| # Generating code |
| 22 Dec 2014 |
| Tags: programming, technical |
| Summary: How to use go generate. |
| |
| Rob Pike |
| |
| ## |
| |
| A property of universal computation—Turing completeness—is that a computer program can write a computer program. |
| This is a powerful idea that is not appreciated as often as it might be, even though it happens frequently. |
| It's a big part of the definition of a compiler, for instance. |
| It's also how the `go` `test` command works: it scans the packages to be tested, |
| writes out a Go program containing a test harness customized for the package, |
| and then compiles and runs it. |
| Modern computers are so fast this expensive-sounding sequence can complete in a fraction of a second. |
| |
| There are lots of other examples of programs that write programs. |
| [Yacc](https://godoc.org/golang.org/x/tools/cmd/goyacc), for instance, reads in a description of a grammar and writes out a program to parse that grammar. |
| The protocol buffer "compiler" reads an interface description and emits structure definitions, |
| methods, and other support code. |
| Configuration tools of all sorts work like this too, examining metadata or the environment |
| and emitting scaffolding customized to the local state. |
| |
| Programs that write programs are therefore important elements in software engineering, |
| but programs like Yacc that produce source code need to be integrated into the build |
| process so their output can be compiled. |
| When an external build tool like Make is being used, this is usually easy to do. |
| But in Go, whose go tool gets all necessary build information from the Go source, there is a problem. |
| There is simply no mechanism to run Yacc from the go tool alone. |
| |
| Until now, that is. |
| |
| The [latest Go release](https://blog.golang.org/go1.4), 1.4, |
| includes a new command that makes it easier to run such tools. |
| It's called `go` `generate`, and it works by scanning for special comments in Go source code |
| that identify general commands to run. |
| It's important to understand that `go` `generate` is not part of `go` `build`. |
| It contains no dependency analysis and must be run explicitly before running `go` `build`. |
| It is intended to be used by the author of the Go package, not its clients. |
| |
| The `go` `generate` command is easy to use. |
| As a warmup, here's how to use it to generate a Yacc grammar. |
| |
| First, install Go's Yacc tool: |
| |
| go get golang.org/x/tools/cmd/goyacc |
| |
| Say you have a Yacc input file called `gopher.y` that defines a grammar for your new language. |
| To produce the Go source file implementing the grammar, |
| you would normally invoke the command like this: |
| |
| goyacc -o gopher.go -p parser gopher.y |
| |
| The `-o` option names the output file while `-p` specifies the package name. |
| |
| To have `go` `generate` drive the process, in any one of the regular (non-generated) `.go` files |
| in the same directory, add this comment anywhere in the file: |
| |
| //go:generate goyacc -o gopher.go -p parser gopher.y |
| |
| This text is just the command above prefixed by a special comment recognized by `go` `generate`. |
| The comment must start at the beginning of the line and have no spaces between the `//` and the `go:generate`. |
| After that marker, the rest of the line specifies a command for `go` `generate` to run. |
| |
| Now run it. Change to the source directory and run `go` `generate`, then `go` `build` and so on: |
| |
| $ cd $GOPATH/myrepo/gopher |
| $ go generate |
| $ go build |
| $ go test |
| |
| That's it. |
| Assuming there are no errors, the `go` `generate` command will invoke `yacc` to create `gopher.go`, |
| at which point the directory holds the full set of Go source files, so we can build, test, and work normally. |
| Every time `gopher.y` is modified, just rerun `go` `generate` to regenerate the parser. |
| |
| For more details about how `go` `generate` works, including options, environment variables, |
| and so on, see the [design document](https://golang.org/s/go1.4-generate). |
| |
| Go generate does nothing that couldn't be done with Make or some other build mechanism, |
| but it comes with the `go` tool—no extra installation required—and fits nicely into the Go ecosystem. |
| Just keep in mind that it is for package authors, not clients, |
| if only for the reason that the program it invokes might not be available on the target machine. |
| Also, if the containing package is intended for import by `go` `get`, |
| once the file is generated (and tested!) it must be checked into the |
| source code repository to be available to clients. |
| |
| Now that we have it, let's use it for something new. |
| As a very different example of how `go` `generate` can help, there is a new program available in the |
| `golang.org/x/tools` repository called `stringer`. |
| It automatically writes string methods for sets of integer constants. |
| It's not part of the released distribution, but it's easy to install: |
| |
| $ go get golang.org/x/tools/cmd/stringer |
| |
| Here's an example from the documentation for |
| [`stringer`](https://godoc.org/golang.org/x/tools/cmd/stringer). |
| Imagine we have some code that contains a set of integer constants defining different types of pills: |
| |
| package painkiller |
| |
| type Pill int |
| |
| const ( |
| Placebo Pill = iota |
| Aspirin |
| Ibuprofen |
| Paracetamol |
| Acetaminophen = Paracetamol |
| ) |
| |
| For debugging, we'd like these constants to pretty-print themselves, which means we want a method with signature, |
| |
| func (p Pill) String() string |
| |
| It's easy to write one by hand, perhaps like this: |
| |
| func (p Pill) String() string { |
| switch p { |
| case Placebo: |
| return "Placebo" |
| case Aspirin: |
| return "Aspirin" |
| case Ibuprofen: |
| return "Ibuprofen" |
| case Paracetamol: // == Acetaminophen |
| return "Paracetamol" |
| } |
| return fmt.Sprintf("Pill(%d)", p) |
| } |
| |
| There are other ways to write this function, of course. |
| We could use a slice of strings indexed by Pill, or a map, or some other technique. |
| Whatever we do, we need to maintain it if we change the set of pills, and we need to make sure it's correct. |
| (The two names for paracetamol make this trickier than it might otherwise be.) |
| Plus the very question of which approach to take depends on the types and values: |
| signed or unsigned, dense or sparse, zero-based or not, and so on. |
| |
| The `stringer` program takes care of all these details. |
| Although it can be run in isolation, it is intended to be driven by `go` `generate`. |
| To use it, add a generate comment to the source, perhaps near the type definition: |
| |
| //go:generate stringer -type=Pill |
| |
| This rule specifies that `go` `generate` should run the `stringer` tool to generate a `String` method for type `Pill`. |
| The output is automatically written to `pill_string.go` (a default we could override with the |
| `-output` flag). |
| |
| Let's run it: |
| |
| $ go generate |
| $ cat pill_string.go |
| // Code generated by stringer -type Pill pill.go; DO NOT EDIT. |
| |
| package painkiller |
| |
| import "fmt" |
| |
| const _Pill_name = "PlaceboAspirinIbuprofenParacetamol" |
| |
| var _Pill_index = [...]uint8{0, 7, 14, 23, 34} |
| |
| func (i Pill) String() string { |
| if i < 0 || i+1 >= Pill(len(_Pill_index)) { |
| return fmt.Sprintf("Pill(%d)", i) |
| } |
| return _Pill_name[_Pill_index[i]:_Pill_index[i+1]] |
| } |
| $ |
| |
| Every time we change the definition of `Pill` or the constants, all we need to do is run |
| |
| $ go generate |
| |
| to update the `String` method. |
| And of course if we've got multiple types set up this way in the same package, |
| that single command will update all their `String` methods with a single command. |
| |
| There's no question the generated method is ugly. |
| That's OK, though, because humans don't need to work on it; machine-generated code is often ugly. |
| It's working hard to be efficient. |
| All the names are smashed together into a single string, |
| which saves memory (only one string header for all the names, even if there are zillions of them). |
| Then an array, `_Pill_index`, maps from value to name by a simple, efficient technique. |
| Note too that `_Pill_index` is an array (not a slice; one more header eliminated) of `uint8`, |
| the smallest integer sufficient to span the space of values. |
| If there were more values, or there were negatives ones, |
| the generated type of `_Pill_index` might change to `uint16` or `int8`: whatever works best. |
| |
| The approach used by the methods printed by `stringer` varies according to the properties of the constant set. |
| For instance, if the constants are sparse, it might use a map. |
| Here's a trivial example based on a constant set representing powers of two: |
| |
| const _Power_name = "p0p1p2p3p4p5..." |
| |
| var _Power_map = map[Power]string{ |
| 1: _Power_name[0:2], |
| 2: _Power_name[2:4], |
| 4: _Power_name[4:6], |
| 8: _Power_name[6:8], |
| 16: _Power_name[8:10], |
| 32: _Power_name[10:12], |
| ..., |
| } |
| |
| func (i Power) String() string { |
| if str, ok := _Power_map[i]; ok { |
| return str |
| } |
| return fmt.Sprintf("Power(%d)", i) |
| } |
| |
| In short, generating the method automatically allows us to do a better job than we would expect a human to do. |
| |
| There are lots of other uses of `go` `generate` already installed in the Go tree. |
| Examples include generating Unicode tables in the `unicode` package, |
| creating efficient methods for encoding and decoding arrays in `encoding/gob`, |
| producing time zone data in the `time` package, and so on. |
| |
| Please use `go` `generate` creatively. |
| It's there to encourage experimentation. |
| |
| And even if you don't, use the new `stringer` tool to write your `String` methods for your integer constants. |
| Let the machine do the work. |