// -*- c -*- // // %CopyrightBegin% // // Copyright Ericsson AB 2017-2018. All Rights Reserved. // // Licensed under the Apache License, Version 2.0 (the "License"); // you may not use this file except in compliance with the License. // You may obtain a copy of the License at // // http://www.apache.org/licenses/LICENSE-2.0 // // Unless required by applicable law or agreed to in writing, software // distributed under the License is distributed on an "AS IS" BASIS, // WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied. // See the License for the specific language governing permissions and // limitations under the License. // // %CopyrightEnd% // // // Stack manipulation instructions follow. // // See the comment for AH() in macros.tab for information about // the layout of stack frames. // allocate(NeedStack, Live) { $AH($NeedStack, 0, $Live); } allocate_heap(NeedStack, NeedHeap, Live) { $AH($NeedStack, $NeedHeap, $Live); } allocate_init(NeedStack, Live, Y) { $AH($NeedStack, 0, $Live); make_blank($Y); } allocate_zero(NeedStack, Live) { Eterm* ptr; int i = $NeedStack; $AH(i, 0, $Live); for (ptr = E + i; ptr > E; ptr--) { make_blank(*ptr); } } allocate_heap_zero(NeedStack, NeedHeap, Live) { Eterm* ptr; int i = $NeedStack; $AH(i, $NeedHeap, $Live); for (ptr = E + i; ptr > E; ptr--) { make_blank(*ptr); } } // This instruction is probably never used (because it is combined with a // a return). However, a future compiler might for some reason emit a // deallocate not followed by a return, and that should work. deallocate(Deallocate) { //| -no_prefetch E = ADD_BYTE_OFFSET(E, $Deallocate); } // // Micro-benchmarks showed that the deallocate_return instruction // became slower when the continuation pointer was moved from // the process struct to the stack. The reason seems to be read // dependencies, i.e. that the CPU cannot figure out beforehand // from which position on the stack the continuation pointer // should be fetched. // // Initializing num_bytes with a constant value seems to restore // the lost speed, so we've specialized the instruction for the // most common values. // deallocate_return0 := dealloc_ret.n0.execute; deallocate_return1 := dealloc_ret.n1.execute; deallocate_return2 := dealloc_ret.n2.execute; deallocate_return3 := dealloc_ret.n3.execute; deallocate_return4 := dealloc_ret.n4.execute; deallocate_return := dealloc_ret.var.execute; dealloc_ret.head() { Uint num_bytes; } dealloc_ret.n0() { num_bytes = (0+1) * sizeof(Eterm); } dealloc_ret.n1() { num_bytes = (1+1) * sizeof(Eterm); } dealloc_ret.n2() { num_bytes = (2+1) * sizeof(Eterm); } dealloc_ret.n3() { num_bytes = (3+1) * sizeof(Eterm); } dealloc_ret.n4() { num_bytes = (4+1) * sizeof(Eterm); } dealloc_ret.var(Deallocate) { num_bytes = $Deallocate; } dealloc_ret.execute() { //| -no_next E = ADD_BYTE_OFFSET(E, num_bytes); $RETURN(); CHECK_TERM(x(0)); $DISPATCH_RETURN(); } move_deallocate_return(Src, Deallocate) { //| -no_next /* * Explicitly do reads first to mitigate the impact of read * dependencies. */ Uint bytes_to_pop = $Deallocate; Eterm src = $Src; E = ADD_BYTE_OFFSET(E, bytes_to_pop); x(0) = src; DTRACE_RETURN_FROM_PC(c_p, I); $RETURN(); CHECK_TERM(x(0)); $DISPATCH_RETURN(); } // Call instructions i_call(CallDest) { //| -no_next $SAVE_CONTINUATION_POINTER($NEXT_INSTRUCTION); $DISPATCH_REL($CallDest); } move_call(Src, CallDest) { //| -no_next Eterm call_dest = $CallDest; Eterm src = $Src; $SAVE_CONTINUATION_POINTER($NEXT_INSTRUCTION); x(0) = src; $DISPATCH_REL(call_dest); } i_call_last(CallDest, Deallocate) { //| -no_next $deallocate($Deallocate); $DISPATCH_REL($CallDest); } move_call_last(Src, CallDest, Deallocate) { //| -no_next Eterm call_dest = $CallDest; Eterm src = $Src; $deallocate($Deallocate); x(0) = src; $DISPATCH_REL(call_dest); } i_call_only(CallDest) { //| -no_next $DISPATCH_REL($CallDest); } move_call_only(Src, CallDest) { //| -no_next Eterm call_dest = $CallDest; Eterm src = $Src; x(0) = src; $DISPATCH_REL(call_dest); } i_call_ext(Dest) { //| -no_next $SAVE_CONTINUATION_POINTER($NEXT_INSTRUCTION); $DISPATCH_EXPORT($Dest); } i_move_call_ext(Src, CallDest) { //| -no_next Eterm call_dest = $CallDest; Eterm src = $Src; $SAVE_CONTINUATION_POINTER($NEXT_INSTRUCTION); x(0) = src; $DISPATCH_EXPORT(call_dest); } i_call_ext_only(Dest) { //| -no_next $DISPATCH_EXPORT($Dest); } i_move_call_ext_only(CallDest, Src) { //| -no_next Eterm call_dest = $CallDest; Eterm src = $Src; x(0) = src; $DISPATCH_EXPORT(call_dest); } i_call_ext_last(Dest, Deallocate) { //| -no_next $deallocate($Deallocate); $DISPATCH_EXPORT($Dest); } i_move_call_ext_last(CallDest, Deallocate, Src) { //| -no_next Eterm call_dest = $CallDest; Eterm src = $Src; $deallocate($Deallocate); x(0) = src; $DISPATCH_EXPORT(call_dest); } APPLY(I, Deallocate, Next) { //| -no_next HEAVY_SWAPOUT; $Next = apply(c_p, reg, $I, $Deallocate); HEAVY_SWAPIN; } HANDLE_APPLY_ERROR() { I = handle_error(c_p, I, reg, &bif_export[BIF_apply_3]->info.mfa); goto post_error_handling; } i_apply() { //| -no_next BeamInstr *next; $APPLY(NULL, 0, next); if (ERTS_LIKELY(next != NULL)) { $SAVE_CONTINUATION_POINTER($NEXT_INSTRUCTION); $DISPATCH_ABS(next); } $HANDLE_APPLY_ERROR(); } i_apply_last(Deallocate) { //| -no_next BeamInstr *next; $APPLY(I, $Deallocate, next); if (ERTS_LIKELY(next != NULL)) { $deallocate($Deallocate); $DISPATCH_ABS(next); } $HANDLE_APPLY_ERROR(); } i_apply_only() { //| -no_next BeamInstr *next; $APPLY(I, 0, next); if (ERTS_LIKELY(next != NULL)) { $DISPATCH_ABS(next); } $HANDLE_APPLY_ERROR(); } FIXED_APPLY(Arity, I, Deallocate, Next) { //| -no_next HEAVY_SWAPOUT; $Next = fixed_apply(c_p, reg, $Arity, $I, $Deallocate); HEAVY_SWAPIN; } apply(Arity) { //| -no_next BeamInstr *next; $FIXED_APPLY($Arity, NULL, 0, next); if (ERTS_LIKELY(next != NULL)) { $SAVE_CONTINUATION_POINTER($NEXT_INSTRUCTION); $DISPATCH_ABS(next); } $HANDLE_APPLY_ERROR(); } apply_last(Arity, Deallocate) { //| -no_next BeamInstr *next; $FIXED_APPLY($Arity, I, $Deallocate, next); if (ERTS_LIKELY(next != NULL)) { $deallocate($Deallocate); $DISPATCH_ABS(next); } $HANDLE_APPLY_ERROR(); } APPLY_FUN(Next) { HEAVY_SWAPOUT; $Next = apply_fun(c_p, r(0), x(1), reg); HEAVY_SWAPIN; } HANDLE_APPLY_FUN_ERROR() { goto find_func_info; } i_apply_fun() { //| -no_next BeamInstr *next; $APPLY_FUN(next); if (ERTS_LIKELY(next != NULL)) { $SAVE_CONTINUATION_POINTER($NEXT_INSTRUCTION); $DISPATCH_FUN(next); } $HANDLE_APPLY_FUN_ERROR(); } i_apply_fun_last(Deallocate) { //| -no_next BeamInstr *next; $APPLY_FUN(next); if (ERTS_LIKELY(next != NULL)) { $deallocate($Deallocate); $DISPATCH_FUN(next); } $HANDLE_APPLY_FUN_ERROR(); } i_apply_fun_only() { //| -no_next BeamInstr *next; $APPLY_FUN(next); if (ERTS_LIKELY(next != NULL)) { $DISPATCH_FUN(next); } $HANDLE_APPLY_FUN_ERROR(); } CALL_FUN(Fun, Next) { //| -no_next HEAVY_SWAPOUT; $Next = call_fun(c_p, $Fun, reg, THE_NON_VALUE); HEAVY_SWAPIN; } i_call_fun(Fun) { //| -no_next BeamInstr *next; $CALL_FUN($Fun, next); if (ERTS_LIKELY(next != NULL)) { $SAVE_CONTINUATION_POINTER($NEXT_INSTRUCTION); $DISPATCH_FUN(next); } $HANDLE_APPLY_FUN_ERROR(); } i_call_fun_last(Fun, Deallocate) { //| -no_next BeamInstr *next; $CALL_FUN($Fun, next); if (ERTS_LIKELY(next != NULL)) { $deallocate($Deallocate); $DISPATCH_FUN(next); } $HANDLE_APPLY_FUN_ERROR(); } return() { //| -no_next DTRACE_RETURN_FROM_PC(c_p, I); $RETURN(); CHECK_TERM(r(0)); HEAP_SPACE_VERIFIED(0); $DISPATCH_RETURN(); } get_list(Src, Hd, Tl) { Eterm* tmp_ptr = list_val($Src); Eterm hd, tl; hd = CAR(tmp_ptr); tl = CDR(tmp_ptr); $Hd = hd; $Tl = tl; } get_hd(Src, Hd) { Eterm* tmp_ptr = list_val($Src); $Hd = CAR(tmp_ptr); } get_tl(Src, Tl) { Eterm* tmp_ptr = list_val($Src); $Tl = CDR(tmp_ptr); } i_get(Src, Dst) { $Dst = erts_pd_hash_get(c_p, $Src); } i_get_hash(Src, Hash, Dst) { $Dst = erts_pd_hash_get_with_hx(c_p, $Hash, $Src); } i_get_tuple_element(Src, Element, Dst) { Eterm* src = ADD_BYTE_OFFSET(tuple_val($Src), $Element); $Dst = *src; } i_get_tuple_element2(Src, Element, Dst) { Eterm* src; Eterm* dst; Eterm E1, E2; src = ADD_BYTE_OFFSET(tuple_val($Src), $Element); dst = &($Dst); E1 = src[0]; E2 = src[1]; dst[0] = E1; dst[1] = E2; } i_get_tuple_element2_dst(Src, Element, D1, D2) { Eterm* src; Eterm E1, E2; src = ADD_BYTE_OFFSET(tuple_val($Src), $Element); E1 = src[0]; E2 = src[1]; $D1 = E1; $D2 = E2; } i_get_tuple_element3(Src, Element, Dst) { Eterm* src; Eterm* dst; Eterm E1, E2, E3; src = ADD_BYTE_OFFSET(tuple_val($Src), $Element); dst = &($Dst); E1 = src[0]; E2 = src[1]; E3 = src[2]; dst[0] = E1; dst[1] = E2; dst[2] = E3; } i_element := element_group.fetch.execute; element_group.head() { Eterm element_tuple; } element_group.fetch(Src) { element_tuple = $Src; } element_group.execute(Fail, Index, Dst) { Eterm element_index = $Index; if (ERTS_LIKELY(is_small(element_index) && is_tuple(element_tuple))) { Eterm* tp = tuple_val(element_tuple); if ((signed_val(element_index) >= 1) && (signed_val(element_index) <= arityval(*tp))) { $Dst = tp[signed_val(element_index)]; $NEXT0(); } } c_p->freason = BADARG; $BIF_ERROR_ARITY_2($Fail, BIF_element_2, element_index, element_tuple); } i_fast_element := fast_element_group.fetch.execute; fast_element_group.head() { Eterm fast_element_tuple; } fast_element_group.fetch(Src) { fast_element_tuple = $Src; } fast_element_group.execute(Fail, Index, Dst) { if (ERTS_LIKELY(is_tuple(fast_element_tuple))) { Eterm* tp = tuple_val(fast_element_tuple); Eterm pos = $Index; /* Untagged integer >= 1 */ if (pos <= arityval(*tp)) { $Dst = tp[pos]; $NEXT0(); } } c_p->freason = BADARG; $BIF_ERROR_ARITY_2($Fail, BIF_element_2, make_small($Index), fast_element_tuple); } init(Y) { make_blank($Y); } init_seq3(Y1) { Eterm* dst = &$Y1; make_blank(dst[0]); make_blank(dst[1]); make_blank(dst[2]); } init_seq4(Y1) { Eterm* dst = &$Y1; make_blank(dst[0]); make_blank(dst[1]); make_blank(dst[2]); make_blank(dst[3]); } init_seq5(Y1) { Eterm* dst = &$Y1; make_blank(dst[0]); make_blank(dst[1]); make_blank(dst[2]); make_blank(dst[3]); make_blank(dst[4]); } init2(Y1, Y2) { make_blank($Y1); make_blank($Y2); } init3(Y1, Y2, Y3) { make_blank($Y1); make_blank($Y2); make_blank($Y3); } i_make_fun(FunP, NumFree) { HEAVY_SWAPOUT; x(0) = new_fun(c_p, reg, (ErlFunEntry *) $FunP, $NumFree); HEAVY_SWAPIN; } move_trim(Src, Dst, Words) { $Dst = $Src; $i_trim($Words); } i_trim(Words) { E += $Words; /* * Clear the reserved location for the continuation pointer at * E[0]. This is not strictly necessary for correctness, but if a * GC is triggered before E[0] is overwritten by another * continuation pointer the now dead term at E[0] would be * retained by the GC. */ E[0] = NIL; } move(Src, Dst) { $Dst = $Src; } move3(S1, D1, S2, D2, S3, D3) { $D1 = $S1; $D2 = $S2; $D3 = $S3; } move2_par(S1, D1, S2, D2) { Eterm V1, V2; V1 = $S1; V2 = $S2; $D1 = V1; $D2 = V2; } move_shift(Src, SD, D) { Eterm V; V = $Src; $D = $SD; $SD = V; } move_src_window2(Src, D1, D2) { Eterm* src = &$Src; Eterm s1, s2; s1 = src[0]; s2 = src[1]; $D1 = s1; $D2 = s2; } move_src_window3(Src, D1, D2, D3) { Eterm* src = &$Src; Eterm s1, s2, s3; s1 = src[0]; s2 = src[1]; s3 = src[2]; $D1 = s1; $D2 = s2; $D3 = s3; } move_src_window4(Src, D1, D2, D3, D4) { Eterm* src = &$Src; Eterm s1, s2, s3, s4; s1 = src[0]; s2 = src[1]; s3 = src[2]; s4 = src[3]; $D1 = s1; $D2 = s2; $D3 = s3; $D4 = s4; } move_window2(S1, S2, D) { Eterm xt0, xt1; Eterm* y = &$D; xt0 = $S1; xt1 = $S2; y[0] = xt0; y[1] = xt1; } move_window3(S1, S2, S3, D) { Eterm xt0, xt1, xt2; Eterm* y = &$D; xt0 = $S1; xt1 = $S2; xt2 = $S3; y[0] = xt0; y[1] = xt1; y[2] = xt2; } move_window4(S1, S2, S3, S4, D) { Eterm xt0, xt1, xt2, xt3; Eterm* y = &$D; xt0 = $S1; xt1 = $S2; xt2 = $S3; xt3 = $S4; y[0] = xt0; y[1] = xt1; y[2] = xt2; y[3] = xt3; } move_window5(S1, S2, S3, S4, S5, D) { Eterm xt0, xt1, xt2, xt3, xt4; Eterm *y = &$D; xt0 = $S1; xt1 = $S2; xt2 = $S3; xt3 = $S4; xt4 = $S5; y[0] = xt0; y[1] = xt1; y[2] = xt2; y[3] = xt3; y[4] = xt4; } move_return(Src) { //| -no_next x(0) = $Src; DTRACE_RETURN_FROM_PC(c_p, I); $RETURN(); $DISPATCH_RETURN(); } move_x1(Src) { x(1) = $Src; } move_x2(Src) { x(2) = $Src; } node(Dst) { $Dst = erts_this_node->sysname; } put_list(Hd, Tl, Dst) { HTOP[0] = $Hd; HTOP[1] = $Tl; $Dst = make_list(HTOP); HTOP += 2; } update_list(Hd, Dst) { HTOP[0] = $Hd; HTOP[1] = $Dst; $Dst = make_list(HTOP); HTOP += 2; } put_tuple2(Dst, Arity) { Eterm* hp = HTOP; Eterm arity = $Arity; /* * If operands are not packed (in the 32-bit VM), * is is not safe to use $Dst directly after I * has been updated. */ Eterm* dst_ptr = &($Dst); //| -no_next ASSERT(arity != 0); *hp++ = make_arityval(arity); I = $NEXT_INSTRUCTION; do { Eterm term = *I++; switch (loader_tag(term)) { case LOADER_X_REG: *hp++ = x(loader_x_reg_index(term)); break; case LOADER_Y_REG: *hp++ = y(loader_y_reg_index(term)); break; default: *hp++ = term; break; } } while (--arity != 0); *dst_ptr = make_tuple(HTOP); HTOP = hp; ASSERT(VALID_INSTR(* (Eterm *)I)); Goto(*I); } self(Dst) { $Dst = c_p->common.id; } set_tuple_element(Element, Tuple, Offset) { Eterm* p; ASSERT(is_tuple($Tuple)); p = (Eterm *) ((unsigned char *) tuple_val($Tuple) + $Offset); *p = $Element; } swap(R1, R2) { Eterm V = $R1; $R1 = $R2; $R2 = V; } swap2(R1, R2, R3) { Eterm V = $R2; $R2 = $R1; $R1 = $R3; $R3 = V; } test_heap(Nh, Live) { $GC_TEST(0, $Nh, $Live); } test_heap_1_put_list(Nh, Reg) { $test_heap($Nh, 1); $put_list($Reg, x(0), x(0)); } is_integer_allocate(Fail, Src, NeedStack, Live) { //| -no_prefetch $is_integer($Fail, $Src); $AH($NeedStack, 0, $Live); } is_nonempty_list(Fail, Src) { //| -no_prefetch if (is_not_list($Src)) { $FAIL($Fail); } } is_nonempty_list_allocate(Fail, Src, Need, Live) { //| -no_prefetch $is_nonempty_list($Fail, $Src); $AH($Need, 0, $Live); } is_nonempty_list_get_list(Fail, Src, Hd, Tl) { //| -no_prefetch $is_nonempty_list($Fail, $Src); $get_list($Src, $Hd, $Tl); } is_nonempty_list_get_hd(Fail, Src, Hd) { //| -no_prefetch $is_nonempty_list($Fail, $Src); $get_hd($Src, $Hd); } is_nonempty_list_get_tl(Fail, Src, Tl) { //| -no_prefetch $is_nonempty_list($Fail, $Src); $get_tl($Src, $Tl); } jump(Fail) { $JUMP($Fail); } move_jump(Lbl, Src, Dst) { Eterm lbl = $Lbl; Eterm src = $Src; $Dst = src; $JUMP(lbl); } // // Test instructions. // is_atom(Fail, Src) { if (is_not_atom($Src)) { $FAIL($Fail); } } is_boolean(Fail, Src) { if (($Src) != am_true && ($Src) != am_false) { $FAIL($Fail); } } is_binary(Fail, Src) { if (is_not_binary($Src) || binary_bitsize($Src) != 0) { $FAIL($Fail); } } is_bitstring(Fail, Src) { if (is_not_binary($Src)) { $FAIL($Fail); } } is_float(Fail, Src) { if (is_not_float($Src)) { $FAIL($Fail); } } is_function(Fail, Src) { if ( !(is_any_fun($Src)) ) { $FAIL($Fail); } } cold_is_function2(Fail, Fun, Arity) { if (erl_is_function(c_p, $Fun, $Arity) != am_true ) { $FAIL($Fail); } } hot_is_function2(Fail, Fun, Arity) { if (!is_function2($Fun, $Arity)) { $FAIL($Fail); } } is_integer(Fail, Src) { if (is_not_integer($Src)) { $FAIL($Fail); } } is_list(Fail, Src) { if (is_not_list($Src) && is_not_nil($Src)) { $FAIL($Fail); } } is_map(Fail, Src) { if (is_not_map($Src)) { $FAIL($Fail); } } is_nil(Fail, Src) { if (is_not_nil($Src)) { $FAIL($Fail); } } is_number(Fail, Src) { if (is_not_integer($Src) && is_not_float($Src)) { $FAIL($Fail); } } is_pid(Fail, Src) { if (is_not_pid($Src)) { $FAIL($Fail); } } is_port(Fail, Src) { if (is_not_port($Src)) { $FAIL($Fail); } } is_reference(Fail, Src) { if (is_not_ref($Src)) { $FAIL($Fail); } } is_tagged_tuple(Fail, Src, Arityval, Tag) { Eterm term = $Src; if (!(BEAM_IS_TUPLE(term) && (tuple_val(term))[0] == $Arityval && (tuple_val(term))[1] == $Tag)) { $FAIL($Fail); } } is_tagged_tuple_ff(NotTupleFail, WrongRecordFail, Src, Arityval, Tag) { Eterm term = $Src; if (is_not_tuple(term)) { $FAIL($NotTupleFail); } else if (ERTS_UNLIKELY((tuple_val(term))[0] != $Arityval || (tuple_val(term))[1] != $Tag)) { $FAIL($WrongRecordFail); } } is_tuple(Fail, Src) { if (is_not_tuple($Src)) { $FAIL($Fail); } } is_tuple_of_arity(Fail, Src, Arityval) { Eterm term = $Src; if (!(BEAM_IS_TUPLE(term) && *tuple_val(term) == $Arityval)) { $FAIL($Fail); } } test_arity(Fail, Pointer, Arity) { if (*tuple_val($Pointer) != $Arity) { $FAIL($Fail); } } test_arity_get_tuple_element(Fail, Pointer, Arity, Pos, Dst) { Eterm* ptr = tuple_val($Pointer); Eterm* src; if (*ptr != $Arity) { $FAIL($Fail); } src = ADD_BYTE_OFFSET(ptr, $Pos); $Dst = *src; } i_is_eq_exact_immed(Fail, X, Y) { if ($X != $Y) { $FAIL($Fail); } } i_is_ne_exact_immed(Fail, X, Y) { if ($X == $Y) { $FAIL($Fail); } } is_eq_exact(Fail, X, Y) { if (!EQ($X, $Y)) { $FAIL($Fail); } } i_is_eq_exact_literal(Fail, Src, Literal) { Eterm src = $Src; if (is_immed(src) || !eq(src, $Literal)) { $FAIL($Fail); } } is_ne_exact(Fail, X, Y) { if (EQ($X, $Y)) { $FAIL($Fail); } } i_is_ne_exact_literal(Fail, Src, Literal) { Eterm src = $Src; if (!is_immed(src) && eq(src, $Literal)) { $FAIL($Fail); } } is_eq(Fail, A, B) { Eterm a = $A; Eterm b = $B; CMP_EQ_ACTION(a, b, $FAIL($Fail)); } is_ne(Fail, A, B) { Eterm a = $A; Eterm b = $B; CMP_NE_ACTION(a, b, $FAIL($Fail)); } is_lt(Fail, X, Y) { CMP_LT_ACTION($X, $Y, $FAIL($Fail)); } is_ge(Fail, X, Y) { CMP_GE_ACTION($X, $Y, $FAIL($Fail)); } badarg(Fail) { $BADARG($Fail); //| -no_next; } badmatch(Src) { c_p->fvalue = $Src; c_p->freason = BADMATCH; goto find_func_info; //| -no_next; } case_end(Src) { c_p->fvalue = $Src; c_p->freason = EXC_CASE_CLAUSE; goto find_func_info; //| -no_next; } if_end() { c_p->freason = EXC_IF_CLAUSE; goto find_func_info; //| -no_next; } system_limit(Fail) { $SYSTEM_LIMIT($Fail); //| -no_next; } catch(Y, Fail) { c_p->catches++; $Y = $Fail; } catch_end(Y) { $try_end($Y); if (is_non_value(r(0))) { c_p->fvalue = NIL; if (x(1) == am_throw) { r(0) = x(2); } else { if (x(1) == am_error) { SWAPOUT; x(2) = add_stacktrace(c_p, x(2), x(3)); SWAPIN; } /* only x(2) is included in the rootset here */ if (E - HTOP < 3) { $GC_SWAPOUT(); PROCESS_MAIN_CHK_LOCKS(c_p); FCALLS -= erts_garbage_collect_nobump(c_p, 3, reg+2, 1, FCALLS); ERTS_VERIFY_UNUSED_TEMP_ALLOC(c_p); PROCESS_MAIN_CHK_LOCKS(c_p); SWAPIN; } r(0) = TUPLE2(HTOP, am_EXIT, x(2)); HTOP += 3; } } CHECK_TERM(r(0)); } try_end(Y) { c_p->catches--; make_blank($Y); } try_case(Y) { $try_end($Y); ASSERT(is_non_value(r(0))); c_p->fvalue = NIL; r(0) = x(1); x(1) = x(2); x(2) = x(3); } try_case_end(Src) { c_p->fvalue = $Src; c_p->freason = EXC_TRY_CLAUSE; goto find_func_info; //| -no_next; } i_raise() { Eterm raise_trace = x(2); Eterm raise_value = x(1); struct StackTrace *s; c_p->fvalue = raise_value; c_p->ftrace = raise_trace; s = get_trace_from_exc(raise_trace); if (s == NULL) { c_p->freason = EXC_ERROR; } else { c_p->freason = PRIMARY_EXCEPTION(s->freason); } goto find_func_info; //| -no_next } build_stacktrace() { SWAPOUT; x(0) = build_stacktrace(c_p, x(0)); SWAPIN; } raw_raise() { //| -no_prefetch Eterm class = x(0); Eterm value = x(1); Eterm stacktrace = x(2); Eterm* freason_ptr; /* * Note that the i_raise instruction will override c_p->freason * with the freason field stored inside the StackTrace struct in * ftrace. Therefore, we must take care to store the class both * inside the StackTrace struct and in c_p->freason (important if * the class is different from the class of the original * exception). */ freason_ptr = get_freason_ptr_from_exc(stacktrace); if (class == am_error) { *freason_ptr = c_p->freason = EXC_ERROR & ~EXF_SAVETRACE; c_p->fvalue = value; c_p->ftrace = stacktrace; goto find_func_info; } else if (class == am_exit) { *freason_ptr = c_p->freason = EXC_EXIT & ~EXF_SAVETRACE; c_p->fvalue = value; c_p->ftrace = stacktrace; goto find_func_info; } else if (class == am_throw) { *freason_ptr = c_p->freason = EXC_THROWN & ~EXF_SAVETRACE; c_p->fvalue = value; c_p->ftrace = stacktrace; goto find_func_info; } else { x(0) = am_badarg; } }