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d4c868da9f97a06c3457b8eafd344a23ed704874
blender-archive/source/blender/functions/intern/generic_virtual_array.cc
Jacques Lucke d4c868da9f Geometry Nodes: refactor virtual array system 
Goals of this refactor:
* Simplify creating virtual arrays.
* Simplify passing virtual arrays around.
* Simplify converting between typed and generic virtual arrays.
* Reduce memory allocations.

As a quick reminder, a virtual arrays is a data structure that behaves like an
array (i.e. it can be accessed using an index). However, it may not actually
be stored as array internally. The two most important implementations
of virtual arrays are those that correspond to an actual plain array and those
that have the same value for every index. However, many more
implementations exist for various reasons (interfacing with legacy attributes,
unified iterator over all points in multiple splines, ...).

With this refactor the core types (`VArray`, `GVArray`, `VMutableArray` and
`GVMutableArray`) can be used like "normal values". They typically live
on the stack. Before, they were usually inside a `std::unique_ptr`. This makes
passing them around much easier. Creation of new virtual arrays is also
much simpler now due to some constructors. Memory allocations are
reduced by making use of small object optimization inside the core types.

Previously, `VArray` was a class with virtual methods that had to be overridden
to change the behavior of a the virtual array. Now,`VArray` has a fixed size
and has no virtual methods. Instead it contains a `VArrayImpl` that is
similar to the old `VArray`. `VArrayImpl` should rarely ever be used directly,
unless a new virtual array implementation is added.

To support the small object optimization for many `VArrayImpl` classes,
a new `blender::Any` type is added. It is similar to `std::any` with two
additional features. It has an adjustable inline buffer size and alignment.
The inline buffer size of `std::any` can't be relied on and is usually too
small for our use case here. Furthermore, `blender::Any` can store
additional user-defined type information without increasing the
stack size.

Differential Revision: https://developer.blender.org/D12986
2021-11-16 10:16:30 +01:00

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/*
* This program is free software; you can redistribute it and/or
* modify it under the terms of the GNU General Public License
* as published by the Free Software Foundation; either version 2
* of the License, or (at your option) any later version.
*
* This program is distributed in the hope that it will be useful,
* but WITHOUT ANY WARRANTY; without even the implied warranty of
* MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the
* GNU General Public License for more details.
*
* You should have received a copy of the GNU General Public License
* along with this program; if not, write to the Free Software Foundation,
* Inc., 51 Franklin Street, Fifth Floor, Boston, MA 02110-1301, USA.
*/
#include "FN_generic_virtual_array.hh"
namespace blender::fn {
/* -------------------------------------------------------------------- */
/** \name #GVArrayImpl
* \{ */
void GVArrayImpl::materialize(const IndexMask mask, void *dst) const
{
for (const int64_t i : mask) {
void *elem_dst = POINTER_OFFSET(dst, type_->size() * i);
this->get(i, elem_dst);
}
}
void GVArrayImpl::materialize_to_uninitialized(const IndexMask mask, void *dst) const
{
for (const int64_t i : mask) {
void *elem_dst = POINTER_OFFSET(dst, type_->size() * i);
this->get_to_uninitialized(i, elem_dst);
}
}
void GVArrayImpl::get(const int64_t index, void *r_value) const
{
type_->destruct(r_value);
this->get_to_uninitialized(index, r_value);
}
bool GVArrayImpl::is_span() const
{
return false;
}
GSpan GVArrayImpl::get_internal_span() const
{
BLI_assert(false);
return GSpan(*type_);
}
bool GVArrayImpl::is_single() const
{
return false;
}
void GVArrayImpl::get_internal_single(void *UNUSED(r_value)) const
{
BLI_assert(false);
}
bool GVArrayImpl::try_assign_VArray(void *UNUSED(varray)) const
{
return false;
}
bool GVArrayImpl::may_have_ownership() const
{
/* Use true as default to avoid accidentally creating subclasses that have this set to false but
* actually own data. Subclasses should set the to false instead. */
return true;
}
/** \} */
/* -------------------------------------------------------------------- */
/** \name #GVMutableArrayImpl
* \{ */
GVMutableArrayImpl::GVMutableArrayImpl(const CPPType &type, const int64_t size)
: GVArrayImpl(type, size)
{
}
void GVMutableArrayImpl::set_by_copy(const int64_t index, const void *value)
{
BUFFER_FOR_CPP_TYPE_VALUE(*type_, buffer);
type_->copy_construct(value, buffer);
this->set_by_move(index, buffer);
type_->destruct(buffer);
}
void GVMutableArrayImpl::set_by_relocate(const int64_t index, void *value)
{
this->set_by_move(index, value);
type_->destruct(value);
}
void GVMutableArrayImpl::set_all(const void *src)
{
if (this->is_span()) {
const GSpan span = this->get_internal_span();
type_->copy_assign_n(src, const_cast<void *>(span.data()), size_);
}
else {
for (int64_t i : IndexRange(size_)) {
this->set_by_copy(i, POINTER_OFFSET(src, type_->size() * i));
}
}
}
void GVMutableArray::fill(const void *value)
{
if (this->is_span()) {
const GSpan span = this->get_internal_span();
this->type().fill_assign_n(value, const_cast<void *>(span.data()), this->size());
}
else {
for (int64_t i : IndexRange(this->size())) {
this->set_by_copy(i, value);
}
}
}
bool GVMutableArrayImpl::try_assign_VMutableArray(void *UNUSED(varray)) const
{
return false;
}
/** \} */
/* -------------------------------------------------------------------- */
/** \name #GVArrayImpl_For_GSpan
* \{ */
GVArrayImpl_For_GSpan::GVArrayImpl_For_GSpan(const GSpan span)
: GVArrayImpl(span.type(), span.size()), data_(span.data()), element_size_(span.type().size())
{
}
GVArrayImpl_For_GSpan::GVArrayImpl_For_GSpan(const CPPType &type, const int64_t size)
: GVArrayImpl(type, size), element_size_(type.size())
{
}
void GVArrayImpl_For_GSpan::get(const int64_t index, void *r_value) const
{
type_->copy_assign(POINTER_OFFSET(data_, element_size_ * index), r_value);
}
void GVArrayImpl_For_GSpan::get_to_uninitialized(const int64_t index, void *r_value) const
{
type_->copy_construct(POINTER_OFFSET(data_, element_size_ * index), r_value);
}
bool GVArrayImpl_For_GSpan::is_span() const
{
return true;
}
GSpan GVArrayImpl_For_GSpan::get_internal_span() const
{
return GSpan(*type_, data_, size_);
}
/** See #VArrayImpl_For_Span_final. */
class GVArrayImpl_For_GSpan_final final : public GVArrayImpl_For_GSpan {
public:
using GVArrayImpl_For_GSpan::GVArrayImpl_For_GSpan;
private:
bool may_have_ownership() const override
{
return false;
}
};
/** \} */
/* -------------------------------------------------------------------- */
/** \name #GVMutableArrayImpl_For_GMutableSpan
* \{ */
GVMutableArrayImpl_For_GMutableSpan::GVMutableArrayImpl_For_GMutableSpan(const GMutableSpan span)
: GVMutableArrayImpl(span.type(), span.size()),
data_(span.data()),
element_size_(span.type().size())
{
}
GVMutableArrayImpl_For_GMutableSpan::GVMutableArrayImpl_For_GMutableSpan(const CPPType &type,
const int64_t size)
: GVMutableArrayImpl(type, size), element_size_(type.size())
{
}
void GVMutableArrayImpl_For_GMutableSpan::get(const int64_t index, void *r_value) const
{
type_->copy_assign(POINTER_OFFSET(data_, element_size_ * index), r_value);
}
void GVMutableArrayImpl_For_GMutableSpan::get_to_uninitialized(const int64_t index,
void *r_value) const
{
type_->copy_construct(POINTER_OFFSET(data_, element_size_ * index), r_value);
}
void GVMutableArrayImpl_For_GMutableSpan::set_by_copy(const int64_t index, const void *value)
{
type_->copy_assign(value, POINTER_OFFSET(data_, element_size_ * index));
}
void GVMutableArrayImpl_For_GMutableSpan::set_by_move(const int64_t index, void *value)
{
type_->move_construct(value, POINTER_OFFSET(data_, element_size_ * index));
}
void GVMutableArrayImpl_For_GMutableSpan::set_by_relocate(const int64_t index, void *value)
{
type_->relocate_assign(value, POINTER_OFFSET(data_, element_size_ * index));
}
bool GVMutableArrayImpl_For_GMutableSpan::is_span() const
{
return true;
}
GSpan GVMutableArrayImpl_For_GMutableSpan::get_internal_span() const
{
return GSpan(*type_, data_, size_);
}
class GVMutableArrayImpl_For_GMutableSpan_final final
: public GVMutableArrayImpl_For_GMutableSpan {
public:
using GVMutableArrayImpl_For_GMutableSpan::GVMutableArrayImpl_For_GMutableSpan;
private:
bool may_have_ownership() const override
{
return false;
}
};
/** \} */
/* -------------------------------------------------------------------- */
/** \name #GVArrayImpl_For_SingleValueRef
* \{ */
/* Generic virtual array where each element has the same value. The value is not owned. */
class GVArrayImpl_For_SingleValueRef : public GVArrayImpl {
protected:
const void *value_ = nullptr;
public:
GVArrayImpl_For_SingleValueRef(const CPPType &type, const int64_t size, const void *value)
: GVArrayImpl(type, size), value_(value)
{
}
protected:
GVArrayImpl_For_SingleValueRef(const CPPType &type, const int64_t size) : GVArrayImpl(type, size)
{
}
void get(const int64_t UNUSED(index), void *r_value) const override
{
type_->copy_assign(value_, r_value);
}
void get_to_uninitialized(const int64_t UNUSED(index), void *r_value) const override
{
type_->copy_construct(value_, r_value);
}
bool is_span() const override
{
return size_ == 1;
}
GSpan get_internal_span() const override
{
return GSpan{*type_, value_, 1};
}
bool is_single() const override
{
return true;
}
void get_internal_single(void *r_value) const override
{
type_->copy_assign(value_, r_value);
}
};
class GVArrayImpl_For_SingleValueRef_final final : public GVArrayImpl_For_SingleValueRef {
public:
using GVArrayImpl_For_SingleValueRef::GVArrayImpl_For_SingleValueRef;
private:
bool may_have_ownership() const override
{
return false;
}
};
/** \} */
/* -------------------------------------------------------------------- */
/** \name #GVArrayImpl_For_SingleValue
* \{ */
/* Same as GVArrayImpl_For_SingleValueRef, but the value is owned. */
class GVArrayImpl_For_SingleValue : public GVArrayImpl_For_SingleValueRef,
NonCopyable,
NonMovable {
public:
GVArrayImpl_For_SingleValue(const CPPType &type, const int64_t size, const void *value)
: GVArrayImpl_For_SingleValueRef(type, size)
{
value_ = MEM_mallocN_aligned(type.size(), type.alignment(), __func__);
type.copy_construct(value, (void *)value_);
}
~GVArrayImpl_For_SingleValue() override
{
type_->destruct((void *)value_);
MEM_freeN((void *)value_);
}
};
/** \} */
/* -------------------------------------------------------------------- */
/** \name #GVArray_GSpan
* \{ */
GVArray_GSpan::GVArray_GSpan(GVArray varray) : GSpan(varray.type()), varray_(std::move(varray))
{
size_ = varray_.size();
if (varray_.is_span()) {
data_ = varray_.get_internal_span().data();
}
else {
owned_data_ = MEM_mallocN_aligned(type_->size() * size_, type_->alignment(), __func__);
varray_.materialize_to_uninitialized(IndexRange(size_), owned_data_);
data_ = owned_data_;
}
}
GVArray_GSpan::~GVArray_GSpan()
{
if (owned_data_ != nullptr) {
type_->destruct_n(owned_data_, size_);
MEM_freeN(owned_data_);
}
}
/** \} */
/* -------------------------------------------------------------------- */
/** \name #GVMutableArray_GSpan
* \{ */
GVMutableArray_GSpan::GVMutableArray_GSpan(GVMutableArray varray, const bool copy_values_to_span)
: GMutableSpan(varray.type()), varray_(std::move(varray))
{
size_ = varray_.size();
if (varray_.is_span()) {
data_ = varray_.get_internal_span().data();
}
else {
owned_data_ = MEM_mallocN_aligned(type_->size() * size_, type_->alignment(), __func__);
if (copy_values_to_span) {
varray_.materialize_to_uninitialized(IndexRange(size_), owned_data_);
}
else {
type_->default_construct_n(owned_data_, size_);
}
data_ = owned_data_;
}
}
GVMutableArray_GSpan::~GVMutableArray_GSpan()
{
if (show_not_saved_warning_) {
if (!save_has_been_called_) {
std::cout << "Warning: Call `apply()` to make sure that changes persist in all cases.\n";
}
}
if (owned_data_ != nullptr) {
type_->destruct_n(owned_data_, size_);
MEM_freeN(owned_data_);
}
}
void GVMutableArray_GSpan::save()
{
save_has_been_called_ = true;
if (data_ != owned_data_) {
return;
}
const int64_t element_size = type_->size();
for (int64_t i : IndexRange(size_)) {
varray_.set_by_copy(i, POINTER_OFFSET(owned_data_, element_size * i));
}
}
void GVMutableArray_GSpan::disable_not_applied_warning()
{
show_not_saved_warning_ = false;
}
/** \} */
/* -------------------------------------------------------------------- */
/** \name #GVArrayImpl_For_SlicedGVArray
* \{ */
class GVArrayImpl_For_SlicedGVArray : public GVArrayImpl {
protected:
GVArray varray_;
int64_t offset_;
public:
GVArrayImpl_For_SlicedGVArray(GVArray varray, const IndexRange slice)
: GVArrayImpl(varray.type(), slice.size()),
varray_(std::move(varray)),
offset_(slice.start())
{
BLI_assert(slice.one_after_last() <= varray_.size());
}
void get(const int64_t index, void *r_value) const override
{
varray_.get(index + offset_, r_value);
}
void get_to_uninitialized(const int64_t index, void *r_value) const override
{
varray_.get_to_uninitialized(index + offset_, r_value);
}
};
/** \} */
/* -------------------------------------------------------------------- */
/** \name #GVArrayCommon
* \{ */
GVArrayCommon::GVArrayCommon() = default;
GVArrayCommon::GVArrayCommon(const GVArrayCommon &other) : storage_(other.storage_)
{
impl_ = this->impl_from_storage();
}
GVArrayCommon::GVArrayCommon(GVArrayCommon &&other) noexcept : storage_(std::move(other.storage_))
{
impl_ = this->impl_from_storage();
other.storage_.reset();
other.impl_ = nullptr;
}
GVArrayCommon::GVArrayCommon(const GVArrayImpl *impl) : impl_(impl)
{
storage_ = impl_;
}
GVArrayCommon::GVArrayCommon(std::shared_ptr<const GVArrayImpl> impl) : impl_(impl.get())
{
if (impl) {
storage_ = std::move(impl);
}
}
GVArrayCommon::~GVArrayCommon() = default;
void GVArrayCommon::materialize(void *dst) const
{
this->materialize(IndexMask(impl_->size()), dst);
}
void GVArrayCommon::materialize(const IndexMask mask, void *dst) const
{
impl_->materialize(mask, dst);
}
void GVArrayCommon::materialize_to_uninitialized(void *dst) const
{
this->materialize_to_uninitialized(IndexMask(impl_->size()), dst);
}
void GVArrayCommon::materialize_to_uninitialized(const IndexMask mask, void *dst) const
{
BLI_assert(mask.min_array_size() <= impl_->size());
impl_->materialize_to_uninitialized(mask, dst);
}
bool GVArrayCommon::may_have_ownership() const
{
return impl_->may_have_ownership();
}
void GVArrayCommon::copy_from(const GVArrayCommon &other)
{
if (this == &other) {
return;
}
storage_ = other.storage_;
impl_ = this->impl_from_storage();
}
void GVArrayCommon::move_from(GVArrayCommon &&other) noexcept
{
if (this == &other) {
return;
}
storage_ = std::move(other.storage_);
impl_ = this->impl_from_storage();
other.storage_.reset();
other.impl_ = nullptr;
}
/* Returns true when the virtual array is stored as a span internally. */
bool GVArrayCommon::is_span() const
{
if (this->is_empty()) {
return true;
}
return impl_->is_span();
}
/* Returns the internally used span of the virtual array. This invokes undefined behavior is the
* virtual array is not stored as a span internally. */
GSpan GVArrayCommon::get_internal_span() const
{
BLI_assert(this->is_span());
if (this->is_empty()) {
return GSpan(impl_->type());
}
return impl_->get_internal_span();
}
/* Returns true when the virtual array returns the same value for every index. */
bool GVArrayCommon::is_single() const
{
if (impl_->size() == 1) {
return true;
}
return impl_->is_single();
}
/* Copies the value that is used for every element into `r_value`, which is expected to point to
* initialized memory. This invokes undefined behavior if the virtual array would not return the
* same value for every index. */
void GVArrayCommon::get_internal_single(void *r_value) const
{
BLI_assert(this->is_single());
if (impl_->size() == 1) {
impl_->get(0, r_value);
return;
}
impl_->get_internal_single(r_value);
}
/* Same as `get_internal_single`, but `r_value` points to initialized memory. */
void GVArrayCommon::get_internal_single_to_uninitialized(void *r_value) const
{
impl_->type().default_construct(r_value);
this->get_internal_single(r_value);
}
const GVArrayImpl *GVArrayCommon::impl_from_storage() const
{
return storage_.extra_info().get_varray(storage_.get());
}
IndexRange GVArrayCommon::index_range() const
{
return IndexRange(this->size());
}
/** \} */
/* -------------------------------------------------------------------- */
/** \name #GVArray
* \{ */
GVArray::GVArray(const GVArray &other) = default;
GVArray::GVArray(GVArray &&other) noexcept = default;
GVArray::GVArray(const GVArrayImpl *impl) : GVArrayCommon(impl)
{
}
GVArray::GVArray(std::shared_ptr<const GVArrayImpl> impl) : GVArrayCommon(std::move(impl))
{
}
GVArray GVArray::ForSingle(const CPPType &type, const int64_t size, const void *value)
{
return GVArray::For<GVArrayImpl_For_SingleValue>(type, size, value);
}
GVArray GVArray::ForSingleRef(const CPPType &type, const int64_t size, const void *value)
{
return GVArray::For<GVArrayImpl_For_SingleValueRef_final>(type, size, value);
}
GVArray GVArray::ForSingleDefault(const CPPType &type, const int64_t size)
{
return GVArray::ForSingleRef(type, size, type.default_value());
}
GVArray GVArray::ForSpan(GSpan span)
{
return GVArray::For<GVArrayImpl_For_GSpan_final>(span);
}
class GVArrayImpl_For_GArray : public GVArrayImpl_For_GSpan {
protected:
GArray<> array_;
public:
GVArrayImpl_For_GArray(GArray<> array)
: GVArrayImpl_For_GSpan(array.as_span()), array_(std::move(array))
{
}
};
GVArray GVArray::ForGArray(GArray<> array)
{
return GVArray::For<GVArrayImpl_For_GArray>(array);
}
GVArray GVArray::ForEmpty(const CPPType &type)
{
return GVArray::ForSpan(GSpan(type));
}
GVArray GVArray::slice(IndexRange slice) const
{
return GVArray::For<GVArrayImpl_For_SlicedGVArray>(*this, slice);
}
GVArray &GVArray::operator=(const GVArray &other)
{
this->copy_from(other);
return *this;
}
GVArray &GVArray::operator=(GVArray &&other) noexcept
{
this->move_from(std::move(other));
return *this;
}
/** \} */
/* -------------------------------------------------------------------- */
/** \name #GVMutableArray
* \{ */
GVMutableArray::GVMutableArray(const GVMutableArray &other) = default;
GVMutableArray::GVMutableArray(GVMutableArray &&other) noexcept = default;
GVMutableArray::GVMutableArray(GVMutableArrayImpl *impl) : GVArrayCommon(impl)
{
}
GVMutableArray::GVMutableArray(std::shared_ptr<GVMutableArrayImpl> impl)
: GVArrayCommon(std::move(impl))
{
}
GVMutableArray GVMutableArray::ForSpan(GMutableSpan span)
{
return GVMutableArray::For<GVMutableArrayImpl_For_GMutableSpan_final>(span);
}
GVMutableArray::operator GVArray() const &
{
GVArray varray;
varray.copy_from(*this);
return varray;
}
GVMutableArray::operator GVArray() &&noexcept
{
GVArray varray;
varray.move_from(std::move(*this));
return varray;
}
GVMutableArray &GVMutableArray::operator=(const GVMutableArray &other)
{
this->copy_from(other);
return *this;
}
GVMutableArray &GVMutableArray::operator=(GVMutableArray &&other) noexcept
{
this->move_from(std::move(other));
return *this;
}
GVMutableArrayImpl *GVMutableArray::get_implementation() const
{
return this->get_impl();
}
/* Copy the values from the source buffer to all elements in the virtual array. */
void GVMutableArray::set_all(const void *src)
{
this->get_impl()->set_all(src);
}
GMutableSpan GVMutableArray::get_internal_span() const
{
BLI_assert(this->is_span());
const GSpan span = impl_->get_internal_span();
return GMutableSpan(span.type(), const_cast<void *>(span.data()), span.size());
}
/** \} */
} // namespace blender::fn
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