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|
open Ast
let string_of_binop = function
| BINOP_And -> "BINOP_And"
| BINOP_Or -> "BINOP_Or"
| BINOP_Add -> "BINOP_Add"
| BINOP_Sub -> "BINOP_Sub"
| BINOP_Mult -> "BINOP_Mult"
| BINOP_Div -> "BINOP_Div"
| BINOP_Rem -> "BINOP_Rem"
let string_of_relop = function
| RELOP_Eq -> "RELOP_Eq"
| RELOP_Ne -> "RELOP_Ne"
| RELOP_Lt -> "RELOP_Lt"
| RELOP_Gt -> "RELOP_Gt"
| RELOP_Le -> "RELOP_Le"
| RELOP_Ge -> "RELOP_Ge"
let string_of_unop = function
| UNOP_Not -> "UNOP_Not"
| UNOP_Neg -> "UNOP_Neg"
let indent x = " " ^ x
let indentfmt fmt =
let cont = Format.sprintf " %s" in
Format.ksprintf cont fmt
let indentxs = List.map indent
type p =
| P_String of string
| P_Sequence of p list
| P_List of p list
| P_Dict of string * (string * p) list
type r =
| R_String of string
| R_Indent of r
| R_Break
| R_Tab
| R_Group of r list
let render_r = function
| R_String s -> s
| R_Tab -> " "
| R_Break -> "\n"
| R_Group _ -> failwith "R_Group should be eliminated"
| R_Indent _ -> failwith "R_Indent should be eliminated"
let rec insert_tabs tabs = function
| R_Indent r ->
insert_tabs (R_Tab::tabs) r
| R_Break ->
R_Group [R_Break; R_Group tabs]
| R_Group rs ->
R_Group (List.map (insert_tabs tabs) rs)
| r ->
r
let rec flatten = function
| R_Indent _ -> failwith "R_Indent should be eliminated"
| R_Group xs -> List.concat @@ List.map flatten xs
| r -> [r]
let render_r r =
String.concat "" @@ List.map render_r @@ flatten @@ insert_tabs [] r
let rec render_p = function
| P_String s ->
R_String s
| P_List xs ->
let rec f acc = function
| [] ->
R_Group (List.rev acc)
| x::xs ->
let entry = R_Group [render_p x; R_String ";"; R_Break] in
f (entry::acc) xs
in
R_Group
[ R_String "["
; R_Indent (R_Group [R_Break; f [] xs])
; R_String "]"
]
| P_Dict (kind, items) ->
let rec f acc = function
| [] ->
R_Group (List.rev acc)
| (k,v)::xs ->
let entry = R_Group [R_String k; R_String " = "; R_Indent (render_p v); R_String ";"; R_Break] in
f (entry::acc) xs
in
R_Group
[ R_String kind
; R_String " "
; R_String "{"
; R_Indent (R_Group [R_Break; f [] items])
; R_String "}"
]
| P_Sequence xs ->
R_Group (List.map render_p xs)
let p_dict k items = P_Dict (k,items)
let p_identifier id = P_String (Format.sprintf "\"%s\"" @@ string_of_identifier id)
let p_string id = P_String (Format.sprintf "\"%s\"" id)
let p_location loc = P_String (string_of_location loc)
let p_node_tag tag = P_String (string_of_node_tag tag)
let p_i32 i = P_String (Int32.to_string i)
let p_char c = P_String (Format.sprintf "'%c'" c)
let p_bool b = P_String (string_of_bool b)
let p_opt f = function
| None -> P_String "None"
| Some x -> P_Sequence [P_String "Some "; f x]
let rec p_expression = function
| EXPR_Id {loc; tag; id} -> p_dict "EXPR_Id"
[ "loc", p_location loc
; "tag", p_node_tag tag
; "id", p_identifier id
]
| EXPR_Int {tag; loc; value} -> p_dict "EXPR_Int"
[ "loc", p_location loc
; "tag", p_node_tag tag
; "value", p_i32 value
]
| EXPR_Char {tag; loc; value} -> p_dict "EXPR_Char"
[ "loc", p_location loc
; "tag", p_node_tag tag
; "value", p_char value
]
| EXPR_String {tag; loc; value} -> p_dict "EXPR_String"
[ "loc", p_location loc
; "tag", p_node_tag tag
; "value", p_string value
]
| EXPR_Bool {tag; loc; value} -> p_dict "EXPR_Bool"
[ "loc", p_location loc
; "tag", p_node_tag tag
; "value", p_bool value
]
| EXPR_Relation {tag; loc; op; lhs; rhs} -> p_dict "EXPR_Relation"
[ "loc", p_location loc
; "tag", p_node_tag tag
; "op", P_String (string_of_relop op)
; "lhs", p_expression lhs
; "rhs", p_expression rhs
]
| EXPR_Binop {tag; loc; op; lhs; rhs} -> p_dict "EXPR_Binop"
[ "loc", p_location loc
; "tag", p_node_tag tag
; "op", P_String (string_of_binop op)
; "lhs", p_expression lhs
; "rhs", p_expression rhs
]
| EXPR_Unop {tag; loc; op; sub} -> p_dict "EXPR_Unop"
[ "loc", p_location loc
; "tag", p_node_tag tag
; "op", P_String (string_of_unop op)
; "sub", p_expression sub
]
| EXPR_Length {tag; loc; arg} -> p_dict "EXPR_Length"
[ "loc", p_location loc
; "tag", p_node_tag tag
; "arg", p_expression arg
]
| EXPR_Index {tag; loc; expr; index} -> p_dict "EXPR_Length"
[ "loc", p_location loc
; "tag", p_node_tag tag
; "expr", p_expression expr
; "index", p_expression index
]
| EXPR_Struct {tag; loc; elements} -> p_dict "EXPR_Struct"
[ "loc", p_location loc
; "tag", p_node_tag tag
; "elements", P_List (List.map p_expression elements)
]
| EXPR_Call call -> P_Sequence
[ P_String "EXPR_Call "
; p_call call
]
and p_call = function
| Call {tag; loc; callee; arguments} -> p_dict "Call"
[ "loc", p_location loc
; "tag", p_node_tag tag
; "callee", p_identifier callee
; "arguments", P_List (List.map p_expression arguments)
]
let rec p_type_expression = function
| TEXPR_Int {loc} -> p_dict "TEXPR_Int"
[ "loc", p_location loc
]
| TEXPR_Bool {loc} -> p_dict "TEXPR_Bool"
[ "loc", p_location loc
]
| TEXPR_Array {loc;sub;dim} -> p_dict "TPEXPR_Array"
[ "loc", p_location loc
; "sub", p_type_expression sub
; "dim", p_opt p_expression dim
]
let p_lvalue = function
| LVALUE_Id {loc; id} -> p_dict "LVALUE_Id"
[ "loc", p_location loc
; "id", p_identifier id
]
| LVALUE_Index {loc; sub; index} -> p_dict "LVALUE_Index"
[ "loc", p_location loc
; "sub", p_expression sub
; "index", p_expression index
]
let p_var_declaration = function
| VarDecl {loc;id;tp} -> p_dict "VarDecl"
[ "loc", p_location loc
; "id", p_identifier id
; "tp", p_type_expression tp
]
let rec p_statement = function
| STMT_Call call -> P_Sequence
[ P_String "STMT_Call "
; p_call call
]
| STMT_Assign {loc; lhs; rhs} -> p_dict "STMT_Assign"
[ "loc", p_location loc
; "lhs", p_lvalue lhs
; "rhs", p_expression rhs
]
| STMT_VarDecl {var; init} -> p_dict "STMT_VarDecl"
[ "var", p_var_declaration var
; "init", p_opt p_expression init
]
| STMT_If {loc; cond; then_branch; else_branch} -> p_dict "STMT_If"
[ "loc", p_location loc
; "cond", p_expression cond
; "then_branch", p_statement then_branch
; "else_branch", p_opt p_statement else_branch
]
| STMT_While {loc; cond; body} -> p_dict "STMT_While"
[ "loc", p_location loc
; "cond", p_expression cond
; "body", p_statement body
]
| STMT_Block block -> P_Sequence
[ P_String "STMT_Block "
; p_statement_block block
]
| STMT_MultiVarDecl {loc; vars; init} -> p_dict "STMT_MultiVarDecl"
[ "loc", p_location loc
; "vars", P_List (List.map (p_opt p_var_declaration) vars)
; "init", p_call init
]
| STMT_Return {loc; values} -> p_dict "STMT_Return"
[ "loc", p_location loc
; "values", P_List (List.map p_expression values)
]
and p_statement_block = function
| STMTBlock {loc; body} -> p_dict "STMTBlock"
[ "loc", p_location loc
; "body", P_List (List.map p_statement body)
]
let p_global_declaration = function
| GDECL_Function {loc;id;formal_parameters; return_types; body} ->
p_dict "GDECL_Function"
[ "loc", p_location loc
; "id", p_identifier id
; "formal_parameters", P_List (List.map p_var_declaration formal_parameters)
; "return_types", P_List (List.map p_type_expression return_types)
; "body", p_opt p_statement_block body
]
let p_module_definition = function
| ModuleDefinition {global_declarations} -> P_Sequence
[ P_String "ModuleDefinition "
; P_List (List.map p_global_declaration global_declarations)
]
let show_module_definition mdef =
let p = p_module_definition mdef in
render_r @@ render_p p
|
