Expression.cpp 13.3 KB
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#include <iostream>
#include <locale>
#include <sstream>

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#include "MantidAPI/Expression.h"

#include <Poco/StringTokenizer.h>

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namespace Mantid {
namespace API {
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typedef Poco::StringTokenizer tokenizer;

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const std::string DEFAULT_OPS_STR[] = {";", ",", "=", "== != > < <= >=",
                                       "&& || ^^", "+ -", "* /", "^"};
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Expression::Expression() {
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  m_operators.reset(new Operators());
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  // Define binary operators. Put them in the reverse precedence order (from
  // lower to higher prec.)
  std::vector<std::string> ops(DEFAULT_OPS_STR, DEFAULT_OPS_STR + 8);
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  add_operators(ops);

  // Define unary operators
  std::set<std::string> unary;
  unary.insert("+");
  unary.insert("-");

  add_unary(unary);
}

/// contructor
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Expression::Expression(const std::vector<std::string> &ops) {
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  m_operators.reset(new Operators());
  add_operators(ops);
}

/// contructor
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Expression::Expression(const std::vector<std::string> &binary,
                       const std::set<std::string> &unary) {
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  m_operators.reset(new Operators());
  add_operators(binary);
  add_unary(unary);
}

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Expression::Expression(const Expression &expr)
    : // m_tokens(expr.m_tokens),
      // m_expr(expr.m_expr),
      m_funct(expr.m_funct),
      m_op(expr.m_op), m_terms(expr.m_terms), m_operators(expr.m_operators) {}
Expression::Expression(const Expression *pexpr)
    : m_operators(pexpr->m_operators) {}
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/// Assignment operator
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Expression &Expression::operator=(const Expression &expr) {
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  m_operators = expr.m_operators;
  m_funct = expr.m_funct;
  m_op = expr.m_op;
  m_terms = expr.m_terms;
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  // m_expr = expr.m_expr;
  // m_tokens = expr.m_tokens;
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  return *this;
}

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void Expression::add_operators(const std::vector<std::string> &ops) {
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  m_operators->binary = ops;
  // Fill in the precedence table (m_op_precedence)
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  for (size_t i = 0; i < m_operators->binary.size(); i++) {
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    char j = 0;
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    tokenizer tkz(m_operators->binary[i], " ",
                  tokenizer::TOK_IGNORE_EMPTY | tokenizer::TOK_TRIM);
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    for (const auto &it : tkz) {
      m_operators->precedence[it] = i + 1;
      m_operators->op_number[it] = j++;
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    }
  }

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  for (auto str : ops) {
    for (char c : str) {
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      if (c == ' ')
        continue;
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      m_operators->symbols.insert(c);
    }
  }
}

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void Expression::add_unary(const std::set<std::string> &ops) {
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  m_operators->unary = ops;
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  for (const auto &op : ops) {
    m_operators->symbols.insert(op.cbegin(), op.cend());
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  }
}

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size_t Expression::op_prec(const std::string &op) const {
  std::map<std::string, size_t>::const_iterator i =
      m_operators->precedence.find(op);
  if (i == m_operators->precedence.end())
    return 0;
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  return i->second;
}

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bool Expression::is_unary(const std::string &op) const {
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  return m_operators->unary.find(op) != m_operators->unary.end();
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}

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bool Expression::is_op_symbol(const char c) const {
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  return m_operators->symbols.find(c) != m_operators->symbols.end();
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}

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void Expression::trim(std::string &str) {
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  size_t i = str.find_first_not_of(" \t\n\r");
  size_t j = str.find_last_not_of(" \t\n\r");
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  if (i == std::string::npos || j == std::string::npos || j < i) {
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    str = "";
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  } else {
    str = str.substr(i, j - i + 1);
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  }
}

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void Expression::parse(const std::string &str) {
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  m_expr = str;
  trim(m_expr);

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  if (m_expr.size() > 1 && m_expr[0] == '(' &&
      m_expr[m_expr.size() - 1] == ')') {
    if (m_expr.find('(', 1) == std::string::npos) {
      m_expr.erase(0, 1);
      m_expr.erase(m_expr.size() - 1, 1);
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      trim(m_expr);
    }
  }

  tokenize();

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  if (m_tokens.size() == 0) {
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    setFunct(m_expr);
    return;
  }

  std::string op = GetOp(0);
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  // size_t prec = m_operators->precedence[op];
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  size_t prec = op_prec(op);
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  tokenizer tkz(m_operators->binary[prec - 1], " ",
                tokenizer::TOK_IGNORE_EMPTY | tokenizer::TOK_TRIM);
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  setFunct(*tkz.begin());

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  for (size_t i = 0; i <= m_tokens.size(); i++) {
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    m_terms.push_back(Expression(this));
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    Expression &t = m_terms.back();
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    if (i)
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      t.m_op = GetOp(i - 1);
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    t.parse(GetToken(i));
  }
  m_expr = "";
  m_tokens.clear();
}

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void Expression::tokenize() {
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  m_tokens.clear();

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  size_t min_prec = 1000;
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  size_t is = 0;
  size_t is1 = 0;
  unsigned int lvl = 0;
  size_t last = m_expr.size() - 1;
  bool inString = false;
  int skip = 0;
  bool canBeBinary = false;
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  bool isNumber =
      false; // if parser is inside a number (important case is 123.45e+67)
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  bool canDotBeAdded = false;
  bool canEBeAdded = false;
  bool canPlusBeAdded = false;
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  Tokens tokens;
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  for (size_t i = 0; i < m_expr.size(); i++) {
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    char c = m_expr[i];
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    if (!inString && skip == 0) {
      if (isNumber) {
        if (c == '.') {
          if (canDotBeAdded) {
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            canDotBeAdded = false;
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          } else {
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            isNumber = false;
          }
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        } else if (c == 'e' || c == 'E') {
          if (canEBeAdded) {
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            canEBeAdded = false;
            canDotBeAdded = false;
            canPlusBeAdded = true;
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          } else {
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            isNumber = false;
          }
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        } else if (c == '+' || c == '-') {
          if (canPlusBeAdded) {
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            canPlusBeAdded = false;
            canEBeAdded = false;
            canDotBeAdded = false;
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          } else {
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            isNumber = false;
          }
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        } else if (!isdigit(c)) {
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          isNumber = false;
        }
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      } else if (isdigit(c)) {
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        isNumber = true;
        canDotBeAdded = true;
        canEBeAdded = true;
        canPlusBeAdded = false;
      }
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      if (lvl == 0 && !isNumber && is_op_symbol(c)) // insert new token
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      {
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        if (i == last) {
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          break;
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          // throw std::runtime_error("Expression: syntax error");
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        }

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        if (is_op_symbol(m_expr[i + 1])) {
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          is1 = i + 2;
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        } else {
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          is1 = i + 1;
        }

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        if (is1 > last) {
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          throw std::runtime_error("Expression: syntax error");
        }

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        std::string op = m_expr.substr(i, is1 - i);
        size_t prec = canBeBinary ? m_operators->precedence[op] : 0;
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        if (!prec) // operator does not exist
        {
          std::ostringstream mess;
          bool error = true;
          // check if it's a binary and a unary operators together
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          if (op.size() == 2) {
            if (is_unary(op)) {
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              is1 -= 2;
              skip = 2;
              prec = min_prec + 1; // do not add token
              error = false;
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            } else {
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              is1 -= 1;
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              std::string uop = op.substr(1, 1);
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              op = op[0];
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              if (is_op_symbol(m_expr[is1 + 1])) {
                uop += m_expr[is1 + 1];
                if (is1 + 2 > last) {
                  mess << "Expression: syntax error at " << is1 + 1;
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                  throw std::runtime_error(mess.str());
                }
              }
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              if (is_unary(uop)) {
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                prec = m_operators->precedence[op];
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                if (prec) { // we don't want to create a new token with unary
                            // operator. it is processed in SetFunct()
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                  skip = 1;
                  error = false;
                }
              }
            }
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          } // op.size == 2
          else if (op.size() == 1) {
            // skip = 1;
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            prec = min_prec + 1; // do not add token
            error = false;
          }
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          if (error) {
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            mess << "Expression: unrecognized operator " << op;
            throw std::runtime_error(mess.str());
          }
        }

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        if (prec <= min_prec) {
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          if (prec < min_prec)
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            min_prec = prec;
          Token tok(is, i - 1, is1, prec);
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          tokens.push_back(tok);
          is = is1;
        }

        i = is1 - 1;

        canBeBinary = false;

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      } // insert new token
      else if (c != ' ' && c != '\t' && c != '\r' && c != '\n') {
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        canBeBinary = true;
      }

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      if (c == '(')
        lvl++;
      if (c == ')') {
        if (lvl)
          lvl--;
        else {
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          throw std::runtime_error("Unmatched brackets");
        }
      }
    } // !inString || skip
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    else if (skip > 0) {
      skip--;
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    }

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    if (c == '"') {
      if (!inString) {
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        inString = true;
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      } else {
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        inString = false;
      }
    }

  } // for i

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  if (tokens.size()) {
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    // remove operators of higher prec
    m_tokens.push_back(Token(tokens[0]));
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    for (size_t i = 0; i < tokens.size(); i++) {
      Token &tok = tokens[i];
      std::string op = m_expr.substr(tok.ie + 1, tok.is1 - tok.ie - 1); //?
      if (m_operators->precedence[op] == min_prec) {
        Token &last_tok = m_tokens.back();
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        last_tok.ie = tok.ie;
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        last_tok.is1 = tok.is1;
        if (i != tokens.size() - 1)
          m_tokens.push_back(Token(tokens[i + 1]));
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      }
    }
  }
}

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std::string Expression::GetToken(size_t i) {
  if (m_tokens.size() == 0)
    return m_expr;
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  if (i < m_tokens.size()) {
    Token &tok = m_tokens[i];
    return m_expr.substr(tok.is, tok.ie - tok.is + 1);
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  }

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  if (i == m_tokens.size()) {
    Token &tok = m_tokens[i - 1];
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    return m_expr.substr(tok.is1);
  }

  return "";
}

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std::string Expression::GetOp(size_t i) {
  if (m_tokens.size() == 0 || i >= m_tokens.size())
    return "";
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  Token &tok = m_tokens[i];
  return m_expr.substr(tok.ie + 1, tok.is1 - tok.ie - 1);
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}

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void Expression::logPrint(const std::string &pads) const {
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  std::string myPads = pads + "   ";
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  if (m_terms.size()) {
    std::cerr << myPads << m_op << '[' << m_funct << ']' << "(" << '\n';
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    for (const auto &m_term : m_terms)
      m_term.logPrint(myPads);
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    std::cerr << myPads << ")" << '\n';
  } else
    std::cerr << myPads << m_op << m_funct << '\n';
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}

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void Expression::setFunct(const std::string &name) {
  if (!op_prec(name)) {
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    std::string op = "";
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    if (name.size() > 1 && is_op_symbol(name[0])) {
      op = name.substr(0, 1);
      if (name.size() > 2 && is_op_symbol(name[1])) {
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        op += name[1];
      }
    }
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    if (!op.empty() && is_unary(op)) {
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      m_funct = op;
      Expression tmp(this);
      tmp.parse(name.substr(op.size()));
      m_terms.push_back(tmp);
      return;
    }
  }

  m_funct = name;
  trim(m_funct);
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  if (m_funct.empty()) {
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    throw std::runtime_error("Expression: Syntax error");
  }

  // Check if the function has arguments
  std::string::size_type i = std::string::npos;

  bool inQuotes = false;
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  for (std::string::const_iterator c = name.begin(); c != name.end(); ++c) {
    if (*c == '"') {
      if (inQuotes)
        inQuotes = false;
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      else
        inQuotes = true;
      continue;
    }

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    if (!inQuotes && *c == '(') {
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      i = c - name.begin();
      break;
    }
  }

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  if (i != std::string::npos) {
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    std::string::size_type j = name.find_last_of(')');
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    if (j == std::string::npos || j < i) {
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      throw std::runtime_error("Unmatched brackets");
    }

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    if (j > i + 1) // nonzero argument list
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    {
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      std::string args = name.substr(i + 1, j - i - 1); //?
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      trim(args);
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      std::string f = name.substr(0, i);
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      Expression tmp(this);
      tmp.parse(args);
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      if (!tmp.isFunct() || tmp.name() != ",") {
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        m_terms.push_back(tmp);
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      } else {
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        std::string my_op = m_op;
        *this = tmp;
        m_op = my_op;
      }
      m_funct = f;
    }
  }
}

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std::string Expression::str() const {
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  bool brackets = false;
  std::ostringstream res;
  size_t prec = op_prec(m_funct);
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  if (size() == 1 && is_unary(m_funct)) { // unary operator
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    res << m_funct;
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    if (op_prec(m_terms[0].m_funct) > 0) {
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      brackets = true;
    }
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  } else if (!prec) { // function with a name
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    res << m_funct;
    brackets = true;
  }

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  if (m_terms.size()) {
    if (brackets)
      res << '(';
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    for (const auto &m_term : m_terms) {
      res << m_term.operator_name();
      size_t prec1 = op_prec(m_term.m_funct);
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      bool isItUnary = false;
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      if (m_term.size() == 1 && is_unary(m_term.m_funct)) {
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        prec1 = 0; // unary operator
        isItUnary = true;
      }
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      bool bk = prec > 0 && prec1 > 0 && prec > prec1;
      if (bk)
        res << '(';
      if (isItUnary)
        res << ' ';
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      res << m_term.str();
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      if (bk)
        res << ')';
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    }
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    if (brackets)
      res << ')';
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  }
  return res.str();
}

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const Expression &Expression::bracketsRemoved() const {
  const Expression *e = this;
  while (e->name().empty() && e->size() == 1) {
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    e = &e->m_terms[0];
  }
  return *e;
}

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/**
 * Return a list of all variable names in this expression
 */
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std::set<std::string> Expression::getVariables() const {
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  std::set<std::string> out;
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  if (!isFunct()) {
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    std::string s = name();
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    if (!s.empty() && !isdigit(s[0])) {
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      out.insert(s);
    }
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  } else {
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    for (const auto &e : *this) {
      if (e.isFunct()) {
        std::set<std::string> tout = e.getVariables();
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        out.insert(tout.begin(), tout.end());
      } else {
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        std::string s = e.name();
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        if (!s.empty() && !isdigit(s[0])) {
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          out.insert(s);
        }
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      }
    }
  }
  return out;
}

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void Expression::rename(const std::string &newName) { m_funct = newName; }
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void Expression::renameAll(const std::string &oldName,
                           const std::string &newName) {
  if (!isFunct() && name() == oldName) {
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    rename(newName);
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  } else {
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    for (auto &term : m_terms) {
      term.renameAll(oldName, newName);
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    }
  }
}

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void Expression::toList(const std::string &sep) {
  if (name() == sep)
    return;
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  Expression term(*this);
  m_terms.resize(1);
  m_terms[0] = term;
  setFunct(sep);
}

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} // API
} // Mantid