ripvec-core 3.1.2

//! `PageRank`-weighted structural overview of a codebase.
//!
//! Builds a dependency graph from tree-sitter definition and import extraction,
//! ranks files by importance using `PageRank` (standard or topic-sensitive), and
//! renders a budget-constrained overview with tiered detail levels.

use std::collections::HashMap;
use std::fmt::Write as _;
use std::path::{Path, PathBuf};

use rayon::prelude::*;
use rkyv::{Archive, Deserialize as RkyvDeserialize, Serialize as RkyvSerialize};
use streaming_iterator::StreamingIterator;
use tree_sitter::{Parser, Query, QueryCursor};

use crate::languages;
use crate::walk;

// ── Data Structures ──────────────────────────────────────────────────

/// Persisted dependency graph with `PageRank` scores.
#[derive(Debug, Clone, Archive, RkyvSerialize, RkyvDeserialize)]
pub struct RepoGraph {
    /// Files in the repository with definitions, imports, and calls.
    pub files: Vec<FileNode>,
    /// File-level edges (derived from def-level call edges).
    pub edges: Vec<(u32, u32, u32)>,
    /// File-level `PageRank` scores (aggregated from def-level).
    pub base_ranks: Vec<f32>,
    /// File-level callers (indices into `files`).
    pub callers: Vec<Vec<u32>>,
    /// File-level callees (indices into `files`).
    pub callees: Vec<Vec<u32>>,
    /// Definition-level call edges: `(caller_def, callee_def, weight)`.
    pub def_edges: Vec<(DefId, DefId, u32)>,
    /// Definition-level `PageRank` scores (flattened: `offsets[file_idx] + def_idx`).
    pub def_ranks: Vec<f32>,
    /// Definition-level callers (flattened, parallel to `def_ranks`).
    pub def_callers: Vec<Vec<DefId>>,
    /// Definition-level callees (flattened, parallel to `def_ranks`).
    pub def_callees: Vec<Vec<DefId>>,
    /// Prefix-sum offsets for flattening `DefId` to linear index.
    pub def_offsets: Vec<usize>,
    /// Auto-tuned alpha for search boost.
    pub alpha: f32,
}

/// A file in the repository with its definitions and imports.
#[derive(Debug, Clone, Archive, RkyvSerialize, RkyvDeserialize)]
pub struct FileNode {
    /// Relative path from the repository root.
    pub path: String,
    /// Definitions (functions, structs, classes, etc.) extracted from this file.
    pub defs: Vec<Definition>,
    /// Import references extracted from this file.
    pub imports: Vec<ImportRef>,
}

/// A definition extracted from a source file.
#[derive(Debug, Clone, Archive, RkyvSerialize, RkyvDeserialize)]
pub struct Definition {
    /// Name of the definition (e.g., function name, class name).
    pub name: String,
    /// Kind of syntax node (e.g., `function_item`, `class_definition`).
    pub kind: String,
    /// 1-based start line number.
    pub start_line: u32,
    /// 1-based end line number.
    pub end_line: u32,
    /// Scope chain (e.g., `"impl_item Foo > fn bar"`).
    pub scope: String,
    /// Function/method signature, if available.
    pub signature: Option<String>,
    /// Byte offset of this definition's start in the source file.
    pub start_byte: u32,
    /// Byte offset of this definition's end in the source file.
    pub end_byte: u32,
    /// Call sites within this definition's body.
    pub calls: Vec<CallRef>,
}

/// An import reference extracted from a source file.
#[derive(Debug, Clone, Archive, RkyvSerialize, RkyvDeserialize)]
pub struct ImportRef {
    /// Raw import path as written in source (e.g., `crate::foo::bar`).
    pub raw_path: String,
    /// Resolved file index in [`RepoGraph::files`], if resolution succeeded.
    pub resolved_idx: Option<u32>,
}

/// Unique identifier for a definition: (file index, definition index within file).
pub type DefId = (u32, u16);

/// A call site extracted from a definition body.
#[derive(Debug, Clone, Archive, RkyvSerialize, RkyvDeserialize)]
pub struct CallRef {
    /// Callee function/method name.
    pub name: String,
    /// Byte offset of the call in the source file (for scoping to definitions).
    pub byte_offset: u32,
    /// Resolved target definition, if resolution succeeded.
    pub resolved: Option<DefId>,
}

// ── Constants ────────────────────────────────────────────────────────

/// `PageRank` damping factor.
const DAMPING: f32 = 0.85;

/// `PageRank` convergence threshold.
const EPSILON: f32 = 1e-6;

/// Maximum `PageRank` iterations.
const MAX_ITERATIONS: usize = 100;

/// Maximum callers/callees stored per file.
const MAX_NEIGHBORS: usize = 5;

/// Approximate characters per token for budget estimation.
const CHARS_PER_TOKEN: usize = 4;

// ── Import Queries ───────────────────────────────────────────────────

/// Compile a tree-sitter import query for the given extension.
///
/// Returns `None` for unsupported extensions.
fn import_query_for_extension(ext: &str) -> Option<(tree_sitter::Language, Query)> {
    let (lang, query_str): (tree_sitter::Language, &str) = match ext {
        "rs" => (
            tree_sitter_rust::LANGUAGE.into(),
            "(use_declaration) @import",
        ),
        "py" | "pyi" => (
            tree_sitter_python::LANGUAGE.into(),
            concat!(
                "(import_statement) @import\n",
                "(import_from_statement) @import",
            ),
        ),
        "js" | "jsx" => (
            tree_sitter_javascript::LANGUAGE.into(),
            "(import_statement source: (string) @import_path) @import",
        ),
        "ts" => (
            tree_sitter_typescript::LANGUAGE_TYPESCRIPT.into(),
            "(import_statement source: (string) @import_path) @import",
        ),
        "tsx" => (
            tree_sitter_typescript::LANGUAGE_TSX.into(),
            "(import_statement source: (string) @import_path) @import",
        ),
        "go" => (
            tree_sitter_go::LANGUAGE.into(),
            "(import_spec path: (interpreted_string_literal) @import_path) @import",
        ),
        // Ruby: require statements.
        "rb" => (
            tree_sitter_ruby::LANGUAGE.into(),
            "(call method: (identifier) @_method arguments: (argument_list (string (string_content) @import_path)) (#eq? @_method \"require\")) @import",
        ),
        _ => return None,
    };
    let query = match Query::new(&lang, query_str) {
        Ok(q) => q,
        Err(e) => {
            tracing::warn!(ext, %e, "import query compilation failed — language may be ABI-incompatible");
            return None;
        }
    };
    Some((lang, query))
}

/// Extract import paths from source using tree-sitter.
fn extract_imports(
    source: &str,
    lang: &tree_sitter::Language,
    import_query: &Query,
) -> Vec<String> {
    let mut parser = Parser::new();
    if parser.set_language(lang).is_err() {
        return vec![];
    }
    let Some(tree) = parser.parse(source, None) else {
        return vec![];
    };

    let mut cursor = QueryCursor::new();
    let mut imports = Vec::new();
    let mut matches = cursor.matches(import_query, tree.root_node(), source.as_bytes());

    while let Some(m) = matches.next() {
        // Prefer @import_path capture (JS/TS/Go), fall back to full @import text
        let mut import_path_text = None;
        let mut import_text = None;

        for cap in m.captures {
            let cap_name = &import_query.capture_names()[cap.index as usize];
            let text = &source[cap.node.start_byte()..cap.node.end_byte()];
            if *cap_name == "import_path" {
                import_path_text = Some(text.trim_matches(|c| c == '"' || c == '\''));
            } else if *cap_name == "import" {
                import_text = Some(text);
            }
        }

        if let Some(path) = import_path_text {
            imports.push(path.to_string());
        } else if let Some(text) = import_text {
            imports.push(text.to_string());
        }
    }

    imports
}

// ── Import Resolution ────────────────────────────────────────────────

/// Resolve a Rust `use` path to a file index in the file map.
///
/// Handles `crate::`, `self::`, and `super::` prefixes. External crate
/// imports are dropped (returns `None`).
fn resolve_rust_import(
    raw: &str,
    file_path: &Path,
    root: &Path,
    file_index: &HashMap<PathBuf, usize>,
) -> Option<usize> {
    // Extract the module path from `use crate::foo::bar;` or `use crate::foo::bar::Baz;`
    let trimmed = raw
        .trim()
        .trim_start_matches("use ")
        .trim_end_matches(';')
        .trim();

    let segments: Vec<&str> = trimmed.split("::").collect();
    if segments.is_empty() {
        return None;
    }

    // Determine the base directory and skip prefix segments
    let (base, skip) = match segments[0] {
        "crate" => {
            // Find the nearest Cargo.toml ancestor to determine the crate root.
            // In a workspace, `crate::foo` resolves relative to the crate's src/,
            // not the workspace root.
            let mut dir = file_path.parent();
            let crate_root = loop {
                match dir {
                    Some(d) if d.join("Cargo.toml").exists() => break d.join("src"),
                    Some(d) => dir = d.parent(),
                    None => break root.join("src"), // fallback
                }
            };
            (crate_root, 1)
        }
        "self" => {
            let dir = file_path.parent()?;
            (dir.to_path_buf(), 1)
        }
        "super" => {
            let dir = file_path.parent()?.parent()?;
            (dir.to_path_buf(), 1)
        }
        // External crate — drop
        _ => return None,
    };

    // Build candidate paths from the remaining segments.
    // Try progressively shorter prefixes since the last segments
    // may be items (struct, fn) rather than modules.
    let path_segments = &segments[skip..];
    for end in (1..=path_segments.len()).rev() {
        let mut candidate = base.clone();
        for seg in &path_segments[..end] {
            // Strip glob patterns like `{Foo, Bar}`
            let clean = seg.split('{').next().unwrap_or(seg).trim();
            if !clean.is_empty() {
                candidate.push(clean);
            }
        }

        // Try file.rs
        let as_file = candidate.with_extension("rs");
        if let Some(&idx) = file_index.get(&as_file) {
            return Some(idx);
        }

        // Try dir/mod.rs
        let as_mod = candidate.join("mod.rs");
        if let Some(&idx) = file_index.get(&as_mod) {
            return Some(idx);
        }
    }

    None
}

/// Resolve an import path to a file index based on file extension.
fn resolve_import(
    raw: &str,
    ext: &str,
    file_path: &Path,
    root: &Path,
    file_index: &HashMap<PathBuf, usize>,
) -> Option<usize> {
    match ext {
        "rs" => resolve_rust_import(raw, file_path, root, file_index),
        "py" | "pyi" => resolve_python_import(raw, root, file_index),
        "js" | "jsx" | "ts" | "tsx" => resolve_js_import(raw, file_path, file_index),
        // Go imports use full package paths — skip local resolution
        _ => None,
    }
}

/// Resolve a Python import to a file index.
///
/// Handles `import foo.bar` and `from foo.bar import baz` patterns.
fn resolve_python_import(
    raw: &str,
    root: &Path,
    file_index: &HashMap<PathBuf, usize>,
) -> Option<usize> {
    let module_path = if let Some(rest) = raw.strip_prefix("from ") {
        rest.split_whitespace().next()?
    } else if let Some(rest) = raw.strip_prefix("import ") {
        rest.split_whitespace().next()?
    } else {
        return None;
    };

    let rel_path: PathBuf = module_path.split('.').collect();
    for ext in ["py", "pyi"] {
        let as_file = root.join(&rel_path).with_extension(ext);
        if let Some(&idx) = file_index.get(&as_file) {
            return Some(idx);
        }
    }

    for init_name in ["__init__.py", "__init__.pyi"] {
        let as_init = root.join(&rel_path).join(init_name);
        if let Some(&idx) = file_index.get(&as_init) {
            return Some(idx);
        }
    }

    None
}

/// Resolve a JS/TS import to a file index.
///
/// Handles relative paths like `./foo` or `../bar`.
fn resolve_js_import(
    raw: &str,
    file_path: &Path,
    file_index: &HashMap<PathBuf, usize>,
) -> Option<usize> {
    if !raw.starts_with('.') {
        return None;
    }

    let dir = file_path.parent()?;
    let candidate = dir.join(raw);

    for ext in &["js", "jsx", "ts", "tsx"] {
        let with_ext = candidate.with_extension(ext);
        if let Some(&idx) = file_index.get(&with_ext) {
            return Some(idx);
        }
    }

    for ext in &["js", "jsx", "ts", "tsx"] {
        let index_file = candidate.join("index").with_extension(ext);
        if let Some(&idx) = file_index.get(&index_file) {
            return Some(idx);
        }
    }

    None
}

// ── Extraction ───────────────────────────────────────────────────────

/// Extract definitions from a source file using tree-sitter.
fn extract_definitions(source: &str, config: &languages::LangConfig) -> Vec<Definition> {
    let mut parser = Parser::new();
    if parser.set_language(&config.language).is_err() {
        return vec![];
    }
    let Some(tree) = parser.parse(source, None) else {
        return vec![];
    };

    let mut cursor = QueryCursor::new();
    let mut defs = Vec::new();
    let mut matches = cursor.matches(&config.query, tree.root_node(), source.as_bytes());

    while let Some(m) = matches.next() {
        let mut name = String::new();
        let mut def_node = None;

        for cap in m.captures {
            let cap_name = &config.query.capture_names()[cap.index as usize];
            if *cap_name == "name" {
                name = source[cap.node.start_byte()..cap.node.end_byte()].to_string();
            } else if *cap_name == "def" {
                def_node = Some(cap.node);
            }
        }

        if let Some(node) = def_node {
            let scope = crate::chunk::build_scope_chain(node, source);
            let signature = crate::chunk::extract_signature(node, source);
            #[expect(clippy::cast_possible_truncation, reason = "line numbers fit in u32")]
            let start_line = node.start_position().row as u32 + 1;
            #[expect(clippy::cast_possible_truncation, reason = "line numbers fit in u32")]
            let end_line = node.end_position().row as u32 + 1;
            #[expect(clippy::cast_possible_truncation, reason = "byte offsets fit in u32")]
            let start_byte = node.start_byte() as u32;
            #[expect(clippy::cast_possible_truncation, reason = "byte offsets fit in u32")]
            let end_byte = node.end_byte() as u32;
            defs.push(Definition {
                name,
                kind: node.kind().to_string(),
                start_line,
                end_line,
                scope,
                signature,
                start_byte,
                end_byte,
                calls: vec![],
            });
        }
    }

    defs
}

// ── Call Extraction & Resolution ────────────────────────────────────

/// Extract call sites from a source file and assign them to definitions.
///
/// Uses the language's call query to find all call expressions, then
/// assigns each call to the definition whose byte range contains it.
/// Calls outside any definition body (module-level) are ignored.
fn extract_calls(source: &str, call_config: &languages::CallConfig, defs: &mut [Definition]) {
    let mut parser = Parser::new();
    if parser.set_language(&call_config.language).is_err() {
        return;
    }
    let Some(tree) = parser.parse(source, None) else {
        return;
    };

    let mut cursor = QueryCursor::new();
    let mut matches = cursor.matches(&call_config.query, tree.root_node(), source.as_bytes());

    while let Some(m) = matches.next() {
        let mut callee_name = None;
        let mut call_byte = 0u32;

        for cap in m.captures {
            let cap_name = &call_config.query.capture_names()[cap.index as usize];
            if *cap_name == "callee" {
                callee_name = Some(source[cap.node.start_byte()..cap.node.end_byte()].to_string());
                #[expect(clippy::cast_possible_truncation, reason = "byte offsets fit in u32")]
                {
                    call_byte = cap.node.start_byte() as u32;
                }
            }
        }

        if let Some(name) = callee_name {
            // Assign to the enclosing definition by byte range
            if let Some(def) = defs
                .iter_mut()
                .find(|d| d.start_byte <= call_byte && call_byte < d.end_byte)
            {
                // Skip self-recursive calls
                if def.name != name {
                    def.calls.push(CallRef {
                        name,
                        byte_offset: call_byte,
                        resolved: None,
                    });
                }
            }
            // Calls outside any definition are ignored (module-level init)
        }
    }
}

/// Build an index from definition name to list of `DefId`s.
fn build_def_index(files: &[FileNode]) -> HashMap<String, Vec<DefId>> {
    let mut index: HashMap<String, Vec<DefId>> = HashMap::new();
    for (file_idx, file) in files.iter().enumerate() {
        for (def_idx, def) in file.defs.iter().enumerate() {
            #[expect(clippy::cast_possible_truncation)]
            let did: DefId = (file_idx as u32, def_idx as u16);
            index.entry(def.name.clone()).or_default().push(did);
        }
    }
    index
}

/// Resolve call references to target definitions.
///
/// Strategy:
/// 1. Scoped calls (`mod_a::foo`): look up candidates by bare name, then prefer
///    the unique candidate whose file path or scope contains the qualifier. If
///    multiple candidates still match after qualifier filtering, the call is
///    ambiguous — leave `resolved` as `None` (no silent first-wins).
/// 2. Unqualified calls — same-file: prefer definitions in the caller's own file.
/// 3. Unqualified calls — imported-file: check definitions in files this file imports.
/// 4. Unqualified calls — ambiguous (multiple candidates, none same-file or imported):
///    leave `resolved` as `None`.
/// 5. Unresolved: leave `resolved` as `None`.
fn resolve_calls(files: &mut [FileNode], def_index: &HashMap<String, Vec<DefId>>) {
    // Pre-compute imported file sets for each file
    let imported_files: Vec<std::collections::HashSet<u32>> = files
        .iter()
        .map(|f| {
            f.imports
                .iter()
                .filter_map(|imp| imp.resolved_idx)
                .collect()
        })
        .collect();

    for file_idx in 0..files.len() {
        for def_idx in 0..files[file_idx].defs.len() {
            for call_idx in 0..files[file_idx].defs[def_idx].calls.len() {
                let call_name = files[file_idx].defs[def_idx].calls[call_idx].name.clone();

                // Determine whether this is a scoped call (contains `::`)
                let (lookup_key, qualifier) = if let Some(pos) = call_name.rfind("::") {
                    // Scoped call: bare name is the trailing component; qualifier is everything before
                    let bare = &call_name[pos + 2..];
                    let qual = &call_name[..pos];
                    (bare.to_string(), Some(qual.to_string()))
                } else {
                    (call_name.clone(), None)
                };

                let Some(candidates) = def_index.get(&lookup_key) else {
                    continue;
                };

                if let Some(qual) = qualifier {
                    // Scoped call: filter candidates by qualifier match.
                    // A candidate matches if the file path or scope chain contains the
                    // qualifier as a path component (e.g., file "mod_a.rs" for qualifier "mod_a",
                    // or file "mod_a/lib.rs", or scope containing "mod_a").
                    let qual_segments: Vec<&str> = qual.split("::").collect();
                    let matching: Vec<DefId> = candidates
                        .iter()
                        .copied()
                        .filter(|&(f_idx, _)| {
                            let file_path = &files[f_idx as usize].path;
                            // Check if the qualifier's last segment appears in the file path stem
                            // or if the full qualifier appears as path components in the file path.
                            let last_segment = qual_segments.last().copied().unwrap_or("");
                            // Normalise: replace path separators with `::` for comparison
                            let path_as_module =
                                file_path.trim_end_matches(".rs").replace(['/', '\\'], "::");
                            path_as_module.contains(last_segment)
                                || file_path.contains(last_segment)
                        })
                        .collect();

                    // Unique match → resolve; ambiguous or no match → leave None
                    if matching.len() == 1 {
                        files[file_idx].defs[def_idx].calls[call_idx].resolved = Some(matching[0]);
                    }
                    // Multiple matches or no matches → resolved stays None (ambiguous)
                    continue;
                }

                // Unqualified call resolution:

                // Priority 1: same file
                #[expect(clippy::cast_possible_truncation)]
                let file_idx_u32 = file_idx as u32;
                if let Some(&did) = candidates.iter().find(|(f, _)| *f == file_idx_u32) {
                    files[file_idx].defs[def_idx].calls[call_idx].resolved = Some(did);
                    continue;
                }

                // Priority 2: imported file — resolve only when unambiguous
                let imported_candidates: Vec<DefId> = candidates
                    .iter()
                    .copied()
                    .filter(|(f, _)| imported_files[file_idx].contains(f))
                    .collect();
                if imported_candidates.len() == 1 {
                    files[file_idx].defs[def_idx].calls[call_idx].resolved =
                        Some(imported_candidates[0]);
                }
                // Priority 3: ambiguous or unresolved — leave as None
            }
        }
    }
}

/// Compute a prefix-sum offset table for flattening `DefId`s to linear indices.
fn def_offsets(files: &[FileNode]) -> Vec<usize> {
    let mut offsets = Vec::with_capacity(files.len() + 1);
    offsets.push(0);
    for file in files {
        offsets.push(offsets.last().unwrap() + file.defs.len());
    }
    offsets
}

/// Flatten a `DefId` to a linear index using the offset table.
fn flatten_def_id(offsets: &[usize], did: DefId) -> usize {
    offsets[did.0 as usize] + did.1 as usize
}

/// Build top-N caller and callee lists for each definition (flattened).
fn build_def_neighbor_lists(
    n: usize,
    edges: &[(u32, u32, u32)],
    offsets: &[usize],
) -> (Vec<Vec<DefId>>, Vec<Vec<DefId>>) {
    let mut incoming: Vec<Vec<(u32, u32)>> = vec![vec![]; n];
    let mut outgoing: Vec<Vec<(u32, u32)>> = vec![vec![]; n];

    for &(src, dst, w) in edges {
        let (s, d) = (src as usize, dst as usize);
        if s < n && d < n {
            incoming[d].push((src, w));
            outgoing[s].push((dst, w));
        }
    }

    // Convert flat index back to DefId
    let to_def_id = |flat: u32| -> DefId {
        let flat_usize = flat as usize;
        let file_idx = offsets.partition_point(|&o| o <= flat_usize) - 1;
        let def_idx = flat_usize - offsets[file_idx];
        #[expect(clippy::cast_possible_truncation)]
        (file_idx as u32, def_idx as u16)
    };

    let callers = incoming
        .into_iter()
        .map(|mut v| {
            v.sort_by_key(|b| std::cmp::Reverse(b.1));
            v.truncate(MAX_NEIGHBORS);
            v.into_iter().map(|(idx, _)| to_def_id(idx)).collect()
        })
        .collect();

    let callees = outgoing
        .into_iter()
        .map(|mut v| {
            v.sort_by_key(|b| std::cmp::Reverse(b.1));
            v.truncate(MAX_NEIGHBORS);
            v.into_iter().map(|(idx, _)| to_def_id(idx)).collect()
        })
        .collect();

    (callers, callees)
}

// ── PageRank ─────────────────────────────────────────────────────────

/// Compute `PageRank` scores for a graph.
///
/// If `focus` is `Some(idx)`, computes topic-sensitive `PageRank` biased
/// toward file `idx`. Otherwise computes standard (uniform) `PageRank`.
///
/// Returns one score per node, summing to 1.0.
#[expect(
    clippy::cast_precision_loss,
    reason = "node count fits comfortably in f32"
)]
fn pagerank(n: usize, edges: &[(u32, u32, u32)], focus: Option<usize>) -> Vec<f32> {
    if n == 0 {
        return vec![];
    }

    // Build adjacency: out_edges[src] = [(dst, weight)]
    let mut out_edges: Vec<Vec<(usize, f32)>> = vec![vec![]; n];
    let mut out_weight: Vec<f32> = vec![0.0; n];

    for &(src, dst, w) in edges {
        let (s, d) = (src as usize, dst as usize);
        if s < n && d < n {
            #[expect(clippy::cast_possible_truncation, reason = "edge weights are small")]
            let wf = f64::from(w) as f32;
            out_edges[s].push((d, wf));
            out_weight[s] += wf;
        }
    }

    // Personalization vector: for topic-sensitive PageRank, blend
    // 70% focus on the target file with 30% uniform. Pure focus
    // (100%) starves unreachable nodes to rank=0 in sparse graphs.
    let bias: Vec<f32> = if let Some(idx) = focus {
        let uniform = 1.0 / n as f32;
        let mut b = vec![0.3 * uniform; n];
        if idx < n {
            b[idx] += 0.7;
        }
        // Normalize to sum=1
        let sum: f32 = b.iter().sum();
        for v in &mut b {
            *v /= sum;
        }
        b
    } else {
        vec![1.0 / n as f32; n]
    };

    let mut rank = vec![1.0 / n as f32; n];
    let mut next_rank = vec![0.0_f32; n];

    for _ in 0..MAX_ITERATIONS {
        // Collect dangling mass (nodes with no outgoing edges)
        let dangling: f32 = rank
            .iter()
            .enumerate()
            .filter(|&(i, _)| out_edges[i].is_empty())
            .map(|(_, &r)| r)
            .sum();

        // Distribute rank
        for (i, nr) in next_rank.iter_mut().enumerate() {
            *nr = (1.0 - DAMPING).mul_add(bias[i], DAMPING * dangling * bias[i]);
        }

        for (src, edges_list) in out_edges.iter().enumerate() {
            if edges_list.is_empty() {
                continue;
            }
            let src_rank = rank[src];
            let total_w = out_weight[src];
            for &(dst, w) in edges_list {
                next_rank[dst] += DAMPING * src_rank * (w / total_w);
            }
        }

        // Check convergence
        let diff: f32 = rank
            .iter()
            .zip(next_rank.iter())
            .map(|(a, b)| (a - b).abs())
            .sum();

        std::mem::swap(&mut rank, &mut next_rank);

        if diff < EPSILON {
            break;
        }
    }

    rank
}

// ── Graph Building ───────────────────────────────────────────────────

/// Intermediate result from definition-level graph computation.
struct DefGraphData {
    def_edges: Vec<(DefId, DefId, u32)>,
    def_ranks: Vec<f32>,
    def_callers: Vec<Vec<DefId>>,
    def_callees: Vec<Vec<DefId>>,
    offsets: Vec<usize>,
    base_ranks: Vec<f32>,
    file_edges: Vec<(u32, u32, u32)>,
}

/// Build definition-level edges, compute `PageRank`, and derive file-level data.
fn compute_def_graph(files: &[FileNode]) -> DefGraphData {
    // Build definition-level edge list from resolved calls
    let mut def_edge_map: HashMap<(DefId, DefId), u32> = HashMap::new();
    for (file_idx, file) in files.iter().enumerate() {
        for (def_idx, def) in file.defs.iter().enumerate() {
            #[expect(clippy::cast_possible_truncation)]
            let caller_id: DefId = (file_idx as u32, def_idx as u16);
            for call in &def.calls {
                if let Some(callee_id) = call.resolved {
                    *def_edge_map.entry((caller_id, callee_id)).or_insert(0) += 1;
                }
            }
        }
    }
    let def_edges: Vec<(DefId, DefId, u32)> = def_edge_map
        .into_iter()
        .map(|((src, dst), w)| (src, dst, w))
        .collect();

    // Compute def-level PageRank
    let offsets = def_offsets(files);
    let n_defs = *offsets.last().unwrap_or(&0);

    let flat_def_edges: Vec<(u32, u32, u32)> = def_edges
        .iter()
        .map(|(src, dst, w)| {
            #[expect(clippy::cast_possible_truncation)]
            (
                flatten_def_id(&offsets, *src) as u32,
                flatten_def_id(&offsets, *dst) as u32,
                *w,
            )
        })
        .collect();

    let def_ranks = pagerank(n_defs, &flat_def_edges, None);

    // Aggregate def ranks to file level
    let base_ranks: Vec<f32> = files
        .iter()
        .enumerate()
        .map(|(i, file)| {
            let start = offsets[i];
            let end = start + file.defs.len();
            def_ranks[start..end].iter().sum()
        })
        .collect();

    // Derive file-level edges from def-level call edges
    let mut file_edge_map: HashMap<(u32, u32), u32> = HashMap::new();
    for &(src, dst, w) in &def_edges {
        let src_file = src.0;
        let dst_file = dst.0;
        if src_file != dst_file {
            *file_edge_map.entry((src_file, dst_file)).or_insert(0) += w;
        }
    }
    let file_edges: Vec<(u32, u32, u32)> = file_edge_map
        .into_iter()
        .map(|((src, dst), w)| (src, dst, w))
        .collect();

    // Build def-level caller/callee lists
    let (def_callers, def_callees) = build_def_neighbor_lists(n_defs, &flat_def_edges, &offsets);

    DefGraphData {
        def_edges,
        def_ranks,
        def_callers,
        def_callees,
        offsets,
        base_ranks,
        file_edges,
    }
}

/// Build a dependency graph from a repository root.
///
/// Walks the directory tree, parses each supported file with tree-sitter,
/// extracts definitions and imports, resolves import paths to files, runs
/// `PageRank`, and builds caller/callee lists.
///
/// # Errors
///
/// Returns an error if file walking or reading fails.
pub fn build_graph(root: &Path) -> crate::Result<RepoGraph> {
    let root = root.canonicalize().map_err(|e| crate::Error::Io {
        path: root.display().to_string(),
        source: e,
    })?;

    let mut walk_options = walk::WalkOptions::default();
    if let Some((_, config)) = crate::cache::config::find_config(&root) {
        walk_options.ignore_patterns = config.ignore.patterns;
    }
    let all_files = walk::collect_files_with_options(&root, &walk_options);

    // Phase 1: parallel filter + read. For each candidate path with a
    // supported extension, read its source from disk and emit a tuple
    // alongside its relative path. rayon spreads the I/O cost across
    // worker threads; on a 1M-file corpus this was ~20s sequential and
    // now sits in the 2-3s range bounded by disk + filter throughput.
    let raw_inputs: Vec<(PathBuf, String, String, String)> = all_files
        .par_iter()
        .filter_map(|path| {
            let ext = path
                .extension()
                .and_then(|e| e.to_str())
                .unwrap_or_default()
                .to_string();
            if languages::config_for_extension(&ext).is_none()
                && import_query_for_extension(&ext).is_none()
            {
                return None;
            }
            let source = std::fs::read_to_string(path).ok()?;
            let rel_path = path
                .strip_prefix(&root)
                .unwrap_or(path)
                .display()
                .to_string();
            Some((path.clone(), rel_path, ext, source))
        })
        .collect();

    // Build the contiguous `files` Vec and the absolute-path -> idx
    // lookup. Sequential because both want stable indices that match
    // `raw_sources`'s order; the per-file work this gates is trivial.
    let mut file_index: HashMap<PathBuf, usize> = HashMap::with_capacity(raw_inputs.len());
    let mut files: Vec<FileNode> = Vec::with_capacity(raw_inputs.len());
    let mut raw_sources: Vec<(usize, String, String)> = Vec::with_capacity(raw_inputs.len());
    for (idx, (abs_path, rel_path, ext, source)) in raw_inputs.into_iter().enumerate() {
        file_index.insert(abs_path, idx);
        files.push(FileNode {
            path: rel_path,
            defs: vec![],
            imports: vec![],
        });
        raw_sources.push((idx, ext, source));
    }

    // Phase 2: parallel per-file definition + import extraction. Each
    // file's tree-sitter parse + def/import queries are independent;
    // par_iter_mut over files.iter_mut().zip(raw_sources.par_iter())
    // lets every rayon worker grind its own slice. The closures here
    // borrow `&root` and `&file_index` immutably (both Sync) and write
    // disjoint `FileNode` slots via the &mut iterator.
    files
        .par_iter_mut()
        .zip(raw_sources.par_iter())
        .for_each(|(file, (_, ext, source))| {
            if let Some(config) = languages::config_for_extension(ext) {
                file.defs = extract_definitions(source, &config);
            }
            if let Some((lang, import_query)) = import_query_for_extension(ext) {
                let raw_imports = extract_imports(source, &lang, &import_query);
                let file_path = root.join(&file.path);
                file.imports = raw_imports
                    .into_iter()
                    .map(|raw| {
                        let resolved_idx =
                            resolve_import(&raw, ext, &file_path, &root, &file_index)
                                .and_then(|i| u32::try_from(i).ok());
                        ImportRef {
                            raw_path: raw,
                            resolved_idx,
                        }
                    })
                    .collect();
            }
        });

    // Phase 3: parallel per-file call extraction. Mutates each
    // FileNode's `defs[*].calls` independently. Aligned with
    // raw_sources by index via the zip.
    files
        .par_iter_mut()
        .zip(raw_sources.par_iter())
        .for_each(|(file, (_, ext, source))| {
            if let Some(call_config) = languages::call_query_for_extension(ext) {
                extract_calls(source, &call_config, &mut file.defs);
            }
        });

    // Resolve call references to target definitions
    let def_index = build_def_index(&files);
    resolve_calls(&mut files, &def_index);

    // Build def-level graph, compute PageRank, and derive file-level data
    let graph_data = compute_def_graph(&files);

    // Build file-level caller/callee lists
    let n = files.len();
    let (callers, callees) = build_neighbor_lists(n, &graph_data.file_edges);

    // Auto-tune alpha based on graph density
    #[expect(clippy::cast_precision_loss, reason = "graph sizes fit in f32")]
    let density = if n > 1 {
        graph_data.file_edges.len() as f32 / (n as f32 * (n as f32 - 1.0))
    } else {
        0.0
    };
    let alpha = 0.3f32.mul_add(density.min(1.0), 0.5);

    Ok(RepoGraph {
        files,
        edges: graph_data.file_edges,
        base_ranks: graph_data.base_ranks,
        callers,
        callees,
        def_edges: graph_data.def_edges,
        def_ranks: graph_data.def_ranks,
        def_callers: graph_data.def_callers,
        def_callees: graph_data.def_callees,
        def_offsets: graph_data.offsets,
        alpha,
    })
}

impl RepoGraph {
    /// Get the `PageRank` score for a specific definition.
    #[must_use]
    pub fn def_rank(&self, did: DefId) -> f32 {
        let flat = self.def_offsets[did.0 as usize] + did.1 as usize;
        self.def_ranks.get(flat).copied().unwrap_or(0.0)
    }

    /// Look up a definition by file path and name. Returns the first match.
    #[must_use]
    pub fn find_def(&self, file_path: &str, def_name: &str) -> Option<DefId> {
        for (file_idx, file) in self.files.iter().enumerate() {
            if file.path == file_path {
                for (def_idx, def) in file.defs.iter().enumerate() {
                    if def.name == def_name {
                        #[expect(clippy::cast_possible_truncation)]
                        return Some((file_idx as u32, def_idx as u16));
                    }
                }
            }
        }
        None
    }
}

/// Build top-N caller and callee lists for each file.
fn build_neighbor_lists(n: usize, edges: &[(u32, u32, u32)]) -> (Vec<Vec<u32>>, Vec<Vec<u32>>) {
    let mut incoming: Vec<Vec<(u32, u32)>> = vec![vec![]; n];
    let mut outgoing: Vec<Vec<(u32, u32)>> = vec![vec![]; n];

    for &(src, dst, w) in edges {
        let (s, d) = (src as usize, dst as usize);
        if s < n && d < n {
            incoming[d].push((src, w));
            outgoing[s].push((dst, w));
        }
    }

    // Sort by weight descending, keep top N
    let trim = |lists: &mut [Vec<(u32, u32)>]| -> Vec<Vec<u32>> {
        lists
            .iter_mut()
            .map(|list| {
                list.sort_by_key(|b| std::cmp::Reverse(b.1));
                list.iter()
                    .take(MAX_NEIGHBORS)
                    .map(|(idx, _)| *idx)
                    .collect()
            })
            .collect()
    };

    (trim(&mut incoming), trim(&mut outgoing))
}

// ── Rendering ────────────────────────────────────────────────────────

/// Render a budget-constrained overview of the repository.
///
/// Files are sorted by `PageRank` (or topic-sensitive rank if `focus` is
/// `Some`). Output uses four tiers of decreasing detail:
///
/// - **Tier 0** (top 10%): full path, rank, callers/callees, signatures with scopes
/// - **Tier 1** (next 20%): full path, rank, signatures
/// - **Tier 2** (next 40%): full path, rank, definition names and kinds
/// - **Tier 3** (bottom 30%): file path only
///
/// Stops accumulating output when the estimated token count exceeds
/// `max_tokens`.
#[must_use]
pub fn render(graph: &RepoGraph, max_tokens: usize, focus: Option<usize>) -> String {
    let n = graph.files.len();
    if n == 0 {
        return String::new();
    }

    // Compute ranks (recompute topic-sensitive if focus is given)
    let ranks = if focus.is_some() {
        pagerank(n, &graph.edges, focus)
    } else {
        graph.base_ranks.clone()
    };

    // Sort file indices by rank descending
    let mut sorted: Vec<usize> = (0..n).collect();
    sorted.sort_by(|&a, &b| ranks[b].total_cmp(&ranks[a]));

    let mut output = String::new();
    let mut used_tokens = 0;
    let max_chars = max_tokens * CHARS_PER_TOKEN;

    for (rank_pos, &file_idx) in sorted.iter().enumerate() {
        if used_tokens >= max_tokens {
            break;
        }

        let file = &graph.files[file_idx];
        let score = ranks[file_idx];
        #[expect(clippy::cast_precision_loss, reason = "file counts fit in f32")]
        let percentile = (rank_pos as f32) / (n as f32);

        let section = if percentile < 0.1 {
            render_tier0(graph, file_idx, file, score)
        } else if percentile < 0.3 {
            render_tier1(file, score)
        } else if percentile < 0.7 {
            render_tier2(file, score)
        } else {
            render_tier3(file)
        };

        let section_chars = section.len();
        if used_tokens > 0 && used_tokens + section_chars / CHARS_PER_TOKEN > max_tokens {
            // Would exceed budget — try to fit at least the path
            let path_line = format!("{}\n", file.path);
            let path_tokens = path_line.len() / CHARS_PER_TOKEN;
            if used_tokens + path_tokens <= max_tokens {
                output.push_str(&path_line);
            }
            break;
        }

        output.push_str(&section);
        used_tokens = output.len().min(max_chars) / CHARS_PER_TOKEN;
    }

    output
}

/// Render tier 0: full detail with callers, callees, and signatures.
fn render_tier0(graph: &RepoGraph, file_idx: usize, file: &FileNode, score: f32) -> String {
    let mut out = format!("## {} (rank: {score:.4})\n", file.path);

    // Callers
    if file_idx < graph.callers.len() && !graph.callers[file_idx].is_empty() {
        let _ = write!(out, "  called by: ");
        let names: Vec<&str> = graph.callers[file_idx]
            .iter()
            .filter_map(|&idx| graph.files.get(idx as usize).map(|f| f.path.as_str()))
            .collect();
        let _ = writeln!(out, "{}", names.join(", "));
    }

    // Callees
    if file_idx < graph.callees.len() && !graph.callees[file_idx].is_empty() {
        let _ = write!(out, "  calls: ");
        let names: Vec<&str> = graph.callees[file_idx]
            .iter()
            .filter_map(|&idx| graph.files.get(idx as usize).map(|f| f.path.as_str()))
            .collect();
        let _ = writeln!(out, "{}", names.join(", "));
    }

    // Definitions with scope and signature
    for def in &file.defs {
        let scope_prefix = if def.scope.is_empty() {
            String::new()
        } else {
            format!("{} > ", def.scope)
        };
        if let Some(sig) = &def.signature {
            let _ = writeln!(out, "  {scope_prefix}{} {sig}", def.kind);
        } else {
            let _ = writeln!(out, "  {scope_prefix}{} {}", def.kind, def.name);
        }
    }
    let _ = writeln!(out);
    out
}

/// Render tier 1: file path, rank, and signatures.
fn render_tier1(file: &FileNode, score: f32) -> String {
    let mut out = format!("## {} (rank: {score:.4})\n", file.path);
    for def in &file.defs {
        if let Some(sig) = &def.signature {
            let _ = writeln!(out, "  {sig}");
        } else {
            let _ = writeln!(out, "  {} {}", def.kind, def.name);
        }
    }
    let _ = writeln!(out);
    out
}

/// Render tier 2: file path, rank, and definition names/kinds.
fn render_tier2(file: &FileNode, score: f32) -> String {
    let mut out = format!("{} (rank: {score:.4})", file.path);
    if !file.defs.is_empty() {
        let names: Vec<String> = file
            .defs
            .iter()
            .map(|d| format!("{}:{}", d.kind, d.name))
            .collect();
        let _ = write!(out, " -- {}", names.join(", "));
    }
    let _ = writeln!(out);
    out
}

/// Render tier 3: file path only.
fn render_tier3(file: &FileNode) -> String {
    format!("{}\n", file.path)
}

// ── Tests ────────────────────────────────────────────────────────────

#[cfg(test)]
mod tests {
    use super::*;

    #[test]
    fn test_pagerank_simple() {
        // 3-node graph: 0 -> 1 -> 2, 2 -> 0 (cycle)
        let edges = vec![(0, 1, 1), (1, 2, 1), (2, 0, 1)];
        let ranks = pagerank(3, &edges, None);

        // All nodes in a symmetric cycle should have equal rank
        assert_eq!(ranks.len(), 3);
        let sum: f32 = ranks.iter().sum();
        assert!(
            (sum - 1.0).abs() < 0.01,
            "ranks should sum to ~1.0, got {sum}"
        );

        // In a perfect cycle, all ranks should be approximately equal
        let expected = 1.0 / 3.0;
        for (i, &r) in ranks.iter().enumerate() {
            assert!(
                (r - expected).abs() < 0.05,
                "rank[{i}] = {r}, expected ~{expected}"
            );
        }
    }

    #[test]
    fn test_pagerank_star() {
        // Star graph: 0,1,2 all point to 3
        let edges = vec![(0, 3, 1), (1, 3, 1), (2, 3, 1)];
        let ranks = pagerank(4, &edges, None);

        assert_eq!(ranks.len(), 4);
        // Node 3 should have the highest rank
        let max_idx = ranks
            .iter()
            .enumerate()
            .max_by(|a, b| a.1.total_cmp(b.1))
            .unwrap()
            .0;
        assert_eq!(max_idx, 3, "node 3 should have highest rank");
        assert!(
            ranks[3] > ranks[0],
            "rank[3]={} should be > rank[0]={}",
            ranks[3],
            ranks[0]
        );
    }

    #[test]
    fn test_pagerank_topic_sensitive() {
        // 3-node chain: 0 -> 1 -> 2
        let edges = vec![(0, 1, 1), (1, 2, 1)];
        let uniform_ranks = pagerank(3, &edges, None);
        let biased_ranks = pagerank(3, &edges, Some(0));

        // With focus on node 0, it should get a higher rank than uniform
        assert!(
            biased_ranks[0] > uniform_ranks[0],
            "focused rank[0]={} should be > uniform rank[0]={}",
            biased_ranks[0],
            uniform_ranks[0]
        );
    }

    #[test]
    fn test_pagerank_empty() {
        let ranks = pagerank(0, &[], None);
        assert!(ranks.is_empty());
    }

    #[test]
    fn test_render_tiers() {
        // Build a small graph with 10 files to exercise all tiers
        let files: Vec<FileNode> = (0..10)
            .map(|i| FileNode {
                path: format!("src/file_{i}.rs"),
                defs: vec![Definition {
                    name: format!("func_{i}"),
                    kind: "function_item".to_string(),
                    start_line: 1,
                    end_line: 5,
                    scope: String::new(),
                    signature: Some(format!("func_{i}(x: i32) -> i32")),
                    start_byte: 0,
                    end_byte: 0,
                    calls: vec![],
                }],
                imports: vec![],
            })
            .collect();

        // Create a star graph: files 1-9 all import from file 0
        let edges: Vec<(u32, u32, u32)> = (1..10).map(|i| (i, 0, 1)).collect();
        let base_ranks = pagerank(10, &edges, None);
        let (top_callers, top_callees) = build_neighbor_lists(10, &edges);

        let graph = RepoGraph {
            files,
            edges,
            base_ranks,
            callers: top_callers,
            callees: top_callees,
            def_edges: vec![],
            def_ranks: vec![],
            def_callers: vec![],
            def_callees: vec![],
            def_offsets: vec![0],
            alpha: 0.5,
        };

        // Large budget: should include all files
        let full = render(&graph, 10_000, None);
        assert!(
            full.contains("file_0"),
            "output should contain the top-ranked file"
        );
        // file_0 should appear as tier 0 (highest rank)
        assert!(
            full.contains("## src/file_0.rs"),
            "top file should have tier 0 heading"
        );

        // Tiny budget: should only fit a few files
        let small = render(&graph, 10, None);
        assert!(
            !small.is_empty(),
            "even tiny budget should produce some output"
        );
        // Should have fewer entries than full render
        let full_lines = full.lines().count();
        let small_lines = small.lines().count();
        assert!(
            small_lines < full_lines,
            "small budget ({small_lines} lines) should have fewer lines than full ({full_lines})"
        );
    }

    #[test]
    fn test_render_empty_graph() {
        let graph = RepoGraph {
            files: vec![],
            edges: vec![],
            base_ranks: vec![],
            callers: vec![],
            callees: vec![],
            def_edges: vec![],
            def_ranks: vec![],
            def_callers: vec![],
            def_callees: vec![],
            def_offsets: vec![0],
            alpha: 0.5,
        };
        let output = render(&graph, 1000, None);
        assert!(output.is_empty(), "empty graph should render empty string");
    }

    #[test]
    fn test_build_graph_on_fixtures() {
        let fixtures = Path::new(env!("CARGO_MANIFEST_DIR"))
            .parent()
            .unwrap()
            .parent()
            .unwrap()
            .join("tests")
            .join("fixtures");

        let graph = build_graph(&fixtures).expect("build_graph should succeed on fixtures");

        // Should find at least the 3 fixture files
        assert!(
            !graph.files.is_empty(),
            "graph should contain files from fixtures"
        );

        // Should find definitions in the Rust fixture
        let rs_file = graph.files.iter().find(|f| f.path.ends_with("sample.rs"));
        assert!(rs_file.is_some(), "should find sample.rs");
        let rs_file = rs_file.unwrap();
        assert!(
            !rs_file.defs.is_empty(),
            "sample.rs should have definitions"
        );
        assert!(
            rs_file.defs.iter().any(|d| d.name == "hello"),
            "should find 'hello' function in sample.rs"
        );

        // Should find definitions in the Python fixture
        let py_file = graph.files.iter().find(|f| f.path.ends_with("sample.py"));
        assert!(py_file.is_some(), "should find sample.py");
        let py_file = py_file.unwrap();
        assert!(
            !py_file.defs.is_empty(),
            "sample.py should have definitions"
        );
        assert!(
            py_file.defs.iter().any(|d| d.name == "greet"),
            "should find 'greet' function in sample.py"
        );

        // PageRank scores should be computed
        assert_eq!(graph.base_ranks.len(), graph.files.len());
        let sum: f32 = graph.base_ranks.iter().sum();
        assert!(
            (sum - 1.0).abs() < 0.01,
            "PageRank scores should sum to ~1.0, got {sum}"
        );
    }

    #[test]
    fn test_extract_imports_rust() {
        let source = "use crate::foo::bar;\nuse std::collections::HashMap;\n";
        let (lang, query) = import_query_for_extension("rs").unwrap();
        let imports = extract_imports(source, &lang, &query);
        assert_eq!(imports.len(), 2);
        assert!(imports[0].contains("crate::foo::bar"));
    }

    #[test]
    fn test_extract_imports_python_stub() {
        let source = "from typing import Protocol\nimport pkg.types\n";
        let (lang, query) = import_query_for_extension("pyi").unwrap();
        let imports = extract_imports(source, &lang, &query);
        assert_eq!(imports.len(), 2);
        assert!(imports[0].contains("from typing import Protocol"));
        assert!(imports[1].contains("import pkg.types"));
    }

    #[test]
    fn test_resolve_python_import_to_stub_file() {
        let root = PathBuf::from("/project");
        let mut file_index = HashMap::new();
        file_index.insert(PathBuf::from("/project/pkg/types.pyi"), 1);

        let result = resolve_python_import("import pkg.types", &root, &file_index);
        assert_eq!(result, Some(1));
    }

    #[test]
    fn test_resolve_rust_crate_import() {
        let root = PathBuf::from("/project");
        let file_path = PathBuf::from("/project/src/main.rs");
        let mut file_index = HashMap::new();
        file_index.insert(PathBuf::from("/project/src/foo/bar.rs"), 1);
        file_index.insert(PathBuf::from("/project/src/main.rs"), 0);

        let result = resolve_rust_import("use crate::foo::bar;", &file_path, &root, &file_index);
        assert_eq!(result, Some(1));
    }

    #[test]
    fn test_resolve_rust_external_crate_dropped() {
        let root = PathBuf::from("/project");
        let file_path = PathBuf::from("/project/src/main.rs");
        let file_index = HashMap::new();

        let result = resolve_rust_import(
            "use std::collections::HashMap;",
            &file_path,
            &root,
            &file_index,
        );
        assert_eq!(result, None, "external crate imports should be dropped");
    }

    #[test]
    fn test_neighbor_lists() {
        // 0 -> 1, 0 -> 2, 1 -> 2
        let edges = vec![(0, 1, 1), (0, 2, 1), (1, 2, 1)];
        let (incoming, outgoing) = build_neighbor_lists(3, &edges);

        // Node 2 should be called by 0 and 1
        assert!(incoming[2].contains(&0));
        assert!(incoming[2].contains(&1));

        // Node 0 should call 1 and 2
        assert!(outgoing[0].contains(&1));
        assert!(outgoing[0].contains(&2));
    }

    /// RED test (R2.3 issue a): A scoped call `mod_a::foo()` must record the full path
    /// "mod_a::foo" in the CallRef, not just "foo".
    #[test]
    fn test_scoped_identifier_calls_preserve_path() {
        use crate::languages;
        use streaming_iterator::StreamingIterator as _;

        let source = "
mod mod_a {
    pub fn foo() {}
}
mod mod_b {
    pub fn foo() {}
}
fn caller() {
    mod_a::foo();
    mod_b::foo();
}
";
        let call_config =
            languages::call_query_for_extension("rs").expect("Rust call config must exist");
        let lang_config =
            languages::config_for_extension("rs").expect("Rust lang config must exist");

        let mut defs = {
            let mut parser = tree_sitter::Parser::new();
            parser.set_language(&lang_config.language).unwrap();
            let tree = parser.parse(source, None).unwrap();
            let mut cursor = tree_sitter::QueryCursor::new();
            let mut out = Vec::new();
            let mut matches =
                cursor.matches(&lang_config.query, tree.root_node(), source.as_bytes());
            while let Some(m) = matches.next() {
                let mut name = String::new();
                let mut def_node = None;
                for cap in m.captures {
                    let cname = &lang_config.query.capture_names()[cap.index as usize];
                    if *cname == "name" {
                        name = source[cap.node.start_byte()..cap.node.end_byte()].to_string();
                    } else if *cname == "def" {
                        def_node = Some(cap.node);
                    }
                }
                if let Some(node) = def_node {
                    #[expect(clippy::cast_possible_truncation)]
                    out.push(Definition {
                        name,
                        kind: node.kind().to_string(),
                        start_line: node.start_position().row as u32 + 1,
                        end_line: node.end_position().row as u32 + 1,
                        scope: String::new(),
                        signature: None,
                        start_byte: node.start_byte() as u32,
                        end_byte: node.end_byte() as u32,
                        calls: vec![],
                    });
                }
            }
            out
        };

        extract_calls(source, &call_config, &mut defs);

        // Find the `caller` function definition
        let caller_def = defs
            .iter()
            .find(|d| d.name == "caller")
            .expect("caller def");

        // Calls must preserve qualified paths
        let call_names: Vec<&str> = caller_def.calls.iter().map(|c| c.name.as_str()).collect();
        assert!(
            call_names.contains(&"mod_a::foo"),
            "expected 'mod_a::foo' in calls, got: {call_names:?}"
        );
        assert!(
            call_names.contains(&"mod_b::foo"),
            "expected 'mod_b::foo' in calls, got: {call_names:?}"
        );
        // Bare 'foo' should NOT appear (the scoped paths replaced it)
        assert!(
            !call_names.contains(&"foo"),
            "bare 'foo' must not appear when scoped path is available. Got: {call_names:?}"
        );
    }

    /// RED test (R2.3 issue b+c): Two defs named `Read` in different modules,
    /// an unqualified call to `Read`. Resolution must NOT silently pick the first.
    /// Either both are returned (ambiguous) or none.
    #[test]
    fn test_ambiguous_name_resolution_returns_all_or_none() {
        // Build two FileNodes each with a def named "Read", then a third with an
        // unqualified call to "Read".
        let file_a = FileNode {
            path: "mod_a.rs".to_string(),
            defs: vec![Definition {
                name: "Read".to_string(),
                kind: "trait_item".to_string(),
                start_line: 1,
                end_line: 3,
                scope: String::new(),
                signature: None,
                start_byte: 0,
                end_byte: 50,
                calls: vec![],
            }],
            imports: vec![],
        };
        let file_b = FileNode {
            path: "mod_b.rs".to_string(),
            defs: vec![Definition {
                name: "Read".to_string(),
                kind: "trait_item".to_string(),
                start_line: 1,
                end_line: 3,
                scope: String::new(),
                signature: None,
                start_byte: 0,
                end_byte: 50,
                calls: vec![],
            }],
            imports: vec![],
        };
        let file_c = FileNode {
            path: "caller.rs".to_string(),
            defs: vec![Definition {
                name: "do_thing".to_string(),
                kind: "function_item".to_string(),
                start_line: 1,
                end_line: 5,
                scope: String::new(),
                signature: None,
                start_byte: 0,
                end_byte: 100,
                calls: vec![CallRef {
                    name: "Read".to_string(),
                    byte_offset: 10,
                    resolved: None,
                }],
            }],
            imports: vec![],
        };

        let mut files = vec![file_a, file_b, file_c];
        let def_index = build_def_index(&files);
        resolve_calls(&mut files, &def_index);

        // The unqualified call to "Read" is ambiguous (two candidates, neither in same
        // file nor imported). Resolution must leave it as None — silent first-wins is wrong.
        let resolved = files[2].defs[0].calls[0].resolved;
        assert_eq!(
            resolved, None,
            "ambiguous unqualified call with no import context must resolve to None, not silently pick first"
        );
    }

    #[test]
    #[ignore = "runs on full ripvec codebase; use --nocapture to see output"]
    fn test_full_repo_map() {
        use std::time::Instant;

        let root = Path::new(env!("CARGO_MANIFEST_DIR"))
            .parent()
            .unwrap()
            .parent()
            .unwrap();

        // Phase 1: build_graph (walk + parse + import resolve + PageRank)
        let t0 = Instant::now();
        let graph = build_graph(root).expect("build_graph on ripvec root");
        let build_ms = t0.elapsed().as_secs_f64() * 1000.0;

        // Phase 2: render (default, no focus)
        let t1 = Instant::now();
        let rendered = render(&graph, 2000, None);
        let render_ms = t1.elapsed().as_secs_f64() * 1000.0;

        // Phase 3: render (topic-sensitive, focused on highest-ranked file)
        let t2 = Instant::now();
        let focus_idx = graph
            .base_ranks
            .iter()
            .enumerate()
            .max_by(|a, b| a.1.total_cmp(b.1))
            .map(|(i, _)| i);
        let focused = render(&graph, 2000, focus_idx);
        let focus_ms = t2.elapsed().as_secs_f64() * 1000.0;

        eprintln!("\n=== Repo Map Performance ===");
        eprintln!(
            "Files: {}, Edges: {}, Defs: {}",
            graph.files.len(),
            graph.edges.len(),
            graph.files.iter().map(|f| f.defs.len()).sum::<usize>()
        );
        eprintln!("build_graph:     {build_ms:.1}ms (walk + parse + resolve + PageRank)");
        eprintln!(
            "render(default): {render_ms:.3}ms ({} chars, ~{} tokens)",
            rendered.len(),
            rendered.len() / 4
        );
        eprintln!(
            "render(focused): {focus_ms:.3}ms ({} chars, ~{} tokens)",
            focused.len(),
            focused.len() / 4
        );

        eprintln!("\nTop 5 by PageRank:");
        let mut ranked: Vec<(usize, f32)> = graph.base_ranks.iter().copied().enumerate().collect();
        ranked.sort_by(|a, b| b.1.total_cmp(&a.1));
        for (i, rank) in ranked.iter().take(5) {
            eprintln!("  {:.4} {}", rank, graph.files[*i].path);
        }

        eprintln!("\n=== Default Render ===\n{rendered}");
        eprintln!(
            "\n=== Focused Render (on {}) ===\n{focused}",
            focus_idx
                .map(|i| graph.files[i].path.as_str())
                .unwrap_or("none")
        );
    }
}