const std = @import("std"); const ast = @import("ast.zig"); const parser = @import("parser.zig"); const errors = @import("errors.zig"); const c_import = @import("c_import.zig"); const Node = ast.Node; /// Comptime evaluation context for the inline-if hoisting pass below. /// Mirrors the values `injectComptimeConstants` will later push into the /// lowering's `comptime_constants` map (OS / ARCH / POINTER_SIZE), but /// derived directly from the build target so we can resolve top-level /// `inline if OS == .X { ... }` arms before imports + lowering run. pub const ComptimeContext = struct { /// Lowercase OS name matching the OperatingSystem enum tag /// (macos / linux / windows / wasm / ios / android / unknown). os: []const u8 = "unknown", /// Lowercase architecture name matching the Architecture enum tag /// (aarch64 / x86_64 / wasm32 / wasm64 / unknown). arch: []const u8 = "unknown", /// 4 for wasm32, 8 for every other target. pointer_size: i64 = 8, }; /// Top-level `inline if OS == .X { decls }` blocks are parsed as /// `if_expr` / `match_expr` nodes in `root.decls`, but the lowering /// pass only knows how to dispatch on `.fn_decl` / `.const_decl` / /// `.var_decl` / etc. at decl positions — an `if_expr` at the top /// level is silently dropped. Same story for `#import` decls inside an /// `inline if` body: they need to be surfaced to the top so import /// resolution sees them. /// /// This pass walks `decls`, replaces every comptime conditional with /// the body of its taken arm (recursively flattened), and drops the /// rest. A condition we can't resolve at this stage is also dropped — /// the caller may want to surface that as a diagnostic later, but for /// the OS / ARCH / POINTER_SIZE patterns we cover here it shouldn't /// happen in practice. pub fn flattenComptimeConditionals(allocator: std.mem.Allocator, decls: []const *Node, ctx: ComptimeContext) std.mem.Allocator.Error![]const *Node { var out = std.ArrayList(*Node).empty; for (decls) |decl| { switch (decl.data) { .if_expr => |ie| { if (ie.is_comptime) { if (evalComptimeCondition(ie.condition, ctx)) |is_true| { const taken: ?*const Node = if (is_true) ie.then_branch else ie.else_branch; if (taken) |b| try appendBranchDecls(allocator, &out, b, ctx); continue; } // Couldn't evaluate — drop the whole conditional. This is // a conservative choice; future work may surface it as a // diagnostic. For OS / ARCH / POINTER_SIZE comparisons // the eval is total, so this shouldn't fire in practice. continue; } try out.append(allocator, decl); }, .match_expr => |me| { if (me.is_comptime) { if (evalComptimeMatch(&me, ctx)) |body| { try appendBranchDecls(allocator, &out, body, ctx); } continue; } try out.append(allocator, decl); }, else => try out.append(allocator, decl), } } return try out.toOwnedSlice(allocator); } fn appendBranchDecls(allocator: std.mem.Allocator, out: *std.ArrayList(*Node), branch: *const Node, ctx: ComptimeContext) std.mem.Allocator.Error!void { const stmts: []const *Node = if (branch.data == .block) branch.data.block.stmts else &[_]*Node{@constCast(branch)}; const recursed = try flattenComptimeConditionals(allocator, stmts, ctx); try out.appendSlice(allocator, recursed); } fn evalComptimeCondition(node: *const Node, ctx: ComptimeContext) ?bool { if (node.data != .binary_op) return null; const bo = &node.data.binary_op; if (bo.op != .eq and bo.op != .neq) return null; const name = switch (bo.lhs.data) { .identifier => |id| id.name, else => return null, }; if (std.mem.eql(u8, name, "OS") or std.mem.eql(u8, name, "ARCH")) { const variant = switch (bo.rhs.data) { .enum_literal => |el| el.name, else => return null, }; const target = if (std.mem.eql(u8, name, "OS")) ctx.os else ctx.arch; const matches = std.mem.eql(u8, variant, target); return if (bo.op == .eq) matches else !matches; } if (std.mem.eql(u8, name, "POINTER_SIZE")) { const rhs_val: i64 = switch (bo.rhs.data) { .int_literal => |il| il.value, else => return null, }; const matches = ctx.pointer_size == rhs_val; return if (bo.op == .eq) matches else !matches; } return null; } fn evalComptimeMatch(me: *const ast.MatchExpr, ctx: ComptimeContext) ?*const Node { const name = switch (me.subject.data) { .identifier => |id| id.name, else => return null, }; if (std.mem.eql(u8, name, "OS") or std.mem.eql(u8, name, "ARCH")) { const target = if (std.mem.eql(u8, name, "OS")) ctx.os else ctx.arch; for (me.arms) |arm| { const pattern = arm.pattern orelse continue; const variant = switch (pattern.data) { .enum_literal => |el| el.name, else => continue, }; if (std.mem.eql(u8, variant, target)) return arm.body; } for (me.arms) |arm| if (arm.pattern == null) return arm.body; return null; } if (std.mem.eql(u8, name, "POINTER_SIZE")) { for (me.arms) |arm| { const pattern = arm.pattern orelse continue; const rhs_val: i64 = switch (pattern.data) { .int_literal => |il| il.value, else => continue, }; if (ctx.pointer_size == rhs_val) return arm.body; } for (me.arms) |arm| if (arm.pattern == null) return arm.body; return null; } return null; } pub fn dirName(path: []const u8) []const u8 { var last_sep: usize = 0; var found = false; for (path, 0..) |ch, i| { if (ch == '/') { last_sep = i; found = true; } } return if (found) path[0..last_sep] else "."; } /// Resolve an import path. Tries (in order): /// 1. relative to `base_dir` (the importing file's directory) /// 2. relative to CWD, absolutified via `root_path` if supplied /// 3. relative to each path in `stdlib_paths` (the install-discovered stdlib) /// Returns the first path that exists. Falls back to the raw path if nothing matches /// so the caller's readFile produces a coherent "not found" error. pub fn resolveImportPath(allocator: std.mem.Allocator, io: std.Io, base_dir: []const u8, raw_path: []const u8, root_path: ?[]const u8, stdlib_paths: []const []const u8) ![]const u8 { if (!std.mem.eql(u8, base_dir, ".")) { const rel_path = try std.fmt.allocPrint(allocator, "{s}/{s}", .{ base_dir, raw_path }); // Check if it exists as file relative to base_dir if (std.Io.Dir.readFileAlloc(.cwd(), io, rel_path, allocator, .limited(10 * 1024 * 1024))) |_| { return rel_path; } else |_| {} // Check if it exists as directory relative to base_dir if (std.Io.Dir.openDir(.cwd(), io, rel_path, .{})) |dir| { dir.close(io); return rel_path; } else |_| {} } // Try CWD-relative (absolutified if root_path is known). const cwd_candidate = if (root_path) |rp| blk: { if (rp.len > 0 and raw_path.len > 0 and raw_path[0] != '/') { break :blk try std.fmt.allocPrint(allocator, "{s}/{s}", .{ rp, raw_path }); } break :blk raw_path; } else raw_path; if (std.Io.Dir.readFileAlloc(.cwd(), io, cwd_candidate, allocator, .limited(10 * 1024 * 1024))) |_| { return cwd_candidate; } else |_| {} if (std.Io.Dir.openDir(.cwd(), io, cwd_candidate, .{})) |dir| { dir.close(io); return cwd_candidate; } else |_| {} // Try each stdlib search path. for (stdlib_paths) |sp| { const cand = try std.fmt.allocPrint(allocator, "{s}/{s}", .{ sp, raw_path }); if (std.Io.Dir.readFileAlloc(.cwd(), io, cand, allocator, .limited(10 * 1024 * 1024))) |_| { return cand; } else |_| {} if (std.Io.Dir.openDir(.cwd(), io, cand, .{})) |dir| { dir.close(io); return cand; } else |_| {} } return cwd_candidate; } /// Discover candidate stdlib search paths from the running binary's location. /// Honors the `SX_STDLIB_PATH` env var as an explicit override. Returns a slice /// of absolute paths owned by the allocator. pub fn discoverStdlibPaths(allocator: std.mem.Allocator) ![]const []const u8 { var out = std.ArrayList([]const u8).empty; // Env override via libc getenv (cross-stdlib-version stable). if (c_getenv("SX_STDLIB_PATH")) |env_path| { try out.append(allocator, try allocator.dupe(u8, std.mem.span(env_path))); } const exe_path = selfExePath(allocator) catch return try out.toOwnedSlice(allocator); const exe_dir = dirName(exe_path); // Stdlib paths are directories containing a `modules/` subdir; the import // directive (e.g. `#import "modules/std.sx"`) supplies the rest. // Dev: zig-out/bin/sx -> repo-root/library try out.append(allocator, try std.fmt.allocPrint(allocator, "{s}/../../library", .{exe_dir})); // Install: /bin/sx -> /library try out.append(allocator, try std.fmt.allocPrint(allocator, "{s}/../library", .{exe_dir})); // Alongside the binary. try out.append(allocator, try std.fmt.allocPrint(allocator, "{s}/library", .{exe_dir})); if (c_getenv("SX_DEBUG_STDLIB") != null) { std.debug.print("[sx] exe_path={s}\n", .{exe_path}); for (out.items, 0..) |p, i| std.debug.print("[sx] stdlib_paths[{d}]={s}\n", .{ i, p }); } return try out.toOwnedSlice(allocator); } const builtin = @import("builtin"); extern "c" fn _NSGetExecutablePath(buf: [*]u8, len: *u32) c_int; extern "c" fn getenv(name: [*:0]const u8) ?[*:0]const u8; fn c_getenv(name: [:0]const u8) ?[*:0]const u8 { return getenv(name.ptr); } fn selfExePath(allocator: std.mem.Allocator) ![]const u8 { var buf: [4096]u8 = undefined; switch (builtin.os.tag) { .macos, .ios => { var len: u32 = buf.len; if (_NSGetExecutablePath(&buf, &len) != 0) return error.PathBufferTooSmall; const span = std.mem.sliceTo(&buf, 0); return try allocator.dupe(u8, span); }, .linux => { const n = try std.posix.readlink("/proc/self/exe", &buf); return try allocator.dupe(u8, n); }, else => return error.UnsupportedHostOS, } } /// A resolved module: the fully-resolved declarations of a single .sx file, /// with its own scope tracking which names are defined. /// /// Imports are non-transitive. `scope` is intentionally *narrow*: it /// contains only the names of decls authored in THIS file (plus namespaced /// import aliases the file introduces). Visibility for names from /// flat-imported modules is computed at lookup time by joining the /// importer's `scope` with each direct flat-import's `scope` via /// `import_graph` — this lets cyclic imports (e.g. std.sx ↔ allocators.sx) /// resolve correctly even though one side of the cycle is skipped during /// `resolveImports` recursion. /// /// `decls` remains the full transitive flat list so the global lowering /// pass can resolve a body in B that calls into C even though A never /// imported C directly. pub const ResolvedModule = struct { path: []const u8, /// Full flat decl list: own decls + every transitively-imported module's /// own decls (deduped by name). Walked by `lowerRoot`/`scanDecls` so /// transitive callees stay resolvable when their callers are lowered. decls: []const *Node, /// Decls authored in this file. What flat importers of THIS module see /// (their visibility BFS joins these names in via `import_graph`). own_decls: []const *Node, /// Names authored in this file (plus namespace aliases this file /// introduces). Used as the per-file leaf in the visibility lookup; /// importers do NOT splice this into their own scope — they walk the /// import graph at query time instead. scope: std.StringHashMap(void), /// Add a declaration authored in this file. Updates scope + own_decls + /// the global flat decl list; dedups by name through `seen_list` (which /// already holds names previously appended via `mergeFlat`, so an /// authored decl that collides with a transitively-imported one stays /// out of the global list while still entering `own_decls` for /// importer-visibility purposes). pub fn addOwnDecl( self: *ResolvedModule, allocator: std.mem.Allocator, list: *std.ArrayList(*Node), own_list: *std.ArrayList(*Node), seen_list: *std.StringHashMap(void), decl: *Node, ) !bool { var append_to_global = true; if (decl.data.declName()) |name| { if (self.scope.contains(name)) return false; try self.scope.put(name, {}); if (seen_list.contains(name)) { append_to_global = false; } else { try seen_list.put(name, {}); } } if (append_to_global) try list.append(allocator, decl); try own_list.append(allocator, decl); return true; } /// Flat-import another module. The imported names are NOT added to /// `self.scope` — visibility joins per-file scopes at lookup time via /// `import_graph`. We only need to append `other.decls` (the full /// transitive list) to the global `list` so the lowering pass can /// still resolve transitively-imported callees. Deduped by name. pub fn mergeFlat( self: *ResolvedModule, allocator: std.mem.Allocator, list: *std.ArrayList(*Node), seen_list: *std.StringHashMap(void), other: ResolvedModule, ) !void { _ = self; for (other.decls) |decl| { if (decl.data.declName()) |name| { if (seen_list.contains(name)) continue; try seen_list.put(name, {}); } try list.append(allocator, decl); } } /// Add another module as a namespaced import. The alias `name` becomes /// part of this module's own decls (so a flat-importer of this module /// sees the alias one hop out — matching authored names). pub fn addNamespace( self: *ResolvedModule, allocator: std.mem.Allocator, list: *std.ArrayList(*Node), own_list: *std.ArrayList(*Node), seen_list: *std.StringHashMap(void), name: []const u8, other: ResolvedModule, span: ast.Span, ) !void { const ns_node = try allocator.create(Node); ns_node.* = .{ .span = span, .data = .{ .namespace_decl = .{ .name = name, .decls = other.decls, } }, }; try self.scope.put(name, {}); try seen_list.put(name, {}); try list.append(allocator, ns_node); try own_list.append(allocator, ns_node); } pub fn finalize( self: *ResolvedModule, allocator: std.mem.Allocator, list: *std.ArrayList(*Node), own_list: *std.ArrayList(*Node), ) !void { self.decls = try list.toOwnedSlice(allocator); self.own_decls = try own_list.toOwnedSlice(allocator); } }; /// Module cache: maps resolved file paths to their ResolvedModules. pub const ModuleCache = std.StringHashMap(ResolvedModule); pub fn resolveImports( allocator: std.mem.Allocator, io: std.Io, root: *Node, base_dir: []const u8, file_path: []const u8, chain: *std.StringHashMap(void), cache: *ModuleCache, source_map: ?*std.StringHashMap([:0]const u8), diagnostics: ?*errors.DiagnosticList, stdlib_paths: []const []const u8, import_graph: ?*std.StringHashMap(std.StringHashMap(void)), comptime_ctx: ComptimeContext, ) !ResolvedModule { // Record this file's edge set so `param_impl_map` lookups can filter // candidates by what's been imported from where. Populated as each // import resolves below; transitive closure computed on demand. if (import_graph) |g| { if (!g.contains(file_path)) { try g.put(file_path, std.StringHashMap(void).init(allocator)); } } var mod = ResolvedModule{ .path = file_path, .decls = &.{}, .own_decls = &.{}, .scope = std.StringHashMap(void).init(allocator), }; if (root.data != .root) { mod.decls = &.{}; return mod; } // Hoist top-level `inline if OS == .X { ... }` body decls (including // any `#import`s inside them) to the top level before resolution // proceeds. After this pass, the decl list contains no top-level // `if_expr` / `match_expr` nodes with `is_comptime = true`. const flat_decls = try flattenComptimeConditionals(allocator, root.data.root.decls, comptime_ctx); var decl_list = std.ArrayList(*Node).empty; var own_decl_list = std.ArrayList(*Node).empty; // Name set spanning every decl already appended to `decl_list` — used // by `mergeFlat` to dedupe across diamond imports now that `mod.scope` // is non-transitive and can no longer serve as the dedup key. var seen_in_list = std.StringHashMap(void).init(allocator); for (flat_decls) |decl| { if (decl.data == .c_import_decl) { // Resolve `#source` / `#include` paths through the same chain // as `#import`: importing-file's directory → CWD → stdlib // search paths. This lets sx-library modules ship their own // C helpers (e.g. the Android JNI insets bridge) without // forcing every consumer to vendor an identically-named copy. { const ci_pre = decl.data.c_import_decl; if (ci_pre.sources.len > 0) { var resolved = try allocator.alloc([]const u8, ci_pre.sources.len); for (ci_pre.sources, 0..) |raw_src, idx| { resolved[idx] = try resolveImportPath(allocator, io, base_dir, raw_src, null, stdlib_paths); } decl.data.c_import_decl.sources = resolved; } if (ci_pre.includes.len > 0) { var resolved = try allocator.alloc([]const u8, ci_pre.includes.len); for (ci_pre.includes, 0..) |raw_inc, idx| { resolved[idx] = try resolveImportPath(allocator, io, base_dir, raw_inc, null, stdlib_paths); } decl.data.c_import_decl.includes = resolved; } } const ci = decl.data.c_import_decl; // Parse headers to get synthetic function declarations const result = c_import.processCImport( allocator, ci.includes, ci.defines, ci.flags, ) catch |err| { if (diagnostics) |diags| { diags.addFmt(.err, decl.span, "#import c failed: {}", .{err}); } return error.ImportError; }; if (ci.name) |ns_name| { // Namespaced: wrap fn_decls + c_import_decl in a namespace var ns_decls = std.ArrayList(*Node).empty; for (result.fn_decls) |fd| { try ns_decls.append(allocator, fd); } // Keep c_import_decl inside namespace so codegen can find sources try ns_decls.append(allocator, decl); const ns_node = try allocator.create(Node); ns_node.* = .{ .span = decl.span, .data = .{ .namespace_decl = .{ .name = ns_name, .decls = try ns_decls.toOwnedSlice(allocator), } }, }; ns_node.source_file = file_path; try mod.scope.put(ns_name, {}); try seen_in_list.put(ns_name, {}); try decl_list.append(allocator, ns_node); try own_decl_list.append(allocator, ns_node); } else { // Flat: add fn_decls directly + keep c_import_decl for (result.fn_decls) |fd| { fd.source_file = file_path; _ = try mod.addOwnDecl(allocator, &decl_list, &own_decl_list, &seen_in_list, fd); } decl.source_file = file_path; _ = try mod.addOwnDecl(allocator, &decl_list, &own_decl_list, &seen_in_list, decl); } continue; } if (decl.data != .import_decl) { decl.source_file = file_path; _ = try mod.addOwnDecl(allocator, &decl_list, &own_decl_list, &seen_in_list, decl); continue; } const imp = decl.data.import_decl; const resolved_path = try resolveImportPath(allocator, io, base_dir, imp.path, null, stdlib_paths); // Record direct-import edge file_path → resolved_path. Self-imports // and chain duplicates are still recorded so the graph reflects what // the user wrote (filter happens at lookup). if (import_graph) |g| { if (g.getPtr(file_path)) |set| { set.put(resolved_path, {}) catch {}; } } // Circular import check — only along the current chain if (chain.contains(resolved_path)) continue; // Resolve or retrieve the imported module const imported_mod = if (cache.get(resolved_path)) |cached| cached else blk: { // Try as file first if (std.Io.Dir.readFileAlloc(.cwd(), io, resolved_path, allocator, .limited(10 * 1024 * 1024))) |imp_bytes| { const imp_source = try allocator.dupeZ(u8, imp_bytes); if (source_map) |sm| { sm.put(resolved_path, imp_source) catch {}; } var p = parser.Parser.init(allocator, imp_source); const imp_root = p.parse() catch { if (diagnostics) |diags| { diags.addFmt(.err, decl.span, "parse error in '{s}': {s}", .{ resolved_path, p.err_msg orelse "unknown" }); } return error.ImportError; }; // Push onto chain before recursing, pop after try chain.put(resolved_path, {}); const imp_dir = dirName(resolved_path); const result = try resolveImports(allocator, io, imp_root, imp_dir, resolved_path, chain, cache, source_map, diagnostics, stdlib_paths, import_graph, comptime_ctx); _ = chain.remove(resolved_path); // Cache try cache.put(resolved_path, result); break :blk result; } else |_| { // File read failed — try as directory import const result = resolveDirectoryImport(allocator, io, resolved_path, chain, cache, source_map, diagnostics, decl.span, stdlib_paths, import_graph, comptime_ctx) catch { if (diagnostics) |diags| { diags.addFmt(.err, decl.span, "cannot read import '{s}' (not a file or directory)", .{resolved_path}); } return error.ImportError; }; try cache.put(resolved_path, result); break :blk result; } }; if (imp.name) |ns_name| { try mod.addNamespace(allocator, &decl_list, &own_decl_list, &seen_in_list, ns_name, imported_mod, decl.span); } else { try mod.mergeFlat(allocator, &decl_list, &seen_in_list, imported_mod); } } try mod.finalize(allocator, &decl_list, &own_decl_list); return mod; } /// Resolve a directory import by aggregating all .sx files in the directory. fn resolveDirectoryImport( allocator: std.mem.Allocator, io: std.Io, dir_path: []const u8, chain: *std.StringHashMap(void), cache: *ModuleCache, source_map: ?*std.StringHashMap([:0]const u8), diagnostics: ?*errors.DiagnosticList, span: ast.Span, stdlib_paths: []const []const u8, import_graph: ?*std.StringHashMap(std.StringHashMap(void)), comptime_ctx: ComptimeContext, ) anyerror!ResolvedModule { // Open the directory with iteration capability const dir = std.Io.Dir.openDir(.cwd(), io, dir_path, .{ .iterate = true }) catch { return error.ImportError; }; defer dir.close(io); // Collect all .sx file names var file_names = std.ArrayList([]const u8).empty; var it = dir.iterate(); while (it.next(io) catch null) |entry| { if (entry.kind != .file) continue; if (!std.mem.endsWith(u8, entry.name, ".sx")) continue; const name_copy = try allocator.dupe(u8, entry.name); try file_names.append(allocator, name_copy); } // Sort alphabetically for deterministic ordering std.mem.sort([]const u8, file_names.items, {}, struct { fn lessThan(_: void, a: []const u8, b: []const u8) bool { return std.mem.order(u8, a, b) == .lt; } }.lessThan); // Add directory to chain for circular import detection try chain.put(dir_path, {}); defer _ = chain.remove(dir_path); // Merge all files into a combined module. From an importer's perspective // a directory is one big module: the combined module's `own_decls` is // the union of every file's `own_decls`, so flat-importing the directory // exposes everything the files themselves authored — but not what those // files transitively imported from outside the directory. var combined = ResolvedModule{ .path = dir_path, .decls = &.{}, .own_decls = &.{}, .scope = std.StringHashMap(void).init(allocator), }; var decl_list = std.ArrayList(*Node).empty; var own_decl_list = std.ArrayList(*Node).empty; var seen_in_list = std.StringHashMap(void).init(allocator); for (file_names.items) |file_name| { const file_path = try std.fmt.allocPrint(allocator, "{s}/{s}", .{ dir_path, file_name }); if (chain.contains(file_path)) continue; const file_mod = if (cache.get(file_path)) |cached| cached else file_blk: { const imp_bytes = std.Io.Dir.readFileAlloc(.cwd(), io, file_path, allocator, .limited(10 * 1024 * 1024)) catch { if (diagnostics) |diags| { diags.addFmt(.err, span, "cannot read '{s}' in directory import", .{file_path}); } return error.ImportError; }; const imp_source = try allocator.dupeZ(u8, imp_bytes); if (source_map) |sm| { sm.put(file_path, imp_source) catch {}; } var p = parser.Parser.init(allocator, imp_source); const imp_root = p.parse() catch { if (diagnostics) |diags| { diags.addFmt(.err, span, "parse error in '{s}': {s}", .{ file_path, p.err_msg orelse "unknown" }); } return error.ImportError; }; try chain.put(file_path, {}); const result = try resolveImports(allocator, io, imp_root, dir_path, file_path, chain, cache, source_map, diagnostics, stdlib_paths, import_graph, comptime_ctx); _ = chain.remove(file_path); try cache.put(file_path, result); break :file_blk result; }; // Source-order matters: a file's own decls (e.g. `impl Foo` blocks) // may reference types defined in OTHER files that THIS file imports. // `file_mod.decls` already lists transitive-imported decls before // the file's own decls (resolveImports processes `#import` lines in // source order, and #imports usually come first), so iterating it // directly preserves the scan order the lowering pass needs to // register `Event` (a tagged_union) before `handle_event(e: *Event)` // triggers the placeholder-struct fallback in `resolveTypeName`. for (file_mod.decls) |decl| { if (decl.data.declName()) |name| { if (seen_in_list.contains(name)) continue; try seen_in_list.put(name, {}); } try decl_list.append(allocator, decl); } // Separately track which decls the directory `re-exports` to its // flat-importers. Position in `own_decl_list` doesn't matter — it's // only consumed by the importer-side visibility join (`isNameVisible` // in lower.zig) which treats it as a set. for (file_mod.own_decls) |decl| { if (decl.data.declName()) |name| { if (combined.scope.contains(name)) continue; try combined.scope.put(name, {}); } try own_decl_list.append(allocator, decl); } } try combined.finalize(allocator, &decl_list, &own_decl_list); return combined; }