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qrpa.pmc
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qrpa.pmc
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/* QRPA is a replacment for Parrot's ResizablePMCArray (RPA) class.
* The key distinguishing feature of QRPA is that it's much
* more efficient for shift and unshift, providing a O(1)
* algorithm instead of the O(n) version that RPA has.
* It also means that splice can be performed a lot more
* efficiently in many common cases. */
pmclass QRPA
provides array
auto_attrs
dynpmc
group nqp
hll nqp
{
ATTR INTVAL elems; /* number of elements */
ATTR INTVAL start; /* slot index of first element */
ATTR INTVAL ssize; /* size of slots array */
ATTR PMC **slots; /* array of PMC slots */
VTABLE void destroy() {
Parrot_QRPA_attributes * const qrpa = PARROT_QRPA(SELF);
if (qrpa->slots) {
mem_gc_free(INTERP, qrpa->slots);
qrpa->slots = 0;
}
}
VTABLE void mark() {
Parrot_QRPA_attributes * const qrpa = PARROT_QRPA(SELF);
INTVAL elems = qrpa->elems;
INTVAL start = qrpa->start;
PMC **slots = qrpa->slots;
slots += start;
for (elems--; elems >= 0; elems--) {
Parrot_gc_mark_PMC_alive(INTERP, slots[elems]);
}
}
VTABLE PMC * clone() {
PMC * const dest = Parrot_pmc_new(INTERP, SELF->vtable->base_type);
Parrot_QRPA_attributes * const qrpa0 = PARROT_QRPA(SELF);
Parrot_QRPA_attributes * const qrpa1 = PARROT_QRPA(dest);
INTVAL elems = qrpa0->elems;
if (elems > 0) {
qrpa1->slots = mem_gc_allocate_n_typed(INTERP, elems, PMC *);
qrpa1->elems = elems;
mem_copy_n_typed(qrpa1->slots, qrpa0->slots + qrpa0->start,
elems, PMC *);
PObj_custom_mark_destroy_SETALL(dest);
}
return dest;
}
/*
=item C<void set_integer_native(INTVAL n)>
Resizes the array to C<n> elements.
=cut
*/
VTABLE void set_integer_native(INTVAL n) {
Parrot_QRPA_attributes * const qrpa = PARROT_QRPA(SELF);
INTVAL elems = qrpa->elems;
INTVAL start = qrpa->start;
INTVAL ssize = qrpa->ssize;
PMC **slots = qrpa->slots;
if (n < 0)
Parrot_ex_throw_from_c_args(INTERP, NULL, EXCEPTION_OUT_OF_BOUNDS,
"QRPA: Can't resize to negative elements");
if (n == elems) { return; }
/* if there aren't enough slots at the end, shift off empty slots
* from the beginning first */
if (start > 0 && n + start > ssize) {
if (elems > 0)
memmove(slots, slots + start, elems * sizeof (PMC *));
qrpa->start = 0;
/* fill out any unused slots with PMCNULL pointers */
while (elems < ssize) {
slots[elems] = PMCNULL;
elems++;
}
}
qrpa->elems = n;
if (n <= ssize) {
/* we already have n slots available, we can just return */
return;
}
/* We need more slots. If the current slot size is less
* than 8K, use the larger of twice the current slot size
* or the actual number of elements needed. Otherwise,
* grow the slots to the next multiple of 4096 (0x1000). */
if (ssize < 8192) {
ssize *= 2;
if (n > ssize) ssize = n;
if (ssize < 8) ssize = 8;
}
else {
ssize = (n + 0x1000) & ~0xfff;
}
/* now allocate the new slot buffer */
slots = (slots)
? mem_gc_realloc_n_typed(INTERP, slots, ssize, PMC *)
: mem_gc_allocate_n_typed(INTERP, ssize, PMC *);
/* fill out any unused slots with PMCNULL pointers */
while (elems < ssize) {
slots[elems] = PMCNULL;
elems++;
}
qrpa->ssize = ssize;
qrpa->slots = slots;
PObj_custom_mark_destroy_SETALL(SELF);
}
VTABLE INTVAL defined_keyed_int(INTVAL pos) {
Parrot_QRPA_attributes * const qrpa = PARROT_QRPA(SELF);
PMC *value;
if (pos < 0)
pos += qrpa->elems;
if (pos < 0 || pos >= qrpa->elems)
return 0;
value = qrpa->slots[qrpa->start + pos];
return !PMC_IS_NULL(value) && VTABLE_defined(INTERP, value);
}
VTABLE INTVAL elements() {
Parrot_QRPA_attributes * const qrpa = PARROT_QRPA(SELF);
return qrpa->elems;
}
VTABLE INTVAL exists_keyed_int(INTVAL pos) {
Parrot_QRPA_attributes * const qrpa = PARROT_QRPA(SELF);
PMC *value;
if (pos < 0)
pos += qrpa->elems;
if (pos < 0 || pos >= qrpa->elems)
return 0;
return !PMC_IS_NULL(qrpa->slots[qrpa->start + pos]);
}
VTABLE INTVAL exists_keyed(PMC *key) {
INTVAL pos = VTABLE_get_integer(INTERP, key);
return SELF.exists_keyed_int(pos);
}
VTABLE INTVAL get_bool() {
const INTVAL elems = SELF.elements();
return (INTVAL)(elems != 0);
}
VTABLE INTVAL get_integer() {
return SELF.elements();
}
VTABLE PMC * get_iter() {
return Parrot_pmc_new_init(INTERP, enum_class_ArrayIterator, SELF);
}
VTABLE FLOATVAL get_number() {
const INTVAL e = SELF.elements();
return (FLOATVAL)e;
}
VTABLE PMC * get_pmc_keyed_int(INTVAL pos) {
Parrot_QRPA_attributes * const qrpa = PARROT_QRPA(SELF);
if (pos < 0) {
pos += qrpa->elems;
if (pos < 0)
Parrot_ex_throw_from_c_args(INTERP, NULL, EXCEPTION_OUT_OF_BOUNDS,
"QRPA: index out of bounds");
}
else if (pos >= qrpa->elems)
return PMCNULL;
return qrpa->slots[qrpa->start + pos];
}
VTABLE PMC *get_pmc_keyed(PMC *key) {
const INTVAL pos = VTABLE_get_integer(INTERP, key);
PMC * const nextkey = Parrot_key_next(INTERP, key);
PMC * box;
if (!nextkey)
return SELF.get_pmc_keyed_int(pos);
box = SELF.get_pmc_keyed_int(pos);
if (PMC_IS_NULL(box))
return PMCNULL;
return VTABLE_get_pmc_keyed(INTERP, box, nextkey);
}
VTABLE void set_pmc_keyed_int(INTVAL pos, PMC *value) {
Parrot_QRPA_attributes * const qrpa = PARROT_QRPA(SELF);
if (pos < 0) {
pos += qrpa->elems;
if (pos < 0)
Parrot_ex_throw_from_c_args(INTERP, NULL,
EXCEPTION_OUT_OF_BOUNDS, "QRPA: index out of bounds");
}
else if (pos >= qrpa->elems)
SELF.set_integer_native(pos + 1);
qrpa->slots[qrpa->start + pos] = value;
}
VTABLE void set_pmc_keyed(PMC *key, PMC *value) {
const INTVAL pos = VTABLE_get_integer(INTERP, key);
PMC * const nextkey = Parrot_key_next(INTERP, key);
if (!nextkey) {
SELF.set_pmc_keyed_int(pos, value);
}
else {
PMC * const box = SELF.get_pmc_keyed_int(pos);
if (PMC_IS_NULL(box)) {
Parrot_ex_throw_from_c_args(interp, NULL,
EXCEPTION_INVALID_OPERATION,
"Cannot autovivify nested arrays");
}
VTABLE_set_pmc_keyed(INTERP, box, nextkey, value);
}
}
VTABLE PMC * pop_pmc() {
Parrot_QRPA_attributes * const qrpa = PARROT_QRPA(SELF);
if (qrpa->elems < 1) {
Parrot_ex_throw_from_c_args(interp, NULL, EXCEPTION_OUT_OF_BOUNDS,
"QRPA: Can't pop from an empty array!");
}
qrpa->elems--;
return qrpa->slots[qrpa->start + qrpa->elems];
}
VTABLE void push_pmc(PMC *value) {
Parrot_QRPA_attributes * const qrpa = PARROT_QRPA(SELF);
SELF.set_integer_native(qrpa->elems + 1);
qrpa->slots[qrpa->start + qrpa->elems - 1] = value;
}
VTABLE PMC * shift_pmc() {
Parrot_QRPA_attributes * const qrpa = PARROT_QRPA(SELF);
PMC *value;
if (qrpa->elems < 1) {
Parrot_ex_throw_from_c_args(interp, NULL, EXCEPTION_OUT_OF_BOUNDS,
"QRPA: Can't pop from an empty array!");
}
value = qrpa->slots[qrpa->start];
qrpa->start++;
qrpa->elems--;
return value;
}
VTABLE void unshift_pmc(PMC *value) {
Parrot_QRPA_attributes * const qrpa = PARROT_QRPA(SELF);
/* If we don't have room at the beginning of the slots,
* make some room (8 slots) for unshifting */
if (qrpa->start < 1) {
INTVAL n = 8;
INTVAL elems = qrpa->elems;
INTVAL i;
/* grow the array */
SELF.set_integer_native(elems + n);
/* move elements and set start */
memmove(qrpa->slots + n, qrpa->slots, elems * sizeof (PMC *));
qrpa->start = n;
qrpa->elems = elems;
/* clear out beginning elements */
for (i = 0; i < n; i++)
qrpa->slots[i] = PMCNULL;
}
/* Now do the unshift */
qrpa->start--;
qrpa->slots[qrpa->start] = value;
qrpa->elems++;
}
VTABLE void splice(PMC *from, INTVAL offset, INTVAL count) {
/* TODO: use qrpa->foo instead of GET_ATTR_* */
INTVAL elems0 = VTABLE_elements(INTERP, SELF);
INTVAL elems1 = VTABLE_elements(INTERP, from);
PMC **slots = 0;
INTVAL start;
INTVAL tail;
/* start from end? */
if (offset < 0)
offset += elems0;
if (offset < 0)
Parrot_ex_throw_from_c_args(INTERP, NULL, EXCEPTION_OUT_OF_BOUNDS,
"QRPA: illegal splice offset\n");
/* When offset == 0, then we may be able to reduce the memmove
* calls and reallocs by adjusting SELF's start, elems0, and
* count to better match the incoming splice. In particular,
* we're seeking to adjust C<count> to as close to C<elems1>
* as we can. */
if (offset == 0) {
INTVAL n = elems1 - count;
GET_ATTR_start(INTERP, SELF, start);
if (n > start) n = start;
if (n <= -elems0) {
elems0 = 0;
count = 0;
SET_ATTR_start(INTERP, SELF, 0);
SET_ATTR_elems(INTERP, SELF, elems0);
}
else if (n != 0) {
elems0 += n;
count += n;
SET_ATTR_start(INTERP, SELF, start - n);
SET_ATTR_elems(INTERP, SELF, elems0);
}
}
/* if count == 0 and elems1 == 0, there's nothing left
* to copy or remove, so the splice is done! */
if (count == 0 && elems1 == 0)
return;
/* number of elements to right of splice (the "tail") */
tail = elems0 - offset - count;
if (tail < 0) tail = 0;
if (tail > 0 && count > elems1) {
/* We're shrinking the array, so first move the tail left */
GET_ATTR_slots(INTERP, SELF, slots);
GET_ATTR_start(INTERP, SELF, start);
memmove(slots + start + offset + elems1,
slots + start + offset + count,
tail * sizeof (PMC *));
}
/* now resize the array */
SELF.set_integer_native(offset + elems1 + tail);
GET_ATTR_slots(INTERP, SELF, slots);
GET_ATTR_start(INTERP, SELF, start);
if (tail > 0 && count < elems1) {
/* The array grew, so move the tail to the right */
memmove(slots + start + offset + elems1,
slots + start + offset + count,
tail * sizeof (PMC *));
}
/* now copy C<from>'s elements into SELF */
if (elems1 > 0) {
PMC *iter = VTABLE_get_iter(INTERP, from);
INTVAL i;
for (i = 0; i < elems1; i++)
slots[start + offset + i] = VTABLE_shift_pmc(INTERP, iter);
}
}
VTABLE INTVAL get_integer_keyed(PMC *key) {
PMC * const val = SELF.get_pmc_keyed(key);
return VTABLE_get_integer(INTERP, val);
}
VTABLE void set_integer_keyed(PMC *key, INTVAL value) {
PMC * const val = Parrot_pmc_new(INTERP, Parrot_hll_get_ctx_HLL_type(INTERP, enum_class_Integer));
VTABLE_set_integer_native(INTERP, val, value);
SELF.set_pmc_keyed(key, val);
}
VTABLE void set_integer_keyed_int(INTVAL pos, INTVAL value) {
PMC * const val = Parrot_pmc_new(INTERP, Parrot_hll_get_ctx_HLL_type(INTERP, enum_class_Integer));
VTABLE_set_integer_native(INTERP, val, value);
SELF.set_pmc_keyed_int(pos, val);
}
VTABLE INTVAL pop_integer() {
PMC * const val = SELF.pop_pmc();
return VTABLE_get_integer(INTERP, val);
}
VTABLE void push_integer(INTVAL value) {
INTVAL elems;
GET_ATTR_elems(INTERP, SELF, elems);
SELF.set_integer_keyed_int(elems, value);
}
VTABLE INTVAL shift_integer() {
PMC * const val = SELF.shift_pmc();
return VTABLE_get_integer(INTERP, val);
}
VTABLE void unshift_integer(INTVAL value) {
PMC * const val = Parrot_pmc_new(INTERP, Parrot_hll_get_ctx_HLL_type(INTERP, enum_class_Integer));
VTABLE_set_integer_native(INTERP, val, value);
SELF.unshift_pmc(val);
}
VTABLE FLOATVAL get_number_keyed(PMC *key) {
PMC * const val = SELF.get_pmc_keyed(key);
return VTABLE_get_number(INTERP, val);
}
VTABLE void set_number_keyed(PMC *key, FLOATVAL value) {
PMC * const val = Parrot_pmc_new(INTERP, Parrot_hll_get_ctx_HLL_type(INTERP, enum_class_Float));
VTABLE_set_number_native(INTERP, val, value);
SELF.set_pmc_keyed(key, val);
}
VTABLE void set_number_keyed_int(INTVAL pos, FLOATVAL value) {
PMC * const val = Parrot_pmc_new(INTERP, Parrot_hll_get_ctx_HLL_type(INTERP, enum_class_Float));
VTABLE_set_number_native(INTERP, val, value);
SELF.set_pmc_keyed_int(pos, val);
}
VTABLE FLOATVAL pop_float() {
PMC * const val = SELF.pop_pmc();
return VTABLE_get_number(INTERP, val);
}
VTABLE void push_float(FLOATVAL value) {
INTVAL elems;
GET_ATTR_elems(INTERP, SELF, elems);
SELF.set_number_keyed_int(elems, value);
}
VTABLE FLOATVAL shift_float() {
PMC * const val = SELF.shift_pmc();
return VTABLE_get_number(INTERP, val);
}
VTABLE void unshift_float(FLOATVAL value) {
PMC * const val = Parrot_pmc_new(INTERP, Parrot_hll_get_ctx_HLL_type(INTERP, enum_class_Float));
VTABLE_set_number_native(INTERP, val, value);
SELF.unshift_pmc(val);
}
VTABLE STRING * get_string_keyed(PMC *key) {
PMC * const val = SELF.get_pmc_keyed(key);
return VTABLE_get_string(INTERP, val);
}
VTABLE void set_string_keyed(PMC *key, STRING *value) {
PMC * const val = Parrot_pmc_new(INTERP, Parrot_hll_get_ctx_HLL_type(INTERP, enum_class_String));
VTABLE_set_string_native(INTERP, val, value);
SELF.set_pmc_keyed(key, val);
}
VTABLE void set_string_keyed_int(INTVAL key, STRING *value) {
PMC * const val = Parrot_pmc_new(INTERP, Parrot_hll_get_ctx_HLL_type(INTERP, enum_class_String));
VTABLE_set_string_native(INTERP, val, value);
SELF.set_pmc_keyed_int(key, val);
}
VTABLE STRING * pop_string() {
PMC * const val = SELF.pop_pmc();
return VTABLE_get_string(INTERP, val);
}
VTABLE void push_string(STRING *value) {
INTVAL elems;
GET_ATTR_elems(INTERP, SELF, elems);
SELF.set_string_keyed_int(elems, value);
}
VTABLE STRING * shift_string() {
PMC * const val = SELF.shift_pmc();
return VTABLE_get_string(INTERP, val);
}
VTABLE void unshift_string(STRING *value) {
PMC * const val = Parrot_pmc_new(INTERP, Parrot_hll_get_ctx_HLL_type(INTERP, enum_class_String));
VTABLE_set_string_native(INTERP, val, value);
SELF.unshift_pmc(val);
}
}
/*
=back
=cut
*/