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|
// recursive descent parser for systemtap scripts
// Copyright (C) 2005-2007 Red Hat Inc.
// Copyright (C) 2006 Intel Corporation.
// Copyright (C) 2007 Bull S.A.S
//
// This file is part of systemtap, and is free software. You can
// redistribute it and/or modify it under the terms of the GNU General
// Public License (GPL); either version 2, or (at your option) any
// later version.
#include "config.h"
#include "staptree.h"
#include "parse.h"
#include "session.h"
#include "util.h"
#include <iostream>
#include <fstream>
#include <cctype>
#include <cstdlib>
#include <cassert>
#include <cerrno>
#include <climits>
#include <sstream>
#include <cstring>
#include <cctype>
using namespace std;
// ------------------------------------------------------------------------
parser::parser (systemtap_session& s, istream& i, bool p):
session (s),
input_name ("<input>"), free_input (0),
input (i, input_name, s), privileged (p),
context(con_unknown), last_t (0), next_t (0), num_errors (0)
{ }
parser::parser (systemtap_session& s, const string& fn, bool p):
session (s),
input_name (fn), free_input (new ifstream (input_name.c_str(), ios::in)),
input (* free_input, input_name, s), privileged (p),
context(con_unknown), last_t (0), next_t (0), num_errors (0)
{ }
parser::~parser()
{
if (free_input) delete free_input;
}
stapfile*
parser::parse (systemtap_session& s, std::istream& i, bool pr)
{
parser p (s, i, pr);
return p.parse ();
}
stapfile*
parser::parse (systemtap_session& s, const std::string& n, bool pr)
{
parser p (s, n, pr);
return p.parse ();
}
static string
tt2str(token_type tt)
{
switch (tt)
{
case tok_junk: return "junk";
case tok_identifier: return "identifier";
case tok_operator: return "operator";
case tok_string: return "string";
case tok_number: return "number";
case tok_embedded: return "embedded-code";
case tok_keyword: return "keyword";
}
return "unknown token";
}
ostream&
operator << (ostream& o, const source_loc& loc)
{
o << loc.file << ":"
<< loc.line << ":"
<< loc.column;
return o;
}
ostream&
operator << (ostream& o, const token& t)
{
o << tt2str(t.type);
if (t.type != tok_embedded && t.type != tok_keyword) // XXX: other types?
{
o << " '";
for (unsigned i=0; i<t.content.length(); i++)
{
char c = t.content[i];
o << (isprint (c) ? c : '?');
}
o << "'";
}
o << " at "
<< t.location;
return o;
}
void
parser::print_error (const parse_error &pe)
{
cerr << "parse error: " << pe.what () << endl;
if (pe.tok)
{
cerr << "\tat: " << *pe.tok << endl;
}
else
{
const token* t = last_t;
if (t)
cerr << "\tsaw: " << *t << endl;
else
cerr << "\tsaw: " << input_name << " EOF" << endl;
}
// XXX: make it possible to print the last input line,
// so as to line up an arrow with the specific error column
num_errors ++;
}
const token*
parser::last ()
{
return last_t;
}
// Here, we perform on-the-fly preprocessing.
// The basic form is %( CONDITION %? THEN-TOKENS %: ELSE-TOKENS %)
// where CONDITION is: kernel_v[r] COMPARISON-OP "version-string"
// or: arch COMPARISON-OP "arch-string"
// or: "string1" COMPARISON-OP "string2"
// or: number1 COMPARISON-OP number2
// The %: ELSE-TOKENS part is optional.
//
// e.g. %( kernel_v > "2.5" %? "foo" %: "baz" %)
// e.g. %( arch != "i686" %? "foo" %: "baz" %)
//
// Up to an entire %( ... %) expression is processed by a single call
// to this function. Tokens included by any nested conditions are
// enqueued in a private vector.
bool eval_pp_conditional (systemtap_session& s,
const token* l, const token* op, const token* r)
{
if (l->type == tok_identifier && (l->content == "kernel_v" ||
l->content == "kernel_vr"))
{
string target_kernel_vr = s.kernel_release;
string target_kernel_v = s.kernel_base_release;
if (! (r->type == tok_string))
throw parse_error ("expected string literal", r);
string query_kernel_vr = r->content;
// collect acceptable strverscmp results.
int rvc_ok1, rvc_ok2;
if (op->type == tok_operator && op->content == "<=")
{ rvc_ok1 = -1; rvc_ok2 = 0; }
else if (op->type == tok_operator && op->content == ">=")
{ rvc_ok1 = 1; rvc_ok2 = 0; }
else if (op->type == tok_operator && op->content == "<")
{ rvc_ok1 = -1; rvc_ok2 = -1; }
else if (op->type == tok_operator && op->content == ">")
{ rvc_ok1 = 1; rvc_ok2 = 1; }
else if (op->type == tok_operator && op->content == "==")
{ rvc_ok1 = 0; rvc_ok2 = 0; }
else if (op->type == tok_operator && op->content == "!=")
{ rvc_ok1 = -1; rvc_ok2 = 1; }
else
throw parse_error ("expected comparison operator", op);
int rvc_result = strverscmp ((l->content == "kernel_vr" ?
target_kernel_vr.c_str() :
target_kernel_v.c_str()),
query_kernel_vr.c_str());
// normalize rvc_result
if (rvc_result < 0) rvc_result = -1;
if (rvc_result > 0) rvc_result = 1;
return (rvc_result == rvc_ok1 || rvc_result == rvc_ok2);
}
else if (l->type == tok_identifier && l->content == "arch")
{
string target_architecture = s.architecture;
if (! (r->type == tok_string))
throw parse_error ("expected string literal", r);
string query_architecture = r->content;
bool result;
if (op->type == tok_operator && op->content == "==")
result = target_architecture == query_architecture;
else if (op->type == tok_operator && op->content == "!=")
result = target_architecture != query_architecture;
else
throw parse_error ("expected '==' or '!='", op);
return result;
}
else if ((l->type == tok_string && r->type == tok_string)
|| (l->type == tok_number && r->type == tok_number))
{
// collect acceptable strverscmp results.
int rvc_ok1, rvc_ok2;
if (op->type == tok_operator && op->content == "<=")
{ rvc_ok1 = -1; rvc_ok2 = 0; }
else if (op->type == tok_operator && op->content == ">=")
{ rvc_ok1 = 1; rvc_ok2 = 0; }
else if (op->type == tok_operator && op->content == "<")
{ rvc_ok1 = -1; rvc_ok2 = -1; }
else if (op->type == tok_operator && op->content == ">")
{ rvc_ok1 = 1; rvc_ok2 = 1; }
else if (op->type == tok_operator && op->content == "==")
{ rvc_ok1 = 0; rvc_ok2 = 0; }
else if (op->type == tok_operator && op->content == "!=")
{ rvc_ok1 = -1; rvc_ok2 = 1; }
else
throw parse_error ("expected comparison operator", op);
int rvc_result = l->content.compare(r->content);
// normalize rvc_result
if (rvc_result < 0) rvc_result = -1;
if (rvc_result > 0) rvc_result = 1;
return (rvc_result == rvc_ok1 || rvc_result == rvc_ok2);
}
else if (l->type == tok_string && r->type == tok_number
&& op->type == tok_operator)
throw parse_error ("expected string literal as right value", r);
else if (l->type == tok_number && r->type == tok_string
&& op->type == tok_operator)
throw parse_error ("expected number literal as right value", r);
// XXX: support other forms? "CONFIG_SMP" ?
else
throw parse_error ("expected 'arch' or 'kernel_v' or 'kernel_vr'\n"
" or comparison between strings or integers", l);
}
// expand_args is used to know if we must expand $x and @x identifiers.
// Only tokens corresponding to the TRUE statement must be expanded
const token*
parser::scan_pp (bool expand_args)
{
while (true)
{
if (enqueued_pp.size() > 0)
{
const token* t = enqueued_pp[0];
enqueued_pp.erase (enqueued_pp.begin());
return t;
}
const token* t = input.scan (expand_args); // NB: not recursive!
if (t == 0) // EOF
return t;
if (! (t->type == tok_operator && t->content == "%(")) // ordinary token
return t;
// We have a %( - it's time to throw a preprocessing party!
const token *l, *op, *r;
l = input.scan (expand_args); // NB: not recursive, though perhaps could be
op = input.scan (expand_args);
r = input.scan (expand_args);
if (l == 0 || op == 0 || r == 0)
throw parse_error ("incomplete condition after '%('", t);
// NB: consider generalizing to consume all tokens until %?, and
// passing that as a vector to an evaluator.
// Do not evaluate the condition if we haven't expanded everything.
// This may occured when having several recursive conditionals.
bool result = expand_args && eval_pp_conditional (session, l, op, r);
delete l;
delete op;
delete r;
const token *m = input.scan (); // NB: not recursive
if (! (m && m->type == tok_operator && m->content == "%?"))
throw parse_error ("expected '%?' marker for conditional", t);
delete m; // "%?"
vector<const token*> my_enqueued_pp;
bool have_token = false;
while (true) // consume THEN tokens
{
m = scan_pp (result); // NB: recursive
if (m == 0)
throw parse_error (have_token ?
"incomplete conditional - missing %: or %)" :
"missing THEN tokens for conditional",
t);
have_token = true;
if (m->type == tok_operator && (m->content == "%:" || // ELSE
m->content == "%)")) // END
break;
// enqueue token
if (result)
my_enqueued_pp.push_back (m);
else
delete m; // unused token
// continue
}
have_token = false;
if (m && m->type == tok_operator && m->content == "%:") // ELSE
{
delete m; // "%:"
while (true)
{
m = scan_pp (expand_args && !result); // NB: recursive
if (m == 0)
throw parse_error (have_token ?
"incomplete conditional - missing %)" :
"missing ELSE tokens for conditional",
t);
have_token = true;
if (m->type == tok_operator && m->content == "%)") // END
break;
// enqueue token
if (! result)
my_enqueued_pp.push_back (m);
else
delete m; // unused token
// continue
}
}
delete t; // "%("
delete m; // "%)"
// NB: we transcribe the retained tokens here, and not inside
// the THEN/ELSE while loops. If it were done there, each loop
// would become infinite (each iteration consuming an ordinary
// token the previous one just pushed there). Guess how I
// figured that out.
enqueued_pp.insert (enqueued_pp.end(),
my_enqueued_pp.begin(),
my_enqueued_pp.end());
// Go back to outermost while(true) loop. We hope that at least
// some THEN or ELSE tokens were enqueued. If not, around we go
// again, until EOF.
}
}
const token*
parser::next ()
{
if (! next_t)
next_t = scan_pp ();
if (! next_t)
throw parse_error ("unexpected end-of-file");
last_t = next_t;
// advance by zeroing next_t
next_t = 0;
return last_t;
}
const token*
parser::peek ()
{
if (! next_t)
next_t = scan_pp ();
// don't advance by zeroing next_t
last_t = next_t;
return next_t;
}
static inline bool
tok_is(token const * t, token_type tt, string const & expected)
{
return t && t->type == tt && t->content == expected;
}
const token*
parser::expect_known (token_type tt, string const & expected)
{
const token *t = next();
if (! (t && t->type == tt && t->content == expected))
throw parse_error ("expected '" + expected + "'");
return t;
}
const token*
parser::expect_unknown (token_type tt, string & target)
{
const token *t = next();
if (!(t && t->type == tt))
throw parse_error ("expected " + tt2str(tt));
target = t->content;
return t;
}
const token*
parser::expect_unknown2 (token_type tt1, token_type tt2, string & target)
{
const token *t = next();
if (!(t && (t->type == tt1 || t->type == tt2)))
throw parse_error ("expected " + tt2str(tt1) + " or " + tt2str(tt2));
target = t->content;
return t;
}
const token*
parser::expect_op (std::string const & expected)
{
return expect_known (tok_operator, expected);
}
const token*
parser::expect_kw (std::string const & expected)
{
return expect_known (tok_identifier, expected);
}
const token*
parser::expect_number (int64_t & value)
{
bool neg = false;
const token *t = next();
if (t->type == tok_operator && t->content == "-")
{
neg = true;
t = next ();
}
if (!(t && t->type == tok_number))
throw parse_error ("expected number");
const char* startp = t->content.c_str ();
char* endp = (char*) startp;
// NB: we allow controlled overflow from LLONG_MIN .. ULLONG_MAX
// Actually, this allows all the way from -ULLONG_MAX to ULLONG_MAX,
// since the lexer only gives us positive digit strings, but we'll
// limit it to LLONG_MIN when a '-' operator is fed into the literal.
errno = 0;
value = (int64_t) strtoull (startp, & endp, 0);
if (errno == ERANGE || errno == EINVAL || *endp != '\0'
|| (neg && (unsigned long long) value > 9223372036854775808ULL)
|| (unsigned long long) value > 18446744073709551615ULL
|| value < -9223372036854775807LL-1)
throw parse_error ("number invalid or out of range");
if (neg)
value = -value;
return t;
}
const token*
parser::expect_ident (std::string & target)
{
return expect_unknown (tok_identifier, target);
}
const token*
parser::expect_ident_or_keyword (std::string & target)
{
return expect_unknown2 (tok_identifier, tok_keyword, target);
}
bool
parser::peek_op (std::string const & op)
{
return tok_is (peek(), tok_operator, op);
}
bool
parser::peek_kw (std::string const & kw)
{
return tok_is (peek(), tok_identifier, kw);
}
lexer::lexer (istream& i, const string& in, systemtap_session& s):
input (i), input_name (in), cursor_suspend_count(0),
cursor_line (1), cursor_column (1), session(s)
{ }
int
lexer::input_peek (unsigned n)
{
while (lookahead.size() <= n)
{
int c = input.get ();
lookahead.push_back (input ? c : -1);
}
return lookahead[n];
}
int
lexer::input_get ()
{
int c = input_peek (0);
lookahead.erase (lookahead.begin ());
if (c < 0) return c; // EOF
if (cursor_suspend_count)
// Track effect of input_put: preserve previous cursor/line_column
// until all of its characters are consumed.
cursor_suspend_count --;
else
{
// update source cursor
if (c == '\n')
{
cursor_line ++;
cursor_column = 1;
}
else
cursor_column ++;
}
return c;
}
void
lexer::input_put (const string& chars)
{
// clog << "[put:" << chars << "]";
for (int i=chars.size()-1; i>=0; i--)
{
int c = chars[i];
lookahead.insert (lookahead.begin(), c);
cursor_suspend_count ++;
}
}
token*
lexer::scan (bool expand_args)
{
token* n = new token;
n->location.file = input_name;
unsigned semiskipped_p = 0;
skip:
n->location.line = cursor_line;
n->location.column = cursor_column;
semiskip:
if (semiskipped_p > 1)
{
input_get ();
throw parse_error ("invalid nested substitution of command line arguments");
}
int c = input_get();
int c2 = input_peek ();
// clog << "{" << (char)c << (char)c2 << "}";
if (c < 0)
{
delete n;
return 0;
}
if (isspace (c))
goto skip;
// Paste command line arguments as character streams into
// the beginning of a token. $1..$999 go through as raw
// characters; @1..@999 are quoted/escaped as strings.
// $# and @# expand to the number of arguments, similarly
// raw or quoted.
if (expand_args &&
(c == '$' || c == '@') &&
(c2 == '#'))
{
input_get(); // swallow '#'
stringstream converter;
converter << session.args.size ();
if (c == '$') input_put (converter.str());
else input_put (lex_cast_qstring (converter.str()));
semiskipped_p ++;
goto semiskip;
}
else if (expand_args &&
(c == '$' || c == '@') &&
(isdigit (c2)))
{
unsigned idx = 0;
do
{
input_get ();
idx = (idx * 10) + (c2 - '0');
c2 = input_peek ();
} while (c2 > 0 &&
isdigit (c2) &&
idx <= session.args.size()); // prevent overflow
if (idx == 0 ||
idx-1 >= session.args.size())
throw parse_error ("command line argument index invalid or out of range", n);
string arg = session.args[idx-1];
if (c == '$') input_put (arg);
else input_put (lex_cast_qstring (arg));
semiskipped_p ++;
goto semiskip;
}
else if (isalpha (c) || c == '$' || c == '@' || c == '_')
{
n->type = tok_identifier;
n->content = (char) c;
while (isalnum (c2) || c2 == '_' || c2 == '$')
{
input_get ();
n->content.push_back (c2);
c2 = input_peek ();
}
if (n->content == "probe"
|| n->content == "global"
|| n->content == "function"
|| n->content == "if"
|| n->content == "else"
|| n->content == "for"
|| n->content == "foreach"
|| n->content == "in"
|| n->content == "limit"
|| n->content == "return"
|| n->content == "delete"
|| n->content == "while"
|| n->content == "break"
|| n->content == "continue"
|| n->content == "next"
|| n->content == "string"
|| n->content == "long")
n->type = tok_keyword;
return n;
}
else if (isdigit (c)) // positive literal
{
n->type = tok_number;
n->content = (char) c;
while (1)
{
int c2 = input_peek ();
if (c2 < 0)
break;
// NB: isalnum is very permissive. We rely on strtol, called in
// parser::parse_literal below, to confirm that the number string
// is correctly formatted and in range.
if (isalnum (c2))
{
n->content.push_back (c2);
input_get ();
}
else
break;
}
return n;
}
else if (c == '\"')
{
n->type = tok_string;
while (1)
{
c = input_get ();
if (c < 0 || c == '\n')
{
n->type = tok_junk;
break;
}
if (c == '\"') // closing double-quotes
break;
else if (c == '\\') // see also input_put
{
c = input_get ();
switch (c)
{
case 'a':
case 'b':
case 't':
case 'n':
case 'v':
case 'f':
case 'r':
case '0' ... '7': // NB: need only match the first digit
case '\\':
// Pass these escapes through to the string value
// being parsed; it will be emitted into a C literal.
n->content.push_back('\\');
// fall through
default:
n->content.push_back(c);
break;
}
}
else
n->content.push_back(c);
}
return n;
}
else if (ispunct (c))
{
int c2 = input_peek ();
int c3 = input_peek (1);
string s1 = string("") + (char) c;
string s2 = (c2 > 0 ? s1 + (char) c2 : s1);
string s3 = (c3 > 0 ? s2 + (char) c3 : s2);
// NB: if we were to recognize negative numeric literals here,
// we'd introduce another grammar ambiguity:
// 1-1 would be parsed as tok_number(1) and tok_number(-1)
// instead of tok_number(1) tok_operator('-') tok_number(1)
if (s1 == "#") // shell comment
{
unsigned this_line = cursor_line;
do { c = input_get (); }
while (c >= 0 && cursor_line == this_line);
goto skip;
}
else if (s2 == "//") // C++ comment
{
unsigned this_line = cursor_line;
do { c = input_get (); }
while (c >= 0 && cursor_line == this_line);
goto skip;
}
else if (c == '/' && c2 == '*') // C comment
{
c2 = input_get ();
unsigned chars = 0;
while (c2 >= 0)
{
chars ++; // track this to prevent "/*/" from being accepted
c = c2;
c2 = input_get ();
if (chars > 1 && c == '*' && c2 == '/')
break;
}
goto skip;
}
else if (c == '%' && c2 == '{') // embedded code
{
n->type = tok_embedded;
(void) input_get (); // swallow '{' already in c2
while (true)
{
c = input_get ();
if (c < 0) // EOF
{
n->type = tok_junk;
break;
}
if (c == '%')
{
c2 = input_peek ();
if (c2 == '}')
{
(void) input_get (); // swallow '}' too
break;
}
}
n->content += c;
}
return n;
}
// We're committed to recognizing at least the first character
// as an operator.
n->type = tok_operator;
// match all valid operators, in decreasing size order
if (s3 == "<<<" ||
s3 == "<<=" ||
s3 == ">>=")
{
n->content = s3;
input_get (); input_get (); // swallow other two characters
}
else if (s2 == "==" ||
s2 == "!=" ||
s2 == "<=" ||
s2 == ">=" ||
s2 == "+=" ||
s2 == "-=" ||
s2 == "*=" ||
s2 == "/=" ||
s2 == "%=" ||
s2 == "&=" ||
s2 == "^=" ||
s2 == "|=" ||
s2 == ".=" ||
s2 == "&&" ||
s2 == "||" ||
s2 == "++" ||
s2 == "--" ||
s2 == "->" ||
s2 == "<<" ||
s2 == ">>" ||
// preprocessor tokens
s2 == "%(" ||
s2 == "%?" ||
s2 == "%:" ||
s2 == "%)")
{
n->content = s2;
input_get (); // swallow other character
}
else
{
n->content = s1;
}
return n;
}
else
{
n->type = tok_junk;
n->content = (char) c;
return n;
}
}
// ------------------------------------------------------------------------
stapfile*
parser::parse ()
{
stapfile* f = new stapfile;
f->name = input_name;
bool empty = true;
while (1)
{
try
{
const token* t = peek ();
if (! t) // nice clean EOF
break;
empty = false;
if (t->type == tok_keyword && t->content == "probe")
{
context = con_probe;
parse_probe (f->probes, f->aliases);
}
else if (t->type == tok_keyword && t->content == "global")
{
context = con_global;
parse_global (f->globals, f->probes);
}
else if (t->type == tok_keyword && t->content == "function")
{
context = con_function;
parse_functiondecl (f->functions);
}
else if (t->type == tok_embedded)
{
context = con_embedded;
f->embeds.push_back (parse_embeddedcode ());
}
else
{
context = con_unknown;
throw parse_error ("expected 'probe', 'global', 'function', or '%{'");
}
}
catch (parse_error& pe)
{
print_error (pe);
if (pe.skip_some) // for recovery
try
{
// Quietly swallow all tokens until the next '}'.
while (1)
{
const token* t = peek ();
if (! t)
break;
next ();
if (t->type == tok_operator && t->content == "}")
break;
}
}
catch (parse_error& pe2)
{
// parse error during recovery ... ugh
print_error (pe2);
}
}
}
if (empty)
{
cerr << "Input file '" << input_name << "' is empty or missing." << endl;
delete f;
return 0;
}
else if (num_errors > 0)
{
cerr << num_errors << " parse error(s)." << endl;
delete f;
return 0;
}
return f;
}
void
parser::parse_probe (std::vector<probe *> & probe_ret,
std::vector<probe_alias *> & alias_ret)
{
const token* t0 = next ();
if (! (t0->type == tok_keyword && t0->content == "probe"))
throw parse_error ("expected 'probe'");
vector<probe_point *> aliases;
vector<probe_point *> locations;
bool equals_ok = true;
int epilogue_alias = 0;
while (1)
{
probe_point * pp = parse_probe_point ();
const token* t = peek ();
if (equals_ok && t
&& t->type == tok_operator && t->content == "=")
{
aliases.push_back(pp);
next ();
continue;
}
else if (equals_ok && t
&& t->type == tok_operator && t->content == "+=")
{
aliases.push_back(pp);
epilogue_alias = 1;
next ();
continue;
}
else if (t && t->type == tok_operator && t->content == ",")
{
locations.push_back(pp);
equals_ok = false;
next ();
continue;
}
else if (t && t->type == tok_operator && t->content == "{")
{
locations.push_back(pp);
break;
}
else
throw parse_error ("expected probe point specifier");
}
if (aliases.empty())
{
probe* p = new probe;
p->tok = t0;
p->locations = locations;
p->body = parse_stmt_block ();
p->privileged = privileged;
probe_ret.push_back (p);
}
else
{
probe_alias* p = new probe_alias (aliases);
if(epilogue_alias)
p->epilogue_style = true;
else
p->epilogue_style = false;
p->tok = t0;
p->locations = locations;
p->body = parse_stmt_block ();
p->privileged = privileged;
alias_ret.push_back (p);
}
}
embeddedcode*
parser::parse_embeddedcode ()
{
embeddedcode* e = new embeddedcode;
const token* t = next ();
if (t->type != tok_embedded)
throw parse_error ("expected '%{'");
if (! privileged)
throw parse_error ("embedded code in unprivileged script",
false /* don't skip tokens for parse resumption */);
e->tok = t;
e->code = t->content;
return e;
}
block*
parser::parse_stmt_block ()
{
block* pb = new block;
const token* t = next ();
if (! (t->type == tok_operator && t->content == "{"))
throw parse_error ("expected '{'");
pb->tok = t;
while (1)
{
try
{
t = peek ();
if (t && t->type == tok_operator && t->content == "}")
{
next ();
break;
}
pb->statements.push_back (parse_statement ());
}
catch (parse_error& pe)
{
print_error (pe);
// Quietly swallow all tokens until the next ';' or '}'.
while (1)
{
const token* t = peek ();
if (! t) return 0;
next ();
if (t->type == tok_operator
&& (t->content == "}" || t->content == ";"))
break;
}
}
}
return pb;
}
statement*
parser::parse_statement ()
{
const token* t = peek ();
if (t && t->type == tok_operator && t->content == ";")
{
null_statement* n = new null_statement ();
n->tok = next ();
return n;
}
else if (t && t->type == tok_operator && t->content == "{")
return parse_stmt_block ();
else if (t && t->type == tok_keyword && t->content == "if")
return parse_if_statement ();
else if (t && t->type == tok_keyword && t->content == "for")
return parse_for_loop ();
else if (t && t->type == tok_keyword && t->content == "foreach")
return parse_foreach_loop ();
else if (t && t->type == tok_keyword && t->content == "return")
return parse_return_statement ();
else if (t && t->type == tok_keyword && t->content == "delete")
return parse_delete_statement ();
else if (t && t->type == tok_keyword && t->content == "while")
return parse_while_loop ();
else if (t && t->type == tok_keyword && t->content == "break")
return parse_break_statement ();
else if (t && t->type == tok_keyword && t->content == "continue")
return parse_continue_statement ();
else if (t && t->type == tok_keyword && t->content == "next")
return parse_next_statement ();
// XXX: "do/while" statement?
else if (t && (t->type == tok_operator || // expressions are flexible
t->type == tok_identifier ||
t->type == tok_number ||
t->type == tok_string))
return parse_expr_statement ();
// XXX: consider generally accepting tok_embedded here too
else
throw parse_error ("expected statement");
}
void
parser::parse_global (vector <vardecl*>& globals, vector<probe*>&)
{
const token* t0 = next ();
if (! (t0->type == tok_keyword && t0->content == "global"))
throw parse_error ("expected 'global'");
while (1)
{
const token* t = next ();
if (! (t->type == tok_identifier))
throw parse_error ("expected identifier");
for (unsigned i=0; i<globals.size(); i++)
if (globals[i]->name == t->content)
throw parse_error ("duplicate global name");
vardecl* d = new vardecl;
d->name = t->content;
d->tok = t;
globals.push_back (d);
t = peek ();
if (t && t->type == tok_operator && t->content == "[") // array size
{
int64_t size;
next ();
expect_number(size);
if (size <= 0 || size > 1000000) // arbitrary max
throw parse_error("array size out of range");
d->maxsize = (int)size;
expect_known(tok_operator, "]");
t = peek ();
}
if (t && t->type == tok_operator && t->content == "=") // initialization
{
if (!d->compatible_arity(0))
throw parse_error("only scalar globals can be initialized");
d->set_arity(0);
next ();
d->init = parse_literal ();
d->type = d->init->type;
t = peek ();
}
if (t && t->type == tok_operator && t->content == ",") // next global
{
next ();
continue;
}
else
break;
}
}
void
parser::parse_functiondecl (std::vector<functiondecl*>& functions)
{
const token* t = next ();
if (! (t->type == tok_keyword && t->content == "function"))
throw parse_error ("expected 'function'");
t = next ();
if (! (t->type == tok_identifier)
&& ! (t->type == tok_keyword
&& (t->content == "string" || t->content == "long")))
throw parse_error ("expected identifier");
for (unsigned i=0; i<functions.size(); i++)
if (functions[i]->name == t->content)
throw parse_error ("duplicate function name");
functiondecl *fd = new functiondecl ();
fd->name = t->content;
fd->tok = t;
t = next ();
if (t->type == tok_operator && t->content == ":")
{
t = next ();
if (t->type == tok_keyword && t->content == "string")
fd->type = pe_string;
else if (t->type == tok_keyword && t->content == "long")
fd->type = pe_long;
else throw parse_error ("expected 'string' or 'long'");
t = next ();
}
if (! (t->type == tok_operator && t->content == "("))
throw parse_error ("expected '('");
while (1)
{
t = next ();
// permit zero-argument fuctions
if (t->type == tok_operator && t->content == ")")
break;
else if (! (t->type == tok_identifier))
throw parse_error ("expected identifier");
vardecl* vd = new vardecl;
vd->name = t->content;
vd->tok = t;
fd->formal_args.push_back (vd);
t = next ();
if (t->type == tok_operator && t->content == ":")
{
t = next ();
if (t->type == tok_keyword && t->content == "string")
vd->type = pe_string;
else if (t->type == tok_keyword && t->content == "long")
vd->type = pe_long;
else throw parse_error ("expected 'string' or 'long'");
t = next ();
}
if (t->type == tok_operator && t->content == ")")
break;
if (t->type == tok_operator && t->content == ",")
continue;
else
throw parse_error ("expected ',' or ')'");
}
t = peek ();
if (t && t->type == tok_embedded)
fd->body = parse_embeddedcode ();
else
fd->body = parse_stmt_block ();
functions.push_back (fd);
}
probe_point*
parser::parse_probe_point ()
{
probe_point* pl = new probe_point;
while (1)
{
const token* t = next ();
if (! (t->type == tok_identifier
// we must allow ".return" and ".function", which are keywords
|| t->type == tok_keyword
|| (t->type == tok_operator && t->content == "*")))
throw parse_error ("expected identifier or '*'");
if (pl->tok == 0) pl->tok = t;
probe_point::component* c = new probe_point::component;
c->functor = t->content;
pl->components.push_back (c);
// NB we may add c->arg soon
const token* last_t = t;
t = peek ();
// We need to keep going until we find something other than a
// '*' or identifier, since a probe point wildcard can be
// something like "*a", "*a*", "a*b", "a*b*", etc.
while (t &&
// case 1: '*{identifier}'
((last_t->type == tok_operator && last_t->content == "*"
&& (t->type == tok_identifier || t->type == tok_keyword))
// case 2: '{identifier}*'
|| ((last_t->type == tok_identifier
|| last_t->type == tok_keyword)
&& t->type == tok_operator && t->content == "*")))
{
c->functor += t->content;
next (); // consume the identifier or '*'
last_t = t;
t = peek ();
}
// consume optional parameter
if (t && t->type == tok_operator && t->content == "(")
{
next (); // consume "("
c->arg = parse_literal ();
t = next ();
if (! (t->type == tok_operator && t->content == ")"))
throw parse_error ("expected ')'");
t = peek ();
}
if (t && t->type == tok_operator && t->content == ".")
{
next ();
continue;
}
// We only fall through here at the end of a probe point (past
// all the dotted/parametrized components).
if (t && t->type == tok_operator && t->content == "?")
{
pl->optional = true;
next ();
t = peek ();
// fall through
}
if (t && t->type == tok_operator
&& (t->content == "{" || t->content == "," ||
t->content == "=" || t->content == "+=" ))
break;
throw parse_error ("expected '.' or ',' or '(' or '?' or '{' or '=' or '+='");
}
return pl;
}
literal*
parser::parse_literal ()
{
const token* t = next ();
literal* l;
if (t->type == tok_string)
l = new literal_string (t->content);
else
{
bool neg = false;
if (t->type == tok_operator && t->content == "-")
{
neg = true;
t = next ();
}
if (t->type == tok_number)
{
const char* startp = t->content.c_str ();
char* endp = (char*) startp;
// NB: we allow controlled overflow from LLONG_MIN .. ULLONG_MAX
// Actually, this allows all the way from -ULLONG_MAX to ULLONG_MAX,
// since the lexer only gives us positive digit strings, but we'll
// limit it to LLONG_MIN when a '-' operator is fed into the literal.
errno = 0;
long long value = (long long) strtoull (startp, & endp, 0);
if (errno == ERANGE || errno == EINVAL || *endp != '\0'
|| (neg && (unsigned long long) value > 9223372036854775808ULL)
|| (unsigned long long) value > 18446744073709551615ULL
|| value < -9223372036854775807LL-1)
throw parse_error ("number invalid or out of range");
if (neg)
value = -value;
l = new literal_number (value);
}
else
throw parse_error ("expected literal string or number");
}
l->tok = t;
return l;
}
if_statement*
parser::parse_if_statement ()
{
const token* t = next ();
if (! (t->type == tok_keyword && t->content == "if"))
throw parse_error ("expected 'if'");
if_statement* s = new if_statement;
s->tok = t;
t = next ();
if (! (t->type == tok_operator && t->content == "("))
throw parse_error ("expected '('");
s->condition = parse_expression ();
t = next ();
if (! (t->type == tok_operator && t->content == ")"))
throw parse_error ("expected ')'");
s->thenblock = parse_statement ();
t = peek ();
if (t && t->type == tok_keyword && t->content == "else")
{
next ();
s->elseblock = parse_statement ();
}
else
s->elseblock = 0; // in case not otherwise initialized
return s;
}
expr_statement*
parser::parse_expr_statement ()
{
expr_statement *es = new expr_statement;
const token* t = peek ();
es->tok = t;
es->value = parse_expression ();
return es;
}
return_statement*
parser::parse_return_statement ()
{
const token* t = next ();
if (! (t->type == tok_keyword && t->content == "return"))
throw parse_error ("expected 'return'");
if (context != con_function)
throw parse_error ("found 'return' not in function context");
return_statement* s = new return_statement;
s->tok = t;
s->value = parse_expression ();
return s;
}
delete_statement*
parser::parse_delete_statement ()
{
const token* t = next ();
if (! (t->type == tok_keyword && t->content == "delete"))
throw parse_error ("expected 'delete'");
delete_statement* s = new delete_statement;
s->tok = t;
s->value = parse_expression ();
return s;
}
next_statement*
parser::parse_next_statement ()
{
const token* t = next ();
if (! (t->type == tok_keyword && t->content == "next"))
throw parse_error ("expected 'next'");
if (context != con_probe)
throw parse_error ("found 'next' not in probe context");
next_statement* s = new next_statement;
s->tok = t;
return s;
}
break_statement*
parser::parse_break_statement ()
{
const token* t = next ();
if (! (t->type == tok_keyword && t->content == "break"))
throw parse_error ("expected 'break'");
break_statement* s = new break_statement;
s->tok = t;
return s;
}
continue_statement*
parser::parse_continue_statement ()
{
const token* t = next ();
if (! (t->type == tok_keyword && t->content == "continue"))
throw parse_error ("expected 'continue'");
continue_statement* s = new continue_statement;
s->tok = t;
return s;
}
for_loop*
parser::parse_for_loop ()
{
const token* t = next ();
if (! (t->type == tok_keyword && t->content == "for"))
throw parse_error ("expected 'for'");
for_loop* s = new for_loop;
s->tok = t;
t = next ();
if (! (t->type == tok_operator && t->content == "("))
throw parse_error ("expected '('");
// initializer + ";"
t = peek ();
if (t && t->type == tok_operator && t->content == ";")
{
s->init = 0;
next ();
}
else
{
s->init = parse_expr_statement ();
t = next ();
if (! (t->type == tok_operator && t->content == ";"))
throw parse_error ("expected ';'");
}
// condition + ";"
t = peek ();
if (t && t->type == tok_operator && t->content == ";")
{
literal_number* l = new literal_number(1);
s->cond = l;
s->cond->tok = next ();
}
else
{
s->cond = parse_expression ();
t = next ();
if (! (t->type == tok_operator && t->content == ";"))
throw parse_error ("expected ';'");
}
// increment + ")"
t = peek ();
if (t && t->type == tok_operator && t->content == ")")
{
s->incr = 0;
next ();
}
else
{
s->incr = parse_expr_statement ();
t = next ();
if (! (t->type == tok_operator && t->content == ")"))
throw parse_error ("expected ')'");
}
// block
s->block = parse_statement ();
return s;
}
for_loop*
parser::parse_while_loop ()
{
const token* t = next ();
if (! (t->type == tok_keyword && t->content == "while"))
throw parse_error ("expected 'while'");
for_loop* s = new for_loop;
s->tok = t;
t = next ();
if (! (t->type == tok_operator && t->content == "("))
throw parse_error ("expected '('");
// dummy init and incr fields
s->init = 0;
s->incr = 0;
// condition
s->cond = parse_expression ();
t = next ();
if (! (t->type == tok_operator && t->content == ")"))
throw parse_error ("expected ')'");
// block
s->block = parse_statement ();
return s;
}
foreach_loop*
parser::parse_foreach_loop ()
{
const token* t = next ();
if (! (t->type == tok_keyword && t->content == "foreach"))
throw parse_error ("expected 'foreach'");
foreach_loop* s = new foreach_loop;
s->tok = t;
s->sort_direction = 0;
s->limit = NULL;
t = next ();
if (! (t->type == tok_operator && t->content == "("))
throw parse_error ("expected '('");
// see also parse_array_in
bool parenthesized = false;
t = peek ();
if (t && t->type == tok_operator && t->content == "[")
{
next ();
parenthesized = true;
}
while (1)
{
t = next ();
if (! (t->type == tok_identifier))
throw parse_error ("expected identifier");
symbol* sym = new symbol;
sym->tok = t;
sym->name = t->content;
s->indexes.push_back (sym);
t = peek ();
if (t && t->type == tok_operator &&
(t->content == "+" || t->content == "-"))
{
if (s->sort_direction)
throw parse_error ("multiple sort directives");
s->sort_direction = (t->content == "+") ? 1 : -1;
s->sort_column = s->indexes.size();
next();
}
if (parenthesized)
{
t = peek ();
if (t && t->type == tok_operator && t->content == ",")
{
next ();
continue;
}
else if (t && t->type == tok_operator && t->content == "]")
{
next ();
break;
}
else
throw parse_error ("expected ',' or ']'");
}
else
break; // expecting only one expression
}
t = next ();
if (! (t->type == tok_keyword && t->content == "in"))
throw parse_error ("expected 'in'");
s->base = parse_indexable();
t = peek ();
if (t && t->type == tok_operator &&
(t->content == "+" || t->content == "-"))
{
if (s->sort_direction)
throw parse_error ("multiple sort directives");
s->sort_direction = (t->content == "+") ? 1 : -1;
s->sort_column = 0;
next();
}
t = peek ();
if (tok_is(t, tok_keyword, "limit"))
{
next (); // get past the "limit"
s->limit = parse_expression ();
}
t = next ();
if (! (t->type == tok_operator && t->content == ")"))
throw parse_error ("expected ')'");
s->block = parse_statement ();
return s;
}
expression*
parser::parse_expression ()
{
return parse_assignment ();
}
expression*
parser::parse_assignment ()
{
expression* op1 = parse_ternary ();
const token* t = peek ();
// right-associative operators
if (t && t->type == tok_operator
&& (t->content == "=" ||
t->content == "<<<" ||
t->content == "+=" ||
t->content == "-=" ||
t->content == "*=" ||
t->content == "/=" ||
t->content == "%=" ||
t->content == "<<=" ||
t->content == ">>=" ||
t->content == "&=" ||
t->content == "^=" ||
t->content == "|=" ||
t->content == ".=" ||
false))
{
// NB: lvalueness is checked during elaboration / translation
assignment* e = new assignment;
e->left = op1;
e->op = t->content;
e->tok = t;
next ();
e->right = parse_expression ();
op1 = e;
}
return op1;
}
expression*
parser::parse_ternary ()
{
expression* op1 = parse_logical_or ();
const token* t = peek ();
if (t && t->type == tok_operator && t->content == "?")
{
ternary_expression* e = new ternary_expression;
e->tok = t;
e->cond = op1;
next ();
e->truevalue = parse_expression (); // XXX
t = next ();
if (! (t->type == tok_operator && t->content == ":"))
throw parse_error ("expected ':'");
e->falsevalue = parse_expression (); // XXX
return e;
}
else
return op1;
}
expression*
parser::parse_logical_or ()
{
expression* op1 = parse_logical_and ();
const token* t = peek ();
while (t && t->type == tok_operator && t->content == "||")
{
logical_or_expr* e = new logical_or_expr;
e->tok = t;
e->op = t->content;
e->left = op1;
next ();
e->right = parse_logical_and ();
op1 = e;
t = peek ();
}
return op1;
}
expression*
parser::parse_logical_and ()
{
expression* op1 = parse_boolean_or ();
const token* t = peek ();
while (t && t->type == tok_operator && t->content == "&&")
{
logical_and_expr *e = new logical_and_expr;
e->left = op1;
e->op = t->content;
e->tok = t;
next ();
e->right = parse_boolean_or ();
op1 = e;
t = peek ();
}
return op1;
}
expression*
parser::parse_boolean_or ()
{
expression* op1 = parse_boolean_xor ();
const token* t = peek ();
while (t && t->type == tok_operator && t->content == "|")
{
binary_expression* e = new binary_expression;
e->left = op1;
e->op = t->content;
e->tok = t;
next ();
e->right = parse_boolean_xor ();
op1 = e;
t = peek ();
}
return op1;
}
expression*
parser::parse_boolean_xor ()
{
expression* op1 = parse_boolean_and ();
const token* t = peek ();
while (t && t->type == tok_operator && t->content == "^")
{
binary_expression* e = new binary_expression;
e->left = op1;
e->op = t->content;
e->tok = t;
next ();
e->right = parse_boolean_and ();
op1 = e;
t = peek ();
}
return op1;
}
expression*
parser::parse_boolean_and ()
{
expression* op1 = parse_array_in ();
const token* t = peek ();
while (t && t->type == tok_operator && t->content == "&")
{
binary_expression* e = new binary_expression;
e->left = op1;
e->op = t->content;
e->tok = t;
next ();
e->right = parse_array_in ();
op1 = e;
t = peek ();
}
return op1;
}
expression*
parser::parse_array_in ()
{
// This is a very tricky case. All these are legit expressions:
// "a in b" "a+0 in b" "[a,b] in c" "[c,(d+0)] in b"
vector<expression*> indexes;
bool parenthesized = false;
const token* t = peek ();
if (t && t->type == tok_operator && t->content == "[")
{
next ();
parenthesized = true;
}
while (1)
{
expression* op1 = parse_comparison ();
indexes.push_back (op1);
if (parenthesized)
{
const token* t = peek ();
if (t && t->type == tok_operator && t->content == ",")
{
next ();
continue;
}
else if (t && t->type == tok_operator && t->content == "]")
{
next ();
break;
}
else
throw parse_error ("expected ',' or ']'");
}
else
break; // expecting only one expression
}
t = peek ();
if (t && t->type == tok_keyword && t->content == "in")
{
array_in *e = new array_in;
e->tok = t;
next (); // swallow "in"
arrayindex* a = new arrayindex;
a->indexes = indexes;
a->base = parse_indexable();
a->tok = a->base->get_tok();
e->operand = a;
return e;
}
else if (indexes.size() == 1) // no "in" - need one expression only
return indexes[0];
else
throw parse_error ("unexpected comma-separated expression list");
}
expression*
parser::parse_comparison ()
{
expression* op1 = parse_shift ();
const token* t = peek ();
while (t && t->type == tok_operator
&& (t->content == ">" ||
t->content == "<" ||
t->content == "==" ||
t->content == "!=" ||
t->content == "<=" ||
t->content == ">="))
{
comparison* e = new comparison;
e->left = op1;
e->op = t->content;
e->tok = t;
next ();
e->right = parse_shift ();
op1 = e;
t = peek ();
}
return op1;
}
expression*
parser::parse_shift ()
{
expression* op1 = parse_concatenation ();
const token* t = peek ();
while (t && t->type == tok_operator &&
(t->content == "<<" || t->content == ">>"))
{
binary_expression* e = new binary_expression;
e->left = op1;
e->op = t->content;
e->tok = t;
next ();
e->right = parse_concatenation ();
op1 = e;
t = peek ();
}
return op1;
}
expression*
parser::parse_concatenation ()
{
expression* op1 = parse_additive ();
const token* t = peek ();
// XXX: the actual awk string-concatenation operator is *whitespace*.
// I don't know how to easily to model that here.
while (t && t->type == tok_operator && t->content == ".")
{
concatenation* e = new concatenation;
e->left = op1;
e->op = t->content;
e->tok = t;
next ();
e->right = parse_additive ();
op1 = e;
t = peek ();
}
return op1;
}
expression*
parser::parse_additive ()
{
expression* op1 = parse_multiplicative ();
const token* t = peek ();
while (t && t->type == tok_operator
&& (t->content == "+" || t->content == "-"))
{
binary_expression* e = new binary_expression;
e->op = t->content;
e->left = op1;
e->tok = t;
next ();
e->right = parse_multiplicative ();
op1 = e;
t = peek ();
}
return op1;
}
expression*
parser::parse_multiplicative ()
{
expression* op1 = parse_unary ();
const token* t = peek ();
while (t && t->type == tok_operator
&& (t->content == "*" || t->content == "/" || t->content == "%"))
{
binary_expression* e = new binary_expression;
e->op = t->content;
e->left = op1;
e->tok = t;
next ();
e->right = parse_unary ();
op1 = e;
t = peek ();
}
return op1;
}
expression*
parser::parse_unary ()
{
const token* t = peek ();
if (t && t->type == tok_operator
&& (t->content == "+" ||
t->content == "-" ||
t->content == "!" ||
t->content == "~" ||
false))
{
unary_expression* e = new unary_expression;
e->op = t->content;
e->tok = t;
next ();
e->operand = parse_crement ();
return e;
}
else
return parse_crement ();
}
expression*
parser::parse_crement () // as in "increment" / "decrement"
{
// NB: Ideally, we'd parse only a symbol as an operand to the
// *crement operators, instead of a general expression value. We'd
// need more complex lookahead code to tell apart the postfix cases.
// So we just punt, and leave it to pass-3 to signal errors on
// cases like "4++".
const token* t = peek ();
if (t && t->type == tok_operator
&& (t->content == "++" || t->content == "--"))
{
pre_crement* e = new pre_crement;
e->op = t->content;
e->tok = t;
next ();
e->operand = parse_value ();
return e;
}
// post-crement or non-crement
expression *op1 = parse_value ();
t = peek ();
if (t && t->type == tok_operator
&& (t->content == "++" || t->content == "--"))
{
post_crement* e = new post_crement;
e->op = t->content;
e->tok = t;
next ();
e->operand = op1;
return e;
}
else
return op1;
}
expression*
parser::parse_value ()
{
const token* t = peek ();
if (! t)
throw parse_error ("expected value");
if (t->type == tok_operator && t->content == "(")
{
next ();
expression* e = parse_expression ();
t = next ();
if (! (t->type == tok_operator && t->content == ")"))
throw parse_error ("expected ')'");
return e;
}
else if (t->type == tok_identifier)
return parse_symbol ();
else
return parse_literal ();
}
const token *
parser::parse_hist_op_or_bare_name (hist_op *&hop, string &name)
{
hop = NULL;
const token* t = expect_ident (name);
if (name == "@hist_linear" || name == "@hist_log")
{
hop = new hist_op;
if (name == "@hist_linear")
hop->htype = hist_linear;
else if (name == "@hist_log")
hop->htype = hist_log;
hop->tok = t;
expect_op("(");
hop->stat = parse_expression ();
int64_t tnum;
if (hop->htype == hist_linear)
{
for (size_t i = 0; i < 3; ++i)
{
expect_op (",");
expect_number (tnum);
hop->params.push_back (tnum);
}
}
expect_op(")");
}
return t;
}
indexable*
parser::parse_indexable ()
{
hist_op *hop = NULL;
string name;
const token *tok = parse_hist_op_or_bare_name(hop, name);
if (hop)
return hop;
else
{
symbol* sym = new symbol;
sym->name = name;
sym->tok = tok;
return sym;
}
}
// var, indexable[index], func(parms), printf("...", ...), $var, $var->member, @stat_op(stat)
expression*
parser::parse_symbol ()
{
hist_op *hop = NULL;
symbol *sym = NULL;
string name;
const token *t = parse_hist_op_or_bare_name(hop, name);
if (!hop)
{
// If we didn't get a hist_op, then we did get an identifier. We can
// now scrutinize this identifier for the various magic forms of identifier
// (printf, @stat_op, and $var...)
bool pf_stream, pf_format, pf_delim, pf_newline;
if (name.size() > 0 && name[0] == '@')
{
stat_op *sop = new stat_op;
if (name == "@avg")
sop->ctype = sc_average;
else if (name == "@count")
sop->ctype = sc_count;
else if (name == "@sum")
sop->ctype = sc_sum;
else if (name == "@min")
sop->ctype = sc_min;
else if (name == "@max")
sop->ctype = sc_max;
else
throw parse_error("unknown statistic operator " + name);
expect_op("(");
sop->tok = t;
sop->stat = parse_expression ();
expect_op(")");
return sop;
}
else if (print_format::parse_print(name,
pf_stream, pf_format, pf_delim, pf_newline))
{
print_format *fmt = new print_format;
fmt->tok = t;
fmt->print_to_stream = pf_stream;
fmt->print_with_format = pf_format;
fmt->print_with_delim = pf_delim;
fmt->print_with_newline = pf_newline;
expect_op("(");
if ((name == "print" || name == "println") &&
(peek_kw("@hist_linear") || peek_kw("@hist_log")))
{
// We have a special case where we recognize
// print(@hist_foo(bar)) as a magic print-the-histogram
// construct. This is sort of gross but it avoids
// promoting histogram references to typeful
// expressions.
hop = NULL;
t = parse_hist_op_or_bare_name(hop, name);
assert(hop);
// It is, sadly, possible that even while parsing a
// hist_op, we *mis-guessed* and the user wishes to
// print(@hist_op(foo)[bucket]), a scalar. In that case
// we must parse the arrayindex and print an expression.
if (!peek_op ("["))
fmt->hist = hop;
else
{
// This is simplified version of the
// multi-array-index parser below, because we can
// only ever have one index on a histogram anyways.
expect_op("[");
struct arrayindex* ai = new arrayindex;
ai->tok = t;
ai->base = hop;
ai->indexes.push_back (parse_expression ());
expect_op("]");
fmt->args.push_back(ai);
}
}
else
{
int min_args = 0;
if (fmt->print_with_format)
{
// Consume and convert a format string. Agreement between the
// format string and the arguments is postponed to the
// typechecking phase.
string tmp;
expect_unknown (tok_string, tmp);
fmt->raw_components = tmp;
fmt->components = print_format::string_to_components (tmp);
}
else if (fmt->print_with_delim)
{
// Consume a delimiter to separate arguments.
fmt->delimiter.clear();
fmt->delimiter.type = print_format::conv_literal;
expect_unknown (tok_string, fmt->delimiter.literal_string);
min_args = 2;
}
else
{
// If we are not printing with a format string, we must have
// at least one argument (of any type).
expression *e = parse_expression ();
fmt->args.push_back(e);
}
// Consume any subsequent arguments.
while (min_args || !peek_op (")"))
{
expect_op(",");
expression *e = parse_expression ();
fmt->args.push_back(e);
if (min_args)
--min_args;
}
}
expect_op(")");
return fmt;
}
else if (name.size() > 0 && name[0] == '$')
{
// target_symbol time
target_symbol *tsym = new target_symbol;
tsym->tok = t;
tsym->base_name = name;
while (true)
{
string c;
if (peek_op ("->"))
{
next();
expect_ident_or_keyword (c);
tsym->components.push_back
(make_pair (target_symbol::comp_struct_member, c));
}
else if (peek_op ("["))
{
next();
expect_unknown (tok_number, c);
expect_op ("]");
tsym->components.push_back
(make_pair (target_symbol::comp_literal_array_index, c));
}
else
break;
}
return tsym;
}
else if (peek_op ("(")) // function call
{
next ();
struct functioncall* f = new functioncall;
f->tok = t;
f->function = name;
// Allow empty actual parameter list
if (peek_op (")"))
{
next ();
return f;
}
while (1)
{
f->args.push_back (parse_expression ());
if (peek_op (")"))
{
next();
break;
}
else if (peek_op (","))
{
next();
continue;
}
else
throw parse_error ("expected ',' or ')'");
}
return f;
}
else
{
sym = new symbol;
sym->name = name;
sym->tok = t;
}
}
// By now, either we had a hist_op in the first place, or else
// we had a plain word and it was converted to a symbol.
assert (!hop != !sym); // logical XOR
// All that remains is to check for array indexing
if (peek_op ("[")) // array
{
next ();
struct arrayindex* ai = new arrayindex;
ai->tok = t;
if (hop)
ai->base = hop;
else
ai->base = sym;
while (1)
{
ai->indexes.push_back (parse_expression ());
if (peek_op ("]"))
{
next();
break;
}
else if (peek_op (","))
{
next();
continue;
}
else
throw parse_error ("expected ',' or ']'");
}
return ai;
}
// If we got to here, we *should* have a symbol; if we have
// a hist_op on its own, it doesn't count as an expression,
// so we throw a parse error.
if (hop)
throw parse_error("base histogram operator where expression expected", t);
return sym;
}
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