blender-archive/source/blender/blenlib/BLI_generic_span.hh

/* SPDX-License-Identifier: GPL-2.0-or-later */

#pragma once

/** \file
 * \ingroup bli
 */

#include "BLI_cpp_type.hh"
#include "BLI_span.hh"

namespace blender {

/**
 * A generic span. It behaves just like a blender::Span<T>, but the type is only known at run-time.
 */
class GSpan {
 protected:
  const CPPType *type_;
  const void *data_;
  int64_t size_;

 public:
  GSpan(const CPPType &type, const void *buffer, int64_t size)
      : type_(&type), data_(buffer), size_(size)
  {
    BLI_assert(size >= 0);
    BLI_assert(buffer != nullptr || size == 0);
    BLI_assert(type.pointer_has_valid_alignment(buffer));
  }

  GSpan(const CPPType &type) : GSpan(type, nullptr, 0)
  {
  }

  template<typename T>
  GSpan(Span<T> array)
      : GSpan(CPPType::get<T>(), static_cast<const void *>(array.data()), array.size())
  {
  }

  const CPPType &type() const
  {
    return *type_;
  }

  bool is_empty() const
  {
    return size_ == 0;
  }

  int64_t size() const
  {
    return size_;
  }

  const void *data() const
  {
    return data_;
  }

  const void *operator[](int64_t index) const
  {
    BLI_assert(index < size_);
    return POINTER_OFFSET(data_, type_->size() * index);
  }

  template<typename T> Span<T> typed() const
  {
    BLI_assert(type_->is<T>());
    return Span<T>(static_cast<const T *>(data_), size_);
  }

  GSpan slice(const int64_t start, int64_t size) const
  {
    BLI_assert(start >= 0);
    BLI_assert(size >= 0);
    const int64_t new_size = std::max<int64_t>(0, std::min(size, size_ - start));
    return GSpan(*type_, POINTER_OFFSET(data_, type_->size() * start), new_size);
  }

  GSpan slice(const IndexRange range) const
  {
    return this->slice(range.start(), range.size());
  }
};

/**
 * A generic mutable span. It behaves just like a blender::MutableSpan<T>, but the type is only
 * known at run-time.
 */
class GMutableSpan {
 protected:
  const CPPType *type_;
  void *data_;
  int64_t size_;

 public:
  GMutableSpan(const CPPType &type, void *buffer, int64_t size)
      : type_(&type), data_(buffer), size_(size)
  {
    BLI_assert(size >= 0);
    BLI_assert(buffer != nullptr || size == 0);
    BLI_assert(type.pointer_has_valid_alignment(buffer));
  }

  GMutableSpan(const CPPType &type) : GMutableSpan(type, nullptr, 0)
  {
  }

  template<typename T>
  GMutableSpan(MutableSpan<T> array)
      : GMutableSpan(CPPType::get<T>(), static_cast<void *>(array.begin()), array.size())
  {
  }

  operator GSpan() const
  {
    return GSpan(*type_, data_, size_);
  }

  const CPPType &type() const
  {
    return *type_;
  }

  bool is_empty() const
  {
    return size_ == 0;
  }

  int64_t size() const
  {
    return size_;
  }

  void *data() const
  {
    return data_;
  }

  void *operator[](int64_t index) const
  {
    BLI_assert(index >= 0);
    BLI_assert(index < size_);
    return POINTER_OFFSET(data_, type_->size() * index);
  }

  template<typename T> MutableSpan<T> typed() const
  {
    BLI_assert(type_->is<T>());
    return MutableSpan<T>(static_cast<T *>(data_), size_);
  }

  GMutableSpan slice(const int64_t start, int64_t size) const
  {
    BLI_assert(start >= 0);
    BLI_assert(size >= 0);
    const int64_t new_size = std::max<int64_t>(0, std::min(size, size_ - start));
    return GMutableSpan(*type_, POINTER_OFFSET(data_, type_->size() * start), new_size);
  }

  GMutableSpan slice(IndexRange range) const
  {
    return this->slice(range.start(), range.size());
  }

  /**
   * Copy all values from another span into this span. This invokes undefined behavior when the
   * destination contains uninitialized data and T is not trivially copy constructible.
   * The size of both spans is expected to be the same.
   */
  void copy_from(GSpan values)
  {
    BLI_assert(type_ == &values.type());
    BLI_assert(size_ == values.size());
    type_->copy_assign_n(values.data(), data_, size_);
  }
};

}  // namespace blender
File headers: SPDX License migration Use a shorter/simpler license convention, stops the header taking so much space. Follow the SPDX license specification: https://spdx.org/licenses - C/C++/objc/objc++ - Python - Shell Scripts - CMake, GNUmakefile While most of the source tree has been included - `./extern/` was left out. - `./intern/cycles` & `./intern/atomic` are also excluded because they use different header conventions. doc/license/SPDX-license-identifiers.txt has been added to list SPDX all used identifiers. See P2788 for the script that automated these edits. Reviewed By: brecht, mont29, sergey Ref D14069 2022-02-11 09:07:11 +11:00			`/* SPDX-License-Identifier: GPL-2.0-or-later */`
Functions: refactor virtual array data structures When a function is executed for many elements (e.g. per point) it is often the case that some parameters are different for every element and other parameters are the same (there are some more less common cases). To simplify writing such functions one can use a "virtual array". This is a data structure that has a value for every index, but might not be stored as an actual array internally. Instead, it might be just a single value or is computed on the fly. There are various tradeoffs involved when using this data structure which are mentioned in `BLI_virtual_array.hh`. It is called "virtual", because it uses inheritance and virtual methods. Furthermore, there is a new virtual vector array data structure, which is an array of vectors. Both these types have corresponding generic variants, which can be used when the data type is not known at compile time. This is typically the case when building a somewhat generic execution system. The function system used these virtual data structures before, but now they are more versatile. I've done this refactor in preparation for the attribute processor and other features of geometry nodes. I moved the typed virtual arrays to blenlib, so that they can be used independent of the function system. One open question for me is whether all the generic data structures (and `CPPType`) should be moved to blenlib as well. They are well isolated and don't really contain any business logic. That can be done later if necessary. 2021-03-21 19:31:24 +01:00
			`#pragma once`

			`/** \file`
BLI: move generic data structures to blenlib This is a follow up to rB2252bc6a5527cd7360d1ccfe7a2d1bc640a8dfa6. 2022-03-19 08:26:29 +01:00			`* \ingroup bli`
Functions: refactor virtual array data structures When a function is executed for many elements (e.g. per point) it is often the case that some parameters are different for every element and other parameters are the same (there are some more less common cases). To simplify writing such functions one can use a "virtual array". This is a data structure that has a value for every index, but might not be stored as an actual array internally. Instead, it might be just a single value or is computed on the fly. There are various tradeoffs involved when using this data structure which are mentioned in `BLI_virtual_array.hh`. It is called "virtual", because it uses inheritance and virtual methods. Furthermore, there is a new virtual vector array data structure, which is an array of vectors. Both these types have corresponding generic variants, which can be used when the data type is not known at compile time. This is typically the case when building a somewhat generic execution system. The function system used these virtual data structures before, but now they are more versatile. I've done this refactor in preparation for the attribute processor and other features of geometry nodes. I moved the typed virtual arrays to blenlib, so that they can be used independent of the function system. One open question for me is whether all the generic data structures (and `CPPType`) should be moved to blenlib as well. They are well isolated and don't really contain any business logic. That can be done later if necessary. 2021-03-21 19:31:24 +01:00			`*/`

BLI: move CPPType to blenlib For more detail about `CPPType`, see `BLI_cpp_type.hh` and D14367. Differential Revision: https://developer.blender.org/D14367 2022-03-18 10:57:45 +01:00			`#include "BLI_cpp_type.hh"`
Functions: refactor virtual array data structures When a function is executed for many elements (e.g. per point) it is often the case that some parameters are different for every element and other parameters are the same (there are some more less common cases). To simplify writing such functions one can use a "virtual array". This is a data structure that has a value for every index, but might not be stored as an actual array internally. Instead, it might be just a single value or is computed on the fly. There are various tradeoffs involved when using this data structure which are mentioned in `BLI_virtual_array.hh`. It is called "virtual", because it uses inheritance and virtual methods. Furthermore, there is a new virtual vector array data structure, which is an array of vectors. Both these types have corresponding generic variants, which can be used when the data type is not known at compile time. This is typically the case when building a somewhat generic execution system. The function system used these virtual data structures before, but now they are more versatile. I've done this refactor in preparation for the attribute processor and other features of geometry nodes. I moved the typed virtual arrays to blenlib, so that they can be used independent of the function system. One open question for me is whether all the generic data structures (and `CPPType`) should be moved to blenlib as well. They are well isolated and don't really contain any business logic. That can be done later if necessary. 2021-03-21 19:31:24 +01:00			`#include "BLI_span.hh"`

BLI: move generic data structures to blenlib This is a follow up to rB2252bc6a5527cd7360d1ccfe7a2d1bc640a8dfa6. 2022-03-19 08:26:29 +01:00			`namespace blender {`
Functions: refactor virtual array data structures When a function is executed for many elements (e.g. per point) it is often the case that some parameters are different for every element and other parameters are the same (there are some more less common cases). To simplify writing such functions one can use a "virtual array". This is a data structure that has a value for every index, but might not be stored as an actual array internally. Instead, it might be just a single value or is computed on the fly. There are various tradeoffs involved when using this data structure which are mentioned in `BLI_virtual_array.hh`. It is called "virtual", because it uses inheritance and virtual methods. Furthermore, there is a new virtual vector array data structure, which is an array of vectors. Both these types have corresponding generic variants, which can be used when the data type is not known at compile time. This is typically the case when building a somewhat generic execution system. The function system used these virtual data structures before, but now they are more versatile. I've done this refactor in preparation for the attribute processor and other features of geometry nodes. I moved the typed virtual arrays to blenlib, so that they can be used independent of the function system. One open question for me is whether all the generic data structures (and `CPPType`) should be moved to blenlib as well. They are well isolated and don't really contain any business logic. That can be done later if necessary. 2021-03-21 19:31:24 +01:00
			`/**`
			`* A generic span. It behaves just like a blender::Span<T>, but the type is only known at run-time.`
			`*/`
			`class GSpan {`
Functions: extend virtual array functionality This adds support for mutable virtual arrays and provides many utilities for creating virtual arrays for various kinds of data. This commit is preparation for D10994. 2021-04-17 15:13:20 +02:00			`protected:`
Functions: refactor virtual array data structures When a function is executed for many elements (e.g. per point) it is often the case that some parameters are different for every element and other parameters are the same (there are some more less common cases). To simplify writing such functions one can use a "virtual array". This is a data structure that has a value for every index, but might not be stored as an actual array internally. Instead, it might be just a single value or is computed on the fly. There are various tradeoffs involved when using this data structure which are mentioned in `BLI_virtual_array.hh`. It is called "virtual", because it uses inheritance and virtual methods. Furthermore, there is a new virtual vector array data structure, which is an array of vectors. Both these types have corresponding generic variants, which can be used when the data type is not known at compile time. This is typically the case when building a somewhat generic execution system. The function system used these virtual data structures before, but now they are more versatile. I've done this refactor in preparation for the attribute processor and other features of geometry nodes. I moved the typed virtual arrays to blenlib, so that they can be used independent of the function system. One open question for me is whether all the generic data structures (and `CPPType`) should be moved to blenlib as well. They are well isolated and don't really contain any business logic. That can be done later if necessary. 2021-03-21 19:31:24 +01:00			`const CPPType *type_;`
			`const void *data_;`
			`int64_t size_;`

			`public:`
			`GSpan(const CPPType &type, const void *buffer, int64_t size)`
			`: type_(&type), data_(buffer), size_(size)`
			`{`
			`BLI_assert(size >= 0);`
			`BLI_assert(buffer != nullptr \|\| size == 0);`
			`BLI_assert(type.pointer_has_valid_alignment(buffer));`
			`}`

			`GSpan(const CPPType &type) : GSpan(type, nullptr, 0)`
			`{`
			`}`

			`template<typename T>`
			`GSpan(Span<T> array)`
			`: GSpan(CPPType::get<T>(), static_cast<const void *>(array.data()), array.size())`
			`{`
			`}`

			`const CPPType &type() const`
			`{`
			`return *type_;`
			`}`

			`bool is_empty() const`
			`{`
			`return size_ == 0;`
			`}`

			`int64_t size() const`
			`{`
			`return size_;`
			`}`

			`const void *data() const`
			`{`
			`return data_;`
			`}`

			`const void *operator[](int64_t index) const`
			`{`
			`BLI_assert(index < size_);`
			`return POINTER_OFFSET(data_, type_->size() * index);`
			`}`

			`template<typename T> Span<T> typed() const`
			`{`
			`BLI_assert(type_->is<T>());`
			`return Span<T>(static_cast<const T *>(data_), size_);`
			`}`
Functions: add slice method for generic spans 2021-04-21 16:59:22 +02:00
			`GSpan slice(const int64_t start, int64_t size) const`
			`{`
			`BLI_assert(start >= 0);`
			`BLI_assert(size >= 0);`
			`const int64_t new_size = std::max<int64_t>(0, std::min(size, size_ - start));`
			`return GSpan(type_, POINTER_OFFSET(data_, type_->size() start), new_size);`
			`}`
BLI: add slice method to index mask and generic span 2021-11-24 17:49:33 +01:00
			`GSpan slice(const IndexRange range) const`
			`{`
			`return this->slice(range.start(), range.size());`
			`}`
Functions: refactor virtual array data structures When a function is executed for many elements (e.g. per point) it is often the case that some parameters are different for every element and other parameters are the same (there are some more less common cases). To simplify writing such functions one can use a "virtual array". This is a data structure that has a value for every index, but might not be stored as an actual array internally. Instead, it might be just a single value or is computed on the fly. There are various tradeoffs involved when using this data structure which are mentioned in `BLI_virtual_array.hh`. It is called "virtual", because it uses inheritance and virtual methods. Furthermore, there is a new virtual vector array data structure, which is an array of vectors. Both these types have corresponding generic variants, which can be used when the data type is not known at compile time. This is typically the case when building a somewhat generic execution system. The function system used these virtual data structures before, but now they are more versatile. I've done this refactor in preparation for the attribute processor and other features of geometry nodes. I moved the typed virtual arrays to blenlib, so that they can be used independent of the function system. One open question for me is whether all the generic data structures (and `CPPType`) should be moved to blenlib as well. They are well isolated and don't really contain any business logic. That can be done later if necessary. 2021-03-21 19:31:24 +01:00			`};`

			`/**`
			`* A generic mutable span. It behaves just like a blender::MutableSpan<T>, but the type is only`
			`* known at run-time.`
			`*/`
			`class GMutableSpan {`
Functions: extend virtual array functionality This adds support for mutable virtual arrays and provides many utilities for creating virtual arrays for various kinds of data. This commit is preparation for D10994. 2021-04-17 15:13:20 +02:00			`protected:`
Functions: refactor virtual array data structures When a function is executed for many elements (e.g. per point) it is often the case that some parameters are different for every element and other parameters are the same (there are some more less common cases). To simplify writing such functions one can use a "virtual array". This is a data structure that has a value for every index, but might not be stored as an actual array internally. Instead, it might be just a single value or is computed on the fly. There are various tradeoffs involved when using this data structure which are mentioned in `BLI_virtual_array.hh`. It is called "virtual", because it uses inheritance and virtual methods. Furthermore, there is a new virtual vector array data structure, which is an array of vectors. Both these types have corresponding generic variants, which can be used when the data type is not known at compile time. This is typically the case when building a somewhat generic execution system. The function system used these virtual data structures before, but now they are more versatile. I've done this refactor in preparation for the attribute processor and other features of geometry nodes. I moved the typed virtual arrays to blenlib, so that they can be used independent of the function system. One open question for me is whether all the generic data structures (and `CPPType`) should be moved to blenlib as well. They are well isolated and don't really contain any business logic. That can be done later if necessary. 2021-03-21 19:31:24 +01:00			`const CPPType *type_;`
			`void *data_;`
			`int64_t size_;`

			`public:`
			`GMutableSpan(const CPPType &type, void *buffer, int64_t size)`
			`: type_(&type), data_(buffer), size_(size)`
			`{`
			`BLI_assert(size >= 0);`
			`BLI_assert(buffer != nullptr \|\| size == 0);`
			`BLI_assert(type.pointer_has_valid_alignment(buffer));`
			`}`

			`GMutableSpan(const CPPType &type) : GMutableSpan(type, nullptr, 0)`
			`{`
			`}`

			`template<typename T>`
			`GMutableSpan(MutableSpan<T> array)`
			`: GMutableSpan(CPPType::get<T>(), static_cast<void *>(array.begin()), array.size())`
			`{`
			`}`

			`operator GSpan() const`
			`{`
			`return GSpan(*type_, data_, size_);`
			`}`

			`const CPPType &type() const`
			`{`
			`return *type_;`
			`}`

			`bool is_empty() const`
			`{`
			`return size_ == 0;`
			`}`

			`int64_t size() const`
			`{`
			`return size_;`
			`}`

			`void *data() const`
			`{`
			`return data_;`
			`}`

			`void *operator[](int64_t index) const`
			`{`
			`BLI_assert(index >= 0);`
			`BLI_assert(index < size_);`
			`return POINTER_OFFSET(data_, type_->size() * index);`
			`}`

			`template<typename T> MutableSpan<T> typed() const`
			`{`
			`BLI_assert(type_->is<T>());`
			`return MutableSpan<T>(static_cast<T *>(data_), size_);`
			`}`
Functions: add slice method for generic spans 2021-04-21 16:59:22 +02:00
			`GMutableSpan slice(const int64_t start, int64_t size) const`
			`{`
			`BLI_assert(start >= 0);`
			`BLI_assert(size >= 0);`
			`const int64_t new_size = std::max<int64_t>(0, std::min(size, size_ - start));`
			`return GMutableSpan(type_, POINTER_OFFSET(data_, type_->size() start), new_size);`
			`}`
BLI: add slice method to index mask and generic span 2021-11-24 17:49:33 +01:00
			`GMutableSpan slice(IndexRange range) const`
			`{`
			`return this->slice(range.start(), range.size());`
			`}`
Curves: Port resample node to the new data-block This commit re-implements the resample curve node to use the new curves type instead of CurveEval. The largest changes come from the need to keep track of offsets into the point attribute arrays, and the fact that the attributes for all curves are stored in a flat array. Another difference is that a bit more of the logic is handled by building of the field network inputs. The idea is to let the field evaluator handle potential optimizations while making the rest of the code simpler. When resampling 1 million small poly curves,the node is about 6 times faster compared to 3.1 on my hardware (500ms to 80ms). This also adds support for Catmull Rom curve inputs. Differential Revision: https://developer.blender.org/D14435 2022-03-30 10:37:39 -05:00
			`/**`
			`* Copy all values from another span into this span. This invokes undefined behavior when the`
			`* destination contains uninitialized data and T is not trivially copy constructible.`
			`* The size of both spans is expected to be the same.`
			`*/`
			`void copy_from(GSpan values)`
			`{`
			`BLI_assert(type_ == &values.type());`
			`BLI_assert(size_ == values.size());`
			`type_->copy_assign_n(values.data(), data_, size_);`
			`}`
Functions: refactor virtual array data structures When a function is executed for many elements (e.g. per point) it is often the case that some parameters are different for every element and other parameters are the same (there are some more less common cases). To simplify writing such functions one can use a "virtual array". This is a data structure that has a value for every index, but might not be stored as an actual array internally. Instead, it might be just a single value or is computed on the fly. There are various tradeoffs involved when using this data structure which are mentioned in `BLI_virtual_array.hh`. It is called "virtual", because it uses inheritance and virtual methods. Furthermore, there is a new virtual vector array data structure, which is an array of vectors. Both these types have corresponding generic variants, which can be used when the data type is not known at compile time. This is typically the case when building a somewhat generic execution system. The function system used these virtual data structures before, but now they are more versatile. I've done this refactor in preparation for the attribute processor and other features of geometry nodes. I moved the typed virtual arrays to blenlib, so that they can be used independent of the function system. One open question for me is whether all the generic data structures (and `CPPType`) should be moved to blenlib as well. They are well isolated and don't really contain any business logic. That can be done later if necessary. 2021-03-21 19:31:24 +01:00			`};`

BLI: move generic data structures to blenlib This is a follow up to rB2252bc6a5527cd7360d1ccfe7a2d1bc640a8dfa6. 2022-03-19 08:26:29 +01:00			`} // namespace blender`