/*
* %CopyrightBegin%
*
* Copyright Ericsson AB 2001-2012. All Rights Reserved.
*
* The contents of this file are subject to the Erlang Public License,
* Version 1.1, (the "License"); you may not use this file except in
* compliance with the License. You should have received a copy of the
* Erlang Public License along with this software. If not, it can be
* retrieved online at http://www.erlang.org/.
*
* Software distributed under the License is distributed on an "AS IS"
* basis, WITHOUT WARRANTY OF ANY KIND, either express or implied. See
* the License for the specific language governing rights and limitations
* under the License.
*
* %CopyrightEnd%
*/
/*
* hipe_bif0.c
*
* Compiler and linker support.
*/
#ifdef HAVE_CONFIG_H
#include "config.h"
#endif
#include "sys.h"
#include "error.h"
#include "erl_vm.h"
#include "global.h"
#include "erl_process.h"
#include "bif.h"
#include "big.h"
#include "beam_load.h"
#include "erl_db.h"
#include "hash.h"
#include "erl_bits.h"
#include "erl_binary.h"
#ifdef HIPE
#include <stddef.h> /* offsetof() */
#include "hipe_arch.h"
#include "hipe_stack.h"
#include "hipe_mode_switch.h"
#include "hipe_native_bif.h"
#include "hipe_bif0.h"
/* We need hipe_literals.h for HIPE_SYSTEM_CRC, but it redefines
a few constants. #undef them here to avoid warnings. */
#undef F_TIMO
#undef THE_NON_VALUE
#undef ERL_FUN_SIZE
#include "hipe_literals.h"
#endif
#define BeamOpCode(Op) ((Uint)BeamOp(Op))
int term_to_Sint32(Eterm term, Sint *sp)
{
Sint val;
if (!term_to_Sint(term, &val))
return 0;
if ((Sint)(Sint32)val != val)
return 0;
*sp = val;
return 1;
}
static Eterm Uint_to_term(Uint x, Process *p)
{
if (IS_USMALL(0, x)) {
return make_small(x);
} else {
Eterm *hp = HAlloc(p, BIG_UINT_HEAP_SIZE);
return uint_to_big(x, hp);
}
}
void *term_to_address(Eterm arg)
{
Uint u;
return term_to_Uint(arg, &u) ? (void*)u : NULL;
}
static Eterm address_to_term(const void *address, Process *p)
{
return Uint_to_term((Uint)address, p);
}
/*
* BIFs for reading and writing memory. Used internally by HiPE.
*/
#if 0 /* XXX: unused */
BIF_RETTYPE hipe_bifs_read_u8_1(BIF_ALIST_1)
{
unsigned char *address = term_to_address(BIF_ARG_1);
if (!address)
BIF_ERROR(BIF_P, BADARG);
BIF_RET(make_small(*address));
}
#endif
#if 0 /* XXX: unused */
BIF_RETTYPE hipe_bifs_read_u32_1(BIF_ALIST_1)
{
Uint32 *address = term_to_address(BIF_ARG_1);
if (!address || !hipe_word32_address_ok(address))
BIF_ERROR(BIF_P, BADARG);
BIF_RET(Uint_to_term(*address, BIF_P));
}
#endif
BIF_RETTYPE hipe_bifs_write_u8_2(BIF_ALIST_2)
{
unsigned char *address;
address = term_to_address(BIF_ARG_1);
if (!address || is_not_small(BIF_ARG_2))
BIF_ERROR(BIF_P, BADARG);
*address = unsigned_val(BIF_ARG_2);
BIF_RET(NIL);
}
#if 0 /* XXX: unused */
BIF_RETTYPE hipe_bifs_write_s32_2(BIF_ALIST_2)
{
Sint32 *address;
Sint value;
address = term_to_address(BIF_ARG_1);
if (!address || !hipe_word32_address_ok(address))
BIF_ERROR(BIF_P, BADARG);
if (!term_to_Sint32(BIF_ARG_2, &value))
BIF_ERROR(BIF_P, BADARG);
*address = value;
BIF_RET(NIL);
}
#endif
BIF_RETTYPE hipe_bifs_write_u32_2(BIF_ALIST_2)
{
Uint32 *address;
Uint value;
address = term_to_address(BIF_ARG_1);
if (!address || !hipe_word32_address_ok(address))
BIF_ERROR(BIF_P, BADARG);
if (!term_to_Uint(BIF_ARG_2, &value))
BIF_ERROR(BIF_P, BADARG);
if ((Uint)(Uint32)value != value)
BIF_ERROR(BIF_P, BADARG);
*address = value;
hipe_flush_icache_word(address);
BIF_RET(NIL);
}
/*
* BIFs for mutable bytearrays.
*/
BIF_RETTYPE hipe_bifs_bytearray_2(BIF_ALIST_2)
{
Sint nelts;
Eterm bin;
if (is_not_small(BIF_ARG_1) ||
(nelts = signed_val(BIF_ARG_1)) < 0 ||
!is_byte(BIF_ARG_2))
BIF_ERROR(BIF_P, BADARG);
bin = new_binary(BIF_P, NULL, nelts);
memset(binary_bytes(bin), unsigned_val(BIF_ARG_2), nelts);
BIF_RET(bin);
}
static inline unsigned char *bytearray_lvalue(Eterm bin, Eterm idx)
{
Sint i;
unsigned char *bytes;
#ifndef DEBUG
ERTS_DECLARE_DUMMY(Uint bitoffs);
ERTS_DECLARE_DUMMY(Uint bitsize);
#else
Uint bitoffs;
Uint bitsize;
#endif
if (is_not_binary(bin) ||
is_not_small(idx) ||
(i = unsigned_val(idx)) >= binary_size(bin))
return NULL;
ERTS_GET_BINARY_BYTES(bin, bytes, bitoffs, bitsize);
ASSERT(bitoffs == 0);
ASSERT(bitsize == 0);
return bytes + i;
}
BIF_RETTYPE hipe_bifs_bytearray_sub_2(BIF_ALIST_2)
{
unsigned char *bytep;
bytep = bytearray_lvalue(BIF_ARG_1, BIF_ARG_2);
if (!bytep)
BIF_ERROR(BIF_P, BADARG);
BIF_RET(make_small(*bytep));
}
BIF_RETTYPE hipe_bifs_bytearray_update_3(BIF_ALIST_3)
{
unsigned char *bytep;
bytep = bytearray_lvalue(BIF_ARG_1, BIF_ARG_2);
if (!bytep || !is_byte(BIF_ARG_3))
BIF_ERROR(BIF_P, BADARG);
*bytep = unsigned_val(BIF_ARG_3);
BIF_RET(BIF_ARG_1);
}
BIF_RETTYPE hipe_bifs_bitarray_2(BIF_ALIST_2)
{
Sint nbits;
Uint nbytes;
Eterm bin;
int bytemask;
if (is_not_small(BIF_ARG_1))
BIF_ERROR(BIF_P, BADARG);
nbits = signed_val(BIF_ARG_1);
if (nbits < 0)
BIF_ERROR(BIF_P, BADARG);
if (BIF_ARG_2 == am_false)
bytemask = 0;
else if (BIF_ARG_2 == am_true)
bytemask = ~0;
else
BIF_ERROR(BIF_P, BADARG);
nbytes = ((Uint)nbits + ((1 << 3) - 1)) >> 3;
bin = new_binary(BIF_P, NULL, nbytes);
memset(binary_bytes(bin), bytemask, nbytes);
BIF_RET(bin);
}
BIF_RETTYPE hipe_bifs_bitarray_update_3(BIF_ALIST_3)
{
unsigned char *bytes, bytemask;
Uint bitnr, bytenr;
int set;
#ifndef DEBUG
ERTS_DECLARE_DUMMY(Uint bitoffs);
ERTS_DECLARE_DUMMY(Uint bitsize);
#else
Uint bitoffs;
Uint bitsize;
#endif
if (is_not_binary(BIF_ARG_1))
BIF_ERROR(BIF_P, BADARG);
if (is_not_small(BIF_ARG_2))
BIF_ERROR(BIF_P, BADARG);
bitnr = unsigned_val(BIF_ARG_2);
bytenr = bitnr >> 3;
if (bytenr >= binary_size(BIF_ARG_1))
BIF_ERROR(BIF_P, BADARG);
if (BIF_ARG_3 == am_false)
set = 0;
else if (BIF_ARG_3 == am_true)
set = 1;
else
BIF_ERROR(BIF_P, BADARG);
ERTS_GET_BINARY_BYTES(BIF_ARG_1, bytes, bitoffs, bitsize);
ASSERT(bitoffs == 0);
ASSERT(bitsize == 0);
bytemask = 1 << (bitnr & ((1 << 3) - 1));
if (set)
bytes[bytenr] |= bytemask;
else
bytes[bytenr] &= ~bytemask;
BIF_RET(BIF_ARG_1);
}
BIF_RETTYPE hipe_bifs_bitarray_sub_2(BIF_ALIST_2)
{
unsigned char *bytes, bytemask;
Uint bitnr, bytenr;
#ifndef DEBUG
ERTS_DECLARE_DUMMY(Uint bitoffs);
ERTS_DECLARE_DUMMY(Uint bitsize);
#else
Uint bitoffs;
Uint bitsize;
#endif
if (is_not_binary(BIF_ARG_1))
BIF_ERROR(BIF_P, BADARG);
if (is_not_small(BIF_ARG_2))
BIF_ERROR(BIF_P, BADARG);
bitnr = unsigned_val(BIF_ARG_2);
bytenr = bitnr >> 3;
if (bytenr >= binary_size(BIF_ARG_1))
BIF_ERROR(BIF_P, BADARG);
ERTS_GET_BINARY_BYTES(BIF_ARG_1, bytes, bitoffs, bitsize);
ASSERT(bitoffs == 0);
ASSERT(bitsize == 0);
bytemask = 1 << (bitnr & ((1 << 3) - 1));
if ((bytes[bytenr] & bytemask) == 0)
BIF_RET(am_false);
else
BIF_RET(am_true);
}
/*
* BIFs for SML-like mutable arrays and reference cells.
* For now, limited to containing immediate data.
*/
#if 1 /* use bignums as carriers, easier on the gc */
#define make_array_header(sz) make_pos_bignum_header((sz))
#define array_header_arity(h) header_arity((h))
#define make_array(hp) make_big((hp))
#define is_not_array(x) is_not_big((x))
#define array_val(x) big_val((x))
#else /* use tuples as carriers, easier debugging, harder on the gc */
#define make_array_header(sz) make_arityval((sz))
#define array_header_arity(h) arityval((h))
#define make_array(hp) make_tuple((hp))
#define is_not_array(x) is_not_tuple((x))
#define array_val(x) tuple_val((x))
#endif
#define array_length(a) array_header_arity(array_val((a))[0])
BIF_RETTYPE hipe_bifs_array_2(BIF_ALIST_2)
{
Eterm *hp;
Sint nelts, i;
if (is_not_small(BIF_ARG_1) ||
(nelts = signed_val(BIF_ARG_1)) < 0 ||
is_not_immed(BIF_ARG_2))
BIF_ERROR(BIF_P, BADARG);
if (nelts == 0) /* bignums must not be empty */
BIF_RET(make_small(0));
hp = HAlloc(BIF_P, 1+nelts);
hp[0] = make_array_header(nelts);
for (i = 1; i <= nelts; ++i)
hp[i] = BIF_ARG_2;
BIF_RET(make_array(hp));
}
BIF_RETTYPE hipe_bifs_array_length_1(BIF_ALIST_1)
{
if (is_not_array(BIF_ARG_1)) {
if (BIF_ARG_1 == make_small(0)) /* fixnum 0 represents empty arrays */
BIF_RET(make_small(0));
BIF_ERROR(BIF_P, BADARG);
}
BIF_RET(make_small(array_header_arity(array_val(BIF_ARG_1)[0])));
}
BIF_RETTYPE hipe_bifs_array_sub_2(BIF_ALIST_2)
{
Uint i;
if (is_not_small(BIF_ARG_2) ||
is_not_array(BIF_ARG_1) ||
(i = unsigned_val(BIF_ARG_2)) >= array_length(BIF_ARG_1))
BIF_ERROR(BIF_P, BADARG);
BIF_RET(array_val(BIF_ARG_1)[i+1]);
}
BIF_RETTYPE hipe_bifs_array_update_3(BIF_ALIST_3)
{
Uint i;
if (is_not_immed(BIF_ARG_3) ||
is_not_small(BIF_ARG_2) ||
is_not_array(BIF_ARG_1) ||
(i = unsigned_val(BIF_ARG_2)) >= array_length(BIF_ARG_1))
BIF_ERROR(BIF_P, BADARG);
array_val(BIF_ARG_1)[i+1] = BIF_ARG_3;
BIF_RET(BIF_ARG_1);
}
BIF_RETTYPE hipe_bifs_ref_1(BIF_ALIST_1)
{
Eterm *hp;
if (is_not_immed(BIF_ARG_1))
BIF_RET(BADARG);
hp = HAlloc(BIF_P, 1+1);
hp[0] = make_array_header(1);
hp[1] = BIF_ARG_1;
BIF_RET(make_array(hp));
}
BIF_RETTYPE hipe_bifs_ref_get_1(BIF_ALIST_1)
{
if (is_not_array(BIF_ARG_1) ||
array_val(BIF_ARG_1)[0] != make_array_header(1))
BIF_ERROR(BIF_P, BADARG);
BIF_RET(array_val(BIF_ARG_1)[1]);
}
BIF_RETTYPE hipe_bifs_ref_set_2(BIF_ALIST_2)
{
if (is_not_immed(BIF_ARG_2) ||
is_not_array(BIF_ARG_1) ||
array_val(BIF_ARG_1)[0] != make_array_header(1))
BIF_ERROR(BIF_P, BADARG);
array_val(BIF_ARG_1)[1] = BIF_ARG_2;
BIF_RET(BIF_ARG_1);
}
/*
* Allocate memory and copy machine code to it.
*/
BIF_RETTYPE hipe_bifs_enter_code_2(BIF_ALIST_2)
{
Uint nrbytes;
void *bytes;
void *address;
Eterm trampolines;
Eterm *hp;
#ifndef DEBUG
ERTS_DECLARE_DUMMY(Uint bitoffs);
ERTS_DECLARE_DUMMY(Uint bitsize);
#else
Uint bitoffs;
Uint bitsize;
#endif
if (is_not_binary(BIF_ARG_1))
BIF_ERROR(BIF_P, BADARG);
nrbytes = binary_size(BIF_ARG_1);
ERTS_GET_BINARY_BYTES(BIF_ARG_1, bytes, bitoffs, bitsize);
ASSERT(bitoffs == 0);
ASSERT(bitsize == 0);
trampolines = NIL;
#ifdef HIPE_ALLOC_CODE
address = HIPE_ALLOC_CODE(nrbytes, BIF_ARG_2, &trampolines, BIF_P);
if (!address)
BIF_ERROR(BIF_P, BADARG);
#else
if (is_not_nil(BIF_ARG_2))
BIF_ERROR(BIF_P, BADARG);
address = erts_alloc(ERTS_ALC_T_HIPE, nrbytes);
#endif
memcpy(address, bytes, nrbytes);
hipe_flush_icache_range(address, nrbytes);
hp = HAlloc(BIF_P, 3);
hp[0] = make_arityval(2);
hp[1] = address_to_term(address, BIF_P);
hp[2] = trampolines;
BIF_RET(make_tuple(hp));
}
/*
* Allocate memory for arbitrary non-Erlang data.
*/
BIF_RETTYPE hipe_bifs_alloc_data_2(BIF_ALIST_2)
{
Uint align, nrbytes;
void *block;
if (is_not_small(BIF_ARG_1) || is_not_small(BIF_ARG_2) ||
(align = unsigned_val(BIF_ARG_1),
align != sizeof(long) && align != sizeof(double)))
BIF_ERROR(BIF_P, BADARG);
nrbytes = unsigned_val(BIF_ARG_2);
if (nrbytes == 0)
BIF_RET(make_small(0));
block = erts_alloc(ERTS_ALC_T_HIPE, nrbytes);
if ((unsigned long)block & (align-1))
fprintf(stderr, "%s: erts_alloc(%lu) returned %p which is not %lu-byte aligned\r\n",
__FUNCTION__, (unsigned long)nrbytes, block, (unsigned long)align);
BIF_RET(address_to_term(block, BIF_P));
}
/*
* Statistics on hipe constants: size of HiPE constants, in words.
*/
unsigned int hipe_constants_size = 0;
BIF_RETTYPE hipe_bifs_constants_size_0(BIF_ALIST_0)
{
BIF_RET(make_small(hipe_constants_size));
}
/*
* Merging constant Erlang terms.
* Uses the constants pool and a hash table of all top-level
* terms merged so far. (Sub-terms are not merged.)
*/
struct const_term {
HashBucket bucket;
Eterm val; /* tagged pointer to mem[0] */
Eterm mem[1]; /* variable size */
};
static Hash const_term_table;
static ErlOffHeap const_term_table_off_heap;
static HashValue const_term_hash(void *tmpl)
{
return make_hash2((Eterm)tmpl);
}
static int const_term_cmp(void *tmpl, void *bucket)
{
return !eq((Eterm)tmpl, ((struct const_term*)bucket)->val);
}
static void *const_term_alloc(void *tmpl)
{
Eterm obj;
Uint size;
Uint alloc_size;
Eterm *hp;
struct const_term *p;
obj = (Eterm)tmpl;
ASSERT(is_not_immed(obj));
size = size_object(obj);
alloc_size = size + (offsetof(struct const_term, mem)/sizeof(Eterm));
hipe_constants_size += alloc_size;
p = (struct const_term*)erts_alloc(ERTS_ALC_T_HIPE, alloc_size * sizeof(Eterm));
/* I have absolutely no idea if having a private 'off_heap'
works or not. _Some_ off_heap object is required for
REFC_BINARY and FUN values, but _where_ it should be is
a complete mystery to me. */
hp = &p->mem[0];
p->val = copy_struct(obj, size, &hp, &const_term_table_off_heap);
return &p->bucket;
}
static void init_const_term_table(void)
{
HashFunctions f;
f.hash = (H_FUN) const_term_hash;
f.cmp = (HCMP_FUN) const_term_cmp;
f.alloc = (HALLOC_FUN) const_term_alloc;
f.free = (HFREE_FUN) NULL;
hash_init(ERTS_ALC_T_HIPE, &const_term_table, "const_term_table", 97, f);
}
BIF_RETTYPE hipe_bifs_merge_term_1(BIF_ALIST_1)
{
static int init_done = 0;
struct const_term *p;
Eterm val;
val = BIF_ARG_1;
if (is_not_immed(val)) {
if (!init_done) {
init_const_term_table();
init_done = 1;
}
p = (struct const_term*)hash_put(&const_term_table, (void*)val);
val = p->val;
}
BIF_RET(val);
}
struct mfa {
Eterm mod;
Eterm fun;
Uint ari;
};
static int term_to_mfa(Eterm term, struct mfa *mfa)
{
Eterm mod, fun, a;
Uint ari;
if (is_not_tuple(term))
return 0;
if (tuple_val(term)[0] != make_arityval(3))
return 0;
mod = tuple_val(term)[1];
if (is_not_atom(mod))
return 0;
mfa->mod = mod;
fun = tuple_val(term)[2];
if (is_not_atom(fun))
return 0;
mfa->fun = fun;
a = tuple_val(term)[3];
if (is_not_small(a))
return 0;
ari = unsigned_val(a);
if (ari > 255)
return 0;
mfa->ari = ari;
return 1;
}
#ifdef DEBUG_LINKER
static void print_mfa(Eterm mod, Eterm fun, unsigned int ari)
{
erts_printf("%T:%T/%u", mod, fun, ari);
}
#endif
/*
* Convert {M,F,A} to pointer to first insn after initial func_info.
*/
static Uint *hipe_find_emu_address(Eterm mod, Eterm name, unsigned int arity)
{
Module *modp;
Uint *code_base;
int i, n;
modp = erts_get_module(mod, erts_active_code_ix());
if (modp == NULL || (code_base = modp->curr.code) == NULL)
return NULL;
n = code_base[MI_NUM_FUNCTIONS];
for (i = 0; i < n; ++i) {
Uint *code_ptr = (Uint*)code_base[MI_FUNCTIONS+i];
ASSERT(code_ptr[0] == BeamOpCode(op_i_func_info_IaaI));
if (code_ptr[3] == name && code_ptr[4] == arity)
return code_ptr+5;
}
return NULL;
}
Uint *hipe_bifs_find_pc_from_mfa(Eterm term)
{
struct mfa mfa;
if (!term_to_mfa(term, &mfa))
return NULL;
return hipe_find_emu_address(mfa.mod, mfa.fun, mfa.ari);
}
BIF_RETTYPE hipe_bifs_fun_to_address_1(BIF_ALIST_1)
{
Eterm *pc = hipe_bifs_find_pc_from_mfa(BIF_ARG_1);
if (!pc)
BIF_ERROR(BIF_P, BADARG);
BIF_RET(address_to_term(pc, BIF_P));
}
static void *hipe_get_emu_address(Eterm m, Eterm f, unsigned int arity, int is_remote)
{
void *address = NULL;
if (!is_remote)
address = hipe_find_emu_address(m, f, arity);
if (!address) {
/* if not found, stub it via the export entry */
/* no lock needed around erts_export_get_or_make_stub() */
Export *export_entry = erts_export_get_or_make_stub(m, f, arity);
address = export_entry->addressv[erts_active_code_ix()];
}
return address;
}
#if 0 /* XXX: unused */
BIF_RETTYPE hipe_bifs_get_emu_address_1(BIF_ALIST_1)
{
struct mfa mfa;
void *address;
if (!term_to_mfa(BIF_ARG_1, &mfa))
BIF_ERROR(BIF_P, BADARG);
address = hipe_get_emu_address(mfa.mod, mfa.fun, mfa.ari);
BIF_RET(address_to_term(address, BIF_P));
}
#endif
BIF_RETTYPE hipe_bifs_set_native_address_3(BIF_ALIST_3)
{
Eterm *pc;
void *address;
int is_closure;
struct mfa mfa;
switch (BIF_ARG_3) {
case am_false:
is_closure = 0;
break;
case am_true:
is_closure = 1;
break;
default:
BIF_ERROR(BIF_P, BADARG);
}
address = term_to_address(BIF_ARG_2);
if (!address)
BIF_ERROR(BIF_P, BADARG);
/* The mfa is needed again later, otherwise we could
simply have called hipe_bifs_find_pc_from_mfa(). */
if (!term_to_mfa(BIF_ARG_1, &mfa))
BIF_ERROR(BIF_P, BADARG);
pc = hipe_find_emu_address(mfa.mod, mfa.fun, mfa.ari);
if (pc) {
hipe_mfa_save_orig_beam_op(mfa.mod, mfa.fun, mfa.ari, pc);
#if HIPE
#ifdef DEBUG_LINKER
printf("%s: ", __FUNCTION__);
print_mfa(mfa.mod, mfa.fun, mfa.ari);
printf(": planting call trap to %p at BEAM pc %p\r\n", address, pc);
#endif
hipe_set_call_trap(pc, address, is_closure);
BIF_RET(am_true);
#endif
}
#ifdef DEBUG_LINKER
printf("%s: ", __FUNCTION__);
print_mfa(mfa.mod, mfa.fun, mfa.ari);
printf(": no BEAM pc found\r\n");
#endif
BIF_RET(am_false);
}
#if 0 /* XXX: unused */
/*
* hipe_bifs_address_to_fun(Address)
* - Address is the address of the start of a emu function's code
* - returns {Module, Function, Arity}
*/
BIF_RETTYPE hipe_bifs_address_to_fun_1(BIF_ALIST_1)
{
Eterm *pc;
Eterm *funcinfo;
Eterm *hp;
pc = term_to_address(BIF_ARG_1);
if (!pc)
BIF_ERROR(BIF_P, BADARG);
funcinfo = find_function_from_pc(pc);
if (!funcinfo)
BIF_RET(am_false);
hp = HAlloc(BIF_P, 4);
hp[0] = make_arityval(3);
hp[1] = funcinfo[0];
hp[2] = funcinfo[1];
hp[3] = make_small(funcinfo[2]);
BIF_RET(make_tuple(hp));
}
#endif
BIF_RETTYPE hipe_bifs_enter_sdesc_1(BIF_ALIST_1)
{
struct sdesc *sdesc;
sdesc = hipe_decode_sdesc(BIF_ARG_1);
if (!sdesc) {
fprintf(stderr, "%s: bad sdesc!\r\n", __FUNCTION__);
BIF_ERROR(BIF_P, BADARG);
}
if (hipe_put_sdesc(sdesc) != sdesc) {
fprintf(stderr, "%s: duplicate entry!\r\n", __FUNCTION__);
BIF_ERROR(BIF_P, BADARG);
}
BIF_RET(NIL);
}
/*
* Hash table mapping {M,F,A} to nbif address.
*/
struct nbif {
HashBucket bucket;
Eterm mod;
Eterm fun;
unsigned arity;
const void *address;
};
static struct nbif nbifs[BIF_SIZE] = {
#define BIF_LIST(MOD,FUN,ARY,CFUN,IX) \
{ {0,0}, MOD, FUN, ARY, &nbif_##CFUN },
#include "erl_bif_list.h"
#undef BIF_LIST
};
#define NBIF_HASH(m,f,a) ((m)*(f)+(a))
static Hash nbif_table;
static HashValue nbif_hash(struct nbif *x)
{
return NBIF_HASH(x->mod, x->fun, x->arity);
}
static int nbif_cmp(struct nbif *x, struct nbif *y)
{
return !(x->mod == y->mod && x->fun == y->fun && x->arity == y->arity);
}
static struct nbif *nbif_alloc(struct nbif *x)
{
return x; /* pre-allocated */
}
static void init_nbif_table(void)
{
HashFunctions f;
int i;
f.hash = (H_FUN) nbif_hash;
f.cmp = (HCMP_FUN) nbif_cmp;
f.alloc = (HALLOC_FUN) nbif_alloc;
f.free = NULL;
hash_init(ERTS_ALC_T_NBIF_TABLE, &nbif_table, "nbif_table", 500, f);
for (i = 0; i < BIF_SIZE; ++i)
hash_put(&nbif_table, &nbifs[i]);
}
static const void *nbif_address(Eterm mod, Eterm fun, unsigned arity)
{
struct nbif tmpl;
struct nbif *nbif;
tmpl.mod = mod;
tmpl.fun = fun;
tmpl.arity = arity;
nbif = hash_get(&nbif_table, &tmpl);
return nbif ? nbif->address : NULL;
}
/*
* hipe_bifs_bif_address(M,F,A) -> address or false
*/
BIF_RETTYPE hipe_bifs_bif_address_3(BIF_ALIST_3)
{
const void *address;
static int init_done = 0;
if (!init_done) {
init_nbif_table();
init_done = 1;
}
if (is_not_atom(BIF_ARG_1) ||
is_not_atom(BIF_ARG_2) ||
is_not_small(BIF_ARG_3) ||
signed_val(BIF_ARG_3) < 0)
BIF_RET(am_false);
address = nbif_address(BIF_ARG_1, BIF_ARG_2, unsigned_val(BIF_ARG_3));
if (address)
BIF_RET(address_to_term(address, BIF_P));
BIF_RET(am_false);
}
/*
* Hash table mapping primops to their addresses.
*/
struct primop {
HashBucket bucket; /* bucket.hvalue == atom_val(name) */
const void *address;
#if defined(__arm__)
void *trampoline;
#endif
};
static struct primop primops[] = {
#define PRIMOP_LIST(ATOM,ADDRESS) { {0,_unchecked_atom_val(ATOM)}, ADDRESS },
#include "hipe_primops.h"
#undef PRIMOP_LIST
};
static Hash primop_table;
static HashValue primop_hash(void *tmpl)
{
return ((struct primop*)tmpl)->bucket.hvalue; /* pre-initialised */
}
static int primop_cmp(void *tmpl, void *bucket)
{
return 0; /* hvalue matched so nothing further to do */
}
static void *primop_alloc(void *tmpl)
{
return tmpl; /* pre-allocated */
}
static void init_primop_table(void)
{
HashFunctions f;
int i;
static int init_done = 0;
if (init_done)
return;
init_done = 1;
f.hash = (H_FUN) primop_hash;
f.cmp = (HCMP_FUN) primop_cmp;
f.alloc = (HALLOC_FUN) primop_alloc;
f.free = NULL;
hash_init(ERTS_ALC_T_HIPE, &primop_table, "primop_table", 50, f);
for (i = 0; i < sizeof(primops)/sizeof(primops[0]); ++i)
hash_put(&primop_table, &primops[i]);
}
static struct primop *primop_table_get(Eterm name)
{
struct primop tmpl;
init_primop_table();
tmpl.bucket.hvalue = atom_val(name);
return hash_get(&primop_table, &tmpl);
}
#if defined(__arm__)
static struct primop *primop_table_put(Eterm name)
{
struct primop tmpl;
init_primop_table();
tmpl.bucket.hvalue = atom_val(name);
return hash_put(&primop_table, &tmpl);
}
void *hipe_primop_get_trampoline(Eterm name)
{
struct primop *primop = primop_table_get(name);
return primop ? primop->trampoline : NULL;
}
void hipe_primop_set_trampoline(Eterm name, void *trampoline)
{
struct primop *primop = primop_table_put(name);
primop->trampoline = trampoline;
}
#endif
/*
* hipe_bifs_primop_address(Atom) -> address or false
*/
BIF_RETTYPE hipe_bifs_primop_address_1(BIF_ALIST_1)
{
const struct primop *primop;
if (is_not_atom(BIF_ARG_1))
BIF_RET(am_false);
primop = primop_table_get(BIF_ARG_1);
if (!primop)
BIF_RET(am_false);
BIF_RET(address_to_term(primop->address, BIF_P));
}
#if 0 /* XXX: unused */
/*
* hipe_bifs_gbif_address(F,A) -> address or false
*/
#define GBIF_LIST(ATOM,ARY,CFUN) extern Eterm gbif_##CFUN(void);
#include "hipe_gbif_list.h"
#undef GBIF_LIST
BIF_RETTYPE hipe_bifs_gbif_address_2(BIF_ALIST_2)
{
Uint arity;
void *address;
if (is_not_atom(BIF_ARG_1) || is_not_small(BIF_ARG_2))
BIF_RET(am_false); /* error or false, does it matter? */
arity = signed_val(BIF_ARG_2);
/* XXX: replace with a hash table later */
do { /* trick to let us use 'break' instead of 'goto' */
#define GBIF_LIST(ATOM,ARY,CFUN) if (BIF_ARG_1 == ATOM && arity == ARY) { address = CFUN; break; }
#include "hipe_gbif_list.h"
#undef GBIF_LIST
printf("\r\n%s: guard BIF ", __FUNCTION__);
fflush(stdout);
erts_printf("%T", BIF_ARG_1);
printf("/%lu isn't listed in hipe_gbif_list.h\r\n", arity);
BIF_RET(am_false);
} while (0);
BIF_RET(address_to_term(address, BIF_P));
}
#endif
BIF_RETTYPE hipe_bifs_atom_to_word_1(BIF_ALIST_1)
{
if (is_not_atom(BIF_ARG_1))
BIF_ERROR(BIF_P, BADARG);
BIF_RET(Uint_to_term(BIF_ARG_1, BIF_P));
}
BIF_RETTYPE hipe_bifs_term_to_word_1(BIF_ALIST_1)
{
BIF_RET(Uint_to_term(BIF_ARG_1, BIF_P));
}
/* XXX: this is really a primop, not a BIF */
BIF_RETTYPE hipe_conv_big_to_float(BIF_ALIST_1)
{
Eterm res;
Eterm *hp;
FloatDef f;
if (is_not_big(BIF_ARG_1))
BIF_ERROR(BIF_P, BADARG);
if (big_to_double(BIF_ARG_1, &f.fd) < 0)
BIF_ERROR(BIF_P, BADARG);
hp = HAlloc(BIF_P, FLOAT_SIZE_OBJECT);
res = make_float(hp);
PUT_DOUBLE(f, hp);
BIF_RET(res);
}
#ifdef NO_FPE_SIGNALS
/*
This is the current solution to make hipe run without FPE.
The native code is the same except that a call to this primop
is made after _every_ float operation to check the result.
The native fcheckerror still done later will detect if an
"emulated" FPE has occured.
We use p->hipe.float_result to avoid passing a 'double' argument,
which has its own calling convention (on amd64 at least).
Simple and slow...
*/
void hipe_emulate_fpe(Process* p)
{
if (!finite(p->hipe.float_result)) {
p->fp_exception = 1;
}
}
#endif
#if 0 /* XXX: unused */
/*
* At least parts of this should be inlined in native code.
* The rest could be made a primop used by both the emulator and
* native code...
*/
BIF_RETTYPE hipe_bifs_make_fun_3(BIF_ALIST_3)
{
Eterm free_vars;
Eterm mod;
Eterm *tp;
Uint index;
Uint uniq;
Uint num_free;
Eterm tmp_var;
Uint *tmp_ptr;
unsigned needed;
ErlFunThing *funp;
Eterm *hp;
int i;
if (is_not_list(BIF_ARG_1) && is_not_nil(BIF_ARG_1))
BIF_ERROR(BIF_P, BADARG);
free_vars = BIF_ARG_1;
if (is_not_atom(BIF_ARG_2))
BIF_ERROR(BIF_P, BADARG);
mod = BIF_ARG_2;
if (is_not_tuple(BIF_ARG_3) ||
(arityval(*tuple_val(BIF_ARG_3)) != 3))
BIF_ERROR(BIF_P, BADARG);
tp = tuple_val(BIF_ARG_3);
if (term_to_Uint(tp[1], &index) == 0)
BIF_ERROR(BIF_P, BADARG);
if (term_to_Uint(tp[2], &uniq) == 0)
BIF_ERROR(BIF_P, BADARG);
if (term_to_Uint(tp[3], &num_free) == 0)
BIF_ERROR(BIF_P, BADARG);
needed = ERL_FUN_SIZE + num_free;
funp = (ErlFunThing *) HAlloc(BIF_P, needed);
hp = funp->env;
funp->thing_word = HEADER_FUN;
/* Need a ErlFunEntry *fe
* fe->refc++;
* funp->fe = fe;
*/
funp->num_free = num_free;
funp->creator = BIF_P->id;
for (i = 0; i < num_free; i++) {
if (is_nil(free_vars))
BIF_ERROR(BIF_P, BADARG);
tmp_ptr = list_val(free_vars);
tmp_var = CAR(tmp_ptr);
free_vars = CDR(tmp_ptr);
*hp++ = tmp_var;
}
if (is_not_nil(free_vars))
BIF_ERROR(BIF_P, BADARG);
#ifndef HYBRID /* FIND ME! */
funp->next = MSO(BIF_P).funs;
MSO(BIF_P).funs = funp;
#endif
BIF_RET(make_fun(funp));
}
#endif
/*
* args: Nativecodeaddress, Module, {Uniq, Index, BeamAddress}
*/
BIF_RETTYPE hipe_bifs_make_fe_3(BIF_ALIST_3)
{
Eterm mod;
Uint index;
Uint uniq;
void *beam_address;
ErlFunEntry *fe;
Eterm *tp;
void *native_address;
native_address = term_to_address(BIF_ARG_1);
if (!native_address)
BIF_ERROR(BIF_P, BADARG);
if (is_not_atom(BIF_ARG_2))
BIF_ERROR(BIF_P, BADARG);
mod = BIF_ARG_2;
if (is_not_tuple(BIF_ARG_3) ||
(arityval(*tuple_val(BIF_ARG_3)) != 3))
BIF_ERROR(BIF_P, BADARG);
tp = tuple_val(BIF_ARG_3);
if (term_to_Uint(tp[1], &uniq) == 0)
BIF_ERROR(BIF_P, BADARG);
if (term_to_Uint(tp[2], &index) == 0)
BIF_ERROR(BIF_P, BADARG);
beam_address = term_to_address(tp[3]);
if (!beam_address)
BIF_ERROR(BIF_P, BADARG);
fe = erts_get_fun_entry(mod, uniq, index);
if (fe == NULL) {
int i = atom_val(mod);
char atom_buf[256];
atom_buf[0] = '\0';
strncat(atom_buf, (char*)atom_tab(i)->name, atom_tab(i)->len);
printf("no fun entry for %s %ld:%ld\n", atom_buf, uniq, index);
BIF_ERROR(BIF_P, BADARG);
}
fe->native_address = native_address;
if (erts_refc_dectest(&fe->refc, 0) == 0)
erts_erase_fun_entry(fe);
BIF_RET(address_to_term((void *)fe, BIF_P));
}
#if 0 /* XXX: unused */
BIF_RETTYPE hipe_bifs_make_native_stub_2(BIF_ALIST_2)
{
void *beamAddress;
Uint beamArity;
void *stubAddress;
if ((beamAddress = term_to_address(BIF_ARG_1)) == 0 ||
is_not_small(BIF_ARG_2) ||
(beamArity = unsigned_val(BIF_ARG_2)) >= 256)
BIF_ERROR(BIF_P, BADARG);
stubAddress = hipe_make_native_stub(beamAddress, beamArity);
BIF_RET(address_to_term(stubAddress, BIF_P));
}
#endif
/*
* MFA info hash table:
* - maps MFA to native code entry point
* - the MFAs it calls (refers_to)
* - the references to it (referred_from)
* - maps MFA to most recent trampoline [if powerpc or arm]
*/
struct hipe_mfa_info {
struct {
unsigned long hvalue;
struct hipe_mfa_info *next;
} bucket;
Eterm m; /* atom */
Eterm f; /* atom */
unsigned int a;
void *remote_address;
void *local_address;
Eterm *beam_code;
Uint orig_beam_op;
struct hipe_mfa_info_list *refers_to;
struct ref *referred_from;
#if defined(__powerpc__) || defined(__ppc__) || defined(__powerpc64__) || defined(__arm__)
void *trampoline;
#endif
};
static struct {
unsigned int log2size;
unsigned int mask; /* INV: mask == (1 << log2size)-1 */
unsigned int used;
struct hipe_mfa_info **bucket;
/*
* The mfa info table is normally updated by the loader,
* which runs in non-concurrent mode. Unfortunately runtime
* apply operations (get_na_nofail) update the table if
* they create a new stub for the mfa, which forces locking.
* XXX: Redesign apply et al to avoid those updates.
*/
erts_smp_mtx_t lock;
} hipe_mfa_info_table;
static inline void hipe_mfa_info_table_init_lock(void)
{
erts_smp_mtx_init(&hipe_mfa_info_table.lock, "hipe_mfait_lock");
}
static inline void hipe_mfa_info_table_lock(void)
{
erts_smp_mtx_lock(&hipe_mfa_info_table.lock);
}
static inline void hipe_mfa_info_table_unlock(void)
{
erts_smp_mtx_unlock(&hipe_mfa_info_table.lock);
}
#define HIPE_MFA_HASH(M,F,A) ((M) * (F) + (A))
static struct hipe_mfa_info **hipe_mfa_info_table_alloc_bucket(unsigned int size)
{
unsigned long nbytes = size * sizeof(struct hipe_mfa_info*);
struct hipe_mfa_info **bucket = erts_alloc(ERTS_ALC_T_HIPE, nbytes);
sys_memzero(bucket, nbytes);
return bucket;
}
static void hipe_mfa_info_table_grow(void)
{
unsigned int old_size, new_size, new_mask;
struct hipe_mfa_info **old_bucket, **new_bucket;
unsigned int i;
old_size = 1 << hipe_mfa_info_table.log2size;
hipe_mfa_info_table.log2size += 1;
new_size = 1 << hipe_mfa_info_table.log2size;
new_mask = new_size - 1;
hipe_mfa_info_table.mask = new_mask;
old_bucket = hipe_mfa_info_table.bucket;
new_bucket = hipe_mfa_info_table_alloc_bucket(new_size);
hipe_mfa_info_table.bucket = new_bucket;
for (i = 0; i < old_size; ++i) {
struct hipe_mfa_info *b = old_bucket[i];
while (b != NULL) {
struct hipe_mfa_info *next = b->bucket.next;
unsigned int j = b->bucket.hvalue & new_mask;
b->bucket.next = new_bucket[j];
new_bucket[j] = b;
b = next;
}
}
erts_free(ERTS_ALC_T_HIPE, old_bucket);
}
static struct hipe_mfa_info *hipe_mfa_info_table_alloc(Eterm m, Eterm f, unsigned int arity)
{
struct hipe_mfa_info *res;
res = (struct hipe_mfa_info*)erts_alloc(ERTS_ALC_T_HIPE, sizeof(*res));
res->m = m;
res->f = f;
res->a = arity;
res->remote_address = NULL;
res->local_address = NULL;
res->beam_code = NULL;
res->orig_beam_op = 0;
res->refers_to = NULL;
res->referred_from = NULL;
#if defined(__powerpc__) || defined(__ppc__) || defined(__powerpc64__) || defined(__arm__)
res->trampoline = NULL;
#endif
return res;
}
void hipe_mfa_info_table_init(void)
{
unsigned int log2size, size;
log2size = 10;
size = 1 << log2size;
hipe_mfa_info_table.log2size = log2size;
hipe_mfa_info_table.mask = size - 1;
hipe_mfa_info_table.used = 0;
hipe_mfa_info_table.bucket = hipe_mfa_info_table_alloc_bucket(size);
hipe_mfa_info_table_init_lock();
}
static inline struct hipe_mfa_info *hipe_mfa_info_table_get_locked(Eterm m, Eterm f, unsigned int arity)
{
unsigned long h;
unsigned int i;
struct hipe_mfa_info *p;
h = HIPE_MFA_HASH(m, f, arity);
i = h & hipe_mfa_info_table.mask;
p = hipe_mfa_info_table.bucket[i];
for (; p; p = p->bucket.next)
/* XXX: do we want to compare p->bucket.hvalue as well? */
if (p->m == m && p->f == f && p->a == arity)
return p;
return NULL;
}
#if 0 /* XXX: unused */
void *hipe_mfa_find_na(Eterm m, Eterm f, unsigned int arity)
{
const struct hipe_mfa_info *p;
p = hipe_mfa_info_table_get(m, f, arity);
return p ? p->address : NULL;
}
#endif
static struct hipe_mfa_info *hipe_mfa_info_table_put_locked(Eterm m, Eterm f, unsigned int arity)
{
unsigned long h;
unsigned int i;
struct hipe_mfa_info *p;
unsigned int size;
h = HIPE_MFA_HASH(m, f, arity);
i = h & hipe_mfa_info_table.mask;
p = hipe_mfa_info_table.bucket[i];
for (; p; p = p->bucket.next)
/* XXX: do we want to compare p->bucket.hvalue as well? */
if (p->m == m && p->f == f && p->a == arity)
return p;
p = hipe_mfa_info_table_alloc(m, f, arity);
p->bucket.hvalue = h;
p->bucket.next = hipe_mfa_info_table.bucket[i];
hipe_mfa_info_table.bucket[i] = p;
hipe_mfa_info_table.used += 1;
size = 1 << hipe_mfa_info_table.log2size;
if (hipe_mfa_info_table.used > (4*size/5)) /* rehash at 80% */
hipe_mfa_info_table_grow();
return p;
}
static void hipe_mfa_set_na(Eterm m, Eterm f, unsigned int arity, void *address, int is_exported)
{
struct hipe_mfa_info *p;
hipe_mfa_info_table_lock();
p = hipe_mfa_info_table_put_locked(m, f, arity);
#ifdef DEBUG_LINKER
printf("%s: ", __FUNCTION__);
print_mfa(m, f, arity);
printf(": changing address from %p to %p\r\n", p->local_address, address);
#endif
p->local_address = address;
if (is_exported)
p->remote_address = address;
hipe_mfa_info_table_unlock();
}
#if defined(__powerpc__) || defined(__ppc__) || defined(__powerpc64__) || defined(__arm__)
void *hipe_mfa_get_trampoline(Eterm m, Eterm f, unsigned int arity)
{
struct hipe_mfa_info *p;
void *trampoline;
hipe_mfa_info_table_lock();
p = hipe_mfa_info_table_put_locked(m, f, arity);
trampoline = p->trampoline;
hipe_mfa_info_table_unlock();
return trampoline;
}
void hipe_mfa_set_trampoline(Eterm m, Eterm f, unsigned int arity, void *trampoline)
{
struct hipe_mfa_info *p;
hipe_mfa_info_table_lock();
p = hipe_mfa_info_table_put_locked(m, f, arity);
p->trampoline = trampoline;
hipe_mfa_info_table_unlock();
}
#endif
BIF_RETTYPE hipe_bifs_set_funinfo_native_address_3(BIF_ALIST_3)
{
struct mfa mfa;
void *address;
int is_exported;
if (!term_to_mfa(BIF_ARG_1, &mfa))
BIF_ERROR(BIF_P, BADARG);
address = term_to_address(BIF_ARG_2);
if (!address)
BIF_ERROR(BIF_P, BADARG);
if (BIF_ARG_3 == am_true)
is_exported = 1;
else if (BIF_ARG_3 == am_false)
is_exported = 0;
else
BIF_ERROR(BIF_P, BADARG);
hipe_mfa_set_na(mfa.mod, mfa.fun, mfa.ari, address, is_exported);
BIF_RET(NIL);
}
BIF_RETTYPE hipe_bifs_invalidate_funinfo_native_addresses_1(BIF_ALIST_1)
{
Eterm lst;
struct mfa mfa;
struct hipe_mfa_info *p;
hipe_mfa_info_table_lock();
lst = BIF_ARG_1;
while (is_list(lst)) {
if (!term_to_mfa(CAR(list_val(lst)), &mfa))
break;
lst = CDR(list_val(lst));
p = hipe_mfa_info_table_get_locked(mfa.mod, mfa.fun, mfa.ari);
if (p) {
p->remote_address = NULL;
p->local_address = NULL;
if (p->beam_code) {
#ifdef DEBUG_LINKER
printf("%s: ", __FUNCTION__);
print_mfa(mfa.mod, mfa.fun, mfa.ari);
printf(": removing call trap from BEAM pc %p (new op %#lx)\r\n",
p->beam_code, p->orig_beam_op);
#endif
p->beam_code[0] = p->orig_beam_op;
p->beam_code = NULL;
p->orig_beam_op = 0;
} else {
#ifdef DEBUG_LINKER
printf("%s: ", __FUNCTION__);
print_mfa(mfa.mod, mfa.fun, mfa.ari);
printf(": no call trap to remove\r\n");
#endif
}
}
}
hipe_mfa_info_table_unlock();
if (is_not_nil(lst))
BIF_ERROR(BIF_P, BADARG);
BIF_RET(NIL);
}
void hipe_mfa_save_orig_beam_op(Eterm mod, Eterm fun, unsigned int ari, Eterm *pc)
{
Uint orig_beam_op;
struct hipe_mfa_info *p;
orig_beam_op = pc[0];
if (orig_beam_op != BeamOpCode(op_hipe_trap_call_closure) &&
orig_beam_op != BeamOpCode(op_hipe_trap_call)) {
hipe_mfa_info_table_lock();
p = hipe_mfa_info_table_put_locked(mod, fun, ari);
#ifdef DEBUG_LINKER
printf("%s: ", __FUNCTION__);
print_mfa(mod, fun, ari);
printf(": saving orig op %#lx from BEAM pc %p\r\n", orig_beam_op, pc);
#endif
p->beam_code = pc;
p->orig_beam_op = orig_beam_op;
hipe_mfa_info_table_unlock();
} else {
#ifdef DEBUG_LINKER
printf("%s: ", __FUNCTION__);
print_mfa(mod, fun, ari);
printf(": orig op %#lx already saved\r\n", orig_beam_op);
#endif
}
}
static void *hipe_make_stub(Eterm m, Eterm f, unsigned int arity, int is_remote)
{
void *BEAMAddress;
void *StubAddress;
#if 0
if (is_not_atom(m) || is_not_atom(f) || arity > 255)
return NULL;
#endif
BEAMAddress = hipe_get_emu_address(m, f, arity, is_remote);
StubAddress = hipe_make_native_stub(BEAMAddress, arity);
#if 0
hipe_mfa_set_na(m, f, arity, StubAddress);
#endif
return StubAddress;
}
static void *hipe_get_na_nofail_locked(Eterm m, Eterm f, unsigned int a, int is_remote)
{
struct hipe_mfa_info *p;
void *address;
p = hipe_mfa_info_table_get_locked(m, f, a);
if (p) {
/* find address, predicting for a runtime apply call */
address = p->remote_address;
if (!is_remote)
address = p->local_address;
if (address)
return address;
/* bummer, install stub, checking if one already existed */
address = p->remote_address;
if (address)
return address;
} else
p = hipe_mfa_info_table_put_locked(m, f, a);
address = hipe_make_stub(m, f, a, is_remote);
/* XXX: how to tell if a BEAM MFA is exported or not? */
p->remote_address = address;
return address;
}
static void *hipe_get_na_nofail(Eterm m, Eterm f, unsigned int a, int is_remote)
{
void *p;
hipe_mfa_info_table_lock();
p = hipe_get_na_nofail_locked(m, f, a, is_remote);
hipe_mfa_info_table_unlock();
return p;
}
/* used for apply/3 in hipe_mode_switch */
void *hipe_get_remote_na(Eterm m, Eterm f, unsigned int a)
{
if (is_not_atom(m) || is_not_atom(f) || a > 255)
return NULL;
return hipe_get_na_nofail(m, f, a, 1);
}
/* primop, but called like a BIF for error handling purposes */
BIF_RETTYPE hipe_find_na_or_make_stub(BIF_ALIST_3)
{
Uint arity;
void *address;
if (is_not_atom(BIF_ARG_1) || is_not_atom(BIF_ARG_2))
BIF_ERROR(BIF_P, BADARG);
arity = unsigned_val(BIF_ARG_3); /* no error check */
address = hipe_get_na_nofail(BIF_ARG_1, BIF_ARG_2, arity, 1);
BIF_RET((Eterm)address); /* semi-Ok */
}
BIF_RETTYPE hipe_bifs_find_na_or_make_stub_2(BIF_ALIST_2)
{
struct mfa mfa;
void *address;
int is_remote;
if (!term_to_mfa(BIF_ARG_1, &mfa))
BIF_ERROR(BIF_P, BADARG);
if (BIF_ARG_2 == am_true)
is_remote = 1;
else if (BIF_ARG_2 == am_false)
is_remote = 0;
else
BIF_ERROR(BIF_P, BADARG);
address = hipe_get_na_nofail(mfa.mod, mfa.fun, mfa.ari, is_remote);
BIF_RET(address_to_term(address, BIF_P));
}
/* primop, but called like a BIF for error handling purposes */
BIF_RETTYPE hipe_nonclosure_address(BIF_ALIST_2)
{
Eterm hdr, m, f;
void *address;
if (!is_boxed(BIF_ARG_1))
goto badfun;
hdr = *boxed_val(BIF_ARG_1);
if (is_export_header(hdr)) {
Export *ep = (Export*)(export_val(BIF_ARG_1)[1]);
unsigned int actual_arity = ep->code[2];
if (actual_arity != BIF_ARG_2)
goto badfun;
m = ep->code[0];
f = ep->code[1];
} else if (hdr == make_arityval(2)) {
Eterm *tp = tuple_val(BIF_ARG_1);
m = tp[1];
f = tp[2];
if (is_not_atom(m) || is_not_atom(f))
goto badfun;
if (!erts_active_export_entry(m, f, BIF_ARG_2))
goto badfun;
} else
goto badfun;
address = hipe_get_na_nofail(m, f, BIF_ARG_2, 1);
BIF_RET((Eterm)address);
badfun:
BIF_P->current = NULL;
BIF_P->fvalue = BIF_ARG_1;
BIF_ERROR(BIF_P, EXC_BADFUN);
}
int hipe_find_mfa_from_ra(const void *ra, Eterm *m, Eterm *f, unsigned int *a)
{
struct hipe_mfa_info *mfa;
long mfa_offset, ra_offset;
struct hipe_mfa_info **bucket;
unsigned int i, nrbuckets;
/* Note about locking: the table is only updated from the
loader, which runs with the rest of the system suspended. */
/* XXX: alas not true; see comment at hipe_mfa_info_table.lock */
hipe_mfa_info_table_lock();
bucket = hipe_mfa_info_table.bucket;
nrbuckets = 1 << hipe_mfa_info_table.log2size;
mfa = NULL;
mfa_offset = LONG_MAX;
for (i = 0; i < nrbuckets; ++i) {
struct hipe_mfa_info *b = bucket[i];
while (b != NULL) {
ra_offset = (char*)ra - (char*)b->local_address;
if (ra_offset > 0 && ra_offset < mfa_offset) {
mfa_offset = ra_offset;
mfa = b;
}
b = b->bucket.next;
}
}
if (mfa) {
*m = mfa->m;
*f = mfa->f;
*a = mfa->a;
}
hipe_mfa_info_table_unlock();
return mfa ? 1 : 0;
}
/*
* Patch Reference Handling.
*/
struct hipe_mfa_info_list {
struct hipe_mfa_info *mfa;
struct hipe_mfa_info_list *next;
};
struct ref {
struct hipe_mfa_info *caller_mfa;
void *address;
void *trampoline;
unsigned int flags;
struct ref *next;
};
#define REF_FLAG_IS_LOAD_MFA 1 /* bit 0: 0 == call, 1 == load_mfa */
#define REF_FLAG_IS_REMOTE 2 /* bit 1: 0 == local, 1 == remote */
#define REF_FLAG_PENDING_REDIRECT 4 /* bit 2: 1 == pending redirect */
#define REF_FLAG_PENDING_REMOVE 8 /* bit 3: 1 == pending remove */
/* add_ref(CalleeMFA, {CallerMFA,Address,'call'|'load_mfa',Trampoline,'remote'|'local'})
*/
BIF_RETTYPE hipe_bifs_add_ref_2(BIF_ALIST_2)
{
struct mfa callee;
Eterm *tuple;
struct mfa caller;
void *address;
void *trampoline;
unsigned int flags;
struct hipe_mfa_info *callee_mfa;
struct hipe_mfa_info *caller_mfa;
struct hipe_mfa_info_list *refers_to;
struct ref *ref;
if (!term_to_mfa(BIF_ARG_1, &callee))
goto badarg;
if (is_not_tuple(BIF_ARG_2))
goto badarg;
tuple = tuple_val(BIF_ARG_2);
if (tuple[0] != make_arityval(5))
goto badarg;
if (!term_to_mfa(tuple[1], &caller))
goto badarg;
address = term_to_address(tuple[2]);
if (!address)
goto badarg;
switch (tuple[3]) {
case am_call:
flags = 0;
break;
case am_load_mfa:
flags = REF_FLAG_IS_LOAD_MFA;
break;
default:
goto badarg;
}
if (is_nil(tuple[4]))
trampoline = NULL;
else {
trampoline = term_to_address(tuple[4]);
if (!trampoline)
goto badarg;
}
switch (tuple[5]) {
case am_local:
break;
case am_remote:
flags |= REF_FLAG_IS_REMOTE;
break;
default:
goto badarg;
}
hipe_mfa_info_table_lock();
callee_mfa = hipe_mfa_info_table_put_locked(callee.mod, callee.fun, callee.ari);
caller_mfa = hipe_mfa_info_table_put_locked(caller.mod, caller.fun, caller.ari);
refers_to = erts_alloc(ERTS_ALC_T_HIPE, sizeof(*refers_to));
refers_to->mfa = callee_mfa;
refers_to->next = caller_mfa->refers_to;
caller_mfa->refers_to = refers_to;
ref = erts_alloc(ERTS_ALC_T_HIPE, sizeof(*ref));
ref->caller_mfa = caller_mfa;
ref->address = address;
ref->trampoline = trampoline;
ref->flags = flags;
ref->next = callee_mfa->referred_from;
callee_mfa->referred_from = ref;
hipe_mfa_info_table_unlock();
BIF_RET(NIL);
badarg:
BIF_ERROR(BIF_P, BADARG);
}
/* Given a CalleeMFA, mark each ref to it as pending-redirect.
* This ensures that remove_refs_from() won't remove them: any
* removal is instead done at the end of redirect_referred_from().
*/
BIF_RETTYPE hipe_bifs_mark_referred_from_1(BIF_ALIST_1) /* get_refs_from */
{
struct mfa mfa;
const struct hipe_mfa_info *p;
struct ref *ref;
if (!term_to_mfa(BIF_ARG_1, &mfa))
BIF_ERROR(BIF_P, BADARG);
hipe_mfa_info_table_lock();
p = hipe_mfa_info_table_get_locked(mfa.mod, mfa.fun, mfa.ari);
if (p)
for (ref = p->referred_from; ref != NULL; ref = ref->next)
ref->flags |= REF_FLAG_PENDING_REDIRECT;
hipe_mfa_info_table_unlock();
BIF_RET(NIL);
}
BIF_RETTYPE hipe_bifs_remove_refs_from_1(BIF_ALIST_1)
{
struct mfa mfa;
struct hipe_mfa_info *caller_mfa, *callee_mfa;
struct hipe_mfa_info_list *refers_to, *tmp_refers_to;
struct ref **prev, *ref;
if (!term_to_mfa(BIF_ARG_1, &mfa))
BIF_ERROR(BIF_P, BADARG);
hipe_mfa_info_table_lock();
caller_mfa = hipe_mfa_info_table_get_locked(mfa.mod, mfa.fun, mfa.ari);
if (caller_mfa) {
refers_to = caller_mfa->refers_to;
while (refers_to) {
callee_mfa = refers_to->mfa;
prev = &callee_mfa->referred_from;
ref = *prev;
while (ref) {
if (ref->caller_mfa == caller_mfa) {
if (ref->flags & REF_FLAG_PENDING_REDIRECT) {
ref->flags |= REF_FLAG_PENDING_REMOVE;
prev = &ref->next;
ref = ref->next;
} else {
struct ref *tmp = ref;
ref = ref->next;
*prev = ref;
erts_free(ERTS_ALC_T_HIPE, tmp);
}
} else {
prev = &ref->next;
ref = ref->next;
}
}
tmp_refers_to = refers_to;
refers_to = refers_to->next;
erts_free(ERTS_ALC_T_HIPE, tmp_refers_to);
}
caller_mfa->refers_to = NULL;
}
hipe_mfa_info_table_unlock();
BIF_RET(NIL);
}
/* redirect_referred_from(CalleeMFA)
* Redirect all pending-redirect refs in CalleeMFA's referred_from.
* Then remove any pending-redirect && pending-remove refs from CalleeMFA's referred_from.
*/
BIF_RETTYPE hipe_bifs_redirect_referred_from_1(BIF_ALIST_1)
{
struct mfa mfa;
struct hipe_mfa_info *p;
struct ref **prev, *ref;
int is_remote, res;
void *new_address;
if (!term_to_mfa(BIF_ARG_1, &mfa))
BIF_ERROR(BIF_P, BADARG);
hipe_mfa_info_table_lock();
p = hipe_mfa_info_table_get_locked(mfa.mod, mfa.fun, mfa.ari);
if (p) {
prev = &p->referred_from;
ref = *prev;
while (ref) {
if (ref->flags & REF_FLAG_PENDING_REDIRECT) {
is_remote = ref->flags & REF_FLAG_IS_REMOTE;
new_address = hipe_get_na_nofail_locked(p->m, p->f, p->a, is_remote);
if (ref->flags & REF_FLAG_IS_LOAD_MFA)
res = hipe_patch_insn(ref->address, (Uint)new_address, am_load_mfa);
else
res = hipe_patch_call(ref->address, new_address, ref->trampoline);
if (res)
fprintf(stderr, "%s: patch failed\r\n", __FUNCTION__);
ref->flags &= ~REF_FLAG_PENDING_REDIRECT;
if (ref->flags & REF_FLAG_PENDING_REMOVE) {
struct ref *tmp = ref;
ref = ref->next;
*prev = ref;
erts_free(ERTS_ALC_T_HIPE, tmp);
} else {
prev = &ref->next;
ref = ref->next;
}
} else {
prev = &ref->next;
ref = ref->next;
}
}
}
hipe_mfa_info_table_unlock();
BIF_RET(NIL);
}
BIF_RETTYPE hipe_bifs_check_crc_1(BIF_ALIST_1)
{
Uint crc;
if (!term_to_Uint(BIF_ARG_1, &crc))
BIF_ERROR(BIF_P, BADARG);
if (crc == HIPE_SYSTEM_CRC)
BIF_RET(am_true);
BIF_RET(am_false);
}
BIF_RETTYPE hipe_bifs_system_crc_1(BIF_ALIST_1)
{
Uint crc;
if (!term_to_Uint(BIF_ARG_1, &crc))
BIF_ERROR(BIF_P, BADARG);
crc ^= (HIPE_SYSTEM_CRC ^ HIPE_LITERALS_CRC);
BIF_RET(Uint_to_term(crc, BIF_P));
}
BIF_RETTYPE hipe_bifs_get_rts_param_1(BIF_ALIST_1)
{
unsigned int is_defined;
unsigned long value;
if (is_not_small(BIF_ARG_1))
BIF_ERROR(BIF_P, BADARG);
is_defined = 1;
value = 0;
switch (unsigned_val(BIF_ARG_1)) {
RTS_PARAMS_CASES
default:
BIF_ERROR(BIF_P, BADARG);
}
if (!is_defined)
BIF_RET(NIL);
BIF_RET(Uint_to_term(value, BIF_P));
}
void hipe_patch_address(Uint *address, Eterm patchtype, Uint value)
{
switch (patchtype) {
case am_load_fe:
hipe_patch_load_fe(address, value);
return;
default:
fprintf(stderr, "%s: unknown patchtype %#lx\r\n",
__FUNCTION__, patchtype);
return;
}
}
struct modinfo {
HashBucket bucket; /* bucket.hvalue == atom_val(the module name) */
unsigned int code_size;
};
static Hash modinfo_table;
static HashValue modinfo_hash(void *tmpl)
{
Eterm mod = (Eterm)tmpl;
return atom_val(mod);
}
static int modinfo_cmp(void *tmpl, void *bucket)
{
/* bucket->hvalue == modinfo_hash(tmpl), so just return 0 (match) */
return 0;
}
static void *modinfo_alloc(void *tmpl)
{
struct modinfo *p;
p = (struct modinfo*)erts_alloc(ERTS_ALC_T_HIPE, sizeof(*p));
p->code_size = 0;
return &p->bucket;
}
static void init_modinfo_table(void)
{
HashFunctions f;
static int init_done = 0;
if (init_done)
return;
init_done = 1;
f.hash = (H_FUN) modinfo_hash;
f.cmp = (HCMP_FUN) modinfo_cmp;
f.alloc = (HALLOC_FUN) modinfo_alloc;
f.free = (HFREE_FUN) NULL;
hash_init(ERTS_ALC_T_HIPE, &modinfo_table, "modinfo_table", 11, f);
}
BIF_RETTYPE hipe_bifs_update_code_size_3(BIF_ALIST_3)
{
struct modinfo *p;
Sint code_size;
init_modinfo_table();
if (is_not_atom(BIF_ARG_1) ||
is_not_small(BIF_ARG_3) ||
(code_size = signed_val(BIF_ARG_3)) < 0)
BIF_ERROR(BIF_P, BADARG);
p = (struct modinfo*)hash_put(&modinfo_table, (void*)BIF_ARG_1);
if (is_nil(BIF_ARG_2)) /* some MFAs, not whole module */
p->code_size += code_size;
else /* whole module */
p->code_size = code_size;
BIF_RET(NIL);
}
BIF_RETTYPE hipe_bifs_code_size_1(BIF_ALIST_1)
{
struct modinfo *p;
unsigned int code_size;
init_modinfo_table();
if (is_not_atom(BIF_ARG_1))
BIF_ERROR(BIF_P, BADARG);
p = (struct modinfo*)hash_get(&modinfo_table, (void*)BIF_ARG_1);
code_size = p ? p->code_size : 0;
BIF_RET(make_small(code_size));
}
BIF_RETTYPE hipe_bifs_patch_insn_3(BIF_ALIST_3)
{
Uint *address, value;
address = term_to_address(BIF_ARG_1);
if (!address)
BIF_ERROR(BIF_P, BADARG);
if (!term_to_Uint(BIF_ARG_2, &value))
BIF_ERROR(BIF_P, BADARG);
if (hipe_patch_insn(address, value, BIF_ARG_3))
BIF_ERROR(BIF_P, BADARG);
BIF_RET(NIL);
}
BIF_RETTYPE hipe_bifs_patch_call_3(BIF_ALIST_3)
{
Uint *callAddress, *destAddress, *trampAddress;
callAddress = term_to_address(BIF_ARG_1);
if (!callAddress)
BIF_ERROR(BIF_P, BADARG);
destAddress = term_to_address(BIF_ARG_2);
if (!destAddress)
BIF_ERROR(BIF_P, BADARG);
if (is_nil(BIF_ARG_3))
trampAddress = NULL;
else {
trampAddress = term_to_address(BIF_ARG_3);
if (!trampAddress)
BIF_ERROR(BIF_P, BADARG);
}
if (hipe_patch_call(callAddress, destAddress, trampAddress))
BIF_ERROR(BIF_P, BADARG);
BIF_RET(NIL);
}