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|
/*
* %CopyrightBegin%
*
* Copyright Ericsson AB 1996-2017. 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%
*/
#ifdef HAVE_CONFIG_H
# include "config.h"
#endif
#include <stddef.h> /* offsetof() */
#include "sys.h"
#include "erl_vm.h"
#include "global.h"
#include "erl_process.h"
#include "error.h"
#include "bif.h"
#include "big.h"
#include "beam_load.h"
#include "erl_binary.h"
#include "erl_map.h"
#include "erl_bits.h"
#include "dist.h"
#include "beam_bp.h"
#include "beam_catches.h"
#include "erl_thr_progress.h"
#include "erl_nfunc_sched.h"
#ifdef HIPE
#include "hipe_mode_switch.h"
#include "hipe_bif1.h"
#endif
#include "dtrace-wrapper.h"
/* #define HARDDEBUG 1 */
#if defined(NO_JUMP_TABLE)
# define OpCase(OpCode) case op_##OpCode
# define CountCase(OpCode) case op_count_##OpCode
# define IsOpCode(InstrWord, OpCode) ((InstrWord) == (BeamInstr)op_##OpCode)
# define Goto(Rel) {Go = (Rel); goto emulator_loop;}
#else
# define OpCase(OpCode) lb_##OpCode
# define CountCase(OpCode) lb_count_##OpCode
# define IsOpCode(InstrWord, OpCode) ((InstrWord) == (BeamInstr)&&lb_##OpCode)
# define Goto(Rel) goto *((void *)Rel)
# define LabelAddr(Label) &&Label
#endif
#ifdef ERTS_ENABLE_LOCK_CHECK
# define PROCESS_MAIN_CHK_LOCKS(P) \
do { \
if ((P)) \
erts_proc_lc_chk_only_proc_main((P)); \
ERTS_LC_ASSERT(!erts_thr_progress_is_blocking()); \
} while (0)
# define ERTS_REQ_PROC_MAIN_LOCK(P) \
do { \
if ((P)) \
erts_proc_lc_require_lock((P), ERTS_PROC_LOCK_MAIN, \
__FILE__, __LINE__); \
} while (0)
# define ERTS_UNREQ_PROC_MAIN_LOCK(P) \
do { \
if ((P)) \
erts_proc_lc_unrequire_lock((P), ERTS_PROC_LOCK_MAIN); \
} while (0)
#else
# define PROCESS_MAIN_CHK_LOCKS(P)
# define ERTS_REQ_PROC_MAIN_LOCK(P)
# define ERTS_UNREQ_PROC_MAIN_LOCK(P)
#endif
/*
* Define macros for deep checking of terms.
*/
#if defined(HARDDEBUG)
# define CHECK_TERM(T) size_object(T)
# define CHECK_ARGS(PC) \
do { \
int i_; \
int Arity_ = PC[-1]; \
for (i_ = 0; i_ < Arity_; i_++) { \
CHECK_TERM(x(i_)); \
} \
} while (0)
#else
# define CHECK_TERM(T) ASSERT(!is_CP(T))
# define CHECK_ARGS(T)
#endif
#define CHECK_ALIGNED(Dst) ASSERT((((Uint)&Dst) & (sizeof(Uint)-1)) == 0)
#define GET_BIF_MODULE(p) (p->info.mfa.module)
#define GET_BIF_FUNCTION(p) (p->info.mfa.function)
#define GET_BIF_ARITY(p) (p->info.mfa.arity)
#define GET_BIF_ADDRESS(p) ((BifFunction) (p->beam[1]))
#define TermWords(t) (((t) / (sizeof(BeamInstr)/sizeof(Eterm))) + !!((t) % (sizeof(BeamInstr)/sizeof(Eterm))))
/*
* We reuse some of fields in the save area in the process structure.
* This is safe to do, since this space is only actively used when
* the process is switched out.
*/
#define REDS_IN(p) ((p)->def_arg_reg[5])
/*
* Add a byte offset to a pointer to Eterm. This is useful when the
* the loader has precalculated a byte offset.
*/
#define ADD_BYTE_OFFSET(ptr, offset) \
((Eterm *) (((unsigned char *)ptr) + (offset)))
/* We don't check the range if an ordinary switch is used */
#ifdef NO_JUMP_TABLE
#define VALID_INSTR(IP) ((UWord)(IP) < (NUMBER_OF_OPCODES*2+10))
#else
#define VALID_INSTR(IP) \
((SWord)LabelAddr(emulator_loop) <= (SWord)(IP) && \
(SWord)(IP) < (SWord)LabelAddr(end_emulator_loop))
#endif /* NO_JUMP_TABLE */
#define SET_CP(p, ip) \
ASSERT(VALID_INSTR(*(ip))); \
(p)->cp = (ip)
#define SET_I(ip) \
ASSERT(VALID_INSTR(* (Eterm *)(ip))); \
I = (ip)
/*
* Register target (X or Y register).
*/
#define REG_TARGET_PTR(Target) (((Target) & 1) ? &yb((Target)-1) : &xb(Target))
/*
* Special Beam instructions.
*/
BeamInstr beam_apply[2];
BeamInstr beam_exit[1];
BeamInstr beam_continue_exit[1];
/* NOTE These should be the only variables containing trace instructions.
** Sometimes tests are form the instruction value, and sometimes
** for the referring variable (one of these), and rouge references
** will most likely cause chaos.
*/
BeamInstr beam_return_to_trace[1]; /* OpCode(i_return_to_trace) */
BeamInstr beam_return_trace[1]; /* OpCode(i_return_trace) */
BeamInstr beam_exception_trace[1]; /* UGLY also OpCode(i_return_trace) */
BeamInstr beam_return_time_trace[1]; /* OpCode(i_return_time_trace) */
/*
* All Beam instructions in numerical order.
*/
#ifndef NO_JUMP_TABLE
void** beam_ops;
#endif
#define SWAPIN \
HTOP = HEAP_TOP(c_p); \
E = c_p->stop
#define SWAPOUT \
HEAP_TOP(c_p) = HTOP; \
c_p->stop = E
#define HEAVY_SWAPIN \
SWAPIN; \
FCALLS = c_p->fcalls
#define HEAVY_SWAPOUT \
SWAPOUT; \
c_p->fcalls = FCALLS
/*
* Use LIGHT_SWAPOUT when the called function
* will call HeapOnlyAlloc() (and never HAlloc()).
*/
#ifdef DEBUG
# /* The stack pointer is used in an assertion. */
# define LIGHT_SWAPOUT SWAPOUT
#else
# define LIGHT_SWAPOUT HEAP_TOP(c_p) = HTOP
#endif
/*
* Use LIGHT_SWAPIN when we know that c_p->stop cannot
* have been updated (i.e. if there cannot have been
* a garbage-collection).
*/
#define LIGHT_SWAPIN HTOP = HEAP_TOP(c_p)
#ifdef FORCE_HEAP_FRAGS
# define HEAP_SPACE_VERIFIED(Words) do { \
c_p->space_verified = (Words); \
c_p->space_verified_from = HTOP; \
}while(0)
#else
# define HEAP_SPACE_VERIFIED(Words) ((void)0)
#endif
#define PRE_BIF_SWAPOUT(P) \
HEAP_TOP((P)) = HTOP; \
(P)->stop = E; \
PROCESS_MAIN_CHK_LOCKS((P)); \
ERTS_UNREQ_PROC_MAIN_LOCK((P))
#define db(N) (N)
#define fb(N) ((Sint)(Sint32)(N))
#define jb(N) ((Sint)(Sint32)(N))
#define tb(N) (N)
#define xb(N) (*(Eterm *) (((unsigned char *)reg) + (N)))
#define yb(N) (*(Eterm *) (((unsigned char *)E) + (N)))
#define Sb(N) (*REG_TARGET_PTR(N))
#define lb(N) (*(double *) (((unsigned char *)&(freg[0].fd)) + (N)))
#define Qb(N) (N)
#define Ib(N) (N)
#define x(N) reg[N]
#define y(N) E[N]
#define r(N) x(N)
/*
* Check that we haven't used the reductions and jump to function pointed to by
* the I register. If we are out of reductions, do a context switch.
*/
#define DispatchMacro() \
do { \
BeamInstr dis_next; \
dis_next = *I; \
CHECK_ARGS(I); \
if (FCALLS > 0 || FCALLS > neg_o_reds) { \
FCALLS--; \
Goto(dis_next); \
} else { \
goto context_switch; \
} \
} while (0) \
#define DispatchMacroFun() \
do { \
BeamInstr dis_next; \
dis_next = *I; \
CHECK_ARGS(I); \
if (FCALLS > 0 || FCALLS > neg_o_reds) { \
FCALLS--; \
Goto(dis_next); \
} else { \
goto context_switch_fun; \
} \
} while (0)
#define DispatchMacrox() \
do { \
if (FCALLS > 0) { \
BeamInstr dis_next; \
SET_I(((Export *) Arg(0))->addressv[erts_active_code_ix()]); \
dis_next = *I; \
FCALLS--; \
CHECK_ARGS(I); \
Goto(dis_next); \
} else if (ERTS_PROC_GET_SAVED_CALLS_BUF(c_p) \
&& FCALLS > neg_o_reds) { \
goto save_calls1; \
} else { \
SET_I(((Export *) Arg(0))->addressv[erts_active_code_ix()]); \
CHECK_ARGS(I); \
goto context_switch; \
} \
} while (0)
#ifdef DEBUG
/*
* To simplify breakpoint setting, put the code in one place only and jump to it.
*/
# define Dispatch() goto do_dispatch
# define Dispatchx() goto do_dispatchx
# define Dispatchfun() goto do_dispatchfun
#else
/*
* Inline for speed.
*/
# define Dispatch() DispatchMacro()
# define Dispatchx() DispatchMacrox()
# define Dispatchfun() DispatchMacroFun()
#endif
#define Arg(N) I[(N)+1]
#define GetR(pos, tr) \
do { \
tr = Arg(pos); \
switch (loader_tag(tr)) { \
case LOADER_X_REG: \
tr = x(loader_x_reg_index(tr)); \
break; \
case LOADER_Y_REG: \
ASSERT(loader_y_reg_index(tr) >= 1); \
tr = y(loader_y_reg_index(tr)); \
break; \
} \
CHECK_TERM(tr); \
} while (0)
#define PUT_TERM_REG(term, desc) \
do { \
switch (loader_tag(desc)) { \
case LOADER_X_REG: \
x(loader_x_reg_index(desc)) = (term); \
break; \
case LOADER_Y_REG: \
y(loader_y_reg_index(desc)) = (term); \
break; \
default: \
ASSERT(0); \
break; \
} \
} while(0)
#define DispatchReturn \
do { \
if (FCALLS > 0 || FCALLS > neg_o_reds) { \
FCALLS--; \
Goto(*I); \
} \
else { \
c_p->current = NULL; \
c_p->arity = 1; \
goto context_switch3; \
} \
} while (0)
#ifdef DEBUG
/* Better static type testing by the C compiler */
# define BEAM_IS_TUPLE(Src) is_tuple(Src)
#else
/* Better performance */
# define BEAM_IS_TUPLE(Src) is_boxed(Src)
#endif
/*
* process_main() is already huge, so we want to avoid inlining
* into it. Especially functions that are seldom used.
*/
#ifdef __GNUC__
# define NOINLINE __attribute__((__noinline__))
#else
# define NOINLINE
#endif
/*
* The following functions are called directly by process_main().
* Don't inline them.
*/
static void init_emulator_finish(void) NOINLINE;
static ErtsCodeMFA *ubif2mfa(void* uf) NOINLINE;
static ErtsCodeMFA *gcbif2mfa(void* gcf) NOINLINE;
static BeamInstr* handle_error(Process* c_p, BeamInstr* pc,
Eterm* reg, ErtsCodeMFA* bif_mfa) NOINLINE;
static BeamInstr* call_error_handler(Process* p, ErtsCodeMFA* mfa,
Eterm* reg, Eterm func) NOINLINE;
static BeamInstr* fixed_apply(Process* p, Eterm* reg, Uint arity,
BeamInstr *I, Uint offs) NOINLINE;
static BeamInstr* apply(Process* p, Eterm* reg,
BeamInstr *I, Uint offs) NOINLINE;
static BeamInstr* call_fun(Process* p, int arity,
Eterm* reg, Eterm args) NOINLINE;
static BeamInstr* apply_fun(Process* p, Eterm fun,
Eterm args, Eterm* reg) NOINLINE;
static Eterm new_fun(Process* p, Eterm* reg,
ErlFunEntry* fe, int num_free) NOINLINE;
static Eterm new_map(Process* p, Eterm* reg, Uint live, Uint n, BeamInstr* ptr) NOINLINE;
static Eterm new_small_map_lit(Process* p, Eterm* reg, Eterm keys_literal,
Uint live, BeamInstr* ptr) NOINLINE;
static Eterm update_map_assoc(Process* p, Eterm* reg, Uint live,
Uint n, BeamInstr* new_p) NOINLINE;
static Eterm update_map_exact(Process* p, Eterm* reg, Uint live,
Uint n, Eterm* new_p) NOINLINE;
static Eterm get_map_element(Eterm map, Eterm key);
static Eterm get_map_element_hash(Eterm map, Eterm key, Uint32 hx);
/*
* Functions not directly called by process_main(). OK to inline.
*/
static BeamInstr* next_catch(Process* c_p, Eterm *reg);
static void terminate_proc(Process* c_p, Eterm Value);
static Eterm add_stacktrace(Process* c_p, Eterm Value, Eterm exc);
static void save_stacktrace(Process* c_p, BeamInstr* pc, Eterm* reg,
ErtsCodeMFA *bif_mfa, Eterm args);
static struct StackTrace * get_trace_from_exc(Eterm exc);
static Eterm make_arglist(Process* c_p, Eterm* reg, int a);
void
init_emulator(void)
{
process_main(0, 0);
}
/*
* On certain platforms, make sure that the main variables really are placed
* in registers.
*/
#if defined(__GNUC__) && defined(sparc) && !defined(DEBUG)
# define REG_xregs asm("%l1")
# define REG_htop asm("%l2")
# define REG_stop asm("%l3")
# define REG_I asm("%l4")
# define REG_fcalls asm("%l5")
#elif defined(__GNUC__) && defined(__amd64__) && !defined(DEBUG)
# define REG_xregs asm("%r12")
# define REG_htop
# define REG_stop asm("%r13")
# define REG_I asm("%rbx")
# define REG_fcalls asm("%r14")
#else
# define REG_xregs
# define REG_htop
# define REG_stop
# define REG_I
# define REG_fcalls
#endif
#ifdef USE_VM_PROBES
# define USE_VM_CALL_PROBES
#endif
#ifdef USE_VM_CALL_PROBES
#define DTRACE_LOCAL_CALL(p, mfa) \
if (DTRACE_ENABLED(local_function_entry)) { \
DTRACE_CHARBUF(process_name, DTRACE_TERM_BUF_SIZE); \
DTRACE_CHARBUF(mfa_buf, DTRACE_TERM_BUF_SIZE); \
int depth = STACK_START(p) - STACK_TOP(p); \
dtrace_fun_decode(p, mfa, process_name, mfa_buf); \
DTRACE3(local_function_entry, process_name, mfa_buf, depth); \
}
#define DTRACE_GLOBAL_CALL(p, mfa) \
if (DTRACE_ENABLED(global_function_entry)) { \
DTRACE_CHARBUF(process_name, DTRACE_TERM_BUF_SIZE); \
DTRACE_CHARBUF(mfa_buf, DTRACE_TERM_BUF_SIZE); \
int depth = STACK_START(p) - STACK_TOP(p); \
dtrace_fun_decode(p, mfa, process_name, mfa_buf); \
DTRACE3(global_function_entry, process_name, mfa_buf, depth); \
}
#define DTRACE_RETURN(p, mfa) \
if (DTRACE_ENABLED(function_return)) { \
DTRACE_CHARBUF(process_name, DTRACE_TERM_BUF_SIZE); \
DTRACE_CHARBUF(mfa_buf, DTRACE_TERM_BUF_SIZE); \
int depth = STACK_START(p) - STACK_TOP(p); \
dtrace_fun_decode(p, mfa, process_name, mfa_buf); \
DTRACE3(function_return, process_name, mfa_buf, depth); \
}
#define DTRACE_BIF_ENTRY(p, mfa) \
if (DTRACE_ENABLED(bif_entry)) { \
DTRACE_CHARBUF(process_name, DTRACE_TERM_BUF_SIZE); \
DTRACE_CHARBUF(mfa_buf, DTRACE_TERM_BUF_SIZE); \
dtrace_fun_decode(p, mfa, process_name, mfa_buf); \
DTRACE2(bif_entry, process_name, mfa_buf); \
}
#define DTRACE_BIF_RETURN(p, mfa) \
if (DTRACE_ENABLED(bif_return)) { \
DTRACE_CHARBUF(process_name, DTRACE_TERM_BUF_SIZE); \
DTRACE_CHARBUF(mfa_buf, DTRACE_TERM_BUF_SIZE); \
dtrace_fun_decode(p, mfa, process_name, mfa_buf); \
DTRACE2(bif_return, process_name, mfa_buf); \
}
#define DTRACE_NIF_ENTRY(p, mfa) \
if (DTRACE_ENABLED(nif_entry)) { \
DTRACE_CHARBUF(process_name, DTRACE_TERM_BUF_SIZE); \
DTRACE_CHARBUF(mfa_buf, DTRACE_TERM_BUF_SIZE); \
dtrace_fun_decode(p, mfa, process_name, mfa_buf); \
DTRACE2(nif_entry, process_name, mfa_buf); \
}
#define DTRACE_NIF_RETURN(p, mfa) \
if (DTRACE_ENABLED(nif_return)) { \
DTRACE_CHARBUF(process_name, DTRACE_TERM_BUF_SIZE); \
DTRACE_CHARBUF(mfa_buf, DTRACE_TERM_BUF_SIZE); \
dtrace_fun_decode(p, mfa, process_name, mfa_buf); \
DTRACE2(nif_return, process_name, mfa_buf); \
}
#define DTRACE_GLOBAL_CALL_FROM_EXPORT(p,e) \
do { \
if (DTRACE_ENABLED(global_function_entry)) { \
BeamInstr* fp = (BeamInstr *) (((Export *) (e))->addressv[erts_active_code_ix()]); \
DTRACE_GLOBAL_CALL((p), erts_code_to_codemfa(fp)); \
} \
} while(0)
#define DTRACE_RETURN_FROM_PC(p) \
do { \
ErtsCodeMFA* cmfa; \
if (DTRACE_ENABLED(function_return) && (cmfa = find_function_from_pc((p)->cp))) { \
DTRACE_RETURN((p), cmfa); \
} \
} while(0)
#else /* USE_VM_PROBES */
#define DTRACE_LOCAL_CALL(p, mfa) do {} while (0)
#define DTRACE_GLOBAL_CALL(p, mfa) do {} while (0)
#define DTRACE_GLOBAL_CALL_FROM_EXPORT(p, e) do {} while (0)
#define DTRACE_RETURN(p, mfa) do {} while (0)
#define DTRACE_RETURN_FROM_PC(p) do {} while (0)
#define DTRACE_BIF_ENTRY(p, mfa) do {} while (0)
#define DTRACE_BIF_RETURN(p, mfa) do {} while (0)
#define DTRACE_NIF_ENTRY(p, mfa) do {} while (0)
#define DTRACE_NIF_RETURN(p, mfa) do {} while (0)
#endif /* USE_VM_PROBES */
#ifdef DEBUG
#define ERTS_DBG_CHK_REDS(P, FC) \
do { \
if (ERTS_PROC_GET_SAVED_CALLS_BUF((P))) { \
ASSERT(FC <= 0); \
ASSERT(erts_proc_sched_data(c_p)->virtual_reds \
<= 0 - (FC)); \
} \
else { \
ASSERT(FC <= CONTEXT_REDS); \
ASSERT(erts_proc_sched_data(c_p)->virtual_reds \
<= CONTEXT_REDS - (FC)); \
} \
} while (0)
#else
#define ERTS_DBG_CHK_REDS(P, FC)
#endif
#ifdef NO_FPE_SIGNALS
# define ERTS_NO_FPE_CHECK_INIT ERTS_FP_CHECK_INIT
# define ERTS_NO_FPE_ERROR ERTS_FP_ERROR
#else
# define ERTS_NO_FPE_CHECK_INIT(p)
# define ERTS_NO_FPE_ERROR(p, a, b)
#endif
/*
* process_main() is called twice:
* The first call performs some initialisation, including exporting
* the instructions' C labels to the loader.
* The second call starts execution of BEAM code. This call never returns.
*/
void process_main(Eterm * x_reg_array, FloatDef* f_reg_array)
{
static int init_done = 0;
Process* c_p = NULL;
int reds_used;
#ifdef DEBUG
ERTS_DECLARE_DUMMY(Eterm pid);
#endif
/* Pointer to X registers: x(1)..x(N); reg[0] is used when doing GC,
* in all other cases x0 is used.
*/
register Eterm* reg REG_xregs = x_reg_array;
/*
* Top of heap (next free location); grows upwards.
*/
register Eterm* HTOP REG_htop = NULL;
/* Stack pointer. Grows downwards; points
* to last item pushed (normally a saved
* continuation pointer).
*/
register Eterm* E REG_stop = NULL;
/*
* Pointer to next threaded instruction.
*/
register BeamInstr *I REG_I = NULL;
/* Number of reductions left. This function
* returns to the scheduler when FCALLS reaches zero.
*/
register Sint FCALLS REG_fcalls = 0;
/*
* X registers and floating point registers are located in
* scheduler specific data.
*/
register FloatDef *freg = f_reg_array;
/*
* For keeping the negative old value of 'reds' when call saving is active.
*/
int neg_o_reds = 0;
#ifdef ERTS_OPCODE_COUNTER_SUPPORT
static void* counting_opcodes[] = { DEFINE_COUNTING_OPCODES };
#else
#ifndef NO_JUMP_TABLE
static void* opcodes[] = { DEFINE_OPCODES };
#else
register BeamInstr Go;
#endif
#endif
Uint64 start_time = 0; /* Monitor long schedule */
BeamInstr* start_time_i = NULL;
ERTS_MSACC_DECLARE_CACHE_X() /* a cached value of the tsd pointer for msacc */
ERL_BITS_DECLARE_STATEP; /* Has to be last declaration */
/*
* Note: In this function, we attempt to place rarely executed code towards
* the end of the function, in the hope that the cache hit rate will be better.
* The initialization code is only run once, so it is at the very end.
*
* Note: c_p->arity must be set to reflect the number of useful terms in
* c_p->arg_reg before calling the scheduler.
*/
if (ERTS_UNLIKELY(!init_done)) {
/* This should only be reached during the init phase when only the main
* process is running. I.e. there is no race for init_done.
*/
init_done = 1;
goto init_emulator;
}
c_p = NULL;
reds_used = 0;
goto do_schedule1;
do_schedule:
ASSERT(c_p->arity < 6);
ASSERT(c_p->debug_reds_in == REDS_IN(c_p));
if (!ERTS_PROC_GET_SAVED_CALLS_BUF(c_p))
reds_used = REDS_IN(c_p) - FCALLS;
else
reds_used = REDS_IN(c_p) - (CONTEXT_REDS + FCALLS);
ASSERT(reds_used >= 0);
do_schedule1:
if (start_time != 0) {
Sint64 diff = erts_timestamp_millis() - start_time;
if (diff > 0 && (Uint) diff > erts_system_monitor_long_schedule) {
ErtsCodeMFA *inptr = find_function_from_pc(start_time_i);
ErtsCodeMFA *outptr = find_function_from_pc(c_p->i);
monitor_long_schedule_proc(c_p,inptr,outptr,(Uint) diff);
}
}
PROCESS_MAIN_CHK_LOCKS(c_p);
ERTS_UNREQ_PROC_MAIN_LOCK(c_p);
ERTS_VERIFY_UNUSED_TEMP_ALLOC(c_p);
c_p = erts_schedule(NULL, c_p, reds_used);
ASSERT(!(c_p->flags & F_HIPE_MODE));
ERTS_VERIFY_UNUSED_TEMP_ALLOC(c_p);
start_time = 0;
#ifdef DEBUG
pid = c_p->common.id; /* Save for debugging purposes */
#endif
ERTS_REQ_PROC_MAIN_LOCK(c_p);
PROCESS_MAIN_CHK_LOCKS(c_p);
ERTS_MSACC_UPDATE_CACHE_X();
if (erts_system_monitor_long_schedule != 0) {
start_time = erts_timestamp_millis();
start_time_i = c_p->i;
}
ERL_BITS_RELOAD_STATEP(c_p);
{
int reds;
Eterm* argp;
BeamInstr next;
int i;
argp = c_p->arg_reg;
for (i = c_p->arity - 1; i >= 0; i--) {
reg[i] = argp[i];
CHECK_TERM(reg[i]);
}
/*
* We put the original reduction count in the process structure, to reduce
* the code size (referencing a field in a struct through a pointer stored
* in a register gives smaller code than referencing a global variable).
*/
SET_I(c_p->i);
REDS_IN(c_p) = reds = c_p->fcalls;
#ifdef DEBUG
c_p->debug_reds_in = reds;
#endif
if (ERTS_PROC_GET_SAVED_CALLS_BUF(c_p)) {
neg_o_reds = -CONTEXT_REDS;
FCALLS = neg_o_reds + reds;
} else {
neg_o_reds = 0;
FCALLS = reds;
}
ERTS_DBG_CHK_REDS(c_p, FCALLS);
next = *I;
SWAPIN;
ASSERT(VALID_INSTR(next));
#ifdef USE_VM_PROBES
if (DTRACE_ENABLED(process_scheduled)) {
DTRACE_CHARBUF(process_buf, DTRACE_TERM_BUF_SIZE);
DTRACE_CHARBUF(fun_buf, DTRACE_TERM_BUF_SIZE);
dtrace_proc_str(c_p, process_buf);
if (ERTS_PROC_IS_EXITING(c_p)) {
strcpy(fun_buf, "<exiting>");
} else {
ErtsCodeMFA *cmfa = find_function_from_pc(c_p->i);
if (cmfa) {
dtrace_fun_decode(c_p, cmfa,
NULL, fun_buf);
} else {
erts_snprintf(fun_buf, sizeof(DTRACE_CHARBUF_NAME(fun_buf)),
"<unknown/%p>", next);
}
}
DTRACE2(process_scheduled, process_buf, fun_buf);
}
#endif
Goto(next);
}
#if defined(DEBUG) || defined(NO_JUMP_TABLE)
emulator_loop:
#endif
#ifdef NO_JUMP_TABLE
switch (Go) {
#endif
#include "beam_hot.h"
#ifdef DEBUG
/*
* Set a breakpoint here to get control just after a call instruction.
* I points to the first instruction in the called function.
*
* In gdb, use 'call dis(I-5, 1)' to show the name of the function.
*/
do_dispatch:
DispatchMacro();
do_dispatchx:
DispatchMacrox();
do_dispatchfun:
DispatchMacroFun();
#endif
/*
* Jumped to from the Dispatch() macro when the reductions are used up.
*
* Since the I register points just beyond the FuncBegin instruction, we
* can get the module, function, and arity for the function being
* called from I[-3], I[-2], and I[-1] respectively.
*/
context_switch_fun:
/* Add one for the environment of the fun */
c_p->arity = erts_code_to_codemfa(I)->arity + 1;
goto context_switch2;
context_switch:
c_p->arity = erts_code_to_codemfa(I)->arity;
context_switch2: /* Entry for fun calls. */
c_p->current = erts_code_to_codemfa(I);
context_switch3:
{
Eterm* argp;
int i;
if (erts_atomic32_read_nob(&c_p->state) & ERTS_PSFLG_EXITING) {
c_p->i = beam_exit;
c_p->arity = 0;
c_p->current = NULL;
goto do_schedule;
}
/*
* Make sure that there is enough room for the argument registers to be saved.
*/
if (c_p->arity > c_p->max_arg_reg) {
/*
* Yes, this is an expensive operation, but you only pay it the first
* time you call a function with more than 6 arguments which is
* scheduled out. This is better than paying for 26 words of wasted
* space for most processes which never call functions with more than
* 6 arguments.
*/
Uint size = c_p->arity * sizeof(c_p->arg_reg[0]);
if (c_p->arg_reg != c_p->def_arg_reg) {
c_p->arg_reg = (Eterm *) erts_realloc(ERTS_ALC_T_ARG_REG,
(void *) c_p->arg_reg,
size);
} else {
c_p->arg_reg = (Eterm *) erts_alloc(ERTS_ALC_T_ARG_REG, size);
}
c_p->max_arg_reg = c_p->arity;
}
/*
* Since REDS_IN(c_p) is stored in the save area (c_p->arg_reg) we must read it
* now before saving registers.
*
* The '+ 1' compensates for the last increment which was not done
* (beacuse the code for the Dispatch() macro becomes shorter that way).
*/
ASSERT(c_p->debug_reds_in == REDS_IN(c_p));
if (!ERTS_PROC_GET_SAVED_CALLS_BUF(c_p))
reds_used = REDS_IN(c_p) - FCALLS;
else
reds_used = REDS_IN(c_p) - (CONTEXT_REDS + FCALLS);
ASSERT(reds_used >= 0);
/*
* Save the argument registers and everything else.
*/
argp = c_p->arg_reg;
for (i = c_p->arity - 1; i >= 0; i--) {
argp[i] = reg[i];
}
SWAPOUT;
c_p->i = I;
goto do_schedule1;
}
#include "beam_warm.h"
OpCase(normal_exit): {
SWAPOUT;
c_p->freason = EXC_NORMAL;
c_p->arity = 0; /* In case this process will ever be garbed again. */
ERTS_UNREQ_PROC_MAIN_LOCK(c_p);
erts_do_exit_process(c_p, am_normal);
ERTS_REQ_PROC_MAIN_LOCK(c_p);
goto do_schedule;
}
OpCase(continue_exit): {
ERTS_UNREQ_PROC_MAIN_LOCK(c_p);
erts_continue_exit_process(c_p);
ERTS_REQ_PROC_MAIN_LOCK(c_p);
goto do_schedule;
}
find_func_info: {
SWAPOUT;
I = handle_error(c_p, I, reg, NULL);
goto post_error_handling;
}
OpCase(call_error_handler):
/*
* At this point, I points to the code[3] in the export entry for
* a function which is not loaded.
*
* code[0]: Module
* code[1]: Function
* code[2]: Arity
* code[3]: &&call_error_handler
* code[4]: Not used
*/
HEAVY_SWAPOUT;
I = call_error_handler(c_p, erts_code_to_codemfa(I),
reg, am_undefined_function);
HEAVY_SWAPIN;
if (I) {
Goto(*I);
}
/* Fall through */
OpCase(error_action_code): {
handle_error:
SWAPOUT;
I = handle_error(c_p, NULL, reg, NULL);
post_error_handling:
if (I == 0) {
goto do_schedule;
} else {
ASSERT(!is_value(r(0)));
SWAPIN;
Goto(*I);
}
}
OpCase(i_func_info_IaaI): {
ErtsCodeInfo *ci = (ErtsCodeInfo*)I;
c_p->freason = EXC_FUNCTION_CLAUSE;
c_p->current = &ci->mfa;
goto handle_error;
}
#include "beam_cold.h"
#ifdef ERTS_OPCODE_COUNTER_SUPPORT
DEFINE_COUNTING_LABELS;
#endif
#ifndef NO_JUMP_TABLE
#ifdef DEBUG
end_emulator_loop:
#endif
#endif
OpCase(int_code_end):
OpCase(label_L):
OpCase(on_load):
OpCase(line_I):
erts_exit(ERTS_ERROR_EXIT, "meta op\n");
/*
* One-time initialization of Beam emulator.
*/
init_emulator:
{
#ifndef NO_JUMP_TABLE
#ifdef ERTS_OPCODE_COUNTER_SUPPORT
#ifdef DEBUG
counting_opcodes[op_catch_end_y] = LabelAddr(lb_catch_end_y);
#endif
counting_opcodes[op_i_func_info_IaaI] = LabelAddr(lb_i_func_info_IaaI);
beam_ops = counting_opcodes;
#else /* #ifndef ERTS_OPCODE_COUNTER_SUPPORT */
beam_ops = opcodes;
#endif /* ERTS_OPCODE_COUNTER_SUPPORT */
#endif /* NO_JUMP_TABLE */
init_emulator_finish();
return;
}
#ifdef NO_JUMP_TABLE
default:
erts_exit(ERTS_ERROR_EXIT, "unexpected op code %d\n",Go);
}
#endif
return; /* Never executed */
save_calls1:
{
BeamInstr dis_next;
save_calls(c_p, (Export *) Arg(0));
SET_I(((Export *) Arg(0))->addressv[erts_active_code_ix()]);
dis_next = *I;
FCALLS--;
Goto(dis_next);
}
}
/*
* One-time initialization of emulator. Does not need to be
* in process_main().
*/
static void
init_emulator_finish(void)
{
int i;
Export* ep;
beam_apply[0] = BeamOpCodeAddr(op_i_apply);
beam_apply[1] = BeamOpCodeAddr(op_normal_exit);
beam_exit[0] = BeamOpCodeAddr(op_error_action_code);
beam_continue_exit[0] = BeamOpCodeAddr(op_continue_exit);
beam_return_to_trace[0] = BeamOpCodeAddr(op_i_return_to_trace);
beam_return_trace[0] = BeamOpCodeAddr(op_return_trace);
beam_exception_trace[0] = BeamOpCodeAddr(op_return_trace); /* UGLY */
beam_return_time_trace[0] = BeamOpCodeAddr(op_i_return_time_trace);
/*
* Enter all BIFs into the export table.
*/
for (i = 0; i < BIF_SIZE; i++) {
ep = erts_export_put(bif_table[i].module,
bif_table[i].name,
bif_table[i].arity);
bif_export[i] = ep;
ep->beam[0] = BeamOpCodeAddr(op_apply_bif);
ep->beam[1] = (BeamInstr) bif_table[i].f;
/* XXX: set func info for bifs */
ep->info.op = BeamOpCodeAddr(op_i_func_info_IaaI);
}
}
/*
* erts_dirty_process_main() is what dirty schedulers execute. Since they handle
* only NIF calls they do not need to be able to execute all BEAM
* instructions.
*/
void erts_dirty_process_main(ErtsSchedulerData *esdp)
{
Process* c_p = NULL;
ErtsMonotonicTime start_time;
#ifdef DEBUG
ERTS_DECLARE_DUMMY(Eterm pid);
#endif
/* Pointer to X registers: x(1)..x(N); reg[0] is used when doing GC,
* in all other cases x0 is used.
*/
register Eterm* reg REG_xregs = NULL;
/*
* Top of heap (next free location); grows upwards.
*/
register Eterm* HTOP REG_htop = NULL;
/* Stack pointer. Grows downwards; points
* to last item pushed (normally a saved
* continuation pointer).
*/
register Eterm* E REG_stop = NULL;
/*
* Pointer to next threaded instruction.
*/
register BeamInstr *I REG_I = NULL;
ERTS_MSACC_DECLARE_CACHE_X() /* a cached value of the tsd pointer for msacc */
/*
* start_time always positive for dirty CPU schedulers,
* and negative for dirty I/O schedulers.
*/
if (ERTS_SCHEDULER_IS_DIRTY_CPU(esdp)) {
start_time = erts_get_monotonic_time(NULL);
ASSERT(start_time >= 0);
}
else {
start_time = ERTS_SINT64_MIN;
ASSERT(start_time < 0);
}
goto do_dirty_schedule;
context_switch:
c_p->current = erts_code_to_codemfa(I); /* Pointer to Mod, Func, Arity */
c_p->arity = c_p->current->arity;
{
int reds_used;
Eterm* argp;
int i;
/*
* Make sure that there is enough room for the argument registers to be saved.
*/
if (c_p->arity > c_p->max_arg_reg) {
/*
* Yes, this is an expensive operation, but you only pay it the first
* time you call a function with more than 6 arguments which is
* scheduled out. This is better than paying for 26 words of wasted
* space for most processes which never call functions with more than
* 6 arguments.
*/
Uint size = c_p->arity * sizeof(c_p->arg_reg[0]);
if (c_p->arg_reg != c_p->def_arg_reg) {
c_p->arg_reg = (Eterm *) erts_realloc(ERTS_ALC_T_ARG_REG,
(void *) c_p->arg_reg,
size);
} else {
c_p->arg_reg = (Eterm *) erts_alloc(ERTS_ALC_T_ARG_REG, size);
}
c_p->max_arg_reg = c_p->arity;
}
/*
* Save the argument registers and everything else.
*/
argp = c_p->arg_reg;
for (i = c_p->arity - 1; i >= 0; i--) {
argp[i] = reg[i];
}
SWAPOUT;
c_p->i = I;
do_dirty_schedule:
if (start_time < 0) {
/*
* Dirty I/O scheduler:
* One reduction consumed regardless of
* time spent in the dirty NIF.
*/
reds_used = esdp->virtual_reds + 1;
}
else {
/*
* Dirty CPU scheduler:
* Reductions based on time consumed by
* the dirty NIF.
*/
Sint64 treds;
treds = erts_time2reds(start_time,
erts_get_monotonic_time(esdp));
treds += esdp->virtual_reds;
reds_used = treds > INT_MAX ? INT_MAX : (int) treds;
}
PROCESS_MAIN_CHK_LOCKS(c_p);
ERTS_UNREQ_PROC_MAIN_LOCK(c_p);
ERTS_VERIFY_UNUSED_TEMP_ALLOC(c_p);
c_p = erts_schedule(esdp, c_p, reds_used);
if (start_time >= 0) {
start_time = erts_get_monotonic_time(esdp);
ASSERT(start_time >= 0);
}
}
ERTS_VERIFY_UNUSED_TEMP_ALLOC(c_p);
#ifdef DEBUG
pid = c_p->common.id; /* Save for debugging purposes */
#endif
ERTS_REQ_PROC_MAIN_LOCK(c_p);
PROCESS_MAIN_CHK_LOCKS(c_p);
ASSERT(!(c_p->flags & F_HIPE_MODE));
ERTS_MSACC_UPDATE_CACHE_X();
/*
* Set fcalls even though we ignore it, so we don't
* confuse code accessing it...
*/
if (ERTS_PROC_GET_SAVED_CALLS_BUF(c_p))
c_p->fcalls = 0;
else
c_p->fcalls = CONTEXT_REDS;
if (erts_atomic32_read_nob(&c_p->state) & ERTS_PSFLG_DIRTY_RUNNING_SYS) {
erts_execute_dirty_system_task(c_p);
goto do_dirty_schedule;
}
else {
ErtsCodeMFA *codemfa;
Eterm* argp;
int i, exiting;
reg = esdp->x_reg_array;
argp = c_p->arg_reg;
for (i = c_p->arity - 1; i >= 0; i--) {
reg[i] = argp[i];
CHECK_TERM(reg[i]);
}
/*
* We put the original reduction count in the process structure, to reduce
* the code size (referencing a field in a struct through a pointer stored
* in a register gives smaller code than referencing a global variable).
*/
I = c_p->i;
SWAPIN;
#ifdef USE_VM_PROBES
if (DTRACE_ENABLED(process_scheduled)) {
DTRACE_CHARBUF(process_buf, DTRACE_TERM_BUF_SIZE);
DTRACE_CHARBUF(fun_buf, DTRACE_TERM_BUF_SIZE);
dtrace_proc_str(c_p, process_buf);
if (ERTS_PROC_IS_EXITING(c_p)) {
strcpy(fun_buf, "<exiting>");
} else {
ErtsCodeMFA *cmfa = find_function_from_pc(c_p->i);
if (cmfa) {
dtrace_fun_decode(c_p, cmfa, NULL, fun_buf);
} else {
erts_snprintf(fun_buf, sizeof(DTRACE_CHARBUF_NAME(fun_buf)),
"<unknown/%p>", *I);
}
}
DTRACE2(process_scheduled, process_buf, fun_buf);
}
#endif
/*
* call_nif is always first instruction in function:
*
* I[-3]: Module
* I[-2]: Function
* I[-1]: Arity
* I[0]: &&call_nif
* I[1]: Function pointer to NIF function
* I[2]: Pointer to erl_module_nif
* I[3]: Function pointer to dirty NIF
*
* This layout is determined by the NifExport struct
*/
ERTS_MSACC_SET_STATE_CACHED_M_X(ERTS_MSACC_STATE_NIF);
codemfa = erts_code_to_codemfa(I);
DTRACE_NIF_ENTRY(c_p, codemfa);
c_p->current = codemfa;
SWAPOUT;
PROCESS_MAIN_CHK_LOCKS(c_p);
ERTS_UNREQ_PROC_MAIN_LOCK(c_p);
ASSERT(!ERTS_PROC_IS_EXITING(c_p));
if (BeamIsOpCode(*I, op_apply_bif)) {
exiting = erts_call_dirty_bif(esdp, c_p, I, reg);
}
else {
ASSERT(BeamIsOpCode(*I, op_call_nif));
exiting = erts_call_dirty_nif(esdp, c_p, I, reg);
}
ASSERT(!(c_p->flags & F_HIBERNATE_SCHED));
PROCESS_MAIN_CHK_LOCKS(c_p);
ERTS_REQ_PROC_MAIN_LOCK(c_p);
ERTS_VERIFY_UNUSED_TEMP_ALLOC(c_p);
ERTS_MSACC_SET_STATE_CACHED_M_X(ERTS_MSACC_STATE_EMULATOR);
if (exiting)
goto do_dirty_schedule;
ASSERT(!ERTS_PROC_IS_EXITING(c_p));
DTRACE_NIF_RETURN(c_p, codemfa);
ERTS_HOLE_CHECK(c_p);
SWAPIN;
I = c_p->i;
goto context_switch;
}
}
static ErtsCodeMFA *
gcbif2mfa(void* gcf)
{
int i;
for (i = 0; erts_gc_bifs[i].bif; i++) {
if (erts_gc_bifs[i].gc_bif == gcf)
return &bif_export[erts_gc_bifs[i].exp_ix]->info.mfa;
}
erts_exit(ERTS_ERROR_EXIT, "bad gc bif");
return NULL;
}
static ErtsCodeMFA *
ubif2mfa(void* uf)
{
int i;
for (i = 0; erts_u_bifs[i].bif; i++) {
if (erts_u_bifs[i].bif == uf)
return &bif_export[erts_u_bifs[i].exp_ix]->info.mfa;
}
erts_exit(ERTS_ERROR_EXIT, "bad u bif");
return NULL;
}
/*
* Mapping from the error code 'class tag' to atoms.
*/
Eterm exception_tag[NUMBER_EXC_TAGS] = {
am_error, /* 0 */
am_exit, /* 1 */
am_throw, /* 2 */
};
/*
* Mapping from error code 'index' to atoms.
*/
Eterm error_atom[NUMBER_EXIT_CODES] = {
am_internal_error, /* 0 */
am_normal, /* 1 */
am_internal_error, /* 2 */
am_badarg, /* 3 */
am_badarith, /* 4 */
am_badmatch, /* 5 */
am_function_clause, /* 6 */
am_case_clause, /* 7 */
am_if_clause, /* 8 */
am_undef, /* 9 */
am_badfun, /* 10 */
am_badarity, /* 11 */
am_timeout_value, /* 12 */
am_noproc, /* 13 */
am_notalive, /* 14 */
am_system_limit, /* 15 */
am_try_clause, /* 16 */
am_notsup, /* 17 */
am_badmap, /* 18 */
am_badkey, /* 19 */
};
/*
* To fully understand the error handling, one must keep in mind that
* when an exception is thrown, the search for a handler can jump back
* and forth between Beam and native code. Upon each mode switch, a
* dummy handler is inserted so that if an exception reaches that point,
* the handler is invoked (like any handler) and transfers control so
* that the search for a real handler is continued in the other mode.
* Therefore, c_p->freason and c_p->fvalue must still hold the exception
* info when the handler is executed, but normalized so that creation of
* error terms and saving of the stack trace is only done once, even if
* we pass through the error handling code several times.
*
* When a new exception is raised, the current stack trace information
* is quick-saved in a small structure allocated on the heap. Depending
* on how the exception is eventually caught (perhaps by causing the
* current process to terminate), the saved information may be used to
* create a symbolic (human-readable) representation of the stack trace
* at the point of the original exception.
*/
static BeamInstr*
handle_error(Process* c_p, BeamInstr* pc, Eterm* reg, ErtsCodeMFA *bif_mfa)
{
Eterm* hp;
Eterm Value = c_p->fvalue;
Eterm Args = am_true;
ASSERT(c_p->freason != TRAP); /* Should have been handled earlier. */
if (c_p->freason & EXF_RESTORE_NIF)
erts_nif_export_restore_error(c_p, &pc, reg, &bif_mfa);
#ifdef DEBUG
if (bif_mfa) {
/* Verify that bif_mfa does not point into our nif export */
NifExport *nep = ERTS_PROC_GET_NIF_TRAP_EXPORT(c_p);
ASSERT(!nep || !ErtsInArea(bif_mfa, (char *)nep, sizeof(NifExport)));
}
#endif
c_p->i = pc; /* In case we call erts_exit(). */
/*
* Check if we have an arglist for the top level call. If so, this
* is encoded in Value, so we have to dig out the real Value as well
* as the Arglist.
*/
if (c_p->freason & EXF_ARGLIST) {
Eterm* tp;
ASSERT(is_tuple(Value));
tp = tuple_val(Value);
Value = tp[1];
Args = tp[2];
}
/*
* Save the stack trace info if the EXF_SAVETRACE flag is set. The
* main reason for doing this separately is to allow throws to later
* become promoted to errors without losing the original stack
* trace, even if they have passed through one or more catch and
* rethrow. It also makes the creation of symbolic stack traces much
* more modular.
*/
if (c_p->freason & EXF_SAVETRACE) {
save_stacktrace(c_p, pc, reg, bif_mfa, Args);
}
/*
* Throws that are not caught are turned into 'nocatch' errors
*/
if ((c_p->freason & EXF_THROWN) && (c_p->catches <= 0) ) {
hp = HAlloc(c_p, 3);
Value = TUPLE2(hp, am_nocatch, Value);
c_p->freason = EXC_ERROR;
}
/* Get the fully expanded error term */
Value = expand_error_value(c_p, c_p->freason, Value);
/* Save final error term and stabilize the exception flags so no
further expansion is done. */
c_p->fvalue = Value;
c_p->freason = PRIMARY_EXCEPTION(c_p->freason);
/* Find a handler or die */
if ((c_p->catches > 0 || IS_TRACED_FL(c_p, F_EXCEPTION_TRACE))
&& !(c_p->freason & EXF_PANIC)) {
BeamInstr *new_pc;
/* The Beam handler code (catch_end or try_end) checks reg[0]
for THE_NON_VALUE to see if the previous code finished
abnormally. If so, reg[1], reg[2] and reg[3] should hold the
exception class, term and trace, respectively. (If the
handler is just a trap to native code, these registers will
be ignored.) */
reg[0] = THE_NON_VALUE;
reg[1] = exception_tag[GET_EXC_CLASS(c_p->freason)];
reg[2] = Value;
reg[3] = c_p->ftrace;
if ((new_pc = next_catch(c_p, reg))) {
c_p->cp = 0; /* To avoid keeping stale references. */
return new_pc;
}
if (c_p->catches > 0) erts_exit(ERTS_ERROR_EXIT, "Catch not found");
}
ERTS_UNREQ_PROC_MAIN_LOCK(c_p);
terminate_proc(c_p, Value);
ERTS_REQ_PROC_MAIN_LOCK(c_p);
return NULL;
}
/*
* Find the nearest catch handler
*/
static BeamInstr*
next_catch(Process* c_p, Eterm *reg) {
int active_catches = c_p->catches > 0;
int have_return_to_trace = 0;
Eterm *ptr, *prev, *return_to_trace_ptr = NULL;
BeamInstr i_return_trace = beam_return_trace[0];
BeamInstr i_return_to_trace = beam_return_to_trace[0];
BeamInstr i_return_time_trace = beam_return_time_trace[0];
ptr = prev = c_p->stop;
ASSERT(is_CP(*ptr));
ASSERT(ptr <= STACK_START(c_p));
if (ptr == STACK_START(c_p)) return NULL;
if ((is_not_CP(*ptr) || (*cp_val(*ptr) != i_return_trace &&
*cp_val(*ptr) != i_return_to_trace &&
*cp_val(*ptr) != i_return_time_trace ))
&& c_p->cp) {
/* Can not follow cp here - code may be unloaded */
BeamInstr *cpp = c_p->cp;
if (cpp == beam_exception_trace) {
ErtsCodeMFA *mfa = (ErtsCodeMFA*)cp_val(ptr[0]);
erts_trace_exception(c_p, mfa,
reg[1], reg[2],
ERTS_TRACER_FROM_ETERM(ptr+1));
/* Skip return_trace parameters */
ptr += 2;
} else if (cpp == beam_return_trace) {
/* Skip return_trace parameters */
ptr += 2;
} else if (cpp == beam_return_time_trace) {
/* Skip return_trace parameters */
ptr += 1;
} else if (cpp == beam_return_to_trace) {
have_return_to_trace = !0; /* Record next cp */
}
}
while (ptr < STACK_START(c_p)) {
if (is_catch(*ptr)) {
if (active_catches) goto found_catch;
ptr++;
}
else if (is_CP(*ptr)) {
prev = ptr;
if (*cp_val(*prev) == i_return_trace) {
/* Skip stack frame variables */
while (++ptr, ptr < STACK_START(c_p) && is_not_CP(*ptr)) {
if (is_catch(*ptr) && active_catches) goto found_catch;
}
if (cp_val(*prev) == beam_exception_trace) {
ErtsCodeMFA *mfa = (ErtsCodeMFA*)cp_val(ptr[0]);
erts_trace_exception(c_p, mfa,
reg[1], reg[2],
ERTS_TRACER_FROM_ETERM(ptr+1));
}
/* Skip return_trace parameters */
ptr += 2;
} else if (*cp_val(*prev) == i_return_to_trace) {
/* Skip stack frame variables */
while (++ptr, ptr < STACK_START(c_p) && is_not_CP(*ptr)) {
if (is_catch(*ptr) && active_catches) goto found_catch;
}
have_return_to_trace = !0; /* Record next cp */
return_to_trace_ptr = NULL;
} else if (*cp_val(*prev) == i_return_time_trace) {
/* Skip stack frame variables */
while (++ptr, ptr < STACK_START(c_p) && is_not_CP(*ptr)) {
if (is_catch(*ptr) && active_catches) goto found_catch;
}
/* Skip return_trace parameters */
ptr += 1;
} else {
if (have_return_to_trace) {
/* Record this cp as possible return_to trace cp */
have_return_to_trace = 0;
return_to_trace_ptr = ptr;
} else return_to_trace_ptr = NULL;
ptr++;
}
} else ptr++;
}
return NULL;
found_catch:
ASSERT(ptr < STACK_START(c_p));
c_p->stop = prev;
if (IS_TRACED_FL(c_p, F_TRACE_RETURN_TO) && return_to_trace_ptr) {
/* The stackframe closest to the catch contained an
* return_to_trace entry, so since the execution now
* continues after the catch, a return_to trace message
* would be appropriate.
*/
erts_trace_return_to(c_p, cp_val(*return_to_trace_ptr));
}
return catch_pc(*ptr);
}
/*
* Terminating the process when an exception is not caught
*/
static void
terminate_proc(Process* c_p, Eterm Value)
{
Eterm *hp;
Eterm Args = NIL;
/* Add a stacktrace if this is an error. */
if (GET_EXC_CLASS(c_p->freason) == EXTAG_ERROR) {
Value = add_stacktrace(c_p, Value, c_p->ftrace);
}
/* EXF_LOG is a primary exception flag */
if (c_p->freason & EXF_LOG) {
int alive = erts_is_alive;
erts_dsprintf_buf_t *dsbufp = erts_create_logger_dsbuf();
/* Build the format message */
erts_dsprintf(dsbufp, "Error in process ~p ");
if (alive)
erts_dsprintf(dsbufp, "on node ~p ");
erts_dsprintf(dsbufp, "with exit value:~n~p~n");
/* Build the args in reverse order */
hp = HAlloc(c_p, 2);
Args = CONS(hp, Value, Args);
if (alive) {
hp = HAlloc(c_p, 2);
Args = CONS(hp, erts_this_node->sysname, Args);
}
hp = HAlloc(c_p, 2);
Args = CONS(hp, c_p->common.id, Args);
erts_send_error_term_to_logger(c_p->group_leader, dsbufp, Args);
}
/*
* If we use a shared heap, the process will be garbage-collected.
* Must zero c_p->arity to indicate that there are no live registers.
*/
c_p->arity = 0;
erts_do_exit_process(c_p, Value);
}
/*
* Build and add a symbolic stack trace to the error value.
*/
static Eterm
add_stacktrace(Process* c_p, Eterm Value, Eterm exc) {
Eterm Where = build_stacktrace(c_p, exc);
Eterm* hp = HAlloc(c_p, 3);
return TUPLE2(hp, Value, Where);
}
/*
* Forming the correct error value from the internal error code.
* This does not update c_p->fvalue or c_p->freason.
*/
Eterm
expand_error_value(Process* c_p, Uint freason, Eterm Value) {
Eterm* hp;
Uint r;
r = GET_EXC_INDEX(freason);
ASSERT(r < NUMBER_EXIT_CODES); /* range check */
ASSERT(is_value(Value));
switch (r) {
case (GET_EXC_INDEX(EXC_PRIMARY)):
/* Primary exceptions use fvalue as it is */
break;
case (GET_EXC_INDEX(EXC_BADMATCH)):
case (GET_EXC_INDEX(EXC_CASE_CLAUSE)):
case (GET_EXC_INDEX(EXC_TRY_CLAUSE)):
case (GET_EXC_INDEX(EXC_BADFUN)):
case (GET_EXC_INDEX(EXC_BADARITY)):
case (GET_EXC_INDEX(EXC_BADMAP)):
case (GET_EXC_INDEX(EXC_BADKEY)):
/* Some common exceptions: value -> {atom, value} */
ASSERT(is_value(Value));
hp = HAlloc(c_p, 3);
Value = TUPLE2(hp, error_atom[r], Value);
break;
default:
/* Other exceptions just use an atom as descriptor */
Value = error_atom[r];
break;
}
#ifdef DEBUG
ASSERT(Value != am_internal_error);
#endif
return Value;
}
/*
* Quick-saving the stack trace in an internal form on the heap. Note
* that c_p->ftrace will point to a cons cell which holds the given args
* and the saved data (encoded as a bignum).
*
* There is an issue with line number information. Line number
* information is associated with the address *before* an operation
* that may fail or be stored stored on the stack. But continuation
* pointers point after its call instruction, not before. To avoid
* finding the wrong line number, we'll need to adjust them so that
* they point at the beginning of the call instruction or inside the
* call instruction. Since its impractical to point at the beginning,
* we'll do the simplest thing and decrement the continuation pointers
* by one.
*
* Here is an example of what can go wrong. Without the adjustment
* of continuation pointers, the call at line 42 below would seem to
* be at line 43:
*
* line 42
* call ...
* line 43
* gc_bif ...
*
* (It would be much better to put the arglist - when it exists - in the
* error value instead of in the actual trace; e.g. '{badarg, Args}'
* instead of using 'badarg' with Args in the trace. The arglist may
* contain very large values, and right now they will be kept alive as
* long as the stack trace is live. Preferably, the stack trace should
* always be small, so that it does not matter if it is long-lived.
* However, it is probably not possible to ever change the format of
* error terms.)
*/
static void
save_stacktrace(Process* c_p, BeamInstr* pc, Eterm* reg,
ErtsCodeMFA *bif_mfa, Eterm args) {
struct StackTrace* s;
int sz;
int depth = erts_backtrace_depth; /* max depth (never negative) */
if (depth > 0) {
/* There will always be a current function */
depth --;
}
/* Create a container for the exception data */
sz = (offsetof(struct StackTrace, trace) + sizeof(BeamInstr *)*depth
+ sizeof(Eterm) - 1) / sizeof(Eterm);
s = (struct StackTrace *) HAlloc(c_p, 1 + sz);
/* The following fields are inside the bignum */
s->header = make_pos_bignum_header(sz);
s->freason = c_p->freason;
s->depth = 0;
/*
* If the failure was in a BIF other than 'error/1', 'error/2',
* 'exit/1' or 'throw/1', save BIF-MFA and save the argument
* registers by consing up an arglist.
*/
if (bif_mfa) {
if (bif_mfa->module == am_erlang) {
switch (bif_mfa->function) {
case am_error:
if (bif_mfa->arity == 1 || bif_mfa->arity == 2)
goto non_bif_stacktrace;
break;
case am_exit:
if (bif_mfa->arity == 1)
goto non_bif_stacktrace;
break;
case am_throw:
if (bif_mfa->arity == 1)
goto non_bif_stacktrace;
break;
default:
break;
}
}
s->current = bif_mfa;
/* Save first stack entry */
ASSERT(pc);
if (depth > 0) {
s->trace[s->depth++] = pc;
depth--;
}
/* Save second stack entry if CP is valid and different from pc */
if (depth > 0 && c_p->cp != 0 && c_p->cp != pc) {
s->trace[s->depth++] = c_p->cp - 1;
depth--;
}
s->pc = NULL;
args = make_arglist(c_p, reg, bif_mfa->arity); /* Overwrite CAR(c_p->ftrace) */
} else {
non_bif_stacktrace:
s->current = c_p->current;
/*
* For a function_clause error, the arguments are in the beam
* registers, c_p->cp is valid, and c_p->current is set.
*/
if ( (GET_EXC_INDEX(s->freason)) ==
(GET_EXC_INDEX(EXC_FUNCTION_CLAUSE)) ) {
int a;
ASSERT(s->current);
a = s->current->arity;
args = make_arglist(c_p, reg, a); /* Overwrite CAR(c_p->ftrace) */
/* Save first stack entry */
ASSERT(c_p->cp);
if (depth > 0) {
s->trace[s->depth++] = c_p->cp - 1;
depth--;
}
s->pc = NULL; /* Ignore pc */
} else {
if (depth > 0 && c_p->cp != 0 && c_p->cp != pc) {
s->trace[s->depth++] = c_p->cp - 1;
depth--;
}
s->pc = pc;
}
}
/* Package args and stack trace */
{
Eterm *hp;
hp = HAlloc(c_p, 2);
c_p->ftrace = CONS(hp, args, make_big((Eterm *) s));
}
/* Save the actual stack trace */
erts_save_stacktrace(c_p, s, depth);
}
void
erts_save_stacktrace(Process* p, struct StackTrace* s, int depth)
{
if (depth > 0) {
Eterm *ptr;
BeamInstr *prev = s->depth ? s->trace[s->depth-1] : NULL;
BeamInstr i_return_trace = beam_return_trace[0];
BeamInstr i_return_to_trace = beam_return_to_trace[0];
/*
* Traverse the stack backwards and add all unique continuation
* pointers to the buffer, up to the maximum stack trace size.
*
* Skip trace stack frames.
*/
ptr = p->stop;
if (ptr < STACK_START(p) &&
(is_not_CP(*ptr)|| (*cp_val(*ptr) != i_return_trace &&
*cp_val(*ptr) != i_return_to_trace)) &&
p->cp) {
/* Cannot follow cp here - code may be unloaded */
BeamInstr *cpp = p->cp;
int trace_cp;
if (cpp == beam_exception_trace || cpp == beam_return_trace) {
/* Skip return_trace parameters */
ptr += 2;
trace_cp = 1;
} else if (cpp == beam_return_to_trace) {
/* Skip return_to_trace parameters */
ptr += 1;
trace_cp = 1;
}
else {
trace_cp = 0;
}
if (trace_cp && s->pc == cpp) {
/*
* If process 'cp' points to a return/exception trace
* instruction and 'cp' has been saved as 'pc' in
* stacktrace, we need to update 'pc' in stacktrace
* with the actual 'cp' located on the top of the
* stack; otherwise, we will lose the top stackframe
* when building the stack trace.
*/
ASSERT(is_CP(p->stop[0]));
s->pc = cp_val(p->stop[0]);
}
}
while (ptr < STACK_START(p) && depth > 0) {
if (is_CP(*ptr)) {
if (*cp_val(*ptr) == i_return_trace) {
/* Skip stack frame variables */
do ++ptr; while (is_not_CP(*ptr));
/* Skip return_trace parameters */
ptr += 2;
} else if (*cp_val(*ptr) == i_return_to_trace) {
/* Skip stack frame variables */
do ++ptr; while (is_not_CP(*ptr));
} else {
BeamInstr *cp = cp_val(*ptr);
if (cp != prev) {
/* Record non-duplicates only */
prev = cp;
s->trace[s->depth++] = cp - 1;
depth--;
}
ptr++;
}
} else ptr++;
}
}
}
/*
* Getting the relevant fields from the term pointed to by ftrace
*/
static struct StackTrace *get_trace_from_exc(Eterm exc) {
if (exc == NIL) {
return NULL;
} else {
ASSERT(is_list(exc));
return (struct StackTrace *) big_val(CDR(list_val(exc)));
}
}
static Eterm get_args_from_exc(Eterm exc) {
if (exc == NIL) {
return NIL;
} else {
ASSERT(is_list(exc));
return CAR(list_val(exc));
}
}
static int is_raised_exc(Eterm exc) {
if (exc == NIL) {
return 0;
} else {
ASSERT(is_list(exc));
return bignum_header_is_neg(*big_val(CDR(list_val(exc))));
}
}
/*
* Creating a list with the argument registers
*/
static Eterm
make_arglist(Process* c_p, Eterm* reg, int a) {
Eterm args = NIL;
Eterm* hp = HAlloc(c_p, 2*a);
while (a > 0) {
args = CONS(hp, reg[a-1], args);
hp += 2;
a--;
}
return args;
}
/*
* Building a symbolic representation of a saved stack trace. Note that
* the exception object 'exc', unless NIL, points to a cons cell which
* holds the given args and the quick-saved data (encoded as a bignum).
*
* If the bignum is negative, the given args is a complete stacktrace.
*/
Eterm
build_stacktrace(Process* c_p, Eterm exc) {
struct StackTrace* s;
Eterm args;
int depth;
FunctionInfo fi;
FunctionInfo* stk;
FunctionInfo* stkp;
Eterm res = NIL;
Uint heap_size;
Eterm* hp;
Eterm mfa;
int i;
if (! (s = get_trace_from_exc(exc))) {
return NIL;
}
#ifdef HIPE
if (s->freason & EXF_NATIVE) {
return hipe_build_stacktrace(c_p, s);
}
#endif
if (is_raised_exc(exc)) {
return get_args_from_exc(exc);
}
/*
* Find the current function. If the saved s->pc is null, then the
* saved s->current should already contain the proper value.
*/
if (s->pc != NULL) {
erts_lookup_function_info(&fi, s->pc, 1);
} else if (GET_EXC_INDEX(s->freason) ==
GET_EXC_INDEX(EXC_FUNCTION_CLAUSE)) {
erts_lookup_function_info(&fi, erts_codemfa_to_code(s->current), 1);
} else {
erts_set_current_function(&fi, s->current);
}
depth = s->depth;
/*
* If fi.current is still NULL, and we have no
* stack at all, default to the initial function
* (e.g. spawn_link(erlang, abs, [1])).
*/
if (fi.mfa == NULL) {
if (depth <= 0)
erts_set_current_function(&fi, &c_p->u.initial);
args = am_true; /* Just in case */
} else {
args = get_args_from_exc(exc);
}
/*
* Look up all saved continuation pointers and calculate
* needed heap space.
*/
stk = stkp = (FunctionInfo *) erts_alloc(ERTS_ALC_T_TMP,
depth*sizeof(FunctionInfo));
heap_size = fi.mfa ? fi.needed + 2 : 0;
for (i = 0; i < depth; i++) {
erts_lookup_function_info(stkp, s->trace[i], 1);
if (stkp->mfa) {
heap_size += stkp->needed + 2;
stkp++;
}
}
/*
* Allocate heap space and build the stacktrace.
*/
hp = HAlloc(c_p, heap_size);
while (stkp > stk) {
stkp--;
hp = erts_build_mfa_item(stkp, hp, am_true, &mfa);
res = CONS(hp, mfa, res);
hp += 2;
}
if (fi.mfa) {
hp = erts_build_mfa_item(&fi, hp, args, &mfa);
res = CONS(hp, mfa, res);
}
erts_free(ERTS_ALC_T_TMP, (void *) stk);
return res;
}
static BeamInstr*
call_error_handler(Process* p, ErtsCodeMFA* mfa, Eterm* reg, Eterm func)
{
Eterm* hp;
Export* ep;
int arity;
Eterm args;
Uint sz;
int i;
DBG_TRACE_MFA_P(mfa, "call_error_handler");
/*
* Search for the error_handler module.
*/
ep = erts_find_function(erts_proc_get_error_handler(p), func, 3,
erts_active_code_ix());
if (ep == NULL) { /* No error handler */
p->current = mfa;
p->freason = EXC_UNDEF;
return 0;
}
/*
* Create a list with all arguments in the x registers.
*/
arity = mfa->arity;
sz = 2 * arity;
if (HeapWordsLeft(p) < sz) {
erts_garbage_collect(p, sz, reg, arity);
}
hp = HEAP_TOP(p);
HEAP_TOP(p) += sz;
args = NIL;
for (i = arity-1; i >= 0; i--) {
args = CONS(hp, reg[i], args);
hp += 2;
}
/*
* Set up registers for call to error_handler:<func>/3.
*/
reg[0] = mfa->module;
reg[1] = mfa->function;
reg[2] = args;
return ep->addressv[erts_active_code_ix()];
}
static Export*
apply_setup_error_handler(Process* p, Eterm module, Eterm function, Uint arity, Eterm* reg)
{
Export* ep;
/*
* Find the export table index for the error handler. Return NULL if
* there is no error handler module.
*/
if ((ep = erts_active_export_entry(erts_proc_get_error_handler(p),
am_undefined_function, 3)) == NULL) {
return NULL;
} else {
int i;
Uint sz = 2*arity;
Eterm* hp;
Eterm args = NIL;
/*
* Always copy args from registers to a new list; this ensures
* that we have the same behaviour whether or not this was
* called from apply or fixed_apply (any additional last
* THIS-argument will be included, assuming that arity has been
* properly adjusted).
*/
if (HeapWordsLeft(p) < sz) {
erts_garbage_collect(p, sz, reg, arity);
}
hp = HEAP_TOP(p);
HEAP_TOP(p) += sz;
for (i = arity-1; i >= 0; i--) {
args = CONS(hp, reg[i], args);
hp += 2;
}
reg[0] = module;
reg[1] = function;
reg[2] = args;
}
return ep;
}
static ERTS_INLINE void
apply_bif_error_adjustment(Process *p, Export *ep,
Eterm *reg, Uint arity,
BeamInstr *I, Uint stack_offset)
{
/*
* I is only set when the apply is a tail call, i.e.,
* from the instructions i_apply_only, i_apply_last_P,
* and apply_last_IP.
*/
if (I
&& BeamIsOpCode(ep->beam[0], op_apply_bif)
&& (ep == bif_export[BIF_error_1]
|| ep == bif_export[BIF_error_2]
|| ep == bif_export[BIF_exit_1]
|| ep == bif_export[BIF_throw_1])) {
/*
* We are about to tail apply one of the BIFs
* erlang:error/1, erlang:error/2, erlang:exit/1,
* or erlang:throw/1. Error handling of these BIFs is
* special!
*
* We need 'p->cp' to point into the calling
* function when handling the error after the BIF has
* been applied. This in order to get the topmost
* stackframe correct. Without the following adjustment,
* 'p->cp' will point into the function that called
* current function when handling the error. We add a
* dummy stackframe in order to achieve this.
*
* Note that these BIFs unconditionally will cause
* an exception to be raised. That is, our modifications
* of 'p->cp' as well as the stack will be corrected by
* the error handling code.
*
* If we find an exception/return-to trace continuation
* pointer as the topmost continuation pointer, we do not
* need to do anything since the information already will
* be available for generation of the stacktrace.
*/
int apply_only = stack_offset == 0;
BeamInstr *cpp;
if (apply_only) {
ASSERT(p->cp != NULL);
cpp = p->cp;
}
else {
ASSERT(is_CP(p->stop[0]));
cpp = cp_val(p->stop[0]);
}
if (cpp != beam_exception_trace
&& cpp != beam_return_trace
&& cpp != beam_return_to_trace) {
Uint need = stack_offset /* bytes */ / sizeof(Eterm);
if (need == 0)
need = 1; /* i_apply_only */
if (p->stop - p->htop < need)
erts_garbage_collect(p, (int) need, reg, arity+1);
p->stop -= need;
if (apply_only) {
/*
* Called from the i_apply_only instruction.
*
* 'p->cp' contains continuation pointer pointing
* into the function that called current function.
* We push that continuation pointer onto the stack,
* and set 'p->cp' to point into current function.
*/
p->stop[0] = make_cp(p->cp);
p->cp = I;
}
else {
/*
* Called from an i_apply_last_p, or apply_last_IP,
* instruction.
*
* Calling instruction will after we return read
* a continuation pointer from the stack and write
* it to 'p->cp', and then remove the topmost
* stackframe of size 'stack_offset'.
*
* We have sized the dummy-stackframe so that it
* will be removed by the instruction we currently
* are executing, and leave the stackframe that
* normally would have been removed intact.
*
*/
p->stop[0] = make_cp(I);
}
}
}
}
static BeamInstr*
apply(Process* p, Eterm* reg, BeamInstr *I, Uint stack_offset)
{
int arity;
Export* ep;
Eterm tmp;
Eterm module = reg[0];
Eterm function = reg[1];
Eterm args = reg[2];
/*
* Check the arguments which should be of the form apply(Module,
* Function, Arguments) where Function is an atom and
* Arguments is an arity long list of terms.
*/
if (is_not_atom(function)) {
/*
* No need to test args here -- done below.
*/
error:
p->freason = BADARG;
error2:
reg[0] = module;
reg[1] = function;
reg[2] = args;
return 0;
}
while (1) {
Eterm m, f, a;
if (is_not_atom(module)) goto error;
if (module != am_erlang || function != am_apply)
break;
/* Adjust for multiple apply of apply/3... */
a = args;
if (is_list(a)) {
Eterm *consp = list_val(a);
m = CAR(consp);
a = CDR(consp);
if (is_list(a)) {
consp = list_val(a);
f = CAR(consp);
a = CDR(consp);
if (is_list(a)) {
consp = list_val(a);
a = CAR(consp);
if (is_nil(CDR(consp))) {
/* erlang:apply/3 */
module = m;
function = f;
args = a;
if (is_not_atom(f))
goto error;
continue;
}
}
}
}
break; /* != erlang:apply/3 */
}
/*
* Walk down the 3rd parameter of apply (the argument list) and copy
* the parameters to the x registers (reg[]).
*/
tmp = args;
arity = 0;
while (is_list(tmp)) {
if (arity < (MAX_REG - 1)) {
reg[arity++] = CAR(list_val(tmp));
tmp = CDR(list_val(tmp));
} else {
p->freason = SYSTEM_LIMIT;
goto error2;
}
}
if (is_not_nil(tmp)) { /* Must be well-formed list */
goto error;
}
/*
* Get the index into the export table, or failing that the export
* entry for the error handler.
*
* Note: All BIFs have export entries; thus, no special case is needed.
*/
if ((ep = erts_active_export_entry(module, function, arity)) == NULL) {
if ((ep = apply_setup_error_handler(p, module, function, arity, reg)) == NULL) goto error;
} else if (ERTS_PROC_GET_SAVED_CALLS_BUF(p)) {
save_calls(p, ep);
}
apply_bif_error_adjustment(p, ep, reg, arity, I, stack_offset);
DTRACE_GLOBAL_CALL_FROM_EXPORT(p, ep);
return ep->addressv[erts_active_code_ix()];
}
static BeamInstr*
fixed_apply(Process* p, Eterm* reg, Uint arity,
BeamInstr *I, Uint stack_offset)
{
Export* ep;
Eterm module;
Eterm function;
module = reg[arity]; /* The THIS pointer already in place */
function = reg[arity+1];
if (is_not_atom(function)) {
error:
p->freason = BADARG;
reg[0] = module;
reg[1] = function;
reg[2] = NIL;
return 0;
}
if (is_not_atom(module)) goto error;
/* Handle apply of apply/3... */
if (module == am_erlang && function == am_apply && arity == 3) {
return apply(p, reg, I, stack_offset);
}
/*
* Get the index into the export table, or failing that the export
* entry for the error handler module.
*
* Note: All BIFs have export entries; thus, no special case is needed.
*/
if ((ep = erts_active_export_entry(module, function, arity)) == NULL) {
if ((ep = apply_setup_error_handler(p, module, function, arity, reg)) == NULL)
goto error;
} else if (ERTS_PROC_GET_SAVED_CALLS_BUF(p)) {
save_calls(p, ep);
}
apply_bif_error_adjustment(p, ep, reg, arity, I, stack_offset);
DTRACE_GLOBAL_CALL_FROM_EXPORT(p, ep);
return ep->addressv[erts_active_code_ix()];
}
int
erts_hibernate(Process* c_p, Eterm* reg)
{
int arity;
Eterm tmp;
Eterm module = reg[0];
Eterm function = reg[1];
Eterm args = reg[2];
if (is_not_atom(module) || is_not_atom(function)) {
/*
* No need to test args here -- done below.
*/
error:
c_p->freason = BADARG;
error2:
reg[0] = module;
reg[1] = function;
reg[2] = args;
return 0;
}
arity = 0;
tmp = args;
while (is_list(tmp)) {
if (arity < MAX_REG) {
tmp = CDR(list_val(tmp));
arity++;
} else {
c_p->freason = SYSTEM_LIMIT;
goto error2;
}
}
if (is_not_nil(tmp)) { /* Must be well-formed list */
goto error;
}
/*
* At this point, arguments are known to be good.
*/
if (c_p->arg_reg != c_p->def_arg_reg) {
/* Save some memory */
erts_free(ERTS_ALC_T_ARG_REG, c_p->arg_reg);
c_p->arg_reg = c_p->def_arg_reg;
c_p->max_arg_reg = sizeof(c_p->def_arg_reg)/sizeof(c_p->def_arg_reg[0]);
}
#ifdef USE_VM_PROBES
if (DTRACE_ENABLED(process_hibernate)) {
ErtsCodeMFA cmfa = { module, function, arity};
DTRACE_CHARBUF(process_name, DTRACE_TERM_BUF_SIZE);
DTRACE_CHARBUF(mfa_buf, DTRACE_TERM_BUF_SIZE);
dtrace_fun_decode(c_p, &cmfa, process_name, mfa_buf);
DTRACE2(process_hibernate, process_name, mfa_buf);
}
#endif
/*
* Arrange for the process to be resumed at the given MFA with
* the stack cleared.
*/
c_p->arity = 3;
c_p->arg_reg[0] = module;
c_p->arg_reg[1] = function;
c_p->arg_reg[2] = args;
c_p->stop = STACK_START(c_p);
c_p->catches = 0;
c_p->i = beam_apply;
c_p->cp = (BeamInstr *) beam_apply+1;
/*
* If there are no waiting messages, garbage collect and
* shrink the heap.
*/
erts_proc_lock(c_p, ERTS_PROC_LOCK_MSGQ|ERTS_PROC_LOCK_STATUS);
ERTS_MSGQ_MV_INQ2PRIVQ(c_p);
if (!c_p->msg.len) {
erts_proc_unlock(c_p, ERTS_PROC_LOCK_MSGQ|ERTS_PROC_LOCK_STATUS);
c_p->fvalue = NIL;
PROCESS_MAIN_CHK_LOCKS(c_p);
erts_garbage_collect_hibernate(c_p);
ERTS_VERIFY_UNUSED_TEMP_ALLOC(c_p);
PROCESS_MAIN_CHK_LOCKS(c_p);
erts_proc_lock(c_p, ERTS_PROC_LOCK_MSGQ|ERTS_PROC_LOCK_STATUS);
ERTS_MSGQ_MV_INQ2PRIVQ(c_p);
if (!c_p->msg.len)
erts_atomic32_read_band_relb(&c_p->state, ~ERTS_PSFLG_ACTIVE);
ASSERT(!ERTS_PROC_IS_EXITING(c_p));
}
erts_proc_unlock(c_p, ERTS_PROC_LOCK_MSGQ|ERTS_PROC_LOCK_STATUS);
c_p->current = &bif_export[BIF_hibernate_3]->info.mfa;
c_p->flags |= F_HIBERNATE_SCHED; /* Needed also when woken! */
return 1;
}
static BeamInstr*
call_fun(Process* p, /* Current process. */
int arity, /* Number of arguments for Fun. */
Eterm* reg, /* Contents of registers. */
Eterm args) /* THE_NON_VALUE or pre-built list of arguments. */
{
Eterm fun = reg[arity];
Eterm hdr;
int i;
Eterm* hp;
if (!is_boxed(fun)) {
goto badfun;
}
hdr = *boxed_val(fun);
if (is_fun_header(hdr)) {
ErlFunThing* funp = (ErlFunThing *) fun_val(fun);
ErlFunEntry* fe = funp->fe;
BeamInstr* code_ptr = fe->address;
Eterm* var_ptr;
unsigned num_free = funp->num_free;
ErtsCodeMFA *mfa = erts_code_to_codemfa(code_ptr);
int actual_arity = mfa->arity;
if (actual_arity == arity+num_free) {
DTRACE_LOCAL_CALL(p, mfa);
if (num_free == 0) {
return code_ptr;
} else {
var_ptr = funp->env;
reg += arity;
i = 0;
do {
reg[i] = var_ptr[i];
i++;
} while (i < num_free);
reg[i] = fun;
return code_ptr;
}
return code_ptr;
} else {
/*
* Something wrong here. First build a list of the arguments.
*/
if (is_non_value(args)) {
Uint sz = 2 * arity;
args = NIL;
if (HeapWordsLeft(p) < sz) {
erts_garbage_collect(p, sz, reg, arity+1);
fun = reg[arity];
}
hp = HEAP_TOP(p);
HEAP_TOP(p) += sz;
for (i = arity-1; i >= 0; i--) {
args = CONS(hp, reg[i], args);
hp += 2;
}
}
if (actual_arity >= 0) {
/*
* There is a fun defined, but the call has the wrong arity.
*/
hp = HAlloc(p, 3);
p->freason = EXC_BADARITY;
p->fvalue = TUPLE2(hp, fun, args);
return NULL;
} else {
Export* ep;
Module* modp;
Eterm module;
ErtsCodeIndex code_ix = erts_active_code_ix();
/*
* No arity. There is no module loaded that defines the fun,
* either because the fun is newly created from the external
* representation (the module has never been loaded),
* or the module defining the fun has been unloaded.
*/
module = fe->module;
ERTS_THR_READ_MEMORY_BARRIER;
if (fe->pend_purge_address) {
/*
* The system is currently trying to purge the
* module containing this fun. Suspend the process
* and let it try again when the purge operation is
* done (may succeed or not).
*/
ep = erts_suspend_process_on_pending_purge_lambda(p, fe);
ASSERT(ep);
}
else {
if ((modp = erts_get_module(module, code_ix)) != NULL
&& modp->curr.code_hdr != NULL) {
/*
* There is a module loaded, but obviously the fun is not
* defined in it. We must not call the error_handler
* (or we will get into an infinite loop).
*/
goto badfun;
}
/*
* No current code for this module. Call the error_handler module
* to attempt loading the module.
*/
ep = erts_find_function(erts_proc_get_error_handler(p),
am_undefined_lambda, 3, code_ix);
if (ep == NULL) { /* No error handler */
p->current = NULL;
p->freason = EXC_UNDEF;
return NULL;
}
}
reg[0] = module;
reg[1] = fun;
reg[2] = args;
reg[3] = NIL;
return ep->addressv[code_ix];
}
}
} else if (is_export_header(hdr)) {
Export *ep;
int actual_arity;
ep = *((Export **) (export_val(fun) + 1));
actual_arity = ep->info.mfa.arity;
if (arity == actual_arity) {
DTRACE_GLOBAL_CALL(p, &ep->info.mfa);
return ep->addressv[erts_active_code_ix()];
} else {
/*
* Wrong arity. First build a list of the arguments.
*/
if (is_non_value(args)) {
args = NIL;
hp = HAlloc(p, arity*2);
for (i = arity-1; i >= 0; i--) {
args = CONS(hp, reg[i], args);
hp += 2;
}
}
hp = HAlloc(p, 3);
p->freason = EXC_BADARITY;
p->fvalue = TUPLE2(hp, fun, args);
return NULL;
}
} else {
badfun:
p->current = NULL;
p->freason = EXC_BADFUN;
p->fvalue = fun;
return NULL;
}
}
static BeamInstr*
apply_fun(Process* p, Eterm fun, Eterm args, Eterm* reg)
{
int arity;
Eterm tmp;
/*
* Walk down the 3rd parameter of apply (the argument list) and copy
* the parameters to the x registers (reg[]).
*/
tmp = args;
arity = 0;
while (is_list(tmp)) {
if (arity < MAX_REG-1) {
reg[arity++] = CAR(list_val(tmp));
tmp = CDR(list_val(tmp));
} else {
p->freason = SYSTEM_LIMIT;
return NULL;
}
}
if (is_not_nil(tmp)) { /* Must be well-formed list */
p->freason = EXC_BADARG;
return NULL;
}
reg[arity] = fun;
return call_fun(p, arity, reg, args);
}
static Eterm
new_fun(Process* p, Eterm* reg, ErlFunEntry* fe, int num_free)
{
unsigned needed = ERL_FUN_SIZE + num_free;
ErlFunThing* funp;
Eterm* hp;
int i;
if (HEAP_LIMIT(p) - HEAP_TOP(p) <= needed) {
PROCESS_MAIN_CHK_LOCKS(p);
erts_garbage_collect(p, needed, reg, num_free);
ERTS_VERIFY_UNUSED_TEMP_ALLOC(p);
PROCESS_MAIN_CHK_LOCKS(p);
}
hp = p->htop;
p->htop = hp + needed;
funp = (ErlFunThing *) hp;
hp = funp->env;
erts_refc_inc(&fe->refc, 2);
funp->thing_word = HEADER_FUN;
funp->next = MSO(p).first;
MSO(p).first = (struct erl_off_heap_header*) funp;
funp->fe = fe;
funp->num_free = num_free;
funp->creator = p->common.id;
funp->arity = (int)fe->address[-1] - num_free;
for (i = 0; i < num_free; i++) {
*hp++ = reg[i];
}
return make_fun(funp);
}
static Eterm get_map_element(Eterm map, Eterm key)
{
Uint32 hx;
const Eterm *vs;
if (is_flatmap(map)) {
flatmap_t *mp;
Eterm *ks;
Uint i;
Uint n;
mp = (flatmap_t *)flatmap_val(map);
ks = flatmap_get_keys(mp);
vs = flatmap_get_values(mp);
n = flatmap_get_size(mp);
if (is_immed(key)) {
for (i = 0; i < n; i++) {
if (ks[i] == key) {
return vs[i];
}
}
} else {
for (i = 0; i < n; i++) {
if (EQ(ks[i], key)) {
return vs[i];
}
}
}
return THE_NON_VALUE;
}
ASSERT(is_hashmap(map));
hx = hashmap_make_hash(key);
vs = erts_hashmap_get(hx,key,map);
return vs ? *vs : THE_NON_VALUE;
}
static Eterm get_map_element_hash(Eterm map, Eterm key, Uint32 hx)
{
const Eterm *vs;
if (is_flatmap(map)) {
flatmap_t *mp;
Eterm *ks;
Uint i;
Uint n;
mp = (flatmap_t *)flatmap_val(map);
ks = flatmap_get_keys(mp);
vs = flatmap_get_values(mp);
n = flatmap_get_size(mp);
if (is_immed(key)) {
for (i = 0; i < n; i++) {
if (ks[i] == key) {
return vs[i];
}
}
} else {
for (i = 0; i < n; i++) {
if (EQ(ks[i], key)) {
return vs[i];
}
}
}
return THE_NON_VALUE;
}
ASSERT(is_hashmap(map));
ASSERT(hx == hashmap_make_hash(key));
vs = erts_hashmap_get(hx, key, map);
return vs ? *vs : THE_NON_VALUE;
}
#define GET_TERM(term, dest) \
do { \
Eterm src = (Eterm)(term); \
switch (loader_tag(src)) { \
case LOADER_X_REG: \
dest = x(loader_x_reg_index(src)); \
break; \
case LOADER_Y_REG: \
dest = y(loader_y_reg_index(src)); \
break; \
default: \
dest = src; \
break; \
} \
} while(0)
static Eterm
new_map(Process* p, Eterm* reg, Uint live, Uint n, BeamInstr* ptr)
{
Uint i;
Uint need = n + 1 /* hdr */ + 1 /*size*/ + 1 /* ptr */ + 1 /* arity */;
Eterm keys;
Eterm *mhp,*thp;
Eterm *E;
flatmap_t *mp;
ErtsHeapFactory factory;
if (n > 2*MAP_SMALL_MAP_LIMIT) {
Eterm res;
if (HeapWordsLeft(p) < n) {
erts_garbage_collect(p, n, reg, live);
}
mhp = p->htop;
thp = p->htop;
E = p->stop;
for (i = 0; i < n/2; i++) {
GET_TERM(*ptr++, *mhp++);
GET_TERM(*ptr++, *mhp++);
}
p->htop = mhp;
erts_factory_proc_init(&factory, p);
res = erts_hashmap_from_array(&factory, thp, n/2, 0);
erts_factory_close(&factory);
return res;
}
if (HeapWordsLeft(p) < need) {
erts_garbage_collect(p, need, reg, live);
}
thp = p->htop;
mhp = thp + 1 + n/2;
E = p->stop;
keys = make_tuple(thp);
*thp++ = make_arityval(n/2);
mp = (flatmap_t *)mhp; mhp += MAP_HEADER_FLATMAP_SZ;
mp->thing_word = MAP_HEADER_FLATMAP;
mp->size = n/2;
mp->keys = keys;
for (i = 0; i < n/2; i++) {
GET_TERM(*ptr++, *thp++);
GET_TERM(*ptr++, *mhp++);
}
p->htop = mhp;
return make_flatmap(mp);
}
static Eterm
new_small_map_lit(Process* p, Eterm* reg, Eterm keys_literal, Uint live, BeamInstr* ptr)
{
Eterm* keys = tuple_val(keys_literal);
Uint n = arityval(*keys);
Uint need = n + 1 /* hdr */ + 1 /*size*/ + 1 /* ptr */ + 1 /* arity */;
Uint i;
flatmap_t *mp;
Eterm *mhp;
Eterm *E;
ASSERT(n <= MAP_SMALL_MAP_LIMIT);
if (HeapWordsLeft(p) < need) {
erts_garbage_collect(p, need, reg, live);
}
mhp = p->htop;
E = p->stop;
mp = (flatmap_t *)mhp; mhp += MAP_HEADER_FLATMAP_SZ;
mp->thing_word = MAP_HEADER_FLATMAP;
mp->size = n;
mp->keys = keys_literal;
for (i = 0; i < n; i++) {
GET_TERM(*ptr++, *mhp++);
}
p->htop = mhp;
return make_flatmap(mp);
}
static Eterm
update_map_assoc(Process* p, Eterm* reg, Uint live, Uint n, BeamInstr* new_p)
{
Uint num_old;
Uint num_updates;
Uint need;
flatmap_t *old_mp, *mp;
Eterm res;
Eterm* hp;
Eterm* E;
Eterm* old_keys;
Eterm* old_vals;
Eterm new_key;
Eterm* kp;
Eterm map;
num_updates = n / 2;
map = reg[live];
if (is_not_flatmap(map)) {
Uint32 hx;
Eterm val;
ASSERT(is_hashmap(map));
res = map;
E = p->stop;
while(num_updates--) {
/* assoc can't fail */
GET_TERM(new_p[0], new_key);
GET_TERM(new_p[1], val);
hx = hashmap_make_hash(new_key);
res = erts_hashmap_insert(p, hx, new_key, val, res, 0);
new_p += 2;
}
return res;
}
old_mp = (flatmap_t *) flatmap_val(map);
num_old = flatmap_get_size(old_mp);
/*
* If the old map is empty, create a new map.
*/
if (num_old == 0) {
return new_map(p, reg, live, n, new_p);
}
/*
* Allocate heap space for the worst case (i.e. all keys in the
* update list are new).
*/
need = 2*(num_old+num_updates) + 1 + MAP_HEADER_FLATMAP_SZ;
if (HeapWordsLeft(p) < need) {
erts_garbage_collect(p, need, reg, live+1);
map = reg[live];
old_mp = (flatmap_t *)flatmap_val(map);
}
/*
* Build the skeleton for the map, ready to be filled in.
*
* +-----------------------------------+
* | (Space for aritvyal for keys) | <-----------+
* +-----------------------------------+ |
* | (Space for key 1) | | <-- kp
* +-----------------------------------+ |
* . |
* . |
* . |
* +-----------------------------------+ |
* | (Space for last key) | |
* +-----------------------------------+ |
* | MAP_HEADER | |
* +-----------------------------------+ |
* | (Space for number of keys/values) | |
* +-----------------------------------+ |
* | Boxed tuple pointer >----------------+
* +-----------------------------------+
* | (Space for value 1) | <-- hp
* +-----------------------------------+
*/
E = p->stop;
kp = p->htop + 1; /* Point to first key */
hp = kp + num_old + num_updates;
res = make_flatmap(hp);
mp = (flatmap_t *)hp;
hp += MAP_HEADER_FLATMAP_SZ;
mp->thing_word = MAP_HEADER_FLATMAP;
mp->keys = make_tuple(kp-1);
old_vals = flatmap_get_values(old_mp);
old_keys = flatmap_get_keys(old_mp);
GET_TERM(*new_p, new_key);
n = num_updates;
/*
* Fill in keys and values, until we run out of either updates
* or old values and keys.
*/
for (;;) {
Eterm key;
Sint c;
ASSERT(kp < (Eterm *)mp);
key = *old_keys;
if ((c = CMP_TERM(key, new_key)) < 0) {
/* Copy old key and value */
*kp++ = key;
*hp++ = *old_vals;
old_keys++, old_vals++, num_old--;
} else { /* Replace or insert new */
GET_TERM(new_p[1], *hp++);
if (c > 0) { /* If new new key */
*kp++ = new_key;
} else { /* If replacement */
*kp++ = key;
old_keys++, old_vals++, num_old--;
}
n--;
if (n == 0) {
break;
} else {
new_p += 2;
GET_TERM(*new_p, new_key);
}
}
if (num_old == 0) {
break;
}
}
/*
* At this point, we have run out of either old keys and values,
* or the update list. In other words, at least of one n and
* num_old must be zero.
*/
if (n > 0) {
/*
* All old keys and values have been copied, but there
* are still new keys and values in the update list that
* must be copied.
*/
ASSERT(num_old == 0);
while (n-- > 0) {
GET_TERM(new_p[0], *kp++);
GET_TERM(new_p[1], *hp++);
new_p += 2;
}
} else {
/*
* All updates are now done. We may still have old
* keys and values that we must copy.
*/
ASSERT(n == 0);
while (num_old-- > 0) {
ASSERT(kp < (Eterm *)mp);
*kp++ = *old_keys++;
*hp++ = *old_vals++;
}
}
/*
* Calculate how many values that are unused at the end of the
* key tuple and fill it out with a bignum header.
*/
if ((n = (Eterm *)mp - kp) > 0) {
*kp = make_pos_bignum_header(n-1);
}
/*
* Fill in the size of the map in both the key tuple and in the map.
*/
n = kp - p->htop - 1; /* Actual number of keys/values */
*p->htop = make_arityval(n);
p->htop = hp;
mp->size = n;
/* The expensive case, need to build a hashmap */
if (n > MAP_SMALL_MAP_LIMIT) {
ErtsHeapFactory factory;
erts_factory_proc_init(&factory, p);
res = erts_hashmap_from_ks_and_vs(&factory,flatmap_get_keys(mp),
flatmap_get_values(mp),n);
erts_factory_close(&factory);
}
return res;
}
/*
* Update values for keys that already exist in the map.
*/
static Eterm
update_map_exact(Process* p, Eterm* reg, Uint live, Uint n, Eterm* new_p)
{
Uint i;
Uint num_old;
Uint need;
flatmap_t *old_mp, *mp;
Eterm res;
Eterm* hp;
Eterm* E;
Eterm* old_keys;
Eterm* old_vals;
Eterm new_key;
Eterm map;
n /= 2; /* Number of values to be updated */
ASSERT(n > 0);
map = reg[live];
if (is_not_flatmap(map)) {
Uint32 hx;
Eterm val;
/* apparently the compiler does not emit is_map instructions,
* bad compiler */
if (is_not_hashmap(map)) {
p->freason = BADMAP;
p->fvalue = map;
return THE_NON_VALUE;
}
res = map;
E = p->stop;
while(n--) {
GET_TERM(new_p[0], new_key);
GET_TERM(new_p[1], val);
hx = hashmap_make_hash(new_key);
res = erts_hashmap_insert(p, hx, new_key, val, res, 1);
if (is_non_value(res)) {
p->fvalue = new_key;
p->freason = BADKEY;
return res;
}
new_p += 2;
}
return res;
}
old_mp = (flatmap_t *) flatmap_val(map);
num_old = flatmap_get_size(old_mp);
/*
* If the old map is empty, fail.
*/
if (num_old == 0) {
E = p->stop;
p->freason = BADKEY;
GET_TERM(new_p[0], p->fvalue);
return THE_NON_VALUE;
}
/*
* Allocate the exact heap space needed.
*/
need = num_old + MAP_HEADER_FLATMAP_SZ;
if (HeapWordsLeft(p) < need) {
erts_garbage_collect(p, need, reg, live+1);
map = reg[live];
old_mp = (flatmap_t *)flatmap_val(map);
}
/*
* Update map, keeping the old key tuple.
*/
hp = p->htop;
E = p->stop;
old_vals = flatmap_get_values(old_mp);
old_keys = flatmap_get_keys(old_mp);
res = make_flatmap(hp);
mp = (flatmap_t *)hp;
hp += MAP_HEADER_FLATMAP_SZ;
mp->thing_word = MAP_HEADER_FLATMAP;
mp->size = num_old;
mp->keys = old_mp->keys;
/* Get array of key/value pairs to be updated */
GET_TERM(*new_p, new_key);
/* Update all values */
for (i = 0; i < num_old; i++) {
if (!EQ(*old_keys, new_key)) {
/* Not same keys */
*hp++ = *old_vals;
} else {
GET_TERM(new_p[1], *hp);
hp++;
n--;
if (n == 0) {
/*
* All updates done. Copy remaining values
* and return the result.
*/
for (i++, old_vals++; i < num_old; i++) {
*hp++ = *old_vals++;
}
ASSERT(hp == p->htop + need);
p->htop = hp;
return res;
} else {
new_p += 2;
GET_TERM(*new_p, new_key);
}
}
old_vals++, old_keys++;
}
/*
* Updates left. That means that at least one the keys in the
* update list did not previously exist.
*/
ASSERT(hp == p->htop + need);
p->freason = BADKEY;
p->fvalue = new_key;
return THE_NON_VALUE;
}
#undef GET_TERM
int catchlevel(Process *p)
{
return p->catches;
}
/*
* Check if the given function is built-in (i.e. a BIF implemented in C).
*
* Returns 0 if not built-in, and a non-zero value if built-in.
*/
int
erts_is_builtin(Eterm Mod, Eterm Name, int arity)
{
Export e;
Export* ep;
if (Mod == am_erlang && Name == am_apply && arity == 3) {
/*
* Special case. apply/3 is built-in (implemented in C),
* but implemented in a different way than all other
* BIFs.
*/
return 1;
}
e.info.mfa.module = Mod;
e.info.mfa.function = Name;
e.info.mfa.arity = arity;
if ((ep = export_get(&e)) == NULL) {
return 0;
}
return ep->addressv[erts_active_code_ix()] == ep->beam &&
BeamIsOpCode(ep->beam[0], op_apply_bif);
}
/*
* Return the current number of reductions for the given process.
* To get the total number of reductions, p->reds must be added.
*/
Uint
erts_current_reductions(Process *current, Process *p)
{
if (current != p) {
return 0;
} else if (current->fcalls < 0 && ERTS_PROC_GET_SAVED_CALLS_BUF(current)) {
return current->fcalls + CONTEXT_REDS;
} else {
return REDS_IN(current) - current->fcalls;
}
}
int
erts_beam_jump_table(void)
{
#if defined(NO_JUMP_TABLE)
return 0;
#else
return 1;
#endif
}
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