; } break; default: *hp++ = *objp++; } } continue; } case EXTERNAL_PID_SUBTAG: case EXTERNAL_PORT_SUBTAG: case EXTERNAL_REF_SUBTAG: { ExternalThing *etp; Uint i = thing_arityval(*objp) + 1; Eterm *hp; GlobalAlloc(from,i,hp); /* A GC above might invalidate the value of objp */ objp = boxed_val(obj); MA_STACK_UPDATE(dst,MA_STACK_POP(offset),make_external(hp)); MA_STACK_POP(dst); etp = (ExternalThing*) hp; while (i--) { *hp++ = *objp++; } etp->next = erts_global_offheap.externals; erts_global_offheap.externals = etp; erts_refc_inc(&etp->node->refc, 2); continue; } case SUB_BINARY_SUBTAG: { ErlSubBin *sb = (ErlSubBin *) objp; Eterm *hp; Eterm res_binary; Eterm real_bin = sb->orig; Uint bit_offset = sb->bitoffs; Uint bit_size = sb -> bitsize; Uint sub_offset = sb->offs; size_t size = sb->size; Uint extra_bytes; Uint real_size; Uint sub_binary_heapneed; if ((bit_size + bit_offset) > 8) { extra_bytes = 2; sub_binary_heapneed = ERL_SUB_BIN_SIZE; } else if ((bit_size + bit_offset) > 0) { extra_bytes = 1; sub_binary_heapneed = ERL_SUB_BIN_SIZE; } else { extra_bytes = 0; sub_binary_heapneed = 0; } real_size = size+extra_bytes; objp = binary_val(real_bin); if (thing_subtag(*objp) == HEAP_BINARY_SUBTAG) { ErlHeapBin *from_bin; ErlHeapBin *to_bin; Uint i = heap_bin_size(real_size); GlobalAlloc(from,i+sub_binary_heapneed,hp); from_bin = (ErlHeapBin *) objp; to_bin = (ErlHeapBin *) hp; to_bin->thing_word = header_heap_bin(real_size); to_bin->size = real_size; sys_memcpy(to_bin->data, ((byte *)from_bin->data) + sub_offset, real_size); res_binary = make_binary(to_bin); hp += i; } else { ProcBin *from_bin; ProcBin *to_bin; ASSERT(thing_subtag(*objp) == REFC_BINARY_SUBTAG); from_bin = (ProcBin *) objp; erts_refc_inc(&from_bin->val->refc, 2); GlobalAlloc(from,PROC_BIN_SIZE+sub_binary_heapneed,hp); to_bin = (ProcBin *) hp; to_bin->thing_word = HEADER_PROC_BIN; to_bin->size = real_size; to_bin->val = from_bin->val; to_bin->bytes = from_bin->bytes + sub_offset; to_bin->next = erts_global_offheap.mso; erts_global_offheap.mso = to_bin; erts_global_offheap.overhead += to_bin->size / sizeof(Eterm); res_binary=make_binary(to_bin); hp += PROC_BIN_SIZE; } if (extra_bytes != 0) { ErlSubBin* res; res = (ErlSubBin *) hp; res->thing_word = HEADER_SUB_BIN; res->size = size; res->bitsize = bit_size; res->bitoffs = bit_offset; res->offs = 0; res->is_writable = 0; res->orig = res_binary; res_binary = make_binary(hp); } MA_STACK_UPDATE(dst,MA_STACK_POP(offset),res_binary); MA_STACK_POP(dst); continue; } case BIN_MATCHSTATE_SUBTAG: erl_exit(ERTS_ABORT_EXIT, "copy_struct_lazy: matchstate term not allowed"); default: { Uint size = thing_arityval(*objp) + 1; Eterm *hp; GlobalAlloc(from,size,hp); /* A GC above might invalidate the value of objp */ objp = boxed_val(obj); MA_STACK_UPDATE(dst,MA_STACK_POP(offset),make_boxed(hp)); MA_STACK_POP(dst); while (size--) { *hp++ = *objp++; } continue; } } continue; } case TAG_PRIMARY_HEADER: ASSERT((obj & _TAG_HEADER_MASK) == ARITYVAL_SUBTAG); { Eterm *objp = &obj; Uint ari = arityval(obj); Uint i; Eterm *hp; GlobalAlloc(from,ari + 1,hp); MA_STACK_UPDATE(dst,MA_STACK_POP(offset),make_tuple(hp)); MA_STACK_POP(dst); *hp = *objp++; for (i = 1; i <= ari; i++) { switch (primary_tag(*objp)) { case TAG_PRIMARY_LIST: case TAG_PRIMARY_BOXED: if (NO_COPY(*objp)) { #ifdef INCREMENTAL if (ptr_within(ptr_val(*objp),inc_fromspc,inc_fromend)) INC_STORE(gray,hp,ari + 1); #endif hp[i] = *objp++; } else { MA_STACK_PUSH(src,*objp++); MA_STACK_PUSH(dst,hp); MA_STACK_PUSH(offset,i); } break; default: hp[i] = *objp++; } } continue; } default: erl_exit(ERTS_ABORT_EXIT, "%s, line %d: Internal error in copy_struct_lazy: 0x%08x\n", __FILE__, __LINE__,obj); } } VERBOSE(DEBUG_MESSAGES, ("Copy allocated @ 0x%08lx:\n%T\n", (unsigned long)ptr_val(dest),dest)); ma_gc_flags &= ~GC_CYCLE_START; ASSERT(eq(orig, dest)); ASSERT(ma_src_top == 0); ASSERT(ma_dst_top == 0); ASSERT(ma_offset_top == 0); return dest; } #undef NO_COPY #endif /* HYBRID */ /* * Copy a term that is guaranteed to be contained in a single * heap block. The heap block is copied word by word, and any * pointers are offsetted to point correctly in the new location. * * Typically used to copy a term from an ets table. * * NOTE: Assumes that term is a tuple (ptr is an untagged tuple ptr). */ Eterm copy_shallow(Eterm* ptr, Uint sz, Eterm** hpp, ErlOffHeap* off_heap) { Eterm* tp = ptr; Eterm* hp = *hpp; Sint offs = hp - tp; while (sz--) { Eterm val = *tp++; switch (primary_tag(val)) { case TAG_PRIMARY_IMMED1: *hp++ = val; break; case TAG_PRIMARY_LIST: case TAG_PRIMARY_BOXED: *hp++ = offset_ptr(val, offs); break; case TAG_PRIMARY_HEADER: *hp++ = val; switch (val & _HEADER_SUBTAG_MASK) { case ARITYVAL_SUBTAG: break; case REFC_BINARY_SUBTAG: { ProcBin* pb = (ProcBin *) (hp-1); int tari = thing_arityval(val); sz -= tari; while (tari--) { *hp++ = *tp++; } erts_refc_inc(&pb->val->refc, 2); pb->next = off_heap->mso; off_heap->mso = pb; off_heap->overhead += pb->size / sizeof(Eterm); } break; case FUN_SUBTAG: { #ifndef HYBRID /* FIND ME! */ ErlFunThing* funp = (ErlFunThing *) (hp-1); #endif int tari = thing_arityval(val); sz -= tari; while (tari--) { *hp++ = *tp++; } #ifndef HYBRID /* FIND ME! */ funp->next = off_heap->funs; off_heap->funs = funp; erts_refc_inc(&funp->fe->refc, 2); #endif } break; case EXTERNAL_PID_SUBTAG: case EXTERNAL_PORT_SUBTAG: case EXTERNAL_REF_SUBTAG: { ExternalThing* etp = (ExternalThing *) (hp-1); int tari = thing_arityval(val); sz -= tari; while (tari--) { *hp++ = *tp++; } etp->next = off_heap->externals; off_heap->externals = etp; erts_refc_inc(&etp->node->refc, 2); } break; default: { int tari = header_arity(val); sz -= tari; while (tari--) { *hp++ = *tp++; } } break; } break; } } *hpp = hp; return make_tuple(ptr + offs); }