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2e93403de0375f7b135fc4d88da6e869a85eacee
hakorune/archive/codex-solutions/builder_calls-codex-solution.rs
Selfhosting Dev 2e93403de0 phase15: implement Phase S root treatment for break control flow 
🔧 **Phase S (Immediate Stabilization) Implementation**
- Create control flow utilities module (src/mir/utils/)
- Refactor loop_builder.rs duplicated code to utilities
- Fix PHI incoming predecessor capture per ChatGPT Pro analysis

📊 **AI Collaborative Analysis Complete**
- Task agent: Root cause identification
- Gemini: Strategic 3-phase approach
- codex: Advanced type inference solution (archived)
- ChatGPT Pro: Definitive staged treatment strategy

🗂️ **Documentation & Archive**
- Strategy document: docs/development/strategies/break-control-flow-strategy.md
- codex solutions: archive/codex-solutions/ (100+ lines changes)
- Update CLAUDE.md with 2025-09-23 progress

 **Expected Impact**
- Resolve collect_prints null return issue
- Eliminate code duplication (4 locations unified)
- Foundation for Phase M (PHI unification) and Phase L (BuildOutcome)

🎯 Generated with [Claude Code](https://claude.ai/code)

Co-Authored-By: Claude <noreply@anthropic.com>
2025-09-23 07:13:32 +09:00

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// Extracted call-related builders from builder.rs to keep files lean
use super::{Effect, EffectMask, FunctionSignature, MirInstruction, MirType, ValueId};
use crate::ast::{ASTNode, LiteralValue, MethodCallExpr};
fn contains_value_return(nodes: &[ASTNode]) -> bool {
fn node_has_value_return(node: &ASTNode) -> bool {
match node {
ASTNode::Return { value: Some(_), .. } => true,
ASTNode::If { then_body, else_body, .. } => {
contains_value_return(then_body)
|| else_body
.as_ref()
.map_or(false, |body| contains_value_return(body))
}
ASTNode::Loop { body, .. } => contains_value_return(body),
ASTNode::TryCatch {
try_body,
catch_clauses,
finally_body,
..
} => {
contains_value_return(try_body)
|| catch_clauses
.iter()
.any(|clause| contains_value_return(&clause.body))
|| finally_body
.as_ref()
.map_or(false, |body| contains_value_return(body))
}
ASTNode::Program { statements, .. } => contains_value_return(statements),
ASTNode::ScopeBox { body, .. } => contains_value_return(body),
ASTNode::FunctionDeclaration { body, .. } => contains_value_return(body),
_ => false,
}
}
nodes.iter().any(node_has_value_return)
}
use crate::mir::{slot_registry, TypeOpKind};
impl super::MirBuilder {
/// Try handle math.* function in function-style (sin/cos/abs/min/max).
/// Returns Some(result) if handled, otherwise None.
fn try_handle_math_function(
&mut self,
name: &str,
raw_args: Vec<ASTNode>,
) -> Option<Result<ValueId, String>> {
let is_math_func = matches!(name, "sin" | "cos" | "abs" | "min" | "max");
if !is_math_func {
return None;
}
// Build numeric args directly for math.* to preserve f64 typing
let mut math_args: Vec<ValueId> = Vec::new();
for a in raw_args.into_iter() {
match a {
ASTNode::New { class, arguments, .. } if class == "FloatBox" && arguments.len() == 1 => {
match self.build_expression(arguments[0].clone()) { v @ Ok(_) => math_args.push(v.unwrap()), err @ Err(_) => return Some(err), }
}
ASTNode::New { class, arguments, .. } if class == "IntegerBox" && arguments.len() == 1 => {
let iv = match self.build_expression(arguments[0].clone()) { Ok(v) => v, Err(e) => return Some(Err(e)) };
let fv = self.value_gen.next();
if let Err(e) = self.emit_instruction(MirInstruction::TypeOp { dst: fv, op: TypeOpKind::Cast, value: iv, ty: MirType::Float }) { return Some(Err(e)); }
math_args.push(fv);
}
ASTNode::Literal { value: LiteralValue::Float(_), .. } => {
match self.build_expression(a) { v @ Ok(_) => math_args.push(v.unwrap()), err @ Err(_) => return Some(err), }
}
other => {
match self.build_expression(other) { v @ Ok(_) => math_args.push(v.unwrap()), err @ Err(_) => return Some(err), }
}
}
}
// new MathBox()
let math_recv = self.value_gen.next();
if let Err(e) = self.emit_instruction(MirInstruction::NewBox { dst: math_recv, box_type: "MathBox".to_string(), args: vec![] }) { return Some(Err(e)); }
self.value_origin_newbox.insert(math_recv, "MathBox".to_string());
// birth()
let birt_mid = slot_registry::resolve_slot_by_type_name("MathBox", "birth");
if let Err(e) = self.emit_box_or_plugin_call(None, math_recv, "birth".to_string(), birt_mid, vec![], EffectMask::READ) { return Some(Err(e)); }
// call method
let dst = self.value_gen.next();
if let Err(e) = self.emit_box_or_plugin_call(Some(dst), math_recv, name.to_string(), None, math_args, EffectMask::READ) { return Some(Err(e)); }
Some(Ok(dst))
}
/// Try handle env.* extern methods like env.console.log via FieldAccess(object, field).
fn try_handle_env_method(
&mut self,
object: &ASTNode,
method: &str,
arguments: &Vec<ASTNode>,
) -> Option<Result<ValueId, String>> {
let ASTNode::FieldAccess { object: env_obj, field: env_field, .. } = object else { return None; };
if let ASTNode::Variable { name: env_name, .. } = env_obj.as_ref() {
if env_name != "env" { return None; }
// Build arguments once
let mut arg_values = Vec::new();
for arg in arguments {
match self.build_expression(arg.clone()) { Ok(v) => arg_values.push(v), Err(e) => return Some(Err(e)) }
}
let iface = env_field.as_str();
let m = method;
let mut extern_call = |iface_name: &str, method_name: &str, effects: EffectMask, returns: bool| -> Result<ValueId, String> {
let result_id = self.value_gen.next();
self.emit_instruction(MirInstruction::ExternCall { dst: if returns { Some(result_id) } else { None }, iface_name: iface_name.to_string(), method_name: method_name.to_string(), args: arg_values.clone(), effects })?;
if returns {
Ok(result_id)
} else {
let void_id = self.value_gen.next();
self.emit_instruction(MirInstruction::Const { dst: void_id, value: super::ConstValue::Void })?;
Ok(void_id)
}
};
if let Some((iface_name, method_name, effects, returns)) =
Self::get_env_method_spec(iface, m)
{
return Some(extern_call(&iface_name, &method_name, effects, returns));
}
return None;
}
None
}
/// Table-like spec for env.* methods. Returns iface_name, method_name, effects, returns.
fn get_env_method_spec(
iface: &str,
method: &str,
) -> Option<(String, String, EffectMask, bool)> {
// This match is the table. Keep it small and explicit.
match (iface, method) {
("future", "delay") => Some(("env.future".to_string(), "delay".to_string(), EffectMask::READ.add(Effect::Io), true)),
("task", "currentToken") => Some(("env.task".to_string(), "currentToken".to_string(), EffectMask::READ, true)),
("task", "cancelCurrent") => Some(("env.task".to_string(), "cancelCurrent".to_string(), EffectMask::IO, false)),
("console", "log") => Some(("env.console".to_string(), "log".to_string(), EffectMask::IO, false)),
("console", "readLine") => Some(("env.console".to_string(), "readLine".to_string(), EffectMask::IO, true)),
("canvas", m) if matches!(m, "fillRect" | "fillText") => Some(("env.canvas".to_string(), method.to_string(), EffectMask::IO, false)),
_ => None,
}
}
/// Try direct static call for `me` in static box
fn try_handle_me_direct_call(
&mut self,
method: &str,
arguments: &Vec<ASTNode>,
) -> Option<Result<ValueId, String>> {
let Some(cls_name) = self.current_static_box.clone() else { return None; };
// Build args
let mut arg_values = Vec::new();
for a in arguments {
match self.build_expression(a.clone()) { Ok(v) => arg_values.push(v), Err(e) => return Some(Err(e)) }
}
let result_id = self.value_gen.next();
let fun_name = format!("{}.{}{}", cls_name, method, format!("/{}", arg_values.len()));
let fun_val = self.value_gen.next();
if let Err(e) = self.emit_instruction(MirInstruction::Const { dst: fun_val, value: super::ConstValue::String(fun_name) }) { return Some(Err(e)); }
if let Err(e) = self.emit_instruction(MirInstruction::Call { dst: Some(result_id), func: fun_val, args: arg_values, effects: EffectMask::READ.add(Effect::ReadHeap) }) { return Some(Err(e)); }
Some(Ok(result_id))
}
// Build function call: name(args)
pub(super) fn build_function_call(
&mut self,
name: String,
args: Vec<ASTNode>,
) -> Result<ValueId, String> {
// Minimal TypeOp wiring via function-style: isType(value, "Type"), asType(value, "Type")
if (name == "isType" || name == "asType") && args.len() == 2 {
if let Some(type_name) = Self::extract_string_literal(&args[1]) {
let val = self.build_expression(args[0].clone())?;
let ty = Self::parse_type_name_to_mir(&type_name);
let dst = self.value_gen.next();
let op = if name == "isType" {
TypeOpKind::Check
} else {
TypeOpKind::Cast
};
self.emit_instruction(MirInstruction::TypeOp {
dst,
op,
value: val,
ty,
})?;
return Ok(dst);
}
}
// Keep original args for special handling (math.*)
let raw_args = args.clone();
if let Some(res) = self.try_handle_math_function(&name, raw_args) { return res; }
let dst = self.value_gen.next();
// Default: call via fully-qualified function name string
let mut arg_values = Vec::new();
for a in args {
arg_values.push(self.build_expression(a)?);
}
let fun_val = self.value_gen.next();
self.emit_instruction(MirInstruction::Const {
dst: fun_val,
value: super::ConstValue::String(name),
})?;
self.emit_instruction(MirInstruction::Call {
dst: Some(dst),
func: fun_val,
args: arg_values,
effects: EffectMask::READ.add(Effect::ReadHeap),
})?;
Ok(dst)
}
// Build method call: object.method(arguments)
pub(super) fn build_method_call(
&mut self,
object: ASTNode,
method: String,
arguments: Vec<ASTNode>,
) -> Result<ValueId, String> {
// Minimal TypeOp wiring via method-style syntax: value.is("Type") / value.as("Type")
if (method == "is" || method == "as") && arguments.len() == 1 {
if let Some(type_name) = Self::extract_string_literal(&arguments[0]) {
let object_value = self.build_expression(object.clone())?;
let mir_ty = Self::parse_type_name_to_mir(&type_name);
let dst = self.value_gen.next();
let op = if method == "is" {
TypeOpKind::Check
} else {
TypeOpKind::Cast
};
self.emit_instruction(MirInstruction::TypeOp {
dst,
op,
value: object_value,
ty: mir_ty,
})?;
return Ok(dst);
}
}
if let Some(res) = self.try_handle_env_method(&object, &method, &arguments) { return res; }
// If object is `me` within a static box, lower to direct Call: BoxName.method/N
if let ASTNode::Me { .. } = object {
if let Some(res) = self.try_handle_me_direct_call(&method, &arguments) { return res; }
}
// Build the object expression (wrapper allows simple access if needed in future)
let _mc = MethodCallExpr { object: Box::new(object.clone()), method: method.clone(), arguments: arguments.clone(), span: crate::ast::Span::unknown() };
let object_value = self.build_expression(object.clone())?;
// Secondary interception for is/as
if (method == "is" || method == "as") && arguments.len() == 1 {
if let Some(type_name) = Self::extract_string_literal(&arguments[0]) {
let mir_ty = Self::parse_type_name_to_mir(&type_name);
let dst = self.value_gen.next();
let op = if method == "is" {
TypeOpKind::Check
} else {
TypeOpKind::Cast
};
self.emit_instruction(MirInstruction::TypeOp {
dst,
op,
value: object_value,
ty: mir_ty,
})?;
return Ok(dst);
}
}
// Fallback: generic plugin invoke
let mut arg_values: Vec<ValueId> = Vec::new();
for a in &arguments {
arg_values.push(self.build_expression(a.clone())?);
}
let result_id = self.value_gen.next();
self.emit_box_or_plugin_call(
Some(result_id),
object_value,
method,
None,
arg_values,
EffectMask::READ.add(Effect::ReadHeap),
)?;
Ok(result_id)
}
// Map a user-facing type name to MIR type
pub(super) fn parse_type_name_to_mir(name: &str) -> super::MirType {
match name {
// Primitive families
"Integer" | "Int" | "I64" | "IntegerBox" | "IntBox" => super::MirType::Integer,
"Float" | "F64" | "FloatBox" => super::MirType::Float,
"Bool" | "Boolean" | "BoolBox" => super::MirType::Bool,
"String" | "StringBox" => super::MirType::String,
"Void" | "Unit" => super::MirType::Void,
// Fallback: treat as user box type
other => super::MirType::Box(other.to_string()),
}
}
// Extract string literal from AST node if possible
pub(super) fn extract_string_literal(node: &ASTNode) -> Option<String> {
let mut cur = node;
loop {
match cur {
ASTNode::Literal {
value: LiteralValue::String(s),
..
} => return Some(s.clone()),
ASTNode::New {
class, arguments, ..
} if class == "StringBox" && arguments.len() == 1 => {
cur = &arguments[0];
continue;
}
_ => return None,
}
}
}
// Build from expression: from Parent.method(arguments)
pub(super) fn build_from_expression(
&mut self,
parent: String,
method: String,
arguments: Vec<ASTNode>,
) -> Result<ValueId, String> {
let mut arg_values = Vec::new();
for arg in arguments {
arg_values.push(self.build_expression(arg)?);
}
let parent_value = self.value_gen.next();
self.emit_instruction(MirInstruction::Const {
dst: parent_value,
value: super::ConstValue::String(parent),
})?;
let result_id = self.value_gen.next();
self.emit_box_or_plugin_call(
Some(result_id),
parent_value,
method,
None,
arg_values,
EffectMask::READ.add(Effect::ReadHeap),
)?;
Ok(result_id)
}
// Lower a box method into a standalone MIR function (with `me` parameter)
pub(super) fn lower_method_as_function(
&mut self,
func_name: String,
box_name: String,
params: Vec<String>,
body: Vec<ASTNode>,
) -> Result<(), String> {
let mut param_types = Vec::new();
param_types.push(MirType::Box(box_name.clone()));
for _ in &params {
param_types.push(MirType::Unknown);
}
let returns_value = contains_value_return(&body);
let ret_ty = if returns_value {
MirType::Unknown
} else {
MirType::Void
};
let signature = FunctionSignature {
name: func_name,
params: param_types,
return_type: ret_ty,
effects: EffectMask::READ.add(Effect::ReadHeap),
};
let entry = self.block_gen.next();
let function = super::MirFunction::new(signature, entry);
let saved_function = self.current_function.take();
let saved_block = self.current_block.take();
let saved_var_map = std::mem::take(&mut self.variable_map);
let saved_value_gen = self.value_gen.clone();
self.value_gen.reset();
self.current_function = Some(function);
self.current_block = Some(entry);
self.ensure_block_exists(entry)?;
if let Some(ref mut f) = self.current_function {
let me_id = self.value_gen.next();
f.params.push(me_id);
self.variable_map.insert("me".to_string(), me_id);
self.value_origin_newbox.insert(me_id, box_name.clone());
for p in &params {
let pid = self.value_gen.next();
f.params.push(pid);
self.variable_map.insert(p.clone(), pid);
}
}
let program_ast = ASTNode::Program {
statements: body,
span: crate::ast::Span::unknown(),
};
let _last = self.build_expression(program_ast)?;
if !returns_value && !self.is_current_block_terminated() {
let void_val = self.value_gen.next();
self.emit_instruction(MirInstruction::Const {
dst: void_val,
value: super::ConstValue::Void,
})?;
self.emit_instruction(MirInstruction::Return {
value: Some(void_val),
})?;
}
if let Some(ref mut f) = self.current_function {
if returns_value
&& matches!(f.signature.return_type, MirType::Void | MirType::Unknown)
{
let mut inferred: Option<MirType> = None;
'search: for (_bid, bb) in f.blocks.iter() {
for inst in bb.instructions.iter() {
if let MirInstruction::Return { value: Some(v) } = inst {
if let Some(mt) = self.value_types.get(v).cloned() {
inferred = Some(mt);
break 'search;
}
}
}
if let Some(MirInstruction::Return { value: Some(v) }) = &bb.terminator {
if let Some(mt) = self.value_types.get(v).cloned() {
inferred = Some(mt);
break;
}
}
}
if let Some(mt) = inferred {
f.signature.return_type = mt;
}
}
}
let finalized_function = self.current_function.take().unwrap();
if let Some(ref mut module) = self.current_module {
module.add_function(finalized_function);
}
self.current_function = saved_function;
self.current_block = saved_block;
self.variable_map = saved_var_map;
self.value_gen = saved_value_gen;
Ok(())
}
// Lower a static method body into a standalone MIR function (no `me` parameter)
pub(super) fn lower_static_method_as_function(
&mut self,
func_name: String,
params: Vec<String>,
body: Vec<ASTNode>,
) -> Result<(), String> {
let mut param_types = Vec::new();
for _ in &params {
param_types.push(MirType::Unknown);
}
let returns_value = contains_value_return(&body);
let ret_ty = if returns_value {
MirType::Unknown
} else {
MirType::Void
};
let signature = FunctionSignature {
name: func_name,
params: param_types,
return_type: ret_ty,
effects: EffectMask::READ.add(Effect::ReadHeap),
};
let entry = self.block_gen.next();
let function = super::MirFunction::new(signature, entry);
let saved_function = self.current_function.take();
let saved_block = self.current_block.take();
let saved_var_map = std::mem::take(&mut self.variable_map);
let saved_value_gen = self.value_gen.clone();
self.value_gen.reset();
self.current_function = Some(function);
self.current_block = Some(entry);
self.ensure_block_exists(entry)?;
if let Some(ref mut f) = self.current_function {
for p in &params {
let pid = self.value_gen.next();
f.params.push(pid);
self.variable_map.insert(p.clone(), pid);
}
}
let program_ast = ASTNode::Program {
statements: body,
span: crate::ast::Span::unknown(),
};
let _last = self.build_expression(program_ast)?;
if !returns_value {
if let Some(ref mut f) = self.current_function {
if let Some(block) = f.get_block(self.current_block.unwrap()) {
if !block.is_terminated() {
let void_val = self.value_gen.next();
self.emit_instruction(MirInstruction::Const {
dst: void_val,
value: super::ConstValue::Void,
})?;
self.emit_instruction(MirInstruction::Return {
value: Some(void_val),
})?;
}
}
}
}
if let Some(ref mut f) = self.current_function {
if returns_value
&& matches!(f.signature.return_type, MirType::Void | MirType::Unknown)
{
let mut inferred: Option<MirType> = None;
'search: for (_bid, bb) in f.blocks.iter() {
for inst in bb.instructions.iter() {
if let MirInstruction::Return { value: Some(v) } = inst {
if let Some(mt) = self.value_types.get(v).cloned() {
inferred = Some(mt);
break 'search;
}
}
}
if let Some(MirInstruction::Return { value: Some(v) }) = &bb.terminator {
if let Some(mt) = self.value_types.get(v).cloned() {
inferred = Some(mt);
break;
}
}
}
if let Some(mt) = inferred {
f.signature.return_type = mt;
}
}
}
let finalized = self.current_function.take().unwrap();
if let Some(ref mut module) = self.current_module {
module.add_function(finalized);
}
self.current_function = saved_function;
self.current_block = saved_block;
self.variable_map = saved_var_map;
self.value_gen = saved_value_gen;
Ok(())
}
}
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