open Types
open Common
open Printf
let bpos = -1, -1
let raw_pos2pos(a, b) = !Info.current_file, a, b
let raw_pos_range { pos = (a1, b1) } { pos = (a2, b2) } = (if a1 = -1 then a2 else a1), (if b2 = -1 then b1 else b2)
let pos_range esp1 esp2 = raw_pos2pos (raw_pos_range esp1 esp2)
let get_pos pesp = raw_pos2pos pesp.pos
let get_pos_start { pos = (start, _) } = start
let get_pos_end { pos = (_, end_) } = end_
let var_dollar_ pos = Deref(I_scalar, Ident(None, "_", pos))
let var_STDOUT = Deref(I_star, Ident(None, "STDOUT", raw_pos2pos bpos))
let new_any mcontext any spaces pos = { mcontext = mcontext ; any = any ; spaces = spaces ; pos = pos }
let new_any_ any spaces pos = new_any M_unknown any spaces pos
let new_esp mcontext e esp_start esp_end = new_any mcontext e esp_start.spaces (raw_pos_range esp_start esp_end)
let new_1esp e esp = new_any esp.mcontext e esp.spaces esp.pos
let new_pesp mcontext prio e esp_start esp_end = new_any mcontext { priority = prio ; expr = e } esp_start.spaces (raw_pos_range esp_start esp_end)
let new_1pesp prio e esp = new_any esp.mcontext { priority = prio ; expr = e } esp.spaces esp.pos
let default_esp e = new_any M_unknown e Space_none bpos
let default_pesp prio e = new_any M_unknown { priority = prio ; expr = e } Space_none bpos
let split_name_or_fq_name full_ident =
match split_at2 ':'':' full_ident with
| [] -> internal_error "split_ident"
| [ident] -> None, ident
| l ->
let fql, name = split_last l in
let fq = String.concat "::" fql in
Some fq, name
let is_var_dollar_ = function
| Deref(I_scalar, Ident(None, "_", _)) -> true
| _ -> false
let is_var_number_match = function
| Deref(I_scalar, Ident(None, s, _)) -> String.length s = 1 && s.[0] <> '0' && char_is_number s.[0]
| _ -> false
let non_scalar_context context = context = I_hash || context = I_array
let is_scalar_context context = context = I_scalar
let rec is_not_a_scalar = function
| Deref_with(_, context, _, _)
| Deref(context, _) -> non_scalar_context context
| List []
| List(_ :: _ :: _) -> true
| Call(Deref(I_func, Ident(None, "map", _)), _)
| Call(Deref(I_func, Ident(None, "grep", _)), _) -> true
| Call_op("?:", [ _cond ; a; b ], _) -> is_not_a_scalar a || is_not_a_scalar b
| _ -> false
let is_a_scalar = function
| Ref _
| Num _
| Raw_string _
| String _ -> true
| My_our(_, [ context, _ ], _)
| Deref_with(_, context, _, _)
| Deref(context, _) -> is_scalar_context context
| _ -> false
let is_a_string = function
| String _ | Raw_string _ -> true
| _ -> false
let is_parenthesized = function
| List[]
| List[List _] -> true
| _ -> false
let un_parenthesize = function
| List[List[e]] -> e
| List[e] -> e
| _ -> internal_error "un_parenthesize"
let rec un_parenthesize_full = function
| List[e] -> un_parenthesize_full e
| e -> e
let rec un_parenthesize_full_l = function
| [ List l ] -> un_parenthesize_full_l l
| l -> l
let is_always_true = function
| Num(n, _) -> float_of_string n <> 0.
| Raw_string(s, _) -> s <> ""
| String(l, _) -> l <> []
| Ref _ -> true
| _ -> false
let is_always_false = function
| Num(n, _) -> float_of_string n = 0.
| Raw_string(s, _) -> s = ""
| String(l, _) -> l = []
| List [] -> true
| Ident(None, "undef", _) -> true
| _ -> false
let not_complex e =
if is_parenthesized e then true else
let rec not_complex_ op = function
| Call_op("?:", _, _) -> false
| Call_op(op', l, _) -> op <> op' && List.for_all (not_complex_ op') l
| e -> not (is_parenthesized e)
in not_complex_ "" (un_parenthesize_full e)
let not_simple = function
| Num _ | Ident _ | Deref(_, Ident _) -> false
| _ -> true
let string_of_Ident = function
| Ident(None, s, _) -> s
| Ident(Some fq, s, _) -> fq ^ "::" ^ s
| _ -> internal_error "string_of_Ident"
let context2s = function
| I_scalar -> "$"
| I_hash -> "%"
| I_array -> "@"
| I_func -> "&"
| I_raw -> ""
| I_star -> "*"
let variable2s(context, ident) = context2s context ^ ident
let rec is_same_fromparser a b =
match a, b with
| Undef, Undef -> true
| Ident(fq1, s1, _), Ident(fq2, s2, _) -> fq1 = fq2 && s1 = s2
| Num(s1, _), Num(s2, _)
| Raw_string(s1, _), Raw_string(s2, _) -> s1 = s2
| String(l1, _), String(l2, _) ->
for_all2_ (fun (s1, e1) (s2, e2) -> s1 = s2 && is_same_fromparser e1 e2) l1 l2
| Ref(c1, e1), Ref(c2, e2)
| Deref(c1, e1), Deref(c2, e2) -> c1 = c2 && is_same_fromparser e1 e2
| Deref_with(c1, c_1, e1, e_1), Deref_with(c2, c_2, e2, e_2) -> c1 = c2 && c_1 = c_2 && is_same_fromparser e1 e2 && is_same_fromparser e_1 e_2
| Diamond(None), Diamond(None) -> true
| Diamond(Some e1), Diamond(Some e2) -> is_same_fromparser e1 e2
| List(l1), List(l2) -> for_all2_ is_same_fromparser l1 l2
| Call_op(op1, l1, _), Call_op(op2, l2, _) -> op1 = op2 && for_all2_ is_same_fromparser l1 l2
| Call(e1, l1), Call(e2, l2) -> is_same_fromparser e1 e2 && for_all2_ is_same_fromparser l1 l2
| Method_call(e1, m1, l1), Method_call(e2, m2, l2) ->
is_same_fromparser e1 e2 && is_same_fromparser m1 m2 && for_all2_ is_same_fromparser l1 l2
| _ -> false
let from_scalar esp =
match esp.any with
| Deref(I_scalar, ident) -> ident
| _ -> internal_error "from_scalar"
let from_array esp =
match esp.any with
| Deref(I_array, ident) -> ident
| _ -> internal_error "from_array"
let rec get_pos_from_expr = function
| Anonymous_sub(_, _, pos)
| String(_, pos)
| Call_op(_, _, pos)
| Perl_checker_comment(_, pos)
| My_our(_, _, pos)
| Raw_string(_, pos)
| Num(_, pos)
| Ident(_, _, pos)
-> pos
| Package e
| Ref(_, e)
| Deref(_, e)
| Sub_declaration(e, _, _, _)
| Deref_with(_, _, e, _)
| Use(e, _)
| Call(e, _)
| Method_call(_, e, _)
-> get_pos_from_expr e
| Diamond(option_e)
-> if option_e = None then raw_pos2pos bpos else get_pos_from_expr (some option_e)
| List l
| Block l
-> if l = [] then raw_pos2pos bpos else get_pos_from_expr (List.hd l)
| Semi_colon
| Too_complex
| Undef
| Label _
-> raw_pos2pos bpos
let msg_with_rawpos (start, end_) msg = Info.pos2sfull_current start end_ ^ msg
let die_with_rawpos raw_pos msg = failwith (msg_with_rawpos raw_pos msg)
let warn raw_pos msg = print_endline_flush (msg_with_rawpos raw_pos msg)
let die_rule msg = die_with_rawpos (Parsing.symbol_start(), Parsing.symbol_end()) msg
let warn_rule msg = warn (Parsing.symbol_start(), Parsing.symbol_end()) msg
let debug msg = if true then print_endline_flush msg
let warn_verb pos msg = if not !Flags.quiet then warn (pos, pos) msg
let warn_too_many_space start = warn_verb start "you should have only one space here"
let warn_no_space start = warn_verb start "you should have a space here"
let warn_cr start = warn_verb start "you should not have a carriage-return (\\n) here"
let warn_space start = warn_verb start "you should not have a space here"
let rec prio_less = function
| P_none, _ | _, P_none -> internal_error "prio_less"
| P_paren_wanted prio1, prio2
| prio1, P_paren_wanted prio2 -> prio_less(prio1, prio2)
| P_ternary, P_or -> false
| P_ternary, P_and -> false
| _, P_loose -> true
| P_loose, _ -> false
| _, P_or -> true
| P_or, _ -> false
| _, P_and -> true
| P_and, _ -> false
| _, P_call_no_paren -> true
| P_call_no_paren, _ -> false
| _, P_comma -> true
| P_comma, _ -> false
| _, P_assign -> true
| P_assign, _ -> false
| _, P_ternary -> true
| P_ternary, _ -> false
| _, P_tight_or -> true
| P_tight_or, _ -> false
| _, P_tight_and -> true
| P_tight_and, _ -> false
| P_bit, P_bit -> true
| P_bit, _ -> false
| _, P_expr -> true
| P_expr, _ -> false
| _, P_eq -> true
| P_eq, _ -> false
| _, P_cmp -> true
| P_cmp, _ -> false
| _, P_add -> true
| P_add, _ -> false
| _, P_mul -> true
| P_mul, _ -> false
| _, P_tight -> true
| P_tight, _ -> false
| _, P_paren _ -> true
| P_paren _, _ -> true
| P_tok, _ -> true
let prio_lo_check pri_out pri_in pos expr =
if prio_less(pri_in, pri_out) then
(match pri_in with
| P_paren (P_paren_wanted _) -> ()
| P_paren pri_in' ->
if pri_in' <> pri_out &&
prio_less(pri_in', pri_out) && not_complex (un_parenthesize expr) then
warn pos "unneeded parentheses"
| _ -> ())
else
(match expr with
| Call_op ("print", [Deref (I_star, Ident (None, "STDOUT", _)); Deref(I_scalar, ident)], _) ->
warn pos (sprintf "use parentheses: replace \"print $%s ...\" with \"print($%s ...)\"" (string_of_Ident ident) (string_of_Ident ident))
| _ -> warn pos "missing parentheses (needed for clarity)")
let prio_lo pri_out in_ = prio_lo_check pri_out in_.any.priority in_.pos in_.any.expr ; in_.any.expr
let prio_lo_after pri_out in_ =
if in_.any.priority = P_call_no_paren then in_.any.expr else prio_lo pri_out in_
let prio_lo_concat esp = prio_lo P_mul { esp with any = { esp.any with priority = P_paren_wanted esp.any.priority } }
let hash_ref esp = Ref(I_hash, prio_lo P_loose esp)
let sp_0 esp =
match esp.spaces with
| Space_none -> ()
| Space_0 -> ()
| Space_1
| Space_n -> warn_space (get_pos_start esp)
| Space_cr -> warn_cr (get_pos_start esp)
let sp_0_or_cr esp =
match esp.spaces with
| Space_none -> ()
| Space_0 -> ()
| Space_1
| Space_n -> warn_space (get_pos_start esp)
| Space_cr -> ()
let sp_1 esp =
match esp.spaces with
| Space_none -> ()
| Space_0 -> warn_no_space (get_pos_start esp)
| Space_1 -> ()
| Space_n -> warn_too_many_space (get_pos_start esp)
| Space_cr -> warn_cr (get_pos_start esp)
let sp_n esp =
match esp.spaces with
| Space_none -> ()
| Space_0 -> warn_no_space (get_pos_start esp)
| Space_1 -> ()
| Space_n -> ()
| Space_cr -> warn_cr (get_pos_start esp)
let sp_p esp =
match esp.spaces with
| Space_none -> ()
| Space_0 -> warn_no_space (get_pos_start esp)
| Space_1 -> ()
| Space_n -> ()
| Space_cr -> ()
let sp_cr esp =
match esp.spaces with
| Space_none -> ()
| Space_0
| Space_1
| Space_n -> warn_verb (get_pos_start esp) "you should have a carriage-return (\\n) here"
| Space_cr -> ()
let sp_same esp1 esp2 =
if esp1.spaces <> Space_0 then sp_p esp2
else if esp2.spaces <> Space_0 then sp_p esp1
let function_to_context word_alone = function
| "map" | "grep" | "grep_index" | "map_index" -> M_array
| "partition" -> M_tuple [ M_ref M_array ; M_ref M_array ]
| "find" -> M_unknown_scalar
| "any" | "every" -> M_bool
| "find_index" -> M_int
| "each_index" -> M_none
| "N" | "N_" -> M_string
| "chop" | "chomp" -> M_none
| "hex" | "length" | "time" | "fork" | "getppid" -> M_int
| "eof" | "wantarray" -> M_int
| "stat" | "lstat" -> M_list
| "arch" | "quotemeta" | "join" | "lc" | "lcfirst" | "uc" | "ucfirst" -> M_string
| "split" -> M_array
| "shift" | "pop" -> M_unknown_scalar
| "die" | "return" | "redo" | "next" | "last" -> M_unknown
| "caller" -> M_mixed [M_string ; M_list]
| "ref" -> M_ref M_unknown_scalar
| "undef" -> if word_alone then M_undef else M_none
| _ -> M_unknown
let word_alone esp =
let word = esp.any in
let mcontext, e = match word with
| Ident(None, f, pos) ->
let e = match f with
| "length" | "stat" | "lstat" | "chop" | "chomp" | "quotemeta" | "lc" | "lcfirst" | "uc" | "ucfirst" ->
Call(Deref(I_func, word), [var_dollar_ pos])
| "split" -> Call(Deref(I_func, word), [ Raw_string(" ", pos) ; var_dollar_ pos ])
| "die" -> Call(Deref(I_func, word), [ Deref(I_scalar, Ident(None, "@", raw_pos2pos bpos)) ])
| "return" | "eof" | "caller"
| "redo" | "next" | "last" ->
Deref(I_func, word)
| "hex" | "ref" ->
warn_rule (sprintf "please use \"%s $_\" instead of \"%s\"" f f) ;
Call(Deref(I_func, word), [ Raw_string(" ", pos) ; var_dollar_ pos ])
| "time" | "wantarray" | "fork" | "getppid" | "arch" ->
warn_rule (sprintf "please use %s() instead of %s" f f) ;
Deref(I_func, word)
| _ -> word
in
function_to_context true f, e
| _ -> M_unknown, word
in
new_pesp mcontext P_tok e esp esp
let check_parenthesized_first_argexpr word esp =
let want_space = word.[0] = '-' in
if word = "return" then () else
match esp.any.expr with
| [ Call_op(_, (e' :: l), _) ]
| e' :: l ->
if is_parenthesized e' then
if l = [] then
(if want_space then sp_n else sp_0) esp
else
(* eg: join (" ", @l) . "\n" *)
die_with_rawpos (get_pos_start esp, get_pos_start esp) "please remove the space before the function call"
else
sp_p esp
| _ ->
if word = "time" then die_rule "please use time() instead of time";
sp_p esp
let check_parenthesized_first_argexpr_with_Ident ident esp =
if esp.any.priority = P_tok then ();
(match ident with
| Ident(Some _, _, _) ->
(match esp.any.expr with
| [e] when is_parenthesized e -> ()
| _ -> warn_rule "use parentheses around argument (otherwise it might cause syntax errors if the package is \"require\"d and not \"use\"d")
| Ident(None, word, _) when List.mem word ["ref" ; "readlink"] ->
if esp.any.priority <> P_tok then warn_rule "use parentheses around argument"
| _ -> ());
check_parenthesized_first_argexpr (string_of_Ident ident) esp
let check_hash_subscript esp =
let can_be_raw_string = function
| "" | "x" | "y" -> false (* special case for {'y'} otherwise the emacs mode goes wild, special case for {'x'} to have the same as {'y'} (since they usually go together) *)
| s ->
char_is_alpha s.[0] && (String.length s = 1 || string_forall_with char_is_alphanumerical_ 1 s)
in
match esp.any.expr with
| List [String ([(s, List [])], _)] when can_be_raw_string s -> warn esp.pos (sprintf "{\"%s\"} can be written {%s}" s s)
| List [Raw_string(s, _)] when can_be_raw_string s -> warn esp.pos (sprintf "{'%s'} can be written {%s}" s s)
| _ -> ()
let check_arrow_needed esp1 esp2 =
match esp1.any.expr with
| Deref_with(I_array, I_scalar, List [List [Call _]], _) -> () (* "->" needed for (f())[0]->{XX} *)
| Deref_with _ -> warn esp2.pos "the arrow \"->\" is unneeded"
| _ -> ()
let check_scalar_subscripted esp =
match esp.any with
| Deref(I_scalar, Deref _) -> warn_rule "for complex dereferencing, use \"->\""
| _ -> ()
let check_negatable_expr esp =
match un_parenthesize_full esp.any.expr with
| Call_op("m//", var :: _, _) when not (is_var_dollar_ var) ->
warn_rule "!($var =~ /.../) is better written $var !~ /.../"
| Call_op("!m//", var :: _, _) when not (is_var_dollar_ var) ->
warn_rule "!($var !~ /.../) is better written $var =~ /.../"
| _ -> ()
let check_ternary_paras(cond, a, b) =
let rec dont_need_short_circuit_rec = function
| Num _
| Raw_string _
| String ([(_, List [])], _)
-> true
| Call(Deref(I_func, Ident(None, "N", _)), [ List(String _ :: l) ])
| Call_op(".", l, _)
| Ref(I_hash, List l)
| List l -> List.for_all dont_need_short_circuit_rec l
| _ -> false
in
let rec dont_need_short_circuit = function
| Ref(_, Deref(_, Ident _))
| Deref(_, Ident _) -> true
| Ref(I_hash, List l)
| List l -> List.for_all dont_need_short_circuit l
| e -> dont_need_short_circuit_rec e
in
let check_ternary_para = function
| List [] -> warn_rule "you may use if_() here\n beware that the short-circuit semantic of ?: is not kept\n if you want to keep the short-circuit behaviour, replace () with @{[]} and there will be no warning anymore"
| _ -> ()
in
if dont_need_short_circuit a || is_same_fromparser cond a then check_ternary_para b;
if dont_need_short_circuit b || is_same_fromparser cond b then check_ternary_para a;
if is_same_fromparser cond a && is_a_scalar a && is_a_scalar b then warn_rule "you can replace \"$foo ? $foo : $bar\" with \"$foo || $bar\"";
[ cond; a; b ]
let check_unneeded_var_dollar_ esp =
if is_var_dollar_ esp.any.expr then warn esp.pos "\"$_ =~ /regexp/\" can be written \"/regexp/\"" else
if is_var_number_match esp.any.expr then warn esp.pos "do not use the result of a match (eg: $1) to match another pattern"
let check_unneeded_var_dollar_not esp =
if is_var_dollar_ esp.any.expr then warn esp.pos "\"$_ !~ /regexp/\" can be written \"!/regexp/\"" else
if is_var_number_match esp.any.expr then warn esp.pos "do not use the result of a match (eg: $1) to match another pattern"
let check_unneeded_var_dollar_s esp =
let expr = esp.any.expr in
if is_var_dollar_ expr then warn esp.pos "\"$_ =~ s/regexp/.../\" can be written \"s/regexp/.../\"" else
if is_var_number_match expr then die_with_rawpos esp.pos "do not modify the result of a match (eg: $1)" else
let expr = match expr with
| List [List [Call_op("=", [ expr; _], _)]] -> expr (* check $xx in ($xx = ...) =~ ... *)
| _ -> expr in
if is_a_string expr || not (is_a_scalar expr) then warn esp.pos "you can only use s/// on a variable"
let check_my esp = if esp.any <> "my" then die_rule "syntax error"
let check_foreach esp = if esp.any = "for" then warn esp.pos "write \"foreach\" instead of \"for\""
let check_for esp = if esp.any = "foreach" then warn esp.pos "write \"for\" instead of \"foreach\""
let check_for_foreach esp arg =
match arg.any.expr with
| List [ Deref(I_scalar, _) ] ->
if esp.any = "foreach" then warn esp.pos "you are using the special fpons trick to locally set $_ with a value, for this please use \"for\" instead of \"foreach\""
| List [ Deref_with(context, I_scalar, _, _) ] when context <> I_func ->
if esp.any = "foreach" then warn esp.pos "you are using the special fpons trick to locally set $_ with a value, for this please use \"for\" instead of \"foreach\""
| List [ Deref(I_hash, _) ] ->
warn esp.pos "foreach with a hash is usually an error"
| _ ->
if esp.any = "for" then warn esp.pos "write \"foreach\" instead of \"for\""
let check_block_sub esp_lines esp_BRACKET_END =
match esp_lines.any with
| [] ->
sp_0_or_cr esp_BRACKET_END
| l ->
(if List.hd l = Semi_colon then sp_0 else sp_p) esp_lines ;
sp_p esp_BRACKET_END ;
if esp_BRACKET_END.spaces <> Space_cr then
(if last l = Semi_colon then warn_verb (get_pos_end esp_lines) "spurious \";\" before closing block")
let check_block_ref esp_lines esp_BRACKET_END =
let l = esp_lines.any in
if l <> [] && List.hd l = Semi_colon
then (sp_0 esp_lines ; sp_p esp_BRACKET_END)
else sp_same esp_lines esp_BRACKET_END ;
if esp_BRACKET_END.spaces <> Space_cr then
(if l <> [] && last l = Semi_colon then warn_verb (get_pos_end esp_lines) "spurious \";\" before closing block")
let check_unless_else elsif else_ =
if elsif.any <> [] then warn elsif.pos "don't use \"elsif\" with \"unless\" (replace \"unless\" with \"if\")";
if else_.any <> [] then warn else_.pos "don't use \"else\" with \"unless\" (replace \"unless\" with \"if\")"
let check_my_our_paren { any = ((comma_closed, _), l) } after_esp =
(if l = [] then sp_0 else sp_1) after_esp ;
if not comma_closed then die_rule "syntax error"
let check_simple_pattern = function
| [ String([ st, List [] ], _); Raw_string("", _) ] ->
if String.length st > 2 &&
st.[0] = '^' && st.[String.length st - 1] = '$' then
let st = skip_n_char_ 1 1 st in
if string_forall_with char_is_alphanumerical_ 0 st then
warn_rule (sprintf "\"... =~ /^%s$/\" is better written \"... eq '%s'\"" st st)
| _ -> ()
let rec only_one esp =
match esp.any with
| [List l'] -> only_one { esp with any = l' }
| [e] -> e
| [] -> die_with_rawpos esp.pos "you must give one argument"
| _ -> die_with_rawpos esp.pos "you must give only one argument"
let only_one_array_ref esp =
let e = only_one esp in
(match e with
| Call_op("last_array_index", [Deref(I_array, e)], _) ->
warn esp.pos (sprintf "you can replace $#%s with -1" (string_of_Ident e))
| _ -> ());
e
let only_one_in_List esp =
match esp.any.expr with
| List l -> only_one { esp with any = l }
| e -> e
let rec is_only_one_in_List = function
| [List l] -> is_only_one_in_List l
| [_] -> true
| _ -> false
let maybe_to_Raw_string = function
| Ident(None, s, pos) -> Raw_string(s, pos)
| Ident(Some fq, s, pos) -> Raw_string(fq ^ "::" ^ s, pos)
| e -> e
let to_List = function
| [e] -> e
| l -> List l
let deref_arraylen e = Call_op("last_array_index", [Deref(I_array, e)], raw_pos2pos bpos)
let deref_raw context e =
let e = match e with
| Raw_string(s, pos) ->
let fq, ident = split_name_or_fq_name s in
Ident(fq, ident, pos)
| Deref(I_scalar, (Ident _ as ident)) ->
warn_rule (sprintf "%s{$%s} can be written %s$%s" (context2s context) (string_of_Ident ident) (context2s context) (string_of_Ident ident));
e
| _ -> e
in Deref(context, e)
let to_Ident { any = (fq, name); pos = pos } = Ident(fq, name, raw_pos2pos pos)
let to_Raw_string { any = s; pos = pos } = Raw_string(s, raw_pos2pos pos)
let to_Method_call (object_, method_, para) =
match method_ with
| Ident(Some "SUPER", name, pos) -> Method_call(maybe_to_Raw_string object_, Raw_string(name, pos), para)
| Ident(Some _, _, _) -> Call(Deref(I_func, method_), maybe_to_Raw_string object_ :: para)
| _ -> Method_call(maybe_to_Raw_string object_, maybe_to_Raw_string method_, para)
let to_Deref_with(from_context, to_context, ref_, para) =
if is_not_a_scalar ref_ then warn_rule "bad deref";
Deref_with(from_context, to_context, ref_, para)
let to_Local esp =
let l =
match esp.any.expr with
| List[List l] -> l
| e -> [e]
in
let local_vars, local_exprs = fpartition (function
| Deref(I_star as context, Ident(None, ident, _))
| Deref(I_scalar as context, Ident(None, ("_" as ident), _)) ->
Some(context, ident)
| Deref(I_scalar, Ident _)
| Deref(I_array, Ident _)
| Deref(I_star, Ident _)
| Deref_with(I_hash, I_scalar, Ident _, _)
| Deref_with(I_hash, I_scalar, Deref(I_scalar, _), _)
| Deref_with(I_hash, I_scalar, Deref_with(I_hash, I_scalar, Ident _, _), _)
| Deref_with(I_hash, I_scalar, Deref_with(I_hash, I_scalar, Deref(I_scalar, Ident _), _), _) ->
None
| _ -> die_with_rawpos esp.pos "bad argument to \"local\""
) l in
if local_vars = [] then Call_op("local", local_exprs, raw_pos2pos esp.pos)
else if local_exprs = [] then My_our("local", local_vars, raw_pos2pos esp.pos)
else die_with_rawpos esp.pos "bad argument to \"local\""
let sub_declaration (name, proto) body sub_kind = Sub_declaration(name, proto, Block body, sub_kind)
let anonymous_sub proto body = Anonymous_sub (proto, Block body.any, raw_pos2pos body.pos)
let call_with_same_para_special f = Call(f, [Deref(I_star, (Ident(None, "_", raw_pos2pos bpos)))])
let remove_call_with_same_para_special = function
| Call(f, [Deref(I_star, (Ident(None, "_", _)))]) -> f
| e -> e
let cook_call_op op para pos =
(match op with
| "le" | "ge" | "eq" | "ne" | "gt" | "lt" | "cmp" ->
if List.exists (function Num _ -> true | _ -> false) para then
warn_rule (sprintf "you should use a number operator, not the string operator \"%s\" (or replace the number with a string)" op)
| "." ->
if List.exists (function Call(Deref(I_func, Ident(None, "N_", _)), _) -> true | _ -> false) para then
warn_rule "N_(\"xxx\") . \"yyy\" is dumb since the string \"xxx\" will never get translated"
| "||=" | "&&=" ->
(match List.hd para with
| List [ List _ ] -> warn_rule "remove the parentheses"
| e -> if is_not_a_scalar e then warn_rule (sprintf "\"%s\" is only useful with a scalar" op))
| "foreach" ->
(match para with
| [ _; Block [ Call_op("if infix", [ List [ Call(Deref(I_func, Ident(None, "push", _)), [ Deref(I_array, (Ident _ as l)) ; Deref(I_scalar, Ident(None, "_", _)) ]) ] ; _ ], _) ; Semi_colon ] ] ->
let l = string_of_Ident l in
warn_rule (sprintf "use \"push @%s, grep { ... } ...\" instead of \"foreach (...) { push @%s, $_ if ... }\"\n or sometimes \"@%s = grep { ... } ...\"" l l l)
| [ _; Block [ Call_op("if infix", [ List [ Call(Deref(I_func, Ident(None, "push", _)), [ Deref(I_array, (Ident _ as l)); _ ]) ] ; _ ], _) ; Semi_colon ] ] ->
let l = string_of_Ident l in
warn_rule (sprintf "use \"push @%s, map { ... ? ... : () } ...\" instead of \"foreach (...) { push @%s, ... if ... }\"\n or sometimes \"@%s = map { ... ? ... : () } ...\"\n or sometimes \"@%s = map { if_(..., ...) } ...\"" l l l l)
| [ _; Block [ List [ Call(Deref(I_func, Ident(None, "push", _)), [ Deref(I_array, (Ident _ as l)); _ ]) ] ; Semi_colon ] ] ->
let l = string_of_Ident l in
warn_rule (sprintf "use \"push @%s, map { ... } ...\" instead of \"foreach (...) { push @%s, ... }\"\n or sometimes \"@%s = map { ... } ...\"" l l l)
| _ -> ())
| "if" ->
(match para with
| List [Call_op ("=", [ _; e ], _)] :: _ when is_always_true e || is_always_false e ->
warn_rule "are you sure you did not mean \"==\" instead of \"=\"?"
| _ -> ())
| _ -> ());
let call = Call_op(op, para, raw_pos2pos pos) in
match op, para with
| "=", [My_our _; Ident(None, "undef", _)] ->
warn pos "no need to initialize variable, it's done by default" ;
call
| "=", [My_our _; List[]] ->
if Info.is_on_same_line_current pos then warn pos "no need to initialize variables, it's done by default" ;
call
| "=", [ Deref(I_star, String ([(sf1, List [])], _)); _ ] ->
warn_rule (sprintf "write *{'%s'} instead of *{\"%s\"}" sf1 sf1) ;
call
| "=", [ Deref(I_star, (Ident _ as f1)); Deref(I_star, (Ident _ as f2)) ] ->
let s1, s2 = string_of_Ident f1, string_of_Ident f2 in
warn pos (sprintf "\"*%s = *%s\" is better written \"*%s = \\&%s\"" s1 s2 s1 s2) ;
sub_declaration (f1, None) [ call_with_same_para_special(Deref(I_func, f2)) ] Glob_assign
| "=", [ Deref(I_star, Raw_string(sf1, pos_f1)); Deref(I_star, (Ident _ as f2)) ] ->
let s2 = string_of_Ident f2 in
warn pos (sprintf "\"*{'%s'} = *%s\" is better written \"*{'%s'} = \\&%s\"" sf1 s2 sf1 s2) ;
sub_declaration (Ident(None, sf1, pos_f1), None) [ call_with_same_para_special(Deref(I_func, f2)) ] Glob_assign
| "=", [ Deref(I_star, (Ident _ as f1)); Ref(I_scalar, Deref(I_func, (Ident _ as f2))) ] ->
sub_declaration (f1, None) [ call_with_same_para_special(Deref(I_func, f2)) ] Glob_assign
| "=", [ Deref(I_star, Raw_string(sf1, pos_f1)); Ref(I_scalar, Deref(I_func, (Ident _ as f2))) ] ->
sub_declaration (Ident(None, sf1, pos_f1), None) [ call_with_same_para_special(Deref(I_func, f2)) ] Glob_assign
| "=", [ Deref(I_star, (Ident _ as f1)); (Anonymous_sub(proto, sub, _)) ] ->
sub_declaration (f1, proto) [ sub ] Glob_assign
| "==", [Call_op("last_array_index", _, _); Num("0", _)] ->
warn_rule "$#x == 0 is better written @x == 1";
call
| "||", e :: _ when is_always_true e -> warn_rule "<constant> || ... is the same as <constant>"; call
| "&&", e :: _ when is_always_false e -> warn_rule "<constant> && ... is the same as <constant>"; call
| "||", e :: _ when is_always_false e -> warn_rule "<constant> || ... is the same as ..."; call
| "&&", e :: _ when is_always_true e -> warn_rule "<constant> && ... is the same as ..."; call
| "or", e :: _ when is_always_true (un_parenthesize_full e) -> warn_rule "<constant> or ... is the same as <constant>"; call
| "and", e :: _ when is_always_false (un_parenthesize_full e) -> warn_rule "<constant> and ... is the same as <constant>"; call
| "or", e :: _ when is_always_false (un_parenthesize_full e) -> warn_rule "<constant> or ... is the same as ..."; call
| "and", e :: _ when is_always_true (un_parenthesize_full e) -> warn_rule "<constant> and ... is the same as ..."; call
| _ ->
call
let to_Call_op mcontext op para esp_start esp_end =
let pos = raw_pos_range esp_start esp_end in
new_any mcontext (cook_call_op op para pos) esp_start.spaces pos
let to_Call_op_ mcontext prio op para esp_start esp_end =
let pos = raw_pos_range esp_start esp_end in
new_any mcontext { priority = prio ; expr = cook_call_op op para pos } esp_start.spaces pos
let followed_by_comma expr true_comma =
if true_comma then expr else
match split_last expr with
| l, Ident(None, s, pos) -> l @ [Raw_string(s, pos)]
| _ -> expr
let pot_strings = Hashtbl.create 16
let po_comments = ref []
let po_comment esp = lpush po_comments esp.any
let check_format_a_la_printf s pos =
let rec check_format_a_la_printf_ contexts i =
try
let i' = String.index_from s i '%' in
try
let contexts =
match s.[i' + 1] with
| '%' -> contexts
| 'd' -> M_int :: contexts
| 's' | 'c' -> M_string :: contexts
| c -> warn (pos + i', pos + i') (sprintf "invalid command %%%c" c); contexts
in
check_format_a_la_printf_ contexts (i' + 2)
with Invalid_argument _ -> warn (pos + i', pos + i') "invalid command %" ; contexts
with Not_found -> contexts
in check_format_a_la_printf_ [] 0
let generate_pot file =
let fd = open_out file in
output_string fd
("# SOME DESCRIPTIVE TITLE.
# Copyright (C) YEAR Free Software Foundation, Inc.
# FIRST AUTHOR <EMAIL@ADDRESS>, YEAR.
#
#, fuzzy
msgid \"\"
msgstr \"\"
\"Project-Id-Version: PACKAGE VERSION\\n\"
\"POT-Creation-Date: " ^ input_line (Unix.open_process_in "date '+%Y-%m-%d %H:%M%z'") ^ "\\n\"
\"PO-Revision-Date: YEAR-MO-DA HO:MI+ZONE\\n\"
\"Last-Translator: FULL NAME <EMAIL@ADDRESS>\\n\"
\"Language-Team: LANGUAGE <LL@li.org>\\n\"
\"MIME-Version: 1.0\\n\"
\"Content-Type: text/plain; charset=CHARSET\\n\"
\"Content-Transfer-Encoding: 8-bit\\n\"
") ;
let rec print_formatted_char = function
| '"' -> output_char fd '\\'; output_char fd '"'
| '\t' -> output_char fd '\\'; output_char fd 't'
| '\\' -> output_char fd '\\'; output_char fd '\\'
| '\n' -> output_string fd "\\n\"\n\""
| c -> output_char fd c
in
let sorted_pot_strings = List.sort (fun (_, pos_a) (_, pos_b) -> compare pos_a pos_b)
(Hashtbl.fold (fun k (v, _) l -> (k,v) :: l) pot_strings [] ) in
List.iter (fun (s, _) ->
match Hashtbl.find_all pot_strings s with
| [] -> ()
| l ->
List.iter (fun _ -> Hashtbl.remove pot_strings s) l ;
List.iter (fun po_comment -> output_string fd ("#. " ^ po_comment ^ "\n")) (collect snd l);
let pos_l = List.sort compare (List.map fst l) in
fprintf fd "#: %s\n" (String.concat " " (List.map Info.pos2s_for_po pos_l)) ;
output_string fd "#, c-format\n" ;
output_string fd (if String.contains s '\n' then "msgid \"\"\n\"" else "msgid \"") ;
String.iter print_formatted_char s ;
output_string fd "\"\n" ;
output_string fd "msgstr \"\"\n\n"
) sorted_pot_strings ;
close_out fd
let call_raw force_non_builtin_func (e, para) =
match e with
| Deref(I_func, Ident(None, f, _)) ->
(match f with
| "join" ->
(match un_parenthesize_full_l para with
| e :: _ when not (is_a_scalar e) -> warn_rule "first argument of join() must be a scalar";
| [_] -> warn_rule "not enough parameters"
| [_; e] when is_a_scalar e -> warn_rule "join('...', $foo) is the same as $foo"
| _ -> ())
| "length" ->
if para = [] then warn_rule "length() with no parameter !?" else
if is_not_a_scalar (List.hd para) then warn_rule "never use \"length @l\", it returns the length of the string int(@l)" ;
| "open" ->
(match para with
| [ List(Ident(None, name, _) :: _) ]
| Ident(None, name, _) :: _ ->
if not (List.mem name [ "STDIN" ; "STDOUT" ; "STDERR" ]) then
warn_rule (sprintf "use a scalar instead of a bareword (eg: occurrences of %s with $%s)" name name)
| _ -> ())
| "N" | "N_" ->
(match para with
| [ List(String([ s, List [] ], (_, pos_offset, _ as pos)) :: para) ] ->
if !Flags.generate_pot then (
Hashtbl.add pot_strings s (pos, !po_comments) ;
po_comments := []
) ;
let contexts = check_format_a_la_printf s pos_offset in
if f = "N" then
if List.length para < List.length contexts then
warn_rule "not enough parameters"
else if List.length para > List.length contexts then
warn_rule "too many parameters" ;
(*if String.contains s '\t' then warn_rule "tabulation in translated string must be written \\\\t";*)
(*if count_matching_char s '\n' > 10 then warn_rule "long string";*)
| [ List(String _ :: _) ] -> die_rule "don't use interpolated translated string, use %s or %d instead"
| _ -> die_rule (sprintf "%s() must be used with a string" f))
| "map" | "grep" | "grep_index" | "map_index" | "partition"
| "find"
| "any" | "every"
| "find_index"
| "each_index" ->
(match para with
| Anonymous_sub(None, Block [ List [ Call(Deref(I_func, Ident(None, "if_", _)),
[ List [ _ ; Deref(I_scalar, Ident(None, "_", _)) ] ]) ] ], _) :: _ when f = "map" ->
warn_rule "you can replace \"map { if_(..., $_) }\" with \"grep { ... }\""
| [ Anonymous_sub _ ; Deref (I_hash, _) ] ->
warn_rule ("a hash is not a valid parameter to function " ^ f)
| Anonymous_sub _ :: _ -> ()
| _ -> warn_rule (sprintf "always use \"%s\" with a block (eg: %s { ... } @list)" f f))
| "member" ->
(match para with
[ List [ _; Call(Deref(I_func, Ident(None, "keys", _)), _) ] ] ->
warn_rule "you can replace \"member($xxx, keys %yyy)\" with \"exists $yyy{$xxx}\""
| _ -> ())
| "pop" | "shift" ->
(match para with
| []
| [ Deref(I_array, _) ]
| [ List [ Deref(I_array, _) ] ] -> ()
| _ -> warn_rule (f ^ " is expecting an array and nothing else"))
| "system" ->
(match un_parenthesize_full_l para with
| [ String(l, _) ] ->
if List.exists (fun (s, _) -> String.contains s '\'' || String.contains s '"') l &&
not (List.exists (fun (s, _) -> List.exists (String.contains s) [ '<' ; '>' ; '&' ; ';']) l) then
warn_rule "instead of quoting parameters you should give a list of arguments"
| _ -> ())
| _ -> ()
);
let para' = match f with
| "no" ->
(match para with
| [ Ident(_, _, pos) as s ] -> Some [ Raw_string(string_of_Ident s, pos) ]
| [ Call(Deref(I_func, (Ident(_, _, pos) as s)), l) ] -> Some(Raw_string(string_of_Ident s, pos) :: l)
| _ -> die_rule "use \"no PACKAGE <para>\"")
| "undef" ->
(match para with
| [ Deref(I_star, ident) ] -> Some [ Deref(I_func, ident) ]
| _ -> None)
| "goto" ->
(match para with
| [ Ident(None, s, pos) ] -> Some [ Raw_string(s, pos) ]
| _ -> None)
| "last" | "next" | "redo" when not force_non_builtin_func ->
(match para with
| [ Ident(None, s, pos) ] -> Some [ Raw_string(s, pos) ]
| _ -> die_rule (sprintf "%s must be used with a raw string" f))
| "split" ->
(match para with
| [ List(Call_op("m//", Deref(I_scalar, Ident(None, "_", _)) :: pattern, pos) :: l) ]
| Call_op("m//", Deref(I_scalar, Ident(None, "_", _)) :: pattern, pos) :: l ->
Some(Call_op("qr//", pattern, pos) :: l)
| _ -> None)
| _ -> None
in Call(e, some_or para' para)
| _ -> Call(e, para)
let call(e, para) = call_raw false (e, para)
let check_return esp_func esp_para =
match esp_func.any with
| Ident(None, "return", _) ->
prio_lo_check P_call_no_paren esp_para.any.priority esp_para.pos (List esp_para.any.expr)
| _ -> ()
let call_and_context(e, para) force_non_builtin_func priority esp_start esp_end =
let context =
match e with
| Deref(I_func, Ident(None, f, _)) -> function_to_context false f
| _ -> M_unknown
in
new_pesp context priority (call_raw force_non_builtin_func (e, para)) esp_start esp_end
let call_no_paren esp_func esp_para = check_return esp_func esp_para; call_and_context(Deref(I_func, esp_func.any), esp_para.any.expr) false P_call_no_paren esp_func esp_para
let call_with_paren esp_func esp_para = check_return esp_func esp_para; call_and_context (Deref(I_func, esp_func.any), esp_para.any.expr) false P_tok esp_func esp_para
let call_func esp_func esp_para =
call_and_context(esp_func.any, esp_para.any.expr) true P_tok esp_func esp_para
let call_one_scalar_para { any = e ; pos = pos } para esp_start esp_end =
let para =
match para with
| [] ->
if e = "shift" || e = "pop" then
[] (* can't decide here *)
else
(if not (List.mem e [ "length" ]) then warn_rule (sprintf "please use \"%s $_\" instead of \"%s\"" e e) ;
[var_dollar_ (raw_pos2pos pos)])
| _ -> para
in
new_pesp M_unknown P_mul (call(Deref(I_func, Ident(None, e, raw_pos2pos pos)), para)) esp_start esp_end
let call_op_if_infix left right esp_start esp_end =
(match left, right with
| List [Call_op("=", [Deref(context, _); _], _)], _ when non_scalar_context context -> ()
| List [Call_op("=", [v; _], _)],
List [Call_op("not", [v'], _)] when is_same_fromparser v v' ->
warn_rule "\"$foo = ... if !$foo\" can be written \"$foo ||= ...\""
| _ -> ());
let pos = raw_pos_range esp_start esp_end in
new_any M_none (Call_op("if infix", [ left ; right], raw_pos2pos pos)) esp_start.spaces pos
let call_op_unless_infix left right esp_start esp_end =
(match left, right with
| List [Call_op("=", [Deref(context, _); _], _)], _ when non_scalar_context context -> ()
| List [Call_op("=", [v; _], _)], List [v'] when is_same_fromparser v v' ->
warn_rule "\"$foo = ... unless $foo\" can be written \"$foo ||= ...\""
| _ -> ());
(match right with
| List [Call_op(op, _, _)] ->
(match op with
| "&&" | "||" | "not" | "ne" | "?:" -> warn_rule "don't use \"unless\" when the condition is complex, use \"if\" instead"
| _ -> ());
| _ -> ());
let pos = raw_pos_range esp_start esp_end in
new_any M_none (Call_op("unless infix", [ left ; right], raw_pos2pos pos)) esp_start.spaces pos
let (current_lexbuf : Lexing.lexbuf option ref) = ref None
let rec list2tokens l =
let rl = ref l in
fun lexbuf ->
match !rl with
| [] -> internal_error "list2tokens"
| ((start, end_), e) :: l ->
(* HACK: fake a normal lexbuf *)
lexbuf.Lexing.lex_start_p <- { Lexing.dummy_pos with Lexing.pos_cnum = start } ;
lexbuf.Lexing.lex_curr_p <- { Lexing.dummy_pos with Lexing.pos_cnum = end_ } ;
rl := l ; e
let parse_tokens parse tokens lexbuf_opt =
if lexbuf_opt <> None then current_lexbuf := lexbuf_opt ;
if tokens = [] then [] else
parse (list2tokens tokens) (some !current_lexbuf)
let parse_interpolated parse l =
let l' = List.map (fun (s, tokens) -> s, to_List(parse_tokens parse tokens None)) l in
match split_last l' with
| pl, ("", List []) -> pl
| _ -> l'
let to_String parse strict { any = l ; pos = pos } =
let l' = parse_interpolated parse l in
(match l' with
| [ "", List [Deref(I_scalar, Ident(None, ident, _))]] ->
if ident <> "!" && strict then warn pos (sprintf "%s is better written without the double quotes" (variable2s(I_scalar, ident)))
| [ "", List [Deref(I_hash, _)]] ->
warn pos "don't use a hash in string context"
| [ "", List [Deref(I_array, _)]] ->
()
| [("", _)] ->
if strict then warn pos "double quotes are unneeded"
| _ -> ());
String(l', raw_pos2pos pos)
let from_PATTERN parse { any = (s, opts) ; pos = pos } =
let re = parse_interpolated parse s in
(match List.rev re with
| (s, List []) :: _ ->
if str_ends_with s ".*" then
warn_rule (sprintf "you can remove \"%s\" at the end of your regexp" ".*")
else if str_ends_with s ".*$" then
warn_rule (sprintf "you can remove \"%s\" at the end of your regexp" ".*$")
| _ -> ());
let pattern = [ String(re, raw_pos2pos pos) ; Raw_string(opts, raw_pos2pos pos) ] in
check_simple_pattern pattern;
pattern
let from_PATTERN_SUBST parse { any = (s1, s2, opts) ; pos = pos } =
[ String(parse_interpolated parse s1, raw_pos2pos pos) ;
String(parse_interpolated parse s2, raw_pos2pos pos) ;
Raw_string(opts, raw_pos2pos pos) ]
let rec mcontext2s = function
| M_none -> "()"
| M_bool -> "bool"
| M_int -> "int"
| M_float -> "float"
| M_string -> "string"
| M_ref c -> "ref(" ^ mcontext2s c ^ ")"
| M_revision -> "revision"
| M_undef -> "undef"
| M_sub -> "sub"
| M_unknown_scalar -> "scalar"
| M_tuple l -> "tuple(" ^ String.concat ", " (List.map mcontext2s l) ^ ")"
| M_list -> "list"
| M_array -> "array"
| M_hash -> "hash"
| M_special -> "special"
| M_unknown -> "unknown"
| M_mixed l -> String.concat " | " (List.map mcontext2s l)
let rec mcontext_lower c1 c2 =
match c1, c2 with
| M_special, _ | _, M_special -> internal_error "M_special in mcontext_compare"
| M_unknown, _
| _, M_unknown -> true
| M_mixed l, c -> List.exists (fun a -> mcontext_lower a c) l
| c, M_mixed l -> List.exists (mcontext_lower c) l
| M_none, M_none | M_sub, M_sub | M_hash, M_hash | M_hash, M_bool -> true
| M_none, _ | M_sub, _ | M_hash, _ -> false
| _, M_list -> true
| M_list, M_bool
| M_list, M_tuple _
(* M_unknown_scalar is M_mixed [ M_int ; M_float ; M_string ; M_bool ; M_ref _ ; M_revision ; M_undef ] *)
| M_unknown_scalar, M_int | M_unknown_scalar, M_float | M_unknown_scalar, M_string | M_unknown_scalar, M_bool
| M_unknown_scalar, M_ref _ | M_unknown_scalar, M_revision | M_unknown_scalar, M_undef | M_unknown_scalar, M_unknown_scalar
| M_array, M_array | M_array, M_int | M_array, M_float | M_array, M_bool | M_array, M_unknown_scalar | M_array, M_tuple _
| M_int, M_int | M_int, M_float | M_int, M_string | M_int, M_bool | M_int, M_unknown_scalar
| M_float, M_float | M_float, M_string | M_float, M_bool | M_float, M_unknown_scalar
| M_string, M_string | M_string, M_bool | M_string, M_unknown_scalar
| M_bool, M_bool | M_bool, M_unknown_scalar
| M_ref _, M_unknown_scalar
| M_revision, M_revision | M_revision, M_unknown_scalar
| M_undef, M_undef | M_undef, M_unknown_scalar
-> true
| M_tuple t1, M_tuple t2 ->
List.length t1 = List.length t2 && for_all2_true mcontext_lower t1 t2
| M_tuple [c], M_int | M_tuple [c], M_float | M_tuple [c], M_string | M_tuple [c], M_bool
| M_tuple [c], M_ref _ | M_tuple [c], M_revision | M_tuple [c], M_undef | M_tuple [c], M_unknown_scalar
-> mcontext_lower c c2
(* | M_ref a, M_ref b -> mcontext_lower a b *)
| _ -> false
let mcontext_is_scalar = function
| M_unknown -> false
| c -> mcontext_lower c M_unknown_scalar
let mcontext_to_scalar = function
| M_array -> M_int
| c -> if mcontext_is_scalar c then c else M_unknown_scalar
let mcontext_merge_raw c1 c2 =
match c1, c2 with
| M_unknown, _ | _, M_unknown -> Some M_unknown
| M_unknown_scalar, c when mcontext_is_scalar c -> Some M_unknown_scalar
| c, M_unknown_scalar when mcontext_is_scalar c -> Some M_unknown_scalar
| M_mixed _, _ | _, M_mixed _ -> internal_error "mcontext_merge_raw"
| _ ->
if mcontext_lower c1 c2 then Some c2 else
if mcontext_lower c2 c1 then Some c1 else
if c1 = c2 then Some c1 else
None
let rec mcontext_lmerge_add l = function
| M_mixed l2 -> List.fold_left mcontext_lmerge_add [] (l2 @ l)
| c ->
let rec add_to = function
| [] -> [c]
| M_mixed subl :: l -> add_to (subl @ l)
| c2 :: l ->
match mcontext_merge_raw c c2 with
| Some c' -> c' :: l
| None -> c2 :: add_to l
in add_to l
let mcontext_lmerge l =
match List.fold_left mcontext_lmerge_add [] l with
| [] -> internal_error "mcontext_lmerge"
| [c] -> c
| l -> M_mixed l
let mcontext_merge c1 c2 = mcontext_lmerge [ c1 ; c2 ]
let mcontext_lmaybe esp = if esp.any = [] then [] else [esp.mcontext]
let mcontext_check_raw wanted_mcontext mcontext =
if not (mcontext_lower mcontext wanted_mcontext) then
warn_rule (sprintf "context %s is not compatible with context %s" (mcontext2s mcontext) (mcontext2s wanted_mcontext))
let mcontext_check wanted_mcontext esp =
(match wanted_mcontext with
| M_list | M_array | M_float | M_mixed [M_array; M_none] | M_tuple _ -> ()
| _ ->
match un_parenthesize_full esp.any.expr with
| Call(Deref(I_func, Ident(None, "grep", _)), _) ->
warn_rule (if wanted_mcontext = M_bool then
"in boolean context, use \"any\" instead of \"grep\"" else
"you may use \"find\" instead of \"grep\"")
| _ -> ());
mcontext_check_raw wanted_mcontext esp.mcontext
let mcontext_check_unop_l wanted_mcontext esp =
mcontext_check wanted_mcontext { esp with any = { esp.any with expr = List esp.any.expr } }
let mcontext_check_non_none esp =
if esp.mcontext = M_none then warn_rule "() context not accepted here"
let mcontext_check_none msg expr esp =
let rec mcontext_check_none_rec msg expr = function
| M_none | M_unknown -> ()
| M_mixed l when List.exists (fun c -> c = M_none) l -> ()
| M_tuple l ->
(match expr with
| [List l_expr]
| [List l_expr ; Semi_colon] ->
let rec iter = function
| e::l_expr, mcontext::l ->
mcontext_check_none_rec (if l = [] then msg else "value is dropped") [e] mcontext ;
iter (l_expr, l)
| [], [] -> ()
| _ -> internal_error "mcontext_check_none"
in iter (un_parenthesize_full_l l_expr, l)
| _ -> internal_error "mcontext_check_none")
| _ ->
match expr with
| [List [Num("1", _)]; Semi_colon] -> () (* allow "1;" for package return value. It would be much better to check we are at toplevel, but hell i don't want to wire this information up to here *)
| [List [Call_op ("<>", [Ident (None, "STDIN", _)], _)]; Semi_colon] -> () (* allow <STDIN> to ask "press return" *)
| [List [Call(Deref(I_func, Ident(None, "map", _)), _)]; Semi_colon] -> warn_rule "if you don't use the return value, use \"foreach\" instead of \"map\""
| _ -> warn esp.pos msg
in
mcontext_check_none_rec msg expr esp.mcontext
(* only returns M_float when there is at least one float *)
let mcontext_float_or_int l =
List.iter (mcontext_check_raw M_float) l;
if List.mem M_float l then M_float else M_int
let mcontext_op_assign left right =
mcontext_check_non_none right;
let left_mcontext =
match left.mcontext with
| M_mixed [ c ; M_none ] -> c
| c -> c
in
let wanted_mcontext = match left_mcontext with
| M_array -> M_list
| M_hash -> M_mixed [ M_hash ; M_list ]
| m -> m
in
mcontext_check wanted_mcontext right;
let return_mcontext =
match left_mcontext with
| M_tuple _ -> M_array
| c -> c
in
mcontext_merge return_mcontext M_none
let mtuple_context_concat c1 c2 =
match c1, c2 with
| M_array, _ | _, M_array
| M_hash, _ | _, M_hash -> M_list
| M_tuple l, _ -> M_tuple (l @ [c2])
| _ -> M_tuple [c1 ; c2]
let symops pri para_context return_context op_str left op right =
sp_same op right;
let skip_context_check =
(op_str = "==" || op_str = "!=") && (match left.any.expr, right.any.expr with
| Deref(I_array, _), List [] -> true (* allow @l == () and @l != () *)
| _ -> false)
in
if not skip_context_check then
(mcontext_check para_context left ; mcontext_check para_context right) ;
to_Call_op_ return_context pri op_str [prio_lo pri left; prio_lo_after pri right] left right