rework typed_ir to have flat expressions
This commit is contained in:
parent
b71f9f09ae
commit
a2cca95dbd
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@ -1,7 +1,7 @@
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comb comparator (
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a: Logic<8>,
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b: Logic<8>
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) -> Logic
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) -> Logic<1>
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{
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~reduce_or(a ^ b)
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}
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@ -1,6 +1,6 @@
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comb identity (
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a: Logic
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) -> Logic
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a: Logic<5>
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) -> Logic<5>
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{
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a
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}
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@ -1,5 +1,5 @@
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use std::cell::Cell;
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use std::collections::BTreeMap;
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use std::collections::{BTreeMap, HashMap};
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use super::parser;
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use super::parser::block_expression::BlockExpr;
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@ -122,20 +122,32 @@ impl Context {
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}
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}
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fn type_expression(
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fn intern_expression(
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&self,
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exprs: &mut HashMap<typed_ir::ExprId, typed_ir::Expr>,
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expr: typed_ir::Expr,
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) -> typed_ir::ExprId {
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let expr_id = expr.id;
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exprs.insert(expr.id, expr);
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expr_id
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}
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fn type_expression(
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&mut self,
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exprs: &mut HashMap<typed_ir::ExprId, typed_ir::Expr>,
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expr: &parser::expression::Expression,
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) -> Result<typed_ir::Expr, CompileError> {
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) -> Result<typed_ir::ExprId, CompileError> {
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use parser::expression::Expression;
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let id = typed_ir::ExprId(self.ids.next() as u32);
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let t_expr = match expr {
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Expression::Path(name) => {
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let signal = self.try_get_signal(name)?;
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typed_ir::Expr {
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let this_expr = typed_ir::Expr {
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id,
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kind: typed_ir::ExprKind::Path(signal.id),
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typ: signal.typ,
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}
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};
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self.intern_expression(exprs, this_expr)
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}
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Expression::Literal(lit) => {
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let data = match lit.kind {
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@ -144,15 +156,16 @@ impl Context {
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self.types.make_const_u32(width, val as u32)
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}
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};
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typed_ir::Expr {
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let this_expr = typed_ir::Expr {
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id,
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kind: typed_ir::ExprKind::Literal(data),
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typ: self.types.primitives.infer,
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}
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};
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self.intern_expression(exprs, this_expr)
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}
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Expression::UnOp(op) => {
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let a = self.type_expression(&op.a)?;
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typed_ir::Expr {
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let a = self.type_expression(exprs, &op.a)?;
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let this_expr = typed_ir::Expr {
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id,
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kind: typed_ir::ExprKind::Call(typed_ir::Call {
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called: self.callables.builtins.bitnot,
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@ -160,11 +173,15 @@ impl Context {
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genargs: vec![],
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}),
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typ: self.types.primitives.infer,
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}
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};
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self.intern_expression(exprs, this_expr)
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}
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Expression::BinOp(op) => {
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let (a, b) = (self.type_expression(&op.a)?, self.type_expression(&op.b)?);
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typed_ir::Expr {
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let (a, b) = (
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self.type_expression(exprs, &op.a)?,
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self.type_expression(exprs, &op.b)?,
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);
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let this_expr = typed_ir::Expr {
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id,
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kind: typed_ir::ExprKind::Call(typed_ir::Call {
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called: self.callables.builtins.xor,
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@ -172,13 +189,14 @@ impl Context {
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genargs: vec![],
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}),
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typ: self.types.primitives.infer,
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}
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};
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self.intern_expression(exprs, this_expr)
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}
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Expression::Call(call) => {
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let args_resolved = call
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.args
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.iter()
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.map(|expr| self.type_expression(expr))
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.map(|expr| self.type_expression(exprs, expr))
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.collect::<Result<Vec<_>, _>>()?;
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let called = self.try_get_callable(call.name.fragment())?;
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let called_callable = self.callables.get(called);
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@ -187,13 +205,13 @@ impl Context {
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received: args_resolved.len(),
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expected: called_callable.argcount(),
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}));
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}
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};
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let genargs_resolved = called_callable
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.genargs
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.iter()
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.map(|genarg| genarg.1)
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.collect();
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typed_ir::Expr {
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let this_expr = typed_ir::Expr {
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id,
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kind: typed_ir::ExprKind::Call(typed_ir::Call {
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called,
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@ -201,28 +219,43 @@ impl Context {
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genargs: genargs_resolved,
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}),
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typ: self.types.primitives.infer,
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}
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};
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self.intern_expression(exprs, this_expr)
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}
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Expression::BlockExpr(block) => match &**block {
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BlockExpr::IfElse(_) => todo!(),
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BlockExpr::Match(match_) => {
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let expr = self.type_expression(&match_.expr)?;
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let expr = self.type_expression(exprs, &match_.expr)?;
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let arms = match_
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.arms
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.iter()
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.map(|(cond, val)| {
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Ok((self.type_expression(cond)?, self.type_expression(val)?))
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Ok((
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self.type_expression(exprs, cond)?,
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self.type_expression(exprs, val)?,
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))
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})
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.collect::<Result<_, _>>()?;
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let typed = typed_ir::Match { expr, arms };
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typed_ir::Expr {
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let this_expr = typed_ir::Expr {
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id,
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kind: typed_ir::ExprKind::Match(Box::new(typed)),
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typ: self.types.primitives.infer,
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}
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};
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self.intern_expression(exprs, this_expr)
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}
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BlockExpr::Block(block) => {
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todo!("expression blocks not representable in typed ir yet")
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// TODO: we need to find some way of resolving a name to an expression
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todo!("can not convert blocks to typed_ir yet");
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for (name, expr) in &block.assignments {
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let signal = typed_ir::Signal {
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id: typed_ir::DefId(self.ids.next() as u32),
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typ: self.types.primitives.infer,
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};
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// TODO: need to add this signal to the block from here, somehow
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self.signals.insert(name.span().to_string(), signal);
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}
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self.type_expression(exprs, &block.value)?
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}
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},
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Expression::StructInit(_) => todo!("structure initialization"),
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@ -247,8 +280,9 @@ impl Context {
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let sig_typename = &port.net.typ;
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let mut sig_type = self.try_get_type(sig_typename.name.fragment())?;
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if let Some(arg) = &sig_typename.generics {
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let elab_expr = self.type_expression(arg)?;
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let elab_val = self.eval_expression(&elab_expr)?;
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let mut exprs = Default::default();
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let elab_expr = self.type_expression(&mut exprs, arg)?;
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let elab_val = self.eval_expression(exprs.get(&elab_expr).unwrap())?;
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sig_type = self
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.types
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.parameterize(sig_type, &[types::GenericArg::Elab(elab_val)])
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@ -294,11 +328,14 @@ impl Context {
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}
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}
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let root_expr = self.type_expression(&comb.expr)?;
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let mut exprs = Default::default();
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let root_expr = self.type_expression(&mut exprs, &comb.expr)?;
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Ok(typed_ir::Body {
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signature: callable_id,
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signals,
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exprs,
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expr: root_expr,
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})
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}
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@ -4,13 +4,18 @@ use super::{make_pubid, CompileError, Context};
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use crate::rtlil;
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use crate::rtlil::RtlilWrite;
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fn wire_for_expr(expr: typed_ir::ExprId) -> rtlil::SigSpec {
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rtlil::SigSpec::Wire(format!("$_expr_{}", expr.0))
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}
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fn lower_expression(
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ctx: &Context,
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module: &mut rtlil::Module,
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body: &typed_ir::Body,
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expr: &typed_ir::Expr,
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) -> Result<rtlil::SigSpec, CompileError> {
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let expr_width = ctx.types.get_width(expr.typ).expect("signal needs width");
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let expr_wire_name = format!("$_sig_{}", expr.id.0);
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let expr_wire_name = format!("$_expr_{}", expr.id.0);
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let expr_wire = rtlil::Wire::new(expr_wire_name.clone(), expr_width, None);
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module.add_wire(expr_wire);
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match &expr.kind {
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@ -19,15 +24,21 @@ fn lower_expression(
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let args_resolved = call
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.args
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.iter()
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.map(|expr| lower_expression(ctx, module, expr))
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.collect::<Result<Vec<_>, _>>()?;
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.map(|expr| wire_for_expr(*expr))
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.collect::<Vec<_>>();
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let args: Vec<_> = call
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.args
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.iter()
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.map(|expr_id| body.exprs.get(expr_id).unwrap())
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.collect();
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let callable = ctx.callables.get(call.called);
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let cell_id = module.make_genid(callable.name());
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if call.called == ctx.callables.builtins.xor {
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let a_width = ctx.types.get_width(call.args[0].typ).unwrap();
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let b_width = ctx.types.get_width(call.args[1].typ).unwrap();
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let a_width = ctx.types.get_width(args[0].typ).unwrap();
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let b_width = ctx.types.get_width(args[1].typ).unwrap();
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let y_width = ctx.types.get_width(expr.typ).unwrap();
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let mut cell = rtlil::Cell::new(&cell_id, "$xor");
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cell.add_param("\\A_SIGNED", "0");
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cell.add_connection("\\Y", &rtlil::SigSpec::Wire(expr_wire_name.clone()));
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module.add_cell(cell);
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} else if call.called == ctx.callables.builtins.reduce_or {
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let a_width = ctx.types.get_width(call.args[0].typ).unwrap();
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let a_width = ctx.types.get_width(args[0].typ).unwrap();
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let y_width = ctx.types.get_width(expr.typ).unwrap();
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let mut cell = rtlil::Cell::new(&cell_id, "$reduce_or");
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cell.add_param("\\A_SIGNED", "0");
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cell.add_connection("\\Y", &rtlil::SigSpec::Wire(expr_wire_name.clone()));
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module.add_cell(cell);
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} else if call.called == ctx.callables.builtins.bitnot {
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let a_width = ctx.types.get_width(call.args[0].typ).unwrap();
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let a_width = ctx.types.get_width(args[0].typ).unwrap();
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let y_width = ctx.types.get_width(expr.typ).unwrap();
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let mut cell = rtlil::Cell::new(&cell_id, "$not");
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cell.add_param("\\A_SIGNED", "0");
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@ -75,11 +86,11 @@ fn lower_expression(
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.iter()
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.map(|(pat, val)| {
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Ok((
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lower_expression(ctx, module, pat)?,
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wire_for_expr(*pat),
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rtlil::CaseRule {
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assign: vec![(
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rtlil::SigSpec::Wire(expr_wire_name.clone()),
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lower_expression(ctx, module, val)?,
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wire_for_expr(*val),
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)],
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switches: vec![],
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},
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@ -88,7 +99,7 @@ fn lower_expression(
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.collect::<Result<Vec<_>, CompileError>>()
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.unwrap();
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let root_switch = rtlil::SwitchRule {
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signal: lower_expression(ctx, module, &match_.expr)?,
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signal: wire_for_expr(match_.expr),
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cases,
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};
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let root_case = rtlil::CaseRule {
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@ -125,11 +136,15 @@ fn lower_comb(
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module.add_wire(rtlil::Wire::new(
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ret_id.clone(),
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ctx.types
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.get_width(block.expr.typ)
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.get_width(block.exprs.get(&block.expr).unwrap().typ)
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.expect("signal has no size"),
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Some(rtlil::PortOption::Output(block.signals.len() as i32)),
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));
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let out_sig = lower_expression(ctx, module, &block.expr)?;
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for (_, expr) in &block.exprs {
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let expr_wire = lower_expression(ctx, module, block, &expr)?;
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module.add_connection(&wire_for_expr(expr.id), &expr_wire);
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}
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let out_sig = wire_for_expr(block.expr);
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module.add_connection(&rtlil::SigSpec::Wire(ret_id), &out_sig);
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Ok(())
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}
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@ -5,9 +5,9 @@ impl Context {
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pub fn pretty_typed_block(
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&self,
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w: &mut dyn std::fmt::Write,
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block: &typed_ir::Body,
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body: &typed_ir::Body,
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) -> std::fmt::Result {
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let callsig = self.callables.get(block.signature);
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let callsig = self.callables.get(body.signature);
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{
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// TODO: ugly copy paste job
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let args = callsig
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@ -36,12 +36,15 @@ impl Context {
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args.join(", ")
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)?;
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}
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for sig in &block.signals {
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for sig in &body.signals {
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let mut typ_pretty = String::new();
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self.types.pretty_type(&mut typ_pretty, sig.typ)?;
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writeln!(w, "sig_{}: {}", sig.id.0, typ_pretty)?
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}
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self.pretty_typed_expr(w, &block.expr)?;
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for (_, expr) in &body.exprs {
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self.pretty_typed_expr(w, &expr)?;
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}
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writeln!(w, "return _{}", body.expr.0)?;
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Ok(())
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}
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|
@ -61,10 +64,7 @@ impl Context {
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let args = call
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.args
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.iter()
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.map(|arg| {
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self.pretty_typed_expr(w, arg)?;
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Ok(format!("_{}", arg.id.0))
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})
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.map(|arg| Ok(format!("_{}", arg.0)))
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.collect::<Result<Vec<_>, std::fmt::Error>>()?;
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let callable = self.callables.get(call.called);
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let genargs = call
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|
@ -84,21 +84,12 @@ impl Context {
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)
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}
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typed_ir::ExprKind::Match(match_) => {
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self.pretty_typed_expr(w, &match_.expr)?;
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let arms = match_
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.arms
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.iter()
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.map(|(pat, val)| {
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self.pretty_typed_expr(w, pat)?;
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self.pretty_typed_expr(w, val)?;
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Ok(format!(" _{} => _{}", pat.id.0, val.id.0))
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})
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.map(|(pat, val)| Ok(format!(" _{} => _{}", pat.0, val.0)))
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.collect::<Result<Vec<_>, _>>()?;
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format!(
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"match (_{}) {{\n{}\n}}",
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&match_.expr.id.0,
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arms.join(",\n")
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)
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format!("match (_{}) {{\n{}\n}}", &match_.expr.0, arms.join(",\n"))
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}
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};
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let mut type_pretty = String::new();
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|
|
|
@ -1,87 +1,104 @@
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use super::typed_ir;
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use super::typed_ir::{Expr, ExprId, ExprKind};
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use super::types;
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use super::Context;
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use super::{CompileError, CompileErrorKind, Context};
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use std::collections::HashMap;
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impl Context {
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pub fn infer_types(&mut self, mut block: typed_ir::Body) -> typed_ir::Body {
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let new_root = self.infer_expr_types(&block.expr);
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block.expr = new_root;
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block
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pub fn infer_types(&mut self, block: typed_ir::Body) -> typed_ir::Body {
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// TODO: ugly ugly hack
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let try_1 = self
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.infer_body_types(&block)
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.expect("could not infer types");
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let try_2 = self
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.infer_body_types(&try_1)
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.expect("could not infer types");
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self.infer_body_types(&try_2)
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.expect("could not infer types")
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}
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pub fn infer_expr_types(&mut self, expr: &typed_ir::Expr) -> typed_ir::Expr {
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pub fn infer_body_types(
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&mut self,
|
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body: &typed_ir::Body,
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) -> Result<typed_ir::Body, CompileError> {
|
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let mut new_exprs = HashMap::new();
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for (expr_id, expr) in &body.exprs {
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if self.types.is_fully_typed(expr.typ) {
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// there is nothing more to infer
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return expr.clone();
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new_exprs.insert(*expr_id, expr.clone());
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continue;
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}
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match &expr.kind {
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typed_ir::ExprKind::Literal(lit) => expr.clone().with_type(lit.typ),
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// we can not see beyond this expression right now
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typed_ir::ExprKind::Path(_) => expr.clone(),
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typed_ir::ExprKind::Call(call) => {
|
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let args_typed: Vec<_> = call
|
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.args
|
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.iter()
|
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.map(|ex| self.infer_expr_types(ex))
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.collect();
|
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let callee_def = self.callables.get(call.called);
|
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ExprKind::Literal(lit) => {
|
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// TODO: don't try to overwrite the type of a literal
|
||||
let infres = self.types.infer_type(expr.typ, lit.typ);
|
||||
new_exprs.insert(*expr_id, expr.clone().with_type(lit.typ));
|
||||
}
|
||||
ExprKind::Path(_) => {
|
||||
new_exprs.insert(*expr_id, expr.clone());
|
||||
}
|
||||
ExprKind::Call(call) => {
|
||||
let called_def = self.callables.get(call.called);
|
||||
let param_types = called_def.args.iter().map(|param| param.1);
|
||||
|
||||
let param_types: Vec<_> = callee_def.args.iter().map(|param| param.1).collect();
|
||||
let mut genargs: Vec<_> = called_def.genargs.iter().map(|a| a.1).collect();
|
||||
let inferred_args: Vec<_> = param_types
|
||||
.iter()
|
||||
.zip(&args_typed)
|
||||
.map(|(param, arg)| self.types.infer_type(*param, arg.typ))
|
||||
.zip(&call.args)
|
||||
.map(|(param, arg)| {
|
||||
self.types
|
||||
.infer_type(param, body.exprs.get(arg).unwrap().typ)
|
||||
})
|
||||
.collect();
|
||||
|
||||
let mut genargs: Vec<_> = callee_def.genargs.iter().map(|a| a.1).collect();
|
||||
|
||||
let mut new_type = callee_def.ret_type;
|
||||
|
||||
if !genargs.is_empty() {
|
||||
// need to infer generic arguments
|
||||
for inf_res in inferred_args {
|
||||
match inf_res {
|
||||
types::InferenceResult::First(_) => todo!(),
|
||||
types::InferenceResult::Second(_) => todo!(),
|
||||
types::InferenceResult::TypeVar(dbi, tvar, typ) => {
|
||||
assert_eq!(dbi, 0);
|
||||
// TODO: type check argument instead of just using it
|
||||
genargs[tvar as usize] = typ;
|
||||
}
|
||||
types::InferenceResult::Incompatible => todo!(),
|
||||
types::InferenceResult::Ambigous => todo!(),
|
||||
_ => todo!(),
|
||||
}
|
||||
}
|
||||
|
||||
// TODO: HACKY HACKY HACK
|
||||
new_type = genargs[0];
|
||||
}
|
||||
|
||||
let mut new_expr = expr.clone();
|
||||
new_expr.typ = new_type;
|
||||
new_expr.kind = typed_ir::ExprKind::Call(typed_ir::Call {
|
||||
called: call.called,
|
||||
args: args_typed,
|
||||
genargs,
|
||||
});
|
||||
new_expr
|
||||
let ret_type = match self.types.infer_type(expr.typ, called_def.ret_type) {
|
||||
types::InferenceResult::TypeVar(dbi, tvar, typ) => {
|
||||
assert_eq!(dbi, 0);
|
||||
genargs[tvar as usize]
|
||||
}
|
||||
typed_ir::ExprKind::Match(match_) => {
|
||||
let new_arms: Vec<_> = match_
|
||||
.arms
|
||||
.iter()
|
||||
.map(|(pat, val)| (self.infer_expr_types(pat), self.infer_expr_types(val)))
|
||||
.collect();
|
||||
// TODO: hacky hacky hacky
|
||||
let res_type = new_arms.first().unwrap().1.typ;
|
||||
let new_match = typed_ir::Match {
|
||||
expr: self.infer_expr_types(&match_.expr),
|
||||
arms: new_arms,
|
||||
types::InferenceResult::First(typ) => typ,
|
||||
x => todo!("{x:?}"),
|
||||
};
|
||||
let mut new_expr = expr.clone().with_type(res_type);
|
||||
new_expr.kind = typed_ir::ExprKind::Match(Box::new(new_match));
|
||||
new_expr
|
||||
let new_expr = typed_ir::Expr {
|
||||
kind: typed_ir::ExprKind::Call(typed_ir::Call {
|
||||
genargs,
|
||||
..call.clone()
|
||||
}),
|
||||
typ: ret_type,
|
||||
..expr.clone()
|
||||
};
|
||||
new_exprs.insert(*expr_id, new_expr);
|
||||
}
|
||||
ExprKind::Match(match_) => {
|
||||
// TODO: hacky hacky hacky
|
||||
let res_type = body.exprs.get(&match_.arms.first().unwrap().1).unwrap().typ;
|
||||
let new_expr = expr.clone().with_type(res_type);
|
||||
new_exprs.insert(*expr_id, new_expr);
|
||||
}
|
||||
}
|
||||
}
|
||||
/*
|
||||
for (expr_id, expr) in &new_exprs {
|
||||
if !self.types.is_fully_typed(expr.typ) {
|
||||
return Err(CompileError::new(CompileErrorKind::TodoError("fail".to_owned())))
|
||||
}
|
||||
}
|
||||
*/
|
||||
let new_body = typed_ir::Body {
|
||||
exprs: new_exprs,
|
||||
..body.clone()
|
||||
};
|
||||
Ok(new_body)
|
||||
}
|
||||
}
|
||||
|
|
|
@ -1,11 +1,12 @@
|
|||
use super::callable::CallableId;
|
||||
use super::types::{ElabData, Type};
|
||||
use std::collections::HashMap;
|
||||
use std::fmt::Debug;
|
||||
|
||||
/// ID of a definition (e.g. variable, block, function)
|
||||
#[derive(Clone, Copy)]
|
||||
pub struct DefId(pub u32);
|
||||
#[derive(Clone, Copy)]
|
||||
#[derive(Clone, Copy, Hash, PartialEq, Eq)]
|
||||
pub struct ExprId(pub u32);
|
||||
|
||||
// more compact Debug impl
|
||||
|
@ -31,14 +32,14 @@ pub struct Expr {
|
|||
#[derive(Debug, Clone)]
|
||||
pub struct Call {
|
||||
pub called: CallableId,
|
||||
pub args: Vec<Expr>,
|
||||
pub args: Vec<ExprId>,
|
||||
pub genargs: Vec<Type>,
|
||||
}
|
||||
|
||||
#[derive(Debug, Clone)]
|
||||
pub struct Match {
|
||||
pub expr: Expr,
|
||||
pub arms: Vec<(Expr, Expr)>,
|
||||
pub expr: ExprId,
|
||||
pub arms: Vec<(ExprId, ExprId)>,
|
||||
}
|
||||
|
||||
#[derive(Debug, Clone)]
|
||||
|
@ -60,7 +61,8 @@ pub struct Signal {
|
|||
pub struct Body {
|
||||
pub signature: CallableId,
|
||||
pub signals: Vec<Signal>,
|
||||
pub expr: Expr,
|
||||
pub exprs: HashMap<ExprId, Expr>,
|
||||
pub expr: ExprId,
|
||||
}
|
||||
|
||||
impl Expr {
|
||||
|
|
|
@ -5,7 +5,7 @@ use std::fmt::Debug;
|
|||
/// easier
|
||||
pub type Type = InternedType;
|
||||
|
||||
#[derive(Copy, Clone, PartialEq)]
|
||||
#[derive(Copy, Clone, PartialEq, Eq)]
|
||||
pub struct InternedType(usize);
|
||||
|
||||
impl Debug for InternedType {
|
||||
|
@ -14,12 +14,12 @@ impl Debug for InternedType {
|
|||
}
|
||||
}
|
||||
|
||||
#[derive(Debug, Clone)]
|
||||
#[derive(Debug, Clone, PartialEq, Eq)]
|
||||
pub struct TypeStruct {
|
||||
kind: TypeKind,
|
||||
}
|
||||
|
||||
#[derive(Debug, Clone)]
|
||||
#[derive(Debug, Clone, PartialEq, Eq)]
|
||||
enum TypeKind {
|
||||
/// Elaboration-time types
|
||||
ElabType(ElabKind),
|
||||
|
@ -34,23 +34,23 @@ enum TypeKind {
|
|||
TypeVar(u32, u32),
|
||||
}
|
||||
|
||||
#[derive(Debug, Clone)]
|
||||
#[derive(Debug, Clone, PartialEq, Eq)]
|
||||
pub enum Adt {
|
||||
Struct(Struct),
|
||||
}
|
||||
|
||||
#[derive(Debug, Clone)]
|
||||
#[derive(Debug, Clone, PartialEq, Eq)]
|
||||
pub struct Struct {
|
||||
members: Vec<Type>,
|
||||
}
|
||||
|
||||
#[derive(Debug, Clone)]
|
||||
#[derive(Debug, Clone, PartialEq, Eq)]
|
||||
pub struct ElabData {
|
||||
pub typ: Type,
|
||||
value: ElabValue,
|
||||
}
|
||||
|
||||
#[derive(Debug, Clone)]
|
||||
#[derive(Debug, Clone, PartialEq, Eq)]
|
||||
enum ElabValue {
|
||||
/// the value is not given and has to be inferred
|
||||
Infer,
|
||||
|
@ -58,14 +58,14 @@ enum ElabValue {
|
|||
Concrete(ElabValueData),
|
||||
}
|
||||
|
||||
#[derive(Debug, Clone)]
|
||||
#[derive(Debug, Clone, PartialEq, Eq)]
|
||||
enum ElabValueData {
|
||||
U32(u32),
|
||||
Bytes(Vec<u8>),
|
||||
}
|
||||
|
||||
/// Types that are only valid during Elaboration
|
||||
#[derive(Debug, Clone)]
|
||||
#[derive(Debug, Clone, PartialEq, Eq)]
|
||||
enum ElabKind {
|
||||
/// general, unsized number type
|
||||
Num,
|
||||
|
@ -85,6 +85,8 @@ pub enum InferenceResult {
|
|||
Second(Type),
|
||||
/// A typevar was inferred
|
||||
TypeVar(u32, u32, Type),
|
||||
/// The types are equivalent
|
||||
Equivalent,
|
||||
/// The types were incompatible
|
||||
Incompatible,
|
||||
/// Neither of the types were complete
|
||||
|
@ -244,7 +246,7 @@ impl TypingContext {
|
|||
|
||||
fn is_fully_typed_kind(&self, kind: &TypeKind) -> bool {
|
||||
match kind {
|
||||
TypeKind::ElabType(_) => todo!(),
|
||||
TypeKind::ElabType(_) => true,
|
||||
TypeKind::Logic(data) => {
|
||||
matches!(data.value, ElabValue::Concrete(_))
|
||||
}
|
||||
|
|
|
@ -15,8 +15,8 @@ use crate::parser::{
|
|||
/// a block that is a single expression
|
||||
#[derive(Debug, Clone)]
|
||||
pub struct ExpressionBlock<'a> {
|
||||
assignments: Vec<(Token<'a>, Expression<'a>)>,
|
||||
value: Expression<'a>,
|
||||
pub assignments: Vec<(Token<'a>, Expression<'a>)>,
|
||||
pub value: Expression<'a>,
|
||||
}
|
||||
|
||||
/// an expression that contains a block
|
||||
|
|
|
@ -8,11 +8,11 @@ use super::{
|
|||
use nom::{
|
||||
branch::alt,
|
||||
bytes::complete::{is_not, tag, take_until},
|
||||
character::complete::{anychar, digit1, line_ending},
|
||||
combinator::{consumed, map, recognize},
|
||||
character::complete::{alpha1, anychar, digit1, line_ending},
|
||||
combinator::{consumed, map, not, peek, recognize},
|
||||
error::ParseError,
|
||||
multi::many0,
|
||||
sequence::tuple,
|
||||
sequence::{terminated, tuple},
|
||||
InputTake,
|
||||
};
|
||||
use std::fmt;
|
||||
|
@ -227,6 +227,7 @@ fn lex_punctuation(input: Span) -> IResult<Span, Token> {
|
|||
|
||||
fn lex_keywords(input: Span) -> IResult<Span, Token> {
|
||||
map(
|
||||
terminated(
|
||||
consumed(alt((
|
||||
map(tag("module"), |_| TokenKind::Module),
|
||||
map(tag("assign"), |_| TokenKind::Assign),
|
||||
|
@ -237,6 +238,8 @@ fn lex_keywords(input: Span) -> IResult<Span, Token> {
|
|||
map(tag("let"), |_| TokenKind::Let),
|
||||
map(tag("struct"), |_| TokenKind::Struct),
|
||||
))),
|
||||
peek(not(alt((alpha1, tag("_"))))),
|
||||
),
|
||||
|(span, kind)| Token::new(span, kind),
|
||||
)(input)
|
||||
}
|
||||
|
|
Loading…
Reference in New Issue