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rpcs3/Utilities/Config.h

639 lines
12 KiB
C++

#pragma once
#include "util/types.hpp"
#include "Utilities/StrUtil.h"
#include "util/logs.hpp"
#include "util/atomic.hpp"
#include "util/shared_ptr.hpp"
#include <utility>
#include <string>
#include <vector>
#include <set>
#include <map>
namespace cfg
{
// Format min and max values
std::vector<std::string> make_int_range(s64 min, s64 max);
// Format min and max unsigned values
std::vector<std::string> make_uint_range(u64 min, u64 max);
// Format min and max float values
std::vector<std::string> make_float_range(f64 min, f64 max);
// Internal hack
bool try_to_enum_value(u64* out, decltype(&fmt_class_string<int>::format) func, std::string_view);
// Internal hack
std::vector<std::string> try_to_enum_list(decltype(&fmt_class_string<int>::format) func);
// Config tree entry type.
enum class type : unsigned
{
node = 0, // cfg::node type
_bool, // cfg::_bool type
_enum, // cfg::_enum type
_int, // cfg::_int type
uint, // cfg::uint type
string, // cfg::string type
set, // cfg::set_entry type
map, // cfg::map_entry type
log, // cfg::log_entry type
device, // cfg::device_entry type
};
// Config tree entry abstract base class
class _base
{
const type m_type{};
protected:
bool m_dynamic = true;
const std::string m_name{};
// Ownerless entry constructor
_base(type _type);
// Owned entry constructor
_base(type _type, class node* owner, std::string name, bool dynamic);
public:
_base(const _base&) = delete;
_base& operator=(const _base&) = delete;
virtual ~_base() = default;
// Get type
type get_type() const { return m_type; }
const std::string& get_name() const { return m_name; }
// Get dynamic property for reloading configs during games
bool get_is_dynamic() const { return m_dynamic; }
// Reset defaults
virtual void from_default() = 0;
// Convert to string (optional)
virtual std::string to_string() const
{
return{};
}
// Try to convert from string (optional)
virtual bool from_string(std::string_view, bool /*dynamic*/ = false);
// Get string list (optional)
virtual std::vector<std::string> to_list() const
{
return{};
}
// Set multiple values. Implementation-specific, optional.
virtual bool from_list(std::vector<std::string>&&);
};
// Config tree node which contains another nodes
class node : public _base
{
std::vector<_base*> m_nodes{};
friend class _base;
public:
// Root node constructor
node()
: _base(type::node)
{
}
// Registered node constructor
node(node* owner, std::string name, bool dynamic = true)
: _base(type::node, owner, std::move(name), dynamic)
{
}
// Get child nodes
const auto& get_nodes() const
{
return m_nodes;
}
// Serialize node
std::string to_string() const override;
// Deserialize node
bool from_string(std::string_view value, bool dynamic = false) override;
// Set default values
void from_default() override;
};
class _bool final : public _base
{
atomic_t<bool> m_value;
public:
bool def;
_bool(node* owner, std::string name, bool def = false, bool dynamic = false)
: _base(type::_bool, owner, std::move(name), dynamic)
, m_value(def)
, def(def)
{
}
explicit operator bool() const
{
return m_value;
}
bool get() const
{
return m_value;
}
void from_default() override;
std::string to_string() const override
{
return m_value ? "true" : "false";
}
bool from_string(std::string_view value, bool /*dynamic*/ = false) override
{
if (value.size() != 4 && value.size() != 5)
{
return false;
}
char copy[5];
std::transform(value.begin(), value.end(), std::begin(copy), ::tolower);
if (value.size() == 5 && std::string_view{copy, 5} == "false")
m_value = false;
else if (value.size() == 4 && std::string_view{copy, 4} == "true")
m_value = true;
else
return false;
return true;
}
void set(const bool& value)
{
m_value = value;
}
};
// Value node with fixed set of possible values, each maps to an enum value of type T.
template <typename T>
class _enum : public _base
{
atomic_t<T> m_value;
public:
const T def;
_enum(node* owner, const std::string& name, T value = {}, bool dynamic = false)
: _base(type::_enum, owner, name, dynamic)
, m_value(value)
, def(value)
{
}
operator T() const
{
return m_value;
}
T get() const
{
return m_value;
}
void set(T value)
{
m_value = value;
}
void from_default() override
{
m_value = def;
}
std::string to_string() const override
{
std::string result;
fmt_class_string<T>::format(result, fmt_unveil<T>::get(m_value.load()));
return result; // TODO: ???
}
bool from_string(std::string_view value, bool /*dynamic*/ = false) override
{
u64 result;
if (try_to_enum_value(&result, &fmt_class_string<T>::format, value))
{
// No narrowing check, it's hard to do right there
m_value = static_cast<T>(static_cast<std::underlying_type_t<T>>(result));
return true;
}
return false;
}
std::vector<std::string> to_list() const override
{
return try_to_enum_list(&fmt_class_string<T>::format);
}
};
// Signed 32/64-bit integer entry with custom Min/Max range.
template <s64 Min, s64 Max>
class _int final : public _base
{
static_assert(Min < Max, "Invalid cfg::_int range");
// Prefer 32 bit type if possible
using int_type = std::conditional_t<Min >= s32{smin} && Max <= s32{smax}, s32, s64>;
atomic_t<int_type> m_value;
public:
int_type def;
// Expose range
static const s64 max = Max;
static const s64 min = Min;
_int(node* owner, const std::string& name, int_type def = std::min<int_type>(Max, std::max<int_type>(Min, 0)), bool dynamic = false)
: _base(type::_int, owner, name, dynamic)
, m_value(def)
, def(def)
{
}
operator int_type() const
{
return m_value;
}
int_type get() const
{
return m_value;
}
void from_default() override
{
m_value = def;
}
std::string to_string() const override
{
return std::to_string(m_value);
}
bool from_string(std::string_view value, bool /*dynamic*/ = false) override
{
s64 result;
if (try_to_int64(&result, value, Min, Max))
{
m_value = static_cast<int_type>(result);
return true;
}
return false;
}
void set(const s64& value)
{
m_value = static_cast<int_type>(value);
}
std::vector<std::string> to_list() const override
{
return make_int_range(Min, Max);
}
};
// Float entry with custom Min/Max range.
template <s32 Min, s32 Max>
class _float final : public _base
{
static_assert(Min < Max, "Invalid cfg::_float range");
using float_type = f64;
atomic_t<float_type> m_value;
public:
float_type def;
// Expose range
static constexpr float_type max = Max;
static constexpr float_type min = Min;
_float(node* owner, const std::string& name, float_type def = std::min<float_type>(Max, std::max<float_type>(Min, 0)), bool dynamic = false)
: _base(type::_int, owner, name, dynamic)
, m_value(def)
, def(def)
{
}
operator float_type() const
{
return m_value;
}
float_type get() const
{
return m_value;
}
void from_default() override
{
m_value = def;
}
std::string to_string() const override
{
return std::to_string(m_value);
}
bool from_string(std::string_view value, bool /*dynamic*/ = false) override
{
f64 result;
if (try_to_float(&result, value, Min, Max))
{
m_value = static_cast<float_type>(result);
return true;
}
return false;
}
void set(const f64& value)
{
m_value = static_cast<float_type>(value);
}
std::vector<std::string> to_list() const override
{
return make_float_range(Min, Max);
}
};
// Alias for 32 bit int
using int32 = _int<s32{smin}, s32{smax}>;
// Alias for 64 bit int
using int64 = _int<s64{smin}, s64{smax}>;
// Unsigned 32/64-bit integer entry with custom Min/Max range.
template <u64 Min, u64 Max>
class uint final : public _base
{
static_assert(Min < Max, "Invalid cfg::uint range");
// Prefer 32 bit type if possible
using int_type = std::conditional_t<Max <= u32{umax}, u32, u64>;
atomic_t<int_type> m_value;
public:
int_type def;
// Expose range
static const u64 max = Max;
static const u64 min = Min;
uint(node* owner, const std::string& name, int_type def = std::max<int_type>(Min, 0), bool dynamic = false)
: _base(type::uint, owner, name, dynamic)
, m_value(def)
, def(def)
{
}
operator int_type() const
{
return m_value;
}
int_type get() const
{
return m_value;
}
void from_default() override
{
m_value = def;
}
std::string to_string() const override
{
return std::to_string(m_value);
}
bool from_string(std::string_view value, bool /*dynamic*/ = false) override
{
u64 result;
if (try_to_uint64(&result, value, Min, Max))
{
m_value = static_cast<int_type>(result);
return true;
}
return false;
}
void set(const u64& value)
{
m_value = static_cast<int_type>(value);
}
std::vector<std::string> to_list() const override
{
return make_uint_range(Min, Max);
}
};
// Alias for 32 bit uint
using uint32 = uint<0, u32{umax}>;
// Alias for 64 bit int
using uint64 = uint<0, u64{umax}>;
// Simple string entry with mutex
class string : public _base
{
atomic_ptr<std::string> m_value;
public:
std::string def;
string(node* owner, std::string name, std::string def = {}, bool dynamic = false)
: _base(type::string, owner, name, dynamic)
, m_value(def)
, def(std::move(def))
{
}
operator std::string() const
{
return *m_value.load().get();
}
std::pair<const std::string&, shared_ptr<std::string>> get() const
{
auto v = m_value.load();
if (auto s = v.get())
{
return {*s, std::move(v)};
}
else
{
static const std::string _empty;
return {_empty, {}};
}
}
void from_default() override;
std::string to_string() const override
{
return *m_value.load().get();
}
bool from_string(std::string_view value, bool /*dynamic*/ = false) override
{
m_value = std::string(value);
return true;
}
};
// Simple set entry (TODO: template for various types)
class set_entry final : public _base
{
std::set<std::string> m_set{};
public:
// Default value is empty list in current implementation
set_entry(node* owner, const std::string& name)
: _base(type::set, owner, name, false)
{
}
const std::set<std::string>& get_set() const
{
return m_set;
}
void set_set(std::set<std::string>&& set)
{
m_set = std::move(set);
}
void from_default() override;
std::vector<std::string> to_list() const override
{
return{ m_set.begin(), m_set.end() };
}
bool from_list(std::vector<std::string>&& list) override
{
m_set = { std::make_move_iterator(list.begin()), std::make_move_iterator(list.end()) };
return true;
}
};
template<typename T>
using map_of_type = std::map<std::string, T, std::less<>>;
class map_entry final : public _base
{
map_of_type<std::string> m_map{};
public:
map_entry(node* owner, const std::string& name)
: _base(type::map, owner, name, true)
{
}
const map_of_type<std::string>& get_map() const
{
return m_map;
}
std::string get_value(std::string_view key);
void set_value(std::string key, std::string value);
void set_map(map_of_type<std::string>&& map);
void erase(std::string_view key);
void from_default() override;
};
class log_entry final : public _base
{
map_of_type<logs::level> m_map{};
public:
log_entry(node* owner, const std::string& name)
: _base(type::log, owner, name, true)
{
}
const map_of_type<logs::level>& get_map() const
{
return m_map;
}
void set_map(map_of_type<logs::level>&& map);
void from_default() override;
};
struct device_info
{
std::string path;
std::string serial;
std::string vid;
std::string pid;
};
class device_entry final : public _base
{
map_of_type<device_info> m_map{};
map_of_type<device_info> m_default{};
public:
device_entry(node* owner, const std::string& name, map_of_type<device_info> def = {})
: _base(type::device, owner, name, true)
, m_map(std::move(def))
{
m_default = m_map;
}
const map_of_type<device_info>& get_map() const
{
return m_map;
}
const map_of_type<device_info>& get_default() const
{
return m_default;
}
void set_map(map_of_type<device_info>&& map);
void from_default() override;
};
}