zig/src-self-hosted/scope.zig

const std = @import("std");
const Allocator = mem.Allocator;
const Decl = @import("decl.zig").Decl;
const Compilation = @import("compilation.zig").Compilation;
const mem = std.mem;
const ast = std.zig.ast;
const Value = @import("value.zig").Value;
const ir = @import("ir.zig");

pub const Scope = struct {
    id: Id,
    parent: ?*Scope,
    ref_count: usize,

    pub fn ref(base: *Scope) void {
        base.ref_count += 1;
    }

    pub fn deref(base: *Scope, comp: *Compilation) void {
        base.ref_count -= 1;
        if (base.ref_count == 0) {
            if (base.parent) |parent| parent.deref(comp);
            switch (base.id) {
                Id.Decls => @fieldParentPtr(Decls, "base", base).destroy(),
                Id.Block => @fieldParentPtr(Block, "base", base).destroy(comp),
                Id.FnDef => @fieldParentPtr(FnDef, "base", base).destroy(comp),
                Id.CompTime => @fieldParentPtr(CompTime, "base", base).destroy(comp),
                Id.Defer => @fieldParentPtr(Defer, "base", base).destroy(comp),
                Id.DeferExpr => @fieldParentPtr(DeferExpr, "base", base).destroy(comp),
            }
        }
    }

    pub fn findFnDef(base: *Scope) ?*FnDef {
        var scope = base;
        while (true) {
            switch (scope.id) {
                Id.FnDef => return @fieldParentPtr(FnDef, "base", base),
                Id.Decls => return null,

                Id.Block,
                Id.Defer,
                Id.DeferExpr,
                Id.CompTime,
                => scope = scope.parent orelse return null,
            }
        }
    }

    pub const Id = enum {
        Decls,
        Block,
        FnDef,
        CompTime,
        Defer,
        DeferExpr,
    };

    pub const Decls = struct {
        base: Scope,
        table: Decl.Table,

        /// Creates a Decls scope with 1 reference
        pub fn create(comp: *Compilation, parent: ?*Scope) !*Decls {
            const self = try comp.a().create(Decls{
                .base = Scope{
                    .id = Id.Decls,
                    .parent = parent,
                    .ref_count = 1,
                },
                .table = undefined,
            });
            errdefer comp.a().destroy(self);

            self.table = Decl.Table.init(comp.a());
            errdefer self.table.deinit();

            if (parent) |p| p.ref();

            return self;
        }

        pub fn destroy(self: *Decls) void {
            self.table.deinit();
            self.table.allocator.destroy(self);
        }
    };

    pub const Block = struct {
        base: Scope,
        incoming_values: std.ArrayList(*ir.Instruction),
        incoming_blocks: std.ArrayList(*ir.BasicBlock),
        end_block: *ir.BasicBlock,
        is_comptime: *ir.Instruction,

        /// Creates a Block scope with 1 reference
        pub fn create(comp: *Compilation, parent: ?*Scope) !*Block {
            const self = try comp.a().create(Block{
                .base = Scope{
                    .id = Id.Block,
                    .parent = parent,
                    .ref_count = 1,
                },
                .incoming_values = undefined,
                .incoming_blocks = undefined,
                .end_block = undefined,
                .is_comptime = undefined,
            });
            errdefer comp.a().destroy(self);

            if (parent) |p| p.ref();
            return self;
        }

        pub fn destroy(self: *Block, comp: *Compilation) void {
            comp.a().destroy(self);
        }
    };

    pub const FnDef = struct {
        base: Scope,

        /// This reference is not counted so that the scope can get destroyed with the function
        fn_val: *Value.Fn,

        /// Creates a FnDef scope with 1 reference
        /// Must set the fn_val later
        pub fn create(comp: *Compilation, parent: ?*Scope) !*FnDef {
            const self = try comp.a().create(FnDef{
                .base = Scope{
                    .id = Id.FnDef,
                    .parent = parent,
                    .ref_count = 1,
                },
                .fn_val = undefined,
            });

            if (parent) |p| p.ref();

            return self;
        }

        pub fn destroy(self: *FnDef, comp: *Compilation) void {
            comp.a().destroy(self);
        }
    };

    pub const CompTime = struct {
        base: Scope,

        /// Creates a CompTime scope with 1 reference
        pub fn create(comp: *Compilation, parent: ?*Scope) !*CompTime {
            const self = try comp.a().create(CompTime{
                .base = Scope{
                    .id = Id.CompTime,
                    .parent = parent,
                    .ref_count = 1,
                },
            });

            if (parent) |p| p.ref();
            return self;
        }

        pub fn destroy(self: *CompTime, comp: *Compilation) void {
            comp.a().destroy(self);
        }
    };

    pub const Defer = struct {
        base: Scope,
        defer_expr_scope: *DeferExpr,
        kind: Kind,

        pub const Kind = enum {
            ScopeExit,
            ErrorExit,
        };

        /// Creates a Defer scope with 1 reference
        pub fn create(
            comp: *Compilation,
            parent: ?*Scope,
            kind: Kind,
            defer_expr_scope: *DeferExpr,
        ) !*Defer {
            const self = try comp.a().create(Defer{
                .base = Scope{
                    .id = Id.Defer,
                    .parent = parent,
                    .ref_count = 1,
                },
                .defer_expr_scope = defer_expr_scope,
                .kind = kind,
            });
            errdefer comp.a().destroy(self);

            defer_expr_scope.base.ref();

            if (parent) |p| p.ref();
            return self;
        }

        pub fn destroy(self: *Defer, comp: *Compilation) void {
            self.defer_expr_scope.base.deref(comp);
            comp.a().destroy(self);
        }
    };

    pub const DeferExpr = struct {
        base: Scope,
        expr_node: *ast.Node,

        /// Creates a DeferExpr scope with 1 reference
        pub fn create(comp: *Compilation, parent: ?*Scope, expr_node: *ast.Node) !*DeferExpr {
            const self = try comp.a().create(DeferExpr{
                .base = Scope{
                    .id = Id.DeferExpr,
                    .parent = parent,
                    .ref_count = 1,
                },
                .expr_node = expr_node,
            });
            errdefer comp.a().destroy(self);

            if (parent) |p| p.ref();
            return self;
        }

        pub fn destroy(self: *DeferExpr, comp: *Compilation) void {
            comp.a().destroy(self);
        }
    };
};
self-hosted: generate zig IR for simple function no tests for this yet. I think the quickest path to testing will be creating the .o files and linking with libc, executing, and then comparing output. 2018-07-12 12:08:40 -07:00			`const std = @import("std");`
			`const Allocator = mem.Allocator;`
			`const Decl = @import("decl.zig").Decl;`
rename Module to Compilation and CompilationUnit to ObjectFile 2018-07-14 13:12:41 -07:00			`const Compilation = @import("compilation.zig").Compilation;`
self-hosted: generate zig IR for simple function no tests for this yet. I think the quickest path to testing will be creating the .o files and linking with libc, executing, and then comparing output. 2018-07-12 12:08:40 -07:00			`const mem = std.mem;`
			`const ast = std.zig.ast;`
			`const Value = @import("value.zig").Value;`
			`const ir = @import("ir.zig");`

self-hosted: build against zig_llvm and embedded LLD Now the self-hosted compiler re-uses the same C++ code for interfacing with LLVM as the C++ code. It also links against the same LLD library files. 2017-12-26 16:44:08 -08:00			`pub const Scope = struct {`
			`id: Id,`
self-hosted: generate zig IR for simple function no tests for this yet. I think the quickest path to testing will be creating the .o files and linking with libc, executing, and then comparing output. 2018-07-12 12:08:40 -07:00			`parent: ?*Scope,`
			`ref_count: usize,`

			`pub fn ref(base: *Scope) void {`
			`base.ref_count += 1;`
			`}`

rename Module to Compilation and CompilationUnit to ObjectFile 2018-07-14 13:12:41 -07:00			`pub fn deref(base: Scope, comp: Compilation) void {`
self-hosted: generate zig IR for simple function no tests for this yet. I think the quickest path to testing will be creating the .o files and linking with libc, executing, and then comparing output. 2018-07-12 12:08:40 -07:00			`base.ref_count -= 1;`
			`if (base.ref_count == 0) {`
rename Module to Compilation and CompilationUnit to ObjectFile 2018-07-14 13:12:41 -07:00			`if (base.parent) \|parent\| parent.deref(comp);`
self-hosted: generate zig IR for simple function no tests for this yet. I think the quickest path to testing will be creating the .o files and linking with libc, executing, and then comparing output. 2018-07-12 12:08:40 -07:00			`switch (base.id) {`
			`Id.Decls => @fieldParentPtr(Decls, "base", base).destroy(),`
rename Module to Compilation and CompilationUnit to ObjectFile 2018-07-14 13:12:41 -07:00			`Id.Block => @fieldParentPtr(Block, "base", base).destroy(comp),`
			`Id.FnDef => @fieldParentPtr(FnDef, "base", base).destroy(comp),`
			`Id.CompTime => @fieldParentPtr(CompTime, "base", base).destroy(comp),`
			`Id.Defer => @fieldParentPtr(Defer, "base", base).destroy(comp),`
			`Id.DeferExpr => @fieldParentPtr(DeferExpr, "base", base).destroy(comp),`
self-hosted: generate zig IR for simple function no tests for this yet. I think the quickest path to testing will be creating the .o files and linking with libc, executing, and then comparing output. 2018-07-12 12:08:40 -07:00			`}`
			`}`
			`}`

			`pub fn findFnDef(base: Scope) ?FnDef {`
			`var scope = base;`
			`while (true) {`
			`switch (scope.id) {`
			`Id.FnDef => return @fieldParentPtr(FnDef, "base", base),`
			`Id.Decls => return null,`

			`Id.Block,`
			`Id.Defer,`
			`Id.DeferExpr,`
			`Id.CompTime,`
			`=> scope = scope.parent orelse return null,`
			`}`
			`}`
			`}`
self-hosted: build against zig_llvm and embedded LLD Now the self-hosted compiler re-uses the same C++ code for interfacing with LLVM as the C++ code. It also links against the same LLD library files. 2017-12-26 16:44:08 -08:00
			`pub const Id = enum {`
			`Decls,`
			`Block,`
			`FnDef,`
			`CompTime,`
self-hosted: generate zig IR for simple function no tests for this yet. I think the quickest path to testing will be creating the .o files and linking with libc, executing, and then comparing output. 2018-07-12 12:08:40 -07:00			`Defer,`
			`DeferExpr,`
			`};`

			`pub const Decls = struct {`
			`base: Scope,`
			`table: Decl.Table,`

			`/// Creates a Decls scope with 1 reference`
rename Module to Compilation and CompilationUnit to ObjectFile 2018-07-14 13:12:41 -07:00			`pub fn create(comp: Compilation, parent: ?Scope) !*Decls {`
			`const self = try comp.a().create(Decls{`
self-hosted: generate zig IR for simple function no tests for this yet. I think the quickest path to testing will be creating the .o files and linking with libc, executing, and then comparing output. 2018-07-12 12:08:40 -07:00			`.base = Scope{`
			`.id = Id.Decls,`
			`.parent = parent,`
			`.ref_count = 1,`
			`},`
			`.table = undefined,`
			`});`
rename Module to Compilation and CompilationUnit to ObjectFile 2018-07-14 13:12:41 -07:00			`errdefer comp.a().destroy(self);`
self-hosted: generate zig IR for simple function no tests for this yet. I think the quickest path to testing will be creating the .o files and linking with libc, executing, and then comparing output. 2018-07-12 12:08:40 -07:00
rename Module to Compilation and CompilationUnit to ObjectFile 2018-07-14 13:12:41 -07:00			`self.table = Decl.Table.init(comp.a());`
self-hosted: generate zig IR for simple function no tests for this yet. I think the quickest path to testing will be creating the .o files and linking with libc, executing, and then comparing output. 2018-07-12 12:08:40 -07:00			`errdefer self.table.deinit();`

			`if (parent) \|p\| p.ref();`

			`return self;`
			`}`

			`pub fn destroy(self: *Decls) void {`
			`self.table.deinit();`
			`self.table.allocator.destroy(self);`
			`}`
			`};`

			`pub const Block = struct {`
			`base: Scope,`
			`incoming_values: std.ArrayList(*ir.Instruction),`
			`incoming_blocks: std.ArrayList(*ir.BasicBlock),`
			`end_block: *ir.BasicBlock,`
			`is_comptime: *ir.Instruction,`

			`/// Creates a Block scope with 1 reference`
rename Module to Compilation and CompilationUnit to ObjectFile 2018-07-14 13:12:41 -07:00			`pub fn create(comp: Compilation, parent: ?Scope) !*Block {`
			`const self = try comp.a().create(Block{`
self-hosted: generate zig IR for simple function no tests for this yet. I think the quickest path to testing will be creating the .o files and linking with libc, executing, and then comparing output. 2018-07-12 12:08:40 -07:00			`.base = Scope{`
			`.id = Id.Block,`
			`.parent = parent,`
			`.ref_count = 1,`
			`},`
			`.incoming_values = undefined,`
			`.incoming_blocks = undefined,`
			`.end_block = undefined,`
			`.is_comptime = undefined,`
			`});`
rename Module to Compilation and CompilationUnit to ObjectFile 2018-07-14 13:12:41 -07:00			`errdefer comp.a().destroy(self);`
self-hosted: generate zig IR for simple function no tests for this yet. I think the quickest path to testing will be creating the .o files and linking with libc, executing, and then comparing output. 2018-07-12 12:08:40 -07:00
			`if (parent) \|p\| p.ref();`
			`return self;`
			`}`

rename Module to Compilation and CompilationUnit to ObjectFile 2018-07-14 13:12:41 -07:00			`pub fn destroy(self: Block, comp: Compilation) void {`
			`comp.a().destroy(self);`
self-hosted: generate zig IR for simple function no tests for this yet. I think the quickest path to testing will be creating the .o files and linking with libc, executing, and then comparing output. 2018-07-12 12:08:40 -07:00			`}`
			`};`

			`pub const FnDef = struct {`
			`base: Scope,`

			`/// This reference is not counted so that the scope can get destroyed with the function`
			`fn_val: *Value.Fn,`

			`/// Creates a FnDef scope with 1 reference`
			`/// Must set the fn_val later`
rename Module to Compilation and CompilationUnit to ObjectFile 2018-07-14 13:12:41 -07:00			`pub fn create(comp: Compilation, parent: ?Scope) !*FnDef {`
			`const self = try comp.a().create(FnDef{`
self-hosted: generate zig IR for simple function no tests for this yet. I think the quickest path to testing will be creating the .o files and linking with libc, executing, and then comparing output. 2018-07-12 12:08:40 -07:00			`.base = Scope{`
			`.id = Id.FnDef,`
			`.parent = parent,`
			`.ref_count = 1,`
			`},`
			`.fn_val = undefined,`
			`});`

			`if (parent) \|p\| p.ref();`

			`return self;`
			`}`

rename Module to Compilation and CompilationUnit to ObjectFile 2018-07-14 13:12:41 -07:00			`pub fn destroy(self: FnDef, comp: Compilation) void {`
			`comp.a().destroy(self);`
self-hosted: generate zig IR for simple function no tests for this yet. I think the quickest path to testing will be creating the .o files and linking with libc, executing, and then comparing output. 2018-07-12 12:08:40 -07:00			`}`
			`};`

			`pub const CompTime = struct {`
			`base: Scope,`

			`/// Creates a CompTime scope with 1 reference`
rename Module to Compilation and CompilationUnit to ObjectFile 2018-07-14 13:12:41 -07:00			`pub fn create(comp: Compilation, parent: ?Scope) !*CompTime {`
			`const self = try comp.a().create(CompTime{`
self-hosted: generate zig IR for simple function no tests for this yet. I think the quickest path to testing will be creating the .o files and linking with libc, executing, and then comparing output. 2018-07-12 12:08:40 -07:00			`.base = Scope{`
			`.id = Id.CompTime,`
			`.parent = parent,`
			`.ref_count = 1,`
			`},`
			`});`

			`if (parent) \|p\| p.ref();`
			`return self;`
			`}`

rename Module to Compilation and CompilationUnit to ObjectFile 2018-07-14 13:12:41 -07:00			`pub fn destroy(self: CompTime, comp: Compilation) void {`
			`comp.a().destroy(self);`
self-hosted: generate zig IR for simple function no tests for this yet. I think the quickest path to testing will be creating the .o files and linking with libc, executing, and then comparing output. 2018-07-12 12:08:40 -07:00			`}`
			`};`

			`pub const Defer = struct {`
			`base: Scope,`
			`defer_expr_scope: *DeferExpr,`
			`kind: Kind,`

			`pub const Kind = enum {`
			`ScopeExit,`
			`ErrorExit,`
			`};`

			`/// Creates a Defer scope with 1 reference`
			`pub fn create(`
rename Module to Compilation and CompilationUnit to ObjectFile 2018-07-14 13:12:41 -07:00			`comp: *Compilation,`
self-hosted: generate zig IR for simple function no tests for this yet. I think the quickest path to testing will be creating the .o files and linking with libc, executing, and then comparing output. 2018-07-12 12:08:40 -07:00			`parent: ?*Scope,`
			`kind: Kind,`
			`defer_expr_scope: *DeferExpr,`
			`) !*Defer {`
rename Module to Compilation and CompilationUnit to ObjectFile 2018-07-14 13:12:41 -07:00			`const self = try comp.a().create(Defer{`
self-hosted: generate zig IR for simple function no tests for this yet. I think the quickest path to testing will be creating the .o files and linking with libc, executing, and then comparing output. 2018-07-12 12:08:40 -07:00			`.base = Scope{`
			`.id = Id.Defer,`
			`.parent = parent,`
			`.ref_count = 1,`
			`},`
			`.defer_expr_scope = defer_expr_scope,`
			`.kind = kind,`
			`});`
rename Module to Compilation and CompilationUnit to ObjectFile 2018-07-14 13:12:41 -07:00			`errdefer comp.a().destroy(self);`
self-hosted: generate zig IR for simple function no tests for this yet. I think the quickest path to testing will be creating the .o files and linking with libc, executing, and then comparing output. 2018-07-12 12:08:40 -07:00
			`defer_expr_scope.base.ref();`

			`if (parent) \|p\| p.ref();`
			`return self;`
			`}`

rename Module to Compilation and CompilationUnit to ObjectFile 2018-07-14 13:12:41 -07:00			`pub fn destroy(self: Defer, comp: Compilation) void {`
			`self.defer_expr_scope.base.deref(comp);`
			`comp.a().destroy(self);`
self-hosted: generate zig IR for simple function no tests for this yet. I think the quickest path to testing will be creating the .o files and linking with libc, executing, and then comparing output. 2018-07-12 12:08:40 -07:00			`}`
			`};`

			`pub const DeferExpr = struct {`
			`base: Scope,`
			`expr_node: *ast.Node,`

			`/// Creates a DeferExpr scope with 1 reference`
rename Module to Compilation and CompilationUnit to ObjectFile 2018-07-14 13:12:41 -07:00			`pub fn create(comp: Compilation, parent: ?Scope, expr_node: ast.Node) !DeferExpr {`
			`const self = try comp.a().create(DeferExpr{`
self-hosted: generate zig IR for simple function no tests for this yet. I think the quickest path to testing will be creating the .o files and linking with libc, executing, and then comparing output. 2018-07-12 12:08:40 -07:00			`.base = Scope{`
			`.id = Id.DeferExpr,`
			`.parent = parent,`
			`.ref_count = 1,`
			`},`
			`.expr_node = expr_node,`
			`});`
rename Module to Compilation and CompilationUnit to ObjectFile 2018-07-14 13:12:41 -07:00			`errdefer comp.a().destroy(self);`
self-hosted: generate zig IR for simple function no tests for this yet. I think the quickest path to testing will be creating the .o files and linking with libc, executing, and then comparing output. 2018-07-12 12:08:40 -07:00
			`if (parent) \|p\| p.ref();`
			`return self;`
			`}`

rename Module to Compilation and CompilationUnit to ObjectFile 2018-07-14 13:12:41 -07:00			`pub fn destroy(self: DeferExpr, comp: Compilation) void {`
			`comp.a().destroy(self);`
self-hosted: generate zig IR for simple function no tests for this yet. I think the quickest path to testing will be creating the .o files and linking with libc, executing, and then comparing output. 2018-07-12 12:08:40 -07:00			`}`
self-hosted: build against zig_llvm and embedded LLD Now the self-hosted compiler re-uses the same C++ code for interfacing with LLVM as the C++ code. It also links against the same LLD library files. 2017-12-26 16:44:08 -08:00			`};`
			`};`