#![allow(dead_code)]
use std::collections::{BTreeMap, BTreeSet};
use std::fmt::Write;
use calcit::calcit::{CalcitProc, CalcitSyntax, CalcitTypeAnnotation, ProcTypeSignature, SchemaKind, SyntaxTypeSignature};
use calcit::cli_args::{CheckTypesCommand, WeakTypesCommand};
use calcit::snapshot;
use cirru_parser::Cirru;
#[derive(Debug, Clone, Copy, PartialEq, Eq)]
pub enum DefKind {
Data,
Fn,
Macro,
Proc,
Syntax,
Other,
}
impl DefKind {
fn as_str(self) -> &'static str {
match self {
DefKind::Data => "data",
DefKind::Fn => "fn",
DefKind::Macro => "macro",
DefKind::Proc => "proc",
DefKind::Syntax => "syntax",
DefKind::Other => "other",
}
}
}
#[derive(Debug, Clone, Copy, PartialEq, Eq, PartialOrd, Ord)]
pub enum CoverageLevel {
None,
Partial,
Full,
}
impl CoverageLevel {
fn as_str(self) -> &'static str {
match self {
CoverageLevel::None => "none",
CoverageLevel::Partial => "partial",
CoverageLevel::Full => "full",
}
}
}
#[derive(Debug, Clone)]
pub struct TypeCoverageRow {
pub ns: String,
pub def: String,
pub kind: DefKind,
pub level: CoverageLevel,
pub params: Vec<String>,
pub param_annotations: BTreeMap<String, Vec<String>>,
pub return_type_hints: Vec<String>,
pub data_type: Option<String>,
pub schema_issues: Vec<String>,
}
#[derive(Debug, Clone, Copy, PartialEq, Eq, PartialOrd, Ord)]
pub enum WeakTypeKind {
SchemaDynamic,
CodeDynamic,
CodeNil,
}
impl WeakTypeKind {
fn as_str(&self) -> &'static str {
match self {
Self::SchemaDynamic => "schema-dynamic",
Self::CodeDynamic => "code-dynamic",
Self::CodeNil => "code-nil",
}
}
pub fn all() -> BTreeSet<Self> {
BTreeSet::from([Self::SchemaDynamic, Self::CodeDynamic, Self::CodeNil])
}
}
#[derive(Debug, Clone, PartialEq, Eq)]
pub struct WeakTypeOccurrence {
pub kind: WeakTypeKind,
pub detail: String,
pub path: String,
}
#[derive(Debug, Clone, PartialEq, Eq)]
pub struct WeakTypeRow {
pub ns: String,
pub def: String,
pub occurrences: Vec<WeakTypeOccurrence>,
}
pub fn parse_weak_type_kinds(raw: &str) -> Result<BTreeSet<WeakTypeKind>, String> {
let mut selected = BTreeSet::new();
for item in raw.split(',').map(str::trim).filter(|s| !s.is_empty()) {
let kind = match item {
"schema-dynamic" => WeakTypeKind::SchemaDynamic,
"code-dynamic" => WeakTypeKind::CodeDynamic,
"code-nil" => WeakTypeKind::CodeNil,
other => {
return Err(format!(
"Unknown weak-type filter `{other}`. Expected comma-separated values from: schema-dynamic, code-dynamic, code-nil"
));
}
};
selected.insert(kind);
}
if selected.is_empty() {
return Err("Weak-type filter cannot be empty. Use comma-separated values from: schema-dynamic, code-dynamic, code-nil".to_owned());
}
Ok(selected)
}
fn format_cirru_path(root: &str, path: &[usize]) -> String {
let mut rendered = root.to_owned();
for idx in path {
rendered.push('.');
rendered.push_str(&idx.to_string());
}
rendered
}
fn weak_type_detail(kind: WeakTypeKind, detail: &str) -> String {
format!("{}:{}", kind.as_str(), detail)
}
pub fn extract_schema_dynamic_position(detail: &str) -> Option<String> {
let mut parts = detail.split(':');
match (parts.next(), parts.next()) {
(Some("schema-dynamic"), Some(position)) => Some(position.to_owned()),
_ => None,
}
}
pub fn extract_schema_dynamic_shape(detail: &str) -> Option<String> {
let mut parts = detail.split(':');
match (parts.next(), parts.next(), parts.next()) {
(Some("schema-dynamic"), Some(_position), Some(shape)) => {
let mut result = shape.to_owned();
for part in parts {
result.push(':');
result.push_str(part);
}
Some(result)
}
_ => None,
}
}
pub fn extract_schema_dynamic_family(detail: &str) -> Option<String> {
let shape = extract_schema_dynamic_shape(detail)?;
let family = shape.split(':').next()?;
let family = family.split('-').next()?;
Some(family.to_owned())
}
fn extend_schema_dynamic_detail(detail: &str, segment: &str) -> String {
format!("{detail}:{segment}")
}
fn push_weak_type_occurrence(
occurrences: &mut Vec<WeakTypeOccurrence>,
kind: WeakTypeKind,
detail: impl Into<String>,
path: impl Into<String>,
) {
occurrences.push(WeakTypeOccurrence {
kind,
detail: detail.into(),
path: path.into(),
});
}
fn scan_schema_dynamic_annotation(
annotation: &CalcitTypeAnnotation,
path: &str,
detail: &str,
occurrences: &mut Vec<WeakTypeOccurrence>,
) {
match annotation {
CalcitTypeAnnotation::Dynamic => {
push_weak_type_occurrence(
occurrences,
WeakTypeKind::SchemaDynamic,
weak_type_detail(WeakTypeKind::SchemaDynamic, detail),
path.to_owned(),
);
}
CalcitTypeAnnotation::List(inner)
| CalcitTypeAnnotation::Set(inner)
| CalcitTypeAnnotation::Ref(inner)
| CalcitTypeAnnotation::Variadic(inner)
| CalcitTypeAnnotation::Optional(inner) => {
let segment = match annotation {
CalcitTypeAnnotation::List(_) => "list-item",
CalcitTypeAnnotation::Set(_) => "set-item",
CalcitTypeAnnotation::Ref(_) => "ref-item",
CalcitTypeAnnotation::Variadic(_) => "variadic-item",
CalcitTypeAnnotation::Optional(_) => "optional-item",
_ => unreachable!("composite item annotation should be covered by the match arm"),
};
let nested_detail = extend_schema_dynamic_detail(detail, segment);
scan_schema_dynamic_annotation(inner, &format!("{path}.item"), &nested_detail, occurrences);
}
CalcitTypeAnnotation::Map(key, value) => {
let key_detail = extend_schema_dynamic_detail(detail, "map-key");
let value_detail = extend_schema_dynamic_detail(detail, "map-value");
scan_schema_dynamic_annotation(key, &format!("{path}.key"), &key_detail, occurrences);
scan_schema_dynamic_annotation(value, &format!("{path}.value"), &value_detail, occurrences);
}
CalcitTypeAnnotation::Fn(fn_annot) => {
for (idx, arg) in fn_annot.arg_types.iter().enumerate() {
let arg_detail = extend_schema_dynamic_detail(detail, "fn-arg");
scan_schema_dynamic_annotation(arg, &format!("{path}.args.{idx}"), &arg_detail, occurrences);
}
let return_detail = extend_schema_dynamic_detail(detail, "fn-return");
scan_schema_dynamic_annotation(&fn_annot.return_type, &format!("{path}.return"), &return_detail, occurrences);
if let Some(rest) = &fn_annot.rest_type {
let rest_detail = extend_schema_dynamic_detail(detail, "fn-rest");
scan_schema_dynamic_annotation(rest, &format!("{path}.rest"), &rest_detail, occurrences);
}
}
CalcitTypeAnnotation::Struct(_, args) | CalcitTypeAnnotation::Enum(_, args) | CalcitTypeAnnotation::TypeRef(_, args) => {
for (idx, arg) in args.iter().enumerate() {
let type_arg_detail = extend_schema_dynamic_detail(detail, "type-arg");
scan_schema_dynamic_annotation(arg, &format!("{path}.type-arg.{idx}"), &type_arg_detail, occurrences);
}
}
_ => {}
}
}
#[derive(Debug, Clone)]
struct WeakCodeParent {
head: Option<String>,
child_index: usize,
}
fn classify_code_dynamic(parent: Option<&WeakCodeParent>) -> &'static str {
match parent.and_then(|it| it.head.as_deref()) {
Some("assert-type") => "assert-type",
Some("hint-fn") => "hint-fn",
Some("::") => "schema-tag",
Some("defstruct") => "defstruct",
Some("defenum") => "defenum",
Some("deftrait") => "deftrait",
Some("quote") | Some("quasiquote") => "quoted",
Some("[]") => "list-item",
_ => "literal",
}
}
fn classify_code_nil(parent: Option<&WeakCodeParent>) -> &'static str {
match parent.and_then(|it| it.head.as_deref()) {
Some("if") if parent.is_some_and(|it| it.child_index == 2) => "if-then",
Some("if") if parent.is_some_and(|it| it.child_index == 3) => "if-else",
Some("let") | Some("&let") => "let-binding",
Some("do") => "do-step",
Some("[]") => "list-item",
Some("{}") | Some("&{}") | Some("#{}") => "collection-item",
Some("cond") | Some("case") | Some("case-default") => "branch",
_ => "literal",
}
}
fn scan_cirru_weak_types(
node: &Cirru,
root: &str,
path: &mut Vec<usize>,
parent: Option<&WeakCodeParent>,
selected: &BTreeSet<WeakTypeKind>,
occurrences: &mut Vec<WeakTypeOccurrence>,
) {
match node {
Cirru::Leaf(text) => {
if text.as_ref() == ":dynamic" && root == "schema" && selected.contains(&WeakTypeKind::SchemaDynamic) {
push_weak_type_occurrence(
occurrences,
WeakTypeKind::SchemaDynamic,
weak_type_detail(WeakTypeKind::SchemaDynamic, "raw-schema"),
format_cirru_path(root, path),
);
} else if text.as_ref() == ":dynamic" && root == "code" && selected.contains(&WeakTypeKind::CodeDynamic) {
push_weak_type_occurrence(
occurrences,
WeakTypeKind::CodeDynamic,
weak_type_detail(WeakTypeKind::CodeDynamic, classify_code_dynamic(parent)),
format_cirru_path(root, path),
);
} else if text.as_ref() == "nil" && root == "code" && selected.contains(&WeakTypeKind::CodeNil) {
push_weak_type_occurrence(
occurrences,
WeakTypeKind::CodeNil,
weak_type_detail(WeakTypeKind::CodeNil, classify_code_nil(parent)),
format_cirru_path(root, path),
);
}
}
Cirru::List(items) => {
let head = items.first().and_then(|item| match item {
Cirru::Leaf(text) => Some(text.to_string()),
_ => None,
});
for (idx, item) in items.iter().enumerate() {
path.push(idx);
let next_parent = WeakCodeParent {
head: head.clone(),
child_index: idx,
};
scan_cirru_weak_types(item, root, path, Some(&next_parent), selected, occurrences);
path.pop();
}
}
}
}
pub fn analyze_weak_types_entry(
ns: &str,
def_name: &str,
entry: &snapshot::CodeEntry,
selected: &BTreeSet<WeakTypeKind>,
) -> Option<WeakTypeRow> {
let mut occurrences: Vec<WeakTypeOccurrence> = vec![];
if matches!(entry.schema.as_ref(), CalcitTypeAnnotation::Dynamic) && selected.contains(&WeakTypeKind::SchemaDynamic) {
push_weak_type_occurrence(
&mut occurrences,
WeakTypeKind::SchemaDynamic,
weak_type_detail(WeakTypeKind::SchemaDynamic, "root"),
"schema".to_owned(),
);
} else if let CalcitTypeAnnotation::Fn(fn_annot) = entry.schema.as_ref() {
if selected.contains(&WeakTypeKind::SchemaDynamic) {
for (idx, arg) in fn_annot.arg_types.iter().enumerate() {
scan_schema_dynamic_annotation(arg, &format!("schema.args.{idx}"), "arg", &mut occurrences);
}
scan_schema_dynamic_annotation(&fn_annot.return_type, "schema.return", "return", &mut occurrences);
if let Some(rest) = &fn_annot.rest_type {
scan_schema_dynamic_annotation(rest, "schema.rest", "rest", &mut occurrences);
}
}
} else if selected.contains(&WeakTypeKind::SchemaDynamic) {
let before = occurrences.len();
scan_schema_dynamic_annotation(entry.schema.as_ref(), "schema", "root", &mut occurrences);
if occurrences.len() == before
&& let Ok(schema_cirru) = snapshot::schema_edn_to_cirru(&entry.schema.to_type_edn())
{
let mut path = vec![];
scan_cirru_weak_types(&schema_cirru, "schema", &mut path, None, selected, &mut occurrences);
}
}
let mut code_path = vec![];
scan_cirru_weak_types(&entry.code, "code", &mut code_path, None, selected, &mut occurrences);
if occurrences.is_empty() {
None
} else {
Some(WeakTypeRow {
ns: ns.to_owned(),
def: def_name.to_owned(),
occurrences,
})
}
}
pub fn run_weak_types_report(options: &WeakTypesCommand, snapshot: &snapshot::Snapshot, out: &mut String) -> Result<(), String> {
if let Some(ns) = &options.ns
&& !snapshot.files.contains_key(ns)
{
return Err(format!("Namespace not found: {ns}"));
}
let selected = options
.only
.as_deref()
.map(parse_weak_type_kinds)
.transpose()?
.unwrap_or_else(WeakTypeKind::all);
let pkg = snapshot.package.as_str();
let explicit_scope = options.ns.is_some() || options.ns_prefix.is_some();
let mut rows: Vec<WeakTypeRow> = vec![];
for (ns, file) in &snapshot.files {
if let Some(exact) = &options.ns
&& ns != exact
{
continue;
}
if let Some(prefix) = &options.ns_prefix
&& !ns.starts_with(prefix)
{
continue;
}
if !(options.deps || explicit_scope || ns == pkg || ns.starts_with(&format!("{pkg}."))) {
continue;
}
for (def_name, entry) in &file.defs {
if let Some(row) = analyze_weak_types_entry(ns, def_name, entry, &selected) {
rows.push(row);
}
}
}
rows.sort_by(|a, b| a.ns.cmp(&b.ns).then(a.def.cmp(&b.def)));
if rows.is_empty() {
let _ = writeln!(out, "No weak type usage found in selected namespace scope.");
return Ok(());
}
let mut kind_count: BTreeMap<&'static str, usize> = BTreeMap::new();
let mut detail_count: BTreeMap<&'static str, BTreeMap<String, usize>> = BTreeMap::new();
let mut schema_shape_count: BTreeMap<String, usize> = BTreeMap::new();
let mut schema_shape_positions: BTreeMap<String, BTreeMap<String, usize>> = BTreeMap::new();
let mut schema_shape_defs: BTreeMap<String, BTreeMap<String, usize>> = BTreeMap::new();
let mut schema_shape_position_defs: BTreeMap<String, BTreeMap<String, usize>> = BTreeMap::new();
let mut schema_family_count: BTreeMap<String, usize> = BTreeMap::new();
let mut schema_family_positions: BTreeMap<String, BTreeMap<String, usize>> = BTreeMap::new();
let mut schema_family_defs: BTreeMap<String, BTreeMap<String, usize>> = BTreeMap::new();
let mut ns_set: BTreeSet<&str> = BTreeSet::new();
let mut def_count = 0usize;
for row in &rows {
def_count += 1;
ns_set.insert(row.ns.as_str());
let def_label = format!("{}/{}", row.ns, row.def);
for occurrence in &row.occurrences {
*kind_count.entry(occurrence.kind.as_str()).or_insert(0) += 1;
*detail_count
.entry(occurrence.kind.as_str())
.or_default()
.entry(occurrence.detail.clone())
.or_insert(0) += 1;
let schema_position = if occurrence.kind == WeakTypeKind::SchemaDynamic {
extract_schema_dynamic_position(&occurrence.detail)
} else {
None
};
if occurrence.kind == WeakTypeKind::SchemaDynamic
&& let Some(shape) = extract_schema_dynamic_shape(&occurrence.detail)
{
*schema_shape_count.entry(shape.clone()).or_insert(0) += 1;
if let Some(position) = &schema_position {
*schema_shape_positions
.entry(shape.clone())
.or_default()
.entry(position.clone())
.or_insert(0) += 1;
*schema_shape_position_defs
.entry(format!("{shape}@{position}"))
.or_default()
.entry(def_label.clone())
.or_insert(0) += 1;
}
*schema_shape_defs.entry(shape).or_default().entry(def_label.clone()).or_insert(0) += 1;
}
if occurrence.kind == WeakTypeKind::SchemaDynamic
&& let Some(family) = extract_schema_dynamic_family(&occurrence.detail)
{
*schema_family_count.entry(family.clone()).or_insert(0) += 1;
if let Some(position) = &schema_position {
*schema_family_positions
.entry(family.clone())
.or_default()
.entry(position.clone())
.or_insert(0) += 1;
}
*schema_family_defs.entry(family).or_default().entry(def_label.clone()).or_insert(0) += 1;
}
}
}
let _ = writeln!(out, "Weak type usage check");
let _ = writeln!(out, "- namespaces: {}", ns_set.len());
let _ = writeln!(out, "- defs with hits: {def_count}");
if let Some(raw) = &options.only {
let _ = writeln!(out, "- only: {raw}");
}
let _ = writeln!(
out,
"- hits: schema-dynamic={} code-dynamic={} code-nil={}",
kind_count.get("schema-dynamic").copied().unwrap_or(0),
kind_count.get("code-dynamic").copied().unwrap_or(0),
kind_count.get("code-nil").copied().unwrap_or(0)
);
let _ = writeln!(out, "- detail:");
for kind in ["schema-dynamic", "code-dynamic", "code-nil"] {
let _ = writeln!(out, " - {kind}");
if let Some(items) = detail_count.get(kind) {
for (detail, count) in items {
let _ = writeln!(out, " - {detail}={count}");
}
}
}
if !schema_shape_count.is_empty() {
let _ = writeln!(out, "- schema-shapes:");
for (shape, count) in &schema_shape_count {
let _ = writeln!(out, " - {shape}={count}");
}
let _ = writeln!(out, "- schema-shape-positions:");
for (shape, positions) in &schema_shape_positions {
let _ = writeln!(out, " - {shape}");
for (position, count) in positions {
let _ = writeln!(out, " - {position}={count}");
}
}
let _ = writeln!(out, "- schema-shape-defs:");
for (shape, defs) in &schema_shape_defs {
let _ = writeln!(out, " - {shape}");
let mut items = defs.iter().collect::<Vec<_>>();
items.sort_by(|(a_name, a_count), (b_name, b_count)| b_count.cmp(a_count).then(a_name.cmp(b_name)));
for (def_name, count) in items {
let _ = writeln!(out, " - {def_name}={count}");
}
}
let _ = writeln!(out, "- schema-shape-position-defs:");
for (shape_position, defs) in &schema_shape_position_defs {
let _ = writeln!(out, " - {shape_position}");
let mut items = defs.iter().collect::<Vec<_>>();
items.sort_by(|(a_name, a_count), (b_name, b_count)| b_count.cmp(a_count).then(a_name.cmp(b_name)));
for (def_name, count) in items {
let _ = writeln!(out, " - {def_name}={count}");
}
}
}
if !schema_family_count.is_empty() {
let _ = writeln!(out, "- schema-families:");
for (family, count) in &schema_family_count {
let _ = writeln!(out, " - {family}={count}");
}
let _ = writeln!(out, "- schema-family-positions:");
for (family, positions) in &schema_family_positions {
let _ = writeln!(out, " - {family}");
for (position, count) in positions {
let _ = writeln!(out, " - {position}={count}");
}
}
let _ = writeln!(out, "- schema-family-defs:");
for (family, defs) in &schema_family_defs {
let _ = writeln!(out, " - {family}");
let mut items = defs.iter().collect::<Vec<_>>();
items.sort_by(|(a_name, a_count), (b_name, b_count)| b_count.cmp(a_count).then(a_name.cmp(b_name)));
for (def_name, count) in items {
let _ = writeln!(out, " - {def_name}={count}");
}
}
}
let _ = writeln!(out,);
let mut current_ns: Option<&str> = None;
for row in &rows {
if current_ns != Some(row.ns.as_str()) {
let _ = writeln!(out, "namespace: {}", row.ns);
current_ns = Some(row.ns.as_str());
}
let _ = writeln!(out, "- def: {}", row.def);
for occurrence in &row.occurrences {
let _ = writeln!(
out,
" - {} ({}) @ {}",
occurrence.kind.as_str(),
occurrence.detail,
occurrence.path
);
}
let _ = writeln!(out,);
}
Ok(())
}
pub fn run_check_types_report(options: &CheckTypesCommand, snapshot: &snapshot::Snapshot, out: &mut String) -> Result<(), String> {
if let Some(ns) = &options.ns
&& !snapshot.files.contains_key(ns)
{
return Err(format!("Namespace not found: {ns}"));
}
let mut rows: Vec<TypeCoverageRow> = Vec::new();
let pkg = snapshot.package.as_str();
let explicit_scope = options.ns.is_some() || options.ns_prefix.is_some();
for (ns, file) in &snapshot.files {
if let Some(exact) = &options.ns
&& ns != exact
{
continue;
}
if let Some(prefix) = &options.ns_prefix
&& !ns.starts_with(prefix)
{
continue;
}
if !(options.deps || explicit_scope || ns == pkg || ns.starts_with(&format!("{pkg}."))) {
continue;
}
for (def_name, entry) in &file.defs {
rows.push(analyze_code_entry(ns, def_name, entry));
}
}
if let Some(raw) = &options.only {
let selected = parse_coverage_levels(raw)?;
rows.retain(|row| selected.contains(&row.level));
}
rows.sort_by(|a, b| {
a.ns
.cmp(&b.ns)
.then(a.level.cmp(&b.level))
.then(a.kind.as_str().cmp(b.kind.as_str()))
.then(a.def.cmp(&b.def))
});
if rows.is_empty() {
let _ = writeln!(out, "No definitions found in selected namespace scope.");
return Ok(());
}
let mut level_count: BTreeMap<&'static str, usize> = BTreeMap::new();
let mut kind_count: BTreeMap<&'static str, usize> = BTreeMap::new();
let mut ns_set: BTreeSet<String> = BTreeSet::new();
for row in &rows {
*level_count.entry(row.level.as_str()).or_insert(0) += 1;
*kind_count.entry(row.kind.as_str()).or_insert(0) += 1;
ns_set.insert(row.ns.clone());
}
let _ = writeln!(out, "Type coverage check");
let _ = writeln!(out, "- namespaces: {}", ns_set.len());
let _ = writeln!(out, "- defs: {}", rows.len());
if let Some(raw) = &options.only {
let _ = writeln!(out, "- only: {raw}");
}
let _ = writeln!(
out,
"- levels: full={} partial={} none={}",
level_count.get("full").copied().unwrap_or(0),
level_count.get("partial").copied().unwrap_or(0),
level_count.get("none").copied().unwrap_or(0)
);
let _ = writeln!(
out,
"- kinds: fn={} macro={} proc={} syntax={} data={} other={}",
kind_count.get("fn").copied().unwrap_or(0),
kind_count.get("macro").copied().unwrap_or(0),
kind_count.get("proc").copied().unwrap_or(0),
kind_count.get("syntax").copied().unwrap_or(0),
kind_count.get("data").copied().unwrap_or(0),
kind_count.get("other").copied().unwrap_or(0)
);
let _ = writeln!(out,);
let mut current_ns: Option<&str> = None;
for row in &rows {
let typed_params = count_typed_params(&row.params, &row.param_annotations);
let total_params = row.params.len();
if current_ns != Some(row.ns.as_str()) {
let _ = writeln!(out, "namespace: {}", row.ns);
current_ns = Some(row.ns.as_str());
}
let _ = writeln!(out, "- def: {}", row.def);
let _ = writeln!(out, " kind: {}", row.kind.as_str());
let _ = writeln!(out, " coverage: {}", row.level.as_str());
match row.kind {
DefKind::Data => {
let _ = writeln!(
out,
" data-type: {}",
row.data_type.clone().unwrap_or_else(|| "unknown".to_string())
);
}
DefKind::Fn => {
if row.return_type_hints.is_empty() {
let _ = writeln!(out, " return: (no hint)");
} else {
let _ = writeln!(out, " return:");
for item in &row.return_type_hints {
let _ = writeln!(out, " - {item}");
}
}
let _ = writeln!(out, " params ({typed_params}/{total_params}):");
if total_params == 0 {
let _ = writeln!(out, " - (no params)");
} else {
for name in &row.params {
match row.param_annotations.get(name) {
Some(types) if !types.is_empty() => {
let _ = writeln!(out, " - {} => {}", name, types.join(" | "));
}
_ => {
let _ = writeln!(out, " - {name} => (no assert-type)");
}
}
}
}
}
DefKind::Macro => {
let _ = writeln!(out, " params ({typed_params}/{total_params}):");
if total_params == 0 {
let _ = writeln!(out, " - (no params)");
} else {
for name in &row.params {
match row.param_annotations.get(name) {
Some(types) if !types.is_empty() => {
let _ = writeln!(out, " - {} => {}", name, types.join(" | "));
}
_ => {
let _ = writeln!(out, " - {name} => (no assert-type)");
}
}
}
}
}
DefKind::Proc => {
if row.return_type_hints.is_empty() {
let _ = writeln!(out, " return: (no hint)");
} else {
let _ = writeln!(out, " return:");
for item in &row.return_type_hints {
let _ = writeln!(out, " - {item}");
}
}
let _ = writeln!(out, " params ({typed_params}/{total_params}):");
if total_params == 0 {
let _ = writeln!(out, " - (no params)");
} else {
for name in &row.params {
match row.param_annotations.get(name) {
Some(types) if !types.is_empty() => {
let _ = writeln!(out, " - {} => {}", name, types.join(" | "));
}
_ => {
let _ = writeln!(out, " - {name} => (no assert-type)");
}
}
}
}
}
DefKind::Syntax => {
if row.return_type_hints.is_empty() {
let _ = writeln!(out, " return: (no hint)");
} else {
let _ = writeln!(out, " return:");
for item in &row.return_type_hints {
let _ = writeln!(out, " - {item}");
}
}
let _ = writeln!(out, " params ({typed_params}/{total_params}):");
if total_params == 0 {
let _ = writeln!(out, " - (no params)");
} else {
for name in &row.params {
match row.param_annotations.get(name) {
Some(types) if !types.is_empty() => {
let _ = writeln!(out, " - {} => {}", name, types.join(" | "));
}
_ => {
let _ = writeln!(out, " - {name} => (no assert-type)");
}
}
}
}
}
DefKind::Other => {
let _ = writeln!(out, " details: no type pattern recognized");
}
}
if !row.schema_issues.is_empty() {
let _ = writeln!(out, " schema-issues:");
for issue in &row.schema_issues {
let _ = writeln!(out, " - {issue}");
}
}
let _ = writeln!(out,);
}
Ok(())
}
fn analyze_builtin_syntax(def_name: &str, sig: &SyntaxTypeSignature) -> TypeCoverageRow {
let params: Vec<String> = sig.param_names.iter().map(|s| s.to_string()).collect();
let param_annotations: BTreeMap<String, Vec<String>> = sig
.param_types
.iter()
.zip(sig.param_names.iter())
.map(|(t, name)| {
let type_str = t.describe();
(name.to_string(), vec![type_str])
})
.collect();
let return_type_hints = vec![sig.return_type.describe()];
let typed_count = param_annotations.values().filter(|v| !v.is_empty()).count();
let level = if params.is_empty() || typed_count == params.len() {
CoverageLevel::Full
} else if typed_count > 0 {
CoverageLevel::Partial
} else {
CoverageLevel::None
};
TypeCoverageRow {
ns: calcit::calcit::CORE_NS.to_owned(),
def: def_name.to_owned(),
kind: DefKind::Syntax,
level,
params,
param_annotations,
return_type_hints,
data_type: None,
schema_issues: vec![],
}
}
fn analyze_builtin_proc(def_name: &str, sig: &ProcTypeSignature) -> TypeCoverageRow {
let params: Vec<String> = sig.arg_types.iter().enumerate().map(|(i, _)| format!("arg{i}")).collect();
let param_annotations: BTreeMap<String, Vec<String>> = sig
.arg_types
.iter()
.enumerate()
.map(|(i, t)| {
let name = format!("arg{i}");
let type_str = t.describe();
(name, vec![type_str])
})
.collect();
let return_type_hints = vec![sig.return_type.describe()];
let typed_count = param_annotations.values().filter(|v| !v.is_empty()).count();
let level = if params.is_empty() || typed_count == params.len() {
CoverageLevel::Full
} else if typed_count > 0 {
CoverageLevel::Partial
} else {
CoverageLevel::None
};
TypeCoverageRow {
ns: calcit::calcit::CORE_NS.to_owned(),
def: def_name.to_owned(),
kind: DefKind::Proc,
level,
params,
param_annotations,
return_type_hints,
data_type: None,
schema_issues: vec![],
}
}
pub fn validate_def_vs_schema(ns: &str, def_name: &str, code: &Cirru, schema: &CalcitTypeAnnotation) -> Vec<String> {
if matches!(code, Cirru::Leaf(s) if s.as_ref() == "&runtime-implementation") {
return vec![];
}
let CalcitTypeAnnotation::Fn(fn_annot) = schema else {
return vec![];
};
let Cirru::List(xs) = code else {
return vec![];
};
let code_kind = match xs.first() {
Some(Cirru::Leaf(s)) if s.as_ref() == "defn" => "defn",
Some(Cirru::Leaf(s)) if s.as_ref() == "defmacro" => "defmacro",
_ => return vec![], };
let mut issues: Vec<String> = vec![];
match (fn_annot.fn_kind, code_kind) {
(SchemaKind::Fn, "defmacro") => {
issues.push(format!("{ns}/{def_name}: schema :kind is :fn but code uses defmacro"));
}
(SchemaKind::Macro, "defn") => {
issues.push(format!("{ns}/{def_name}: schema :kind is :macro but code uses defn"));
}
_ => {}
}
if code_kind == "defmacro" {
return issues;
}
let (required_count, has_rest) = analyze_param_arity(xs.get(2));
let schema_required = fn_annot.arg_types.len();
let schema_has_rest = fn_annot.rest_type.is_some();
if required_count != schema_required {
issues.push(format!(
"{ns}/{def_name}: schema has {schema_required} required arg(s) but code has {required_count}"
));
}
if has_rest != schema_has_rest {
if has_rest {
issues.push(format!("{ns}/{def_name}: code has & rest param but schema has no :rest"));
} else {
issues.push(format!("{ns}/{def_name}: schema has :rest but code has no & param"));
}
}
issues
}
pub fn analyze_param_arity(args: Option<&Cirru>) -> (usize, bool) {
let Some(Cirru::List(xs)) = args else {
return (0, false);
};
let mut required = 0usize;
let mut has_rest = false;
let mut after_amp = false;
for item in xs.iter() {
match item {
Cirru::Leaf(s) => {
let s = s.as_ref();
if s == "&" {
after_amp = true;
} else if s == "[]" || s == "," || s == "?" {
} else if after_amp {
has_rest = true;
} else if !s.starts_with(':') && !s.starts_with('|') && !s.chars().all(|c| c.is_ascii_digit()) {
required += 1;
}
}
Cirru::List(_) => {
if !after_amp {
required += 1;
}
}
}
}
(required, has_rest)
}
pub fn analyze_code_entry(ns: &str, def_name: &str, entry: &snapshot::CodeEntry) -> TypeCoverageRow {
if ns == calcit::calcit::CORE_NS {
if let Ok(proc) = (*def_name).parse::<CalcitProc>() {
if let Some(sig) = proc.get_type_signature() {
return analyze_builtin_proc(def_name, sig);
}
}
if let Ok(syntax) = (*def_name).parse::<CalcitSyntax>() {
if let Some(sig) = syntax.get_type_signature() {
return analyze_builtin_syntax(def_name, &sig);
}
}
}
let (kind, params, param_annotations, return_type_hints, data_type, level) = match &entry.code {
Cirru::List(xs) => match xs.first() {
Some(Cirru::Leaf(head)) if &**head == "defn" => {
if let CalcitTypeAnnotation::Fn(fn_annot) = entry.schema.as_ref()
&& let Ok(schema) = snapshot::schema_edn_to_cirru(&fn_annot.to_schema_edn())
&& let Some((params, param_annotations, return_type_hints, level)) = extract_fn_schema_hints(&schema)
{
return TypeCoverageRow {
ns: ns.to_owned(),
def: def_name.to_owned(),
kind: DefKind::Fn,
level,
params,
param_annotations,
return_type_hints,
data_type: None,
schema_issues: validate_def_vs_schema(ns, def_name, &entry.code, &entry.schema),
};
}
if std::env::var("CR_DEBUG_SCHEMA").is_ok() {
let schema_kind = match entry.schema.as_ref() {
CalcitTypeAnnotation::Fn(fn_annot) => match snapshot::schema_edn_to_cirru(&fn_annot.to_schema_edn()) {
Ok(schema) => match extract_fn_schema_hints(&schema) {
Some(_) => "Fn/schema-hints-ok".to_owned(),
None => "Fn/schema-hints-none".to_owned(),
},
Err(e) => format!("Fn/edn-to-cirru-err:{e}"),
},
other => format!("non-fn:{other:?}"),
};
eprintln!("[debug] {ns}/{def_name}: schema={schema_kind}");
}
let args = xs.get(2);
let body = &xs[3..];
let params = extract_param_symbols(args);
let param_annotations = extract_assert_type_annotations(body);
let return_type_hints = extract_return_type_hints(body);
let typed_count = count_typed_params(¶ms, ¶m_annotations);
let ret_typed = !return_type_hints.is_empty();
let level = if ret_typed && (params.is_empty() || typed_count == params.len()) {
CoverageLevel::Full
} else if ret_typed || typed_count > 0 {
CoverageLevel::Partial
} else {
CoverageLevel::None
};
(DefKind::Fn, params, param_annotations, return_type_hints, None, level)
}
Some(Cirru::Leaf(head)) if &**head == "defmacro" => {
let args = xs.get(2);
let body = &xs[3..];
let params = extract_param_symbols(args);
let param_annotations = extract_assert_type_annotations(body);
(DefKind::Macro, params, param_annotations, Vec::new(), None, CoverageLevel::Full)
}
Some(Cirru::Leaf(head)) if &**head == "def" => {
let inferred = xs.get(2).and_then(infer_data_type);
let level = CoverageLevel::Full;
(DefKind::Data, Vec::new(), BTreeMap::new(), Vec::new(), inferred, level)
}
_ => (DefKind::Other, Vec::new(), BTreeMap::new(), Vec::new(), None, CoverageLevel::Full),
},
_ => (DefKind::Other, Vec::new(), BTreeMap::new(), Vec::new(), None, CoverageLevel::Full),
};
TypeCoverageRow {
ns: ns.to_owned(),
def: def_name.to_owned(),
kind,
level,
params,
param_annotations,
return_type_hints,
data_type,
schema_issues: validate_def_vs_schema(ns, def_name, &entry.code, &entry.schema),
}
}
fn unwrap_optional_schema(schema: &Cirru) -> &Cirru {
match schema {
Cirru::List(items) => {
if let Some(Cirru::Leaf(head)) = items.first() {
if &**head == ":optional" && items.len() == 2 {
return &items[1];
}
if &**head == "::" && items.len() == 3 && matches!(items.get(1), Some(Cirru::Leaf(tag)) if &**tag == ":optional") {
return &items[2];
}
}
schema
}
_ => schema,
}
}
fn schema_to_map(schema: &Cirru) -> Option<BTreeMap<&str, &Cirru>> {
let schema = unwrap_optional_schema(schema);
let Cirru::List(items) = schema else {
return None;
};
let Some(Cirru::Leaf(head)) = items.first() else {
return None;
};
let mut data = BTreeMap::new();
match &**head {
"&{}" => {
if (items.len() - 1) % 2 != 0 {
return None;
}
for idx in (1..items.len()).step_by(2) {
let key = match &items[idx] {
Cirru::Leaf(s) if s.starts_with(':') => s.as_ref(),
_ => return None,
};
data.insert(key, &items[idx + 1]);
}
}
"{}" => {
for pair in items.iter().skip(1) {
let Cirru::List(xs) = pair else {
return None;
};
if xs.len() != 2 {
return None;
}
let key = match &xs[0] {
Cirru::Leaf(s) if s.starts_with(':') => s.as_ref(),
_ => return None,
};
data.insert(key, &xs[1]);
}
}
_ => return None,
}
Some(data)
}
fn is_schema_list_annotation(node: &Cirru) -> bool {
match node {
Cirru::Leaf(s) => s.as_ref() == ":list",
Cirru::List(xs) => {
matches!(xs.first(), Some(Cirru::Leaf(head)) if &**head == "::")
&& matches!(xs.get(1), Some(Cirru::Leaf(tag)) if &**tag == ":list")
}
}
}
fn render_schema_param_type(ty_node: Option<&Cirru>, wrap_rest_as_list: bool) -> String {
let Some(ty_node) = ty_node else {
return ":dynamic".to_owned();
};
let rendered = render_cirru_inline(ty_node);
if !wrap_rest_as_list || rendered == ":dynamic" || is_schema_list_annotation(ty_node) {
rendered
} else {
format!(":: :list {rendered}")
}
}
fn read_schema_param_tuple(item: &Cirru, default_name: &str, wrap_rest_as_list: bool) -> Option<(String, String)> {
match item {
Cirru::Leaf(_) => Some((default_name.to_owned(), render_schema_param_type(Some(item), wrap_rest_as_list))),
Cirru::List(xs) => {
let Some(Cirru::Leaf(head)) = xs.first() else {
return None;
};
if &**head != "[]" && &**head != "::" {
return None;
}
match xs.len() {
2 => {
let ty = render_schema_param_type(xs.get(1), wrap_rest_as_list);
Some((default_name.to_owned(), ty))
}
3 => {
let ty_node = match xs.get(1) {
Some(Cirru::Leaf(name)) if name.starts_with('\'') => xs.get(2),
_ => Some(item),
};
let ty = render_schema_param_type(ty_node, wrap_rest_as_list);
Some((default_name.to_owned(), ty))
}
_ => None,
}
}
}
}
type FnSchemaHints = (Vec<String>, BTreeMap<String, Vec<String>>, Vec<String>, CoverageLevel);
pub fn extract_fn_schema_hints(schema: &Cirru) -> Option<FnSchemaHints> {
let schema = schema_to_map(schema)?;
let mut params: Vec<String> = Vec::new();
let mut param_annotations: BTreeMap<String, Vec<String>> = BTreeMap::new();
if let Some(args_node) = schema.get(":args")
&& let Cirru::List(items) = args_node
&& matches!(items.first(), Some(Cirru::Leaf(head)) if &**head == "[]")
{
for (idx, item) in items.iter().skip(1).enumerate() {
if let Some((name, ty)) = read_schema_param_tuple(item, &format!("arg{idx}"), false) {
params.push(name.clone());
param_annotations.entry(name).or_default().push(ty);
}
}
}
if let Some(rest_node) = schema.get(":rest")
&& let Some((name, ty)) = read_schema_param_tuple(rest_node, "rest", true)
{
params.push(name.clone());
param_annotations.entry(name).or_default().push(ty);
}
let return_type_hints = vec![
schema
.get(":return")
.map_or_else(|| ":dynamic".to_owned(), |v| render_cirru_inline(v)),
];
let typed_count = params
.iter()
.filter(|name| {
param_annotations
.get(*name)
.is_some_and(|hints| hints.iter().any(|hint| hint != ":dynamic"))
})
.count();
let ret_typed = return_type_hints.iter().any(|hint| hint != ":dynamic");
let level = if ret_typed && (params.is_empty() || typed_count == params.len()) {
CoverageLevel::Full
} else if ret_typed || typed_count > 0 {
CoverageLevel::Partial
} else {
CoverageLevel::None
};
Some((params, param_annotations, return_type_hints, level))
}
fn extract_param_symbols(args: Option<&Cirru>) -> Vec<String> {
let mut out: Vec<String> = vec![];
if let Some(node) = args {
collect_param_symbols(node, &mut out);
}
dedup_keep_order(out)
}
fn collect_param_symbols(node: &Cirru, out: &mut Vec<String>) {
match node {
Cirru::Leaf(s) => {
let name = s.as_ref();
if name == "&" || name == "?" || name == "[]" || name == "," {
return;
}
if name.starts_with('|') || name.starts_with(':') || name.chars().all(|c| c.is_ascii_digit()) {
return;
}
out.push(name.to_string());
}
Cirru::List(xs) => {
for x in xs {
collect_param_symbols(x, out);
}
}
}
}
fn extract_assert_type_annotations(nodes: &[Cirru]) -> BTreeMap<String, Vec<String>> {
let mut out: BTreeMap<String, Vec<String>> = BTreeMap::new();
for node in nodes {
collect_assert_type_annotations(node, &mut out);
}
for items in out.values_mut() {
let mut seen: BTreeSet<String> = BTreeSet::new();
items.retain(|v| seen.insert(v.to_owned()));
}
out
}
fn collect_assert_type_annotations(node: &Cirru, out: &mut BTreeMap<String, Vec<String>>) {
match node {
Cirru::Leaf(_) => {}
Cirru::List(xs) => {
if let Some(Cirru::Leaf(head)) = xs.first()
&& &**head == "assert-type"
&& let Some(Cirru::Leaf(symbol)) = xs.get(1)
&& let Some(ty_node) = xs.get(2)
{
out.entry(symbol.to_string()).or_default().push(render_cirru_inline(ty_node));
}
for x in xs {
collect_assert_type_annotations(x, out);
}
}
}
}
fn extract_return_type_hints(nodes: &[Cirru]) -> Vec<String> {
let mut out: Vec<String> = Vec::new();
for node in nodes {
collect_return_type_hints(node, &mut out);
}
let mut seen: BTreeSet<String> = BTreeSet::new();
out.retain(|v| seen.insert(v.to_owned()));
out
}
fn collect_return_type_hints(node: &Cirru, out: &mut Vec<String>) {
match node {
Cirru::Leaf(_) => {}
Cirru::List(xs) => {
if let Some(Cirru::Leaf(head)) = xs.first()
&& &**head == "return-type"
&& let Some(ty_node) = xs.get(1)
{
out.push(render_cirru_inline(ty_node));
}
for x in xs {
collect_return_type_hints(x, out);
}
}
}
}
pub fn count_typed_params(params: &[String], annotations: &BTreeMap<String, Vec<String>>) -> usize {
params
.iter()
.filter(|name| annotations.get(*name).is_some_and(|items| !items.is_empty()))
.count()
}
fn dedup_keep_order(items: Vec<String>) -> Vec<String> {
let mut seen: BTreeSet<String> = BTreeSet::new();
let mut out: Vec<String> = Vec::new();
for item in items {
if seen.insert(item.to_owned()) {
out.push(item);
}
}
out
}
fn render_cirru_inline(node: &Cirru) -> String {
match node {
Cirru::Leaf(s) => s.to_string(),
Cirru::List(xs) => {
let parts = xs.iter().map(render_cirru_inline).collect::<Vec<_>>().join(" ");
format!("({parts})")
}
}
}
pub fn parse_coverage_levels(raw: &str) -> Result<BTreeSet<CoverageLevel>, String> {
let mut selected: BTreeSet<CoverageLevel> = BTreeSet::new();
for part in raw.split(',') {
let token = part.trim().to_ascii_lowercase();
if token.is_empty() {
continue;
}
match token.as_str() {
"none" => {
selected.insert(CoverageLevel::None);
}
"partial" => {
selected.insert(CoverageLevel::Partial);
}
"full" => {
selected.insert(CoverageLevel::Full);
}
_ => {
return Err(format!(
"Unknown coverage level `{token}` in --only. Expected comma-separated values from: none,partial,full"
));
}
}
}
if selected.is_empty() {
return Err("`--only` is empty. Use one or more of: none,partial,full".to_string());
}
Ok(selected)
}
fn infer_data_type(node: &Cirru) -> Option<String> {
match node {
Cirru::Leaf(s) => {
let raw = s.as_ref();
if raw == "nil" {
Some("nil".to_string())
} else if raw == "true" || raw == "false" {
Some("bool".to_string())
} else if raw.starts_with('|') {
Some("string".to_string())
} else if raw.starts_with(':') {
Some("tag".to_string())
} else if raw.parse::<f64>().is_ok() {
Some("number".to_string())
} else {
None
}
}
Cirru::List(xs) => match xs.first() {
Some(Cirru::Leaf(head)) if &**head == "[]" => Some("list".to_string()),
Some(Cirru::Leaf(head)) if &**head == "{}" || &**head == "&{}" => Some("map".to_string()),
Some(Cirru::Leaf(head)) if &**head == "#{}" => Some("set".to_string()),
Some(Cirru::Leaf(head)) if &**head == "::" => Some("tuple".to_string()),
Some(Cirru::Leaf(head)) if &**head == "defn" || &**head == "fn" => Some("fn".to_string()),
Some(Cirru::Leaf(head)) if &**head == "defmacro" => Some("macro".to_string()),
_ => None,
},
}
}
pub fn format_check_types(options: &CheckTypesCommand, snapshot: &snapshot::Snapshot) -> Result<String, String> {
let mut out = String::new();
run_check_types_report(options, snapshot, &mut out)?;
Ok(out)
}
pub fn format_weak_types(options: &WeakTypesCommand, snapshot: &snapshot::Snapshot) -> Result<String, String> {
let mut out = String::new();
run_weak_types_report(options, snapshot, &mut out)?;
Ok(out)
}