// TnzCore includes
#include "trandom.h"
#include "tutil.h"
#include "tconvert.h"
// TnzBase includes
#include "ttokenizer.h"
#include "tunit.h"
#include "tparser.h"
#include "tdoubleparam.h"
#include "tdoublekeyframe.h"
// STD includes
#include <map>
#include <math.h>
#include <functional>
#include <memory>
// Qt includes
#include <QString>
#include "tgrammar.h"
const double PI = 4 * atan(1.0);
const double toDeg(double rad) { return rad * 180.0 / PI; }
const double toRad(double deg) { return deg / 180.0 * PI; }
namespace TSyntax
{
//===================================================================
//
// RandomManager
//
// es. x = RandomManager::instance()->getValue(seed, frame);
//
//-------------------------------------------------------------------
class RandomSequence
{
TRandom m_rnd;
std::vector<double> m_values;
public:
RandomSequence(UINT seed) : m_rnd(seed) {}
double getValue(int i)
{
assert(i >= 0);
if (i >= (int)m_values.size()) {
m_values.reserve(i + 1);
while (i >= (int)m_values.size())
m_values.push_back(m_rnd.getDouble());
}
return m_values[i];
}
};
//-------------------------------------------------------------------
class RandomManager
{ // singleton
typedef std::map<UINT, RandomSequence *> Table;
Table m_table;
RandomManager() {}
public:
~RandomManager()
{
for (Table::iterator i = m_table.begin(); i != m_table.end(); ++i)
delete i->second;
}
static RandomManager *instance()
{
static RandomManager _instance;
return &_instance;
}
RandomSequence *getSequence(UINT seed)
{
Table::iterator i = m_table.find(seed);
if (i == m_table.end()) {
RandomSequence *seq = new RandomSequence(seed);
m_table[seed] = seq;
return seq;
} else
return i->second;
}
double getValue(UINT seed, double t)
{
RandomSequence *seq = getSequence(seed);
return seq->getValue(t > 0 ? tfloor(t) : 0);
}
};
//===================================================================
// Calculator
//-------------------------------------------------------------------
Calculator::Calculator()
: m_rootNode(0), m_param(0), m_unit(0)
{
}
//-------------------------------------------------------------------
Calculator::~Calculator()
{
delete m_rootNode;
}
//-------------------------------------------------------------------
void Calculator::setRootNode(CalculatorNode *node)
{
if (node != m_rootNode) {
delete m_rootNode;
m_rootNode = node;
}
}
//===================================================================
// Nodes
//-------------------------------------------------------------------
template <class Op>
class Op0Node : public CalculatorNode
{
public:
Op0Node(Calculator *calc)
: CalculatorNode(calc) {}
double compute(double vars[3]) const
{
Op op;
return op();
}
};
//-------------------------------------------------------------------
template <class Op>
class Op1Node : public CalculatorNode
{
protected:
std::auto_ptr<CalculatorNode> m_a;
public:
Op1Node(Calculator *calc, CalculatorNode *a)
: CalculatorNode(calc), m_a(a) {}
double compute(double vars[3]) const
{
Op op;
return op(m_a->compute(vars));
}
void accept(CalculatorNodeVisitor &visitor) { m_a->accept(visitor); }
};
//-------------------------------------------------------------------
template <class Op>
class Op2Node : public CalculatorNode
{
protected:
std::auto_ptr<CalculatorNode> m_a, m_b;
public:
Op2Node(Calculator *calc, CalculatorNode *a, CalculatorNode *b)
: CalculatorNode(calc), m_a(a), m_b(b) {}
double compute(double vars[3]) const
{
Op op;
return op(m_a->compute(vars), m_b->compute(vars));
}
void accept(CalculatorNodeVisitor &visitor)
{
m_a->accept(visitor), m_b->accept(visitor);
}
};
//-------------------------------------------------------------------
template <class Op>
class Op3Node : public CalculatorNode
{
protected:
std::auto_ptr<CalculatorNode> m_a, m_b, m_c;
public:
Op3Node(Calculator *calc, CalculatorNode *a, CalculatorNode *b, CalculatorNode *c)
: CalculatorNode(calc), m_a(a), m_b(b), m_c(c) {}
double compute(double vars[3]) const
{
Op op;
return op(m_a->compute(vars), m_b->compute(vars), m_c->compute(vars));
}
void accept(CalculatorNodeVisitor &visitor)
{
m_a->accept(visitor), m_b->accept(visitor), m_c->accept(visitor);
}
};
//-------------------------------------------------------------------
class ChsNode : public CalculatorNode
{
std::auto_ptr<CalculatorNode> m_a;
public:
ChsNode(Calculator *calc, CalculatorNode *a) : CalculatorNode(calc), m_a(a) {}
double compute(double vars[3]) const { return -m_a->compute(vars); }
void accept(CalculatorNodeVisitor &visitor) { m_a->accept(visitor); }
};
//-------------------------------------------------------------------
class QuestionNode : public CalculatorNode
{
std::auto_ptr<CalculatorNode> m_a, m_b, m_c;
public:
QuestionNode(Calculator *calc, CalculatorNode *a, CalculatorNode *b, CalculatorNode *c)
: CalculatorNode(calc), m_a(a), m_b(b), m_c(c) {}
double compute(double vars[3]) const
{
return (m_a->compute(vars) != 0) ? m_b->compute(vars) : m_c->compute(vars);
}
void accept(CalculatorNodeVisitor &visitor)
{
m_a->accept(visitor), m_b->accept(visitor), m_c->accept(visitor);
}
};
//-------------------------------------------------------------------
class NotNode : public CalculatorNode
{
std::auto_ptr<CalculatorNode> m_a;
public:
NotNode(Calculator *calc, CalculatorNode *a) : CalculatorNode(calc), m_a(a) {}
double compute(double vars[3]) const { return m_a->compute(vars) == 0; }
void accept(CalculatorNodeVisitor &visitor) { m_a->accept(visitor); }
};
//-------------------------------------------------------------------
class CycleNode : public CalculatorNode
{
std::auto_ptr<CalculatorNode> m_a;
public:
CycleNode(Calculator *calc, CalculatorNode *a) : CalculatorNode(calc), m_a(a) {}
double compute(double vars[3]) const
{
struct locals {
static inline double compute(const TDoubleParam ¶m, double f)
{
if (param.getKeyframeCount() >= 2 && f < param.keyframeIndexToFrame(0)) {
TDoubleKeyframe kf = param.getKeyframe(0);
if (kf.m_type == TDoubleKeyframe::Expression || kf.m_type == TDoubleKeyframe::SimilarShape)
return param.getDefaultValue();
}
double value = param.getValue(f);
return value;
}
};
double delta = std::max(1.0, m_a->compute(vars));
const TDoubleParam *ownerParam = getCalculator()->getOwnerParameter();
if (!ownerParam)
return 0;
double value = locals::compute(*ownerParam, vars[FRAME] - 1 - delta);
if (getCalculator()->getUnit())
value = getCalculator()->getUnit()->convertTo(value);
return value;
}
void accept(CalculatorNodeVisitor &visitor) { m_a->accept(visitor); }
};
//-------------------------------------------------------------------
class RandomNode : public CalculatorNode
{
std::auto_ptr<CalculatorNode> m_seed, m_min, m_max, m_arg;
public:
RandomNode(Calculator *calc) : CalculatorNode(calc), m_seed(0), m_min(0), m_max(0)
{
m_arg.reset(new VariableNode(calc, CalculatorNode::FRAME));
}
void setSeed(CalculatorNode *arg)
{
assert(m_seed.get() == 0);
m_seed.reset(arg);
}
void setMax(CalculatorNode *arg)
{
assert(m_max.get() == 0);
m_max.reset(arg);
}
void setMin(CalculatorNode *arg)
{
assert(m_min.get() == 0);
m_min.reset(arg);
}
double compute(double vars[3]) const
{
double s = (m_seed.get() != 0) ? m_seed->compute(vars) : 0;
double r = RandomManager::instance()->getValue(s, fabs(m_arg->compute(vars)));
if (m_min.get() == 0)
if (m_max.get() == 0)
return r;
else
return m_max->compute(vars) * r;
else
return (1 - r) * m_min->compute(vars) + r * m_max->compute(vars);
}
void accept(CalculatorNodeVisitor &visitor)
{
m_arg->accept(visitor);
if (m_seed.get())
m_seed->accept(visitor);
if (m_min.get())
m_min->accept(visitor);
if (m_max.get())
m_max->accept(visitor);
}
};
//===================================================================
// Patterns
//-------------------------------------------------------------------
CalculatorNode *Pattern::popNode(std::vector<CalculatorNode *> &stack) const
{
CalculatorNode *node = stack.back();
stack.pop_back();
return node;
}
//===================================================================
class NumberPattern : public Pattern
{
public:
bool matchToken(const std::vector<Token> &previousTokens, const Token &token) const
{
return previousTokens.empty() && token.getType() == Token::Number;
}
bool isFinished(const std::vector<Token> &previousTokens, const Token &token) const
{
return previousTokens.size() == 1;
}
TokenType getTokenType(const std::vector<Token> &previousTokens, const Token &token) const
{
return Number;
}
void createNode(
Calculator *calc,
std::vector<CalculatorNode *> &stack,
const std::vector<Token> &tokens) const
{
assert(tokens.size() == 1);
assert(tokens[0].getType() == Token::Number);
stack.push_back(new NumberNode(calc, tokens[0].getDoubleValue()));
}
};
//-------------------------------------------------------------------
class ConstantPattern : public Pattern
{
std::string m_constantName;
double m_value;
public:
ConstantPattern(std::string constantName, double value, std::string description = "")
: m_constantName(constantName), m_value(value)
{
setDescription(description);
}
std::string getFirstKeyword() const { return m_constantName; }
bool matchToken(const std::vector<Token> &previousTokens, const Token &token) const
{
return previousTokens.empty() && token.getText() == m_constantName;
}
bool isFinished(const std::vector<Token> &previousTokens, const Token &token) const
{
return previousTokens.size() == 1;
}
TokenType getTokenType(const std::vector<Token> &previousTokens, const Token &token) const
{
return Constant;
}
void createNode(
Calculator *calc,
std::vector<CalculatorNode *> &stack,
const std::vector<Token> &tokens) const
{
assert(tokens.size() == 1);
stack.push_back(new NumberNode(calc, m_value));
}
};
//-------------------------------------------------------------------
class VariablePattern : public Pattern
{
std::string m_variableName;
int m_varIdx;
public:
VariablePattern(std::string variableName, int varIdx, std::string description = "")
: m_variableName(variableName), m_varIdx(varIdx)
{
setDescription(description);
}
std::string getFirstKeyword() const { return m_variableName; }
bool matchToken(const std::vector<Token> &previousTokens, const Token &token) const
{
return previousTokens.empty() && token.getText() == m_variableName;
}
bool isFinished(const std::vector<Token> &previousTokens, const Token &token) const
{
return previousTokens.size() == 1;
}
TokenType getTokenType(const std::vector<Token> &previousTokens, const Token &token) const
{
return Variable;
}
void createNode(
Calculator *calc,
std::vector<CalculatorNode *> &stack,
const std::vector<Token> &tokens) const
{
assert(tokens.size() == 1);
assert(tokens[0].getText() == m_variableName);
stack.push_back(new VariableNode(calc, m_varIdx));
}
};
//-------------------------------------------------------------------
template <class Op>
class Op2Pattern : public Pattern
{
std::string m_opName;
int m_priority;
public:
Op2Pattern(std::string opName, int priority)
: m_opName(opName), m_priority(priority) {}
int getPriority() const { return m_priority; }
std::string getFirstKeyword() const { return m_opName; }
bool expressionExpected(const std::vector<Token> &previousTokens) const
{
return previousTokens.empty() || previousTokens.size() == 2;
}
bool matchToken(const std::vector<Token> &previousTokens, const Token &token) const
{
return previousTokens.size() == 1 && token.getText() == m_opName;
}
bool isFinished(const std::vector<Token> &previousTokens, const Token &token) const
{
return previousTokens.size() == 3;
}
TokenType getTokenType(const std::vector<Token> &previousTokens, const Token &token) const
{
return previousTokens.size() == 1 ? Operator : InternalError;
}
void createNode(
Calculator *calc,
std::vector<CalculatorNode *> &stack,
const std::vector<Token> &tokens) const
{
assert(tokens.size() == 3);
assert(tokens[1].getText() == m_opName);
CalculatorNode *b = popNode(stack);
CalculatorNode *a = popNode(stack);
stack.push_back(new Op2Node<Op>(calc, a, b));
}
};
//-------------------------------------------------------------------
class UnaryMinusPattern : public Pattern
{
public:
UnaryMinusPattern() {}
int getPriority() const { return 50; }
std::string getFirstKeyword() const { return "-"; }
bool expressionExpected(const std::vector<Token> &previousTokens) const
{
return previousTokens.size() == 1;
}
bool matchToken(const std::vector<Token> &previousTokens, const Token &token) const
{
return previousTokens.empty() && token.getText() == "-";
}
bool isFinished(const std::vector<Token> &previousTokens, const Token &token) const
{
return previousTokens.size() == 2;
}
TokenType getTokenType(const std::vector<Token> &previousTokens, const Token &token) const
{
return Operator;
}
void createNode(
Calculator *calc,
std::vector<CalculatorNode *> &stack,
const std::vector<Token> &tokens) const
{
assert(tokens.size() == 2);
assert(tokens[0].getText() == "-");
stack.push_back(new ChsNode(calc, popNode(stack)));
}
};
//-------------------------------------------------------------------
class NotPattern : public Pattern
{
std::string m_prefix;
public:
NotPattern(std::string prefix, std::string description) : m_prefix(prefix)
{
setDescription(description);
}
int getPriority() const { return 5; }
std::string getFirstKeyword() const { return m_prefix; }
bool expressionExpected(const std::vector<Token> &previousTokens) const
{
return previousTokens.size() == 1;
}
bool matchToken(const std::vector<Token> &previousTokens, const Token &token) const
{
return previousTokens.empty() && token.getText() == m_prefix;
}
bool isFinished(const std::vector<Token> &previousTokens, const Token &token) const
{
return previousTokens.size() == 2;
}
TokenType getTokenType(const std::vector<Token> &previousTokens, const Token &token) const
{
return Operator;
}
void createNode(
Calculator *calc,
std::vector<CalculatorNode *> &stack,
const std::vector<Token> &tokens) const
{
assert(tokens.size() == 2);
assert(tokens[0].getText() == m_prefix);
stack.push_back(new NotNode(calc, popNode(stack)));
}
};
//-------------------------------------------------------------------
class QuestionTernaryPattern : public Pattern
{
public:
QuestionTernaryPattern() {}
int getPriority() const { return 5; }
std::string getFirstKeyword() const { return "?"; }
bool expressionExpected(const std::vector<Token> &previousTokens) const
{
int i = (int)previousTokens.size();
return i == 0 || i == 2 || i == 4;
}
bool matchToken(const std::vector<Token> &previousTokens, const Token &token) const
{
int i = (int)previousTokens.size();
return i == 1 && token.getText() == "?" || i == 3 && token.getText() == ":";
}
bool isFinished(const std::vector<Token> &previousTokens, const Token &token) const
{
return previousTokens.size() == 5;
}
TokenType getTokenType(const std::vector<Token> &previousTokens, const Token &token) const
{
int i = (int)previousTokens.size();
return (i == 1 || i == 3) ? Operator : InternalError;
}
void createNode(
Calculator *calc,
std::vector<CalculatorNode *> &stack,
const std::vector<Token> &tokens) const
{
CalculatorNode *node1 = popNode(stack);
CalculatorNode *node2 = popNode(stack);
CalculatorNode *node3 = popNode(stack);
stack.push_back(new QuestionNode(calc, node3, node2, node1));
}
};
//-------------------------------------------------------------------
class BraketPattern : public Pattern
{
public:
BraketPattern() {}
int getPriority() const { return 5; }
std::string getFirstKeyword() const { return "("; }
bool expressionExpected(const std::vector<Token> &previousTokens) const
{
return previousTokens.size() == 1;
}
bool matchToken(const std::vector<Token> &previousTokens, const Token &token) const
{
return previousTokens.empty() && token.getText() == "(" ||
previousTokens.size() == 2 && token.getText() == ")";
}
bool isFinished(const std::vector<Token> &previousTokens, const Token &token) const
{
return previousTokens.size() == 3;
}
TokenType getTokenType(const std::vector<Token> &previousTokens, const Token &token) const
{
return previousTokens.size() != 1 ? Parenthesis : InternalError;
}
void createNode(
Calculator *calc,
std::vector<CalculatorNode *> &stack,
const std::vector<Token> &tokens) const
{
assert(tokens.size() == 3);
assert(tokens[0].getText() == "(");
assert(tokens[2].getText() == ")");
}
};
//-------------------------------------------------------------------
class FunctionPattern : public Pattern
{
protected:
std::string m_functionName;
bool m_implicitArgAllowed;
// if m_implicitArgAllowed == true then the first argument is the frame number
// e.g. f(5) means f(frame,5)
// to use a different first argument (e.g. t*10) you have to write f(t*10;5)
int m_minArgCount;
std::vector<double> m_optionalArgDefaults;
public:
FunctionPattern(std::string functionName, int minArgCount)
: m_functionName(functionName), m_implicitArgAllowed(false), m_minArgCount(minArgCount)
{
}
void allowImplicitArg(bool allowed) { m_implicitArgAllowed = allowed; }
void addOptionalArg(double value) { m_optionalArgDefaults.push_back(value); }
std::string getFirstKeyword() const { return m_functionName; }
bool expressionExpected(const std::vector<Token> &previousTokens) const
{
int n = (int)previousTokens.size();
return 2 <= n && (n & 1) == 0;
}
bool matchToken(const std::vector<Token> &previousTokens, const Token &token) const
{
int i = (int)previousTokens.size();
std::string s = toLower(token.getText());
if (i == 0)
return s == toLower(m_functionName);
else if (i == 1)
return s == "(";
else if ((i & 1) == 0)
return true;
else if (s == ",")
return true;
else if (s == ";")
return i == 3 && m_implicitArgAllowed;
else if (s == ")") {
int n = (i - 1) / 2;
if (previousTokens.size() > 3 && previousTokens[3].getText() == ";")
n--;
if (n < m_minArgCount || n > m_minArgCount + (int)m_optionalArgDefaults.size())
return false;
else
return true;
} else
return false;
}
bool isFinished(const std::vector<Token> &previousTokens, const Token &token) const
{
if (previousTokens.empty())
return false;
return m_minArgCount == 0 && previousTokens.size() == 1 && token.getText() != "(" ||
previousTokens.back().getText() == ")";
}
TokenType getTokenType(const std::vector<Token> &previousTokens, const Token &token) const
{
int i = (int)previousTokens.size();
if (i == 0)
return Function;
else if (i == 1 || token.getText() == ")")
return Function;
else if (i == 3)
return token.getText() == ";" ? Comma : Comma;
else if (i & 1)
return Comma;
else
return InternalError;
}
void getArgs(
std::vector<CalculatorNode *> &nodes,
Calculator *calc, std::vector<CalculatorNode *> &stack,
const std::vector<Token> &tokens) const
{
bool implicitArgUsed = m_implicitArgAllowed && tokens.size() > 3 && tokens[3].getText() == ";";
// n = number of arguments to provide (mandatory + optional + implicit)
int n = m_minArgCount + (int)m_optionalArgDefaults.size() + (m_implicitArgAllowed ? 1 : 0);
// m = number of default arguments to assign (with their default value)
int m = n - (tokens.size() - 2) / 2;
if (m_implicitArgAllowed && !implicitArgUsed)
m--;
assert(m <= (int)m_optionalArgDefaults.size());
if (m > (int)m_optionalArgDefaults.size())
m = (int)m_optionalArgDefaults.size();
nodes.resize(n);
// fetch arguments from the stack
int k = n - m;
if (implicitArgUsed) {
while (k > 0)
nodes[--k] = popNode(stack);
} else {
while (k > 1)
nodes[--k] = popNode(stack);
nodes[0] = new VariableNode(calc, CalculatorNode::FRAME);
}
// add default values
for (int i = 0; i < m; i++)
nodes[n - m + i] = new NumberNode(calc, m_optionalArgDefaults[i]);
}
};
//-------------------------------------------------------------------
template <class Function>
class F0Pattern : public FunctionPattern
{
public:
F0Pattern(std::string functionName) : FunctionPattern(functionName, 0) {}
void createNode(Calculator *calc, std::vector<CalculatorNode *> &stack,
const std::vector<Token> &tokens) const
{
stack.push_back(new Op0Node<Function>(calc, m_functionName));
}
};
//-------------------------------------------------------------------
template <class Function>
class F1Pattern : public FunctionPattern
{
public:
F1Pattern(std::string functionName, std::string descr = "") : FunctionPattern(functionName, 1) { setDescription(descr); }
void createNode(Calculator *calc, std::vector<CalculatorNode *> &stack,
const std::vector<Token> &tokens) const
{
stack.push_back(new Op1Node<Function>(calc, popNode(stack)));
}
};
//-------------------------------------------------------------------
template <class Function>
class F2Pattern : public FunctionPattern
{
public:
F2Pattern(std::string functionName, std::string descr = "") : FunctionPattern(functionName, 2) { setDescription(descr); }
void createNode(Calculator *calc, std::vector<CalculatorNode *> &stack,
const std::vector<Token> &tokens) const
{
CalculatorNode *b = popNode(stack);
CalculatorNode *a = popNode(stack);
stack.push_back(new Op2Node<Function>(calc, a, b));
}
};
//-------------------------------------------------------------------
template <class Function>
class F3Pattern : public FunctionPattern
{
public:
F3Pattern(std::string functionName, std::string descr = "") : FunctionPattern(functionName, 3) { setDescription(descr); }
void createNode(Calculator *calc, std::vector<CalculatorNode *> &stack,
const std::vector<Token> &tokens) const
{
CalculatorNode *c = popNode(stack);
CalculatorNode *b = popNode(stack);
CalculatorNode *a = popNode(stack);
stack.push_back(new Op3Node<Function>(calc, a, b, c));
}
};
//-------------------------------------------------------------------
template <class Function>
class Fs2Pattern : public FunctionPattern
{
public:
Fs2Pattern(std::string functionName, std::string description)
: FunctionPattern(functionName, 1)
{
allowImplicitArg(true);
setDescription(description);
}
void createNode(Calculator *calc, std::vector<CalculatorNode *> &stack,
const std::vector<Token> &tokens) const
{
std::vector<CalculatorNode *> nodes;
getArgs(nodes, calc, stack, tokens);
stack.push_back(new Op2Node<Function>(calc, nodes[0], nodes[1]));
}
};
//-------------------------------------------------------------------
template <class Function>
class Fs3Pattern : public FunctionPattern
{
public:
Fs3Pattern(std::string functionName, double defVal, std::string descr)
: FunctionPattern(functionName, 1)
{
allowImplicitArg(true);
addOptionalArg(defVal);
setDescription(descr);
}
void createNode(Calculator *calc, std::vector<CalculatorNode *> &stack,
const std::vector<Token> &tokens) const
{
std::vector<CalculatorNode *> nodes;
getArgs(nodes, calc, stack, tokens);
stack.push_back(new Op3Node<Function>(calc, nodes[0], nodes[1], nodes[2]));
}
};
//-------------------------------------------------------------------
class CyclePattern : public FunctionPattern
{
public:
CyclePattern(std::string functionName) : FunctionPattern(functionName, 1)
{
setDescription("cycle(period)\nCycles the transitions of the period previous frames to the selected range");
}
void createNode(Calculator *calc, std::vector<CalculatorNode *> &stack,
const std::vector<Token> &tokens) const
{
CalculatorNode *a = popNode(stack);
stack.push_back(new CycleNode(calc, a));
}
};
//-------------------------------------------------------------------
class RandomPattern : public FunctionPattern
{
bool m_seed;
public:
RandomPattern(std::string functionName, bool seed, std::string description)
: FunctionPattern(functionName, seed ? 1 : 0), m_seed(seed)
{
allowImplicitArg(true);
addOptionalArg(0);
addOptionalArg(0);
setDescription(description);
}
void createNode(Calculator *calc, std::vector<CalculatorNode *> &stack,
const std::vector<Token> &tokens) const
{
int n = ((int)tokens.size() - 1) / 2;
if (m_seed)
n--;
RandomNode *randomNode = new RandomNode(calc);
if (n > 0) {
randomNode->setMax(popNode(stack));
if (n > 1)
randomNode->setMin(popNode(stack));
}
if (m_seed)
randomNode->setSeed(popNode(stack));
stack.push_back(randomNode);
}
};
//===================================================================
class PatternTable
{
std::map<std::string, Pattern *> m_kTable;
std::vector<Pattern *> m_uTable;
Grammar::Position m_position;
public:
PatternTable(Grammar::Position position) : m_position(position) {}
~PatternTable()
{
for (std::map<std::string, Pattern *>::iterator
it = m_kTable.begin();
it != m_kTable.end(); ++it)
delete it->second;
for (std::vector<Pattern *>::iterator
it = m_uTable.begin();
it != m_uTable.end(); ++it)
delete *it;
}
void addPattern(Pattern *pattern)
{
std::string keyword = pattern->getFirstKeyword();
if (keyword != "") {
// first keyword should be unique
assert(m_kTable.count(keyword) == 0);
m_kTable[keyword] = pattern;
} else
m_uTable.push_back(pattern);
}
const Pattern *getPattern(const Token &token) const
{
std::vector<Token> tokens;
if (m_position == Grammar::ExpressionEnd)
tokens.push_back(Token());
if (token.getType() == Token::Punct || token.getType() == Token::Ident) {
std::string keyword = token.getText();
std::map<std::string, Pattern *>::const_iterator it = m_kTable.find(keyword);
if (it != m_kTable.end()) {
Pattern *pattern = it->second;
if (pattern->matchToken(tokens, token)) {
return pattern;
}
}
}
for (int i = 0; i < (int)m_uTable.size(); i++) {
Pattern *pattern = m_uTable[i];
if (pattern->matchToken(tokens, token)) {
return pattern;
}
}
return 0;
}
void getSuggestions(Grammar::Suggestions &suggestions) const
{
std::map<std::string, Pattern *>::const_iterator it;
for (it = m_kTable.begin(); it != m_kTable.end(); ++it) {
suggestions.push_back(std::make_pair(it->first, it->second->getDescription()));
}
for (int i = 0; i < (int)m_uTable.size(); i++) {
std::vector<std::string> keywords;
m_uTable[i]->getAcceptableKeywords(keywords);
for (int j = 0; j < (int)keywords.size(); j++)
suggestions.push_back(std::make_pair(keywords[j], m_uTable[i]->getDescription()));
}
}
};
//===================================================================
//
// funzioni trigonometriche, log, exp, ecc.
//
//-------------------------------------------------------------------
class Pow
{
public:
double operator()(double x, double y) const { return pow(x, y); }
};
// class Mod {public: double operator()(double x, double y) const {return (int)x % (int)y;} };
class Sin
{
public:
double operator()(double x) const { return sin(toRad(x)); }
};
class Cos
{
public:
double operator()(double x) const { return cos(toRad(x)); }
};
class Tan
{
public:
double operator()(double x) const { return tan(toRad(x)); }
};
class Sinh
{
public:
double operator()(double x) const { return sinh(toRad(x)); }
};
class Cosh
{
public:
double operator()(double x) const { return cosh(toRad(x)); }
};
class Tanh
{
public:
double operator()(double x) const { return tanh(toRad(x)); }
};
class Atan
{
public:
double operator()(double x) const { return toDeg(atan(x)); }
};
class Atan2
{
public:
double operator()(double x, double y) const { return toDeg(atan2(x, y)); }
};
class Log
{
public:
double operator()(double x) const { return log(x); }
};
class Exp
{
public:
double operator()(double x) const { return exp(x); }
};
class Floor
{
public:
double operator()(double x) const { return tfloor(x); }
};
class Ceil
{
public:
double operator()(double x) const { return tceil(x); }
};
class Round
{
public:
double operator()(double x) const { return tround(x); }
};
class Abs
{
public:
double operator()(double x) const { return fabs(x); }
};
class Sign
{
public:
double operator()(double x) const { return x > 0 ? 1 : x < 0 ? -1 : 0; }
};
class Sqrt
{
public:
double operator()(double x) const { return x >= 0.0 ? sqrt(x) : 0; }
};
class Sqr
{
public:
double operator()(double x) const { return x * x; }
};
class Crop
{
public:
double operator()(double x, double a, double b) const { return tcrop(x, a, b); }
};
class Step
{
public:
double operator()(double x, double y) const { return x < y ? 0 : 1; }
};
class Mod
{
public:
double operator()(double x, double y) const
{
if (y == 0.0)
return 0;
return x - y * floor(x / y);
}
};
class Min
{
public:
double operator()(double x, double y) const { return x < y ? x : y; }
};
class Max
{
public:
double operator()(double x, double y) const { return x > y ? x : y; }
};
class Gt
{
public:
double operator()(double x, double y) const { return x > y ? 1 : 0; }
};
class Ge
{
public:
double operator()(double x, double y) const { return x >= y ? 1 : 0; }
};
class Lt
{
public:
double operator()(double x, double y) const { return x < y ? 1 : 0; }
};
class Le
{
public:
double operator()(double x, double y) const { return x <= y ? 1 : 0; }
};
class Ne
{
public:
double operator()(double x, double y) const { return x != y ? 1 : 0; }
};
class Eq
{
public:
double operator()(double x, double y) const { return x == y ? 1 : 0; }
};
class And
{
public:
double operator()(double x, double y) const { return (x != 0) && (y != 0) ? 1 : 0; }
};
class Or
{
public:
double operator()(double x, double y) const { return (x != 0) || (y != 0) ? 1 : 0; }
};
class Not
{
public:
double operator()(double x) const { return x == 0; }
};
class Smoothstep
{
public:
double operator()(double v, double min, double max) const
{
if (v <= min)
return 0;
else if (v >= max)
return 1;
double t = (v - min) / (max - min);
return -2 * t * t * t + 3 * t * t;
}
};
class Pulse
{
public:
double operator()(double x, double x0, double length) const
{
// double length=5.0;
double b = (.69315 * 4.0) / (length * length);
x -= x0;
return exp(-x * x * b);
}
};
class Saw
{
public:
double operator()(double x, double length, double height) const
{
if (length <= 0.0)
return 0.0;
if (height <= 0.0)
height = length;
double q = x / length;
return height * (q - floor(q));
}
};
class Wave
{
public:
double operator()(double x, double length) const
{
if (length <= 0.0)
return 0.0;
return sin(x * 2 * PI / length);
}
};
//===================================================================
class Grammar::Imp
{
public:
PatternTable m_prePatterns, m_postPatterns;
Imp()
: m_prePatterns(Grammar::ExpressionStart), m_postPatterns(Grammar::ExpressionEnd)
{
}
~Imp() {}
};
Grammar::Grammar()
: m_imp(new Imp())
{
addPattern(new NumberPattern());
addPattern(new ConstantPattern("pi", PI, "3.14159265..."));
addPattern(new VariablePattern("t", CalculatorNode::T, "ranges from 0.0 to 1.0 along the transition"));
const std::string f_desc = "the current frame number";
addPattern(new VariablePattern("f", CalculatorNode::FRAME, f_desc));
addPattern(new VariablePattern("frame", CalculatorNode::FRAME, f_desc));
const std::string r_desc = "the current frame number, relative to the transition";
addPattern(new VariablePattern("r", CalculatorNode::RFRAME, r_desc));
addPattern(new VariablePattern("rframe", CalculatorNode::RFRAME, r_desc));
addPattern(new Op2Pattern<std::plus<double>>("+", 10));
addPattern(new Op2Pattern<std::multiplies<double>>("*", 20));
addPattern(new Op2Pattern<Pow>("^", 30));
addPattern(new Op2Pattern<std::minus<double>>("-", 10));
addPattern(new Op2Pattern<std::divides<double>>("/", 20));
addPattern(new Op2Pattern<Mod>("%", 8));
addPattern(new Op2Pattern<Gt>(">", 6));
addPattern(new Op2Pattern<Ge>(">=", 6));
addPattern(new Op2Pattern<Lt>("<", 6));
addPattern(new Op2Pattern<Le>("<=", 6));
addPattern(new Op2Pattern<Eq>("==", 6));
addPattern(new Op2Pattern<Ne>("!=", 6));
addPattern(new Op2Pattern<And>("&&", 3));
addPattern(new Op2Pattern<Or>("||", 2));
addPattern(new Op2Pattern<And>("and", 3));
addPattern(new Op2Pattern<Or>("or", 2));
addPattern(new NotPattern("!", "not"));
addPattern(new NotPattern("not", ""));
addPattern(new UnaryMinusPattern());
addPattern(new BraketPattern());
addPattern(new QuestionTernaryPattern());
addPattern(new F1Pattern<Sin>("sin", "sin(degree)"));
addPattern(new F1Pattern<Cos>("cos", "cos(degree)"));
addPattern(new F1Pattern<Tan>("tan", "tan(degree)"));
addPattern(new F1Pattern<Sinh>("sinh", "sinh(degree)\nHyperbolic sine"));
addPattern(new F1Pattern<Cosh>("cosh", "cosh(degree)\nHyperbolic cosine"));
addPattern(new F1Pattern<Tanh>("tanh", "tanh(degree)\nHyperbolic tangent"));
addPattern(new F1Pattern<Atan>("atan", "atan(x)\nArctangent : the inverse of tan()"));
addPattern(new F2Pattern<Atan2>("atan2", "atan2(y,x)\nThe counter-clockwise angle in degree between the x-axis and the point(x,y)"));
addPattern(new F1Pattern<Log>("log", "log(x)\nThe natural logarithm of x (base e)"));
addPattern(new F1Pattern<Exp>("exp", "exp(x)\nThe base-e exponential of x"));
addPattern(new F1Pattern<Floor>("floor", "floor(x)\nThe greatest integer <= x"));
const std::string ceil_desc = "The smallest integer >= x";
addPattern(new F1Pattern<Ceil>("ceil", "ceil(x)\n" + ceil_desc));
addPattern(new F1Pattern<Ceil>("ceiling", "ceiling(x)\n" + ceil_desc));
addPattern(new F1Pattern<Round>("round", "round(x)\nThe integer nearest to x"));
addPattern(new F1Pattern<Abs>("abs", "abs(x)\nThe absolute value of x"));
addPattern(new F1Pattern<Sign>("sign", "sign(x)\n-1 if x<0, 1 if x>0 and 0 if x=0"));
const std::string sqrt_desc = "Square root of x";
addPattern(new F1Pattern<Sqrt>("sqrt", "sqrt(x)\n" + sqrt_desc));
addPattern(new F1Pattern<Sqr>("sqr", "sqr(x)\n" + sqrt_desc));
addPattern(new F3Pattern<Crop>("crop", "crop(x,a,b)\na if x<a, b if x>b, x if x in [a,b]"));
addPattern(new F3Pattern<Crop>("clamp", "clamp(x,a,b)\na if x<a, b if x>b, x if x in [a,b]"));
addPattern(new F2Pattern<Min>("min", "min(a,b)"));
addPattern(new F2Pattern<Max>("max", "max(a,b)"));
addPattern(new F2Pattern<Step>("step", "min(x,x0)\n0 if x<x0, 1 if x>=x0"));
addPattern(new F3Pattern<Smoothstep>("smoothstep", "smoothstep(x,x0)\n0 if x<x0, 1 if x>=x0\nas step, but with smooth transition"));
const std::string pulse_desc = "Generates a bump ranging from 0.0 to 1.0 set at position pos";
addPattern(new Fs3Pattern<Pulse>("pulse", 0.5, "pulse(pos)\npulse(pos,length)\npulse(arg; pos)\npulse(arg;pos,length)\n" + pulse_desc));
addPattern(new Fs3Pattern<Pulse>("bump", 0.5, "bump(pos)\nbump(pos,length)\nbump(arg; pos)\nbump(arg;pos,length)\n" + pulse_desc));
const std::string saw_desc = "Generates a periodic sawtooth shaped curve";
addPattern(new Fs3Pattern<Saw>("sawtooth", 0.0, "sawtooth(length)\nsawtooth(length, height)\nsawtooth(arg; length)\nsawtooth(arg; length, height)\n" + saw_desc));
addPattern(new Fs3Pattern<Saw>("saw", 0.0, "saw(length)\nsaw(length, height)\nsaw(arg; length)\nsaw(arg; length, height)\n" + saw_desc));
addPattern(new Fs2Pattern<Wave>("wave", "wave(_length)\nwave(_arg;_length)\nsame as sin(f*180/length)"));
const std::string rnd_desc = "Generates random number between min and max";
addPattern(new RandomPattern("random", false, "random = random(0,1)\nrandom(max) = random(0,max)\nrandom(min,max)\n" + rnd_desc));
addPattern(new RandomPattern("rnd", false, "rnd = rnd(0,1)\nrnd(max) = rnd(0,max)\nrnd(min,max)\n" + rnd_desc));
const std::string rnd_s_desc = rnd_desc + "; seed select different random sequences";
addPattern(new RandomPattern("random_s", true, "random_s(seed) = random_s(seed, 0,1)\nrandom_s(seed,max) = random_s(seed, 0,max)\nrandom_s(seed,min,max)\n" + rnd_s_desc));
addPattern(new RandomPattern("rnd_s", true, "rnd_s(seed) = rnd_s(seed, 0,1)\nrnd_s(seed,max) = rnd_s(seed, 0,max)\nrnd_s(seed,min,max)\n" + rnd_s_desc));
addPattern(new CyclePattern("cycle"));
}
Grammar::~Grammar()
{
}
void Grammar::addPattern(Pattern *pattern)
{
std::vector<Token> noTokens;
if (pattern->expressionExpected(noTokens))
m_imp->m_postPatterns.addPattern(pattern);
else
m_imp->m_prePatterns.addPattern(pattern);
}
const Pattern *Grammar::getPattern(Position position, const Token &token) const
{
Pattern *pattern = 0;
if (position == ExpressionStart)
return m_imp->m_prePatterns.getPattern(token);
else
return m_imp->m_postPatterns.getPattern(token);
}
void Grammar::getSuggestions(Grammar::Suggestions &suggestions, Position position) const
{
if (position == ExpressionStart)
return m_imp->m_prePatterns.getSuggestions(suggestions);
else
return m_imp->m_postPatterns.getSuggestions(suggestions);
}
//===================================================================
} // namespace TSyntax