const std = @import("std"); const g = @import("spirv/grammar.zig"); const Allocator = std.mem.Allocator; const ExtendedStructSet = std.StringHashMap(void); pub fn main() !void { var arena = std.heap.ArenaAllocator.init(std.heap.page_allocator); defer arena.deinit(); const allocator = arena.allocator(); const args = try std.process.argsAlloc(allocator); if (args.len != 2) { usageAndExit(std.io.getStdErr(), args[0], 1); } const spec_path = args[1]; const spec = try std.fs.cwd().readFileAlloc(allocator, spec_path, std.math.maxInt(usize)); // Required for json parsing. @setEvalBranchQuota(10000); var scanner = std.json.Scanner.initCompleteInput(allocator, spec); var diagnostics = std.json.Diagnostics{}; scanner.enableDiagnostics(&diagnostics); const parsed = std.json.parseFromTokenSource(g.CoreRegistry, allocator, &scanner, .{}) catch |err| { std.debug.print("line,col: {},{}\n", .{ diagnostics.getLine(), diagnostics.getColumn() }); return err; }; var bw = std.io.bufferedWriter(std.io.getStdOut().writer()); try render(bw.writer(), allocator, parsed.value); try bw.flush(); } /// Returns a set with types that require an extra struct for the `Instruction` interface /// to the spir-v spec, or whether the original type can be used. fn extendedStructs( arena: Allocator, kinds: []const g.OperandKind, ) !ExtendedStructSet { var map = ExtendedStructSet.init(arena); try map.ensureTotalCapacity(@as(u32, @intCast(kinds.len))); for (kinds) |kind| { const enumerants = kind.enumerants orelse continue; for (enumerants) |enumerant| { if (enumerant.parameters.len > 0) { break; } } else continue; map.putAssumeCapacity(kind.kind, {}); } return map; } // Return a score for a particular priority. Duplicate instruction/operand enum values are // removed by picking the tag with the lowest score to keep, and by making an alias for the // other. Note that the tag does not need to be just a tag at this point, in which case it // gets the lowest score automatically anyway. fn tagPriorityScore(tag: []const u8) usize { if (tag.len == 0) { return 1; } else if (std.mem.eql(u8, tag, "EXT")) { return 2; } else if (std.mem.eql(u8, tag, "KHR")) { return 3; } else { return 4; } } fn render(writer: anytype, allocator: Allocator, registry: g.CoreRegistry) !void { try writer.writeAll( \\//! This file is auto-generated by tools/gen_spirv_spec.zig. \\ \\const Version = @import("std").SemanticVersion; \\ \\pub const Word = u32; \\pub const IdResult = struct{ \\ id: Word, \\}; \\pub const IdResultType = IdResult; \\pub const IdRef = IdResult; \\ \\pub const IdMemorySemantics = IdRef; \\pub const IdScope = IdRef; \\ \\pub const LiteralInteger = Word; \\pub const LiteralString = []const u8; \\pub const LiteralContextDependentNumber = union(enum) { \\ int32: i32, \\ uint32: u32, \\ int64: i64, \\ uint64: u64, \\ float32: f32, \\ float64: f64, \\}; \\pub const LiteralExtInstInteger = struct{ inst: Word }; \\pub const LiteralSpecConstantOpInteger = struct { opcode: Opcode }; \\pub const PairLiteralIntegerIdRef = struct { value: LiteralInteger, label: IdRef }; \\pub const PairIdRefLiteralInteger = struct { target: IdRef, member: LiteralInteger }; \\pub const PairIdRefIdRef = [2]IdRef; \\ \\pub const Quantifier = enum { \\ required, \\ optional, \\ variadic, \\}; \\ \\pub const Operand = struct { \\ kind: OperandKind, \\ quantifier: Quantifier, \\}; \\ \\pub const OperandCategory = enum { \\ bit_enum, \\ value_enum, \\ id, \\ literal, \\ composite, \\}; \\ \\pub const Enumerant = struct { \\ name: []const u8, \\ value: Word, \\ parameters: []const OperandKind, \\}; \\ \\ ); try writer.print( \\pub const version = Version{{ .major = {}, .minor = {}, .patch = {} }}; \\pub const magic_number: Word = {s}; \\ \\ , .{ registry.major_version, registry.minor_version, registry.revision, registry.magic_number }, ); const extended_structs = try extendedStructs(allocator, registry.operand_kinds); try renderClass(writer, allocator, registry.instructions); try renderOperandKind(writer, registry.operand_kinds); try renderOpcodes(writer, allocator, registry.instructions, extended_structs); try renderOperandKinds(writer, allocator, registry.operand_kinds, extended_structs); } fn renderClass(writer: anytype, allocator: Allocator, instructions: []const g.Instruction) !void { var class_map = std.StringArrayHashMap(void).init(allocator); for (instructions) |inst| { if (std.mem.eql(u8, inst.class.?, "@exclude")) { continue; } try class_map.put(inst.class.?, {}); } try writer.writeAll("pub const Class = enum {\n"); for (class_map.keys()) |class| { try renderInstructionClass(writer, class); try writer.writeAll(",\n"); } try writer.writeAll("};\n"); } fn renderInstructionClass(writer: anytype, class: []const u8) !void { // Just assume that these wont clobber zig builtin types. var prev_was_sep = true; for (class) |c| { switch (c) { '-', '_' => prev_was_sep = true, else => if (prev_was_sep) { try writer.writeByte(std.ascii.toUpper(c)); prev_was_sep = false; } else { try writer.writeByte(std.ascii.toLower(c)); }, } } } fn renderOperandKind(writer: anytype, operands: []const g.OperandKind) !void { try writer.writeAll("pub const OperandKind = enum {\n"); for (operands) |operand| { try writer.print("{},\n", .{std.zig.fmtId(operand.kind)}); } try writer.writeAll( \\ \\pub fn category(self: OperandKind) OperandCategory { \\return switch (self) { \\ ); for (operands) |operand| { const cat = switch (operand.category) { .BitEnum => "bit_enum", .ValueEnum => "value_enum", .Id => "id", .Literal => "literal", .Composite => "composite", }; try writer.print(".{} => .{s},\n", .{ std.zig.fmtId(operand.kind), cat }); } try writer.writeAll( \\}; \\} \\pub fn enumerants(self: OperandKind) []const Enumerant { \\return switch (self) { \\ ); for (operands) |operand| { switch (operand.category) { .BitEnum, .ValueEnum => {}, else => { try writer.print(".{} => unreachable,\n", .{std.zig.fmtId(operand.kind)}); continue; }, } try writer.print(".{} => &[_]Enumerant{{", .{std.zig.fmtId(operand.kind)}); for (operand.enumerants.?) |enumerant| { if (enumerant.value == .bitflag and std.mem.eql(u8, enumerant.enumerant, "None")) { continue; } try renderEnumerant(writer, enumerant); try writer.writeAll(","); } try writer.writeAll("},\n"); } try writer.writeAll("};\n}\n};\n"); } fn renderEnumerant(writer: anytype, enumerant: g.Enumerant) !void { try writer.print(".{{.name = \"{s}\", .value = ", .{enumerant.enumerant}); switch (enumerant.value) { .bitflag => |flag| try writer.writeAll(flag), .int => |int| try writer.print("{}", .{int}), } try writer.writeAll(", .parameters = &[_]OperandKind{"); for (enumerant.parameters, 0..) |param, i| { if (i != 0) try writer.writeAll(", "); // Note, param.quantifier will always be one. try writer.print(".{}", .{std.zig.fmtId(param.kind)}); } try writer.writeAll("}}"); } fn renderOpcodes( writer: anytype, allocator: Allocator, instructions: []const g.Instruction, extended_structs: ExtendedStructSet, ) !void { var inst_map = std.AutoArrayHashMap(u32, usize).init(allocator); try inst_map.ensureTotalCapacity(instructions.len); var aliases = std.ArrayList(struct { inst: usize, alias: usize }).init(allocator); try aliases.ensureTotalCapacity(instructions.len); for (instructions, 0..) |inst, i| { if (std.mem.eql(u8, inst.class.?, "@exclude")) { continue; } const result = inst_map.getOrPutAssumeCapacity(inst.opcode); if (!result.found_existing) { result.value_ptr.* = i; continue; } const existing = instructions[result.value_ptr.*]; const tag_index = std.mem.indexOfDiff(u8, inst.opname, existing.opname).?; const inst_priority = tagPriorityScore(inst.opname[tag_index..]); const existing_priority = tagPriorityScore(existing.opname[tag_index..]); if (inst_priority < existing_priority) { aliases.appendAssumeCapacity(.{ .inst = result.value_ptr.*, .alias = i }); result.value_ptr.* = i; } else { aliases.appendAssumeCapacity(.{ .inst = i, .alias = result.value_ptr.* }); } } const instructions_indices = inst_map.values(); try writer.writeAll("pub const Opcode = enum(u16) {\n"); for (instructions_indices) |i| { const inst = instructions[i]; try writer.print("{} = {},\n", .{ std.zig.fmtId(inst.opname), inst.opcode }); } try writer.writeByte('\n'); for (aliases.items) |alias| { try writer.print("pub const {} = Opcode.{};\n", .{ std.zig.fmtId(instructions[alias.inst].opname), std.zig.fmtId(instructions[alias.alias].opname), }); } try writer.writeAll( \\ \\pub fn Operands(comptime self: Opcode) type { \\return switch (self) { \\ ); for (instructions_indices) |i| { const inst = instructions[i]; try renderOperand(writer, .instruction, inst.opname, inst.operands, extended_structs); } try writer.writeAll( \\}; \\} \\pub fn operands(self: Opcode) []const Operand { \\return switch (self) { \\ ); for (instructions_indices) |i| { const inst = instructions[i]; try writer.print(".{} => &[_]Operand{{", .{std.zig.fmtId(inst.opname)}); for (inst.operands) |operand| { const quantifier = if (operand.quantifier) |q| switch (q) { .@"?" => "optional", .@"*" => "variadic", } else "required"; try writer.print(".{{.kind = .{s}, .quantifier = .{s}}},", .{ operand.kind, quantifier }); } try writer.writeAll("},\n"); } try writer.writeAll( \\}; \\} \\pub fn class(self: Opcode) Class { \\return switch (self) { \\ ); for (instructions_indices) |i| { const inst = instructions[i]; try writer.print(".{} => .", .{std.zig.fmtId(inst.opname)}); try renderInstructionClass(writer, inst.class.?); try writer.writeAll(",\n"); } try writer.writeAll("};\n}\n};\n"); } fn renderOperandKinds( writer: anytype, allocator: Allocator, kinds: []const g.OperandKind, extended_structs: ExtendedStructSet, ) !void { for (kinds) |kind| { switch (kind.category) { .ValueEnum => try renderValueEnum(writer, allocator, kind, extended_structs), .BitEnum => try renderBitEnum(writer, allocator, kind, extended_structs), else => {}, } } } fn renderValueEnum( writer: anytype, allocator: Allocator, enumeration: g.OperandKind, extended_structs: ExtendedStructSet, ) !void { const enumerants = enumeration.enumerants orelse return error.InvalidRegistry; var enum_map = std.AutoArrayHashMap(u32, usize).init(allocator); try enum_map.ensureTotalCapacity(enumerants.len); var aliases = std.ArrayList(struct { enumerant: usize, alias: usize }).init(allocator); try aliases.ensureTotalCapacity(enumerants.len); for (enumerants, 0..) |enumerant, i| { const result = enum_map.getOrPutAssumeCapacity(enumerant.value.int); if (!result.found_existing) { result.value_ptr.* = i; continue; } const existing = enumerants[result.value_ptr.*]; const tag_index = std.mem.indexOfDiff(u8, enumerant.enumerant, existing.enumerant).?; const enum_priority = tagPriorityScore(enumerant.enumerant[tag_index..]); const existing_priority = tagPriorityScore(existing.enumerant[tag_index..]); if (enum_priority < existing_priority) { aliases.appendAssumeCapacity(.{ .enumerant = result.value_ptr.*, .alias = i }); result.value_ptr.* = i; } else { aliases.appendAssumeCapacity(.{ .enumerant = i, .alias = result.value_ptr.* }); } } const enum_indices = enum_map.values(); try writer.print("pub const {s} = enum(u32) {{\n", .{std.zig.fmtId(enumeration.kind)}); for (enum_indices) |i| { const enumerant = enumerants[i]; if (enumerant.value != .int) return error.InvalidRegistry; try writer.print("{} = {},\n", .{ std.zig.fmtId(enumerant.enumerant), enumerant.value.int }); } try writer.writeByte('\n'); for (aliases.items) |alias| { try writer.print("pub const {} = {}.{};\n", .{ std.zig.fmtId(enumerants[alias.enumerant].enumerant), std.zig.fmtId(enumeration.kind), std.zig.fmtId(enumerants[alias.alias].enumerant), }); } if (!extended_structs.contains(enumeration.kind)) { try writer.writeAll("};\n"); return; } try writer.print("\npub const Extended = union({}) {{\n", .{std.zig.fmtId(enumeration.kind)}); for (enum_indices) |i| { const enumerant = enumerants[i]; try renderOperand(writer, .@"union", enumerant.enumerant, enumerant.parameters, extended_structs); } try writer.writeAll("};\n};\n"); } fn renderBitEnum( writer: anytype, allocator: Allocator, enumeration: g.OperandKind, extended_structs: ExtendedStructSet, ) !void { try writer.print("pub const {s} = packed struct {{\n", .{std.zig.fmtId(enumeration.kind)}); var flags_by_bitpos = [_]?usize{null} ** 32; const enumerants = enumeration.enumerants orelse return error.InvalidRegistry; var aliases = std.ArrayList(struct { flag: usize, alias: u5 }).init(allocator); try aliases.ensureTotalCapacity(enumerants.len); for (enumerants, 0..) |enumerant, i| { if (enumerant.value != .bitflag) return error.InvalidRegistry; const value = try parseHexInt(enumerant.value.bitflag); if (value == 0) { continue; // Skip 'none' items } std.debug.assert(@popCount(value) == 1); const bitpos = std.math.log2_int(u32, value); if (flags_by_bitpos[bitpos]) |*existing| { const tag_index = std.mem.indexOfDiff(u8, enumerant.enumerant, enumerants[existing.*].enumerant).?; const enum_priority = tagPriorityScore(enumerant.enumerant[tag_index..]); const existing_priority = tagPriorityScore(enumerants[existing.*].enumerant[tag_index..]); if (enum_priority < existing_priority) { aliases.appendAssumeCapacity(.{ .flag = existing.*, .alias = bitpos }); existing.* = i; } else { aliases.appendAssumeCapacity(.{ .flag = i, .alias = bitpos }); } } else { flags_by_bitpos[bitpos] = i; } } for (flags_by_bitpos, 0..) |maybe_flag_index, bitpos| { if (maybe_flag_index) |flag_index| { try writer.print("{}", .{std.zig.fmtId(enumerants[flag_index].enumerant)}); } else { try writer.print("_reserved_bit_{}", .{bitpos}); } try writer.writeAll(": bool = false,\n"); } try writer.writeByte('\n'); for (aliases.items) |alias| { try writer.print("pub const {}: {} = .{{.{} = true}};\n", .{ std.zig.fmtId(enumerants[alias.flag].enumerant), std.zig.fmtId(enumeration.kind), std.zig.fmtId(enumerants[flags_by_bitpos[alias.alias].?].enumerant), }); } if (!extended_structs.contains(enumeration.kind)) { try writer.writeAll("};\n"); return; } try writer.print("\npub const Extended = struct {{\n", .{}); for (flags_by_bitpos, 0..) |maybe_flag_index, bitpos| { const flag_index = maybe_flag_index orelse { try writer.print("_reserved_bit_{}: bool = false,\n", .{bitpos}); continue; }; const enumerant = enumerants[flag_index]; try renderOperand(writer, .mask, enumerant.enumerant, enumerant.parameters, extended_structs); } try writer.writeAll("};\n};\n"); } fn renderOperand( writer: anytype, kind: enum { @"union", instruction, mask, }, field_name: []const u8, parameters: []const g.Operand, extended_structs: ExtendedStructSet, ) !void { if (kind == .instruction) { try writer.writeByte('.'); } try writer.print("{}", .{std.zig.fmtId(field_name)}); if (parameters.len == 0) { switch (kind) { .@"union" => try writer.writeAll(",\n"), .instruction => try writer.writeAll(" => void,\n"), .mask => try writer.writeAll(": bool = false,\n"), } return; } if (kind == .instruction) { try writer.writeAll(" => "); } else { try writer.writeAll(": "); } if (kind == .mask) { try writer.writeByte('?'); } try writer.writeAll("struct{"); for (parameters, 0..) |param, j| { if (j != 0) { try writer.writeAll(", "); } try renderFieldName(writer, parameters, j); try writer.writeAll(": "); if (param.quantifier) |q| { switch (q) { .@"?" => try writer.writeByte('?'), .@"*" => try writer.writeAll("[]const "), } } try writer.print("{}", .{std.zig.fmtId(param.kind)}); if (extended_structs.contains(param.kind)) { try writer.writeAll(".Extended"); } if (param.quantifier) |q| { switch (q) { .@"?" => try writer.writeAll(" = null"), .@"*" => try writer.writeAll(" = &.{}"), } } } try writer.writeAll("}"); if (kind == .mask) { try writer.writeAll(" = null"); } try writer.writeAll(",\n"); } fn renderFieldName(writer: anytype, operands: []const g.Operand, field_index: usize) !void { const operand = operands[field_index]; // Should be enough for all names - adjust as needed. var name_backing_buffer: [64]u8 = undefined; var name_buffer = std.ArrayListUnmanaged(u8).initBuffer(&name_backing_buffer); derive_from_kind: { // Operand names are often in the json encoded as "'Name'" (with two sets of quotes). // Additionally, some operands have ~ in them at the end (D~ref~). const name = std.mem.trim(u8, operand.name, "'~"); if (name.len == 0) { break :derive_from_kind; } // Some names have weird characters in them (like newlines) - skip any such ones. // Use the same loop to transform to snake-case. for (name) |c| { switch (c) { 'a'...'z', '0'...'9' => name_buffer.appendAssumeCapacity(c), 'A'...'Z' => name_buffer.appendAssumeCapacity(std.ascii.toLower(c)), ' ', '~' => name_buffer.appendAssumeCapacity('_'), else => break :derive_from_kind, } } // Assume there are no duplicate 'name' fields. try writer.print("{}", .{std.zig.fmtId(name_buffer.items)}); return; } // Translate to snake case. name_buffer.items.len = 0; for (operand.kind, 0..) |c, i| { switch (c) { 'a'...'z', '0'...'9' => name_buffer.appendAssumeCapacity(c), 'A'...'Z' => if (i > 0 and std.ascii.isLower(operand.kind[i - 1])) { name_buffer.appendSliceAssumeCapacity(&[_]u8{ '_', std.ascii.toLower(c) }); } else { name_buffer.appendAssumeCapacity(std.ascii.toLower(c)); }, else => unreachable, // Assume that the name is valid C-syntax (and contains no underscores). } } try writer.print("{}", .{std.zig.fmtId(name_buffer.items)}); // For fields derived from type name, there could be any amount. // Simply check against all other fields, and if another similar one exists, add a number. const need_extra_index = for (operands, 0..) |other_operand, i| { if (i != field_index and std.mem.eql(u8, operand.kind, other_operand.kind)) { break true; } } else false; if (need_extra_index) { try writer.print("_{}", .{field_index}); } } fn parseHexInt(text: []const u8) !u31 { const prefix = "0x"; if (!std.mem.startsWith(u8, text, prefix)) return error.InvalidHexInt; return try std.fmt.parseInt(u31, text[prefix.len..], 16); } fn usageAndExit(file: std.fs.File, arg0: []const u8, code: u8) noreturn { file.writer().print( \\Usage: {s} \\ \\Generates Zig bindings for a SPIR-V specification .json (either core or \\extinst versions). The result, printed to stdout, should be used to update \\files in src/codegen/spirv. Don't forget to format the output. \\ \\The relevant specifications can be obtained from the SPIR-V registry: \\https://github.com/KhronosGroup/SPIRV-Headers/blob/master/include/spirv/unified1/ \\ , .{arg0}) catch std.process.exit(1); std.process.exit(code); }