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|
/*
* %CopyrightBegin%
*
* Copyright Ericsson AB 1999-2018. All Rights Reserved.
*
* Licensed under the Apache License, Version 2.0 (the "License");
* you may not use this file except in compliance with the License.
* You may obtain a copy of the License at
*
* http://www.apache.org/licenses/LICENSE-2.0
*
* Unless required by applicable law or agreed to in writing, software
* distributed under the License is distributed on an "AS IS" BASIS,
* WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
* See the License for the specific language governing permissions and
* limitations under the License.
*
* %CopyrightEnd%
*/
/*
* BIFs logically belonging to the lists module.
*/
#ifdef HAVE_CONFIG_H
# include "config.h"
#endif
#include "sys.h"
#include "erl_vm.h"
#include "global.h"
#include "bif.h"
#include "erl_binary.h"
static Eterm keyfind(int Bif, Process* p, Eterm Key, Eterm Pos, Eterm List);
static BIF_RETTYPE append(Process* p, Eterm A, Eterm B)
{
Eterm list;
Eterm copy;
Eterm last;
Eterm* hp = NULL;
Sint i;
list = A;
if (is_nil(list)) {
BIF_RET(B);
}
if (is_not_list(list)) {
BIF_ERROR(p, BADARG);
}
/* optimistic append on heap first */
if ((i = HeapWordsLeft(p) / 2) < 4) {
goto list_tail;
}
hp = HEAP_TOP(p);
copy = last = CONS(hp, CAR(list_val(list)), make_list(hp+2));
list = CDR(list_val(list));
hp += 2;
i -= 2; /* don't use the last 2 words (extra i--;) */
while(i-- && is_list(list)) {
Eterm* listp = list_val(list);
last = CONS(hp, CAR(listp), make_list(hp+2));
list = CDR(listp);
hp += 2;
}
/* A is proper and B is NIL return A as-is, don't update HTOP */
if (is_nil(list) && is_nil(B)) {
BIF_RET(A);
}
if (is_nil(list)) {
HEAP_TOP(p) = hp;
CDR(list_val(last)) = B;
BIF_RET(copy);
}
list_tail:
if ((i = erts_list_length(list)) < 0) {
BIF_ERROR(p, BADARG);
}
/* remaining list was proper and B is NIL */
if (is_nil(B)) {
BIF_RET(A);
}
if (hp) {
/* Note: fall through case, already written
* on the heap.
* The last 2 words of the heap is not written yet
*/
Eterm *hp_save = hp;
ASSERT(i != 0);
HEAP_TOP(p) = hp + 2;
if (i == 1) {
hp[0] = CAR(list_val(list));
hp[1] = B;
BIF_RET(copy);
}
hp = HAlloc(p, 2*(i - 1));
last = CONS(hp_save, CAR(list_val(list)), make_list(hp));
} else {
hp = HAlloc(p, 2*i);
copy = last = CONS(hp, CAR(list_val(list)), make_list(hp+2));
hp += 2;
}
list = CDR(list_val(list));
i--;
ASSERT(i > -1);
while(i--) {
Eterm* listp = list_val(list);
last = CONS(hp, CAR(listp), make_list(hp+2));
list = CDR(listp);
hp += 2;
}
CDR(list_val(last)) = B;
BIF_RET(copy);
}
/*
* erlang:'++'/2
*/
Eterm
ebif_plusplus_2(BIF_ALIST_2)
{
return append(BIF_P, BIF_ARG_1, BIF_ARG_2);
}
BIF_RETTYPE append_2(BIF_ALIST_2)
{
return append(BIF_P, BIF_ARG_1, BIF_ARG_2);
}
/* erlang:'--'/2
*
* Subtracts a list from another (LHS -- RHS), removing the first occurrence of
* each element in LHS from RHS. There is no type coercion so the elements must
* match exactly.
*
* The BIF is broken into several stages that can all trap individually, and it
* chooses its algorithm based on input size. If either input is small it will
* use a linear scan tuned to which side it's on, and if both inputs are large
* enough it will convert RHS into a multiset to provide good asymptotic
* behavior. */
#define SUBTRACT_LHS_THRESHOLD 16
#define SUBTRACT_RHS_THRESHOLD 16
typedef enum {
SUBTRACT_STAGE_START,
SUBTRACT_STAGE_LEN_LHS,
/* Naive linear scan that's efficient when
* LEN_LHS <= SUBTRACT_LHS_THRESHOLD. */
SUBTRACT_STAGE_NAIVE_LHS,
SUBTRACT_STAGE_LEN_RHS,
/* As SUBTRACT_STAGE_NAIVE_LHS but for RHS. */
SUBTRACT_STAGE_NAIVE_RHS,
/* Creates a multiset from RHS for faster lookups before sweeping through
* LHS. The set is implemented as a red-black tree and duplicate elements
* are handled by a counter on each node. */
SUBTRACT_STAGE_SET_BUILD,
SUBTRACT_STAGE_SET_FINISH
} ErtsSubtractCtxStage;
typedef struct subtract_node__ {
struct subtract_node__ *parent;
struct subtract_node__ *left;
struct subtract_node__ *right;
int is_red;
Eterm key;
Uint count;
} subtract_tree_t;
typedef struct {
ErtsSubtractCtxStage stage;
Eterm lhs_original;
Eterm rhs_original;
Uint lhs_remaining;
Uint rhs_remaining;
Eterm iterator;
Eterm *result_cdr;
Eterm result;
union {
Eterm lhs_elements[SUBTRACT_LHS_THRESHOLD];
Eterm rhs_elements[SUBTRACT_RHS_THRESHOLD];
struct {
subtract_tree_t *tree;
/* A memory area for the tree's nodes, saving us the need to have
* one allocation per node. */
subtract_tree_t *alloc_start;
subtract_tree_t *alloc;
} rhs_set;
} u;
} ErtsSubtractContext;
#define ERTS_RBT_PREFIX subtract
#define ERTS_RBT_T subtract_tree_t
#define ERTS_RBT_KEY_T Eterm
#define ERTS_RBT_FLAGS_T int
#define ERTS_RBT_INIT_EMPTY_TNODE(T) \
do { \
(T)->parent = NULL; \
(T)->left = NULL; \
(T)->right = NULL; \
} while(0)
#define ERTS_RBT_IS_RED(T) ((T)->is_red)
#define ERTS_RBT_SET_RED(T) ((T)->is_red = 1)
#define ERTS_RBT_IS_BLACK(T) (!ERTS_RBT_IS_RED(T))
#define ERTS_RBT_SET_BLACK(T) ((T)->is_red = 0)
#define ERTS_RBT_GET_FLAGS(T) ((T)->is_red)
#define ERTS_RBT_SET_FLAGS(T, F) ((T)->is_red = F)
#define ERTS_RBT_GET_PARENT(T) ((T)->parent)
#define ERTS_RBT_SET_PARENT(T, P) ((T)->parent = P)
#define ERTS_RBT_GET_RIGHT(T) ((T)->right)
#define ERTS_RBT_SET_RIGHT(T, R) ((T)->right = (R))
#define ERTS_RBT_GET_LEFT(T) ((T)->left)
#define ERTS_RBT_SET_LEFT(T, L) ((T)->left = (L))
#define ERTS_RBT_GET_KEY(T) ((T)->key)
#define ERTS_RBT_CMP_KEYS(KX, KY) CMP_TERM(KX, KY)
#define ERTS_RBT_WANT_LOOKUP_INSERT
#define ERTS_RBT_WANT_LOOKUP
#define ERTS_RBT_WANT_DELETE
#define ERTS_RBT_UNDEF
#include "erl_rbtree.h"
static int subtract_continue(Process *p, ErtsSubtractContext *context);
static void subtract_ctx_dtor(ErtsSubtractContext *context) {
switch (context->stage) {
case SUBTRACT_STAGE_SET_BUILD:
case SUBTRACT_STAGE_SET_FINISH:
erts_free(ERTS_ALC_T_LIST_TRAP, context->u.rhs_set.alloc_start);
break;
default:
break;
}
}
static int subtract_ctx_bin_dtor(Binary *context_bin) {
ErtsSubtractContext *context = ERTS_MAGIC_BIN_DATA(context_bin);
subtract_ctx_dtor(context);
return 1;
}
static void subtract_ctx_move(ErtsSubtractContext *from,
ErtsSubtractContext *to) {
int uses_result_cdr = 0;
to->stage = from->stage;
to->lhs_original = from->lhs_original;
to->rhs_original = from->rhs_original;
to->lhs_remaining = from->lhs_remaining;
to->rhs_remaining = from->rhs_remaining;
to->iterator = from->iterator;
to->result = from->result;
switch (to->stage) {
case SUBTRACT_STAGE_NAIVE_LHS:
sys_memcpy(to->u.lhs_elements,
from->u.lhs_elements,
sizeof(Eterm) * to->lhs_remaining);
break;
case SUBTRACT_STAGE_NAIVE_RHS:
sys_memcpy(to->u.rhs_elements,
from->u.rhs_elements,
sizeof(Eterm) * to->rhs_remaining);
uses_result_cdr = 1;
break;
case SUBTRACT_STAGE_SET_FINISH:
uses_result_cdr = 1;
/* FALL THROUGH */
case SUBTRACT_STAGE_SET_BUILD:
to->u.rhs_set.alloc_start = from->u.rhs_set.alloc_start;
to->u.rhs_set.alloc = from->u.rhs_set.alloc;
to->u.rhs_set.tree = from->u.rhs_set.tree;
break;
default:
break;
}
if (uses_result_cdr) {
if (from->result_cdr == &from->result) {
to->result_cdr = &to->result;
} else {
to->result_cdr = from->result_cdr;
}
}
}
static Eterm subtract_create_trap_state(Process *p,
ErtsSubtractContext *context) {
Binary *state_bin;
Eterm *hp;
state_bin = erts_create_magic_binary(sizeof(ErtsSubtractContext),
subtract_ctx_bin_dtor);
subtract_ctx_move(context, ERTS_MAGIC_BIN_DATA(state_bin));
hp = HAlloc(p, ERTS_MAGIC_REF_THING_SIZE);
return erts_mk_magic_ref(&hp, &MSO(p), state_bin);
}
static int subtract_enter_len_lhs(Process *p, ErtsSubtractContext *context) {
context->stage = SUBTRACT_STAGE_LEN_LHS;
context->iterator = context->lhs_original;
context->lhs_remaining = 0;
return subtract_continue(p, context);
}
static int subtract_enter_len_rhs(Process *p, ErtsSubtractContext *context) {
context->stage = SUBTRACT_STAGE_LEN_RHS;
context->iterator = context->rhs_original;
context->rhs_remaining = 0;
return subtract_continue(p, context);
}
static int subtract_get_length(Process *p, Eterm *iterator_p, Uint *count_p) {
static const Sint ELEMENTS_PER_RED = 32;
Sint budget, count;
Eterm iterator;
budget = ELEMENTS_PER_RED * ERTS_BIF_REDS_LEFT(p);
iterator = *iterator_p;
#ifdef DEBUG
budget = budget / 10 + 1;
#endif
for (count = 0; count < budget && is_list(iterator); count++) {
iterator = CDR(list_val(iterator));
}
if (!is_list(iterator) && !is_nil(iterator)) {
return -1;
}
BUMP_REDS(p, count / ELEMENTS_PER_RED);
*iterator_p = iterator;
*count_p += count;
if (is_nil(iterator)) {
return 1;
}
return 0;
}
static int subtract_enter_naive_lhs(Process *p, ErtsSubtractContext *context) {
Eterm iterator;
int i = 0;
context->stage = SUBTRACT_STAGE_NAIVE_LHS;
context->iterator = context->rhs_original;
context->result = NIL;
iterator = context->lhs_original;
while (is_list(iterator)) {
const Eterm *cell = list_val(iterator);
ASSERT(i < SUBTRACT_LHS_THRESHOLD);
context->u.lhs_elements[i++] = CAR(cell);
iterator = CDR(cell);
}
ASSERT(i == context->lhs_remaining);
return subtract_continue(p, context);
}
static int subtract_naive_lhs(Process *p, ErtsSubtractContext *context) {
const Sint CHECKS_PER_RED = 16;
Sint checks, budget;
budget = CHECKS_PER_RED * ERTS_BIF_REDS_LEFT(p);
checks = 0;
while (checks < budget && is_list(context->iterator)) {
const Eterm *cell;
Eterm value, next;
int found_at;
cell = list_val(context->iterator);
value = CAR(cell);
next = CDR(cell);
for (found_at = 0; found_at < context->lhs_remaining; found_at++) {
if (EQ(value, context->u.lhs_elements[found_at])) {
/* We shift the array one step down as we have to preserve
* order.
*
* Note that we can't exit early as that would suppress errors
* in the right-hand side (this runs prior to determining the
* length of RHS). */
context->lhs_remaining--;
sys_memmove(&context->u.lhs_elements[found_at],
&context->u.lhs_elements[found_at + 1],
(context->lhs_remaining - found_at) * sizeof(Eterm));
break;
}
}
checks += MAX(1, context->lhs_remaining);
context->iterator = next;
}
BUMP_REDS(p, MIN(checks, budget) / CHECKS_PER_RED);
if (is_list(context->iterator)) {
return 0;
} else if (!is_nil(context->iterator)) {
return -1;
}
if (context->lhs_remaining > 0) {
Eterm *hp;
int i;
hp = HAlloc(p, context->lhs_remaining * 2);
for (i = context->lhs_remaining - 1; i >= 0; i--) {
Eterm value = context->u.lhs_elements[i];
context->result = CONS(hp, value, context->result);
hp += 2;
}
}
ASSERT(context->lhs_remaining > 0 || context->result == NIL);
return 1;
}
static int subtract_enter_naive_rhs(Process *p, ErtsSubtractContext *context) {
Eterm iterator;
int i = 0;
context->stage = SUBTRACT_STAGE_NAIVE_RHS;
context->iterator = context->lhs_original;
context->result_cdr = &context->result;
context->result = NIL;
iterator = context->rhs_original;
while (is_list(iterator)) {
const Eterm *cell = list_val(iterator);
ASSERT(i < SUBTRACT_RHS_THRESHOLD);
context->u.rhs_elements[i++] = CAR(cell);
iterator = CDR(cell);
}
ASSERT(i == context->rhs_remaining);
return subtract_continue(p, context);
}
static int subtract_naive_rhs(Process *p, ErtsSubtractContext *context) {
const Sint CHECKS_PER_RED = 16;
Sint checks, budget;
budget = CHECKS_PER_RED * ERTS_BIF_REDS_LEFT(p);
checks = 0;
#ifdef DEBUG
budget = budget / 10 + 1;
#endif
while (checks < budget && is_list(context->iterator)) {
const Eterm *cell;
Eterm value, next;
int found_at;
cell = list_val(context->iterator);
value = CAR(cell);
next = CDR(cell);
for (found_at = context->rhs_remaining - 1; found_at >= 0; found_at--) {
if (EQ(value, context->u.rhs_elements[found_at])) {
break;
}
}
if (found_at < 0) {
/* Destructively add the value to the result. This is safe
* since the GC is disabled and the unfinished term is never
* leaked to the outside world. */
Eterm *hp = HAllocX(p, 2, context->lhs_remaining * 2);
*context->result_cdr = make_list(hp);
context->result_cdr = &CDR(hp);
CAR(hp) = value;
} else if (found_at >= 0) {
Eterm swap;
if (context->rhs_remaining-- == 1) {
/* We've run out of items to remove, so the rest of the
* result will be equal to the remainder of the input. We know
* that LHS is well-formed as any errors would've been reported
* during length determination. */
*context->result_cdr = next;
BUMP_REDS(p, MIN(budget, checks) / CHECKS_PER_RED);
return 1;
}
swap = context->u.rhs_elements[context->rhs_remaining];
context->u.rhs_elements[found_at] = swap;
}
checks += context->rhs_remaining;
context->iterator = next;
context->lhs_remaining--;
}
/* The result only has to be terminated when returning it to the user, but
* we're doing it when trapping as well to prevent headaches when
* debugging. */
*context->result_cdr = NIL;
BUMP_REDS(p, MIN(budget, checks) / CHECKS_PER_RED);
if (is_list(context->iterator)) {
ASSERT(context->lhs_remaining > 0 && context->rhs_remaining > 0);
return 0;
}
return 1;
}
static int subtract_enter_set_build(Process *p, ErtsSubtractContext *context) {
context->stage = SUBTRACT_STAGE_SET_BUILD;
context->u.rhs_set.alloc_start =
erts_alloc(ERTS_ALC_T_LIST_TRAP,
context->rhs_remaining * sizeof(subtract_tree_t));
context->u.rhs_set.alloc = context->u.rhs_set.alloc_start;
context->u.rhs_set.tree = NULL;
context->iterator = context->rhs_original;
return subtract_continue(p, context);
}
static int subtract_set_build(Process *p, ErtsSubtractContext *context) {
const static Sint INSERTIONS_PER_RED = 16;
Sint budget, insertions;
budget = INSERTIONS_PER_RED * ERTS_BIF_REDS_LEFT(p);
insertions = 0;
#ifdef DEBUG
budget = budget / 10 + 1;
#endif
while (insertions < budget && is_list(context->iterator)) {
subtract_tree_t *existing_node, *new_node;
const Eterm *cell;
Eterm value, next;
cell = list_val(context->iterator);
value = CAR(cell);
next = CDR(cell);
new_node = context->u.rhs_set.alloc;
new_node->key = value;
new_node->count = 1;
existing_node = subtract_rbt_lookup_insert(&context->u.rhs_set.tree,
new_node);
if (existing_node != NULL) {
existing_node->count++;
} else {
context->u.rhs_set.alloc++;
}
context->iterator = next;
insertions++;
}
BUMP_REDS(p, insertions / INSERTIONS_PER_RED);
ASSERT(is_list(context->iterator) || is_nil(context->iterator));
ASSERT(context->u.rhs_set.tree != NULL);
return is_nil(context->iterator);
}
static int subtract_enter_set_finish(Process *p, ErtsSubtractContext *context) {
context->stage = SUBTRACT_STAGE_SET_FINISH;
context->result_cdr = &context->result;
context->result = NIL;
context->iterator = context->lhs_original;
return subtract_continue(p, context);
}
static int subtract_set_finish(Process *p, ErtsSubtractContext *context) {
const Sint CHECKS_PER_RED = 8;
Sint checks, budget;
budget = CHECKS_PER_RED * ERTS_BIF_REDS_LEFT(p);
checks = 0;
#ifdef DEBUG
budget = budget / 10 + 1;
#endif
while (checks < budget && is_list(context->iterator)) {
subtract_tree_t *node;
const Eterm *cell;
Eterm value, next;
cell = list_val(context->iterator);
value = CAR(cell);
next = CDR(cell);
ASSERT(context->rhs_remaining > 0);
node = subtract_rbt_lookup(context->u.rhs_set.tree, value);
if (node == NULL) {
Eterm *hp = HAllocX(p, 2, context->lhs_remaining * 2);
*context->result_cdr = make_list(hp);
context->result_cdr = &CDR(hp);
CAR(hp) = value;
} else {
if (context->rhs_remaining-- == 1) {
*context->result_cdr = next;
BUMP_REDS(p, checks / CHECKS_PER_RED);
return 1;
}
if (node->count-- == 1) {
subtract_rbt_delete(&context->u.rhs_set.tree, node);
}
}
context->iterator = next;
context->lhs_remaining--;
checks++;
}
*context->result_cdr = NIL;
BUMP_REDS(p, checks / CHECKS_PER_RED);
if (is_list(context->iterator)) {
ASSERT(context->lhs_remaining > 0 && context->rhs_remaining > 0);
return 0;
}
return 1;
}
static int subtract_continue(Process *p, ErtsSubtractContext *context) {
switch (context->stage) {
case SUBTRACT_STAGE_START: {
return subtract_enter_len_lhs(p, context);
}
case SUBTRACT_STAGE_LEN_LHS: {
int res = subtract_get_length(p,
&context->iterator,
&context->lhs_remaining);
if (res != 1) {
return res;
}
if (context->lhs_remaining <= SUBTRACT_LHS_THRESHOLD) {
return subtract_enter_naive_lhs(p, context);
}
return subtract_enter_len_rhs(p, context);
}
case SUBTRACT_STAGE_NAIVE_LHS: {
return subtract_naive_lhs(p, context);
}
case SUBTRACT_STAGE_LEN_RHS: {
int res = subtract_get_length(p,
&context->iterator,
&context->rhs_remaining);
if (res != 1) {
return res;
}
/* We've walked through both lists fully now so we no longer need
* to check for errors past this point. */
if (context->rhs_remaining <= SUBTRACT_RHS_THRESHOLD) {
return subtract_enter_naive_rhs(p, context);
}
return subtract_enter_set_build(p, context);
}
case SUBTRACT_STAGE_NAIVE_RHS: {
return subtract_naive_rhs(p, context);
}
case SUBTRACT_STAGE_SET_BUILD: {
int res = subtract_set_build(p, context);
if (res != 1) {
return res;
}
return subtract_enter_set_finish(p, context);
}
case SUBTRACT_STAGE_SET_FINISH: {
return subtract_set_finish(p, context);
}
default:
ERTS_ASSERT(!"unreachable");
}
}
static int subtract_start(Process *p, Eterm lhs, Eterm rhs,
ErtsSubtractContext *context) {
context->stage = SUBTRACT_STAGE_START;
context->lhs_original = lhs;
context->rhs_original = rhs;
return subtract_continue(p, context);
}
/* erlang:'--'/2 */
static Eterm subtract(Export *bif_entry, BIF_ALIST_2) {
Eterm lhs = BIF_ARG_1, rhs = BIF_ARG_2;
if ((is_list(lhs) || is_nil(lhs)) && (is_list(rhs) || is_nil(rhs))) {
/* We start with the context on the stack in the hopes that we won't
* have to trap. */
ErtsSubtractContext context;
int res;
res = subtract_start(BIF_P, lhs, rhs, &context);
if (res == 0) {
Eterm state_mref;
state_mref = subtract_create_trap_state(BIF_P, &context);
erts_set_gc_state(BIF_P, 0);
BIF_TRAP2(bif_entry, BIF_P, state_mref, NIL);
}
subtract_ctx_dtor(&context);
if (res < 0) {
BIF_ERROR(BIF_P, BADARG);
}
BIF_RET(context.result);
} else if (is_internal_magic_ref(lhs)) {
ErtsSubtractContext *context;
int (*dtor)(Binary*);
Binary *magic_bin;
int res;
magic_bin = erts_magic_ref2bin(lhs);
dtor = ERTS_MAGIC_BIN_DESTRUCTOR(magic_bin);
if (dtor != subtract_ctx_bin_dtor) {
BIF_ERROR(BIF_P, BADARG);
}
ASSERT(BIF_P->flags & F_DISABLE_GC);
ASSERT(rhs == NIL);
context = ERTS_MAGIC_BIN_DATA(magic_bin);
res = subtract_continue(BIF_P, context);
if (res == 0) {
BIF_TRAP2(bif_entry, BIF_P, lhs, NIL);
}
erts_set_gc_state(BIF_P, 1);
if (res < 0) {
ERTS_BIF_ERROR_TRAPPED2(BIF_P, BADARG, bif_entry,
context->lhs_original,
context->rhs_original);
}
BIF_RET(context->result);
}
ASSERT(!(BIF_P->flags & F_DISABLE_GC));
BIF_ERROR(BIF_P, BADARG);
}
BIF_RETTYPE ebif_minusminus_2(BIF_ALIST_2) {
return subtract(bif_export[BIF_ebif_minusminus_2], BIF_CALL_ARGS);
}
BIF_RETTYPE subtract_2(BIF_ALIST_2) {
return subtract(bif_export[BIF_subtract_2], BIF_CALL_ARGS);
}
BIF_RETTYPE lists_member_2(BIF_ALIST_2)
{
Eterm term;
Eterm list;
Eterm item;
int non_immed_key;
int reds_left = ERTS_BIF_REDS_LEFT(BIF_P);
int max_iter = 16 * reds_left;
if (is_nil(BIF_ARG_2)) {
BIF_RET(am_false);
} else if (is_not_list(BIF_ARG_2)) {
BIF_ERROR(BIF_P, BADARG);
}
term = BIF_ARG_1;
non_immed_key = is_not_immed(term);
list = BIF_ARG_2;
while (is_list(list)) {
if (--max_iter < 0) {
BUMP_ALL_REDS(BIF_P);
BIF_TRAP2(bif_export[BIF_lists_member_2], BIF_P, term, list);
}
item = CAR(list_val(list));
if ((item == term) || (non_immed_key && eq(item, term))) {
BIF_RET2(am_true, reds_left - max_iter/16);
}
list = CDR(list_val(list));
}
if (is_not_nil(list)) {
BUMP_REDS(BIF_P, reds_left - max_iter/16);
BIF_ERROR(BIF_P, BADARG);
}
BIF_RET2(am_false, reds_left - max_iter/16);
}
static BIF_RETTYPE lists_reverse_alloc(Process *c_p,
Eterm list_in,
Eterm tail_in)
{
static const Uint CELLS_PER_RED = 40;
Eterm *alloc_top, *alloc_end;
Uint cells_left, max_cells;
Eterm list, tail;
Eterm lookahead;
list = list_in;
tail = tail_in;
cells_left = max_cells = CELLS_PER_RED * (1 + ERTS_BIF_REDS_LEFT(c_p));
lookahead = list;
while (cells_left != 0 && is_list(lookahead)) {
lookahead = CDR(list_val(lookahead));
cells_left--;
}
BUMP_REDS(c_p, (max_cells - cells_left) / CELLS_PER_RED);
if (is_not_list(lookahead) && is_not_nil(lookahead)) {
BIF_ERROR(c_p, BADARG);
}
alloc_top = HAlloc(c_p, 2 * (max_cells - cells_left));
alloc_end = alloc_top + 2 * (max_cells - cells_left);
while (alloc_top < alloc_end) {
Eterm *pair = list_val(list);
tail = CONS(alloc_top, CAR(pair), tail);
list = CDR(pair);
ASSERT(is_list(list) || is_nil(list));
alloc_top += 2;
}
if (is_nil(list)) {
BIF_RET(tail);
}
ASSERT(is_list(tail) && cells_left == 0);
BIF_TRAP2(bif_export[BIF_lists_reverse_2], c_p, list, tail);
}
static BIF_RETTYPE lists_reverse_onheap(Process *c_p,
Eterm list_in,
Eterm tail_in)
{
static const Uint CELLS_PER_RED = 60;
Eterm *alloc_start, *alloc_top, *alloc_end;
Uint cells_left, max_cells;
Eterm list, tail;
list = list_in;
tail = tail_in;
cells_left = max_cells = CELLS_PER_RED * (1 + ERTS_BIF_REDS_LEFT(c_p));
ASSERT(HEAP_LIMIT(c_p) >= HEAP_TOP(c_p) + 2);
alloc_start = HEAP_TOP(c_p);
alloc_end = HEAP_LIMIT(c_p) - 2;
alloc_top = alloc_start;
/* Don't process more cells than we have reductions for. */
alloc_end = MIN(alloc_top + (cells_left * 2), alloc_end);
while (alloc_top < alloc_end && is_list(list)) {
Eterm *pair = list_val(list);
tail = CONS(alloc_top, CAR(pair), tail);
list = CDR(pair);
alloc_top += 2;
}
cells_left -= (alloc_top - alloc_start) / 2;
HEAP_TOP(c_p) = alloc_top;
ASSERT(cells_left >= 0 && cells_left <= max_cells);
BUMP_REDS(c_p, (max_cells - cells_left) / CELLS_PER_RED);
if (is_nil(list)) {
BIF_RET(tail);
} else if (is_list(list)) {
ASSERT(is_list(tail));
if (cells_left > CELLS_PER_RED) {
return lists_reverse_alloc(c_p, list, tail);
}
BUMP_ALL_REDS(c_p);
BIF_TRAP2(bif_export[BIF_lists_reverse_2], c_p, list, tail);
}
BIF_ERROR(c_p, BADARG);
}
BIF_RETTYPE lists_reverse_2(BIF_ALIST_2)
{
/* Handle legal and illegal non-lists quickly. */
if (is_nil(BIF_ARG_1)) {
BIF_RET(BIF_ARG_2);
} else if (is_not_list(BIF_ARG_1)) {
BIF_ERROR(BIF_P, BADARG);
}
/* We build the reversal on the unused part of the heap if possible to save
* us the trouble of having to figure out the list size. We fall back to
* lists_reverse_alloc when we run out of space. */
if (HeapWordsLeft(BIF_P) > 8) {
return lists_reverse_onheap(BIF_P, BIF_ARG_1, BIF_ARG_2);
}
return lists_reverse_alloc(BIF_P, BIF_ARG_1, BIF_ARG_2);
}
BIF_RETTYPE
lists_keymember_3(BIF_ALIST_3)
{
Eterm res;
res = keyfind(BIF_lists_keymember_3, BIF_P,
BIF_ARG_1, BIF_ARG_2, BIF_ARG_3);
if (is_value(res) && is_tuple(res)) {
return am_true;
} else {
return res;
}
}
BIF_RETTYPE
lists_keysearch_3(BIF_ALIST_3)
{
Eterm res;
res = keyfind(BIF_lists_keysearch_3, BIF_P,
BIF_ARG_1, BIF_ARG_2, BIF_ARG_3);
if (is_non_value(res) || is_not_tuple(res)) {
return res;
} else { /* Tuple */
Eterm* hp = HAlloc(BIF_P, 3);
return TUPLE2(hp, am_value, res);
}
}
BIF_RETTYPE
lists_keyfind_3(BIF_ALIST_3)
{
return keyfind(BIF_lists_keyfind_3, BIF_P,
BIF_ARG_1, BIF_ARG_2, BIF_ARG_3);
}
static Eterm
keyfind(int Bif, Process* p, Eterm Key, Eterm Pos, Eterm List)
{
int max_iter = 10 * CONTEXT_REDS;
Sint pos;
Eterm term;
if (!is_small(Pos) || (pos = signed_val(Pos)) < 1) {
BIF_ERROR(p, BADARG);
}
if (is_small(Key)) {
double float_key = (double) signed_val(Key);
while (is_list(List)) {
if (--max_iter < 0) {
BUMP_ALL_REDS(p);
BIF_TRAP3(bif_export[Bif], p, Key, Pos, List);
}
term = CAR(list_val(List));
List = CDR(list_val(List));
if (is_tuple(term)) {
Eterm *tuple_ptr = tuple_val(term);
if (pos <= arityval(*tuple_ptr)) {
Eterm element = tuple_ptr[pos];
if (Key == element) {
return term;
} else if (is_float(element)) {
FloatDef f;
GET_DOUBLE(element, f);
if (f.fd == float_key) {
return term;
}
}
}
}
}
} else if (is_immed(Key)) {
while (is_list(List)) {
if (--max_iter < 0) {
BUMP_ALL_REDS(p);
BIF_TRAP3(bif_export[Bif], p, Key, Pos, List);
}
term = CAR(list_val(List));
List = CDR(list_val(List));
if (is_tuple(term)) {
Eterm *tuple_ptr = tuple_val(term);
if (pos <= arityval(*tuple_ptr)) {
Eterm element = tuple_ptr[pos];
if (Key == element) {
return term;
}
}
}
}
} else {
while (is_list(List)) {
if (--max_iter < 0) {
BUMP_ALL_REDS(p);
BIF_TRAP3(bif_export[Bif], p, Key, Pos, List);
}
term = CAR(list_val(List));
List = CDR(list_val(List));
if (is_tuple(term)) {
Eterm *tuple_ptr = tuple_val(term);
if (pos <= arityval(*tuple_ptr)) {
Eterm element = tuple_ptr[pos];
if (CMP_EQ(Key, element)) {
return term;
}
}
}
}
}
if (is_not_nil(List)) {
BIF_ERROR(p, BADARG);
}
return am_false;
}
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