/*
* Removes values before an index and shifts old values down
* without fragmenting memory by reallocating memory.
*/
static VALUE remove_before_bang (VALUE self, VALUE index)
{
int int_index = FIX2INT(index);
long new_length = 0;
if (int_index < 0)
{
int_index += RARRAY_LEN(self);
if (int_index < 0)
{
return self;
}
}
if (RARRAY_LEN(self) > int_index)
{
MEMMOVE(RARRAY_PTR(self), RARRAY_PTR(self) + int_index, VALUE, RARRAY_LEN(self) - int_index);
new_length = RARRAY_LEN(self) - int_index;
ARY_SET_LEN(self, new_length);
}
else
{
ARY_SET_LEN(self, 0);
}
return self;
}
MRB_API mrb_value
mrb_ary_shift(mrb_state *mrb, mrb_value self)
{
struct RArray *a = mrb_ary_ptr(self);
mrb_int len = ARY_LEN(a);
mrb_value val;
ary_modify_check(mrb, a);
if (len == 0) return mrb_nil_value();
if (ARY_SHARED_P(a)) {
L_SHIFT:
val = a->as.heap.ptr[0];
a->as.heap.ptr++;
a->as.heap.len--;
return val;
}
if (len > ARY_SHIFT_SHARED_MIN) {
ary_make_shared(mrb, a);
goto L_SHIFT;
}
else {
mrb_value *ptr = ARY_PTR(a);
mrb_int size = len;
val = *ptr;
while (--size) {
*ptr = *(ptr+1);
++ptr;
}
ARY_SET_LEN(a, len-1);
}
return val;
}
/* self = [1,2,3]
item = 0
self.unshift item
p self #=> [0, 1, 2, 3] */
MRB_API mrb_value
mrb_ary_unshift(mrb_state *mrb, mrb_value self, mrb_value item)
{
struct RArray *a = mrb_ary_ptr(self);
mrb_int len = ARY_LEN(a);
if (ARY_SHARED_P(a)
&& a->as.heap.aux.shared->refcnt == 1 /* shared only referenced from this array */
&& a->as.heap.ptr - a->as.heap.aux.shared->ptr >= 1) /* there's room for unshifted item */ {
a->as.heap.ptr--;
a->as.heap.ptr[0] = item;
}
else {
mrb_value *ptr;
ary_modify(mrb, a);
if (ARY_CAPA(a) < len + 1)
ary_expand_capa(mrb, a, len + 1);
ptr = ARY_PTR(a);
value_move(ptr + 1, ptr, len);
ptr[0] = item;
}
ARY_SET_LEN(a, len+1);
mrb_field_write_barrier_value(mrb, (struct RBasic*)a, item);
return self;
}
static mrb_value
mrb_ary_times(mrb_state *mrb, mrb_value self)
{
struct RArray *a1 = mrb_ary_ptr(self);
struct RArray *a2;
mrb_value *ptr;
mrb_int times, len1;
mrb_get_args(mrb, "i", ×);
if (times < 0) {
mrb_raise(mrb, E_ARGUMENT_ERROR, "negative argument");
}
if (times == 0) return mrb_ary_new(mrb);
if (ARY_MAX_SIZE / times < ARY_LEN(a1)) {
mrb_raise(mrb, E_ARGUMENT_ERROR, "array size too big");
}
len1 = ARY_LEN(a1);
a2 = ary_new_capa(mrb, len1 * times);
ARY_SET_LEN(a2, len1 * times);
ptr = ARY_PTR(a2);
while (times--) {
array_copy(ptr, ARY_PTR(a1), len1);
ptr += len1;
}
return mrb_obj_value(a2);
}
static mrb_value
mrb_ary_unshift_m(mrb_state *mrb, mrb_value self)
{
struct RArray *a = mrb_ary_ptr(self);
mrb_value *vals, *ptr;
mrb_int alen, len;
mrb_get_args(mrb, "*!", &vals, &alen);
len = ARY_LEN(a);
if (alen > ARY_MAX_SIZE - len) {
mrb_raise(mrb, E_ARGUMENT_ERROR, "array size too big");
}
if (ARY_SHARED_P(a)
&& a->as.heap.aux.shared->refcnt == 1 /* shared only referenced from this array */
&& a->as.heap.ptr - a->as.heap.aux.shared->ptr >= alen) /* there's room for unshifted item */ {
ary_modify_check(mrb, a);
a->as.heap.ptr -= len;
ptr = a->as.heap.ptr;
}
else {
ary_modify(mrb, a);
if (alen == 0) return self;
if (ARY_CAPA(a) < len + alen)
ary_expand_capa(mrb, a, len + alen);
ptr = ARY_PTR(a);
value_move(ptr + alen, ptr, len);
}
array_copy(ptr, vals, alen);
ARY_SET_LEN(a, len+alen);
while (alen--) {
mrb_field_write_barrier_value(mrb, (struct RBasic*)a, vals[alen]);
}
return self;
}
static mrb_value
mrb_ary_delete_at(mrb_state *mrb, mrb_value self)
{
struct RArray *a = mrb_ary_ptr(self);
mrb_int index;
mrb_value val;
mrb_value *ptr;
mrb_int len, alen = ARY_LEN(a);
mrb_get_args(mrb, "i", &index);
if (index < 0) index += alen;
if (index < 0 || alen <= index) return mrb_nil_value();
ary_modify(mrb, a);
ptr = ARY_PTR(a);
val = ptr[index];
ptr += index;
len = alen - index;
while (--len) {
*ptr = *(ptr+1);
++ptr;
}
ARY_SET_LEN(a, alen-1);
ary_shrink_capa(mrb, a);
return val;
}
/*
* Extract array range
*/
static VALUE my_ary_subseq (VALUE ary, long beg, long len)
{
VALUE klass = Qnil;
VALUE ary2 = Qnil;
if (beg > RARRAY_LEN(ary))
{
return Qnil;
}
if (beg < 0 || len < 0)
{
return Qnil;
}
if (RARRAY_LEN(ary) < len || RARRAY_LEN(ary) < beg + len)
{
len = RARRAY_LEN(ary) - beg;
}
klass = rb_obj_class(ary);
if (len == 0)
{
return my_ary_new(klass, 0);
}
ary2 = my_ary_new(klass, len);
MEMCPY(RARRAY_PTR(ary2), RARRAY_PTR(ary) + beg, VALUE, len);
ARY_SET_LEN(ary2, len);
return ary2;
}
/* mrb_gc_unregister() removes the object from GC root. */
MRB_API void
mrb_gc_unregister(mrb_state *mrb, mrb_value obj)
{
mrb_sym root = mrb_intern_lit(mrb, GC_ROOT_NAME);
mrb_value table = mrb_gv_get(mrb, root);
struct RArray *a;
mrb_int i;
if (mrb_nil_p(table)) return;
if (mrb_type(table) != MRB_TT_ARRAY) {
mrb_gv_set(mrb, root, mrb_nil_value());
return;
}
a = mrb_ary_ptr(table);
mrb_ary_modify(mrb, a);
for (i = 0; i < ARY_LEN(a); i++) {
if (mrb_obj_eq(mrb, ARY_PTR(a)[i], obj)) {
mrb_int len = ARY_LEN(a)-1;
mrb_value *ptr = ARY_PTR(a);
ARY_SET_LEN(a, len);
memmove(&ptr[i], &ptr[i + 1], (len - i) * sizeof(mrb_value));
break;
}
}
}
static void
ary_replace(mrb_state *mrb, struct RArray *a, mrb_value *argv, mrb_int len)
{
ary_modify(mrb, a);
if (ARY_CAPA(a) < len)
ary_expand_capa(mrb, a, len);
array_copy(ARY_PTR(a), argv, len);
mrb_write_barrier(mrb, (struct RBasic*)a);
ARY_SET_LEN(a, len);
}
MRB_API mrb_value
mrb_ary_new_from_values(mrb_state *mrb, mrb_int size, const mrb_value *vals)
{
struct RArray *a = ary_new_capa(mrb, size);
array_copy(ARY_PTR(a), vals, size);
ARY_SET_LEN(a, size);
return mrb_obj_value(a);
}
MRB_API mrb_value
mrb_assoc_new(mrb_state *mrb, mrb_value car, mrb_value cdr)
{
struct RArray *a;
a = ary_new_capa(mrb, 2);
ARY_PTR(a)[0] = car;
ARY_PTR(a)[1] = cdr;
ARY_SET_LEN(a, 2);
return mrb_obj_value(a);
}
MRB_API mrb_value
mrb_ary_pop(mrb_state *mrb, mrb_value ary)
{
struct RArray *a = mrb_ary_ptr(ary);
mrb_int len = ARY_LEN(a);
ary_modify_check(mrb, a);
if (len == 0) return mrb_nil_value();
ARY_SET_LEN(a, len-1);
return ARY_PTR(a)[len-1];
}
MRB_API void
mrb_ary_push(mrb_state *mrb, mrb_value ary, mrb_value elem)
{
struct RArray *a = mrb_ary_ptr(ary);
mrb_int len = ARY_LEN(a);
ary_modify(mrb, a);
if (len == ARY_CAPA(a))
ary_expand_capa(mrb, a, len + 1);
ARY_PTR(a)[len] = elem;
ARY_SET_LEN(a, len+1);
mrb_field_write_barrier_value(mrb, (struct RBasic*)a, elem);
}
static void
ary_concat(mrb_state *mrb, struct RArray *a, struct RArray *a2)
{
mrb_int len;
if (ARY_LEN(a2) > ARY_MAX_SIZE - ARY_LEN(a)) {
mrb_raise(mrb, E_ARGUMENT_ERROR, "array size too big");
}
len = ARY_LEN(a) + ARY_LEN(a2);
ary_modify(mrb, a);
if (ARY_CAPA(a) < len) {
ary_expand_capa(mrb, a, len);
}
array_copy(ARY_PTR(a)+ARY_LEN(a), ARY_PTR(a2), ARY_LEN(a2));
mrb_write_barrier(mrb, (struct RBasic*)a);
ARY_SET_LEN(a, len);
}
static mrb_value
mrb_ary_reverse(mrb_state *mrb, mrb_value self)
{
struct RArray *a = mrb_ary_ptr(self), *b = ary_new_capa(mrb, ARY_LEN(a));
mrb_int len = ARY_LEN(a);
if (len > 0) {
mrb_value *p1, *p2, *e;
p1 = ARY_PTR(a);
e = p1 + len;
p2 = ARY_PTR(b) + len - 1;
while (p1 < e) {
*p2-- = *p1++;
}
ARY_SET_LEN(b, len);
}
return mrb_obj_value(b);
}
static mrb_value
mrb_ary_plus(mrb_state *mrb, mrb_value self)
{
struct RArray *a1 = mrb_ary_ptr(self);
struct RArray *a2;
mrb_value *ptr;
mrb_int blen, len1;
mrb_get_args(mrb, "a", &ptr, &blen);
if (ARY_MAX_SIZE - blen < ARY_LEN(a1)) {
mrb_raise(mrb, E_ARGUMENT_ERROR, "array size too big");
}
len1 = ARY_LEN(a1);
a2 = ary_new_capa(mrb, len1 + blen);
array_copy(ARY_PTR(a2), ARY_PTR(a1), len1);
array_copy(ARY_PTR(a2) + len1, ptr, blen);
ARY_SET_LEN(a2, len1+blen);
return mrb_obj_value(a2);
}
MRB_API mrb_value
mrb_ary_resize(mrb_state *mrb, mrb_value ary, mrb_int new_len)
{
mrb_int old_len;
struct RArray *a = mrb_ary_ptr(ary);
ary_modify(mrb, a);
old_len = RARRAY_LEN(ary);
if (old_len != new_len) {
ARY_SET_LEN(a, new_len);
if (new_len < old_len) {
ary_shrink_capa(mrb, a);
}
else {
ary_expand_capa(mrb, a, new_len);
ary_fill_with_nil(ARY_PTR(a) + old_len, new_len - old_len);
}
}
return ary;
}
static mrb_value
mrb_ary_push_m(mrb_state *mrb, mrb_value self)
{
mrb_value *argv;
mrb_int len, len2, alen;
struct RArray *a;
mrb_get_args(mrb, "*!", &argv, &alen);
a = mrb_ary_ptr(self);
ary_modify(mrb, a);
len = ARY_LEN(a);
len2 = len + alen;
if (ARY_CAPA(a) < len2) {
ary_expand_capa(mrb, a, len2);
}
array_copy(ARY_PTR(a)+len, argv, alen);
ARY_SET_LEN(a, len2);
mrb_write_barrier(mrb, (struct RBasic*)a);
return self;
}
static void
ary_replace(mrb_state *mrb, struct RArray *a, struct RArray *b)
{
mrb_int len = ARY_LEN(b);
ary_modify_check(mrb, a);
if (a == b) return;
if (ARY_SHARED_P(a)) {
mrb_ary_decref(mrb, a->as.heap.aux.shared);
a->as.heap.aux.capa = 0;
a->as.heap.len = 0;
a->as.heap.ptr = NULL;
ARY_UNSET_SHARED_FLAG(a);
}
if (ARY_SHARED_P(b)) {
shared_b:
if (ARY_EMBED_P(a)) {
ARY_UNSET_EMBED_FLAG(a);
}
else {
mrb_free(mrb, a->as.heap.ptr);
}
a->as.heap.ptr = b->as.heap.ptr;
a->as.heap.len = len;
a->as.heap.aux.shared = b->as.heap.aux.shared;
a->as.heap.aux.shared->refcnt++;
ARY_SET_SHARED_FLAG(a);
mrb_write_barrier(mrb, (struct RBasic*)a);
return;
}
if (!MRB_FROZEN_P(b) && len > ARY_REPLACE_SHARED_MIN) {
ary_make_shared(mrb, b);
goto shared_b;
}
if (ARY_CAPA(a) < len)
ary_expand_capa(mrb, a, len);
array_copy(ARY_PTR(a), ARY_PTR(b), len);
mrb_write_barrier(mrb, (struct RBasic*)a);
ARY_SET_LEN(a, len);
}
MRB_API void
mrb_ary_set(mrb_state *mrb, mrb_value ary, mrb_int n, mrb_value val)
{
struct RArray *a = mrb_ary_ptr(ary);
mrb_int len = ARY_LEN(a);
ary_modify(mrb, a);
/* range check */
if (n < 0) {
n += len;
if (n < 0) {
mrb_raisef(mrb, E_INDEX_ERROR, "index %S out of array", mrb_fixnum_value(n - len));
}
}
if (len <= n) {
if (ARY_CAPA(a) <= n)
ary_expand_capa(mrb, a, n + 1);
ary_fill_with_nil(ARY_PTR(a) + len, n + 1 - len);
ARY_SET_LEN(a, n+1);
}
ARY_PTR(a)[n] = val;
mrb_field_write_barrier_value(mrb, (struct RBasic*)a, val);
}
/*
* Allocates space for an array but leaves the array length at 0
*/
static VALUE initialize (VALUE self, VALUE size)
{
rb_call_super(1, &size);
ARY_SET_LEN(self, 0);
return self;
}
MRB_API mrb_value
mrb_ary_splice(mrb_state *mrb, mrb_value ary, mrb_int head, mrb_int len, mrb_value rpl)
{
struct RArray *a = mrb_ary_ptr(ary);
mrb_int alen = ARY_LEN(a);
const mrb_value *argv;
mrb_int argc;
mrb_int tail;
ary_modify(mrb, a);
/* len check */
if (len < 0) mrb_raisef(mrb, E_INDEX_ERROR, "negative length (%S)", mrb_fixnum_value(len));
/* range check */
if (head < 0) {
head += alen;
if (head < 0) {
mrb_raise(mrb, E_INDEX_ERROR, "index is out of array");
}
}
tail = head + len;
if (alen < len || alen < tail) {
len = alen - head;
}
/* size check */
if (mrb_array_p(rpl)) {
argc = RARRAY_LEN(rpl);
argv = RARRAY_PTR(rpl);
if (argv == ARY_PTR(a)) {
struct RArray *r;
if (argc > 32767) {
mrb_raise(mrb, E_ARGUMENT_ERROR, "too big recursive splice");
}
r = ary_dup(mrb, a);
argv = ARY_PTR(r);
}
}
else {
argc = 1;
argv = &rpl;
}
if (head >= alen) {
if (head > ARY_MAX_SIZE - argc) {
mrb_raisef(mrb, E_INDEX_ERROR, "index %S too big", mrb_fixnum_value(head));
}
len = head + argc;
if (len > ARY_CAPA(a)) {
ary_expand_capa(mrb, a, head + argc);
}
ary_fill_with_nil(ARY_PTR(a) + alen, head - alen);
if (argc > 0) {
array_copy(ARY_PTR(a) + head, argv, argc);
}
ARY_SET_LEN(a, len);
}
else {
mrb_int newlen;
if (alen - len > ARY_MAX_SIZE - argc) {
mrb_raisef(mrb, E_INDEX_ERROR, "index %S too big", mrb_fixnum_value(alen + argc - len));
}
newlen = alen + argc - len;
if (newlen > ARY_CAPA(a)) {
ary_expand_capa(mrb, a, newlen);
}
if (len != argc) {
mrb_value *ptr = ARY_PTR(a);
tail = head + len;
value_move(ptr + head + argc, ptr + tail, alen - tail);
ARY_SET_LEN(a, newlen);
}
if (argc > 0) {
value_move(ARY_PTR(a) + head, argv, argc);
}
}
mrb_write_barrier(mrb, (struct RBasic*)a);
return ary;
}
