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// Copyright (C) 2010, Gabriel Dos Reis.
// All rights reserved.
//
// Redistribution and use in source and binary forms, with or without
// modification, are permitted provided that the following conditions are
// met:
//
// - Redistributions of source code must retain the above copyright
// notice, this list of conditions and the following disclaimer.
//
// - Redistributions in binary form must reproduce the above copyright
// notice, this list of conditions and the following disclaimer in
// the documentation and/or other materials provided with the
// distribution.
//
// - Neither the name of The Numerical Algorithms Group Ltd. nor the
// names of its contributors may be used to endorse or promote products
// derived from this software without specific prior written permission.
//
// THIS SOFTWARE IS PROVIDED BY THE COPYRIGHT HOLDERS AND CONTRIBUTORS "AS
// IS" AND ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED
// TO, THE IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR A
// PARTICULAR PURPOSE ARE DISCLAIMED. IN NO EVENT SHALL THE COPYRIGHT OWNER
// OR CONTRIBUTORS BE LIABLE FOR ANY DIRECT, INDIRECT, INCIDENTAL, SPECIAL,
// EXEMPLARY, OR CONSEQUENTIAL DAMAGES (INCLUDING, BUT NOT LIMITED TO,
// PROCUREMENT OF SUBSTITUTE GOODS OR SERVICES; LOSS OF USE, DATA, OR
// PROFITS; OR BUSINESS INTERRUPTION) HOWEVER CAUSED AND ON ANY THEORY OF
// LIABILITY, WHETHER IN CONTRACT, STRICT LIABILITY, OR TORT (INCLUDING
// NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY OUT OF THE USE OF THIS
// SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF SUCH DAMAGE.
// --% Author: Gabriel Dos Reis.
#include <ctype.h>
#include <iostream>
#include <iterator>
#include <open-axiom/sexpr>
namespace OpenAxiom {
namespace Sexpr {
std::ostream&
operator<<(std::ostream& os, const Token& t) {
switch (t.type) {
case Token::dot: os << "DOT"; break;
case Token::comma: os << "COMMA"; break;
case Token::open_paren: os << "OPEN_PAREN"; break;
case Token::close_paren: os << "CLOSE_PAREN"; break;
case Token::apostrophe: os << "APOSTROPHE"; break;
case Token::backquote: os << "BACKQUOTE"; break;
case Token::backslash: os << "BACKSLASH"; break;
case Token::sharp_open_paren: os << "SHARP_OPEN_PAREN"; break;
case Token::sharp_apostrophe: os << "SHARP_APOSTROPHE"; break;
case Token::sharp_colon: os << "SHARP_COLON"; break;
case Token::integer: os << "INTEGER"; break;
case Token::string: os << "STRING"; break;
case Token::identifier: os << "IDENTIFIER"; break;
case Token::sharp_integer_sharp:
os << "SHARP_INTEGER_SHARP"; break;
case Token::sharp_integer_equal:
os << "SHARP_INTEGER_EQUAL"; break;
default: os << "UNKNOWN"; break;
}
os << '(';
if (t.lexeme != 0) {
os << '"';
std::copy(t.lexeme->begin(), t.lexeme->end(),
std::ostream_iterator<char>(os));
os << '"';
}
else
os << "<missing>";
return os << ')';
}
// Return true if character `c' introduces a blank.
static bool
is_blank(char c) {
return c == ' ' or c == '\t' or c == '\v'
or c == '\n' or c == '\f' or c == '\r';
}
// Return true if the character `c' introduces a delimiter.
static bool
is_delimiter(char c) {
return is_blank(c)
or c == '(' or c == ')' or c == '\''
or c == '`' or c == '\\' or c == '#';
}
// Move `cur' past all consecutive blank characters, and
// return the new position.
static const char*
skip_blank(const char*& cur, const char* end) {
while (cur < end and is_blank(*cur))
++cur;
return cur;
}
// Move `cur' until a word boundary is reached.
static const char*
skip_to_word_boundary(const char*& cur, const char* end) {
while (cur < end and not is_delimiter(*cur))
++cur;
return cur;
}
// Move `cur' one-past a non-esacaped character `c'.
// Return true if the character was seen.
static bool
skip_to_nonescaped_char(const char*& cur, const char* end, char c) {
for (; cur < end; ++cur)
if (cur[0] == c and cur[-1] != '\\') {
++cur;
return true;
}
return false;
}
// Move `cur' past the closing fence of an absolute identifier.
// Return true if the closing fence was effectively seen.
static inline bool
skip_to_fence(const char*& cur, const char* end) {
return skip_to_nonescaped_char(cur, end, '|');
}
// Move `cur' past the closing quote of string literal.
// Return true if the closing fence was effectively seen.
static inline bool
skip_to_quote(const char*& cur, const char* end) {
return skip_to_nonescaped_char(cur, end, '"');
}
// Return true if the character `c' be part of a non-absolute
// identifier.
static bool
identifier_part(char c) {
switch (c) {
case '+': case '-': case '*': case '/': case '%': case '^':
case '~': case '@': case '$': case '&': case ':': case '=':
case '<': case '>': case '?': case '!': case '_':
return true;
default:
return isalnum(c);
}
}
// Return true if the character `c' has a special meaning after
// the sharp character.
static bool
special_after_sharp(char c) {
return c == '(' or c == '\'' or c == ':';
}
// Return true if the sequence `[cur, end)' has a prefix that is
// an integer followrd by the equal sign or the sharp sign.
// `cur' is moved along the way.
static bool
only_digits_before_equal_or_shap(const char*& cur, const char* end) {
while (cur < end and isdigit(*cur))
++cur;
return cur < end and (*cur == '#' or *cur == '=');
}
// The token `t' was thought to designate an identifier.
// Reclassify it as an integer if, in fact, its lexeme consists
// entirely of digits.
static void
maybe_reclassify(Token& t) {
const char* cur = t.lexeme->begin();
const char* end = t.lexeme->end();
while (cur < end and isdigit(*cur))
++cur;
if (cur == end)
t.type = Token::integer;
}
const char*
Lexer::tokenize(const char* cur, const char* end) {
while (skip_blank(cur, end) < end) {
Token t = { Token::unknown, 0 };
switch (*cur) {
case '.': case ',': case '(': case ')':
case '\'': case '\\':
t.type = Token::Type(OPENAXIOM_SEXPR_TOKEN1(*cur));
t.lexeme = strings.intern(cur, 1);
++cur;
break;
case '#': {
const char* start = cur;
if (cur + 1 < end and special_after_sharp(cur[1])) {
t.type = Token::Type(OPENAXIOM_SEXPR_TOKEN2(cur[0], cur[1]));
t.lexeme = strings.intern(cur, 2);
cur += 2;
}
else if (only_digits_before_equal_or_shap(++cur, end)) {
t.type = *cur == '#'
? Token::sharp_integer_sharp
: Token::sharp_integer_equal;
t.lexeme = strings.intern(start, cur - start + 1);
++cur;
}
else {
skip_to_word_boundary(cur, end);
t.lexeme = strings.intern(start, cur - start);
}
break;
}
case '|': {
const char* start = cur;
skip_to_fence(++cur, end);
t.type = Token::identifier;
t.lexeme = strings.intern(start, cur - start);
break;
}
case '"': {
const char* start = cur;
skip_to_quote(++cur, end);
t.type = Token::string;
t.lexeme = strings.intern(start, cur - start);
break;
}
default:
if (identifier_part(*cur)) {
const char* start = cur;
skip_to_word_boundary(++cur, end);
t.type = Token::identifier;
t.lexeme = strings.intern(start, cur - start);
maybe_reclassify(t);
}
else {
const char* start = cur;
skip_to_word_boundary(++cur, end);
t.lexeme = strings.intern(start, cur - start);
}
break;
}
tokens.push_back(t);
}
return cur;
}
// ----------
// -- Atom --
// ----------
Atom::Atom(const Token& t) : tok(t) { }
void
Atom::accept(Visitor& v) const {
v.visit(*this);
}
// -------------
// -- Integer --
// -------------
Integer::Integer(const Token& t) : Atom(t) { }
void
Integer::accept(Visitor& v) const {
v.visit(*this);
}
// ------------
// -- String --
// ------------
String::String(const Token& t) : Atom(t) { }
void
String::accept(Visitor& v) const {
v.visit(*this);
}
// ------------
// -- Symbol --
// ------------
Symbol::Symbol(const Token& t, Kind k) : Atom(t), sort(k) { }
void
Symbol::accept(Visitor& v) const {
v.visit(*this);
}
// ------------
// -- Anchor --
// ------------
Anchor::Anchor(size_t t, const Syntax* s) : tag(t), val(s) { }
void
Anchor::accept(Visitor& v) const {
v.visit(*this);
}
// ---------------
// -- Reference --
// ---------------
Reference::Reference(const Token& t, size_t v) : Atom(t), pos(v) { }
void
Reference::accept(Visitor& v) const {
v.visit(*this);
}
// -----------
// -- Quote --
// -----------
Quote::Quote(const Syntax* s) : form(s) { }
void
Quote::accept(Visitor& v) const {
v.visit(*this);
}
// --------------
// -- Function --
// --------------
Function::Function(const Syntax* s) : form(s) { }
void
Function::accept(Visitor& v) const {
v.visit(*this);
}
// ----------
// -- Pair --
// ----------
Pair::Pair(const Syntax* f, const Syntax* s) : elts(f, s) { }
void
Pair::accept(Visitor& v) const {
v.visit(*this);
}
// ----------
// -- List --
// ----------
List::List() { }
List::List(const base& elts) : base(elts) { }
List::~List() { }
void
List::accept(Visitor& v) const {
v.visit(*this);
}
// ------------
// -- Vector --
// ------------
Vector::Vector() { }
Vector::Vector(const base& elts) : base(elts) { }
Vector::~Vector() { }
void
Vector::accept(Visitor& v) const {
v.visit(*this);
}
// ---------------------
// -- Syntax::Visitor --
// ---------------------
// implicitly convert a reference to `T' to a reference to `S'.
template<typename S, typename T>
inline const S&
as(const T& t) {
return t;
}
void
Syntax::Visitor::visit(const Integer& i) {
visit(as<Atom>(i));
}
void
Syntax::Visitor::visit(const String& s) {
visit(as<Atom>(s));
}
void
Syntax::Visitor::visit(const Symbol& s) {
visit(as<Atom>(s));
}
void
Syntax::Visitor::visit(const Reference& r) {
visit(as<Atom>(r));
}
// ---------------
// -- Allocator --
// ---------------
Allocator::Allocator() { }
// This destructor is defined here so that it provides
// a single instantiation point for destructors of all
// used templates floating around.
Allocator::~Allocator() { }
const Integer*
Allocator::make_integer(const Token& t) {
return ints.allocate(t);
}
const String*
Allocator::make_string(const Token& t) {
return strs.allocate(t);
}
const Symbol*
Allocator::make_symbol(const Token& t, Symbol::Kind k) {
return syms.allocate(t, k);
}
const Anchor*
Allocator::make_anchor(size_t t, const Syntax* s) {
return ancs.allocate(t, s);
}
const Reference*
Allocator::make_reference(const Token& t, size_t i) {
return refs.allocate(t, i);
}
const Quote*
Allocator::make_quote(const Syntax* s) {
return quotes.allocate(s);
}
const Function*
Allocator::make_function(const Syntax* s) {
return funs.allocate(s);
}
const Pair*
Allocator::make_pair(const Syntax* f, const Syntax* s) {
return pairs.allocate(f, s);
}
const List*
Allocator::make_list(const std::vector<const Syntax*>& elts) {
if (elts.empty())
return &empty_list;
return lists.make(elts);
}
const Vector*
Allocator::make_vector(const std::vector<const Syntax*>& elts) {
if (elts.empty())
return &empty_vector;
return vectors.make(elts);
}
// ------------
// -- Parser --
// ------------
// Signal a parse error
static void
parse_error(const std::string& s) {
throw SystemError(s);
}
// Signal that an expected syntax object was missing
static void
expected_syntax(const std::string& s) {
parse_error("expected " + s);
}
// Signal an abrupt end of input
static void
unexpected_end_of_input(const std::string& s) {
parse_error("unexpected end of input after " + s);
}
// Signal a missing closing parenthesis
static void
missing_closer_for(const std::string& s) {
parse_error("missing closing parenthesis for " + s);
}
// The sequence of characters in [cur, last) consists
// entirely of digits. Return the corresponding natural value.
static size_t
natural_value(const char* cur, const char* last) {
size_t n = 0;
for (; cur < last; ++cur)
// FIXME: check for overflow.
n = 10 * n + (*cur - '0');
return n;
}
// Parse a plain identifier or a Lisp-style keyword identifier.
const Symbol*
Parser::parse_symbol(const Token*& cur, const Token* last) {
Symbol::Kind kind = *cur->lexeme->begin() == ':'
? Symbol::keyword
: Symbol::ordinary;
return alloc.make_symbol(*cur++, kind);
}
// Parse an anchor definition of the form #n=<syntax>
const Anchor*
Parser::parse_anchor(const Token*& cur, const Token* last) {
const size_t n = natural_value(cur->lexeme->begin() + 1,
cur->lexeme->end() - 1);
if (++cur == last)
unexpected_end_of_input("sharp-integer-equal sign");
return alloc.make_anchor(n, parse_syntax(cur, last));
}
// Parse a reference to an anchor, #n#
const Reference*
Parser::parse_reference(const Token*& cur, const Token* last) {
const size_t n = natural_value(cur->lexeme->begin() + 1,
cur->lexeme->end() - 1);
return alloc.make_reference(*cur++, n);
}
// Parse an uninterned symbol #:<identifier>
const Symbol*
Parser::parse_uninterned(const Token*& cur, const Token* last) {
if (cur == last or cur->type != Token::identifier)
expected_syntax("symbol after sharp-colon sign");
// FIXME: check that the identifier is not a keyword.
return alloc.make_symbol(*cur++, Symbol::uninterned);
}
// Parse a function syntax: #'<syntax>
const Function*
Parser::parse_function(const Token*& cur, const Token* last) {
if (cur == last)
unexpected_end_of_input("sharp-quote sign");
return alloc.make_function(parse_syntax(cur, last));
}
// Parse a quotation
const Quote*
Parser::parse_quote(const Token*& cur, const Token* last) {
if (cur == last)
unexpected_end_of_input("quote sign");
return alloc.make_quote(parse_syntax(cur, last));
}
// Parse a vector of syntax objects: #(s .. s)
const Vector*
Parser::parse_vector(const Token*& cur, const Token* last) {
std::vector<const Syntax*> elts;
while (cur < last and cur->type != Token::close_paren)
elts.push_back(parse_syntax(cur, last));
if (cur == last)
missing_closer_for("vector");
++cur;
return alloc.make_vector(elts);
}
// Constructs a pair or a list syntax object.
// This function is hairy for three reasons: (a) it is not known
// whether we list or a pair until after we have seen the
// enclosed tokens; (b) a dot is allowed at most once; (c) Lisp-style
// improper lists are not allowed.
const Syntax*
Parser::parse_list_or_pair(const Token*& cur, const Token* last) {
std::vector<const Syntax*> elts;
bool saw_dot = false;
while (cur < last and cur->type != Token::close_paren) {
if (cur->type == Token::dot) {
if (elts.size() != 1)
parse_error("unexpected dot sign");
saw_dot = true;
++cur;
continue;
}
elts.push_back(parse_syntax(cur, last));
if (saw_dot && elts.size() == 2)
break;
}
if (cur == last or cur->type != Token::close_paren)
missing_closer_for(saw_dot ? "pair" : "list");
++cur;
if (saw_dot)
return alloc.make_pair(elts.front(), elts.back());
return alloc.make_list(elts);
}
Parser::Parser(Allocator& a, std::vector<const Syntax*>& v)
: alloc(a), syns(v) { }
const Syntax*
Parser::parse_syntax(const Token*& cur, const Token* last) {
switch (cur->type) {
case Token::integer:
return alloc.make_integer(*cur++);
case Token::string:
return alloc.make_string(*cur++);
case Token::identifier:
return parse_symbol(cur, last);
case Token::sharp_integer_equal:
return parse_anchor(cur, last);
case Token::sharp_integer_sharp:
return parse_reference(cur, last);
case Token::sharp_colon:
return parse_uninterned(++cur, last);
case Token::sharp_apostrophe:
return parse_function(++cur, last);
case Token::sharp_open_paren:
return parse_vector(++cur, last);
case Token::apostrophe:
return parse_quote(++cur, last);
case Token::open_paren:
return parse_list_or_pair(++cur, last);
default:
parse_error(std::string("parse error before ")
+ cur->lexeme->begin());
return 0; // never executed
}
}
const Token*
Parser::parse(const Token* cur, const Token* last) {
while (cur < last)
syns.push_back(parse_syntax(cur, last));
return cur;
}
}
}
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