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--edit -- Solved the question : a comment on the last sidenote would be helpfull. Also comments on phoenix::bind overload handling would be helpfull (in my answer).

I'm working on a system with strict typing requirements, I want to ensure that I am parsing integers that meet the constraints of int32_t and int64_t, I wan't the parsers to synthesise and constrain the parsed strings to the mentioned types.

How do I go about this ? The document mentions that long_long is only available on platforms with 64-bit support, but I need to parse int64_t's on 32-bit platforms as well.

An excerpt from my parser is as follows:

  eps(_b == VALUE_INT4) >> qi::long_ 
    [phoenix::bind(&AddEntry, _r1,_a, _1, _pass)] ) // 
| ( eps(_b == VALUE_INT8) >> qi::long_long)

AddEntry has a int32_t overload and a int64_t overload, is a phoenix::static_cast_ on _1in order ? And if this is the case how do I parse 64-bit integers on a modern 32-bit platform ? I assume BOOST_HAS_LONG_LONG is only not-defined on archaic hardware like the 8008 ;) .

<Rant> I wish they had stuck with the standards set out in c99 and <boost/cstdint.hpp>, most of us want to program against clean abstractions. There are probably good reasons for the numeric parsers being defined the way they are. however, grand-scheme use could be better defined in the documentation. </Rant>

On a side note: Does the conditional epsilon style above rival a case statement in performance ?

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2 Answers 2

up vote 1 down vote accepted

1) Qi parsers already check for overflow conditions. The parser component will fail if the input is not representable by the type the component is supposed to match. For instance, int_parser<int32_t, 10> will fail for numbers not fitting into a signed 32 bit integer.

You can use the long_long parser (i.e. the predefined 64 bit integer parser) only if BOOST_HAS_LONG_LONG is defined. If you have a platform where this is not the case, you can still emulate a 64bit integer by writing your own wrapper type exposing the functionality as expected by Qi numeric parsers (see here), for instance:

struct my_64bit_int {
typedef int_parser<my_64bit_int, 10> my_64bit_int_parser_type;
my_64bit_int_parser_type const my_64bit_int_parser;

and use it as:

my_64bit_int bigint;
parse(b, e, my_64bit_int_parser, bigint);

2) You can't bind overloaded functions without helping the compiler, i.e. given:

void AddEntry(int32_t);
void AddEntry(int64_t);

you need to cast the function pointer explicitly if you want to bind for an int32_t:

phoenix::bind((void(*)(int32_t))&AddEntry, _1);

Answer to sidenote: No. The alternative parser is always sequentially executing the different alternatives in the same sequence as specified, stopping when the first of those matches. Its overall complexity is O(N), where N is the number of separate alternatives (see here).

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Thank you as always Hartmut :D on the side-note, I was expecting O(N), however I was worried about the internals, I would be concerned if the implementation made N function calls for N conditionals, in function condition-checking would be what I would expect (like a case statement, unless I misunderstood how a case statement works). –  Hassan Syed Apr 6 '11 at 21:34
To elaborate, switch(xtype){ case(int): break; case(string): break; } is what I have tried to implement with ( eps(x_type == int) | eps(x_type == string) ). If the constructed parser had to make a function call internally to evaluate the eps(condion) for each element the overhead might be prohibitive. –  Hassan Syed Apr 6 '11 at 21:43

These templatas will get you the semantics you want.

qi::int_parser< int32_t,  10, 1,10>  p_int32_t;
qi::int_parser< int64_t, 10, 1, 19> p_int64_t;

These parsers were unit tested and created expectation errors on overflow --i.e., when >= 2^31 and >= 2^63 respectively.

Overloads aren't picked up by phoenix::bind afaik (correct me if I'm wrong please),

therefore a macro along the lines of

#define  ADD_ENTRY(TP,prefix)                                           \
    void AddEntry_##prefix( value_variant_vector & v, uint32_t ordinal, \
                            TP entry, bool & ok_)                       \

For those interested the compiler error message is as follows (when AddEntry is a template function):

/opt/dev_64_swat/dsl/src/parser/RowAndTable.cc:43: error: no matching function 
for call to ‘bind(<unresolved overloaded function type>, const
boost::phoenix::actor<boost::spirit::attribute<1> >&, const 
boost::phoenix::actor<boost::spirit::local_variable<0> >&, const 
boost::phoenix::actor<boost::spirit::argument<0> >&, const   
boost::phoenix::actor<boost::phoenix::argument<2> >&)’

I get errors on hand written overloads as well.

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