2388 lines
93 KiB
Zig
2388 lines
93 KiB
Zig
const std = @import("std");
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const mem = std.mem;
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const Allocator = std.mem.Allocator;
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const ArrayListUnmanaged = std.ArrayListUnmanaged;
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const Value = @import("value.zig").Value;
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const Type = @import("type.zig").Type;
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const TypedValue = @import("TypedValue.zig");
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const assert = std.debug.assert;
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const BigIntConst = std.math.big.int.Const;
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const BigIntMutable = std.math.big.int.Mutable;
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const Target = std.Target;
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const Package = @import("Package.zig");
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const link = @import("link.zig");
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const ir = @import("ir.zig");
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const zir = @import("zir.zig");
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const Module = @This();
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const Inst = ir.Inst;
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/// General-purpose allocator.
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allocator: *Allocator,
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/// Pointer to externally managed resource.
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root_pkg: *Package,
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/// Module owns this resource.
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root_scope: *Scope.ZIRModule,
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bin_file: link.ElfFile,
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bin_file_dir: std.fs.Dir,
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bin_file_path: []const u8,
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/// It's rare for a decl to be exported, so we save memory by having a sparse map of
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/// Decl pointers to details about them being exported.
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/// The Export memory is owned by the `export_owners` table; the slice itself is owned by this table.
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decl_exports: std.AutoHashMap(*Decl, []*Export),
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/// This models the Decls that perform exports, so that `decl_exports` can be updated when a Decl
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/// is modified. Note that the key of this table is not the Decl being exported, but the Decl that
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/// is performing the export of another Decl.
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/// This table owns the Export memory.
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export_owners: std.AutoHashMap(*Decl, []*Export),
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/// Maps fully qualified namespaced names to the Decl struct for them.
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decl_table: std.AutoHashMap(Decl.Hash, *Decl),
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optimize_mode: std.builtin.Mode,
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link_error_flags: link.ElfFile.ErrorFlags = link.ElfFile.ErrorFlags{},
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work_queue: std.fifo.LinearFifo(WorkItem, .Dynamic),
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/// We optimize memory usage for a compilation with no compile errors by storing the
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/// error messages and mapping outside of `Decl`.
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/// The ErrorMsg memory is owned by the decl, using Module's allocator.
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/// Note that a Decl can succeed but the Fn it represents can fail. In this case,
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/// a Decl can have a failed_decls entry but have analysis status of success.
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failed_decls: std.AutoHashMap(*Decl, *ErrorMsg),
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/// Using a map here for consistency with the other fields here.
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/// The ErrorMsg memory is owned by the `Scope.ZIRModule`, using Module's allocator.
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failed_files: std.AutoHashMap(*Scope.ZIRModule, *ErrorMsg),
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/// Using a map here for consistency with the other fields here.
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/// The ErrorMsg memory is owned by the `Export`, using Module's allocator.
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failed_exports: std.AutoHashMap(*Export, *ErrorMsg),
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/// Incrementing integer used to compare against the corresponding Decl
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/// field to determine whether a Decl's status applies to an ongoing update, or a
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/// previous analysis.
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generation: u32 = 0,
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/// Candidates for deletion. After a semantic analysis update completes, this list
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/// contains Decls that need to be deleted if they end up having no references to them.
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deletion_set: std.ArrayListUnmanaged(*Decl) = std.ArrayListUnmanaged(*Decl){},
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pub const WorkItem = union(enum) {
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/// Write the machine code for a Decl to the output file.
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codegen_decl: *Decl,
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/// Decl has been determined to be outdated; perform semantic analysis again.
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re_analyze_decl: *Decl,
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};
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pub const Export = struct {
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options: std.builtin.ExportOptions,
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/// Byte offset into the file that contains the export directive.
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src: usize,
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/// Represents the position of the export, if any, in the output file.
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link: link.ElfFile.Export,
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/// The Decl that performs the export. Note that this is *not* the Decl being exported.
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owner_decl: *Decl,
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/// The Decl being exported. Note this is *not* the Decl performing the export.
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exported_decl: *Decl,
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status: enum {
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in_progress,
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failed,
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/// Indicates that the failure was due to a temporary issue, such as an I/O error
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/// when writing to the output file. Retrying the export may succeed.
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failed_retryable,
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complete,
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},
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};
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pub const Decl = struct {
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/// This name is relative to the containing namespace of the decl. It uses a null-termination
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/// to save bytes, since there can be a lot of decls in a compilation. The null byte is not allowed
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/// in symbol names, because executable file formats use null-terminated strings for symbol names.
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/// All Decls have names, even values that are not bound to a zig namespace. This is necessary for
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/// mapping them to an address in the output file.
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/// Memory owned by this decl, using Module's allocator.
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name: [*:0]const u8,
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/// The direct parent container of the Decl. This field will need to get more fleshed out when
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/// self-hosted supports proper struct types and Zig AST => ZIR.
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/// Reference to externally owned memory.
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scope: *Scope.ZIRModule,
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/// Byte offset into the source file that contains this declaration.
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/// This is the base offset that src offsets within this Decl are relative to.
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src: usize,
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/// The most recent value of the Decl after a successful semantic analysis.
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typed_value: union(enum) {
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never_succeeded: void,
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most_recent: TypedValue.Managed,
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},
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/// Represents the "shallow" analysis status. For example, for decls that are functions,
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/// the function type is analyzed with this set to `in_progress`, however, the semantic
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/// analysis of the function body is performed with this value set to `success`. Functions
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/// have their own analysis status field.
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analysis: enum {
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/// Semantic analysis for this Decl is running right now. This state detects dependency loops.
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in_progress,
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/// This Decl might be OK but it depends on another one which did not successfully complete
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/// semantic analysis.
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dependency_failure,
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/// Semantic analysis failure.
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/// There will be a corresponding ErrorMsg in Module.failed_decls.
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sema_failure,
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/// There will be a corresponding ErrorMsg in Module.failed_decls.
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codegen_failure,
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/// There will be a corresponding ErrorMsg in Module.failed_decls.
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/// This indicates the failure was something like running out of disk space,
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/// and attempting codegen again may succeed.
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codegen_failure_retryable,
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/// Everything is done. During an update, this Decl may be out of date, depending
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/// on its dependencies. The `generation` field can be used to determine if this
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/// completion status occurred before or after a given update.
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complete,
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/// A Module update is in progress, and this Decl has been flagged as being known
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/// to require re-analysis.
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outdated,
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},
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/// This flag is set when this Decl is added to a check_for_deletion set, and cleared
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/// when removed.
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deletion_flag: bool,
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/// An integer that can be checked against the corresponding incrementing
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/// generation field of Module. This is used to determine whether `complete` status
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/// represents pre- or post- re-analysis.
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generation: u32,
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/// Represents the position of the code in the output file.
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/// This is populated regardless of semantic analysis and code generation.
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link: link.ElfFile.TextBlock = link.ElfFile.TextBlock.empty,
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contents_hash: Hash,
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/// The shallow set of other decls whose typed_value could possibly change if this Decl's
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/// typed_value is modified.
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dependants: ArrayListUnmanaged(*Decl) = ArrayListUnmanaged(*Decl){},
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/// The shallow set of other decls whose typed_value changing indicates that this Decl's
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/// typed_value may need to be regenerated.
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dependencies: ArrayListUnmanaged(*Decl) = ArrayListUnmanaged(*Decl){},
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pub fn destroy(self: *Decl, allocator: *Allocator) void {
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allocator.free(mem.spanZ(self.name));
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if (self.typedValueManaged()) |tvm| {
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tvm.deinit(allocator);
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}
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self.dependants.deinit(allocator);
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self.dependencies.deinit(allocator);
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allocator.destroy(self);
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}
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pub const Hash = [16]u8;
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/// If the name is small enough, it is used directly as the hash.
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/// If it is long, blake3 hash is computed.
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pub fn hashSimpleName(name: []const u8) Hash {
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var out: Hash = undefined;
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if (name.len <= Hash.len) {
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mem.copy(u8, &out, name);
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mem.set(u8, out[name.len..], 0);
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} else {
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std.crypto.Blake3.hash(name, &out);
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}
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return out;
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}
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/// Must generate unique bytes with no collisions with other decls.
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/// The point of hashing here is only to limit the number of bytes of
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/// the unique identifier to a fixed size (16 bytes).
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pub fn fullyQualifiedNameHash(self: Decl) Hash {
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// Right now we only have ZIRModule as the source. So this is simply the
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// relative name of the decl.
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return hashSimpleName(mem.spanZ(self.name));
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}
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pub fn typedValue(self: *Decl) error{AnalysisFail}!TypedValue {
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const tvm = self.typedValueManaged() orelse return error.AnalysisFail;
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return tvm.typed_value;
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}
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pub fn value(self: *Decl) error{AnalysisFail}!Value {
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return (try self.typedValue()).val;
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}
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pub fn dump(self: *Decl) void {
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const loc = std.zig.findLineColumn(self.scope.source.bytes, self.src);
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std.debug.warn("{}:{}:{} name={} status={}", .{
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self.scope.sub_file_path,
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loc.line + 1,
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loc.column + 1,
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mem.spanZ(self.name),
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@tagName(self.analysis),
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});
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if (self.typedValueManaged()) |tvm| {
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std.debug.warn(" ty={} val={}", .{ tvm.typed_value.ty, tvm.typed_value.val });
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}
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std.debug.warn("\n", .{});
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}
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fn typedValueManaged(self: *Decl) ?*TypedValue.Managed {
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switch (self.typed_value) {
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.most_recent => |*x| return x,
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.never_succeeded => return null,
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}
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}
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fn removeDependant(self: *Decl, other: *Decl) void {
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for (self.dependants.items) |item, i| {
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if (item == other) {
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_ = self.dependants.swapRemove(i);
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return;
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}
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}
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unreachable;
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}
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fn removeDependency(self: *Decl, other: *Decl) void {
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for (self.dependencies.items) |item, i| {
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if (item == other) {
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_ = self.dependencies.swapRemove(i);
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return;
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}
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}
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unreachable;
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}
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};
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/// Fn struct memory is owned by the Decl's TypedValue.Managed arena allocator.
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pub const Fn = struct {
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/// This memory owned by the Decl's TypedValue.Managed arena allocator.
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fn_type: Type,
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analysis: union(enum) {
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/// The value is the source instruction.
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queued: *zir.Inst.Fn,
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in_progress: *Analysis,
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/// There will be a corresponding ErrorMsg in Module.failed_decls
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sema_failure,
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/// This Fn might be OK but it depends on another Decl which did not successfully complete
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/// semantic analysis.
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dependency_failure,
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success: Body,
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},
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owner_decl: *Decl,
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/// This memory is temporary and points to stack memory for the duration
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/// of Fn analysis.
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pub const Analysis = struct {
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inner_block: Scope.Block,
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/// TODO Performance optimization idea: instead of this inst_table,
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/// use a field in the zir.Inst instead to track corresponding instructions
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inst_table: std.AutoHashMap(*zir.Inst, *Inst),
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needed_inst_capacity: usize,
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};
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};
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pub const Scope = struct {
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tag: Tag,
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pub fn cast(base: *Scope, comptime T: type) ?*T {
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if (base.tag != T.base_tag)
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return null;
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return @fieldParentPtr(T, "base", base);
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}
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/// Asserts the scope has a parent which is a DeclAnalysis and
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/// returns the arena Allocator.
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pub fn arena(self: *Scope) *Allocator {
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switch (self.tag) {
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.block => return self.cast(Block).?.arena,
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.decl => return &self.cast(DeclAnalysis).?.arena.allocator,
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.zir_module => return &self.cast(ZIRModule).?.contents.module.arena.allocator,
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}
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}
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/// Asserts the scope has a parent which is a DeclAnalysis and
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/// returns the Decl.
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|
pub fn decl(self: *Scope) ?*Decl {
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return switch (self.tag) {
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.block => self.cast(Block).?.decl,
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.decl => self.cast(DeclAnalysis).?.decl,
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.zir_module => null,
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};
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}
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/// Asserts the scope has a parent which is a ZIRModule and
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/// returns it.
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pub fn namespace(self: *Scope) *ZIRModule {
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switch (self.tag) {
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.block => return self.cast(Block).?.decl.scope,
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.decl => return self.cast(DeclAnalysis).?.decl.scope,
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.zir_module => return self.cast(ZIRModule).?,
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}
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}
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pub fn dumpInst(self: *Scope, inst: *Inst) void {
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const zir_module = self.namespace();
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const loc = std.zig.findLineColumn(zir_module.source.bytes, inst.src);
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std.debug.warn("{}:{}:{}: {}: ty={}\n", .{
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zir_module.sub_file_path,
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loc.line + 1,
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loc.column + 1,
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@tagName(inst.tag),
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inst.ty,
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});
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}
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pub const Tag = enum {
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zir_module,
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block,
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decl,
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};
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pub const ZIRModule = struct {
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pub const base_tag: Tag = .zir_module;
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base: Scope = Scope{ .tag = base_tag },
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/// Relative to the owning package's root_src_dir.
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|
/// Reference to external memory, not owned by ZIRModule.
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sub_file_path: []const u8,
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source: union(enum) {
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unloaded: void,
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bytes: [:0]const u8,
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},
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contents: union {
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not_available: void,
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module: *zir.Module,
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},
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|
status: enum {
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never_loaded,
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unloaded_success,
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unloaded_parse_failure,
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unloaded_sema_failure,
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loaded_sema_failure,
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loaded_success,
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},
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pub fn unload(self: *ZIRModule, allocator: *Allocator) void {
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switch (self.status) {
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.never_loaded,
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.unloaded_parse_failure,
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.unloaded_sema_failure,
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.unloaded_success,
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=> {},
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.loaded_success => {
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self.contents.module.deinit(allocator);
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allocator.destroy(self.contents.module);
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self.status = .unloaded_success;
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},
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.loaded_sema_failure => {
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self.contents.module.deinit(allocator);
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allocator.destroy(self.contents.module);
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self.status = .unloaded_sema_failure;
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},
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}
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switch (self.source) {
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.bytes => |bytes| {
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allocator.free(bytes);
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self.source = .{ .unloaded = {} };
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},
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|
.unloaded => {},
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}
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}
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pub fn deinit(self: *ZIRModule, allocator: *Allocator) void {
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self.unload(allocator);
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self.* = undefined;
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}
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|
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pub fn dumpSrc(self: *ZIRModule, src: usize) void {
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const loc = std.zig.findLineColumn(self.source.bytes, src);
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std.debug.warn("{}:{}:{}\n", .{ self.sub_file_path, loc.line + 1, loc.column + 1 });
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|
}
|
|
};
|
|
|
|
/// This is a temporary structure, references to it are valid only
|
|
/// during semantic analysis of the block.
|
|
pub const Block = struct {
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|
pub const base_tag: Tag = .block;
|
|
base: Scope = Scope{ .tag = base_tag },
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|
func: *Fn,
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|
decl: *Decl,
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|
instructions: ArrayListUnmanaged(*Inst),
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|
/// Points to the arena allocator of DeclAnalysis
|
|
arena: *Allocator,
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|
};
|
|
|
|
/// This is a temporary structure, references to it are valid only
|
|
/// during semantic analysis of the decl.
|
|
pub const DeclAnalysis = struct {
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|
pub const base_tag: Tag = .decl;
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|
base: Scope = Scope{ .tag = base_tag },
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|
decl: *Decl,
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|
arena: std.heap.ArenaAllocator,
|
|
};
|
|
};
|
|
|
|
pub const Body = struct {
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|
instructions: []*Inst,
|
|
};
|
|
|
|
pub const AllErrors = struct {
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|
arena: std.heap.ArenaAllocator.State,
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|
list: []const Message,
|
|
|
|
pub const Message = struct {
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|
src_path: []const u8,
|
|
line: usize,
|
|
column: usize,
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|
byte_offset: usize,
|
|
msg: []const u8,
|
|
};
|
|
|
|
pub fn deinit(self: *AllErrors, allocator: *Allocator) void {
|
|
self.arena.promote(allocator).deinit();
|
|
}
|
|
|
|
fn add(
|
|
arena: *std.heap.ArenaAllocator,
|
|
errors: *std.ArrayList(Message),
|
|
sub_file_path: []const u8,
|
|
source: []const u8,
|
|
simple_err_msg: ErrorMsg,
|
|
) !void {
|
|
const loc = std.zig.findLineColumn(source, simple_err_msg.byte_offset);
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|
try errors.append(.{
|
|
.src_path = try arena.allocator.dupe(u8, sub_file_path),
|
|
.msg = try arena.allocator.dupe(u8, simple_err_msg.msg),
|
|
.byte_offset = simple_err_msg.byte_offset,
|
|
.line = loc.line,
|
|
.column = loc.column,
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|
});
|
|
}
|
|
};
|
|
|
|
pub const InitOptions = struct {
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|
target: std.Target,
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|
root_pkg: *Package,
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|
output_mode: std.builtin.OutputMode,
|
|
bin_file_dir: ?std.fs.Dir = null,
|
|
bin_file_path: []const u8,
|
|
link_mode: ?std.builtin.LinkMode = null,
|
|
object_format: ?std.builtin.ObjectFormat = null,
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|
optimize_mode: std.builtin.Mode = .Debug,
|
|
};
|
|
|
|
pub fn init(gpa: *Allocator, options: InitOptions) !Module {
|
|
const root_scope = try gpa.create(Scope.ZIRModule);
|
|
errdefer gpa.destroy(root_scope);
|
|
|
|
root_scope.* = .{
|
|
.sub_file_path = options.root_pkg.root_src_path,
|
|
.source = .{ .unloaded = {} },
|
|
.contents = .{ .not_available = {} },
|
|
.status = .never_loaded,
|
|
};
|
|
|
|
const bin_file_dir = options.bin_file_dir orelse std.fs.cwd();
|
|
var bin_file = try link.openBinFilePath(gpa, bin_file_dir, options.bin_file_path, .{
|
|
.target = options.target,
|
|
.output_mode = options.output_mode,
|
|
.link_mode = options.link_mode orelse .Static,
|
|
.object_format = options.object_format orelse options.target.getObjectFormat(),
|
|
});
|
|
errdefer bin_file.deinit();
|
|
|
|
return Module{
|
|
.allocator = gpa,
|
|
.root_pkg = options.root_pkg,
|
|
.root_scope = root_scope,
|
|
.bin_file_dir = bin_file_dir,
|
|
.bin_file_path = options.bin_file_path,
|
|
.bin_file = bin_file,
|
|
.optimize_mode = options.optimize_mode,
|
|
.decl_table = std.AutoHashMap(Decl.Hash, *Decl).init(gpa),
|
|
.decl_exports = std.AutoHashMap(*Decl, []*Export).init(gpa),
|
|
.export_owners = std.AutoHashMap(*Decl, []*Export).init(gpa),
|
|
.failed_decls = std.AutoHashMap(*Decl, *ErrorMsg).init(gpa),
|
|
.failed_files = std.AutoHashMap(*Scope.ZIRModule, *ErrorMsg).init(gpa),
|
|
.failed_exports = std.AutoHashMap(*Export, *ErrorMsg).init(gpa),
|
|
.work_queue = std.fifo.LinearFifo(WorkItem, .Dynamic).init(gpa),
|
|
};
|
|
}
|
|
|
|
pub fn deinit(self: *Module) void {
|
|
self.bin_file.deinit();
|
|
const allocator = self.allocator;
|
|
self.deletion_set.deinit(allocator);
|
|
self.work_queue.deinit();
|
|
{
|
|
var it = self.decl_table.iterator();
|
|
while (it.next()) |kv| {
|
|
kv.value.destroy(allocator);
|
|
}
|
|
self.decl_table.deinit();
|
|
}
|
|
{
|
|
var it = self.failed_decls.iterator();
|
|
while (it.next()) |kv| {
|
|
kv.value.destroy(allocator);
|
|
}
|
|
self.failed_decls.deinit();
|
|
}
|
|
{
|
|
var it = self.failed_files.iterator();
|
|
while (it.next()) |kv| {
|
|
kv.value.destroy(allocator);
|
|
}
|
|
self.failed_files.deinit();
|
|
}
|
|
{
|
|
var it = self.failed_exports.iterator();
|
|
while (it.next()) |kv| {
|
|
kv.value.destroy(allocator);
|
|
}
|
|
self.failed_exports.deinit();
|
|
}
|
|
{
|
|
var it = self.decl_exports.iterator();
|
|
while (it.next()) |kv| {
|
|
const export_list = kv.value;
|
|
allocator.free(export_list);
|
|
}
|
|
self.decl_exports.deinit();
|
|
}
|
|
{
|
|
var it = self.export_owners.iterator();
|
|
while (it.next()) |kv| {
|
|
freeExportList(allocator, kv.value);
|
|
}
|
|
self.export_owners.deinit();
|
|
}
|
|
{
|
|
self.root_scope.deinit(allocator);
|
|
allocator.destroy(self.root_scope);
|
|
}
|
|
self.* = undefined;
|
|
}
|
|
|
|
fn freeExportList(allocator: *Allocator, export_list: []*Export) void {
|
|
for (export_list) |exp| {
|
|
allocator.destroy(exp);
|
|
}
|
|
allocator.free(export_list);
|
|
}
|
|
|
|
pub fn target(self: Module) std.Target {
|
|
return self.bin_file.options.target;
|
|
}
|
|
|
|
/// Detect changes to source files, perform semantic analysis, and update the output files.
|
|
pub fn update(self: *Module) !void {
|
|
self.generation += 1;
|
|
|
|
// TODO Use the cache hash file system to detect which source files changed.
|
|
// Here we simulate a full cache miss.
|
|
// Analyze the root source file now.
|
|
// Source files could have been loaded for any reason; to force a refresh we unload now.
|
|
self.root_scope.unload(self.allocator);
|
|
self.analyzeRoot(self.root_scope) catch |err| switch (err) {
|
|
error.AnalysisFail => {
|
|
assert(self.totalErrorCount() != 0);
|
|
},
|
|
else => |e| return e,
|
|
};
|
|
|
|
try self.performAllTheWork();
|
|
|
|
// Process the deletion set.
|
|
while (self.deletion_set.popOrNull()) |decl| {
|
|
if (decl.dependants.items.len != 0) {
|
|
decl.deletion_flag = false;
|
|
continue;
|
|
}
|
|
try self.deleteDecl(decl);
|
|
}
|
|
|
|
// If there are any errors, we anticipate the source files being loaded
|
|
// to report error messages. Otherwise we unload all source files to save memory.
|
|
if (self.totalErrorCount() == 0) {
|
|
self.root_scope.unload(self.allocator);
|
|
}
|
|
|
|
try self.bin_file.flush();
|
|
self.link_error_flags = self.bin_file.error_flags;
|
|
}
|
|
|
|
/// Having the file open for writing is problematic as far as executing the
|
|
/// binary is concerned. This will remove the write flag, or close the file,
|
|
/// or whatever is needed so that it can be executed.
|
|
/// After this, one must call` makeFileWritable` before calling `update`.
|
|
pub fn makeBinFileExecutable(self: *Module) !void {
|
|
return self.bin_file.makeExecutable();
|
|
}
|
|
|
|
pub fn makeBinFileWritable(self: *Module) !void {
|
|
return self.bin_file.makeWritable(self.bin_file_dir, self.bin_file_path);
|
|
}
|
|
|
|
pub fn totalErrorCount(self: *Module) usize {
|
|
return self.failed_decls.size +
|
|
self.failed_files.size +
|
|
self.failed_exports.size +
|
|
@boolToInt(self.link_error_flags.no_entry_point_found);
|
|
}
|
|
|
|
pub fn getAllErrorsAlloc(self: *Module) !AllErrors {
|
|
var arena = std.heap.ArenaAllocator.init(self.allocator);
|
|
errdefer arena.deinit();
|
|
|
|
var errors = std.ArrayList(AllErrors.Message).init(self.allocator);
|
|
defer errors.deinit();
|
|
|
|
{
|
|
var it = self.failed_files.iterator();
|
|
while (it.next()) |kv| {
|
|
const scope = kv.key;
|
|
const err_msg = kv.value;
|
|
const source = try self.getSource(scope);
|
|
try AllErrors.add(&arena, &errors, scope.sub_file_path, source, err_msg.*);
|
|
}
|
|
}
|
|
{
|
|
var it = self.failed_decls.iterator();
|
|
while (it.next()) |kv| {
|
|
const decl = kv.key;
|
|
const err_msg = kv.value;
|
|
const source = try self.getSource(decl.scope);
|
|
try AllErrors.add(&arena, &errors, decl.scope.sub_file_path, source, err_msg.*);
|
|
}
|
|
}
|
|
{
|
|
var it = self.failed_exports.iterator();
|
|
while (it.next()) |kv| {
|
|
const decl = kv.key.owner_decl;
|
|
const err_msg = kv.value;
|
|
const source = try self.getSource(decl.scope);
|
|
try AllErrors.add(&arena, &errors, decl.scope.sub_file_path, source, err_msg.*);
|
|
}
|
|
}
|
|
|
|
if (self.link_error_flags.no_entry_point_found) {
|
|
try errors.append(.{
|
|
.src_path = self.root_pkg.root_src_path,
|
|
.line = 0,
|
|
.column = 0,
|
|
.byte_offset = 0,
|
|
.msg = try std.fmt.allocPrint(&arena.allocator, "no entry point found", .{}),
|
|
});
|
|
}
|
|
|
|
assert(errors.items.len == self.totalErrorCount());
|
|
|
|
return AllErrors{
|
|
.list = try arena.allocator.dupe(AllErrors.Message, errors.items),
|
|
.arena = arena.state,
|
|
};
|
|
}
|
|
|
|
const InnerError = error{ OutOfMemory, AnalysisFail };
|
|
|
|
pub fn performAllTheWork(self: *Module) error{OutOfMemory}!void {
|
|
while (self.work_queue.readItem()) |work_item| switch (work_item) {
|
|
.codegen_decl => |decl| switch (decl.analysis) {
|
|
.in_progress => unreachable,
|
|
.outdated => unreachable,
|
|
|
|
.sema_failure,
|
|
.codegen_failure,
|
|
.dependency_failure,
|
|
=> continue,
|
|
|
|
.complete, .codegen_failure_retryable => {
|
|
if (decl.typed_value.most_recent.typed_value.val.cast(Value.Payload.Function)) |payload| {
|
|
switch (payload.func.analysis) {
|
|
.queued => self.analyzeFnBody(decl, payload.func) catch |err| switch (err) {
|
|
error.AnalysisFail => {
|
|
if (payload.func.analysis == .queued) {
|
|
payload.func.analysis = .dependency_failure;
|
|
}
|
|
continue;
|
|
},
|
|
else => |e| return e,
|
|
},
|
|
.in_progress => unreachable,
|
|
.sema_failure, .dependency_failure => continue,
|
|
.success => {},
|
|
}
|
|
}
|
|
|
|
assert(decl.typed_value.most_recent.typed_value.ty.hasCodeGenBits());
|
|
|
|
self.bin_file.updateDecl(self, decl) catch |err| switch (err) {
|
|
error.OutOfMemory => return error.OutOfMemory,
|
|
error.AnalysisFail => {
|
|
decl.analysis = .dependency_failure;
|
|
},
|
|
else => {
|
|
try self.failed_decls.ensureCapacity(self.failed_decls.size + 1);
|
|
self.failed_decls.putAssumeCapacityNoClobber(decl, try ErrorMsg.create(
|
|
self.allocator,
|
|
decl.src,
|
|
"unable to codegen: {}",
|
|
.{@errorName(err)},
|
|
));
|
|
decl.analysis = .codegen_failure_retryable;
|
|
},
|
|
};
|
|
},
|
|
},
|
|
.re_analyze_decl => |decl| switch (decl.analysis) {
|
|
.in_progress => unreachable,
|
|
|
|
.sema_failure,
|
|
.codegen_failure,
|
|
.dependency_failure,
|
|
.complete,
|
|
.codegen_failure_retryable,
|
|
=> continue,
|
|
|
|
.outdated => {
|
|
const zir_module = self.getSrcModule(decl.scope) catch |err| switch (err) {
|
|
error.OutOfMemory => return error.OutOfMemory,
|
|
else => {
|
|
try self.failed_decls.ensureCapacity(self.failed_decls.size + 1);
|
|
self.failed_decls.putAssumeCapacityNoClobber(decl, try ErrorMsg.create(
|
|
self.allocator,
|
|
decl.src,
|
|
"unable to load source file '{}': {}",
|
|
.{ decl.scope.sub_file_path, @errorName(err) },
|
|
));
|
|
decl.analysis = .codegen_failure_retryable;
|
|
continue;
|
|
},
|
|
};
|
|
const decl_name = mem.spanZ(decl.name);
|
|
// We already detected deletions, so we know this will be found.
|
|
const src_decl = zir_module.findDecl(decl_name).?;
|
|
self.reAnalyzeDecl(decl, src_decl) catch |err| switch (err) {
|
|
error.OutOfMemory => return error.OutOfMemory,
|
|
error.AnalysisFail => continue,
|
|
};
|
|
},
|
|
},
|
|
};
|
|
}
|
|
|
|
fn declareDeclDependency(self: *Module, depender: *Decl, dependee: *Decl) !void {
|
|
try depender.dependencies.ensureCapacity(self.allocator, depender.dependencies.items.len + 1);
|
|
try dependee.dependants.ensureCapacity(self.allocator, dependee.dependants.items.len + 1);
|
|
|
|
for (depender.dependencies.items) |item| {
|
|
if (item == dependee) break; // Already in the set.
|
|
} else {
|
|
depender.dependencies.appendAssumeCapacity(dependee);
|
|
}
|
|
|
|
for (dependee.dependants.items) |item| {
|
|
if (item == depender) break; // Already in the set.
|
|
} else {
|
|
dependee.dependants.appendAssumeCapacity(depender);
|
|
}
|
|
}
|
|
|
|
fn getSource(self: *Module, root_scope: *Scope.ZIRModule) ![:0]const u8 {
|
|
switch (root_scope.source) {
|
|
.unloaded => {
|
|
const source = try self.root_pkg.root_src_dir.readFileAllocOptions(
|
|
self.allocator,
|
|
root_scope.sub_file_path,
|
|
std.math.maxInt(u32),
|
|
1,
|
|
0,
|
|
);
|
|
root_scope.source = .{ .bytes = source };
|
|
return source;
|
|
},
|
|
.bytes => |bytes| return bytes,
|
|
}
|
|
}
|
|
|
|
fn getSrcModule(self: *Module, root_scope: *Scope.ZIRModule) !*zir.Module {
|
|
switch (root_scope.status) {
|
|
.never_loaded, .unloaded_success => {
|
|
try self.failed_files.ensureCapacity(self.failed_files.size + 1);
|
|
|
|
const source = try self.getSource(root_scope);
|
|
|
|
var keep_zir_module = false;
|
|
const zir_module = try self.allocator.create(zir.Module);
|
|
defer if (!keep_zir_module) self.allocator.destroy(zir_module);
|
|
|
|
zir_module.* = try zir.parse(self.allocator, source);
|
|
defer if (!keep_zir_module) zir_module.deinit(self.allocator);
|
|
|
|
if (zir_module.error_msg) |src_err_msg| {
|
|
self.failed_files.putAssumeCapacityNoClobber(
|
|
root_scope,
|
|
try ErrorMsg.create(self.allocator, src_err_msg.byte_offset, "{}", .{src_err_msg.msg}),
|
|
);
|
|
root_scope.status = .unloaded_parse_failure;
|
|
return error.AnalysisFail;
|
|
}
|
|
|
|
root_scope.status = .loaded_success;
|
|
root_scope.contents = .{ .module = zir_module };
|
|
keep_zir_module = true;
|
|
|
|
return zir_module;
|
|
},
|
|
|
|
.unloaded_parse_failure,
|
|
.unloaded_sema_failure,
|
|
=> return error.AnalysisFail,
|
|
|
|
.loaded_success, .loaded_sema_failure => return root_scope.contents.module,
|
|
}
|
|
}
|
|
|
|
fn analyzeRoot(self: *Module, root_scope: *Scope.ZIRModule) !void {
|
|
switch (root_scope.status) {
|
|
.never_loaded => {
|
|
const src_module = try self.getSrcModule(root_scope);
|
|
|
|
// Here we ensure enough queue capacity to store all the decls, so that later we can use
|
|
// appendAssumeCapacity.
|
|
try self.work_queue.ensureUnusedCapacity(src_module.decls.len);
|
|
|
|
for (src_module.decls) |decl| {
|
|
if (decl.cast(zir.Inst.Export)) |export_inst| {
|
|
_ = try self.resolveDecl(&root_scope.base, &export_inst.base);
|
|
}
|
|
}
|
|
},
|
|
|
|
.unloaded_parse_failure,
|
|
.unloaded_sema_failure,
|
|
.unloaded_success,
|
|
.loaded_sema_failure,
|
|
.loaded_success,
|
|
=> {
|
|
const src_module = try self.getSrcModule(root_scope);
|
|
|
|
var exports_to_resolve = std.ArrayList(*zir.Inst).init(self.allocator);
|
|
defer exports_to_resolve.deinit();
|
|
|
|
// Keep track of the decls that we expect to see in this file so that
|
|
// we know which ones have been deleted.
|
|
var deleted_decls = std.AutoHashMap(*Decl, void).init(self.allocator);
|
|
defer deleted_decls.deinit();
|
|
try deleted_decls.ensureCapacity(self.decl_table.size);
|
|
{
|
|
var it = self.decl_table.iterator();
|
|
while (it.next()) |kv| {
|
|
deleted_decls.putAssumeCapacityNoClobber(kv.value, {});
|
|
}
|
|
}
|
|
|
|
for (src_module.decls) |src_decl| {
|
|
const name_hash = Decl.hashSimpleName(src_decl.name);
|
|
if (self.decl_table.get(name_hash)) |kv| {
|
|
const decl = kv.value;
|
|
deleted_decls.removeAssertDiscard(decl);
|
|
const new_contents_hash = Decl.hashSimpleName(src_decl.contents);
|
|
//std.debug.warn("'{}' contents: '{}'\n", .{ src_decl.name, src_decl.contents });
|
|
if (!mem.eql(u8, &new_contents_hash, &decl.contents_hash)) {
|
|
//std.debug.warn("'{}' {x} => {x}\n", .{ src_decl.name, decl.contents_hash, new_contents_hash });
|
|
try self.markOutdatedDecl(decl);
|
|
decl.contents_hash = new_contents_hash;
|
|
}
|
|
} else if (src_decl.cast(zir.Inst.Export)) |export_inst| {
|
|
try exports_to_resolve.append(&export_inst.base);
|
|
}
|
|
}
|
|
{
|
|
// Handle explicitly deleted decls from the source code. Not to be confused
|
|
// with when we delete decls because they are no longer referenced.
|
|
var it = deleted_decls.iterator();
|
|
while (it.next()) |kv| {
|
|
//std.debug.warn("noticed '{}' deleted from source\n", .{kv.key.name});
|
|
try self.deleteDecl(kv.key);
|
|
}
|
|
}
|
|
for (exports_to_resolve.items) |export_inst| {
|
|
_ = try self.resolveDecl(&root_scope.base, export_inst);
|
|
}
|
|
},
|
|
}
|
|
}
|
|
|
|
fn deleteDecl(self: *Module, decl: *Decl) !void {
|
|
try self.deletion_set.ensureCapacity(self.allocator, self.deletion_set.items.len + decl.dependencies.items.len);
|
|
|
|
//std.debug.warn("deleting decl '{}'\n", .{decl.name});
|
|
const name_hash = decl.fullyQualifiedNameHash();
|
|
self.decl_table.removeAssertDiscard(name_hash);
|
|
// Remove itself from its dependencies, because we are about to destroy the decl pointer.
|
|
for (decl.dependencies.items) |dep| {
|
|
dep.removeDependant(decl);
|
|
if (dep.dependants.items.len == 0) {
|
|
// We don't recursively perform a deletion here, because during the update,
|
|
// another reference to it may turn up.
|
|
assert(!dep.deletion_flag);
|
|
dep.deletion_flag = true;
|
|
self.deletion_set.appendAssumeCapacity(dep);
|
|
}
|
|
}
|
|
// Anything that depends on this deleted decl certainly needs to be re-analyzed.
|
|
for (decl.dependants.items) |dep| {
|
|
dep.removeDependency(decl);
|
|
if (dep.analysis != .outdated) {
|
|
// TODO Move this failure possibility to the top of the function.
|
|
try self.markOutdatedDecl(dep);
|
|
}
|
|
}
|
|
if (self.failed_decls.remove(decl)) |entry| {
|
|
entry.value.destroy(self.allocator);
|
|
}
|
|
self.deleteDeclExports(decl);
|
|
self.bin_file.freeDecl(decl);
|
|
decl.destroy(self.allocator);
|
|
}
|
|
|
|
/// Delete all the Export objects that are caused by this Decl. Re-analysis of
|
|
/// this Decl will cause them to be re-created (or not).
|
|
fn deleteDeclExports(self: *Module, decl: *Decl) void {
|
|
const kv = self.export_owners.remove(decl) orelse return;
|
|
|
|
for (kv.value) |exp| {
|
|
if (self.decl_exports.get(exp.exported_decl)) |decl_exports_kv| {
|
|
// Remove exports with owner_decl matching the regenerating decl.
|
|
const list = decl_exports_kv.value;
|
|
var i: usize = 0;
|
|
var new_len = list.len;
|
|
while (i < new_len) {
|
|
if (list[i].owner_decl == decl) {
|
|
mem.copyBackwards(*Export, list[i..], list[i + 1 .. new_len]);
|
|
new_len -= 1;
|
|
} else {
|
|
i += 1;
|
|
}
|
|
}
|
|
decl_exports_kv.value = self.allocator.shrink(list, new_len);
|
|
if (new_len == 0) {
|
|
self.decl_exports.removeAssertDiscard(exp.exported_decl);
|
|
}
|
|
}
|
|
|
|
self.bin_file.deleteExport(exp.link);
|
|
self.allocator.destroy(exp);
|
|
}
|
|
self.allocator.free(kv.value);
|
|
}
|
|
|
|
fn analyzeFnBody(self: *Module, decl: *Decl, func: *Fn) !void {
|
|
// Use the Decl's arena for function memory.
|
|
var arena = decl.typed_value.most_recent.arena.?.promote(self.allocator);
|
|
defer decl.typed_value.most_recent.arena.?.* = arena.state;
|
|
var analysis: Fn.Analysis = .{
|
|
.inner_block = .{
|
|
.func = func,
|
|
.decl = decl,
|
|
.instructions = .{},
|
|
.arena = &arena.allocator,
|
|
},
|
|
.needed_inst_capacity = 0,
|
|
.inst_table = std.AutoHashMap(*zir.Inst, *Inst).init(self.allocator),
|
|
};
|
|
defer analysis.inner_block.instructions.deinit(self.allocator);
|
|
defer analysis.inst_table.deinit();
|
|
|
|
const fn_inst = func.analysis.queued;
|
|
func.analysis = .{ .in_progress = &analysis };
|
|
|
|
try self.analyzeBody(&analysis.inner_block.base, fn_inst.positionals.body);
|
|
|
|
func.analysis = .{
|
|
.success = .{
|
|
.instructions = try arena.allocator.dupe(*Inst, analysis.inner_block.instructions.items),
|
|
},
|
|
};
|
|
}
|
|
|
|
fn reAnalyzeDecl(self: *Module, decl: *Decl, old_inst: *zir.Inst) InnerError!void {
|
|
switch (decl.analysis) {
|
|
.in_progress => unreachable,
|
|
.dependency_failure,
|
|
.sema_failure,
|
|
.codegen_failure,
|
|
.codegen_failure_retryable,
|
|
.complete,
|
|
=> return,
|
|
|
|
.outdated => {}, // Decl re-analysis
|
|
}
|
|
//std.debug.warn("re-analyzing {}\n", .{decl.name});
|
|
decl.src = old_inst.src;
|
|
|
|
// The exports this Decl performs will be re-discovered, so we remove them here
|
|
// prior to re-analysis.
|
|
self.deleteDeclExports(decl);
|
|
// Dependencies will be re-discovered, so we remove them here prior to re-analysis.
|
|
for (decl.dependencies.items) |dep| {
|
|
dep.removeDependant(decl);
|
|
if (dep.dependants.items.len == 0) {
|
|
// We don't perform a deletion here, because this Decl or another one
|
|
// may end up referencing it before the update is complete.
|
|
assert(!dep.deletion_flag);
|
|
dep.deletion_flag = true;
|
|
try self.deletion_set.append(self.allocator, dep);
|
|
}
|
|
}
|
|
decl.dependencies.shrink(self.allocator, 0);
|
|
var decl_scope: Scope.DeclAnalysis = .{
|
|
.decl = decl,
|
|
.arena = std.heap.ArenaAllocator.init(self.allocator),
|
|
};
|
|
errdefer decl_scope.arena.deinit();
|
|
|
|
const typed_value = self.analyzeInstConst(&decl_scope.base, old_inst) catch |err| switch (err) {
|
|
error.OutOfMemory => return error.OutOfMemory,
|
|
error.AnalysisFail => {
|
|
switch (decl.analysis) {
|
|
.in_progress => decl.analysis = .dependency_failure,
|
|
else => {},
|
|
}
|
|
decl.generation = self.generation;
|
|
return error.AnalysisFail;
|
|
},
|
|
};
|
|
const arena_state = try decl_scope.arena.allocator.create(std.heap.ArenaAllocator.State);
|
|
arena_state.* = decl_scope.arena.state;
|
|
|
|
var prev_type_has_bits = false;
|
|
var type_changed = true;
|
|
|
|
if (decl.typedValueManaged()) |tvm| {
|
|
prev_type_has_bits = tvm.typed_value.ty.hasCodeGenBits();
|
|
type_changed = !tvm.typed_value.ty.eql(typed_value.ty);
|
|
|
|
tvm.deinit(self.allocator);
|
|
}
|
|
decl.typed_value = .{
|
|
.most_recent = .{
|
|
.typed_value = typed_value,
|
|
.arena = arena_state,
|
|
},
|
|
};
|
|
decl.analysis = .complete;
|
|
decl.generation = self.generation;
|
|
if (typed_value.ty.hasCodeGenBits()) {
|
|
// We don't fully codegen the decl until later, but we do need to reserve a global
|
|
// offset table index for it. This allows us to codegen decls out of dependency order,
|
|
// increasing how many computations can be done in parallel.
|
|
try self.bin_file.allocateDeclIndexes(decl);
|
|
try self.work_queue.writeItem(.{ .codegen_decl = decl });
|
|
} else if (prev_type_has_bits) {
|
|
self.bin_file.freeDecl(decl);
|
|
}
|
|
|
|
// If the decl is a function, and the type is the same, we do not need
|
|
// to chase the dependants.
|
|
if (type_changed or typed_value.val.tag() != .function) {
|
|
for (decl.dependants.items) |dep| {
|
|
switch (dep.analysis) {
|
|
.in_progress => unreachable,
|
|
.outdated => continue, // already queued for update
|
|
|
|
.dependency_failure,
|
|
.sema_failure,
|
|
.codegen_failure,
|
|
.codegen_failure_retryable,
|
|
.complete,
|
|
=> if (dep.generation != self.generation) {
|
|
try self.markOutdatedDecl(dep);
|
|
},
|
|
}
|
|
}
|
|
}
|
|
}
|
|
|
|
fn markOutdatedDecl(self: *Module, decl: *Decl) !void {
|
|
//std.debug.warn("mark {} outdated\n", .{decl.name});
|
|
try self.work_queue.writeItem(.{ .re_analyze_decl = decl });
|
|
if (self.failed_decls.remove(decl)) |entry| {
|
|
entry.value.destroy(self.allocator);
|
|
}
|
|
decl.analysis = .outdated;
|
|
}
|
|
|
|
fn resolveDecl(self: *Module, scope: *Scope, old_inst: *zir.Inst) InnerError!*Decl {
|
|
const hash = Decl.hashSimpleName(old_inst.name);
|
|
if (self.decl_table.get(hash)) |kv| {
|
|
const decl = kv.value;
|
|
try self.reAnalyzeDecl(decl, old_inst);
|
|
return decl;
|
|
} else if (old_inst.cast(zir.Inst.DeclVal)) |decl_val| {
|
|
// This is just a named reference to another decl.
|
|
return self.analyzeDeclVal(scope, decl_val);
|
|
} else {
|
|
const new_decl = blk: {
|
|
try self.decl_table.ensureCapacity(self.decl_table.size + 1);
|
|
const new_decl = try self.allocator.create(Decl);
|
|
errdefer self.allocator.destroy(new_decl);
|
|
const name = try mem.dupeZ(self.allocator, u8, old_inst.name);
|
|
errdefer self.allocator.free(name);
|
|
new_decl.* = .{
|
|
.name = name,
|
|
.scope = scope.namespace(),
|
|
.src = old_inst.src,
|
|
.typed_value = .{ .never_succeeded = {} },
|
|
.analysis = .in_progress,
|
|
.deletion_flag = false,
|
|
.contents_hash = Decl.hashSimpleName(old_inst.contents),
|
|
.link = link.ElfFile.TextBlock.empty,
|
|
.generation = 0,
|
|
};
|
|
self.decl_table.putAssumeCapacityNoClobber(hash, new_decl);
|
|
break :blk new_decl;
|
|
};
|
|
|
|
var decl_scope: Scope.DeclAnalysis = .{
|
|
.decl = new_decl,
|
|
.arena = std.heap.ArenaAllocator.init(self.allocator),
|
|
};
|
|
errdefer decl_scope.arena.deinit();
|
|
|
|
const typed_value = self.analyzeInstConst(&decl_scope.base, old_inst) catch |err| switch (err) {
|
|
error.OutOfMemory => return error.OutOfMemory,
|
|
error.AnalysisFail => {
|
|
switch (new_decl.analysis) {
|
|
.in_progress => new_decl.analysis = .dependency_failure,
|
|
else => {},
|
|
}
|
|
new_decl.generation = self.generation;
|
|
return error.AnalysisFail;
|
|
},
|
|
};
|
|
const arena_state = try decl_scope.arena.allocator.create(std.heap.ArenaAllocator.State);
|
|
|
|
arena_state.* = decl_scope.arena.state;
|
|
|
|
new_decl.typed_value = .{
|
|
.most_recent = .{
|
|
.typed_value = typed_value,
|
|
.arena = arena_state,
|
|
},
|
|
};
|
|
new_decl.analysis = .complete;
|
|
new_decl.generation = self.generation;
|
|
if (typed_value.ty.hasCodeGenBits()) {
|
|
// We don't fully codegen the decl until later, but we do need to reserve a global
|
|
// offset table index for it. This allows us to codegen decls out of dependency order,
|
|
// increasing how many computations can be done in parallel.
|
|
try self.bin_file.allocateDeclIndexes(new_decl);
|
|
try self.work_queue.writeItem(.{ .codegen_decl = new_decl });
|
|
}
|
|
return new_decl;
|
|
}
|
|
}
|
|
|
|
/// Declares a dependency on the decl.
|
|
fn resolveCompleteDecl(self: *Module, scope: *Scope, old_inst: *zir.Inst) InnerError!*Decl {
|
|
const decl = try self.resolveDecl(scope, old_inst);
|
|
switch (decl.analysis) {
|
|
.in_progress => unreachable,
|
|
.outdated => unreachable,
|
|
|
|
.dependency_failure,
|
|
.sema_failure,
|
|
.codegen_failure,
|
|
.codegen_failure_retryable,
|
|
=> return error.AnalysisFail,
|
|
|
|
.complete => {},
|
|
}
|
|
if (scope.decl()) |scope_decl| {
|
|
try self.declareDeclDependency(scope_decl, decl);
|
|
}
|
|
return decl;
|
|
}
|
|
|
|
fn resolveInst(self: *Module, scope: *Scope, old_inst: *zir.Inst) InnerError!*Inst {
|
|
if (scope.cast(Scope.Block)) |block| {
|
|
if (block.func.analysis.in_progress.inst_table.get(old_inst)) |kv| {
|
|
return kv.value;
|
|
}
|
|
}
|
|
|
|
const decl = try self.resolveCompleteDecl(scope, old_inst);
|
|
const decl_ref = try self.analyzeDeclRef(scope, old_inst.src, decl);
|
|
return self.analyzeDeref(scope, old_inst.src, decl_ref, old_inst.src);
|
|
}
|
|
|
|
fn requireRuntimeBlock(self: *Module, scope: *Scope, src: usize) !*Scope.Block {
|
|
return scope.cast(Scope.Block) orelse
|
|
return self.fail(scope, src, "instruction illegal outside function body", .{});
|
|
}
|
|
|
|
fn resolveInstConst(self: *Module, scope: *Scope, old_inst: *zir.Inst) InnerError!TypedValue {
|
|
const new_inst = try self.resolveInst(scope, old_inst);
|
|
const val = try self.resolveConstValue(scope, new_inst);
|
|
return TypedValue{
|
|
.ty = new_inst.ty,
|
|
.val = val,
|
|
};
|
|
}
|
|
|
|
fn resolveConstValue(self: *Module, scope: *Scope, base: *Inst) !Value {
|
|
return (try self.resolveDefinedValue(scope, base)) orelse
|
|
return self.fail(scope, base.src, "unable to resolve comptime value", .{});
|
|
}
|
|
|
|
fn resolveDefinedValue(self: *Module, scope: *Scope, base: *Inst) !?Value {
|
|
if (base.value()) |val| {
|
|
if (val.isUndef()) {
|
|
return self.fail(scope, base.src, "use of undefined value here causes undefined behavior", .{});
|
|
}
|
|
return val;
|
|
}
|
|
return null;
|
|
}
|
|
|
|
fn resolveConstString(self: *Module, scope: *Scope, old_inst: *zir.Inst) ![]u8 {
|
|
const new_inst = try self.resolveInst(scope, old_inst);
|
|
const wanted_type = Type.initTag(.const_slice_u8);
|
|
const coerced_inst = try self.coerce(scope, wanted_type, new_inst);
|
|
const val = try self.resolveConstValue(scope, coerced_inst);
|
|
return val.toAllocatedBytes(scope.arena());
|
|
}
|
|
|
|
fn resolveType(self: *Module, scope: *Scope, old_inst: *zir.Inst) !Type {
|
|
const new_inst = try self.resolveInst(scope, old_inst);
|
|
const wanted_type = Type.initTag(.@"type");
|
|
const coerced_inst = try self.coerce(scope, wanted_type, new_inst);
|
|
const val = try self.resolveConstValue(scope, coerced_inst);
|
|
return val.toType();
|
|
}
|
|
|
|
fn analyzeExport(self: *Module, scope: *Scope, export_inst: *zir.Inst.Export) InnerError!void {
|
|
try self.decl_exports.ensureCapacity(self.decl_exports.size + 1);
|
|
try self.export_owners.ensureCapacity(self.export_owners.size + 1);
|
|
const symbol_name = try self.resolveConstString(scope, export_inst.positionals.symbol_name);
|
|
const exported_decl = try self.resolveCompleteDecl(scope, export_inst.positionals.value);
|
|
const typed_value = exported_decl.typed_value.most_recent.typed_value;
|
|
switch (typed_value.ty.zigTypeTag()) {
|
|
.Fn => {},
|
|
else => return self.fail(
|
|
scope,
|
|
export_inst.positionals.value.src,
|
|
"unable to export type '{}'",
|
|
.{typed_value.ty},
|
|
),
|
|
}
|
|
const new_export = try self.allocator.create(Export);
|
|
errdefer self.allocator.destroy(new_export);
|
|
|
|
const owner_decl = scope.decl().?;
|
|
|
|
new_export.* = .{
|
|
.options = .{ .name = symbol_name },
|
|
.src = export_inst.base.src,
|
|
.link = .{},
|
|
.owner_decl = owner_decl,
|
|
.exported_decl = exported_decl,
|
|
.status = .in_progress,
|
|
};
|
|
|
|
// Add to export_owners table.
|
|
const eo_gop = self.export_owners.getOrPut(owner_decl) catch unreachable;
|
|
if (!eo_gop.found_existing) {
|
|
eo_gop.kv.value = &[0]*Export{};
|
|
}
|
|
eo_gop.kv.value = try self.allocator.realloc(eo_gop.kv.value, eo_gop.kv.value.len + 1);
|
|
eo_gop.kv.value[eo_gop.kv.value.len - 1] = new_export;
|
|
errdefer eo_gop.kv.value = self.allocator.shrink(eo_gop.kv.value, eo_gop.kv.value.len - 1);
|
|
|
|
// Add to exported_decl table.
|
|
const de_gop = self.decl_exports.getOrPut(exported_decl) catch unreachable;
|
|
if (!de_gop.found_existing) {
|
|
de_gop.kv.value = &[0]*Export{};
|
|
}
|
|
de_gop.kv.value = try self.allocator.realloc(de_gop.kv.value, de_gop.kv.value.len + 1);
|
|
de_gop.kv.value[de_gop.kv.value.len - 1] = new_export;
|
|
errdefer de_gop.kv.value = self.allocator.shrink(de_gop.kv.value, de_gop.kv.value.len - 1);
|
|
|
|
self.bin_file.updateDeclExports(self, exported_decl, de_gop.kv.value) catch |err| switch (err) {
|
|
error.OutOfMemory => return error.OutOfMemory,
|
|
else => {
|
|
try self.failed_exports.ensureCapacity(self.failed_exports.size + 1);
|
|
self.failed_exports.putAssumeCapacityNoClobber(new_export, try ErrorMsg.create(
|
|
self.allocator,
|
|
export_inst.base.src,
|
|
"unable to export: {}",
|
|
.{@errorName(err)},
|
|
));
|
|
new_export.status = .failed_retryable;
|
|
},
|
|
};
|
|
}
|
|
|
|
/// TODO should not need the cast on the last parameter at the callsites
|
|
fn addNewInstArgs(
|
|
self: *Module,
|
|
block: *Scope.Block,
|
|
src: usize,
|
|
ty: Type,
|
|
comptime T: type,
|
|
args: Inst.Args(T),
|
|
) !*Inst {
|
|
const inst = try self.addNewInst(block, src, ty, T);
|
|
inst.args = args;
|
|
return &inst.base;
|
|
}
|
|
|
|
fn addNewInst(self: *Module, block: *Scope.Block, src: usize, ty: Type, comptime T: type) !*T {
|
|
const inst = try block.arena.create(T);
|
|
inst.* = .{
|
|
.base = .{
|
|
.tag = T.base_tag,
|
|
.ty = ty,
|
|
.src = src,
|
|
},
|
|
.args = undefined,
|
|
};
|
|
try block.instructions.append(self.allocator, &inst.base);
|
|
return inst;
|
|
}
|
|
|
|
fn constInst(self: *Module, scope: *Scope, src: usize, typed_value: TypedValue) !*Inst {
|
|
const const_inst = try scope.arena().create(Inst.Constant);
|
|
const_inst.* = .{
|
|
.base = .{
|
|
.tag = Inst.Constant.base_tag,
|
|
.ty = typed_value.ty,
|
|
.src = src,
|
|
},
|
|
.val = typed_value.val,
|
|
};
|
|
return &const_inst.base;
|
|
}
|
|
|
|
fn constStr(self: *Module, scope: *Scope, src: usize, str: []const u8) !*Inst {
|
|
const ty_payload = try scope.arena().create(Type.Payload.Array_u8_Sentinel0);
|
|
ty_payload.* = .{ .len = str.len };
|
|
|
|
const bytes_payload = try scope.arena().create(Value.Payload.Bytes);
|
|
bytes_payload.* = .{ .data = str };
|
|
|
|
return self.constInst(scope, src, .{
|
|
.ty = Type.initPayload(&ty_payload.base),
|
|
.val = Value.initPayload(&bytes_payload.base),
|
|
});
|
|
}
|
|
|
|
fn constType(self: *Module, scope: *Scope, src: usize, ty: Type) !*Inst {
|
|
return self.constInst(scope, src, .{
|
|
.ty = Type.initTag(.type),
|
|
.val = try ty.toValue(scope.arena()),
|
|
});
|
|
}
|
|
|
|
fn constVoid(self: *Module, scope: *Scope, src: usize) !*Inst {
|
|
return self.constInst(scope, src, .{
|
|
.ty = Type.initTag(.void),
|
|
.val = Value.initTag(.the_one_possible_value),
|
|
});
|
|
}
|
|
|
|
fn constUndef(self: *Module, scope: *Scope, src: usize, ty: Type) !*Inst {
|
|
return self.constInst(scope, src, .{
|
|
.ty = ty,
|
|
.val = Value.initTag(.undef),
|
|
});
|
|
}
|
|
|
|
fn constBool(self: *Module, scope: *Scope, src: usize, v: bool) !*Inst {
|
|
return self.constInst(scope, src, .{
|
|
.ty = Type.initTag(.bool),
|
|
.val = ([2]Value{ Value.initTag(.bool_false), Value.initTag(.bool_true) })[@boolToInt(v)],
|
|
});
|
|
}
|
|
|
|
fn constIntUnsigned(self: *Module, scope: *Scope, src: usize, ty: Type, int: u64) !*Inst {
|
|
const int_payload = try scope.arena().create(Value.Payload.Int_u64);
|
|
int_payload.* = .{ .int = int };
|
|
|
|
return self.constInst(scope, src, .{
|
|
.ty = ty,
|
|
.val = Value.initPayload(&int_payload.base),
|
|
});
|
|
}
|
|
|
|
fn constIntSigned(self: *Module, scope: *Scope, src: usize, ty: Type, int: i64) !*Inst {
|
|
const int_payload = try scope.arena().create(Value.Payload.Int_i64);
|
|
int_payload.* = .{ .int = int };
|
|
|
|
return self.constInst(scope, src, .{
|
|
.ty = ty,
|
|
.val = Value.initPayload(&int_payload.base),
|
|
});
|
|
}
|
|
|
|
fn constIntBig(self: *Module, scope: *Scope, src: usize, ty: Type, big_int: BigIntConst) !*Inst {
|
|
const val_payload = if (big_int.positive) blk: {
|
|
if (big_int.to(u64)) |x| {
|
|
return self.constIntUnsigned(scope, src, ty, x);
|
|
} else |err| switch (err) {
|
|
error.NegativeIntoUnsigned => unreachable,
|
|
error.TargetTooSmall => {}, // handled below
|
|
}
|
|
const big_int_payload = try scope.arena().create(Value.Payload.IntBigPositive);
|
|
big_int_payload.* = .{ .limbs = big_int.limbs };
|
|
break :blk &big_int_payload.base;
|
|
} else blk: {
|
|
if (big_int.to(i64)) |x| {
|
|
return self.constIntSigned(scope, src, ty, x);
|
|
} else |err| switch (err) {
|
|
error.NegativeIntoUnsigned => unreachable,
|
|
error.TargetTooSmall => {}, // handled below
|
|
}
|
|
const big_int_payload = try scope.arena().create(Value.Payload.IntBigNegative);
|
|
big_int_payload.* = .{ .limbs = big_int.limbs };
|
|
break :blk &big_int_payload.base;
|
|
};
|
|
|
|
return self.constInst(scope, src, .{
|
|
.ty = ty,
|
|
.val = Value.initPayload(val_payload),
|
|
});
|
|
}
|
|
|
|
fn analyzeInstConst(self: *Module, scope: *Scope, old_inst: *zir.Inst) InnerError!TypedValue {
|
|
const new_inst = try self.analyzeInst(scope, old_inst);
|
|
return TypedValue{
|
|
.ty = new_inst.ty,
|
|
.val = try self.resolveConstValue(scope, new_inst),
|
|
};
|
|
}
|
|
|
|
fn analyzeInst(self: *Module, scope: *Scope, old_inst: *zir.Inst) InnerError!*Inst {
|
|
switch (old_inst.tag) {
|
|
.breakpoint => return self.analyzeInstBreakpoint(scope, old_inst.cast(zir.Inst.Breakpoint).?),
|
|
.call => return self.analyzeInstCall(scope, old_inst.cast(zir.Inst.Call).?),
|
|
.compileerror => return self.analyzeInstCompileError(scope, old_inst.cast(zir.Inst.CompileError).?),
|
|
.declref => return self.analyzeInstDeclRef(scope, old_inst.cast(zir.Inst.DeclRef).?),
|
|
.declval => return self.analyzeInstDeclVal(scope, old_inst.cast(zir.Inst.DeclVal).?),
|
|
.str => {
|
|
const bytes = old_inst.cast(zir.Inst.Str).?.positionals.bytes;
|
|
// The bytes references memory inside the ZIR module, which can get deallocated
|
|
// after semantic analysis is complete. We need the memory to be in the Decl's arena.
|
|
const arena_bytes = try scope.arena().dupe(u8, bytes);
|
|
return self.constStr(scope, old_inst.src, arena_bytes);
|
|
},
|
|
.int => {
|
|
const big_int = old_inst.cast(zir.Inst.Int).?.positionals.int;
|
|
return self.constIntBig(scope, old_inst.src, Type.initTag(.comptime_int), big_int);
|
|
},
|
|
.ptrtoint => return self.analyzeInstPtrToInt(scope, old_inst.cast(zir.Inst.PtrToInt).?),
|
|
.fieldptr => return self.analyzeInstFieldPtr(scope, old_inst.cast(zir.Inst.FieldPtr).?),
|
|
.deref => return self.analyzeInstDeref(scope, old_inst.cast(zir.Inst.Deref).?),
|
|
.as => return self.analyzeInstAs(scope, old_inst.cast(zir.Inst.As).?),
|
|
.@"asm" => return self.analyzeInstAsm(scope, old_inst.cast(zir.Inst.Asm).?),
|
|
.@"unreachable" => return self.analyzeInstUnreachable(scope, old_inst.cast(zir.Inst.Unreachable).?),
|
|
.@"return" => return self.analyzeInstRet(scope, old_inst.cast(zir.Inst.Return).?),
|
|
.@"fn" => return self.analyzeInstFn(scope, old_inst.cast(zir.Inst.Fn).?),
|
|
.@"export" => {
|
|
try self.analyzeExport(scope, old_inst.cast(zir.Inst.Export).?);
|
|
return self.constVoid(scope, old_inst.src);
|
|
},
|
|
.primitive => return self.analyzeInstPrimitive(scope, old_inst.cast(zir.Inst.Primitive).?),
|
|
.ref => return self.analyzeInstRef(scope, old_inst.cast(zir.Inst.Ref).?),
|
|
.fntype => return self.analyzeInstFnType(scope, old_inst.cast(zir.Inst.FnType).?),
|
|
.intcast => return self.analyzeInstIntCast(scope, old_inst.cast(zir.Inst.IntCast).?),
|
|
.bitcast => return self.analyzeInstBitCast(scope, old_inst.cast(zir.Inst.BitCast).?),
|
|
.elemptr => return self.analyzeInstElemPtr(scope, old_inst.cast(zir.Inst.ElemPtr).?),
|
|
.add => return self.analyzeInstAdd(scope, old_inst.cast(zir.Inst.Add).?),
|
|
.cmp => return self.analyzeInstCmp(scope, old_inst.cast(zir.Inst.Cmp).?),
|
|
.condbr => return self.analyzeInstCondBr(scope, old_inst.cast(zir.Inst.CondBr).?),
|
|
.isnull => return self.analyzeInstIsNull(scope, old_inst.cast(zir.Inst.IsNull).?),
|
|
.isnonnull => return self.analyzeInstIsNonNull(scope, old_inst.cast(zir.Inst.IsNonNull).?),
|
|
}
|
|
}
|
|
|
|
fn analyzeInstCompileError(self: *Module, scope: *Scope, inst: *zir.Inst.CompileError) InnerError!*Inst {
|
|
return self.fail(scope, inst.base.src, "{}", .{inst.positionals.msg});
|
|
}
|
|
|
|
fn analyzeInstBreakpoint(self: *Module, scope: *Scope, inst: *zir.Inst.Breakpoint) InnerError!*Inst {
|
|
const b = try self.requireRuntimeBlock(scope, inst.base.src);
|
|
return self.addNewInstArgs(b, inst.base.src, Type.initTag(.void), Inst.Breakpoint, Inst.Args(Inst.Breakpoint){});
|
|
}
|
|
|
|
fn analyzeInstRef(self: *Module, scope: *Scope, inst: *zir.Inst.Ref) InnerError!*Inst {
|
|
const decl = try self.resolveCompleteDecl(scope, inst.positionals.operand);
|
|
return self.analyzeDeclRef(scope, inst.base.src, decl);
|
|
}
|
|
|
|
fn analyzeInstDeclRef(self: *Module, scope: *Scope, inst: *zir.Inst.DeclRef) InnerError!*Inst {
|
|
const decl_name = try self.resolveConstString(scope, inst.positionals.name);
|
|
// This will need to get more fleshed out when there are proper structs & namespaces.
|
|
const zir_module = scope.namespace();
|
|
const src_decl = zir_module.contents.module.findDecl(decl_name) orelse
|
|
return self.fail(scope, inst.positionals.name.src, "use of undeclared identifier '{}'", .{decl_name});
|
|
|
|
const decl = try self.resolveCompleteDecl(scope, src_decl);
|
|
return self.analyzeDeclRef(scope, inst.base.src, decl);
|
|
}
|
|
|
|
fn analyzeDeclVal(self: *Module, scope: *Scope, inst: *zir.Inst.DeclVal) InnerError!*Decl {
|
|
const decl_name = inst.positionals.name;
|
|
// This will need to get more fleshed out when there are proper structs & namespaces.
|
|
const zir_module = scope.namespace();
|
|
const src_decl = zir_module.contents.module.findDecl(decl_name) orelse
|
|
return self.fail(scope, inst.base.src, "use of undeclared identifier '{}'", .{decl_name});
|
|
|
|
const decl = try self.resolveCompleteDecl(scope, src_decl);
|
|
|
|
return decl;
|
|
}
|
|
|
|
fn analyzeInstDeclVal(self: *Module, scope: *Scope, inst: *zir.Inst.DeclVal) InnerError!*Inst {
|
|
const decl = try self.analyzeDeclVal(scope, inst);
|
|
const ptr = try self.analyzeDeclRef(scope, inst.base.src, decl);
|
|
return self.analyzeDeref(scope, inst.base.src, ptr, inst.base.src);
|
|
}
|
|
|
|
fn analyzeDeclRef(self: *Module, scope: *Scope, src: usize, decl: *Decl) InnerError!*Inst {
|
|
const decl_tv = try decl.typedValue();
|
|
const ty_payload = try scope.arena().create(Type.Payload.SingleConstPointer);
|
|
ty_payload.* = .{ .pointee_type = decl_tv.ty };
|
|
const val_payload = try scope.arena().create(Value.Payload.DeclRef);
|
|
val_payload.* = .{ .decl = decl };
|
|
return self.constInst(scope, src, .{
|
|
.ty = Type.initPayload(&ty_payload.base),
|
|
.val = Value.initPayload(&val_payload.base),
|
|
});
|
|
}
|
|
|
|
fn analyzeInstCall(self: *Module, scope: *Scope, inst: *zir.Inst.Call) InnerError!*Inst {
|
|
const func = try self.resolveInst(scope, inst.positionals.func);
|
|
if (func.ty.zigTypeTag() != .Fn)
|
|
return self.fail(scope, inst.positionals.func.src, "type '{}' not a function", .{func.ty});
|
|
|
|
const cc = func.ty.fnCallingConvention();
|
|
if (cc == .Naked) {
|
|
// TODO add error note: declared here
|
|
return self.fail(
|
|
scope,
|
|
inst.positionals.func.src,
|
|
"unable to call function with naked calling convention",
|
|
.{},
|
|
);
|
|
}
|
|
const call_params_len = inst.positionals.args.len;
|
|
const fn_params_len = func.ty.fnParamLen();
|
|
if (func.ty.fnIsVarArgs()) {
|
|
if (call_params_len < fn_params_len) {
|
|
// TODO add error note: declared here
|
|
return self.fail(
|
|
scope,
|
|
inst.positionals.func.src,
|
|
"expected at least {} arguments, found {}",
|
|
.{ fn_params_len, call_params_len },
|
|
);
|
|
}
|
|
return self.fail(scope, inst.base.src, "TODO implement support for calling var args functions", .{});
|
|
} else if (fn_params_len != call_params_len) {
|
|
// TODO add error note: declared here
|
|
return self.fail(
|
|
scope,
|
|
inst.positionals.func.src,
|
|
"expected {} arguments, found {}",
|
|
.{ fn_params_len, call_params_len },
|
|
);
|
|
}
|
|
|
|
if (inst.kw_args.modifier == .compile_time) {
|
|
return self.fail(scope, inst.base.src, "TODO implement comptime function calls", .{});
|
|
}
|
|
if (inst.kw_args.modifier != .auto) {
|
|
return self.fail(scope, inst.base.src, "TODO implement call with modifier {}", .{inst.kw_args.modifier});
|
|
}
|
|
|
|
// TODO handle function calls of generic functions
|
|
|
|
const fn_param_types = try self.allocator.alloc(Type, fn_params_len);
|
|
defer self.allocator.free(fn_param_types);
|
|
func.ty.fnParamTypes(fn_param_types);
|
|
|
|
const casted_args = try scope.arena().alloc(*Inst, fn_params_len);
|
|
for (inst.positionals.args) |src_arg, i| {
|
|
const uncasted_arg = try self.resolveInst(scope, src_arg);
|
|
casted_args[i] = try self.coerce(scope, fn_param_types[i], uncasted_arg);
|
|
}
|
|
|
|
const b = try self.requireRuntimeBlock(scope, inst.base.src);
|
|
return self.addNewInstArgs(b, inst.base.src, Type.initTag(.void), Inst.Call, Inst.Args(Inst.Call){
|
|
.func = func,
|
|
.args = casted_args,
|
|
});
|
|
}
|
|
|
|
fn analyzeInstFn(self: *Module, scope: *Scope, fn_inst: *zir.Inst.Fn) InnerError!*Inst {
|
|
const fn_type = try self.resolveType(scope, fn_inst.positionals.fn_type);
|
|
const new_func = try scope.arena().create(Fn);
|
|
new_func.* = .{
|
|
.fn_type = fn_type,
|
|
.analysis = .{ .queued = fn_inst },
|
|
.owner_decl = scope.decl().?,
|
|
};
|
|
const fn_payload = try scope.arena().create(Value.Payload.Function);
|
|
fn_payload.* = .{ .func = new_func };
|
|
return self.constInst(scope, fn_inst.base.src, .{
|
|
.ty = fn_type,
|
|
.val = Value.initPayload(&fn_payload.base),
|
|
});
|
|
}
|
|
|
|
fn analyzeInstFnType(self: *Module, scope: *Scope, fntype: *zir.Inst.FnType) InnerError!*Inst {
|
|
const return_type = try self.resolveType(scope, fntype.positionals.return_type);
|
|
|
|
if (return_type.zigTypeTag() == .NoReturn and
|
|
fntype.positionals.param_types.len == 0 and
|
|
fntype.kw_args.cc == .Unspecified)
|
|
{
|
|
return self.constType(scope, fntype.base.src, Type.initTag(.fn_noreturn_no_args));
|
|
}
|
|
|
|
if (return_type.zigTypeTag() == .NoReturn and
|
|
fntype.positionals.param_types.len == 0 and
|
|
fntype.kw_args.cc == .Naked)
|
|
{
|
|
return self.constType(scope, fntype.base.src, Type.initTag(.fn_naked_noreturn_no_args));
|
|
}
|
|
|
|
if (return_type.zigTypeTag() == .Void and
|
|
fntype.positionals.param_types.len == 0 and
|
|
fntype.kw_args.cc == .C)
|
|
{
|
|
return self.constType(scope, fntype.base.src, Type.initTag(.fn_ccc_void_no_args));
|
|
}
|
|
|
|
return self.fail(scope, fntype.base.src, "TODO implement fntype instruction more", .{});
|
|
}
|
|
|
|
fn analyzeInstPrimitive(self: *Module, scope: *Scope, primitive: *zir.Inst.Primitive) InnerError!*Inst {
|
|
return self.constInst(scope, primitive.base.src, primitive.positionals.tag.toTypedValue());
|
|
}
|
|
|
|
fn analyzeInstAs(self: *Module, scope: *Scope, as: *zir.Inst.As) InnerError!*Inst {
|
|
const dest_type = try self.resolveType(scope, as.positionals.dest_type);
|
|
const new_inst = try self.resolveInst(scope, as.positionals.value);
|
|
return self.coerce(scope, dest_type, new_inst);
|
|
}
|
|
|
|
fn analyzeInstPtrToInt(self: *Module, scope: *Scope, ptrtoint: *zir.Inst.PtrToInt) InnerError!*Inst {
|
|
const ptr = try self.resolveInst(scope, ptrtoint.positionals.ptr);
|
|
if (ptr.ty.zigTypeTag() != .Pointer) {
|
|
return self.fail(scope, ptrtoint.positionals.ptr.src, "expected pointer, found '{}'", .{ptr.ty});
|
|
}
|
|
// TODO handle known-pointer-address
|
|
const b = try self.requireRuntimeBlock(scope, ptrtoint.base.src);
|
|
const ty = Type.initTag(.usize);
|
|
return self.addNewInstArgs(b, ptrtoint.base.src, ty, Inst.PtrToInt, Inst.Args(Inst.PtrToInt){ .ptr = ptr });
|
|
}
|
|
|
|
fn analyzeInstFieldPtr(self: *Module, scope: *Scope, fieldptr: *zir.Inst.FieldPtr) InnerError!*Inst {
|
|
const object_ptr = try self.resolveInst(scope, fieldptr.positionals.object_ptr);
|
|
const field_name = try self.resolveConstString(scope, fieldptr.positionals.field_name);
|
|
|
|
const elem_ty = switch (object_ptr.ty.zigTypeTag()) {
|
|
.Pointer => object_ptr.ty.elemType(),
|
|
else => return self.fail(scope, fieldptr.positionals.object_ptr.src, "expected pointer, found '{}'", .{object_ptr.ty}),
|
|
};
|
|
switch (elem_ty.zigTypeTag()) {
|
|
.Array => {
|
|
if (mem.eql(u8, field_name, "len")) {
|
|
const len_payload = try scope.arena().create(Value.Payload.Int_u64);
|
|
len_payload.* = .{ .int = elem_ty.arrayLen() };
|
|
|
|
const ref_payload = try scope.arena().create(Value.Payload.RefVal);
|
|
ref_payload.* = .{ .val = Value.initPayload(&len_payload.base) };
|
|
|
|
return self.constInst(scope, fieldptr.base.src, .{
|
|
.ty = Type.initTag(.single_const_pointer_to_comptime_int),
|
|
.val = Value.initPayload(&ref_payload.base),
|
|
});
|
|
} else {
|
|
return self.fail(
|
|
scope,
|
|
fieldptr.positionals.field_name.src,
|
|
"no member named '{}' in '{}'",
|
|
.{ field_name, elem_ty },
|
|
);
|
|
}
|
|
},
|
|
else => return self.fail(scope, fieldptr.base.src, "type '{}' does not support field access", .{elem_ty}),
|
|
}
|
|
}
|
|
|
|
fn analyzeInstIntCast(self: *Module, scope: *Scope, intcast: *zir.Inst.IntCast) InnerError!*Inst {
|
|
const dest_type = try self.resolveType(scope, intcast.positionals.dest_type);
|
|
const new_inst = try self.resolveInst(scope, intcast.positionals.value);
|
|
|
|
const dest_is_comptime_int = switch (dest_type.zigTypeTag()) {
|
|
.ComptimeInt => true,
|
|
.Int => false,
|
|
else => return self.fail(
|
|
scope,
|
|
intcast.positionals.dest_type.src,
|
|
"expected integer type, found '{}'",
|
|
.{
|
|
dest_type,
|
|
},
|
|
),
|
|
};
|
|
|
|
switch (new_inst.ty.zigTypeTag()) {
|
|
.ComptimeInt, .Int => {},
|
|
else => return self.fail(
|
|
scope,
|
|
intcast.positionals.value.src,
|
|
"expected integer type, found '{}'",
|
|
.{new_inst.ty},
|
|
),
|
|
}
|
|
|
|
if (dest_is_comptime_int or new_inst.value() != null) {
|
|
return self.coerce(scope, dest_type, new_inst);
|
|
}
|
|
|
|
return self.fail(scope, intcast.base.src, "TODO implement analyze widen or shorten int", .{});
|
|
}
|
|
|
|
fn analyzeInstBitCast(self: *Module, scope: *Scope, inst: *zir.Inst.BitCast) InnerError!*Inst {
|
|
const dest_type = try self.resolveType(scope, inst.positionals.dest_type);
|
|
const operand = try self.resolveInst(scope, inst.positionals.operand);
|
|
return self.bitcast(scope, dest_type, operand);
|
|
}
|
|
|
|
fn analyzeInstElemPtr(self: *Module, scope: *Scope, inst: *zir.Inst.ElemPtr) InnerError!*Inst {
|
|
const array_ptr = try self.resolveInst(scope, inst.positionals.array_ptr);
|
|
const uncasted_index = try self.resolveInst(scope, inst.positionals.index);
|
|
const elem_index = try self.coerce(scope, Type.initTag(.usize), uncasted_index);
|
|
|
|
if (array_ptr.ty.isSinglePointer() and array_ptr.ty.elemType().zigTypeTag() == .Array) {
|
|
if (array_ptr.value()) |array_ptr_val| {
|
|
if (elem_index.value()) |index_val| {
|
|
// Both array pointer and index are compile-time known.
|
|
const index_u64 = index_val.toUnsignedInt();
|
|
// @intCast here because it would have been impossible to construct a value that
|
|
// required a larger index.
|
|
const elem_ptr = try array_ptr_val.elemPtr(scope.arena(), @intCast(usize, index_u64));
|
|
|
|
const type_payload = try scope.arena().create(Type.Payload.SingleConstPointer);
|
|
type_payload.* = .{ .pointee_type = array_ptr.ty.elemType().elemType() };
|
|
|
|
return self.constInst(scope, inst.base.src, .{
|
|
.ty = Type.initPayload(&type_payload.base),
|
|
.val = elem_ptr,
|
|
});
|
|
}
|
|
}
|
|
}
|
|
|
|
return self.fail(scope, inst.base.src, "TODO implement more analyze elemptr", .{});
|
|
}
|
|
|
|
fn analyzeInstAdd(self: *Module, scope: *Scope, inst: *zir.Inst.Add) InnerError!*Inst {
|
|
const lhs = try self.resolveInst(scope, inst.positionals.lhs);
|
|
const rhs = try self.resolveInst(scope, inst.positionals.rhs);
|
|
|
|
if (lhs.ty.zigTypeTag() == .Int and rhs.ty.zigTypeTag() == .Int) {
|
|
if (lhs.value()) |lhs_val| {
|
|
if (rhs.value()) |rhs_val| {
|
|
// TODO is this a performance issue? maybe we should try the operation without
|
|
// resorting to BigInt first.
|
|
var lhs_space: Value.BigIntSpace = undefined;
|
|
var rhs_space: Value.BigIntSpace = undefined;
|
|
const lhs_bigint = lhs_val.toBigInt(&lhs_space);
|
|
const rhs_bigint = rhs_val.toBigInt(&rhs_space);
|
|
const limbs = try scope.arena().alloc(
|
|
std.math.big.Limb,
|
|
std.math.max(lhs_bigint.limbs.len, rhs_bigint.limbs.len) + 1,
|
|
);
|
|
var result_bigint = BigIntMutable{ .limbs = limbs, .positive = undefined, .len = undefined };
|
|
result_bigint.add(lhs_bigint, rhs_bigint);
|
|
const result_limbs = result_bigint.limbs[0..result_bigint.len];
|
|
|
|
if (!lhs.ty.eql(rhs.ty)) {
|
|
return self.fail(scope, inst.base.src, "TODO implement peer type resolution", .{});
|
|
}
|
|
|
|
const val_payload = if (result_bigint.positive) blk: {
|
|
const val_payload = try scope.arena().create(Value.Payload.IntBigPositive);
|
|
val_payload.* = .{ .limbs = result_limbs };
|
|
break :blk &val_payload.base;
|
|
} else blk: {
|
|
const val_payload = try scope.arena().create(Value.Payload.IntBigNegative);
|
|
val_payload.* = .{ .limbs = result_limbs };
|
|
break :blk &val_payload.base;
|
|
};
|
|
|
|
return self.constInst(scope, inst.base.src, .{
|
|
.ty = lhs.ty,
|
|
.val = Value.initPayload(val_payload),
|
|
});
|
|
}
|
|
}
|
|
}
|
|
|
|
return self.fail(scope, inst.base.src, "TODO implement more analyze add", .{});
|
|
}
|
|
|
|
fn analyzeInstDeref(self: *Module, scope: *Scope, deref: *zir.Inst.Deref) InnerError!*Inst {
|
|
const ptr = try self.resolveInst(scope, deref.positionals.ptr);
|
|
return self.analyzeDeref(scope, deref.base.src, ptr, deref.positionals.ptr.src);
|
|
}
|
|
|
|
fn analyzeDeref(self: *Module, scope: *Scope, src: usize, ptr: *Inst, ptr_src: usize) InnerError!*Inst {
|
|
const elem_ty = switch (ptr.ty.zigTypeTag()) {
|
|
.Pointer => ptr.ty.elemType(),
|
|
else => return self.fail(scope, ptr_src, "expected pointer, found '{}'", .{ptr.ty}),
|
|
};
|
|
if (ptr.value()) |val| {
|
|
return self.constInst(scope, src, .{
|
|
.ty = elem_ty,
|
|
.val = try val.pointerDeref(scope.arena()),
|
|
});
|
|
}
|
|
|
|
return self.fail(scope, src, "TODO implement runtime deref", .{});
|
|
}
|
|
|
|
fn analyzeInstAsm(self: *Module, scope: *Scope, assembly: *zir.Inst.Asm) InnerError!*Inst {
|
|
const return_type = try self.resolveType(scope, assembly.positionals.return_type);
|
|
const asm_source = try self.resolveConstString(scope, assembly.positionals.asm_source);
|
|
const output = if (assembly.kw_args.output) |o| try self.resolveConstString(scope, o) else null;
|
|
|
|
const inputs = try scope.arena().alloc([]const u8, assembly.kw_args.inputs.len);
|
|
const clobbers = try scope.arena().alloc([]const u8, assembly.kw_args.clobbers.len);
|
|
const args = try scope.arena().alloc(*Inst, assembly.kw_args.args.len);
|
|
|
|
for (inputs) |*elem, i| {
|
|
elem.* = try self.resolveConstString(scope, assembly.kw_args.inputs[i]);
|
|
}
|
|
for (clobbers) |*elem, i| {
|
|
elem.* = try self.resolveConstString(scope, assembly.kw_args.clobbers[i]);
|
|
}
|
|
for (args) |*elem, i| {
|
|
const arg = try self.resolveInst(scope, assembly.kw_args.args[i]);
|
|
elem.* = try self.coerce(scope, Type.initTag(.usize), arg);
|
|
}
|
|
|
|
const b = try self.requireRuntimeBlock(scope, assembly.base.src);
|
|
return self.addNewInstArgs(b, assembly.base.src, return_type, Inst.Assembly, Inst.Args(Inst.Assembly){
|
|
.asm_source = asm_source,
|
|
.is_volatile = assembly.kw_args.@"volatile",
|
|
.output = output,
|
|
.inputs = inputs,
|
|
.clobbers = clobbers,
|
|
.args = args,
|
|
});
|
|
}
|
|
|
|
fn analyzeInstCmp(self: *Module, scope: *Scope, inst: *zir.Inst.Cmp) InnerError!*Inst {
|
|
const lhs = try self.resolveInst(scope, inst.positionals.lhs);
|
|
const rhs = try self.resolveInst(scope, inst.positionals.rhs);
|
|
const op = inst.positionals.op;
|
|
|
|
const is_equality_cmp = switch (op) {
|
|
.eq, .neq => true,
|
|
else => false,
|
|
};
|
|
const lhs_ty_tag = lhs.ty.zigTypeTag();
|
|
const rhs_ty_tag = rhs.ty.zigTypeTag();
|
|
if (is_equality_cmp and lhs_ty_tag == .Null and rhs_ty_tag == .Null) {
|
|
// null == null, null != null
|
|
return self.constBool(scope, inst.base.src, op == .eq);
|
|
} else if (is_equality_cmp and
|
|
((lhs_ty_tag == .Null and rhs_ty_tag == .Optional) or
|
|
rhs_ty_tag == .Null and lhs_ty_tag == .Optional))
|
|
{
|
|
// comparing null with optionals
|
|
const opt_operand = if (lhs_ty_tag == .Optional) lhs else rhs;
|
|
if (opt_operand.value()) |opt_val| {
|
|
const is_null = opt_val.isNull();
|
|
return self.constBool(scope, inst.base.src, if (op == .eq) is_null else !is_null);
|
|
}
|
|
const b = try self.requireRuntimeBlock(scope, inst.base.src);
|
|
switch (op) {
|
|
.eq => return self.addNewInstArgs(
|
|
b,
|
|
inst.base.src,
|
|
Type.initTag(.bool),
|
|
Inst.IsNull,
|
|
Inst.Args(Inst.IsNull){ .operand = opt_operand },
|
|
),
|
|
.neq => return self.addNewInstArgs(
|
|
b,
|
|
inst.base.src,
|
|
Type.initTag(.bool),
|
|
Inst.IsNonNull,
|
|
Inst.Args(Inst.IsNonNull){ .operand = opt_operand },
|
|
),
|
|
else => unreachable,
|
|
}
|
|
} else if (is_equality_cmp and
|
|
((lhs_ty_tag == .Null and rhs.ty.isCPtr()) or (rhs_ty_tag == .Null and lhs.ty.isCPtr())))
|
|
{
|
|
return self.fail(scope, inst.base.src, "TODO implement C pointer cmp", .{});
|
|
} else if (lhs_ty_tag == .Null or rhs_ty_tag == .Null) {
|
|
const non_null_type = if (lhs_ty_tag == .Null) rhs.ty else lhs.ty;
|
|
return self.fail(scope, inst.base.src, "comparison of '{}' with null", .{non_null_type});
|
|
} else if (is_equality_cmp and
|
|
((lhs_ty_tag == .EnumLiteral and rhs_ty_tag == .Union) or
|
|
(rhs_ty_tag == .EnumLiteral and lhs_ty_tag == .Union)))
|
|
{
|
|
return self.fail(scope, inst.base.src, "TODO implement equality comparison between a union's tag value and an enum literal", .{});
|
|
} else if (lhs_ty_tag == .ErrorSet and rhs_ty_tag == .ErrorSet) {
|
|
if (!is_equality_cmp) {
|
|
return self.fail(scope, inst.base.src, "{} operator not allowed for errors", .{@tagName(op)});
|
|
}
|
|
return self.fail(scope, inst.base.src, "TODO implement equality comparison between errors", .{});
|
|
} else if (lhs.ty.isNumeric() and rhs.ty.isNumeric()) {
|
|
// This operation allows any combination of integer and float types, regardless of the
|
|
// signed-ness, comptime-ness, and bit-width. So peer type resolution is incorrect for
|
|
// numeric types.
|
|
return self.cmpNumeric(scope, inst.base.src, lhs, rhs, op);
|
|
}
|
|
return self.fail(scope, inst.base.src, "TODO implement more cmp analysis", .{});
|
|
}
|
|
|
|
fn analyzeInstIsNull(self: *Module, scope: *Scope, inst: *zir.Inst.IsNull) InnerError!*Inst {
|
|
const operand = try self.resolveInst(scope, inst.positionals.operand);
|
|
return self.analyzeIsNull(scope, inst.base.src, operand, true);
|
|
}
|
|
|
|
fn analyzeInstIsNonNull(self: *Module, scope: *Scope, inst: *zir.Inst.IsNonNull) InnerError!*Inst {
|
|
const operand = try self.resolveInst(scope, inst.positionals.operand);
|
|
return self.analyzeIsNull(scope, inst.base.src, operand, false);
|
|
}
|
|
|
|
fn analyzeInstCondBr(self: *Module, scope: *Scope, inst: *zir.Inst.CondBr) InnerError!*Inst {
|
|
const uncasted_cond = try self.resolveInst(scope, inst.positionals.condition);
|
|
const cond = try self.coerce(scope, Type.initTag(.bool), uncasted_cond);
|
|
|
|
if (try self.resolveDefinedValue(scope, cond)) |cond_val| {
|
|
const body = if (cond_val.toBool()) &inst.positionals.true_body else &inst.positionals.false_body;
|
|
try self.analyzeBody(scope, body.*);
|
|
return self.constVoid(scope, inst.base.src);
|
|
}
|
|
|
|
const parent_block = try self.requireRuntimeBlock(scope, inst.base.src);
|
|
|
|
var true_block: Scope.Block = .{
|
|
.func = parent_block.func,
|
|
.decl = parent_block.decl,
|
|
.instructions = .{},
|
|
.arena = parent_block.arena,
|
|
};
|
|
defer true_block.instructions.deinit(self.allocator);
|
|
try self.analyzeBody(&true_block.base, inst.positionals.true_body);
|
|
|
|
var false_block: Scope.Block = .{
|
|
.func = parent_block.func,
|
|
.decl = parent_block.decl,
|
|
.instructions = .{},
|
|
.arena = parent_block.arena,
|
|
};
|
|
defer false_block.instructions.deinit(self.allocator);
|
|
try self.analyzeBody(&false_block.base, inst.positionals.false_body);
|
|
|
|
return self.addNewInstArgs(parent_block, inst.base.src, Type.initTag(.void), Inst.CondBr, Inst.Args(Inst.CondBr){
|
|
.condition = cond,
|
|
.true_body = .{ .instructions = try scope.arena().dupe(*Inst, true_block.instructions.items) },
|
|
.false_body = .{ .instructions = try scope.arena().dupe(*Inst, false_block.instructions.items) },
|
|
});
|
|
}
|
|
|
|
fn wantSafety(self: *Module, scope: *Scope) bool {
|
|
return switch (self.optimize_mode) {
|
|
.Debug => true,
|
|
.ReleaseSafe => true,
|
|
.ReleaseFast => false,
|
|
.ReleaseSmall => false,
|
|
};
|
|
}
|
|
|
|
fn analyzeInstUnreachable(self: *Module, scope: *Scope, unreach: *zir.Inst.Unreachable) InnerError!*Inst {
|
|
const b = try self.requireRuntimeBlock(scope, unreach.base.src);
|
|
if (self.wantSafety(scope)) {
|
|
// TODO Once we have a panic function to call, call it here instead of this.
|
|
_ = try self.addNewInstArgs(b, unreach.base.src, Type.initTag(.void), Inst.Breakpoint, {});
|
|
}
|
|
return self.addNewInstArgs(b, unreach.base.src, Type.initTag(.noreturn), Inst.Unreach, {});
|
|
}
|
|
|
|
fn analyzeInstRet(self: *Module, scope: *Scope, inst: *zir.Inst.Return) InnerError!*Inst {
|
|
const b = try self.requireRuntimeBlock(scope, inst.base.src);
|
|
return self.addNewInstArgs(b, inst.base.src, Type.initTag(.noreturn), Inst.Ret, {});
|
|
}
|
|
|
|
fn analyzeBody(self: *Module, scope: *Scope, body: zir.Module.Body) !void {
|
|
if (scope.cast(Scope.Block)) |b| {
|
|
const analysis = b.func.analysis.in_progress;
|
|
analysis.needed_inst_capacity += body.instructions.len;
|
|
try analysis.inst_table.ensureCapacity(analysis.needed_inst_capacity);
|
|
for (body.instructions) |src_inst| {
|
|
const new_inst = try self.analyzeInst(scope, src_inst);
|
|
analysis.inst_table.putAssumeCapacityNoClobber(src_inst, new_inst);
|
|
}
|
|
} else {
|
|
for (body.instructions) |src_inst| {
|
|
_ = try self.analyzeInst(scope, src_inst);
|
|
}
|
|
}
|
|
}
|
|
|
|
fn analyzeIsNull(
|
|
self: *Module,
|
|
scope: *Scope,
|
|
src: usize,
|
|
operand: *Inst,
|
|
invert_logic: bool,
|
|
) InnerError!*Inst {
|
|
return self.fail(scope, src, "TODO implement analysis of isnull and isnotnull", .{});
|
|
}
|
|
|
|
/// Asserts that lhs and rhs types are both numeric.
|
|
fn cmpNumeric(
|
|
self: *Module,
|
|
scope: *Scope,
|
|
src: usize,
|
|
lhs: *Inst,
|
|
rhs: *Inst,
|
|
op: std.math.CompareOperator,
|
|
) !*Inst {
|
|
assert(lhs.ty.isNumeric());
|
|
assert(rhs.ty.isNumeric());
|
|
|
|
const lhs_ty_tag = lhs.ty.zigTypeTag();
|
|
const rhs_ty_tag = rhs.ty.zigTypeTag();
|
|
|
|
if (lhs_ty_tag == .Vector and rhs_ty_tag == .Vector) {
|
|
if (lhs.ty.arrayLen() != rhs.ty.arrayLen()) {
|
|
return self.fail(scope, src, "vector length mismatch: {} and {}", .{
|
|
lhs.ty.arrayLen(),
|
|
rhs.ty.arrayLen(),
|
|
});
|
|
}
|
|
return self.fail(scope, src, "TODO implement support for vectors in cmpNumeric", .{});
|
|
} else if (lhs_ty_tag == .Vector or rhs_ty_tag == .Vector) {
|
|
return self.fail(scope, src, "mixed scalar and vector operands to comparison operator: '{}' and '{}'", .{
|
|
lhs.ty,
|
|
rhs.ty,
|
|
});
|
|
}
|
|
|
|
if (lhs.value()) |lhs_val| {
|
|
if (rhs.value()) |rhs_val| {
|
|
return self.constBool(scope, src, Value.compare(lhs_val, op, rhs_val));
|
|
}
|
|
}
|
|
|
|
// TODO handle comparisons against lazy zero values
|
|
// Some values can be compared against zero without being runtime known or without forcing
|
|
// a full resolution of their value, for example `@sizeOf(@Frame(function))` is known to
|
|
// always be nonzero, and we benefit from not forcing the full evaluation and stack frame layout
|
|
// of this function if we don't need to.
|
|
|
|
// It must be a runtime comparison.
|
|
const b = try self.requireRuntimeBlock(scope, src);
|
|
// For floats, emit a float comparison instruction.
|
|
const lhs_is_float = switch (lhs_ty_tag) {
|
|
.Float, .ComptimeFloat => true,
|
|
else => false,
|
|
};
|
|
const rhs_is_float = switch (rhs_ty_tag) {
|
|
.Float, .ComptimeFloat => true,
|
|
else => false,
|
|
};
|
|
if (lhs_is_float and rhs_is_float) {
|
|
// Implicit cast the smaller one to the larger one.
|
|
const dest_type = x: {
|
|
if (lhs_ty_tag == .ComptimeFloat) {
|
|
break :x rhs.ty;
|
|
} else if (rhs_ty_tag == .ComptimeFloat) {
|
|
break :x lhs.ty;
|
|
}
|
|
if (lhs.ty.floatBits(self.target()) >= rhs.ty.floatBits(self.target())) {
|
|
break :x lhs.ty;
|
|
} else {
|
|
break :x rhs.ty;
|
|
}
|
|
};
|
|
const casted_lhs = try self.coerce(scope, dest_type, lhs);
|
|
const casted_rhs = try self.coerce(scope, dest_type, rhs);
|
|
return self.addNewInstArgs(b, src, dest_type, Inst.Cmp, Inst.Args(Inst.Cmp){
|
|
.lhs = casted_lhs,
|
|
.rhs = casted_rhs,
|
|
.op = op,
|
|
});
|
|
}
|
|
// For mixed unsigned integer sizes, implicit cast both operands to the larger integer.
|
|
// For mixed signed and unsigned integers, implicit cast both operands to a signed
|
|
// integer with + 1 bit.
|
|
// For mixed floats and integers, extract the integer part from the float, cast that to
|
|
// a signed integer with mantissa bits + 1, and if there was any non-integral part of the float,
|
|
// add/subtract 1.
|
|
const lhs_is_signed = if (lhs.value()) |lhs_val|
|
|
lhs_val.compareWithZero(.lt)
|
|
else
|
|
(lhs.ty.isFloat() or lhs.ty.isSignedInt());
|
|
const rhs_is_signed = if (rhs.value()) |rhs_val|
|
|
rhs_val.compareWithZero(.lt)
|
|
else
|
|
(rhs.ty.isFloat() or rhs.ty.isSignedInt());
|
|
const dest_int_is_signed = lhs_is_signed or rhs_is_signed;
|
|
|
|
var dest_float_type: ?Type = null;
|
|
|
|
var lhs_bits: usize = undefined;
|
|
if (lhs.value()) |lhs_val| {
|
|
if (lhs_val.isUndef())
|
|
return self.constUndef(scope, src, Type.initTag(.bool));
|
|
const is_unsigned = if (lhs_is_float) x: {
|
|
var bigint_space: Value.BigIntSpace = undefined;
|
|
var bigint = try lhs_val.toBigInt(&bigint_space).toManaged(self.allocator);
|
|
defer bigint.deinit();
|
|
const zcmp = lhs_val.orderAgainstZero();
|
|
if (lhs_val.floatHasFraction()) {
|
|
switch (op) {
|
|
.eq => return self.constBool(scope, src, false),
|
|
.neq => return self.constBool(scope, src, true),
|
|
else => {},
|
|
}
|
|
if (zcmp == .lt) {
|
|
try bigint.addScalar(bigint.toConst(), -1);
|
|
} else {
|
|
try bigint.addScalar(bigint.toConst(), 1);
|
|
}
|
|
}
|
|
lhs_bits = bigint.toConst().bitCountTwosComp();
|
|
break :x (zcmp != .lt);
|
|
} else x: {
|
|
lhs_bits = lhs_val.intBitCountTwosComp();
|
|
break :x (lhs_val.orderAgainstZero() != .lt);
|
|
};
|
|
lhs_bits += @boolToInt(is_unsigned and dest_int_is_signed);
|
|
} else if (lhs_is_float) {
|
|
dest_float_type = lhs.ty;
|
|
} else {
|
|
const int_info = lhs.ty.intInfo(self.target());
|
|
lhs_bits = int_info.bits + @boolToInt(!int_info.signed and dest_int_is_signed);
|
|
}
|
|
|
|
var rhs_bits: usize = undefined;
|
|
if (rhs.value()) |rhs_val| {
|
|
if (rhs_val.isUndef())
|
|
return self.constUndef(scope, src, Type.initTag(.bool));
|
|
const is_unsigned = if (rhs_is_float) x: {
|
|
var bigint_space: Value.BigIntSpace = undefined;
|
|
var bigint = try rhs_val.toBigInt(&bigint_space).toManaged(self.allocator);
|
|
defer bigint.deinit();
|
|
const zcmp = rhs_val.orderAgainstZero();
|
|
if (rhs_val.floatHasFraction()) {
|
|
switch (op) {
|
|
.eq => return self.constBool(scope, src, false),
|
|
.neq => return self.constBool(scope, src, true),
|
|
else => {},
|
|
}
|
|
if (zcmp == .lt) {
|
|
try bigint.addScalar(bigint.toConst(), -1);
|
|
} else {
|
|
try bigint.addScalar(bigint.toConst(), 1);
|
|
}
|
|
}
|
|
rhs_bits = bigint.toConst().bitCountTwosComp();
|
|
break :x (zcmp != .lt);
|
|
} else x: {
|
|
rhs_bits = rhs_val.intBitCountTwosComp();
|
|
break :x (rhs_val.orderAgainstZero() != .lt);
|
|
};
|
|
rhs_bits += @boolToInt(is_unsigned and dest_int_is_signed);
|
|
} else if (rhs_is_float) {
|
|
dest_float_type = rhs.ty;
|
|
} else {
|
|
const int_info = rhs.ty.intInfo(self.target());
|
|
rhs_bits = int_info.bits + @boolToInt(!int_info.signed and dest_int_is_signed);
|
|
}
|
|
|
|
const dest_type = if (dest_float_type) |ft| ft else blk: {
|
|
const max_bits = std.math.max(lhs_bits, rhs_bits);
|
|
const casted_bits = std.math.cast(u16, max_bits) catch |err| switch (err) {
|
|
error.Overflow => return self.fail(scope, src, "{} exceeds maximum integer bit count", .{max_bits}),
|
|
};
|
|
break :blk try self.makeIntType(scope, dest_int_is_signed, casted_bits);
|
|
};
|
|
const casted_lhs = try self.coerce(scope, dest_type, lhs);
|
|
const casted_rhs = try self.coerce(scope, dest_type, lhs);
|
|
|
|
return self.addNewInstArgs(b, src, dest_type, Inst.Cmp, Inst.Args(Inst.Cmp){
|
|
.lhs = casted_lhs,
|
|
.rhs = casted_rhs,
|
|
.op = op,
|
|
});
|
|
}
|
|
|
|
fn makeIntType(self: *Module, scope: *Scope, signed: bool, bits: u16) !Type {
|
|
if (signed) {
|
|
const int_payload = try scope.arena().create(Type.Payload.IntSigned);
|
|
int_payload.* = .{ .bits = bits };
|
|
return Type.initPayload(&int_payload.base);
|
|
} else {
|
|
const int_payload = try scope.arena().create(Type.Payload.IntUnsigned);
|
|
int_payload.* = .{ .bits = bits };
|
|
return Type.initPayload(&int_payload.base);
|
|
}
|
|
}
|
|
|
|
fn coerce(self: *Module, scope: *Scope, dest_type: Type, inst: *Inst) !*Inst {
|
|
// If the types are the same, we can return the operand.
|
|
if (dest_type.eql(inst.ty))
|
|
return inst;
|
|
|
|
const in_memory_result = coerceInMemoryAllowed(dest_type, inst.ty);
|
|
if (in_memory_result == .ok) {
|
|
return self.bitcast(scope, dest_type, inst);
|
|
}
|
|
|
|
// *[N]T to []T
|
|
if (inst.ty.isSinglePointer() and dest_type.isSlice() and
|
|
(!inst.ty.pointerIsConst() or dest_type.pointerIsConst()))
|
|
{
|
|
const array_type = inst.ty.elemType();
|
|
const dst_elem_type = dest_type.elemType();
|
|
if (array_type.zigTypeTag() == .Array and
|
|
coerceInMemoryAllowed(dst_elem_type, array_type.elemType()) == .ok)
|
|
{
|
|
return self.coerceArrayPtrToSlice(scope, dest_type, inst);
|
|
}
|
|
}
|
|
|
|
// comptime_int to fixed-width integer
|
|
if (inst.ty.zigTypeTag() == .ComptimeInt and dest_type.zigTypeTag() == .Int) {
|
|
// The representation is already correct; we only need to make sure it fits in the destination type.
|
|
const val = inst.value().?; // comptime_int always has comptime known value
|
|
if (!val.intFitsInType(dest_type, self.target())) {
|
|
return self.fail(scope, inst.src, "type {} cannot represent integer value {}", .{ inst.ty, val });
|
|
}
|
|
return self.constInst(scope, inst.src, .{ .ty = dest_type, .val = val });
|
|
}
|
|
|
|
// integer widening
|
|
if (inst.ty.zigTypeTag() == .Int and dest_type.zigTypeTag() == .Int) {
|
|
const src_info = inst.ty.intInfo(self.target());
|
|
const dst_info = dest_type.intInfo(self.target());
|
|
if (src_info.signed == dst_info.signed and dst_info.bits >= src_info.bits) {
|
|
if (inst.value()) |val| {
|
|
return self.constInst(scope, inst.src, .{ .ty = dest_type, .val = val });
|
|
} else {
|
|
return self.fail(scope, inst.src, "TODO implement runtime integer widening", .{});
|
|
}
|
|
} else {
|
|
return self.fail(scope, inst.src, "TODO implement more int widening {} to {}", .{ inst.ty, dest_type });
|
|
}
|
|
}
|
|
|
|
return self.fail(scope, inst.src, "TODO implement type coercion from {} to {}", .{ inst.ty, dest_type });
|
|
}
|
|
|
|
fn bitcast(self: *Module, scope: *Scope, dest_type: Type, inst: *Inst) !*Inst {
|
|
if (inst.value()) |val| {
|
|
// Keep the comptime Value representation; take the new type.
|
|
return self.constInst(scope, inst.src, .{ .ty = dest_type, .val = val });
|
|
}
|
|
// TODO validate the type size and other compile errors
|
|
const b = try self.requireRuntimeBlock(scope, inst.src);
|
|
return self.addNewInstArgs(b, inst.src, dest_type, Inst.BitCast, Inst.Args(Inst.BitCast){ .operand = inst });
|
|
}
|
|
|
|
fn coerceArrayPtrToSlice(self: *Module, scope: *Scope, dest_type: Type, inst: *Inst) !*Inst {
|
|
if (inst.value()) |val| {
|
|
// The comptime Value representation is compatible with both types.
|
|
return self.constInst(scope, inst.src, .{ .ty = dest_type, .val = val });
|
|
}
|
|
return self.fail(scope, inst.src, "TODO implement coerceArrayPtrToSlice runtime instruction", .{});
|
|
}
|
|
|
|
fn fail(self: *Module, scope: *Scope, src: usize, comptime format: []const u8, args: var) InnerError {
|
|
@setCold(true);
|
|
const err_msg = try ErrorMsg.create(self.allocator, src, format, args);
|
|
return self.failWithOwnedErrorMsg(scope, src, err_msg);
|
|
}
|
|
|
|
fn failWithOwnedErrorMsg(self: *Module, scope: *Scope, src: usize, err_msg: *ErrorMsg) InnerError {
|
|
{
|
|
errdefer err_msg.destroy(self.allocator);
|
|
try self.failed_decls.ensureCapacity(self.failed_decls.size + 1);
|
|
try self.failed_files.ensureCapacity(self.failed_files.size + 1);
|
|
}
|
|
switch (scope.tag) {
|
|
.decl => {
|
|
const decl = scope.cast(Scope.DeclAnalysis).?.decl;
|
|
decl.analysis = .sema_failure;
|
|
self.failed_decls.putAssumeCapacityNoClobber(decl, err_msg);
|
|
},
|
|
.block => {
|
|
const block = scope.cast(Scope.Block).?;
|
|
block.func.analysis = .sema_failure;
|
|
self.failed_decls.putAssumeCapacityNoClobber(block.decl, err_msg);
|
|
},
|
|
.zir_module => {
|
|
const zir_module = scope.cast(Scope.ZIRModule).?;
|
|
zir_module.status = .loaded_sema_failure;
|
|
self.failed_files.putAssumeCapacityNoClobber(zir_module, err_msg);
|
|
},
|
|
}
|
|
return error.AnalysisFail;
|
|
}
|
|
|
|
const InMemoryCoercionResult = enum {
|
|
ok,
|
|
no_match,
|
|
};
|
|
|
|
fn coerceInMemoryAllowed(dest_type: Type, src_type: Type) InMemoryCoercionResult {
|
|
if (dest_type.eql(src_type))
|
|
return .ok;
|
|
|
|
// TODO: implement more of this function
|
|
|
|
return .no_match;
|
|
}
|
|
|
|
pub const ErrorMsg = struct {
|
|
byte_offset: usize,
|
|
msg: []const u8,
|
|
|
|
pub fn create(allocator: *Allocator, byte_offset: usize, comptime format: []const u8, args: var) !*ErrorMsg {
|
|
const self = try allocator.create(ErrorMsg);
|
|
errdefer allocator.destroy(self);
|
|
self.* = try init(allocator, byte_offset, format, args);
|
|
return self;
|
|
}
|
|
|
|
/// Assumes the ErrorMsg struct and msg were both allocated with allocator.
|
|
pub fn destroy(self: *ErrorMsg, allocator: *Allocator) void {
|
|
self.deinit(allocator);
|
|
allocator.destroy(self);
|
|
}
|
|
|
|
pub fn init(allocator: *Allocator, byte_offset: usize, comptime format: []const u8, args: var) !ErrorMsg {
|
|
return ErrorMsg{
|
|
.byte_offset = byte_offset,
|
|
.msg = try std.fmt.allocPrint(allocator, format, args),
|
|
};
|
|
}
|
|
|
|
pub fn deinit(self: *ErrorMsg, allocator: *Allocator) void {
|
|
allocator.free(self.msg);
|
|
self.* = undefined;
|
|
}
|
|
};
|