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//! # Reduced AST
//! The reduced AST is a minimal AST designed to be built from the full AST after all possible
//! static checks have been done. Consequently, the AST reduction phase does very little error
//! checking itself - any errors should ideally be caught either by an earlier phase, or are
//! runtime errors that the evaluator should handle. That said, becuase it does do table lookups
//! that can in principle fail [especially at the moment with most static analysis not yet complete],
//! there is an Expr variant `ReductionError` to handle these cases.
//!
//! A design decision to make - should the ReducedAST types contain all information about
//! type/layout necessary for the evaluator to work? If so, then the evaluator should not
//! have access to the symbol table at all and ReducedAST should carry that information. If not,
//! then ReducedAST shouldn't be duplicating information that can be queried at runtime from the
//! symbol table. But I think the former might make sense since ultimately the bytecode will be
//! built from the ReducedAST.
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use std ::rc ::Rc ;
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use std ::str ::FromStr ;
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use crate ::ast ::* ;
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use crate ::symbol_table ::{ Symbol , SymbolSpec , SymbolTable , FullyQualifiedSymbolName } ;
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use crate ::builtin ::Builtin ;
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#[ derive(Debug) ]
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pub struct ReducedAST ( pub Vec < Stmt > ) ;
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#[ derive(Debug, Clone) ]
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pub enum Stmt {
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PreBinding {
name : Rc < String > ,
func : Func ,
} ,
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Binding {
name : Rc < String > ,
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constant : bool ,
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expr : Expr ,
} ,
Expr ( Expr ) ,
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Noop ,
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}
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#[ derive(Debug, Clone) ]
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pub enum Expr {
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Unit ,
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Lit ( Lit ) ,
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Tuple ( Vec < Expr > ) ,
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Func ( Func ) ,
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Sym ( Rc < String > ) ,
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Constructor {
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type_name : Rc < String > ,
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name : Rc < String > ,
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tag : usize ,
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arity : usize , // n.b. arity here is always the value from the symbol table - if it doesn't match what it's being called with, that's an eval error, eval will handle it
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} ,
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Call {
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f : Box < Expr > ,
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args : Vec < Expr > ,
} ,
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Assign {
val : Box < Expr > ,
expr : Box < Expr > ,
} ,
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Conditional {
cond : Box < Expr > ,
then_clause : Vec < Stmt > ,
else_clause : Vec < Stmt > ,
} ,
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ConditionalTargetSigilValue ,
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CaseMatch {
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cond : Box < Expr > ,
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alternatives : Vec < Alternative >
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} ,
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UnimplementedSigilValue ,
ReductionError ( String ) ,
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}
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pub type BoundVars = Vec < Option < Rc < String > > > ; //remember that order matters here
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#[ derive(Debug, Clone) ]
pub struct Alternative {
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pub matchable : Subpattern ,
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pub item : Vec < Stmt > ,
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}
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#[ derive(Debug, Clone) ]
pub struct Subpattern {
pub tag : Option < usize > ,
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pub subpatterns : Vec < Option < Subpattern > > ,
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pub bound_vars : BoundVars ,
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pub guard : Option < Expr > ,
}
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#[ derive(Debug, Clone) ]
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pub enum Lit {
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Nat ( u64 ) ,
Int ( i64 ) ,
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Float ( f64 ) ,
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Bool ( bool ) ,
StringLit ( Rc < String > ) ,
}
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#[ derive(Debug, Clone) ]
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pub enum Func {
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BuiltIn ( Builtin ) ,
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UserDefined {
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name : Option < Rc < String > > ,
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params : Vec < Rc < String > > ,
body : Vec < Stmt > ,
}
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}
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pub fn reduce ( ast : & AST , symbol_table : & SymbolTable ) -> ReducedAST {
let mut reducer = Reducer { symbol_table } ;
reducer . ast ( ast )
}
struct Reducer < ' a > {
symbol_table : & ' a SymbolTable
}
impl < ' a > Reducer < ' a > {
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fn ast ( & mut self , ast : & AST ) -> ReducedAST {
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let mut output = vec! [ ] ;
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for statement in ast . statements . iter ( ) {
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output . push ( self . statement ( statement ) ) ;
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}
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ReducedAST ( output )
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}
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fn statement ( & mut self , stmt : & Meta < Statement > ) -> Stmt {
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match & stmt . node ( ) . kind {
StatementKind ::Expression ( expr ) = > Stmt ::Expr ( self . expression ( & expr ) ) ,
StatementKind ::Declaration ( decl ) = > self . declaration ( & decl ) ,
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}
}
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fn block ( & mut self , block : & Block ) -> Vec < Stmt > {
block . iter ( ) . map ( | stmt | self . statement ( stmt ) ) . collect ( )
}
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fn invocation_argument ( & mut self , invoc : & InvocationArgument ) -> Expr {
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use crate ::ast ::InvocationArgument ::* ;
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match invoc {
Positional ( ex ) = > self . expression ( ex ) ,
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Keyword { .. } = > Expr ::UnimplementedSigilValue ,
Ignored = > Expr ::UnimplementedSigilValue ,
}
}
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fn expression ( & mut self , expr : & Meta < Expression > ) -> Expr {
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use crate ::ast ::ExpressionKind ::* ;
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let symbol_table = self . symbol_table ;
let ref node = expr . node ( ) ;
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let ref input = node . kind ;
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match input {
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NatLiteral ( n ) = > Expr ::Lit ( Lit ::Nat ( * n ) ) ,
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FloatLiteral ( f ) = > Expr ::Lit ( Lit ::Float ( * f ) ) ,
StringLiteral ( s ) = > Expr ::Lit ( Lit ::StringLit ( s . clone ( ) ) ) ,
BoolLiteral ( b ) = > Expr ::Lit ( Lit ::Bool ( * b ) ) ,
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BinExp ( binop , lhs , rhs ) = > self . binop ( binop , lhs , rhs ) ,
PrefixExp ( op , arg ) = > self . prefix ( op , arg ) ,
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Value ( qualified_name ) = > {
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let ref id = qualified_name . id ;
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let ref sym_name = match symbol_table . get_fqsn_from_id ( id ) {
Some ( fqsn ) = > fqsn ,
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None = > return Expr ::ReductionError ( format! ( " FQSN lookup for Value {:?} failed " , qualified_name ) ) ,
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} ;
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//TODO this probably needs to change
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let FullyQualifiedSymbolName ( ref v ) = sym_name ;
let name = v . last ( ) . unwrap ( ) . name . clone ( ) ;
match symbol_table . lookup_by_fqsn ( & sym_name ) {
Some ( Symbol { spec : SymbolSpec ::DataConstructor { index , type_args , type_name } , .. } ) = > Expr ::Constructor {
type_name : type_name . clone ( ) ,
name : name . clone ( ) ,
tag : index . clone ( ) ,
arity : type_args . len ( ) ,
} ,
_ = > Expr ::Sym ( name . clone ( ) ) ,
}
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} ,
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Call { f , arguments } = > self . reduce_call_expression ( f , arguments ) ,
TupleLiteral ( exprs ) = > Expr ::Tuple ( exprs . iter ( ) . map ( | e | self . expression ( e ) ) . collect ( ) ) ,
IfExpression { discriminator , body } = > self . reduce_if_expression ( discriminator , body ) ,
Lambda { params , body , .. } = > self . reduce_lambda ( params , body ) ,
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NamedStruct { name , fields } = > self . reduce_named_struct ( name . node ( ) , fields ) ,
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Index { .. } = > Expr ::UnimplementedSigilValue ,
WhileExpression { .. } = > Expr ::UnimplementedSigilValue ,
ForExpression { .. } = > Expr ::UnimplementedSigilValue ,
ListLiteral { .. } = > Expr ::UnimplementedSigilValue ,
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}
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}
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fn reduce_lambda ( & mut self , params : & Vec < FormalParam > , body : & Block ) -> Expr {
Expr ::Func ( Func ::UserDefined {
name : None ,
params : params . iter ( ) . map ( | param | param . name . clone ( ) ) . collect ( ) ,
body : self . block ( body ) ,
} )
}
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fn reduce_named_struct ( & mut self , name : & QualifiedName , fields : & Vec < ( Rc < String > , Meta < Expression > ) > ) -> Expr {
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let symbol_table = self . symbol_table ;
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let ref sym_name = match symbol_table . get_fqsn_from_id ( & name . id ) {
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Some ( fqsn ) = > fqsn ,
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None = > return Expr ::ReductionError ( format! ( " FQSN lookup for name {:?} failed " , name ) ) ,
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} ;
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let FullyQualifiedSymbolName ( ref v ) = sym_name ;
let ref name = v . last ( ) . unwrap ( ) . name ;
let ( type_name , index , members_from_table ) = match symbol_table . lookup_by_fqsn ( & sym_name ) {
Some ( Symbol { spec : SymbolSpec ::RecordConstructor { members , type_name , index } , .. } ) = > ( type_name . clone ( ) , index , members ) ,
_ = > return Expr ::ReductionError ( " Not a record constructor " . to_string ( ) ) ,
} ;
let arity = members_from_table . len ( ) ;
let mut args : Vec < ( Rc < String > , Expr ) > = fields . iter ( )
. map ( | ( name , expr ) | ( name . clone ( ) , self . expression ( expr ) ) )
. collect ( ) ;
args . as_mut_slice ( )
. sort_unstable_by ( | ( name1 , _ ) , ( name2 , _ ) | name1 . cmp ( name2 ) ) ; //arbitrary - sorting by alphabetical order
let args = args . into_iter ( ) . map ( | ( _ , expr ) | expr ) . collect ( ) ;
//TODO make sure this sorting actually works
let f = box Expr ::Constructor { type_name , name : name . clone ( ) , tag : * index , arity , } ;
Expr ::Call { f , args }
}
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fn reduce_call_expression ( & mut self , func : & Meta < Expression > , arguments : & Vec < InvocationArgument > ) -> Expr {
Expr ::Call {
f : Box ::new ( self . expression ( func ) ) ,
args : arguments . iter ( ) . map ( | arg | self . invocation_argument ( arg ) ) . collect ( ) ,
}
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}
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fn reduce_if_expression ( & mut self , discriminator : & Discriminator , body : & IfExpressionBody ) -> Expr {
let symbol_table = self . symbol_table ;
let cond = Box ::new ( match * discriminator {
Discriminator ::Simple ( ref expr ) = > self . expression ( expr ) ,
Discriminator ::BinOp ( ref _expr , ref _binop ) = > panic! ( " Can't yet handle binop discriminators " )
} ) ;
match * body {
IfExpressionBody ::SimpleConditional ( ref then_clause , ref else_clause ) = > {
let then_clause = self . block ( then_clause ) ;
let else_clause = match else_clause {
None = > vec! [ ] ,
Some ( stmts ) = > self . block ( stmts ) ,
} ;
Expr ::Conditional { cond , then_clause , else_clause }
} ,
IfExpressionBody ::SimplePatternMatch ( ref pat , ref then_clause , ref else_clause ) = > {
let then_clause = self . block ( then_clause ) ;
let else_clause = match else_clause {
None = > vec! [ ] ,
Some ( stmts ) = > self . block ( stmts ) ,
} ;
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let alternatives = vec! [
pat . to_alternative ( then_clause , symbol_table ) ,
Alternative {
matchable : Subpattern {
tag : None ,
subpatterns : vec ! [ ] ,
bound_vars : vec ! [ ] ,
guard : None ,
} ,
item : else_clause
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} ,
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] ;
Expr ::CaseMatch {
cond ,
alternatives ,
}
} ,
IfExpressionBody ::GuardList ( ref guard_arms ) = > {
let mut alternatives = vec! [ ] ;
for arm in guard_arms {
match arm . guard {
Guard ::Pat ( ref p ) = > {
let item = self . block ( & arm . body ) ;
let alt = p . to_alternative ( item , symbol_table ) ;
alternatives . push ( alt ) ;
} ,
Guard ::HalfExpr ( HalfExpr { op : _ , expr : _ } ) = > {
return Expr ::UnimplementedSigilValue
}
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}
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}
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Expr ::CaseMatch { cond , alternatives }
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}
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}
}
fn binop ( & mut self , binop : & BinOp , lhs : & Box < Meta < Expression > > , rhs : & Box < Meta < Expression > > ) -> Expr {
let operation = Builtin ::from_str ( binop . sigil ( ) ) . ok ( ) ;
match operation {
Some ( Builtin ::Assignment ) = > Expr ::Assign {
val : Box ::new ( self . expression ( & * lhs ) ) ,
expr : Box ::new ( self . expression ( & * rhs ) ) ,
} ,
Some ( op ) = > {
let f = Box ::new ( Expr ::Func ( Func ::BuiltIn ( op ) ) ) ;
Expr ::Call { f , args : vec ! [ self . expression ( & * lhs ) , self . expression ( & * rhs ) ] }
} ,
None = > {
//TODO handle a user-defined operation
Expr ::UnimplementedSigilValue
}
}
}
fn prefix ( & mut self , prefix : & PrefixOp , arg : & Box < Meta < Expression > > ) -> Expr {
match prefix . builtin {
Some ( op ) = > {
let f = Box ::new ( Expr ::Func ( Func ::BuiltIn ( op ) ) ) ;
Expr ::Call { f , args : vec ! [ self . expression ( arg ) ] }
} ,
None = > { //TODO need this for custom prefix ops
Expr ::UnimplementedSigilValue
}
}
}
fn declaration ( & mut self , declaration : & Declaration ) -> Stmt {
use self ::Declaration ::* ;
match declaration {
Binding { name , constant , expr , .. } = > Stmt ::Binding { name : name . clone ( ) , constant : * constant , expr : self . expression ( expr ) } ,
FuncDecl ( Signature { name , params , .. } , statements ) = > Stmt ::PreBinding {
name : name . clone ( ) ,
func : Func ::UserDefined {
name : Some ( name . clone ( ) ) ,
params : params . iter ( ) . map ( | param | param . name . clone ( ) ) . collect ( ) ,
body : self . block ( & statements ) ,
}
} ,
TypeDecl { .. } = > Stmt ::Noop ,
TypeAlias ( _ , _ ) = > Stmt ::Noop ,
Interface { .. } = > Stmt ::Noop ,
Impl { .. } = > Stmt ::Expr ( Expr ::UnimplementedSigilValue ) ,
_ = > Stmt ::Expr ( Expr ::UnimplementedSigilValue )
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}
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}
}
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/* ig var pat
* x is SomeBigOldEnum ( _ , x , Some ( t ) )
* /
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fn handle_symbol ( symbol : Option < & Symbol > , inner_patterns : & Vec < Pattern > , symbol_table : & SymbolTable ) -> Subpattern {
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use self ::Pattern ::* ;
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let tag = symbol . map ( | symbol | match symbol . spec {
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SymbolSpec ::DataConstructor { index , .. } = > index . clone ( ) ,
_ = > panic! ( " Symbol is not a data constructor - this should've been caught in type-checking " ) ,
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} ) ;
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let bound_vars = inner_patterns . iter ( ) . map ( | p | match p {
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VarOrName ( qualified_name ) = > {
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let fqsn = symbol_table . get_fqsn_from_id ( & qualified_name . id ) ;
let symbol_exists = fqsn . and_then ( | fqsn | symbol_table . lookup_by_fqsn ( & fqsn ) ) . is_some ( ) ;
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if symbol_exists {
None
} else {
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let QualifiedName { components , .. } = qualified_name ;
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if components . len ( ) = = 1 {
Some ( components [ 0 ] . clone ( ) )
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} else {
panic! ( " Bad variable name in pattern " ) ;
}
}
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} ,
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_ = > None ,
} ) . collect ( ) ;
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let subpatterns = inner_patterns . iter ( ) . map ( | p | match p {
Ignored = > None ,
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VarOrName ( _ ) = > None ,
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Literal ( other ) = > Some ( other . to_subpattern ( symbol_table ) ) ,
tp @ TuplePattern ( _ ) = > Some ( tp . to_subpattern ( symbol_table ) ) ,
ts @ TupleStruct ( _ , _ ) = > Some ( ts . to_subpattern ( symbol_table ) ) ,
Record ( .. ) = > unimplemented! ( ) ,
} ) . collect ( ) ;
let guard = None ;
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/*
let guard_equality_exprs : Vec < Expr > = subpatterns . iter ( ) . map ( | p | match p {
Literal ( lit ) = > match lit {
_ = > unimplemented! ( )
} ,
_ = > unimplemented! ( )
} ) . collect ( ) ;
* /
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Subpattern {
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tag ,
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subpatterns ,
guard ,
bound_vars ,
}
}
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impl Pattern {
fn to_alternative ( & self , item : Vec < Stmt > , symbol_table : & SymbolTable ) -> Alternative {
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let s = self . to_subpattern ( symbol_table ) ;
Alternative {
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matchable : Subpattern {
tag : s . tag ,
subpatterns : s . subpatterns ,
bound_vars : s . bound_vars ,
guard : s . guard ,
} ,
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item
}
}
fn to_subpattern ( & self , symbol_table : & SymbolTable ) -> Subpattern {
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use self ::Pattern ::* ;
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match self {
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TupleStruct ( QualifiedName { components , id } , inner_patterns ) = > {
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let fqsn = symbol_table . get_fqsn_from_id ( & id ) ;
match fqsn . and_then ( | fqsn | symbol_table . lookup_by_fqsn ( & fqsn ) ) {
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Some ( symbol ) = > handle_symbol ( Some ( symbol ) , inner_patterns , symbol_table ) ,
None = > {
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panic! ( " Symbol {:?} not found " , components ) ;
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}
}
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} ,
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TuplePattern ( inner_patterns ) = > handle_symbol ( None , inner_patterns , symbol_table ) ,
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Record ( _name , _pairs ) = > {
unimplemented! ( )
} ,
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Ignored = > Subpattern { tag : None , subpatterns : vec ! [ ] , guard : None , bound_vars : vec ! [ ] } ,
Literal ( lit ) = > lit . to_subpattern ( symbol_table ) ,
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VarOrName ( QualifiedName { components , id } ) = > {
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// if fqsn is Some, treat this as a symbol pattern. If it's None, treat it
// as a variable.
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println! ( " Calling VarOrName reduction with : {:?} " , components ) ;
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let fqsn = symbol_table . get_fqsn_from_id ( & id ) ;
match fqsn . and_then ( | fqsn | symbol_table . lookup_by_fqsn ( & fqsn ) ) {
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Some ( symbol ) = > handle_symbol ( Some ( symbol ) , & vec! [ ] , symbol_table ) ,
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None = > {
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let name = if components . len ( ) = = 1 {
components [ 0 ] . clone ( )
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} else {
panic! ( " check this line of code yo " ) ;
} ;
Subpattern {
tag : None ,
subpatterns : vec ! [ ] ,
guard : None ,
bound_vars : vec ! [ Some ( name . clone ( ) ) ] ,
}
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}
}
} ,
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}
}
}
impl PatternLiteral {
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fn to_subpattern ( & self , _symbol_table : & SymbolTable ) -> Subpattern {
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use self ::PatternLiteral ::* ;
match self {
NumPattern { neg , num } = > {
let comparison = Expr ::Lit ( match ( neg , num ) {
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( false , ExpressionKind ::NatLiteral ( n ) ) = > Lit ::Nat ( * n ) ,
( false , ExpressionKind ::FloatLiteral ( f ) ) = > Lit ::Float ( * f ) ,
( true , ExpressionKind ::NatLiteral ( n ) ) = > Lit ::Int ( - 1 * ( * n as i64 ) ) ,
( true , ExpressionKind ::FloatLiteral ( f ) ) = > Lit ::Float ( - 1.0 * f ) ,
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_ = > panic! ( " This should never happen " )
} ) ;
let guard = Some ( Expr ::Call {
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f : Box ::new ( Expr ::Func ( Func ::BuiltIn ( Builtin ::Equality ) ) ) ,
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args : vec ! [ comparison , Expr ::ConditionalTargetSigilValue ] ,
} ) ;
Subpattern {
tag : None ,
subpatterns : vec ! [ ] ,
guard ,
bound_vars : vec ! [ ] ,
}
} ,
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StringPattern ( s ) = > {
let guard = Some ( Expr ::Call {
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f : Box ::new ( Expr ::Func ( Func ::BuiltIn ( Builtin ::Equality ) ) ) ,
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args : vec ! [ Expr ::Lit ( Lit ::StringLit ( s . clone ( ) ) ) , Expr ::ConditionalTargetSigilValue ]
} ) ;
Subpattern {
tag : None ,
subpatterns : vec ! [ ] ,
guard ,
bound_vars : vec ! [ ] ,
}
} ,
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BoolPattern ( b ) = > {
let guard = Some ( if * b {
Expr ::ConditionalTargetSigilValue
} else {
Expr ::Call {
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f : Box ::new ( Expr ::Func ( Func ::BuiltIn ( Builtin ::BooleanNot ) ) ) ,
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args : vec ! [ Expr ::ConditionalTargetSigilValue ]
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}
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} ) ;
Subpattern {
tag : None ,
subpatterns : vec ! [ ] ,
guard ,
bound_vars : vec ! [ ] ,
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}
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} ,
}
}
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}