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|
/**
* @file llinitparam.h
* @brief parameter block abstraction for creating complex objects and
* parsing construction parameters from xml and LLSD
*
* $LicenseInfo:firstyear=2008&license=viewerlgpl$
* Second Life Viewer Source Code
* Copyright (C) 2010, Linden Research, Inc.
*
* This library is free software; you can redistribute it and/or
* modify it under the terms of the GNU Lesser General Public
* License as published by the Free Software Foundation;
* version 2.1 of the License only.
*
* This library 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
* Lesser General Public License for more details.
*
* You should have received a copy of the GNU Lesser General Public
* License along with this library; if not, write to the Free Software
* Foundation, Inc., 51 Franklin Street, Fifth Floor, Boston, MA 02110-1301 USA
*
* Linden Research, Inc., 945 Battery Street, San Francisco, CA 94111 USA
* $/LicenseInfo$
*/
#ifndef LL_LLPARAM_H
#define LL_LLPARAM_H
#include <vector>
#include <list>
#include <boost/function.hpp>
#include <boost/type_traits/is_convertible.hpp>
#include <boost/type_traits/is_enum.hpp>
#include <boost/unordered_map.hpp>
#include "llerror.h"
#include "llstl.h"
#include "llpredicate.h"
namespace LLTypeTags
{
template <typename INNER_TYPE, int _SORT_ORDER>
struct TypeTagBase
{
typedef void is_tag_t;
typedef INNER_TYPE inner_t;
static const int SORT_ORDER=_SORT_ORDER;
};
template <int VAL1, int VAL2>
struct GreaterThan
{
static const bool value = VAL1 > VAL2;
};
template<typename ITEM, typename REST, bool NEEDS_SWAP = GreaterThan<ITEM::SORT_ORDER, REST::SORT_ORDER>::value >
struct Swap
{
typedef typename ITEM::template Cons<REST>::value_t value_t;
};
template<typename ITEM, typename REST>
struct Swap<ITEM, REST, true>
{
typedef typename REST::template Cons<Swap<ITEM, typename REST::inner_t>::value_t>::value_t value_t;
};
template<typename T, typename SORTABLE = void>
struct IsSortable
{
static const bool value = false;
};
template<typename T>
struct IsSortable<T, typename T::is_tag_t>
{
static const bool value = true;
};
template<typename ITEM, typename REST, bool IS_REST_SORTABLE = IsSortable<REST>::value>
struct InsertInto
{
typedef typename ITEM::template Cons<REST>::value_t value_t;
};
template<typename ITEM, typename REST>
struct InsertInto <ITEM, REST, true>
{
typedef typename Swap<ITEM, REST>::value_t value_t;
};
template<typename T, bool SORTABLE = IsSortable<T>::value>
struct Sorted
{
typedef T value_t;
};
template<typename T>
struct Sorted <T, true>
{
typedef typename InsertInto<T, typename Sorted<typename T::inner_t>::value_t>::value_t value_t;
};
}
namespace LLInitParam
{
// used to indicate no matching value to a given name when parsing
struct Flag{};
template<typename T> const T& defaultValue() { static T value; return value; }
// wraps comparison operator between any 2 values of the same type
// specialize to handle cases where equality isn't defined well, or at all
template <typename T, bool IS_BOOST_FUNCTION = boost::is_convertible<T, boost::function_base>::value >
struct ParamCompare
{
static bool equals(const T &a, const T &b)
{
return a == b;
}
};
// boost function types are not comparable
template<typename T>
struct ParamCompare<T, true>
{
static bool equals(const T&a, const T &b)
{
return false;
}
};
template<>
struct ParamCompare<LLSD, false>
{
static bool equals(const LLSD &a, const LLSD &b) { return false; }
};
template<>
struct ParamCompare<Flag, false>
{
static bool equals(const Flag& a, const Flag& b) { return false; }
};
// helper functions and classes
typedef ptrdiff_t param_handle_t;
struct IS_A_BLOCK {};
struct NOT_BLOCK {};
// these templates allow us to distinguish between template parameters
// that derive from BaseBlock and those that don't
template<typename T, typename BLOCK_IDENTIFIER = void>
struct IsBlock
{
typedef NOT_BLOCK value_t;
};
template<typename T>
struct IsBlock<T, typename T::baseblock_base_class_t>
{
typedef IS_A_BLOCK value_t;
};
// ParamValue class directly manages the wrapped value
// by holding on to a copy (scalar params)
// or deriving from it (blocks)
// has specializations for custom value behavior
// and "tag" values like Lazy and Atomic
template<typename T, typename VALUE_IS_BLOCK = typename IsBlock<T>::value_t>
class ParamValue
{
typedef ParamValue<T, VALUE_IS_BLOCK> self_t;
public:
typedef T default_value_t;
typedef T value_t;
ParamValue(): mValue() {}
ParamValue(const default_value_t& other) : mValue(other) {}
void setValue(const value_t& val)
{
mValue = val;
}
const value_t& getValue() const
{
return mValue;
}
T& getValue()
{
return mValue;
}
bool isValid() const { return true; }
protected:
T mValue;
};
template<typename T>
class ParamValue<T, IS_A_BLOCK>
: public T
{
typedef ParamValue<T, IS_A_BLOCK> self_t;
public:
typedef T default_value_t;
typedef T value_t;
ParamValue()
: T()
{}
ParamValue(const default_value_t& other)
: T(other)
{}
void setValue(const value_t& val)
{
*this = val;
}
const value_t& getValue() const
{
return *this;
}
T& getValue()
{
return *this;
}
};
// empty default implementation of key cache
// leverages empty base class optimization
template <typename T>
class TypeValues
: public ParamValue<typename LLTypeTags::Sorted<T>::value_t>
{
private:
struct Inaccessable{};
public:
typedef std::map<std::string, T> value_name_map_t;
typedef Inaccessable name_t;
typedef TypeValues<T> type_value_t;
typedef ParamValue<typename LLTypeTags::Sorted<T>::value_t> param_value_t;
typedef typename param_value_t::value_t value_t;
TypeValues(const typename param_value_t::value_t& val)
: param_value_t(val)
{}
void setValueName(const std::string& key) {}
std::string getValueName() const { return ""; }
std::string calcValueName(const value_t& value) const { return ""; }
void clearValueName() const {}
static bool getValueFromName(const std::string& name, value_t& value)
{
return false;
}
static bool valueNamesExist()
{
return false;
}
static std::vector<std::string>* getPossibleValues()
{
return NULL;
}
void assignNamedValue(const Inaccessable& name)
{}
operator const value_t&() const
{
return param_value_t::getValue();
}
const value_t& operator()() const
{
return param_value_t::getValue();
}
static value_name_map_t* getValueNames() {return NULL;}
};
// helper class to implement name value lookups
// and caching of last used name
template <typename T, typename DERIVED_TYPE = TypeValues<T>, bool IS_SPECIALIZED = true >
class TypeValuesHelper
: public ParamValue<typename LLTypeTags::Sorted<T>::value_t>
{
typedef TypeValuesHelper<T, DERIVED_TYPE, IS_SPECIALIZED> self_t;
public:
typedef typename std::map<std::string, T> value_name_map_t;
typedef std::string name_t;
typedef self_t type_value_t;
typedef ParamValue<typename LLTypeTags::Sorted<T>::value_t> param_value_t;
typedef typename param_value_t::value_t value_t;
TypeValuesHelper(const typename param_value_t::value_t& val)
: param_value_t(val)
{}
//TODO: cache key by index to save on param block size
void setValueName(const std::string& value_name)
{
mValueName = value_name;
}
std::string getValueName() const
{
return mValueName;
}
std::string calcValueName(const value_t& value) const
{
value_name_map_t* map = getValueNames();
for (typename value_name_map_t::iterator it = map->begin(), end_it = map->end();
it != end_it;
++it)
{
if (ParamCompare<T>::equals(it->second, value))
{
return it->first;
}
}
return "";
}
void clearValueName() const
{
mValueName.clear();
}
static bool getValueFromName(const std::string& name, value_t& value)
{
value_name_map_t* map = getValueNames();
typename value_name_map_t::iterator found_it = map->find(name);
if (found_it == map->end()) return false;
value = found_it->second;
return true;
}
static bool valueNamesExist()
{
return !getValueNames()->empty();
}
static value_name_map_t* getValueNames()
{
static value_name_map_t sMap;
static bool sInitialized = false;
if (!sInitialized)
{
sInitialized = true;
DERIVED_TYPE::declareValues();
}
return &sMap;
}
static std::vector<std::string>* getPossibleValues()
{
static std::vector<std::string> sValues;
value_name_map_t* map = getValueNames();
for (typename value_name_map_t::iterator it = map->begin(), end_it = map->end();
it != end_it;
++it)
{
sValues.push_back(it->first);
}
return &sValues;
}
static void declare(const std::string& name, const value_t& value)
{
(*getValueNames())[name] = value;
}
void operator ()(const std::string& name)
{
*this = name;
}
void assignNamedValue(const std::string& name)
{
if (getValueFromName(name, param_value_t::getValue()))
{
setValueName(name);
}
}
operator const value_t&() const
{
return param_value_t::getValue();
}
const value_t& operator()() const
{
return param_value_t::getValue();
}
protected:
static void getName(const std::string& name, const value_t& value)
{}
mutable std::string mValueName;
};
// string types can support custom named values, but need
// to disambiguate in code between a string that is a named value
// and a string that is a name
template <typename DERIVED_TYPE>
class TypeValuesHelper<std::string, DERIVED_TYPE, true>
: public TypeValuesHelper<std::string, DERIVED_TYPE, false>
{
public:
typedef TypeValuesHelper<std::string, DERIVED_TYPE, true> self_t;
typedef TypeValuesHelper<std::string, DERIVED_TYPE, false> base_t;
typedef std::string value_t;
typedef std::string name_t;
typedef self_t type_value_t;
TypeValuesHelper(const std::string& val)
: TypeValuesHelper(val)
{}
void operator ()(const std::string& name)
{
*this = name;
}
self_t& operator =(const std::string& name)
{
if (base_t::getValueFromName(name, ParamValue<std::string>::getValue()))
{
base_t::setValueName(name);
}
else
{
ParamValue<std::string>::setValue(name);
}
return *this;
}
operator const value_t&() const
{
return ParamValue<std::string>::getValue();
}
const value_t& operator()() const
{
return ParamValue<std::string>::getValue();
}
};
// parser base class with mechanisms for registering readers/writers/inspectors of different types
class LL_COMMON_API Parser
{
LOG_CLASS(Parser);
public:
typedef std::vector<std::pair<std::string, bool> > name_stack_t;
typedef std::pair<name_stack_t::iterator, name_stack_t::iterator> name_stack_range_t;
typedef std::vector<std::string> possible_values_t;
typedef bool (*parser_read_func_t)(Parser& parser, void* output);
typedef bool (*parser_write_func_t)(Parser& parser, const void*, name_stack_t&);
typedef boost::function<void (name_stack_t&, S32, S32, const possible_values_t*)> parser_inspect_func_t;
typedef std::map<const std::type_info*, parser_read_func_t> parser_read_func_map_t;
typedef std::map<const std::type_info*, parser_write_func_t> parser_write_func_map_t;
typedef std::map<const std::type_info*, parser_inspect_func_t> parser_inspect_func_map_t;
public:
Parser(parser_read_func_map_t& read_map, parser_write_func_map_t& write_map, parser_inspect_func_map_t& inspect_map)
: mParseSilently(false),
mParserReadFuncs(&read_map),
mParserWriteFuncs(&write_map),
mParserInspectFuncs(&inspect_map)
{}
virtual ~Parser();
template <typename T> bool readValue(T& param, typename boost::disable_if<boost::is_enum<T> >::type* dummy = 0)
{
parser_read_func_map_t::iterator found_it = mParserReadFuncs->find(&typeid(T));
if (found_it != mParserReadFuncs->end())
{
return found_it->second(*this, (void*)¶m);
}
return false;
}
template <typename T> bool readValue(T& param, typename boost::enable_if<boost::is_enum<T> >::type* dummy = 0)
{
parser_read_func_map_t::iterator found_it = mParserReadFuncs->find(&typeid(T));
if (found_it != mParserReadFuncs->end())
{
return found_it->second(*this, (void*)¶m);
}
else
{
found_it = mParserReadFuncs->find(&typeid(S32));
if (found_it != mParserReadFuncs->end())
{
S32 int_value;
bool parsed = found_it->second(*this, (void*)&int_value);
param = (T)int_value;
return parsed;
}
}
return false;
}
template <typename T> bool writeValue(const T& param, name_stack_t& name_stack)
{
parser_write_func_map_t::iterator found_it = mParserWriteFuncs->find(&typeid(T));
if (found_it != mParserWriteFuncs->end())
{
return found_it->second(*this, (const void*)¶m, name_stack);
}
return false;
}
// dispatch inspection to registered inspection functions, for each parameter in a param block
template <typename T> bool inspectValue(name_stack_t& name_stack, S32 min_count, S32 max_count, const possible_values_t* possible_values)
{
parser_inspect_func_map_t::iterator found_it = mParserInspectFuncs->find(&typeid(T));
if (found_it != mParserInspectFuncs->end())
{
found_it->second(name_stack, min_count, max_count, possible_values);
return true;
}
return false;
}
virtual std::string getCurrentElementName() = 0;
virtual void parserWarning(const std::string& message);
virtual void parserError(const std::string& message);
void setParseSilently(bool silent) { mParseSilently = silent; }
protected:
template <typename T>
void registerParserFuncs(parser_read_func_t read_func, parser_write_func_t write_func = NULL)
{
mParserReadFuncs->insert(std::make_pair(&typeid(T), read_func));
mParserWriteFuncs->insert(std::make_pair(&typeid(T), write_func));
}
template <typename T>
void registerInspectFunc(parser_inspect_func_t inspect_func)
{
mParserInspectFuncs->insert(std::make_pair(&typeid(T), inspect_func));
}
bool mParseSilently;
private:
parser_read_func_map_t* mParserReadFuncs;
parser_write_func_map_t* mParserWriteFuncs;
parser_inspect_func_map_t* mParserInspectFuncs;
};
class Param;
enum ESerializePredicates
{
PROVIDED,
REQUIRED,
VALID,
HAS_DEFAULT_VALUE,
EMPTY
};
typedef LLPredicate::Rule<ESerializePredicates> predicate_rule_t;
predicate_rule_t default_parse_rules();
// various callbacks and constraints associated with an individual param
struct LL_COMMON_API ParamDescriptor
{
struct UserData
{
virtual ~UserData() {}
};
typedef bool(*merge_func_t)(Param&, const Param&, bool);
typedef bool(*deserialize_func_t)(Param&, Parser&, Parser::name_stack_range_t&, bool);
typedef bool(*serialize_func_t)(const Param&, Parser&, Parser::name_stack_t&, const predicate_rule_t rules, const Param* diff_param);
typedef void(*inspect_func_t)(const Param&, Parser&, Parser::name_stack_t&, S32 min_count, S32 max_count);
typedef bool(*validation_func_t)(const Param*);
ParamDescriptor(param_handle_t p,
merge_func_t merge_func,
deserialize_func_t deserialize_func,
serialize_func_t serialize_func,
validation_func_t validation_func,
inspect_func_t inspect_func,
S32 min_count,
S32 max_count);
ParamDescriptor();
~ParamDescriptor();
param_handle_t mParamHandle;
merge_func_t mMergeFunc;
deserialize_func_t mDeserializeFunc;
serialize_func_t mSerializeFunc;
inspect_func_t mInspectFunc;
validation_func_t mValidationFunc;
S32 mMinCount;
S32 mMaxCount;
S32 mNumRefs;
UserData* mUserData;
};
typedef ParamDescriptor* ParamDescriptorPtr;
// each derived Block class keeps a static data structure maintaining offsets to various params
class LL_COMMON_API BlockDescriptor
{
public:
BlockDescriptor();
typedef enum e_initialization_state
{
UNINITIALIZED,
INITIALIZING,
INITIALIZED
} EInitializationState;
void aggregateBlockData(BlockDescriptor& src_block_data);
void addParam(ParamDescriptorPtr param, const char* name);
typedef boost::unordered_map<const std::string, ParamDescriptorPtr> param_map_t;
typedef std::vector<ParamDescriptorPtr> param_list_t;
typedef std::list<ParamDescriptorPtr> all_params_list_t;
typedef std::vector<std::pair<param_handle_t, ParamDescriptor::validation_func_t> > param_validation_list_t;
param_map_t mNamedParams; // parameters with associated names
param_list_t mUnnamedParams; // parameters with_out_ associated names
param_validation_list_t mValidationList; // parameters that must be validated
all_params_list_t mAllParams; // all parameters, owns descriptors
size_t mMaxParamOffset;
EInitializationState mInitializationState; // whether or not static block data has been initialized
class BaseBlock* mCurrentBlockPtr; // pointer to block currently being constructed
};
//TODO: implement in terms of owned_ptr
template<typename T>
class LazyValue
{
public:
LazyValue()
: mPtr(NULL)
{}
~LazyValue()
{
delete mPtr;
}
LazyValue(const T& value)
{
mPtr = new T(value);
}
LazyValue(const LazyValue& other)
: mPtr(NULL)
{
*this = other;
}
LazyValue& operator = (const LazyValue& other)
{
if (!other.mPtr)
{
delete mPtr;
mPtr = NULL;
}
else
{
if (!mPtr)
{
mPtr = new T(*other.mPtr);
}
else
{
*mPtr = *(other.mPtr);
}
}
return *this;
}
bool operator==(const LazyValue& other) const
{
if (empty() || other.empty()) return false;
return *mPtr == *other.mPtr;
}
bool empty() const
{
return mPtr == NULL;
}
void set(const T& other)
{
if (!mPtr)
{
mPtr = new T(other);
}
else
{
*mPtr = other;
}
}
const T& get() const
{
return *ensureInstance();
}
T& get()
{
return *ensureInstance();
}
operator const T&() const
{
return get();
}
private:
// lazily allocate an instance of T
T* ensureInstance() const
{
if (mPtr == NULL)
{
mPtr = new T();
}
return mPtr;
}
private:
mutable T* mPtr;
};
// root class of all parameter blocks
class LL_COMMON_API BaseBlock
{
public:
// lift block tags into baseblock namespace so derived classes do not need to qualify them
typedef LLInitParam::IS_A_BLOCK IS_A_BLOCK;
typedef LLInitParam::NOT_BLOCK NOT_A_BLOCK;
template<typename T>
struct Sequential : public LLTypeTags::TypeTagBase<T, 2>
{
template <typename S> struct Cons { typedef Sequential<ParamValue<S> > value_t; };
template <typename S> struct Cons<Sequential<S> > { typedef Sequential<S> value_t; };
};
template<typename T>
struct Atomic : public LLTypeTags::TypeTagBase<T, 1>
{
template <typename S> struct Cons { typedef Atomic<ParamValue<S> > value_t; };
template <typename S> struct Cons<Atomic<S> > { typedef Atomic<S> value_t; };
};
template<typename T, typename BLOCK_T = typename IsBlock<T>::value_t >
struct Lazy : public LLTypeTags::TypeTagBase<T, 0>
{
template <typename S> struct Cons
{
typedef Lazy<ParamValue<S, BLOCK_T>, BLOCK_T> value_t;
};
template <typename S> struct Cons<Lazy<S, IS_A_BLOCK> >
{
typedef Lazy<S, IS_A_BLOCK> value_t;
};
template <typename S> struct Cons<Lazy<S, NOT_A_BLOCK> >
{
typedef Lazy<S, BLOCK_T> value_t;
};
};
// "Multiple" constraint types, put here in root class to avoid ambiguity during use
struct AnyAmount
{
enum { minCount = 0 };
enum { maxCount = U32_MAX };
};
template<U32 MIN_AMOUNT>
struct AtLeast
{
enum { minCount = MIN_AMOUNT };
enum { maxCount = U32_MAX };
};
template<U32 MAX_AMOUNT>
struct AtMost
{
enum { minCount = 0 };
enum { maxCount = MAX_AMOUNT };
};
template<U32 MIN_AMOUNT, U32 MAX_AMOUNT>
struct Between
{
enum { minCount = MIN_AMOUNT };
enum { maxCount = MAX_AMOUNT };
};
template<U32 EXACT_COUNT>
struct Exactly
{
enum { minCount = EXACT_COUNT };
enum { maxCount = EXACT_COUNT };
};
// this typedef identifies derived classes as being blocks
typedef void baseblock_base_class_t;
LOG_CLASS(BaseBlock);
friend class Param;
BaseBlock()
: mValidated(false),
mParamProvided(false)
{}
virtual ~BaseBlock() {}
bool submitValue(Parser::name_stack_t& name_stack, Parser& p, bool silent=false);
param_handle_t getHandleFromParam(const Param* param) const;
bool validateBlock(bool emit_errors = true) const;
bool isProvided() const
{
return mParamProvided;
}
bool isValid() const
{
return validateBlock(false);
}
Param* getParamFromHandle(const param_handle_t param_handle)
{
if (param_handle == 0) return NULL;
U8* baseblock_address = reinterpret_cast<U8*>(this);
return reinterpret_cast<Param*>(baseblock_address + param_handle);
}
const Param* getParamFromHandle(const param_handle_t param_handle) const
{
const U8* baseblock_address = reinterpret_cast<const U8*>(this);
return reinterpret_cast<const Param*>(baseblock_address + param_handle);
}
void addSynonym(Param& param, const std::string& synonym);
// Blocks can override this to do custom tracking of changes
virtual void paramChanged(const Param& changed_param, bool user_provided)
{
if (user_provided)
{
// a child param has been explicitly changed
// so *some* aspect of this block is now provided
mValidated = false;
mParamProvided = true;
}
}
bool deserializeBlock(Parser& p, Parser::name_stack_range_t& name_stack_range, bool new_name);
bool serializeBlock(Parser& p, Parser::name_stack_t& name_stack, const predicate_rule_t rule, const BaseBlock* diff_block = NULL) const;
bool inspectBlock(Parser& p, Parser::name_stack_t name_stack = Parser::name_stack_t(), S32 min_count = 0, S32 max_count = S32_MAX) const;
virtual const BlockDescriptor& mostDerivedBlockDescriptor() const { return getBlockDescriptor(); }
virtual BlockDescriptor& mostDerivedBlockDescriptor() { return getBlockDescriptor(); }
// take all provided params from other and apply to self
bool overwriteFrom(const BaseBlock& other)
{
return false;
}
// take all provided params that are not already provided, and apply to self
bool fillFrom(const BaseBlock& other)
{
return false;
}
ParamDescriptorPtr findParamDescriptor(const Param& param);
// take all provided params from other and apply to self
bool mergeBlock(BlockDescriptor& block_data, const BaseBlock& other, bool overwrite);
static BlockDescriptor& getBlockDescriptor()
{
static BlockDescriptor sBlockDescriptor;
return sBlockDescriptor;
}
protected:
void init(BlockDescriptor& descriptor, BlockDescriptor& base_descriptor, size_t block_size);
bool mergeBlockParam(bool source_provided, bool dst_provided, BlockDescriptor& block_data, const BaseBlock& source, bool overwrite)
{
return mergeBlock(block_data, source, overwrite);
}
mutable bool mValidated; // lazy validation flag
bool mParamProvided;
private:
const std::string& getParamName(const BlockDescriptor& block_data, const Param* paramp) const;
};
class LL_COMMON_API Param
{
public:
void setProvided(bool is_provided = true)
{
mIsProvided = is_provided;
enclosingBlock().paramChanged(*this, is_provided);
}
Param& operator =(const Param& other)
{
mIsProvided = other.mIsProvided;
// don't change mEnclosingblockoffset
return *this;
}
protected:
bool anyProvided() const { return mIsProvided; }
Param(BaseBlock* enclosing_block);
// store pointer to enclosing block as offset to reduce space and allow for quick copying
BaseBlock& enclosingBlock() const
{
const U8* my_addr = reinterpret_cast<const U8*>(this);
// get address of enclosing BLOCK class using stored offset to enclosing BaseBlock class
return *const_cast<BaseBlock*>
(reinterpret_cast<const BaseBlock*>
(my_addr - (ptrdiff_t)getEnclosingBlockOffset()));
}
U32 getEnclosingBlockOffset() const
{
return ((U32)mEnclosingBlockOffsetHigh << 16) | (U32)mEnclosingBlockOffsetLow;
}
private:
friend class BaseBlock;
//24 bits for member offset field and 1 bit for provided flag
U16 mEnclosingBlockOffsetLow;
U8 mEnclosingBlockOffsetHigh:7;
U8 mIsProvided:1;
};
template<typename T, typename NAME_VALUE_LOOKUP = TypeValues<T> >
struct ParamIterator
{
typedef typename std::vector<typename NAME_VALUE_LOOKUP::type_value_t >::const_iterator const_iterator;
typedef typename std::vector<typename NAME_VALUE_LOOKUP::type_value_t >::iterator iterator;
};
// wrapper for parameter with a known type
// specialized to handle 4 cases:
// simple "scalar" value
// parameter that is itself a block
// multiple scalar values, stored in a vector
// multiple blocks, stored in a vector
template<typename T,
typename NAME_VALUE_LOOKUP = TypeValues<T>,
bool HAS_MULTIPLE_VALUES = false,
typename VALUE_IS_BLOCK = typename IsBlock<ParamValue<typename LLTypeTags::Sorted<T>::value_t> >::value_t>
class TypedParam
: public Param,
public NAME_VALUE_LOOKUP::type_value_t
{
protected:
typedef TypedParam<T, NAME_VALUE_LOOKUP, HAS_MULTIPLE_VALUES, VALUE_IS_BLOCK> self_t;
typedef ParamValue<typename LLTypeTags::Sorted<T>::value_t> param_value_t;
typedef typename param_value_t::default_value_t default_value_t;
typedef typename NAME_VALUE_LOOKUP::type_value_t named_value_t;
public:
typedef typename param_value_t::value_t value_t;
using named_value_t::operator();
TypedParam(BlockDescriptor& block_descriptor, const char* name, const default_value_t& value, ParamDescriptor::validation_func_t validate_func, S32 min_count, S32 max_count)
: Param(block_descriptor.mCurrentBlockPtr),
named_value_t(value)
{
if (LL_UNLIKELY(block_descriptor.mInitializationState == BlockDescriptor::INITIALIZING))
{
init(block_descriptor, validate_func, min_count, max_count, name);
}
}
bool isProvided() const { return Param::anyProvided(); }
bool isValid() const { return true; }
static bool deserializeParam(Param& param, Parser& parser, Parser::name_stack_range_t& name_stack_range, bool new_name)
{
self_t& typed_param = static_cast<self_t&>(param);
// no further names in stack, attempt to parse value now
if (name_stack_range.first == name_stack_range.second)
{
std::string name;
// try to parse a known named value
if(named_value_t::valueNamesExist()
&& parser.readValue(name)
&& named_value_t::getValueFromName(name, typed_param.getValue()))
{
typed_param.setValueName(name);
typed_param.setProvided();
return true;
}
// try to read value directly
else if (parser.readValue(typed_param.getValue()))
{
typed_param.clearValueName();
typed_param.setProvided();
return true;
}
}
return false;
}
static bool serializeParam(const Param& param, Parser& parser, Parser::name_stack_t& name_stack, const predicate_rule_t predicate_rule, const Param* diff_param)
{
bool serialized = false;
const self_t& typed_param = static_cast<const self_t&>(param);
const self_t* diff_typed_param = static_cast<const self_t*>(diff_param);
LLPredicate::Value<ESerializePredicates> predicate;
if (diff_typed_param && ParamCompare<T>::equals(typed_param.getValue(), diff_typed_param->getValue()))
{
predicate.set(HAS_DEFAULT_VALUE);
}
predicate.set(VALID, typed_param.isValid());
predicate.set(PROVIDED, typed_param.anyProvided());
predicate.set(EMPTY, false);
if (!predicate_rule.check(predicate)) return false;
if (!name_stack.empty())
{
name_stack.back().second = true;
}
std::string key = typed_param.getValueName();
// first try to write out name of name/value pair
if (!key.empty())
{
if (!diff_typed_param || !ParamCompare<std::string>::equals(diff_typed_param->getValueName(), key))
{
serialized = parser.writeValue(key, name_stack);
}
}
// then try to serialize value directly
else if (!diff_typed_param || ParamCompare<T>::equals(typed_param.getValue(), diff_typed_param->getValue()))
{
serialized = parser.writeValue(typed_param.getValue(), name_stack);
if (!serialized)
{
std::string calculated_key = typed_param.calcValueName(typed_param.getValue());
if (calculated_key.size()
&& (!diff_typed_param
|| !ParamCompare<std::string>::equals(static_cast<const self_t*>(diff_param)->getValueName(), calculated_key)))
{
serialized = parser.writeValue(calculated_key, name_stack);
}
}
}
return serialized;
}
static void inspectParam(const Param& param, Parser& parser, Parser::name_stack_t& name_stack, S32 min_count, S32 max_count)
{
// tell parser about our actual type
parser.inspectValue<T>(name_stack, min_count, max_count, NULL);
// then tell it about string-based alternatives ("red", "blue", etc. for LLColor4)
if (named_value_t::getPossibleValues())
{
parser.inspectValue<std::string>(name_stack, min_count, max_count, named_value_t::getPossibleValues());
}
}
void set(const value_t& val, bool flag_as_provided = true)
{
named_value_t::clearValueName();
setValue(val);
setProvided(flag_as_provided);
}
self_t& operator =(const typename named_value_t::name_t& name)
{
named_value_t::assignNamedValue(name);
return *this;
}
protected:
self_t& operator =(const self_t& other)
{
param_value_t::operator =(other);
Param::operator =(other);
return *this;
}
static bool mergeWith(Param& dst, const Param& src, bool overwrite)
{
const self_t& src_typed_param = static_cast<const self_t&>(src);
self_t& dst_typed_param = static_cast<self_t&>(dst);
if (src_typed_param.isProvided()
&& (overwrite || !dst_typed_param.isProvided()))
{
dst_typed_param.set(src_typed_param.getValue());
return true;
}
return false;
}
private:
void init( BlockDescriptor &block_descriptor, ParamDescriptor::validation_func_t validate_func, S32 min_count, S32 max_count, const char* name )
{
ParamDescriptorPtr param_descriptor = ParamDescriptorPtr(new ParamDescriptor(
block_descriptor.mCurrentBlockPtr->getHandleFromParam(this),
&mergeWith,
&deserializeParam,
&serializeParam,
validate_func,
&inspectParam,
min_count, max_count));
block_descriptor.addParam(param_descriptor, name);
}
};
// parameter that is a block
template <typename BLOCK_T, typename NAME_VALUE_LOOKUP>
class TypedParam<BLOCK_T, NAME_VALUE_LOOKUP, false, IS_A_BLOCK>
: public Param,
public NAME_VALUE_LOOKUP::type_value_t
{
protected:
typedef ParamValue<typename LLTypeTags::Sorted<BLOCK_T>::value_t> param_value_t;
typedef typename param_value_t::default_value_t default_value_t;
typedef TypedParam<BLOCK_T, NAME_VALUE_LOOKUP, false, IS_A_BLOCK> self_t;
typedef typename NAME_VALUE_LOOKUP::type_value_t named_value_t;
public:
using named_value_t::operator();
typedef typename param_value_t::value_t value_t;
TypedParam(BlockDescriptor& block_descriptor, const char* name, const default_value_t& value, ParamDescriptor::validation_func_t validate_func, S32 min_count, S32 max_count)
: Param(block_descriptor.mCurrentBlockPtr),
named_value_t(value)
{
if (LL_UNLIKELY(block_descriptor.mInitializationState == BlockDescriptor::INITIALIZING))
{
init(block_descriptor, validate_func, min_count, max_count, name);
}
}
static bool deserializeParam(Param& param, Parser& parser, Parser::name_stack_range_t& name_stack_range, bool new_name)
{
self_t& typed_param = static_cast<self_t&>(param);
if (name_stack_range.first == name_stack_range.second)
{ // try to parse a known named value
std::string name;
if(named_value_t::valueNamesExist()
&& parser.readValue(name)
&& named_value_t::getValueFromName(name, typed_param.getValue()))
{
typed_param.setValueName(name);
typed_param.setProvided();
return true;
}
}
if(typed_param.deserializeBlock(parser, name_stack_range, new_name))
{ // attempt to parse block...
typed_param.clearValueName();
typed_param.setProvided();
return true;
}
return false;
}
static bool serializeParam(const Param& param, Parser& parser, Parser::name_stack_t& name_stack, const predicate_rule_t predicate_rule, const Param* diff_param)
{
const self_t& typed_param = static_cast<const self_t&>(param);
LLPredicate::Value<ESerializePredicates> predicate;
predicate.set(VALID, typed_param.isValid());
predicate.set(PROVIDED, typed_param.anyProvided());
if (!predicate_rule.check(predicate)) return false;
if (!name_stack.empty())
{
name_stack.back().second = true;
}
std::string key = typed_param.getValueName();
if (!key.empty())
{
if (!diff_param || !ParamCompare<std::string>::equals(static_cast<const self_t*>(diff_param)->getValueName(), key))
{
parser.writeValue(key, name_stack);
return true;
}
}
else
{
return typed_param.serializeBlock(parser, name_stack, predicate_rule, static_cast<const self_t*>(diff_param));
}
return false;
}
static void inspectParam(const Param& param, Parser& parser, Parser::name_stack_t& name_stack, S32 min_count, S32 max_count)
{
const self_t& typed_param = static_cast<const self_t&>(param);
// tell parser about our actual type
parser.inspectValue<value_t>(name_stack, min_count, max_count, NULL);
// then tell it about string-based alternatives ("red", "blue", etc. for LLColor4)
if (named_value_t::getPossibleValues())
{
parser.inspectValue<std::string>(name_stack, min_count, max_count, named_value_t::getPossibleValues());
}
typed_param.inspectBlock(parser, name_stack, min_count, max_count);
}
// a param-that-is-a-block is provided when the user has set one of its child params
// *and* the block as a whole validates
bool isProvided() const
{
return Param::anyProvided() && isValid();
}
bool isValid() const
{
return param_value_t::isValid();
}
// assign block contents to this param-that-is-a-block
void set(const value_t& val, bool flag_as_provided = true)
{
setValue(val);
named_value_t::clearValueName();
setProvided(flag_as_provided);
}
self_t& operator =(const typename named_value_t::name_t& name)
{
named_value_t::assignNamedValue(name);
return *this;
}
// propagate changed status up to enclosing block
/*virtual*/ void paramChanged(const Param& changed_param, bool user_provided)
{
param_value_t::paramChanged(changed_param, user_provided);
if (user_provided)
{
setProvided();
named_value_t::clearValueName();
}
else
{
Param::enclosingBlock().paramChanged(*this, user_provided);
}
}
protected:
self_t& operator =(const self_t& other)
{
param_value_t::operator =(other);
Param::operator =(other);
return *this;
}
static bool mergeWith(Param& dst, const Param& src, bool overwrite)
{
const self_t& src_typed_param = static_cast<const self_t&>(src);
self_t& dst_typed_param = static_cast<self_t&>(dst);
if (src_typed_param.anyProvided())
{
if (dst_typed_param.mergeBlockParam(src_typed_param.isProvided(), dst_typed_param.isProvided(), param_value_t::getBlockDescriptor(), src_typed_param, overwrite))
{
dst_typed_param.clearValueName();
dst_typed_param.setProvided(true);
return true;
}
}
return false;
}
private:
void init( BlockDescriptor &block_descriptor, ParamDescriptor::validation_func_t validate_func, S32 min_count, S32 max_count, const char* name )
{
ParamDescriptorPtr param_descriptor = ParamDescriptorPtr(new ParamDescriptor(
block_descriptor.mCurrentBlockPtr->getHandleFromParam(this),
&mergeWith,
&deserializeParam,
&serializeParam,
validate_func,
&inspectParam,
min_count, max_count));
block_descriptor.addParam(param_descriptor, name);
}
};
// list of non-block parameters
template <typename MULTI_VALUE_T, typename NAME_VALUE_LOOKUP>
class TypedParam<MULTI_VALUE_T, NAME_VALUE_LOOKUP, true, NOT_BLOCK>
: public Param
{
protected:
typedef TypedParam<MULTI_VALUE_T, NAME_VALUE_LOOKUP, true, NOT_BLOCK> self_t;
typedef ParamValue<typename LLTypeTags::Sorted<MULTI_VALUE_T>::value_t> param_value_t;
typedef typename std::vector<typename NAME_VALUE_LOOKUP::type_value_t> container_t;
typedef container_t default_value_t;
typedef typename NAME_VALUE_LOOKUP::type_value_t named_value_t;
public:
typedef typename param_value_t::value_t value_t;
TypedParam(BlockDescriptor& block_descriptor, const char* name, const default_value_t& value, ParamDescriptor::validation_func_t validate_func, S32 min_count, S32 max_count)
: Param(block_descriptor.mCurrentBlockPtr),
mMinCount(min_count),
mMaxCount(max_count)
{
std::copy(value.begin(), value.end(), std::back_inserter(mValues));
if (LL_UNLIKELY(block_descriptor.mInitializationState == BlockDescriptor::INITIALIZING))
{
init(block_descriptor, validate_func, min_count, max_count, name);
}
}
bool isProvided() const { return Param::anyProvided() && isValid(); }
bool isValid() const
{
size_t num_elements = numValidElements();
return mMinCount < num_elements && num_elements < mMaxCount;
}
static bool deserializeParam(Param& param, Parser& parser, Parser::name_stack_range_t& name_stack_range, bool new_name)
{
Parser::name_stack_range_t new_name_stack_range(name_stack_range);
self_t& typed_param = static_cast<self_t&>(param);
value_t value;
// pop first element if empty string
if (new_name_stack_range.first != new_name_stack_range.second && new_name_stack_range.first->first.empty())
{
++new_name_stack_range.first;
}
// no further names in stack, attempt to parse value now
if (new_name_stack_range.first == new_name_stack_range.second)
{
std::string name;
// try to parse a known named value
if(named_value_t::valueNamesExist()
&& parser.readValue(name)
&& named_value_t::getValueFromName(name, value))
{
typed_param.add(value);
typed_param.mValues.back().setValueName(name);
return true;
}
else if (parser.readValue(value)) // attempt to read value directly
{
typed_param.add(value);
return true;
}
}
return false;
}
static bool serializeParam(const Param& param, Parser& parser, Parser::name_stack_t& name_stack, const predicate_rule_t predicate_rule, const Param* diff_param)
{
bool serialized = false;
const self_t& typed_param = static_cast<const self_t&>(param);
LLPredicate::Value<ESerializePredicates> predicate;
predicate.set(REQUIRED, typed_param.mMinCount > 0);
predicate.set(VALID, typed_param.isValid());
predicate.set(PROVIDED, typed_param.anyProvided());
predicate.set(EMPTY, typed_param.mValues.empty());
if (!predicate_rule.check(predicate)) return false;
for (const_iterator it = typed_param.mValues.begin(), end_it = typed_param.mValues.end();
it != end_it;
++it)
{
std::string key = it->getValueName();
name_stack.push_back(std::make_pair(std::string(), true));
if(key.empty())
// not parsed via name values, write out value directly
{
bool value_written = parser.writeValue(*it, name_stack);
if (!value_written)
{
std::string calculated_key = it->calcValueName(it->getValue());
if (parser.writeValue(calculated_key, name_stack))
{
serialized = true;
}
else
{
break;
}
}
}
else
{
if(parser.writeValue(key, name_stack))
{
serialized = true;
}
else
{
break;
}
}
}
return serialized;
}
static void inspectParam(const Param& param, Parser& parser, Parser::name_stack_t& name_stack, S32 min_count, S32 max_count)
{
parser.inspectValue<MULTI_VALUE_T>(name_stack, min_count, max_count, NULL);
if (named_value_t::getPossibleValues())
{
parser.inspectValue<std::string>(name_stack, min_count, max_count, named_value_t::getPossibleValues());
}
}
void set(const container_t& val, bool flag_as_provided = true)
{
mValues = val;
setProvided(flag_as_provided);
}
param_value_t& add()
{
mValues.push_back(value_t());
Param::setProvided();
return mValues.back();
}
self_t& add(const value_t& item)
{
mValues.push_back(item);
setProvided();
return *this;
}
self_t& add(const typename named_value_t::name_t& name)
{
value_t value;
// try to parse a per type named value
if (named_value_t::getValueFromName(name, value))
{
add(value);
mValues.back().setValueName(name);
}
return *this;
}
// implicit conversion
operator const container_t&() const { return mValues; }
// explicit conversion
const container_t& operator()() const { return mValues; }
typedef typename container_t::iterator iterator;
typedef typename container_t::const_iterator const_iterator;
iterator begin() { return mValues.begin(); }
iterator end() { return mValues.end(); }
const_iterator begin() const { return mValues.begin(); }
const_iterator end() const { return mValues.end(); }
bool empty() const { return mValues.empty(); }
size_t size() const { return mValues.size(); }
size_t numValidElements() const
{
return mValues.size();
}
protected:
static bool mergeWith(Param& dst, const Param& src, bool overwrite)
{
const self_t& src_typed_param = static_cast<const self_t&>(src);
self_t& dst_typed_param = static_cast<self_t&>(dst);
if (overwrite)
{
std::copy(src_typed_param.begin(), src_typed_param.end(), std::back_inserter(dst_typed_param.mValues));
}
else
{
container_t new_values(src_typed_param.mValues);
std::copy(dst_typed_param.begin(), dst_typed_param.end(), std::back_inserter(new_values));
std::swap(dst_typed_param.mValues, new_values);
}
if (src_typed_param.begin() != src_typed_param.end())
{
dst_typed_param.setProvided();
}
return true;
}
container_t mValues;
size_t mMinCount,
mMaxCount;
private:
void init( BlockDescriptor &block_descriptor, ParamDescriptor::validation_func_t validate_func, S32 min_count, S32 max_count, const char* name )
{
ParamDescriptorPtr param_descriptor = ParamDescriptorPtr(new ParamDescriptor(
block_descriptor.mCurrentBlockPtr->getHandleFromParam(this),
&mergeWith,
&deserializeParam,
&serializeParam,
validate_func,
&inspectParam,
min_count, max_count));
block_descriptor.addParam(param_descriptor, name);
}
};
// list of block parameters
template <typename MULTI_BLOCK_T, typename NAME_VALUE_LOOKUP>
class TypedParam<MULTI_BLOCK_T, NAME_VALUE_LOOKUP, true, IS_A_BLOCK>
: public Param
{
protected:
typedef TypedParam<MULTI_BLOCK_T, NAME_VALUE_LOOKUP, true, IS_A_BLOCK> self_t;
typedef ParamValue<typename LLTypeTags::Sorted<MULTI_BLOCK_T>::value_t> param_value_t;
typedef typename std::vector<typename NAME_VALUE_LOOKUP::type_value_t> container_t;
typedef typename NAME_VALUE_LOOKUP::type_value_t named_value_t;
typedef container_t default_value_t;
typedef typename container_t::iterator iterator;
typedef typename container_t::const_iterator const_iterator;
public:
typedef typename param_value_t::value_t value_t;
TypedParam(BlockDescriptor& block_descriptor, const char* name, const default_value_t& value, ParamDescriptor::validation_func_t validate_func, S32 min_count, S32 max_count)
: Param(block_descriptor.mCurrentBlockPtr),
mMinCount(min_count),
mMaxCount(max_count)
{
std::copy(value.begin(), value.end(), back_inserter(mValues));
if (LL_UNLIKELY(block_descriptor.mInitializationState == BlockDescriptor::INITIALIZING))
{
init(block_descriptor, validate_func, min_count, max_count, name);
}
}
bool isProvided() const { return Param::anyProvided() && isValid(); }
bool isValid() const
{
size_t num_elements = numValidElements();
return mMinCount < num_elements && num_elements < mMaxCount;
}
static bool deserializeParam(Param& param, Parser& parser, Parser::name_stack_range_t& name_stack_range, bool new_name)
{
Parser::name_stack_range_t new_name_stack_range(name_stack_range);
self_t& typed_param = static_cast<self_t&>(param);
bool new_value = false;
bool new_array_value = false;
// pop first element if empty string
if (new_name_stack_range.first != new_name_stack_range.second && new_name_stack_range.first->first.empty())
{
new_array_value = new_name_stack_range.first->second;
++new_name_stack_range.first;
}
if (new_name || new_array_value || typed_param.mValues.empty())
{
new_value = true;
typed_param.mValues.push_back(value_t());
}
param_value_t& value = typed_param.mValues.back();
if (new_name_stack_range.first == new_name_stack_range.second)
{ // try to parse a known named value
std::string name;
if(named_value_t::valueNamesExist()
&& parser.readValue(name)
&& named_value_t::getValueFromName(name, value.getValue()))
{
typed_param.mValues.back().setValueName(name);
typed_param.setProvided();
if (new_array_value)
{
name_stack_range.first->second = false;
}
return true;
}
}
// attempt to parse block...
if(value.deserializeBlock(parser, new_name_stack_range, new_name))
{
typed_param.setProvided();
if (new_array_value)
{
name_stack_range.first->second = false;
}
return true;
}
if (new_value)
{ // failed to parse new value, pop it off
typed_param.mValues.pop_back();
}
return false;
}
static bool serializeParam(const Param& param, Parser& parser, Parser::name_stack_t& name_stack, const predicate_rule_t predicate_rule, const Param* diff_param)
{
bool serialized = false;
const self_t& typed_param = static_cast<const self_t&>(param);
LLPredicate::Value<ESerializePredicates> predicate;
predicate.set(REQUIRED, typed_param.mMinCount > 0);
predicate.set(VALID, typed_param.isValid());
predicate.set(PROVIDED, typed_param.anyProvided());
predicate.set(EMPTY, typed_param.mValues.empty());
if (!predicate_rule.check(predicate)) return false;
for (const_iterator it = typed_param.mValues.begin(), end_it = typed_param.mValues.end();
it != end_it;
++it)
{
name_stack.push_back(std::make_pair(std::string(), true));
std::string key = it->getValueName();
if (!key.empty())
{
serialized |= parser.writeValue(key, name_stack);
}
// Not parsed via named values, write out value directly
// NOTE: currently we don't do diffing of Multiples
else
{
serialized = it->serializeBlock(parser, name_stack, predicate_rule, NULL);
}
name_stack.pop_back();
}
if (!serialized && predicate_rule.check(ll_make_predicate(EMPTY)))
{
serialized |= parser.writeValue(Flag(), name_stack);
}
return serialized;
}
static void inspectParam(const Param& param, Parser& parser, Parser::name_stack_t& name_stack, S32 min_count, S32 max_count)
{
const param_value_t& value_param = param_value_t(value_t());
// tell parser about our actual type
parser.inspectValue<value_t>(name_stack, min_count, max_count, NULL);
// then tell it about string-based alternatives ("red", "blue", etc. for LLColor4)
if (named_value_t::getPossibleValues())
{
parser.inspectValue<std::string>(name_stack, min_count, max_count, named_value_t::getPossibleValues());
}
value_param.inspectBlock(parser, name_stack, min_count, max_count);
}
void set(const container_t& val, bool flag_as_provided = true)
{
mValues = val;
setProvided(flag_as_provided);
}
param_value_t& add()
{
mValues.push_back(value_t());
setProvided();
return mValues.back();
}
self_t& add(const value_t& item)
{
mValues.push_back(item);
setProvided();
return *this;
}
self_t& add(const typename named_value_t::name_t& name)
{
value_t value;
// try to parse a per type named value
if (named_value_t::getValueFromName(name, value))
{
add(value);
mValues.back().setValueName(name);
}
return *this;
}
// implicit conversion
operator const container_t&() const { return mValues; }
// explicit conversion
const container_t& operator()() const { return mValues; }
iterator begin() { return mValues.begin(); }
iterator end() { return mValues.end(); }
const_iterator begin() const { return mValues.begin(); }
const_iterator end() const { return mValues.end(); }
bool empty() const { return mValues.empty(); }
size_t size() const { return mValues.size(); }
size_t numValidElements() const
{
size_t count = 0;
for (const_iterator it = mValues.begin(), end_it = mValues.end();
it != end_it;
++it)
{
if(it->isValid()) count++;
}
return count;
}
protected:
static bool mergeWith(Param& dst, const Param& src, bool overwrite)
{
const self_t& src_typed_param = static_cast<const self_t&>(src);
self_t& dst_typed_param = static_cast<self_t&>(dst);
if (overwrite)
{
std::copy(src_typed_param.begin(), src_typed_param.end(), std::back_inserter(dst_typed_param.mValues));
}
else
{
container_t new_values(src_typed_param.mValues);
std::copy(dst_typed_param.begin(), dst_typed_param.end(), std::back_inserter(new_values));
std::swap(dst_typed_param.mValues, new_values);
}
if (src_typed_param.begin() != src_typed_param.end())
{
dst_typed_param.setProvided();
}
return true;
}
container_t mValues;
size_t mMinCount,
mMaxCount;
private:
void init( BlockDescriptor &block_descriptor, ParamDescriptor::validation_func_t validate_func, S32 min_count, S32 max_count, const char* name )
{
ParamDescriptorPtr param_descriptor = ParamDescriptorPtr(new ParamDescriptor(
block_descriptor.mCurrentBlockPtr->getHandleFromParam(this),
&mergeWith,
&deserializeParam,
&serializeParam,
validate_func,
&inspectParam,
min_count, max_count));
block_descriptor.addParam(param_descriptor, name);
}
};
template <typename DERIVED_BLOCK, typename BASE_BLOCK = BaseBlock>
class ChoiceBlock : public BASE_BLOCK
{
typedef ChoiceBlock<DERIVED_BLOCK, BASE_BLOCK> self_t;
typedef ChoiceBlock<DERIVED_BLOCK, BASE_BLOCK> enclosing_block_t;
typedef BASE_BLOCK base_block_t;
LOG_CLASS(self_t);
public:
// take all provided params from other and apply to self
bool overwriteFrom(const self_t& other)
{
return static_cast<DERIVED_BLOCK*>(this)->mergeBlock(getBlockDescriptor(), other, true);
}
// take all provided params that are not already provided, and apply to self
bool fillFrom(const self_t& other)
{
return static_cast<DERIVED_BLOCK*>(this)->mergeBlock(getBlockDescriptor(), other, false);
}
bool mergeBlockParam(bool source_provided, bool dest_provided, BlockDescriptor& block_data, const self_t& source, bool overwrite)
{
bool source_override = source_provided && (overwrite || !dest_provided);
if (source_override || source.mCurChoice == mCurChoice)
{
return mergeBlock(block_data, source, overwrite);
}
return false;
}
// merge with other block
bool mergeBlock(BlockDescriptor& block_data, const self_t& other, bool overwrite)
{
mCurChoice = other.mCurChoice;
return base_block_t::mergeBlock(getBlockDescriptor(), other, overwrite);
}
// clear out old choice when param has changed
/*virtual*/ void paramChanged(const Param& changed_param, bool user_provided)
{
param_handle_t changed_param_handle = base_block_t::getHandleFromParam(&changed_param);
// if we have a new choice...
if (changed_param_handle != mCurChoice)
{
// clear provided flag on previous choice
Param* previous_choice = base_block_t::getParamFromHandle(mCurChoice);
if (previous_choice)
{
previous_choice->setProvided(false);
}
mCurChoice = changed_param_handle;
}
base_block_t::paramChanged(changed_param, user_provided);
}
virtual const BlockDescriptor& mostDerivedBlockDescriptor() const { return getBlockDescriptor(); }
virtual BlockDescriptor& mostDerivedBlockDescriptor() { return getBlockDescriptor(); }
protected:
ChoiceBlock()
: mCurChoice(0)
{
BaseBlock::init(getBlockDescriptor(), base_block_t::getBlockDescriptor(), sizeof(DERIVED_BLOCK));
}
// Alternatives are mutually exclusive wrt other Alternatives in the same block.
// One alternative in a block will always have isChosen() == true.
// At most one alternative in a block will have isProvided() == true.
template <typename T, typename NAME_VALUE_LOOKUP = typename TypeValues<T>::type_value_t >
class Alternative : public TypedParam<T, NAME_VALUE_LOOKUP, false>
{
typedef TypedParam<T, NAME_VALUE_LOOKUP, false> super_t;
typedef typename super_t::value_t value_t;
typedef typename super_t::default_value_t default_value_t;
public:
friend class ChoiceBlock<DERIVED_BLOCK>;
using super_t::operator =;
explicit Alternative(const char* name = "", const default_value_t& val = defaultValue<default_value_t>())
: super_t(DERIVED_BLOCK::getBlockDescriptor(), name, val, NULL, 0, 1),
mOriginalValue(val)
{
// assign initial choice to first declared option
DERIVED_BLOCK* blockp = ((DERIVED_BLOCK*)DERIVED_BLOCK::getBlockDescriptor().mCurrentBlockPtr);
if (LL_UNLIKELY(DERIVED_BLOCK::getBlockDescriptor().mInitializationState == BlockDescriptor::INITIALIZING))
{
if(blockp->mCurChoice == 0)
{
blockp->mCurChoice = Param::enclosingBlock().getHandleFromParam(this);
}
}
}
void choose()
{
static_cast<enclosing_block_t&>(Param::enclosingBlock()).paramChanged(*this, true);
}
void chooseAs(const value_t& val)
{
super_t::set(val);
}
void operator =(const value_t& val)
{
super_t::set(val);
}
void operator()(const value_t& val)
{
super_t::set(val);
}
operator const value_t&() const
{
return (*this)();
}
const value_t& operator()() const
{
if (static_cast<enclosing_block_t&>(Param::enclosingBlock()).getCurrentChoice() == this)
{
return super_t::getValue();
}
return mOriginalValue;
}
bool isChosen() const
{
return static_cast<enclosing_block_t&>(Param::enclosingBlock()).getCurrentChoice() == this;
}
private:
default_value_t mOriginalValue;
};
public:
static BlockDescriptor& getBlockDescriptor()
{
static BlockDescriptor sBlockDescriptor;
return sBlockDescriptor;
}
private:
param_handle_t mCurChoice;
const Param* getCurrentChoice() const
{
return base_block_t::getParamFromHandle(mCurChoice);
}
};
template <typename DERIVED_BLOCK, typename BASE_BLOCK = BaseBlock>
class Block
: public BASE_BLOCK
{
typedef Block<DERIVED_BLOCK, BASE_BLOCK> self_t;
protected:
typedef Block<DERIVED_BLOCK, BASE_BLOCK> block_t;
public:
typedef BASE_BLOCK base_block_t;
// take all provided params from other and apply to self
bool overwriteFrom(const self_t& other)
{
return static_cast<DERIVED_BLOCK*>(this)->mergeBlock(getBlockDescriptor(), other, true);
}
// take all provided params that are not already provided, and apply to self
bool fillFrom(const self_t& other)
{
return static_cast<DERIVED_BLOCK*>(this)->mergeBlock(getBlockDescriptor(), other, false);
}
virtual const BlockDescriptor& mostDerivedBlockDescriptor() const { return getBlockDescriptor(); }
virtual BlockDescriptor& mostDerivedBlockDescriptor() { return getBlockDescriptor(); }
protected:
Block()
{
//#pragma message("Parsing LLInitParam::Block")
BaseBlock::init(getBlockDescriptor(), BASE_BLOCK::getBlockDescriptor(), sizeof(DERIVED_BLOCK));
}
//
// Nested classes for declaring parameters
//
template <typename T, typename NAME_VALUE_LOOKUP = typename TypeValues<T>::type_value_t >
class Optional : public TypedParam<T, NAME_VALUE_LOOKUP, false>
{
typedef TypedParam<T, NAME_VALUE_LOOKUP, false> super_t;
typedef typename super_t::value_t value_t;
typedef typename super_t::default_value_t default_value_t;
public:
using super_t::operator();
using super_t::operator =;
explicit Optional(const char* name = "", const default_value_t& val = defaultValue<default_value_t>())
: super_t(DERIVED_BLOCK::getBlockDescriptor(), name, val, NULL, 0, 1)
{
//#pragma message("Parsing LLInitParam::Block::Optional")
}
Optional& operator =(const value_t& val)
{
set(val);
return *this;
}
DERIVED_BLOCK& operator()(const value_t& val)
{
super_t::set(val);
return static_cast<DERIVED_BLOCK&>(Param::enclosingBlock());
}
};
template <typename T, typename NAME_VALUE_LOOKUP = typename TypeValues<T>::type_value_t >
class Mandatory : public TypedParam<T, NAME_VALUE_LOOKUP, false>
{
typedef TypedParam<T, NAME_VALUE_LOOKUP, false> super_t;
typedef Mandatory<T, NAME_VALUE_LOOKUP> self_t;
typedef typename super_t::value_t value_t;
typedef typename super_t::default_value_t default_value_t;
public:
using super_t::operator();
using super_t::operator =;
// mandatory parameters require a name to be parseable
explicit Mandatory(const char* name = "", const default_value_t& val = defaultValue<default_value_t>())
: super_t(DERIVED_BLOCK::getBlockDescriptor(), name, val, &validate, 1, 1)
{}
Mandatory& operator =(const value_t& val)
{
set(val);
return *this;
}
DERIVED_BLOCK& operator()(const value_t& val)
{
super_t::set(val);
return static_cast<DERIVED_BLOCK&>(Param::enclosingBlock());
}
static bool validate(const Param* p)
{
// valid only if provided
return static_cast<const self_t*>(p)->isProvided();
}
};
template <typename T, typename RANGE = BaseBlock::AnyAmount, typename NAME_VALUE_LOOKUP = typename TypeValues<T>::type_value_t >
class Multiple : public TypedParam<T, NAME_VALUE_LOOKUP, true>
{
typedef TypedParam<T, NAME_VALUE_LOOKUP, true> super_t;
typedef Multiple<T, RANGE, NAME_VALUE_LOOKUP> self_t;
typedef typename super_t::container_t container_t;
typedef typename super_t::value_t value_t;
public:
typedef typename super_t::iterator iterator;
typedef typename super_t::const_iterator const_iterator;
explicit Multiple(const char* name = "")
: super_t(DERIVED_BLOCK::getBlockDescriptor(), name, container_t(), &validate, RANGE::minCount, RANGE::maxCount)
{}
Multiple& operator =(const container_t& val)
{
set(val);
return *this;
}
DERIVED_BLOCK& operator()(const container_t& val)
{
super_t::set(val);
return static_cast<DERIVED_BLOCK&>(Param::enclosingBlock());
}
static bool validate(const Param* paramp)
{
size_t num_valid = ((super_t*)paramp)->numValidElements();
return RANGE::minCount <= num_valid && num_valid <= RANGE::maxCount;
}
};
// can appear in data files, but will ignored during parsing
// cannot read or write in code
class Ignored : public Param
{
public:
explicit Ignored(const char* name)
: Param(DERIVED_BLOCK::getBlockDescriptor().mCurrentBlockPtr)
{
BlockDescriptor& block_descriptor = DERIVED_BLOCK::getBlockDescriptor();
if (LL_UNLIKELY(block_descriptor.mInitializationState == BlockDescriptor::INITIALIZING))
{
ParamDescriptorPtr param_descriptor = ParamDescriptorPtr(new ParamDescriptor(
block_descriptor.mCurrentBlockPtr->getHandleFromParam(this),
NULL,
&deserializeParam,
NULL,
NULL,
NULL,
0, S32_MAX));
block_descriptor.addParam(param_descriptor, name);
}
}
static bool deserializeParam(Param& param, Parser& parser, Parser::name_stack_range_t& name_stack_range, bool new_name)
{
if (name_stack_range.first == name_stack_range.second)
{
//std::string message = llformat("Deprecated value %s ignored", getName().c_str());
//parser.parserWarning(message);
return true;
}
return false;
}
};
// can appear in data files, or be written to in code, but data will be ignored
// cannot be read in code
class Deprecated : public Ignored
{
public:
explicit Deprecated(const char* name) : Ignored(name) {}
// dummy writer interfaces
template<typename T>
Deprecated& operator =(const T& val)
{
// do nothing
return *this;
}
template<typename T>
DERIVED_BLOCK& operator()(const T& val)
{
// do nothing
return static_cast<DERIVED_BLOCK&>(Param::enclosingBlock());
}
template<typename T>
void set(const T& val, bool flag_as_provided = true)
{
// do nothing
}
};
public:
static BlockDescriptor& getBlockDescriptor()
{
static BlockDescriptor sBlockDescriptor;
return sBlockDescriptor;
}
protected:
template <typename T, typename NAME_VALUE_LOOKUP, bool multiple, typename is_block>
void changeDefault(TypedParam<T, NAME_VALUE_LOOKUP, multiple, is_block>& param,
const typename TypedParam<T, NAME_VALUE_LOOKUP, multiple, is_block>::value_t& value)
{
if (!param.isProvided())
{
param.set(value, false);
}
}
};
template<typename T, typename BLOCK_T>
struct IsBlock<ParamValue<BaseBlock::Lazy<T, BaseBlock::IS_A_BLOCK>, BLOCK_T >, void>
{
typedef IS_A_BLOCK value_t;
};
template<typename T, typename BLOCK_T>
struct IsBlock<ParamValue<BaseBlock::Lazy<T, BaseBlock::NOT_A_BLOCK>, BLOCK_T >, void>
{
typedef NOT_BLOCK value_t;
};
template<typename T, typename BLOCK_IDENTIFIER>
struct IsBlock<ParamValue<BaseBlock::Atomic<T>, typename IsBlock<BaseBlock::Atomic<T> >::value_t >, BLOCK_IDENTIFIER>
{
typedef typename IsBlock<T>::value_t value_t;
};
template<typename T, typename BLOCK_IDENTIFIER>
struct IsBlock<ParamValue<BaseBlock::Sequential<T>, typename IsBlock<BaseBlock::Sequential<T> >::value_t >, BLOCK_IDENTIFIER>
{
typedef typename IsBlock<T>::value_t value_t;
};
template<typename T>
struct InnerMostType
{
typedef T value_t;
};
template<typename T>
struct InnerMostType<ParamValue<T, NOT_BLOCK> >
{
typedef typename InnerMostType<T>::value_t value_t;
};
template<typename T>
struct InnerMostType<ParamValue<T, IS_A_BLOCK> >
{
typedef typename InnerMostType<T>::value_t value_t;
};
template<typename T, typename BLOCK_T>
class ParamValue <BaseBlock::Atomic<T>, BLOCK_T>
{
typedef ParamValue <BaseBlock::Atomic<T>, BLOCK_T> self_t;
public:
typedef typename InnerMostType<T>::value_t value_t;
typedef T default_value_t;
ParamValue()
: mValue()
{}
ParamValue(const default_value_t& value)
: mValue(value)
{}
void setValue(const value_t& val)
{
mValue.setValue(val);
}
const value_t& getValue() const
{
return mValue.getValue();
}
value_t& getValue()
{
return mValue.getValue();
}
bool deserializeBlock(Parser& p, Parser::name_stack_range_t& name_stack_range, bool new_name)
{
if (new_name)
{
resetToDefault();
}
return mValue.deserializeBlock(p, name_stack_range, new_name);
}
bool serializeBlock(Parser& p, Parser::name_stack_t& name_stack, const predicate_rule_t predicate_rule, const self_t* diff_block = NULL) const
{
const BaseBlock* base_block = diff_block
? &(diff_block->mValue)
: NULL;
return mValue.serializeBlock(p, name_stack, predicate_rule, base_block);
}
bool inspectBlock(Parser& p, Parser::name_stack_t name_stack = Parser::name_stack_t(), S32 min_count = 0, S32 max_count = S32_MAX) const
{
return mValue.inspectBlock(p, name_stack, min_count, max_count);
}
bool mergeBlockParam(bool source_provided, bool dst_provided, BlockDescriptor& block_data, const self_t& source, bool overwrite)
{
if ((overwrite && source_provided) // new values coming in on top or...
|| (!overwrite && !dst_provided)) // values being pushed under with nothing already there
{
// clear away what is there and take the new stuff as a whole
resetToDefault();
return mValue.mergeBlock(block_data, source.getValue(), overwrite);
}
return mValue.mergeBlock(block_data, source.getValue(), overwrite);
}
bool validateBlock(bool emit_errors = true) const
{
return mValue.validateBlock(emit_errors);
}
bool isValid() const
{
return validateBlock(false);
}
static BlockDescriptor& getBlockDescriptor()
{
return value_t::getBlockDescriptor();
}
private:
void resetToDefault()
{
static T default_value;
mValue = default_value;
}
T mValue;
};
template<typename T>
class ParamValue <BaseBlock::Sequential<T>, IS_A_BLOCK>
{
typedef ParamValue <BaseBlock::Sequential<T>, IS_A_BLOCK> self_t;
public:
typedef typename InnerMostType<T>::value_t value_t;
typedef T default_value_t;
ParamValue()
: mValue()
{
mCurParam = getBlockDescriptor().mAllParams.begin();
}
ParamValue(const default_value_t& value)
: mValue(value)
{
mCurParam = getBlockDescriptor().mAllParams.begin();
}
void setValue(const value_t& val)
{
mValue.setValue(val);
}
const value_t& getValue() const
{
return mValue.getValue();
}
value_t& getValue()
{
return mValue.getValue();
}
bool deserializeBlock(Parser& p, Parser::name_stack_range_t& name_stack_range, bool new_name)
{
if (new_name)
{
mCurParam = getBlockDescriptor().mAllParams.begin();
}
if (name_stack_range.first == name_stack_range.second
&& mCurParam != getBlockDescriptor().mAllParams.end())
{
// deserialize to mCurParam
ParamDescriptor& pd = *(*mCurParam);
ParamDescriptor::deserialize_func_t deserialize_func = pd.mDeserializeFunc;
Param* paramp = mValue.getParamFromHandle(pd.mParamHandle);
if (deserialize_func
&& paramp
&& deserialize_func(*paramp, p, name_stack_range, new_name))
{
++mCurParam;
return true;
}
else
{
return false;
}
}
else
{
return mValue.deserializeBlock(p, name_stack_range, new_name);
}
}
bool serializeBlock(Parser& p, Parser::name_stack_t& name_stack, const predicate_rule_t predicate_rule, const self_t* diff_block = NULL) const
{
const BaseBlock* base_block = diff_block
? &(diff_block->mValue)
: NULL;
return mValue.serializeBlock(p, name_stack, predicate_rule, base_block);
}
bool inspectBlock(Parser& p, Parser::name_stack_t name_stack = Parser::name_stack_t(), S32 min_count = 0, S32 max_count = S32_MAX) const
{
return mValue.inspectBlock(p, name_stack, min_count, max_count);
}
bool mergeBlockParam(bool source_provided, bool dst_provided, BlockDescriptor& block_data, const self_t& source, bool overwrite)
{
return mValue.mergeBlock(block_data, source.getValue(), overwrite);
}
bool validateBlock(bool emit_errors = true) const
{
return mValue.validateBlock(emit_errors);
}
bool isValid() const
{
return validateBlock(false);
}
static BlockDescriptor& getBlockDescriptor()
{
return value_t::getBlockDescriptor();
}
private:
BlockDescriptor::all_params_list_t::iterator mCurParam;
T mValue;
};
template<typename T>
class ParamValue <BaseBlock::Sequential<T>, NOT_BLOCK>
: public T
{
typedef ParamValue <BaseBlock::Sequential<T>, NOT_BLOCK> self_t;
public:
typedef typename InnerMostType<T>::value_t value_t;
typedef T default_value_t;
ParamValue()
: T()
{}
ParamValue(const default_value_t& value)
: T(value.getValue())
{}
bool isValid() const { return true; }
};
template<typename T, typename BLOCK_T>
class ParamValue <BaseBlock::Lazy<T, IS_A_BLOCK>, BLOCK_T>
{
typedef ParamValue <BaseBlock::Lazy<T, IS_A_BLOCK>, BLOCK_T> self_t;
public:
typedef typename InnerMostType<T>::value_t value_t;
typedef LazyValue<T> default_value_t;
ParamValue()
: mValue()
{}
ParamValue(const default_value_t& other)
: mValue(other)
{}
ParamValue(const T& value)
: mValue(value)
{}
void setValue(const value_t& val)
{
mValue.set(val);
}
const value_t& getValue() const
{
return mValue.get().getValue();
}
value_t& getValue()
{
return mValue.get().getValue();
}
bool deserializeBlock(Parser& p, Parser::name_stack_range_t& name_stack_range, bool new_name)
{
return mValue.get().deserializeBlock(p, name_stack_range, new_name);
}
bool serializeBlock(Parser& p, Parser::name_stack_t& name_stack, const predicate_rule_t predicate_rule, const self_t* diff_block = NULL) const
{
if (mValue.empty()) return false;
const BaseBlock* base_block = (diff_block && !diff_block->mValue.empty())
? &(diff_block->mValue.get().getValue())
: NULL;
return mValue.get().serializeBlock(p, name_stack, predicate_rule, base_block);
}
bool inspectBlock(Parser& p, Parser::name_stack_t name_stack = Parser::name_stack_t(), S32 min_count = 0, S32 max_count = S32_MAX) const
{
return mValue.get().inspectBlock(p, name_stack, min_count, max_count);
}
bool mergeBlockParam(bool source_provided, bool dst_provided, BlockDescriptor& block_data, const self_t& source, bool overwrite)
{
return source.mValue.empty() || mValue.get().mergeBlock(block_data, source.getValue(), overwrite);
}
bool validateBlock(bool emit_errors = true) const
{
return mValue.empty() || mValue.get().validateBlock(emit_errors);
}
bool isValid() const
{
return validateBlock(false);
}
static BlockDescriptor& getBlockDescriptor()
{
return value_t::getBlockDescriptor();
}
private:
LazyValue<T> mValue;
};
template<typename T, typename BLOCK_T>
class ParamValue <BaseBlock::Lazy<T, NOT_BLOCK>, BLOCK_T>
{
typedef ParamValue <BaseBlock::Lazy<T, NOT_BLOCK>, BLOCK_T> self_t;
public:
typedef typename InnerMostType<T>::value_t value_t;
typedef LazyValue<T> default_value_t;
ParamValue()
: mValue()
{}
ParamValue(const default_value_t& other)
: mValue(other)
{}
ParamValue(const T& value)
: mValue(value)
{}
void setValue(const value_t& val)
{
mValue.set(val);
}
const value_t& getValue() const
{
return mValue.get().getValue();
}
value_t& getValue()
{
return mValue.get().getValue();
}
bool isValid() const
{
return true;
}
private:
LazyValue<T> mValue;
};
template <>
class ParamValue <LLSD, NOT_BLOCK>
: public BaseBlock
{
public:
typedef LLSD value_t;
typedef LLSD default_value_t;
ParamValue()
{}
ParamValue(const default_value_t& other)
: mValue(other)
{}
void setValue(const value_t& val) { mValue = val; }
const value_t& getValue() const { return mValue; }
LLSD& getValue() { return mValue; }
// block param interface
LL_COMMON_API bool deserializeBlock(Parser& p, Parser::name_stack_range_t& name_stack_range, bool new_name);
LL_COMMON_API bool serializeBlock(Parser& p, Parser::name_stack_t& name_stack, const predicate_rule_t predicate_rule, const BaseBlock* diff_block = NULL) const;
bool inspectBlock(Parser& p, Parser::name_stack_t name_stack = Parser::name_stack_t(), S32 min_count = 0, S32 max_count = S32_MAX) const
{
//TODO: implement LLSD params as schema type Any
return true;
}
private:
static void serializeElement(Parser& p, const LLSD& sd, Parser::name_stack_t& name_stack);
LLSD mValue;
};
template<typename T>
class CustomParamValue
: public Block<ParamValue<T> >
{
public:
typedef enum e_value_age
{
VALUE_NEEDS_UPDATE, // mValue needs to be refreshed from the block parameters
VALUE_AUTHORITATIVE, // mValue holds the authoritative value (which has been replicated to the block parameters via updateBlockFromValue)
BLOCK_AUTHORITATIVE // mValue is derived from the block parameters, which are authoritative
} EValueAge;
typedef TypeValues<T> derived_t;
typedef CustomParamValue<T> self_t;
typedef Block<ParamValue<T> > block_t;
typedef T default_value_t;
typedef T value_t;
typedef void baseblock_base_class_t;
CustomParamValue(const default_value_t& value = T())
: mValue(value),
mValueAge(VALUE_AUTHORITATIVE)
{}
bool deserializeBlock(Parser& parser, Parser::name_stack_range_t& name_stack_range, bool new_name)
{
derived_t& typed_param = static_cast<derived_t&>(*this);
// try to parse direct value T
if (name_stack_range.first == name_stack_range.second)
{
if(parser.readValue(typed_param.mValue))
{
typed_param.mValueAge = VALUE_AUTHORITATIVE;
typed_param.updateBlockFromValue(false);
return true;
}
}
// fall back on parsing block components for T
return typed_param.BaseBlock::deserializeBlock(parser, name_stack_range, new_name);
}
bool serializeBlock(Parser& parser, Parser::name_stack_t& name_stack, const predicate_rule_t predicate_rule, const BaseBlock* diff_block = NULL) const
{
const derived_t& typed_param = static_cast<const derived_t&>(*this);
const derived_t* diff_param = static_cast<const derived_t*>(diff_block);
//std::string key = typed_param.getValueName();
//// first try to write out name of name/value pair
//if (!key.empty())
//{
// if (!diff_param || !ParamCompare<std::string>::equals(diff_param->getValueName(), key))
// {
// return parser.writeValue(key, name_stack);
// }
//}
// then try to serialize value directly
if (!diff_param || !ParamCompare<T>::equals(typed_param.getValue(), diff_param->getValue()))
{
if (parser.writeValue(typed_param.getValue(), name_stack))
{
return true;
}
else
{
//RN: *always* serialize provided components of BlockValue (don't pass diff_param on),
// since these tend to be viewed as the constructor arguments for the value T. It seems
// cleaner to treat the uniqueness of a BlockValue according to the generated value, and
// not the individual components. This way <color red="0" green="1" blue="0"/> will not
// be exported as <color green="1"/>, since it was probably the intent of the user to
// be specific about the RGB color values. This also fixes an issue where we distinguish
// between rect.left not being provided and rect.left being explicitly set to 0 (same as default)
if (typed_param.mValueAge == VALUE_AUTHORITATIVE)
{
// if the value is authoritative but the parser doesn't accept the value type
// go ahead and make a copy, and splat the value out to its component params
// and serialize those params
derived_t copy(typed_param);
copy.updateBlockFromValue(true);
return copy.block_t::serializeBlock(parser, name_stack, predicate_rule, NULL);
}
else
{
return block_t::serializeBlock(parser, name_stack, predicate_rule, NULL);
}
}
}
return false;
}
bool validateBlock(bool emit_errors = true) const
{
if (mValueAge == VALUE_NEEDS_UPDATE)
{
if (block_t::validateBlock(emit_errors))
{
// clear stale keyword associated with old value
mValueAge = BLOCK_AUTHORITATIVE;
static_cast<derived_t*>(const_cast<self_t*>(this))->updateValueFromBlock();
return true;
}
else
{
//block value incomplete, so not considered provided
// will attempt to revalidate on next call to isProvided()
return false;
}
}
else
{
// we have a valid value in hand
return true;
}
}
// propagate change status up to enclosing block
/*virtual*/ void paramChanged(const Param& changed_param, bool user_provided)
{
BaseBlock::paramChanged(changed_param, user_provided);
if (user_provided)
{
// a parameter changed, so our value is out of date
mValueAge = VALUE_NEEDS_UPDATE;
}
}
void setValue(const value_t& val)
{
// set param version number to be up to date, so we ignore block contents
mValueAge = VALUE_AUTHORITATIVE;
mValue = val;
static_cast<derived_t*>(this)->updateBlockFromValue(false);
}
const value_t& getValue() const
{
validateBlock(true);
return mValue;
}
T& getValue()
{
validateBlock(true);
return mValue;
}
protected:
// use this from within updateValueFromBlock() to set the value without making it authoritative
void updateValue(const value_t& value)
{
mValue = value;
}
bool mergeBlockParam(bool source_provided, bool dst_provided, BlockDescriptor& block_data, const BaseBlock& source, bool overwrite)
{
bool source_override = source_provided && (overwrite || !dst_provided);
const derived_t& src_typed_param = static_cast<const derived_t&>(source);
if (source_override && src_typed_param.mValueAge == VALUE_AUTHORITATIVE)
{
// copy value over
setValue(src_typed_param.getValue());
return true;
}
// merge individual parameters into destination
if (mValueAge == VALUE_AUTHORITATIVE)
{
static_cast<derived_t*>(this)->updateBlockFromValue(dst_provided);
}
return mergeBlock(block_data, source, overwrite);
}
bool mergeBlock(BlockDescriptor& block_data, const BaseBlock& source, bool overwrite)
{
return block_t::mergeBlock(block_data, source, overwrite);
}
private:
mutable T mValue;
mutable EValueAge mValueAge;
};
}
#endif // LL_LLPARAM_H
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