/* * The compiler code necessary to support the #fmt extension. Eventually this * should all get sucked into either the standard library extfmt module or the * compiler syntax extension plugin interface. */ import extfmt::ct::*; import base::*; import codemap::span; import ext::build::*; export expand_syntax_ext; fn expand_syntax_ext(cx: ext_ctxt, sp: span, arg: ast::mac_arg, _body: ast::mac_body) -> @ast::expr { let args = get_mac_args_no_max(cx, sp, arg, 1u, ~"fmt"); let fmt = expr_to_str(cx, args[0], ~"first argument to #fmt must be a string literal."); let fmtspan = args[0].span; debug!{"Format string:"}; log(debug, fmt); fn parse_fmt_err_(cx: ext_ctxt, sp: span, msg: ~str) -> ! { cx.span_fatal(sp, msg); } let parse_fmt_err = fn@(s: ~str) -> ! { parse_fmt_err_(cx, fmtspan, s) }; let pieces = parse_fmt_string(fmt, parse_fmt_err); return pieces_to_expr(cx, sp, pieces, args); } // FIXME (#2249): A lot of these functions for producing expressions can // probably be factored out in common with other code that builds // expressions. Also: Cleanup the naming of these functions. // NOTE: Moved many of the common ones to build.rs --kevina fn pieces_to_expr(cx: ext_ctxt, sp: span, pieces: ~[piece], args: ~[@ast::expr]) -> @ast::expr { fn make_path_vec(_cx: ext_ctxt, ident: ast::ident) -> ~[ast::ident] { return ~[@~"extfmt", @~"rt", ident]; } fn make_rt_path_expr(cx: ext_ctxt, sp: span, ident: ast::ident) -> @ast::expr { let path = make_path_vec(cx, ident); return mk_path(cx, sp, path); } // Produces an AST expression that represents a RT::conv record, // which tells the RT::conv* functions how to perform the conversion fn make_rt_conv_expr(cx: ext_ctxt, sp: span, cnv: conv) -> @ast::expr { fn make_flags(cx: ext_ctxt, sp: span, flags: ~[flag]) -> @ast::expr { let mut tmp_expr = make_rt_path_expr(cx, sp, @~"flag_none"); for flags.each |f| { let fstr = match f { flag_left_justify => ~"flag_left_justify", flag_left_zero_pad => ~"flag_left_zero_pad", flag_space_for_sign => ~"flag_space_for_sign", flag_sign_always => ~"flag_sign_always", flag_alternate => ~"flag_alternate" }; tmp_expr = mk_binary(cx, sp, ast::bitor, tmp_expr, make_rt_path_expr(cx, sp, @fstr)); } return tmp_expr; } fn make_count(cx: ext_ctxt, sp: span, cnt: count) -> @ast::expr { match cnt { count_implied => { return make_rt_path_expr(cx, sp, @~"count_implied"); } count_is(c) => { let count_lit = mk_int(cx, sp, c); let count_is_path = make_path_vec(cx, @~"count_is"); let count_is_args = ~[count_lit]; return mk_call(cx, sp, count_is_path, count_is_args); } _ => cx.span_unimpl(sp, ~"unimplemented #fmt conversion") } } fn make_ty(cx: ext_ctxt, sp: span, t: ty) -> @ast::expr { let mut rt_type; match t { ty_hex(c) => match c { case_upper => rt_type = ~"ty_hex_upper", case_lower => rt_type = ~"ty_hex_lower" }, ty_bits => rt_type = ~"ty_bits", ty_octal => rt_type = ~"ty_octal", _ => rt_type = ~"ty_default" } return make_rt_path_expr(cx, sp, @rt_type); } fn make_conv_rec(cx: ext_ctxt, sp: span, flags_expr: @ast::expr, width_expr: @ast::expr, precision_expr: @ast::expr, ty_expr: @ast::expr) -> @ast::expr { return mk_rec_e(cx, sp, ~[{ident: @~"flags", ex: flags_expr}, {ident: @~"width", ex: width_expr}, {ident: @~"precision", ex: precision_expr}, {ident: @~"ty", ex: ty_expr}]); } let rt_conv_flags = make_flags(cx, sp, cnv.flags); let rt_conv_width = make_count(cx, sp, cnv.width); let rt_conv_precision = make_count(cx, sp, cnv.precision); let rt_conv_ty = make_ty(cx, sp, cnv.ty); return make_conv_rec(cx, sp, rt_conv_flags, rt_conv_width, rt_conv_precision, rt_conv_ty); } fn make_conv_call(cx: ext_ctxt, sp: span, conv_type: ~str, cnv: conv, arg: @ast::expr) -> @ast::expr { let fname = ~"conv_" + conv_type; let path = make_path_vec(cx, @fname); let cnv_expr = make_rt_conv_expr(cx, sp, cnv); let args = ~[cnv_expr, arg]; return mk_call(cx, arg.span, path, args); } fn make_new_conv(cx: ext_ctxt, sp: span, cnv: conv, arg: @ast::expr) -> @ast::expr { // FIXME: Move validation code into core::extfmt (Issue #2249) fn is_signed_type(cnv: conv) -> bool { match cnv.ty { ty_int(s) => match s { signed => return true, unsigned => return false }, ty_float => return true, _ => return false } } let unsupported = ~"conversion not supported in #fmt string"; match cnv.param { option::none => (), _ => cx.span_unimpl(sp, unsupported) } for cnv.flags.each |f| { match f { flag_left_justify => (), flag_sign_always => { if !is_signed_type(cnv) { cx.span_fatal(sp, ~"+ flag only valid in " + ~"signed #fmt conversion"); } } flag_space_for_sign => { if !is_signed_type(cnv) { cx.span_fatal(sp, ~"space flag only valid in " + ~"signed #fmt conversions"); } } flag_left_zero_pad => (), _ => cx.span_unimpl(sp, unsupported) } } match cnv.width { count_implied => (), count_is(_) => (), _ => cx.span_unimpl(sp, unsupported) } match cnv.precision { count_implied => (), count_is(_) => (), _ => cx.span_unimpl(sp, unsupported) } match cnv.ty { ty_str => return make_conv_call(cx, arg.span, ~"str", cnv, arg), ty_int(sign) => match sign { signed => return make_conv_call(cx, arg.span, ~"int", cnv, arg), unsigned => { return make_conv_call(cx, arg.span, ~"uint", cnv, arg) } }, ty_bool => return make_conv_call(cx, arg.span, ~"bool", cnv, arg), ty_char => return make_conv_call(cx, arg.span, ~"char", cnv, arg), ty_hex(_) => { return make_conv_call(cx, arg.span, ~"uint", cnv, arg); } ty_bits => return make_conv_call(cx, arg.span, ~"uint", cnv, arg), ty_octal => return make_conv_call(cx, arg.span, ~"uint", cnv, arg), ty_float => { return make_conv_call(cx, arg.span, ~"float", cnv, arg); } ty_poly => return make_conv_call(cx, arg.span, ~"poly", cnv, arg) } } fn log_conv(c: conv) { match c.param { some(p) => { log(debug, ~"param: " + int::to_str(p, 10u)); } _ => debug!{"param: none"} } for c.flags.each |f| { match f { flag_left_justify => debug!{"flag: left justify"}, flag_left_zero_pad => debug!{"flag: left zero pad"}, flag_space_for_sign => debug!{"flag: left space pad"}, flag_sign_always => debug!{"flag: sign always"}, flag_alternate => debug!{"flag: alternate"} } } match c.width { count_is(i) => log( debug, ~"width: count is " + int::to_str(i, 10u)), count_is_param(i) => log( debug, ~"width: count is param " + int::to_str(i, 10u)), count_is_next_param => debug!{"width: count is next param"}, count_implied => debug!{"width: count is implied"} } match c.precision { count_is(i) => log( debug, ~"prec: count is " + int::to_str(i, 10u)), count_is_param(i) => log( debug, ~"prec: count is param " + int::to_str(i, 10u)), count_is_next_param => debug!{"prec: count is next param"}, count_implied => debug!{"prec: count is implied"} } match c.ty { ty_bool => debug!{"type: bool"}, ty_str => debug!{"type: str"}, ty_char => debug!{"type: char"}, ty_int(s) => match s { signed => debug!{"type: signed"}, unsigned => debug!{"type: unsigned"} }, ty_bits => debug!{"type: bits"}, ty_hex(cs) => match cs { case_upper => debug!{"type: uhex"}, case_lower => debug!{"type: lhex"}, }, ty_octal => debug!{"type: octal"}, ty_float => debug!{"type: float"}, ty_poly => debug!{"type: poly"} } } let fmt_sp = args[0].span; let mut n = 0u; let mut piece_exprs = ~[]; let nargs = args.len(); for pieces.each |pc| { match pc { piece_string(s) => { vec::push(piece_exprs, mk_uniq_str(cx, fmt_sp, s)) } piece_conv(conv) => { n += 1u; if n >= nargs { cx.span_fatal(sp, ~"not enough arguments to #fmt " + ~"for the given format string"); } debug!{"Building conversion:"}; log_conv(conv); let arg_expr = args[n]; let c_expr = make_new_conv(cx, fmt_sp, conv, arg_expr); vec::push(piece_exprs, c_expr); } } } let expected_nargs = n + 1u; // n conversions + the fmt string if expected_nargs < nargs { cx.span_fatal (sp, fmt!{"too many arguments to #fmt. found %u, expected %u", nargs, expected_nargs}); } let arg_vec = mk_fixed_vec_e(cx, fmt_sp, piece_exprs); return mk_call(cx, fmt_sp, ~[@~"str", @~"concat"], ~[arg_vec]); } // // Local Variables: // mode: rust // fill-column: 78; // indent-tabs-mode: nil // c-basic-offset: 4 // buffer-file-coding-system: utf-8-unix // End: //