#pragma once
/*
* Copyright (C) 2024 Brett Terpstra
*
* 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 3 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, see <https://www.gnu.org/licenses/>.
*/
#ifndef BLT_GP_TREE_H
#define BLT_GP_TREE_H
#include <blt/gp/util/meta.h>
#include <blt/gp/typesystem.h>
#include <blt/gp/stack.h>
#include <blt/gp/fwdecl.h>
#include <blt/std/types.h>
#include <utility>
#include <stack>
#include <ostream>
#include <atomic>
namespace blt::gp
{
struct op_container_t
{
op_container_t(const size_t type_size, const operator_id id, const bool is_value):
m_type_size(type_size), m_id(id), m_is_value(is_value), m_has_drop(false)
{
}
op_container_t(const size_t type_size, const operator_id id, const bool is_value, const bool has_drop):
m_type_size(type_size), m_id(id), m_is_value(is_value), m_has_drop(has_drop)
{
}
[[nodiscard]] auto type_size() const
{
return m_type_size;
}
[[nodiscard]] auto id() const
{
return m_id;
}
[[nodiscard]] auto is_value() const
{
return m_is_value;
}
[[nodiscard]] bool has_drop() const
{
return m_has_drop;
}
private:
size_t m_type_size;
operator_id m_id;
bool m_is_value;
bool m_has_drop;
};
class evaluation_context
{
public:
explicit evaluation_context() = default;
blt::gp::stack_allocator values;
};
class tree_t
{
public:
explicit tree_t(gp_program& program);
tree_t(const tree_t& copy): func(copy.func)
{
copy_fast(copy);
}
tree_t& operator=(const tree_t& copy)
{
if (this == ©)
return *this;
copy_fast(copy);
return *this;
}
/**
* This function copies the data from the provided tree, will attempt to reserve and copy in one step.
* will avoid reallocation if enough space is already present.
*
* This function is meant to copy into and replaces data inside the tree.
*/
void copy_fast(const tree_t& copy)
{
if (this == ©)
return;
operations.reserve(copy.operations.size());
auto copy_it = copy.operations.begin();
auto op_it = operations.begin();
for (; op_it != operations.end(); ++op_it)
{
if (op_it->has_drop())
{
}
if (copy_it == copy.operations.end())
break;
*op_it = *copy_it;
if (copy_it->has_drop())
{
}
++copy_it;
}
const auto op_it_cpy = op_it;
for (; op_it != operations.end(); ++op_it)
{
if (op_it->has_drop())
{
}
}
operations.erase(op_it_cpy, operations.end());
for (; copy_it != copy.operations.end(); ++copy_it)
operations.emplace_back(*copy_it);
values.reserve(copy.values.stored());
values.reset();
values.insert(copy.values);
}
tree_t(tree_t&& move) = default;
tree_t& operator=(tree_t&& move) = default;
void clear(gp_program& program);
struct child_t
{
ptrdiff_t start;
// one past the end
ptrdiff_t end;
};
void insert_operator(const op_container_t& container)
{
operations.emplace_back(container);
}
template <typename... Args>
void emplace_operator(Args&&... args)
{
operations.emplace_back(std::forward<Args>(args)...);
}
[[nodiscard]] inline tracked_vector<op_container_t>& get_operations()
{
return operations;
}
[[nodiscard]] inline const tracked_vector<op_container_t>& get_operations() const
{
return operations;
}
[[nodiscard]] inline stack_allocator& get_values()
{
return values;
}
[[nodiscard]] inline const blt::gp::stack_allocator& get_values() const
{
return values;
}
template <typename T, std::enable_if_t<!(std::is_pointer_v<T> || std::is_null_pointer_v<T>), bool> = true>
[[nodiscard]] evaluation_context& evaluate(const T& context) const
{
return (*func)(*this, const_cast<void*>(static_cast<const void*>(&context)));
}
[[nodiscard]] evaluation_context& evaluate() const
{
return (*func)(*this, nullptr);
}
blt::size_t get_depth(gp_program& program) const;
/**
* Helper template for returning the result of the last evaluation
*/
template <typename T>
T get_evaluation_value(evaluation_context& context) const
{
return context.values.pop<T>();
}
/**
* Helper template for returning the result of the last evaluation
*/
template <typename T>
T& get_evaluation_ref(evaluation_context& context) const
{
return context.values.from<T>(0);
}
/**
* Helper template for returning the result of evaluation (this calls it)
*/
template <typename T, typename Context>
T get_evaluation_value(const Context& context) const
{
return evaluate(context).values.template pop<T>();
}
template <typename T>
T get_evaluation_value() const
{
return evaluate().values.pop<T>();
}
void print(gp_program& program, std::ostream& output, bool print_literals = true, bool pretty_indent = false,
bool include_types = false) const;
bool check(gp_program& program, void* context) const;
void find_child_extends(gp_program& program, tracked_vector<child_t>& vec, blt::size_t parent_node, blt::size_t argc) const;
// places one past the end of the child. so it's [start, end)
blt::ptrdiff_t find_endpoint(blt::gp::gp_program& program, blt::ptrdiff_t start) const;
blt::ptrdiff_t find_parent(blt::gp::gp_program& program, blt::ptrdiff_t start) const;
// valid for [begin, end)
static size_t total_value_bytes(const detail::const_op_iter_t begin, const detail::const_op_iter_t end)
{
size_t total = 0;
for (auto it = begin; it != end; ++it)
{
if (it->is_value())
total += it->type_size();
}
return total;
}
[[nodiscard]] size_t total_value_bytes(const size_t begin, const size_t end) const
{
return total_value_bytes(operations.begin() + static_cast<blt::ptrdiff_t>(begin),
operations.begin() + static_cast<blt::ptrdiff_t>(end));
}
[[nodiscard]] size_t total_value_bytes(const size_t begin) const
{
return total_value_bytes(operations.begin() + static_cast<blt::ptrdiff_t>(begin), operations.end());
}
[[nodiscard]] size_t total_value_bytes() const
{
return total_value_bytes(operations.begin(), operations.end());
}
template <typename Context, typename... Operators>
static auto make_execution_lambda(size_t call_reserve_size, Operators&... operators)
{
return [call_reserve_size, &operators...](const tree_t& tree, void* context) -> evaluation_context& {
const auto& ops = tree.operations;
const auto& vals = tree.values;
thread_local evaluation_context results{};
results.values.reset();
results.values.reserve(call_reserve_size);
size_t total_so_far = 0;
for (const auto& operation : iterate(ops).rev())
{
if (operation.is_value())
{
total_so_far += operation.type_size();
results.values.copy_from(vals.from(total_so_far), operation.type_size());
continue;
}
call_jmp_table<Context>(operation.id(), context, results.values, results.values, operators...);
}
return results;
};
}
private:
template <typename Context, typename Operator>
static void execute(void* context, stack_allocator& write_stack, stack_allocator& read_stack, Operator& operation)
{
if constexpr (std::is_same_v<detail::remove_cv_ref<typename Operator::First_Arg>, Context>)
{
write_stack.push(operation(context, read_stack));
}
else
{
write_stack.push(operation(read_stack));
}
}
template <typename Context, size_t id, typename Operator>
static bool call(const size_t op, void* context, stack_allocator& write_stack, stack_allocator& read_stack, Operator& operation)
{
if (id == op)
{
execute<Context>(context, write_stack, read_stack, operation);
return false;
}
return true;
}
template <typename Context, typename... Operators, size_t... operator_ids>
static void call_jmp_table_internal(size_t op, void* context, stack_allocator& write_stack, stack_allocator& read_stack,
std::integer_sequence<size_t, operator_ids...>, Operators&... operators)
{
if (op >= sizeof...(operator_ids))
{
BLT_UNREACHABLE;
}
(call<Context, operator_ids>(op, context, write_stack, read_stack, operators) && ...);
}
template <typename Context, typename... Operators>
static void call_jmp_table(size_t op, void* context, stack_allocator& write_stack, stack_allocator& read_stack,
Operators&... operators)
{
call_jmp_table_internal<Context>(op, context, write_stack, read_stack, std::index_sequence_for<Operators...>(), operators...);
}
tracked_vector<op_container_t> operations;
stack_allocator values;
detail::eval_func_t* func;
};
struct fitness_t
{
double raw_fitness = 0;
double standardized_fitness = 0;
double adjusted_fitness = 0;
i64 hits = 0;
};
struct individual_t
{
tree_t tree;
fitness_t fitness;
void copy_fast(const tree_t& copy)
{
// fast copy of the tree
tree.copy_fast(copy);
// reset fitness
fitness = {};
}
individual_t() = delete;
explicit individual_t(tree_t&& tree): tree(std::move(tree))
{
}
explicit individual_t(const tree_t& tree): tree(tree)
{
}
individual_t(const individual_t&) = default;
individual_t(individual_t&&) = default;
individual_t& operator=(const individual_t&) = delete;
individual_t& operator=(individual_t&&) = default;
};
class population_t
{
public:
class population_tree_iterator
{
public:
population_tree_iterator(tracked_vector<individual_t>& ind, blt::size_t pos): ind(ind), pos(pos)
{
}
auto begin()
{
return population_tree_iterator(ind, 0);
}
auto end()
{
return population_tree_iterator(ind, ind.size());
}
population_tree_iterator operator++(int)
{
auto prev = pos++;
return {ind, prev};
}
population_tree_iterator operator++()
{
return {ind, ++pos};
}
tree_t& operator*()
{
return ind[pos].tree;
}
tree_t& operator->()
{
return ind[pos].tree;
}
friend bool operator==(population_tree_iterator a, population_tree_iterator b)
{
return a.pos == b.pos;
}
friend bool operator!=(population_tree_iterator a, population_tree_iterator b)
{
return a.pos != b.pos;
}
private:
tracked_vector<individual_t>& ind;
blt::size_t pos;
};
tracked_vector<individual_t>& get_individuals()
{
return individuals;
}
[[nodiscard]] const tracked_vector<individual_t>& get_individuals() const
{
return individuals;
}
population_tree_iterator for_each_tree()
{
return population_tree_iterator{individuals, 0};
}
auto begin()
{
return individuals.begin();
}
auto end()
{
return individuals.end();
}
[[nodiscard]] auto begin() const
{
return individuals.begin();
}
[[nodiscard]] auto end() const
{
return individuals.end();
}
void clear()
{
individuals.clear();
}
population_t() = default;
population_t(const population_t&) = default;
population_t(population_t&&) = default;
population_t& operator=(const population_t&) = delete;
population_t& operator=(population_t&&) = default;
private:
tracked_vector<individual_t> individuals;
};
}
#endif //BLT_GP_TREE_H