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#lang qtest/markdown
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# Macros
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A _macro_ is a syntactic form with an associated _transformer_ that
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_expands_ the original form into existing forms. To put it another way,
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a macro is an extension to the Racket compiler. Most of the syntactic
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forms of `racket/base` and `racket` are actually macros that expand into
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a small set of core constructs.
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Like many languages, Racket provides pattern-based macros that make
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simple transformations easy to implement and reliable to use. Racket
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also supports arbitrary macro transformers that are implemented in
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Racket—or in a macro-extended variant of Racket.
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This chapter provides an introduction to Racket macros, but see [_Fear
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of Macros_](http://www.greghendershott.com/fear-of-macros/) for an
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introduction from a different perspective.
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1 Pattern-Based Macros
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1.1 `define-syntax-rule`
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1.2 Lexical Scope
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1.3 `define-syntax` and `syntax-rules`
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1.4 Matching Sequences
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1.5 Identifier Macros
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1.6 `set!` Transformers
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1.7 Macro-Generating Macros
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1.8 Extended Example: Call-by-Reference Functions
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2 General Macro Transformers
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2.1 Syntax Objects
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2.2 Macro Transformer Procedures
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2.3 Mixing Patterns and Expressions: `syntax-case`
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2.4 `with-syntax` and `generate-temporaries`
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2.5 Compile and Run-Time Phases
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2.6 General Phase Levels
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2.6.1 Phases and Bindings
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2.6.2 Phases and Modules
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2.7 Syntax Taints
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3 Module Instantiations and Visits
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3.1 Declaration versus Instantiation
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3.2 Compile-Time Instantiation
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3.3 Visiting Modules
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3.4 Lazy Visits via Available Modules
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## 1. Pattern-Based Macros
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A _pattern-based macro_ replaces any code that matches a pattern to an
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expansion that uses parts of the original syntax that match parts of the
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pattern.
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### 1.1. `define-syntax-rule`
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The simplest way to create a macro is to use `define-syntax-rule`:
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```racket
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(define-syntax-rule pattern template)
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```
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As a running example, consider the `swap` macro, which swaps the values
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stored in two variables. It can be implemented using
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`define-syntax-rule` as follows:
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> The macro is “un-Rackety” in the sense that it involves side effects on
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> variables—but the point of macros is to let you add syntactic forms that
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> some other language designer might not approve.
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```racket
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(define-syntax-rule (swap x y)
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(let ([tmp x])
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(set! x y)
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(set! y tmp)))
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```
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The `define-syntax-rule` form binds a macro that matches a single
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pattern. The pattern must always start with an open parenthesis followed
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by an identifier, which is `swap` in this case. After the initial
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identifier, other identifiers are _macro pattern variables_ that can
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match anything in a use of the macro. Thus, this macro matches the form
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`(swap form1 form2)` for any `form1` and `form2`.
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> Macro pattern variables are similar to pattern variables for `match`.
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> See \[missing\].
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After the pattern in `define-syntax-rule` is the _template_. The
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template is used in place of a form that matches the pattern, except
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that each instance of a pattern variable in the template is replaced
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with the part of the macro use the pattern variable matched. For
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example, in
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`(swap` `first` `last)`
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the pattern variable `x` matches `first` and `y` matches `last`, so that
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the expansion is
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```racket
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(let ([tmp first])
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(set! first last)
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(set! last tmp))
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```
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### 1.2. Lexical Scope
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Suppose that we use the `swap` macro to swap variables named `tmp` and
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`other`:
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```racket
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(let ([tmp 5]
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[other 6])
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(swap tmp other)
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(list tmp other))
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```
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The result of the above expression should be `(6 5)`. The naive
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expansion of this use of `swap`, however, is
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```racket
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(let ([tmp 5]
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[other 6])
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(let ([tmp tmp])
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(set! tmp other)
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(set! other tmp))
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(list tmp other))
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```
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whose result is `(5 6)`. The problem is that the naive expansion
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confuses the `tmp` in the context where `swap` is used with the `tmp`
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that is in the macro template.
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Racket doesn’t produce the naive expansion for the above use of `swap`.
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Instead, it produces
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```racket
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(let ([tmp 5]
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[other 6])
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(let ([tmp_1 tmp])
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(set! tmp other)
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(set! other tmp_1))
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(list tmp other))
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```
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with the correct result in `(6 5)`. Similarly, in the example
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```racket
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(let ([set! 5]
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[other 6])
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(swap set! other)
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(list set! other))
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```
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the expansion is
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```racket
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(let ([set!_1 5]
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[other 6])
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(let ([tmp_1 set!_1])
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(set! set!_1 other)
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(set! other tmp_1))
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(list set!_1 other))
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```
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so that the local `set!` binding doesn’t interfere with the assignments
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introduced by the macro template.
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In other words, Racket’s pattern-based macros automatically maintain
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lexical scope, so macro implementors can reason about variable reference
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in macros and macro uses in the same way as for functions and function
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calls.
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### 1.3. `define-syntax` and `syntax-rules`
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The `define-syntax-rule` form binds a macro that matches a single
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pattern, but Racket’s macro system supports transformers that match
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multiple patterns starting with the same identifier. To write such
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macros, the programmer must use the more general `define-syntax` form
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along with the `syntax-rules` transformer form:
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```racket
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(define-syntax id
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(syntax-rules (literal-id ...)
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[pattern template]
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...))
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```
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> The `define-syntax-rule` form is itself a macro that expands into
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> `define-syntax` with a `syntax-rules` form that contains only one
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> pattern and template.
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For example, suppose we would like a `rotate` macro that generalizes
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`swap` to work on either two or three identifiers, so that
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```racket
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(let ([red 1] [green 2] [blue 3])
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(rotate red green) ; swaps
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(rotate red green blue) ; rotates left
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(list red green blue))
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```
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produces `(1 3 2)`. We can implement `rotate` using `syntax-rules`:
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```racket
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(define-syntax rotate
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(syntax-rules ()
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[(rotate a b) (swap a b)]
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[(rotate a b c) (begin
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(swap a b)
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(swap b c))]))
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```
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The expression `(rotate red green)` matches the first pattern in the
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`syntax-rules` form, so it expands to `(swap red green)`. The expression
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`(rotate red green blue)` matches the second pattern, so it expands to
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`(begin (swap red green) (swap green blue))`.
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### 1.4. Matching Sequences
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A better `rotate` macro would allow any number of identifiers, instead
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of just two or three. To match a use of `rotate` with any number of
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identifiers, we need a pattern form that has something like a Kleene
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star. In a Racket macro pattern, a star is written as `...`.
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To implement `rotate` with `...`, we need a base case to handle a single
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identifier, and an inductive case to handle more than one identifier:
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```racket
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(define-syntax rotate
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(syntax-rules ()
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[(rotate a) (void)]
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[(rotate a b c ...) (begin
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(swap a b)
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(rotate b c ...))]))
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```
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When a pattern variable like `c` is followed by `...` in a pattern, then
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it must be followed by `...` in a template, too. The pattern variable
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effectively matches a sequence of zero or more forms, and it is replaced
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in the template by the same sequence.
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Both versions of `rotate` so far are a bit inefficient, since pairwise
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swapping keeps moving the value from the first variable into every
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variable in the sequence until it arrives at the last one. A more
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efficient `rotate` would move the first value directly to the last
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variable. We can use `...` patterns to implement the more efficient
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variant using a helper macro:
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```racket
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(define-syntax rotate
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(syntax-rules ()
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[(rotate a c ...)
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(shift-to (c ... a) (a c ...))]))
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(define-syntax shift-to
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(syntax-rules ()
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[(shift-to (from0 from ...) (to0 to ...))
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(let ([tmp from0])
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(set! to from) ...
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(set! to0 tmp))]))
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```
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In the `shift-to` macro, `...` in the template follows `(set! to from)`,
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which causes the `(set! to from)` expression to be duplicated as many
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times as necessary to use each identifier matched in the `to` and `from`
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sequences. \(The number of `to` and `from` matches must be the same,
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otherwise the macro expansion fails with an error.\)
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### 1.5. Identifier Macros
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Given our macro definitions, the `swap` or `rotate` identifiers must be
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used after an open parenthesis, otherwise a syntax error is reported:
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```racket
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> (+ swap 3)
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eval:2:0: swap: bad syntax
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in: swap
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```
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An _identifier macro_ is a pattern-matching macro that works when used
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by itself without parentheses. For example, we can define `val` as an
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identifier macro that expands to `(get-val)`, so `(+ val 3)` would
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expand to `(+ (get-val) 3)`.
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```racket
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> (define-syntax val
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(lambda (stx)
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(syntax-case stx ()
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[val (identifier? (syntax val)) (syntax (get-val))])))
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> (define-values (get-val put-val!)
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(let ([private-val 0])
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(values (lambda () private-val)
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(lambda (v) (set! private-val v)))))
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> val
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0
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> (+ val 3)
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3
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```
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The `val` macro uses `syntax-case`, which enables defining more powerful
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macros and will be explained in the Mixing Patterns and Expressions:
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`syntax-case` section. For now it is sufficient to know that to define a
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macro, `syntax-case` is used in a `lambda`, and its templates must be
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wrapped with an explicit `syntax` constructor. Finally, `syntax-case`
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clauses may specify additional guard conditions after the pattern.
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Our `val` macro uses an `identifier?` condition to ensure that `val`
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_must not_ be used with parentheses. Instead, the macro raises a syntax
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error:
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```racket
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> (val)
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eval:8:0: val: bad syntax
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in: (val)
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```
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### 1.6. `set!` Transformers
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With the above `val` macro, we still must call `put-val!` to change the
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stored value. It would be more convenient, however, to use `set!`
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directly on `val`. To invoke the macro when `val` is used with `set!`,
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we create an assignment transformer with `make-set!-transformer`. We
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must also declare `set!` as a literal in the `syntax-case` literal list.
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```racket
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> (define-syntax val2
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(make-set!-transformer
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(lambda (stx)
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(syntax-case stx (set!)
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[val2 (identifier? (syntax val2)) (syntax (get-val))]
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[(set! val2 e) (syntax (put-val! e))]))))
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> val2
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0
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> (+ val2 3)
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3
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> (set! val2 10)
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> val2
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10
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```
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### 1.7. Macro-Generating Macros
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Suppose that we have many identifiers like `val` and `val2` that we’d
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like to redirect to accessor and mutator functions like `get-val` and
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`put-val!`. We’d like to be able to just write:
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`(define-get/put-id` `val` `get-val` `put-val!)`
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Naturally, we can implement `define-get/put-id` as a macro:
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```racket
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> (define-syntax-rule (define-get/put-id id get put!)
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(define-syntax id
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(make-set!-transformer
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(lambda (stx)
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(syntax-case stx (set!)
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[id (identifier? (syntax id)) (syntax (get))]
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[(set! id e) (syntax (put! e))])))))
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> (define-get/put-id val3 get-val put-val!)
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> (set! val3 11)
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> val3
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11
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```
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The `define-get/put-id` macro is a _macro-generating macro_.
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### 1.8. Extended Example: Call-by-Reference Functions
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We can use pattern-matching macros to add a form to Racket for defining
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first-order _call-by-reference_ functions. When a call-by-reference
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function body mutates its formal argument, the mutation applies to
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variables that are supplied as actual arguments in a call to the
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function.
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For example, if `define-cbr` is like `define` except that it defines a
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call-by-reference function, then
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```racket
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(define-cbr (f a b)
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(swap a b))
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(let ([x 1] [y 2])
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(f x y)
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(list x y))
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```
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produces `(2 1)`.
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We will implement call-by-reference functions by having function calls
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supply accessor and mutators for the arguments, instead of supplying
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argument values directly. In particular, for the function `f` above,
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we’ll generate
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```racket
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(define (do-f get-a get-b put-a! put-b!)
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(define-get/put-id a get-a put-a!)
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(define-get/put-id b get-b put-b!)
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(swap a b))
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```
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and redirect a function call `(f x y)` to
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```racket
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(do-f (lambda () x)
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(lambda () y)
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(lambda (v) (set! x v))
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(lambda (v) (set! y v)))
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```
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Clearly, then `define-cbr` is a macro-generating macro, which binds `f`
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to a macro that expands to a call of `do-f`. That is, `(define-cbr (f a
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b) (swap a b))` needs to generate the definition
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```racket
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(define-syntax f
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(syntax-rules ()
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[(id actual ...)
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(do-f (lambda () actual)
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...
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(lambda (v)
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(set! actual v))
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...)]))
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```
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At the same time, `define-cbr` needs to define `do-f` using the body of
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`f`, this second part is slightly more complex, so we defer most of it
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to a `define-for-cbr` helper module, which lets us write `define-cbr`
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easily enough:
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```racket
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(define-syntax-rule (define-cbr (id arg ...) body)
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(begin
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(define-syntax id
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(syntax-rules ()
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[(id actual (... ...))
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(do-f (lambda () actual)
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(... ...)
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(lambda (v)
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(set! actual v))
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(... ...))]))
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(define-for-cbr do-f (arg ...)
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() ; explained below...
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body)))
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```
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Our remaining task is to define `define-for-cbr` so that it converts
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`(define-for-cbr` `do-f` `(a` `b)` `()` `(swap` `a` `b))`
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|
|
|
to the function definition `do-f` above. Most of the work is generating
|
|
|
a `define-get/put-id` declaration for each argument, `a` and `b`, and
|
|
|
putting them before the body. Normally, that’s an easy task for `...` in
|
|
|
a pattern and template, but this time there’s a catch: we need to
|
|
|
generate the names `get-a` and `put-a!` as well as `get-b` and `put-b!`,
|
|
|
and the pattern language provides no way to synthesize identifiers based
|
|
|
on existing identifiers.
|
|
|
|
|
|
As it turns out, lexical scope gives us a way around this problem. The
|
|
|
trick is to iterate expansions of `define-for-cbr` once for each
|
|
|
argument in the function, and that’s why `define-for-cbr` starts with an
|
|
|
apparently useless `()` after the argument list. We need to keep track
|
|
|
of all the arguments seen so far and the `get` and `put` names generated
|
|
|
for each, in addition to the arguments left to process. After we’ve
|
|
|
processed all the identifiers, then we have all the names we need.
|
|
|
|
|
|
Here is the definition of `define-for-cbr`:
|
|
|
|
|
|
```racket
|
|
|
(define-syntax define-for-cbr
|
|
|
(syntax-rules ()
|
|
|
[(define-for-cbr do-f (id0 id ...)
|
|
|
(gens ...) body)
|
|
|
(define-for-cbr do-f (id ...)
|
|
|
(gens ... (id0 get put)) body)]
|
|
|
[(define-for-cbr do-f ()
|
|
|
((id get put) ...) body)
|
|
|
(define (do-f get ... put ...)
|
|
|
(define-get/put-id id get put) ...
|
|
|
body)]))
|
|
|
```
|
|
|
|
|
|
Step-by-step, expansion proceeds as follows:
|
|
|
|
|
|
```racket
|
|
|
(define-for-cbr do-f (a b)
|
|
|
() (swap a b))
|
|
|
=> (define-for-cbr do-f (b)
|
|
|
([a get_1 put_1]) (swap a b))
|
|
|
=> (define-for-cbr do-f ()
|
|
|
([a get_1 put_1] [b get_2 put_2]) (swap a b))
|
|
|
=> (define (do-f get_1 get_2 put_1 put_2)
|
|
|
(define-get/put-id a get_1 put_1)
|
|
|
(define-get/put-id b get_2 put_2)
|
|
|
(swap a b))
|
|
|
```
|
|
|
|
|
|
The “subscripts” on `get_1`, `get_2`, `put_1`, and `put_2` are inserted
|
|
|
by the macro expander to preserve lexical scope, since the `get`
|
|
|
generated by each iteration of `define-for-cbr` should not bind the
|
|
|
`get` generated by a different iteration. In other words, we are
|
|
|
essentially tricking the macro expander into generating fresh names for
|
|
|
us, but the technique illustrates some of the surprising power of
|
|
|
pattern-based macros with automatic lexical scope.
|
|
|
|
|
|
The last expression eventually expands to just
|
|
|
|
|
|
```racket
|
|
|
(define (do-f get_1 get_2 put_1 put_2)
|
|
|
(let ([tmp (get_1)])
|
|
|
(put_1 (get_2))
|
|
|
(put_2 tmp)))
|
|
|
```
|
|
|
|
|
|
which implements the call-by-name function `f`.
|
|
|
|
|
|
To summarize, then, we can add call-by-reference functions to Racket
|
|
|
with just three small pattern-based macros: `define-cbr`,
|
|
|
`define-for-cbr`, and `define-get/put-id`.
|
|
|
|
|
|
## 2. General Macro Transformers
|
|
|
|
|
|
The `define-syntax` form creates a _transformer binding_ for an
|
|
|
identifier, which is a binding that can be used at compile time while
|
|
|
expanding expressions to be evaluated at run time. The compile-time
|
|
|
value associated with a transformer binding can be anything; if it is a
|
|
|
procedure of one argument, then the binding is used as a macro, and the
|
|
|
procedure is the _macro transformer_.
|
|
|
|
|
|
2.1 Syntax Objects
|
|
|
2.2 Macro Transformer Procedures
|
|
|
2.3 Mixing Patterns and Expressions: `syntax-case`
|
|
|
2.4 `with-syntax` and `generate-temporaries`
|
|
|
2.5 Compile and Run-Time Phases
|
|
|
2.6 General Phase Levels
|
|
|
2.6.1 Phases and Bindings
|
|
|
2.6.2 Phases and Modules
|
|
|
2.7 Syntax Taints
|
|
|
|
|
|
### 2.1. Syntax Objects
|
|
|
|
|
|
The input and output of a macro transformer \(i.e., source and
|
|
|
replacement forms\) are represented as _syntax objects_. A syntax object
|
|
|
contains symbols, lists, and constant values \(such as numbers\) that
|
|
|
essentially correspond to the `quote`d form of the expression. For
|
|
|
example, a representation of the expression `(+ 1 2)` contains the
|
|
|
symbol `'+` and the numbers `1` and `2`, all in a list. In addition to
|
|
|
this quoted content, a syntax object associates source-location and
|
|
|
lexical-binding information with each part of the form. The
|
|
|
source-location information is used when reporting syntax errors \(for
|
|
|
example\), and the lexical-binding information allows the macro system
|
|
|
to maintain lexical scope. To accommodate this extra information, the
|
|
|
represention of the expression `(+ 1 2)` is not merely `'(+ 1 2)`, but a
|
|
|
packaging of `'(+ 1 2)` into a syntax object.
|
|
|
|
|
|
To create a literal syntax object, use the `syntax` form:
|
|
|
|
|
|
```racket
|
|
|
> (syntax (+ 1 2))
|
|
|
#<syntax:eval:1:0 (+ 1 2)>
|
|
|
```
|
|
|
|
|
|
In the same way that `'` abbreviates `quote`, `#'` abbreviates `syntax`:
|
|
|
|
|
|
```racket
|
|
|
> #'(+ 1 2)
|
|
|
#<syntax:eval:1:0 (+ 1 2)>
|
|
|
```
|
|
|
|
|
|
A syntax object that contains just a symbol is an _identifier syntax
|
|
|
object_. Racket provides some additional operations specific to
|
|
|
identifier syntax objects, including the `identifier?` operation to
|
|
|
detect identifiers. Most notably, `free-identifier=?` determines
|
|
|
whether two identifiers refer to the same binding:
|
|
|
|
|
|
```racket
|
|
|
> (identifier? #'car)
|
|
|
#t
|
|
|
> (identifier? #'(+ 1 2))
|
|
|
#f
|
|
|
> (free-identifier=? #'car #'cdr)
|
|
|
#f
|
|
|
> (free-identifier=? #'car #'car)
|
|
|
#t
|
|
|
> (require (only-in racket/base [car also-car]))
|
|
|
> (free-identifier=? #'car #'also-car)
|
|
|
#t
|
|
|
```
|
|
|
|
|
|
To see the lists, symbols, numbers, etc. within a syntax object, use
|
|
|
`syntax->datum`:
|
|
|
|
|
|
```racket
|
|
|
> (syntax->datum #'(+ 1 2))
|
|
|
'(+ 1 2)
|
|
|
```
|
|
|
|
|
|
The `syntax-e` function is similar to `syntax->datum`, but it unwraps a
|
|
|
single layer of source-location and lexical-context information, leaving
|
|
|
sub-forms that have their own information wrapped as syntax objects:
|
|
|
|
|
|
```racket
|
|
|
> (syntax-e #'(+ 1 2))
|
|
|
'(#<syntax:eval:1:0 +> #<syntax:eval:1:0 1> #<syntax:eval:1:0 2>)
|
|
|
```
|
|
|
|
|
|
The `syntax-e` function always leaves syntax-object wrappers around
|
|
|
sub-forms that are represented via symbols, numbers, and other literal
|
|
|
values. The only time it unwraps extra sub-forms is when unwrapping a
|
|
|
pair, in which case the `cdr` of the pair may be recursively unwrapped,
|
|
|
depending on how the syntax object was constructed.
|
|
|
|
|
|
The opposite of `syntax->datum` is, of course, `datum->syntax`. In
|
|
|
addition to a datum like `'(+ 1 2)`, `datum->syntax` needs an existing
|
|
|
syntax object to donate its lexical context, and optionally another
|
|
|
syntax object to donate its source location:
|
|
|
|
|
|
```racket
|
|
|
> (datum->syntax #'lex
|
|
|
'(+ 1 2)
|
|
|
#'srcloc)
|
|
|
#<syntax:eval:1:0 (+ 1 2)>
|
|
|
```
|
|
|
|
|
|
In the above example, the lexical context of `#'lex` is used for the new
|
|
|
syntax object, while the source location of `#'srcloc` is used.
|
|
|
|
|
|
When the second \(i.e., the “datum”\) argument to `datum->syntax`
|
|
|
includes syntax objects, those syntax objects are preserved intact in
|
|
|
the result. That is, deconstructing the result with `syntax-e`
|
|
|
eventually produces the syntax objects that were given to
|
|
|
`datum->syntax`.
|
|
|
|
|
|
### 2.2. Macro Transformer Procedures
|
|
|
|
|
|
Any procedure of one argument can be a macro transformer. As it turns
|
|
|
out, the `syntax-rules` form is a macro that expands to a procedure
|
|
|
form. For example, if you evaluate a `syntax-rules` form directly
|
|
|
\(instead of placing on the right-hand of a `define-syntax` form\), the
|
|
|
result is a procedure:
|
|
|
|
|
|
```racket
|
|
|
> (syntax-rules () [(nothing) something])
|
|
|
#<procedure>
|
|
|
```
|
|
|
|
|
|
Instead of using `syntax-rules`, you can write your own macro
|
|
|
transformer procedure directly using `lambda`. The argument to the
|
|
|
procedure is a syntax object that represents the source form, and the
|
|
|
result of the procedure must be a syntax object that represents the
|
|
|
replacement form:
|
|
|
|
|
|
```racket
|
|
|
> (define-syntax self-as-string
|
|
|
(lambda (stx)
|
|
|
(datum->syntax stx
|
|
|
(format "~s" (syntax->datum stx)))))
|
|
|
> (self-as-string (+ 1 2))
|
|
|
"(self-as-string (+ 1 2))"
|
|
|
```
|
|
|
|
|
|
The source form passed to a macro transformer represents an expression
|
|
|
in which its identifier is used in an application position \(i.e., after
|
|
|
a parenthesis that starts an expression\), or it represents the
|
|
|
identifier by itself if it is used as an expression position and not in
|
|
|
an application position.The procedure produced by `syntax-rules` raises
|
|
|
a syntax error if its argument corresponds to a use of the identifier by
|
|
|
itself, which is why `syntax-rules` does not implement an identifier
|
|
|
macro.
|
|
|
|
|
|
```racket
|
|
|
> (self-as-string (+ 1 2))
|
|
|
"(self-as-string (+ 1 2))"
|
|
|
> self-as-string
|
|
|
"self-as-string"
|
|
|
```
|
|
|
|
|
|
The `define-syntax` form supports the same shortcut syntax for functions
|
|
|
as `define`, so that the following `self-as-string` definition is
|
|
|
equivalent to the one that uses `lambda` explicitly:
|
|
|
|
|
|
```racket
|
|
|
> (define-syntax (self-as-string stx)
|
|
|
(datum->syntax stx
|
|
|
(format "~s" (syntax->datum stx))))
|
|
|
> (self-as-string (+ 1 2))
|
|
|
"(self-as-string (+ 1 2))"
|
|
|
```
|
|
|
|
|
|
### 2.3. Mixing Patterns and Expressions: `syntax-case`
|
|
|
|
|
|
The procedure generated by `syntax-rules` internally uses `syntax-e` to
|
|
|
deconstruct the given syntax object, and it uses `datum->syntax` to
|
|
|
construct the result. The `syntax-rules` form doesn’t provide a way to
|
|
|
escape from pattern-matching and template-construction mode into an
|
|
|
arbitrary Racket expression.
|
|
|
|
|
|
The `syntax-case` form lets you mix pattern matching, template
|
|
|
construction, and arbitrary expressions:
|
|
|
|
|
|
```racket
|
|
|
(syntax-case stx-expr (literal-id ...)
|
|
|
[pattern expr]
|
|
|
...)
|
|
|
```
|
|
|
|
|
|
Unlike `syntax-rules`, the `syntax-case` form does not produce a
|
|
|
procedure. Instead, it starts with a `stx-expr` expression that
|
|
|
determines the syntax object to match against the `pattern`s. Also, each
|
|
|
`syntax-case` clause has a `pattern` and `expr`, instead of a `pattern`
|
|
|
and `template`. Within an `expr`, the `syntax` form—usually abbreviated
|
|
|
with `#'`—shifts into template-construction mode; if the `expr` of a
|
|
|
clause starts with `#'`, then we have something like a `syntax-rules`
|
|
|
form:
|
|
|
|
|
|
```racket
|
|
|
> (syntax->datum
|
|
|
(syntax-case #'(+ 1 2) ()
|
|
|
[(op n1 n2) #'(- n1 n2)]))
|
|
|
'(- 1 2)
|
|
|
```
|
|
|
|
|
|
We could write the `swap` macro using `syntax-case` instead of
|
|
|
`define-syntax-rule` or `syntax-rules`:
|
|
|
|
|
|
```racket
|
|
|
(define-syntax (swap stx)
|
|
|
(syntax-case stx ()
|
|
|
[(swap x y) #'(let ([tmp x])
|
|
|
(set! x y)
|
|
|
(set! y tmp))]))
|
|
|
```
|
|
|
|
|
|
One advantage of using `syntax-case` is that we can provide better error
|
|
|
reporting for `swap`. For example, with the `define-syntax-rule`
|
|
|
definition of `swap`, then `(swap x 2)` produces a syntax error in terms
|
|
|
of `set!`, because `2` is not an identifier. We can refine our
|
|
|
`syntax-case` implementation of `swap` to explicitly check the
|
|
|
sub-forms:
|
|
|
|
|
|
```racket
|
|
|
(define-syntax (swap stx)
|
|
|
(syntax-case stx ()
|
|
|
[(swap x y)
|
|
|
(if (and (identifier? #'x)
|
|
|
(identifier? #'y))
|
|
|
#'(let ([tmp x])
|
|
|
(set! x y)
|
|
|
(set! y tmp))
|
|
|
(raise-syntax-error #f
|
|
|
"not an identifier"
|
|
|
stx
|
|
|
(if (identifier? #'x)
|
|
|
#'y
|
|
|
#'x)))]))
|
|
|
```
|
|
|
|
|
|
With this definition, `(swap x 2)` provides a syntax error originating
|
|
|
from `swap` instead of `set!`.
|
|
|
|
|
|
In the above definition of `swap`, `#'x` and `#'y` are templates, even
|
|
|
though they are not used as the result of the macro transformer. This
|
|
|
example illustrates how templates can be used to access pieces of the
|
|
|
input syntax, in this case for checking the form of the pieces. Also,
|
|
|
the match for `#'x` or `#'y` is used in the call to
|
|
|
`raise-syntax-error`, so that the syntax-error message can point
|
|
|
directly to the source location of the non-identifier.
|
|
|
|
|
|
### 2.4. `with-syntax` and `generate-temporaries`
|
|
|
|
|
|
Since `syntax-case` lets us compute with arbitrary Racket expressions,
|
|
|
we can more simply solve a problem that we had in writing
|
|
|
`define-for-cbr` \(see Extended Example: Call-by-Reference Functions\),
|
|
|
where we needed to generate a set of names based on a sequence `id ...`:
|
|
|
|
|
|
```racket
|
|
|
(define-syntax (define-for-cbr stx)
|
|
|
(syntax-case stx ()
|
|
|
[(_ do-f (id ...) body)
|
|
|
....
|
|
|
#'(define (do-f get ... put ...)
|
|
|
(define-get/put-id id get put) ...
|
|
|
body) ....]))
|
|
|
```
|
|
|
|
|
|
In place of the `....`s above, we need to bind `get ...` and `put ...`
|
|
|
to lists of generated identifiers. We cannot use `let` to bind `get` and
|
|
|
`put`, because we need bindings that count as pattern variables, instead
|
|
|
of normal local variables. The `with-syntax` form lets us bind pattern
|
|
|
variables:
|
|
|
|
|
|
```racket
|
|
|
(define-syntax (define-for-cbr stx)
|
|
|
(syntax-case stx ()
|
|
|
[(_ do-f (id ...) body)
|
|
|
(with-syntax ([(get ...) ....]
|
|
|
[(put ...) ....])
|
|
|
#'(define (do-f get ... put ...)
|
|
|
(define-get/put-id id get put) ...
|
|
|
body))]))
|
|
|
```
|
|
|
|
|
|
Now we need an expression in place of `....` that generates as many
|
|
|
identifiers as there are `id` matches in the original pattern. Since
|
|
|
this is a common task, Racket provides a helper function,
|
|
|
`generate-temporaries`, that takes a sequence of identifiers and returns
|
|
|
a sequence of generated identifiers:
|
|
|
|
|
|
```racket
|
|
|
(define-syntax (define-for-cbr stx)
|
|
|
(syntax-case stx ()
|
|
|
[(_ do-f (id ...) body)
|
|
|
(with-syntax ([(get ...) (generate-temporaries #'(id ...))]
|
|
|
[(put ...) (generate-temporaries #'(id ...))])
|
|
|
#'(define (do-f get ... put ...)
|
|
|
(define-get/put-id id get put) ...
|
|
|
body))]))
|
|
|
```
|
|
|
|
|
|
This way of generating identifiers is normally easier to think about
|
|
|
than tricking the macro expander into generating names with purely
|
|
|
pattern-based macros.
|
|
|
|
|
|
In general, the left-hand side of a `with-syntax` binding is a pattern,
|
|
|
just like in `syntax-case`. In fact, a `with-syntax` form is just a
|
|
|
`syntax-case` form turned partially inside-out.
|
|
|
|
|
|
### 2.5. Compile and Run-Time Phases
|
|
|
|
|
|
As sets of macros get more complicated, you might want to write your own
|
|
|
helper functions, like `generate-temporaries`. For example, to provide
|
|
|
good syntax error messsages, `swap`, `rotate`, and `define-cbr` all
|
|
|
should check that certain sub-forms in the source form are identifiers.
|
|
|
We could use a `check-ids` function to perform this checking everywhere:
|
|
|
|
|
|
```racket
|
|
|
(define-syntax (swap stx)
|
|
|
(syntax-case stx ()
|
|
|
[(swap x y) (begin
|
|
|
(check-ids stx #'(x y))
|
|
|
#'(let ([tmp x])
|
|
|
(set! x y)
|
|
|
(set! y tmp)))]))
|
|
|
|
|
|
(define-syntax (rotate stx)
|
|
|
(syntax-case stx ()
|
|
|
[(rotate a c ...)
|
|
|
(begin
|
|
|
(check-ids stx #'(a c ...))
|
|
|
#'(shift-to (c ... a) (a c ...)))]))
|
|
|
```
|
|
|
|
|
|
The `check-ids` function can use the `syntax->list` function to convert
|
|
|
a syntax-object wrapping a list into a list of syntax objects:
|
|
|
|
|
|
```racket
|
|
|
(define (check-ids stx forms)
|
|
|
(for-each
|
|
|
(lambda (form)
|
|
|
(unless (identifier? form)
|
|
|
(raise-syntax-error #f
|
|
|
"not an identifier"
|
|
|
stx
|
|
|
form)))
|
|
|
(syntax->list forms)))
|
|
|
```
|
|
|
|
|
|
If you define `swap` and `check-ids` in this way, however, it doesn’t
|
|
|
work:
|
|
|
|
|
|
```racket
|
|
|
> (let ([a 1] [b 2]) (swap a b))
|
|
|
check-ids: undefined;
|
|
|
cannot reference an identifier before its definition
|
|
|
in module: top-level
|
|
|
```
|
|
|
|
|
|
The problem is that `check-ids` is defined as a run-time expression, but
|
|
|
`swap` is trying to use it at compile time. In interactive mode, compile
|
|
|
time and run time are interleaved, but they are not interleaved within
|
|
|
the body of a module, and they are not interleaved across modules that
|
|
|
are compiled ahead-of-time. To help make all of these modes treat code
|
|
|
consistently, Racket separates the binding spaces for different phases.
|
|
|
|
|
|
To define a `check-ids` function that can be referenced at compile time,
|
|
|
use `begin-for-syntax`:
|
|
|
|
|
|
```racket
|
|
|
(begin-for-syntax
|
|
|
(define (check-ids stx forms)
|
|
|
(for-each
|
|
|
(lambda (form)
|
|
|
(unless (identifier? form)
|
|
|
(raise-syntax-error #f
|
|
|
"not an identifier"
|
|
|
stx
|
|
|
form)))
|
|
|
(syntax->list forms))))
|
|
|
```
|
|
|
|
|
|
With this for-syntax definition, then `swap` works:
|
|
|
|
|
|
```racket
|
|
|
> (let ([a 1] [b 2]) (swap a b) (list a b))
|
|
|
'(2 1)
|
|
|
> (swap a 1)
|
|
|
eval:13:0: swap: not an identifier
|
|
|
at: 1
|
|
|
in: (swap a 1)
|
|
|
```
|
|
|
|
|
|
When organizing a program into modules, you may want to put helper
|
|
|
functions in one module to be used by macros that reside on other
|
|
|
modules. In that case, you can write the helper function using `define`:
|
|
|
|
|
|
`"utils.rkt"`
|
|
|
```racket
|
|
|
#lang racket
|
|
|
|
|
|
(provide check-ids)
|
|
|
|
|
|
(define (check-ids stx forms)
|
|
|
(for-each
|
|
|
(lambda (form)
|
|
|
(unless (identifier? form)
|
|
|
(raise-syntax-error #f
|
|
|
"not an identifier"
|
|
|
stx
|
|
|
form)))
|
|
|
(syntax->list forms)))
|
|
|
```
|
|
|
|
|
|
Then, in the module that implements macros, import the helper function
|
|
|
using `(require (for-syntax "utils.rkt"))` instead of `(require
|
|
|
"utils.rkt")`:
|
|
|
|
|
|
```racket
|
|
|
#lang racket
|
|
|
|
|
|
(require (for-syntax "utils.rkt"))
|
|
|
|
|
|
(define-syntax (swap stx)
|
|
|
(syntax-case stx ()
|
|
|
[(swap x y) (begin
|
|
|
(check-ids stx #'(x y))
|
|
|
#'(let ([tmp x])
|
|
|
(set! x y)
|
|
|
(set! y tmp)))]))
|
|
|
```
|
|
|
|
|
|
Since modules are separately compiled and cannot have circular
|
|
|
dependencies, the `"utils.rkt"` module’s run-time body can be compiled
|
|
|
before the compiling the module that implements `swap`. Thus, the
|
|
|
run-time definitions in `"utils.rkt"` can be used to implement `swap`,
|
|
|
as long as they are explicitly shifted into compile time by `(require
|
|
|
(for-syntax ....))`.
|
|
|
|
|
|
The `racket` module provides `syntax-case`, `generate-temporaries`,
|
|
|
`lambda`, `if`, and more for use in both the run-time and compile-time
|
|
|
phases. That is why we can use `syntax-case` in the `racket` REPL both
|
|
|
directly and in the right-hand side of a `define-syntax` form.
|
|
|
|
|
|
The `racket/base` module, in contrast, exports those bindings only in
|
|
|
the run-time phase. If you change the module above that defines `swap`
|
|
|
so that it uses the `racket/base` language instead of `racket`, then it
|
|
|
no longer works. Adding `(require (for-syntax racket/base))` imports
|
|
|
`syntax-case` and more into the compile-time phase, so that the module
|
|
|
works again.
|
|
|
|
|
|
Suppose that `define-syntax` is used to define a local macro in the
|
|
|
right-hand side of a `define-syntax` form. In that case, the right-hand
|
|
|
side of the inner `define-syntax` is in the _meta-compile phase level_,
|
|
|
also known as _phase level 2_. To import `syntax-case` into that phase
|
|
|
level, you would have to use `(require (for-syntax (for-syntax
|
|
|
racket/base)))` or, equivalently, `(require (for-meta 2 racket/base))`.
|
|
|
For example,
|
|
|
|
|
|
```racket
|
|
|
#lang racket/base
|
|
|
(require ;; This provides the bindings for the definition
|
|
|
;; of shell-game.
|
|
|
(for-syntax racket/base)
|
|
|
|
|
|
;; And this for the definition of
|
|
|
;; swap.
|
|
|
(for-syntax (for-syntax racket/base)))
|
|
|
|
|
|
(define-syntax (shell-game stx)
|
|
|
|
|
|
(define-syntax (swap stx)
|
|
|
(syntax-case stx ()
|
|
|
[(_ a b)
|
|
|
#'(let ([tmp a])
|
|
|
(set! a b)
|
|
|
(set! b tmp))]))
|
|
|
|
|
|
(syntax-case stx ()
|
|
|
[(_ a b c)
|
|
|
(let ([a #'a] [b #'b] [c #'c])
|
|
|
(when (= 0 (random 2)) (swap a b))
|
|
|
(when (= 0 (random 2)) (swap b c))
|
|
|
(when (= 0 (random 2)) (swap a c))
|
|
|
#`(list #,a #,b #,c))]))
|
|
|
|
|
|
(shell-game 3 4 5)
|
|
|
(shell-game 3 4 5)
|
|
|
(shell-game 3 4 5)
|
|
|
```
|
|
|
|
|
|
Negative phase levels also exist. If a macro uses a helper function that
|
|
|
is imported `for-syntax`, and if the helper function returns
|
|
|
syntax-object constants generated by `syntax`, then identifiers in the
|
|
|
syntax will need bindings at _phase level -1_, also known as the
|
|
|
_template phase level_, to have any binding at the run-time phase level
|
|
|
relative to the module that defines the macro.
|
|
|
|
|
|
For instance, the `swap-stx` helper function in the example below is not
|
|
|
a syntax transformer—it’s just an ordinary function—but it produces
|
|
|
syntax objects that get spliced into the result of `shell-game`.
|
|
|
Therefore, its containing `helper` submodule needs to be imported at
|
|
|
`shell-game`’s phase 1 with `(require (for-syntax 'helper))`.
|
|
|
|
|
|
But from the perspective of `swap-stx`, its results will ultimately be
|
|
|
evaluated at phase level -1, when the syntax returned by `shell-game` is
|
|
|
evaluated. In other words, a negative phase level is a positive phase
|
|
|
level from the opposite direction: `shell-game`’s phase 1 is
|
|
|
`swap-stx`’s phase 0, so `shell-game`’s phase 0 is `swap-stx`’s phase
|
|
|
-1. And that’s why this example won’t work—the `'helper` submodule has
|
|
|
no bindings at phase -1.
|
|
|
|
|
|
```racket
|
|
|
#lang racket/base
|
|
|
(require (for-syntax racket/base))
|
|
|
|
|
|
(module helper racket/base
|
|
|
(provide swap-stx)
|
|
|
(define (swap-stx a-stx b-stx)
|
|
|
#`(let ([tmp #,a-stx])
|
|
|
(set! #,a-stx #,b-stx)
|
|
|
(set! #,b-stx tmp))))
|
|
|
|
|
|
(require (for-syntax 'helper))
|
|
|
|
|
|
(define-syntax (shell-game stx)
|
|
|
(syntax-case stx ()
|
|
|
[(_ a b c)
|
|
|
#`(begin
|
|
|
#,(swap-stx #'a #'b)
|
|
|
#,(swap-stx #'b #'c)
|
|
|
#,(swap-stx #'a #'c)
|
|
|
(list a b c))]))
|
|
|
|
|
|
(define x 3)
|
|
|
(define y 4)
|
|
|
(define z 5)
|
|
|
(shell-game x y z)
|
|
|
```
|
|
|
|
|
|
To repair this example, we add `(require (for-template racket/base))` to
|
|
|
the `'helper` submodule.
|
|
|
|
|
|
```racket
|
|
|
#lang racket/base
|
|
|
(require (for-syntax racket/base))
|
|
|
|
|
|
(module helper racket/base
|
|
|
(require (for-template racket/base)) ; binds `let` and `set!` at phase -1
|
|
|
(provide swap-stx)
|
|
|
(define (swap-stx a-stx b-stx)
|
|
|
#`(let ([tmp #,a-stx])
|
|
|
(set! #,a-stx #,b-stx)
|
|
|
(set! #,b-stx tmp))))
|
|
|
|
|
|
(require (for-syntax 'helper))
|
|
|
|
|
|
(define-syntax (shell-game stx)
|
|
|
(syntax-case stx ()
|
|
|
[(_ a b c)
|
|
|
#`(begin
|
|
|
#,(swap-stx #'a #'b)
|
|
|
#,(swap-stx #'b #'c)
|
|
|
#,(swap-stx #'a #'c)
|
|
|
(list a b c))]))
|
|
|
|
|
|
(define x 3)
|
|
|
(define y 4)
|
|
|
(define z 5)
|
|
|
(shell-game x y z)
|
|
|
(shell-game x y z)
|
|
|
(shell-game x y z)
|
|
|
```
|
|
|
|
|
|
### 2.6. General Phase Levels
|
|
|
|
|
|
A _phase_ can be thought of as a way to separate computations in a
|
|
|
pipeline of processes where one produces code that is used by the next.
|
|
|
\(E.g., a pipeline that consists of a preprocessor process, a compiler,
|
|
|
and an assembler.\)
|
|
|
|
|
|
Imagine starting two Racket processes for this purpose. If you ignore
|
|
|
inter-process communication channels like sockets and files, the
|
|
|
processes will have no way to share anything other than the text that is
|
|
|
piped from the standard output of one process into the standard input of
|
|
|
the other. Similarly, Racket effectively allows multiple invocations of
|
|
|
a module to exist in the same process but separated by phase. Racket
|
|
|
enforces _separation_ of such phases, where different phases cannot
|
|
|
communicate in any way other than via the protocol of macro expansion,
|
|
|
where the output of one phases is the code used in the next.
|
|
|
|
|
|
#### 2.6.1. Phases and Bindings
|
|
|
|
|
|
Every binding of an identifier exists in a particular phase. The link
|
|
|
between a binding and its phase is represented by an integer _phase
|
|
|
level_. Phase level 0 is the phase used for “plain” \(or “runtime”\)
|
|
|
definitions, so
|
|
|
|
|
|
`(define` `age` `5)`
|
|
|
|
|
|
adds a binding for `age` into phase level 0. The identifier `age` can
|
|
|
be defined at a higher phase level using `begin-for-syntax`:
|
|
|
|
|
|
```racket
|
|
|
(begin-for-syntax
|
|
|
(define age 5))
|
|
|
```
|
|
|
|
|
|
With a single `begin-for-syntax` wrapper, `age` is defined at phase
|
|
|
level 1. We can easily mix these two definitions in the same module or
|
|
|
in a top-level namespace, and there is no clash between the two `age`s
|
|
|
that are defined at different phase levels:
|
|
|
|
|
|
```racket
|
|
|
> (define age 3)
|
|
|
> (begin-for-syntax
|
|
|
(define age 9))
|
|
|
```
|
|
|
|
|
|
The `age` binding at phase level 0 has a value of 3, and the `age`
|
|
|
binding at phase level 1 has a value of 9.
|
|
|
|
|
|
Syntax objects capture binding information as a first-class value. Thus,
|
|
|
|
|
|
`#'age`
|
|
|
|
|
|
is a syntax object that represents the `age` binding—but since there are
|
|
|
two `age`s \(one at phase level 0 and one at phase level 1\), which one
|
|
|
does it capture? In fact, Racket imbues `#'age` with lexical
|
|
|
information for all phase levels, so the answer is that `#'age` captures
|
|
|
both.
|
|
|
|
|
|
The relevant binding of `age` captured by `#'age` is determined when
|
|
|
`#'age` is eventually used. As an example, we bind `#'age` to a pattern
|
|
|
variable so we can use it in a template, and then we `eval`uate the
|
|
|
template: We use `eval` here to demonstrate phases, but see \[missing\]
|
|
|
for caveats about `eval`.
|
|
|
|
|
|
```racket
|
|
|
> (eval (with-syntax ([age #'age])
|
|
|
#'(displayln age)))
|
|
|
3
|
|
|
```
|
|
|
|
|
|
The result is `3` because `age` is used at phase 0 level. We can try
|
|
|
again with the use of `age` inside `begin-for-syntax`:
|
|
|
|
|
|
```racket
|
|
|
> (eval (with-syntax ([age #'age])
|
|
|
#'(begin-for-syntax
|
|
|
(displayln age))))
|
|
|
9
|
|
|
```
|
|
|
|
|
|
In this case, the answer is `9`, because we are using `age` at phase
|
|
|
level 1 instead of 0 \(i.e., `begin-for-syntax` evaluates its
|
|
|
expressions at phase level 1\). So, you can see that we started with the
|
|
|
same syntax object, `#'age`, and we were able to use it in two different
|
|
|
ways: at phase level 0 and at phase level 1.
|
|
|
|
|
|
A syntax object has a lexical context from the moment it first exists. A
|
|
|
syntax object that is provided from a module retains its lexical
|
|
|
context, and so it references bindings in the context of its source
|
|
|
module, not the context of its use. The following example defines
|
|
|
`button` at phase level 0 and binds it to `0`, while `see-button` binds
|
|
|
the syntax object for `button` in module `a`:
|
|
|
|
|
|
```racket
|
|
|
> (module a racket
|
|
|
(define button 0)
|
|
|
(provide (for-syntax see-button))
|
|
|
; Why not (define see-button #'button)? We explain later.
|
|
|
(define-for-syntax see-button #'button))
|
|
|
> (module b racket
|
|
|
(require 'a)
|
|
|
(define button 8)
|
|
|
(define-syntax (m stx)
|
|
|
see-button)
|
|
|
(m))
|
|
|
> (require 'b)
|
|
|
0
|
|
|
```
|
|
|
|
|
|
The result of the `m` macro is the value of `see-button`, which is
|
|
|
`#'button` with the lexical context of the `a` module. Even though
|
|
|
there is another `button` in `b`, the second `button` will not confuse
|
|
|
Racket, because the lexical context of `#'button` \(the value bound to
|
|
|
`see-button`\) is `a`.
|
|
|
|
|
|
Note that `see-button` is bound at phase level 1 by virtue of defining
|
|
|
it with `define-for-syntax`. Phase level 1 is needed because `m` is a
|
|
|
macro, so its body executes at one phase higher than the context of its
|
|
|
definition. Since `m` is defined at phase level 0, its body is at phase
|
|
|
level 1, so any bindings referenced by the body must be at phase level
|
|
|
1.
|
|
|
|
|
|
#### 2.6.2. Phases and Modules
|
|
|
|
|
|
A phase level is a module-relative concept. When importing from another
|
|
|
module via `require`, Racket lets us shift imported bindings to a phase
|
|
|
level that is different from the original one:
|
|
|
|
|
|
```racket
|
|
|
(require "a.rkt") ; import with no phase shift
|
|
|
(require (for-syntax "a.rkt")) ; shift phase by +1
|
|
|
(require (for-template "a.rkt")) ; shift phase by -1
|
|
|
(require (for-meta 5 "a.rkt")) ; shift phase by +5
|
|
|
```
|
|
|
|
|
|
That is, using `for-syntax` in `require` means that all of the bindings
|
|
|
from that module will have their phase levels increased by one. A
|
|
|
binding that is `define`d at phase level 0 and imported with
|
|
|
`for-syntax` becomes a phase-level 1 binding:
|
|
|
|
|
|
```racket
|
|
|
> (module c racket
|
|
|
(define x 0) ; defined at phase level 0
|
|
|
(provide x))
|
|
|
> (module d racket
|
|
|
(require (for-syntax 'c))
|
|
|
; has a binding at phase level 1, not 0:
|
|
|
#'x)
|
|
|
```
|
|
|
|
|
|
Let’s see what happens if we try to create a binding for the `#'button`
|
|
|
syntax object at phase level 0:
|
|
|
|
|
|
```racket
|
|
|
> (define button 0)
|
|
|
> (define see-button #'button)
|
|
|
```
|
|
|
|
|
|
Now both `button` and `see-button` are defined at phase 0. The lexical
|
|
|
context of `#'button` will know that there is a binding for `button` at
|
|
|
phase 0. In fact, it seems like things are working just fine if we try
|
|
|
to `eval` `see-button`:
|
|
|
|
|
|
```racket
|
|
|
> (eval see-button)
|
|
|
0
|
|
|
```
|
|
|
|
|
|
Now, let’s use `see-button` in a macro:
|
|
|
|
|
|
```racket
|
|
|
> (define-syntax (m stx)
|
|
|
see-button)
|
|
|
> (m)
|
|
|
see-button: undefined;
|
|
|
cannot reference an identifier before its definition
|
|
|
in module: top-level
|
|
|
```
|
|
|
|
|
|
Clearly, `see-button` is not defined at phase level 1, so we cannot
|
|
|
refer to it inside the macro body. Let’s try to use `see-button` in
|
|
|
another module by putting the button definitions in a module and
|
|
|
importing it at phase level 1. Then, we will get `see-button` at phase
|
|
|
level 1:
|
|
|
|
|
|
```racket
|
|
|
> (module a racket
|
|
|
(define button 0)
|
|
|
(define see-button #'button)
|
|
|
(provide see-button))
|
|
|
> (module b racket
|
|
|
(require (for-syntax 'a)) ; gets see-button at phase level 1
|
|
|
(define-syntax (m stx)
|
|
|
see-button)
|
|
|
(m))
|
|
|
eval:1:0: button: unbound identifier;
|
|
|
also, no #%top syntax transformer is bound
|
|
|
in: button
|
|
|
```
|
|
|
|
|
|
Racket says that `button` is unbound now! When `a` is imported at phase
|
|
|
level 1, we have the following bindings:
|
|
|
|
|
|
```racket
|
|
|
button at phase level 1
|
|
|
see-button at phase level 1
|
|
|
```
|
|
|
|
|
|
So the macro `m` can see a binding for `see-button` at phase level 1 and
|
|
|
will return the `#'button` syntax object, which refers to `button`
|
|
|
binding at phase level 1. But the use of `m` is at phase level 0, and
|
|
|
there is no `button` at phase level 0 in `b`. That is why `see-button`
|
|
|
needs to be bound at phase level 1, as in the original `a`. In the
|
|
|
original `b`, then, we have the following bindings:
|
|
|
|
|
|
```racket
|
|
|
button at phase level 0
|
|
|
see-button at phase level 1
|
|
|
```
|
|
|
|
|
|
In this scenario, we can use `see-button` in the macro, since
|
|
|
`see-button` is bound at phase level 1. When the macro expands, it will
|
|
|
refer to a `button` binding at phase level 0.
|
|
|
|
|
|
Defining `see-button` with `(define see-button #'button)` isn’t
|
|
|
inherently wrong; it depends on how we intend to use `see-button`. For
|
|
|
example, we can arrange for `m` to sensibly use `see-button` because it
|
|
|
puts it in a phase level 1 context using `begin-for-syntax`:
|
|
|
|
|
|
```racket
|
|
|
> (module a racket
|
|
|
(define button 0)
|
|
|
(define see-button #'button)
|
|
|
(provide see-button))
|
|
|
> (module b racket
|
|
|
(require (for-syntax 'a))
|
|
|
(define-syntax (m stx)
|
|
|
(with-syntax ([x see-button])
|
|
|
#'(begin-for-syntax
|
|
|
(displayln x))))
|
|
|
(m))
|
|
|
0
|
|
|
```
|
|
|
|
|
|
In this case, module `b` has both `button` and `see-button` bound at
|
|
|
phase level 1. The expansion of the macro is
|
|
|
|
|
|
```racket
|
|
|
(begin-for-syntax
|
|
|
(displayln button))
|
|
|
```
|
|
|
|
|
|
which works, because `button` is bound at phase level 1.
|
|
|
|
|
|
Now, you might try to cheat the phase system by importing `a` at both
|
|
|
phase level 0 and phase level 1. Then you would have the following
|
|
|
bindings
|
|
|
|
|
|
```racket
|
|
|
button at phase level 0
|
|
|
see-button at phase level 0
|
|
|
button at phase level 1
|
|
|
see-button at phase level 1
|
|
|
```
|
|
|
|
|
|
You might expect now that `see-button` in a macro would work, but it
|
|
|
doesn’t:
|
|
|
|
|
|
```racket
|
|
|
> (module a racket
|
|
|
(define button 0)
|
|
|
(define see-button #'button)
|
|
|
(provide see-button))
|
|
|
> (module b racket
|
|
|
(require 'a
|
|
|
(for-syntax 'a))
|
|
|
(define-syntax (m stx)
|
|
|
see-button)
|
|
|
(m))
|
|
|
eval:1:0: button: unbound identifier;
|
|
|
also, no #%top syntax transformer is bound
|
|
|
in: button
|
|
|
```
|
|
|
|
|
|
The `see-button` inside macro `m` comes from the `(for-syntax 'a)`
|
|
|
import. For macro `m` to work, it needs to have `button` bound at phase
|
|
|
0. That binding exists—it’s implied by `(require 'a)`. However,
|
|
|
`(require 'a)` and `(require (for-syntax 'a))` are _different
|
|
|
instantiations_ of the same module. The `see-button` at phase 1 only
|
|
|
refers to the `button` at phase 1, not the `button` bound at phase 0
|
|
|
from a different instantiation—even from the same source module.
|
|
|
|
|
|
This kind of phase-level mismatch between instantiations can be repaired
|
|
|
with `syntax-shift-phase-level`. Recall that a syntax object like
|
|
|
`#'button` captures lexical information at _all_ phase levels. The
|
|
|
problem here is that `see-button` is invoked at phase 1, but needs to
|
|
|
return a syntax object that can be evaluated at phase 0. By default,
|
|
|
`see-button` is bound to `#'button` at the same phase level. But with
|
|
|
`syntax-shift-phase-level`, we can make `see-button` refer to `#'button`
|
|
|
at a different relative phase level. In this case, we use a phase shift
|
|
|
of `-1` to make `see-button` at phase 1 refer to `#'button` at phase 0.
|
|
|
\(Because the phase shift happens at every level, it will also make
|
|
|
`see-button` at phase 0 refer to `#'button` at phase -1.\)
|
|
|
|
|
|
Note that `syntax-shift-phase-level` merely creates a reference across
|
|
|
phases. To make that reference work, we still need to instantiate our
|
|
|
module at both phases so the reference and its target have their
|
|
|
bindings available. Thus, in module `'b`, we still import module `'a` at
|
|
|
both phase 0 and phase 1—using `(require 'a (for-syntax 'a))`—so we have
|
|
|
a phase-1 binding for `see-button` and a phase-0 binding for `button`.
|
|
|
Now macro `m` will work.
|
|
|
|
|
|
```racket
|
|
|
> (module a racket
|
|
|
(define button 0)
|
|
|
(define see-button (syntax-shift-phase-level #'button -1))
|
|
|
(provide see-button))
|
|
|
> (module b racket
|
|
|
(require 'a (for-syntax 'a))
|
|
|
(define-syntax (m stx)
|
|
|
see-button)
|
|
|
(m))
|
|
|
> (require 'b)
|
|
|
0
|
|
|
```
|
|
|
|
|
|
By the way, what happens to the `see-button` that’s bound at phase 0?
|
|
|
Its `#'button` binding has likewise been shifted, but to phase -1. Since
|
|
|
`button` itself isn’t bound at phase -1, if we try to evaluate
|
|
|
`see-button` at phase 0, we get an error. In other words, we haven’t
|
|
|
permanently cured our mismatch problem—we’ve just shifted it to a less
|
|
|
bothersome location.
|
|
|
|
|
|
```racket
|
|
|
> (module a racket
|
|
|
(define button 0)
|
|
|
(define see-button (syntax-shift-phase-level #'button -1))
|
|
|
(provide see-button))
|
|
|
> (module b racket
|
|
|
(require 'a (for-syntax 'a))
|
|
|
(define-syntax (m stx)
|
|
|
see-button)
|
|
|
(m))
|
|
|
> (module b2 racket
|
|
|
(require 'a)
|
|
|
(eval see-button))
|
|
|
> (require 'b2)
|
|
|
button: undefined;
|
|
|
cannot reference an identifier before its definition
|
|
|
in module: top-level
|
|
|
```
|
|
|
|
|
|
Mismatches like the one above can also arise when a macro tries to match
|
|
|
literal bindings—using `syntax-case` or `syntax-parse`.
|
|
|
|
|
|
```racket
|
|
|
> (module x racket
|
|
|
(require (for-syntax syntax/parse)
|
|
|
(for-template racket/base))
|
|
|
|
|
|
(provide (all-defined-out))
|
|
|
|
|
|
(define button 0)
|
|
|
(define (make) #'button)
|
|
|
(define-syntax (process stx)
|
|
|
(define-literal-set locals (button))
|
|
|
(syntax-parse stx
|
|
|
[(_ (n (~literal button))) #'#''ok])))
|
|
|
> (module y racket
|
|
|
(require (for-meta 1 'x)
|
|
|
(for-meta 2 'x racket/base))
|
|
|
|
|
|
(begin-for-syntax
|
|
|
(define-syntax (m stx)
|
|
|
(with-syntax ([out (make)])
|
|
|
#'(process (0 out)))))
|
|
|
|
|
|
(define-syntax (p stx)
|
|
|
(m))
|
|
|
|
|
|
(p))
|
|
|
eval:2.0: process: expected the identifier `button'
|
|
|
at: button
|
|
|
in: (process (0 button))
|
|
|
```
|
|
|
|
|
|
In this example, `make` is being used in `y` at phase level 2, and it
|
|
|
returns the `#'button` syntax object—which refers to `button` bound at
|
|
|
phase level 0 inside `x` and at phase level 2 in `y` from `(for-meta 2
|
|
|
'x)`. The `process` macro is imported at phase level 1 from `(for-meta
|
|
|
1 'x)`, and it knows that `button` should be bound at phase level 1.
|
|
|
When the `syntax-parse` is executed inside `process`, it is looking for
|
|
|
`button` bound at phase level 1 but it sees only a phase level 2 binding
|
|
|
and doesn’t match.
|
|
|
|
|
|
To fix the example, we can provide `make` at phase level 1 relative to
|
|
|
`x`, and then we import it at phase level 1 in `y`:
|
|
|
|
|
|
```racket
|
|
|
> (module x racket
|
|
|
(require (for-syntax syntax/parse)
|
|
|
(for-template racket/base))
|
|
|
|
|
|
(provide (all-defined-out))
|
|
|
|
|
|
(define button 0)
|
|
|
|
|
|
(provide (for-syntax make))
|
|
|
(define-for-syntax (make) #'button)
|
|
|
(define-syntax (process stx)
|
|
|
(define-literal-set locals (button))
|
|
|
(syntax-parse stx
|
|
|
[(_ (n (~literal button))) #'#''ok])))
|
|
|
> (module y racket
|
|
|
(require (for-meta 1 'x)
|
|
|
(for-meta 2 racket/base))
|
|
|
|
|
|
(begin-for-syntax
|
|
|
(define-syntax (m stx)
|
|
|
(with-syntax ([out (make)])
|
|
|
#'(process (0 out)))))
|
|
|
|
|
|
(define-syntax (p stx)
|
|
|
(m))
|
|
|
|
|
|
(p))
|
|
|
> (require 'y)
|
|
|
'ok
|
|
|
```
|
|
|
|
|
|
### 2.7. Syntax Taints
|
|
|
|
|
|
A use of a macro can expand into a use of an identifier that is not
|
|
|
exported from the module that binds the macro. In general, such an
|
|
|
identifier must not be extracted from the expanded expression and used
|
|
|
in a different context, because using the identifier in a different
|
|
|
context may break invariants of the macro’s module.
|
|
|
|
|
|
For example, the following module exports a macro `go` that expands to a
|
|
|
use of `unchecked-go`:
|
|
|
|
|
|
`"m.rkt"`
|
|
|
```racket
|
|
|
#lang racket
|
|
|
(provide go)
|
|
|
|
|
|
(define (unchecked-go n x)
|
|
|
; to avoid disaster, n must be a number
|
|
|
(+ n 17))
|
|
|
|
|
|
(define-syntax (go stx)
|
|
|
(syntax-case stx ()
|
|
|
[(_ x)
|
|
|
#'(unchecked-go 8 x)]))
|
|
|
```
|
|
|
|
|
|
If the reference to `unchecked-go` is extracted from the expansion of
|
|
|
`(go 'a)`, then it might be inserted into a new expression,
|
|
|
`(unchecked-go #f 'a)`, leading to disaster. The `datum->syntax`
|
|
|
procedure can be used similarly to construct references to an unexported
|
|
|
identifier, even when no macro expansion includes a reference to the
|
|
|
identifier.
|
|
|
|
|
|
To prevent such abuses of unexported identifiers, the `go` macro must
|
|
|
explicitly protect its expansion by using `syntax-protect`:
|
|
|
|
|
|
```racket
|
|
|
(define-syntax (go stx)
|
|
|
(syntax-case stx ()
|
|
|
[(_ x)
|
|
|
(syntax-protect #'(unchecked-go 8 x))]))
|
|
|
```
|
|
|
|
|
|
The `syntax-protect` function causes any syntax object that is extracted
|
|
|
from the result of `go` to be _tainted_. The macro expander rejects
|
|
|
tainted identifiers, so attempting to extract `unchecked-go` from the
|
|
|
expansion of `(go 'a)` produces an identifier that cannot be used to
|
|
|
construct a new expression \(or, at least, not one that the macro
|
|
|
expander will accept\). The `syntax-rules`, `syntax-id-rule`, and
|
|
|
`define-syntax-rule` forms automatically protect their expansion
|
|
|
results.
|
|
|
|
|
|
More precisely, `syntax-protect` _arms_ a syntax object with a _dye
|
|
|
pack_. When a syntax object is armed, then `syntax-e` taints any syntax
|
|
|
object in its result. Similarly, `datum->syntax` taints its result when
|
|
|
its first argument is armed. Finally, if any part of a quoted syntax
|
|
|
object is armed, then the corresponding part is tainted in the resulting
|
|
|
syntax constant.
|
|
|
|
|
|
Of course, the macro expander itself must be able to _disarm_ a taint on
|
|
|
a syntax object, so that it can further expand an expression or its
|
|
|
sub-expressions. When a syntax object is armed with a dye pack, the dye
|
|
|
pack has an associated inspector that can be used to disarm the dye
|
|
|
pack. A `(syntax-protect stx)` function call is actually a shorthand for
|
|
|
`(syntax-arm stx #f #t)`, which arms `stx` using a suitable inspector.
|
|
|
The expander uses `syntax-disarm` and with its inspector on every
|
|
|
expression before trying to expand or compile it.
|
|
|
|
|
|
In much the same way that the macro expander copies properties from a
|
|
|
syntax transformer’s input to its output \(see \[missing\]\), the
|
|
|
expander copies dye packs from a transformer’s input to its output.
|
|
|
Building on the previous example,
|
|
|
|
|
|
`"n.rkt"`
|
|
|
```racket
|
|
|
#lang racket
|
|
|
(require "m.rkt")
|
|
|
|
|
|
(provide go-more)
|
|
|
|
|
|
(define y 'hello)
|
|
|
|
|
|
(define-syntax (go-more stx)
|
|
|
(syntax-protect #'(go y)))
|
|
|
```
|
|
|
|
|
|
the expansion of `(go-more)` introduces a reference to the unexported
|
|
|
`y` in `(go y)`, and the expansion result is armed so that `y` cannot be
|
|
|
extracted from the expansion. Even if `go` did not use `syntax-protect`
|
|
|
for its result \(perhaps because it does not need to protect
|
|
|
`unchecked-go` after all\), the dye pack on `(go y)` is propagated to
|
|
|
the final expansion `(unchecked-go 8 y)`. The macro expander uses
|
|
|
`syntax-rearm` to propagate dye packs from a transformer’s input to its
|
|
|
output.
|
|
|
|
|
|
#### 2.7.1. Tainting Modes
|
|
|
|
|
|
In some cases, a macro implementor intends to allow limited
|
|
|
destructuring of a macro result without tainting the result. For
|
|
|
example, given the following `define-like-y` macro,
|
|
|
|
|
|
`"q.rkt"`
|
|
|
```racket
|
|
|
#lang racket
|
|
|
|
|
|
(provide define-like-y)
|
|
|
|
|
|
(define y 'hello)
|
|
|
|
|
|
(define-syntax (define-like-y stx)
|
|
|
(syntax-case stx ()
|
|
|
[(_ id) (syntax-protect #'(define-values (id) y))]))
|
|
|
```
|
|
|
|
|
|
someone may use the macro in an internal definition:
|
|
|
|
|
|
```racket
|
|
|
(let ()
|
|
|
(define-like-y x)
|
|
|
x)
|
|
|
```
|
|
|
|
|
|
The implementor of the `"q.rkt"` module most likely intended to allow
|
|
|
such uses of `define-like-y`. To convert an internal definition into a
|
|
|
`letrec` binding, however, the `define` form produced by `define-like-y`
|
|
|
must be deconstructed, which would normally taint both the binding `x`
|
|
|
and the reference to `y`.
|
|
|
|
|
|
Instead, the internal use of `define-like-y` is allowed, because
|
|
|
`syntax-protect` treats specially a syntax list that begins with
|
|
|
`define-values`. In that case, instead of arming the overall expression,
|
|
|
each individual element of the syntax list is armed, pushing dye packs
|
|
|
further into the second element of the list so that they are attached to
|
|
|
the defined identifiers. Thus, `define-values`, `x`, and `y` in the
|
|
|
expansion result `(define-values (x) y)` are individually armed, and the
|
|
|
definition can be deconstructed for conversion to `letrec`.
|
|
|
|
|
|
Just like `syntax-protect`, the expander rearms a transformer result
|
|
|
that starts with `define-values`, by pushing dye packs into the list
|
|
|
elements. As a result, `define-like-y` could have been implemented to
|
|
|
produce `(define id y)`, which uses `define` instead of `define-values`.
|
|
|
In that case, the entire `define` form is at first armed with a dye
|
|
|
pack, but as the `define` form is expanded to `define-values`, the dye
|
|
|
pack is moved to the parts.
|
|
|
|
|
|
The macro expander treats syntax-list results starting with
|
|
|
`define-syntaxes` in the same way that it treats results starting with
|
|
|
`define-values`. Syntax-list results starting with `begin` are treated
|
|
|
similarly, except that the second element of the syntax list is treated
|
|
|
like all the other elements \(i.e., the immediate element is armed,
|
|
|
instead of its content\). Furthermore, the macro expander applies this
|
|
|
special handling recursively, in case a macro produces a `begin` form
|
|
|
that contains nested `define-values` forms.
|
|
|
|
|
|
The default application of dye packs can be overridden by attaching a
|
|
|
`'taint-mode` property \(see \[missing\]\) to the resulting syntax
|
|
|
object of a macro transformer. If the property value is `'opaque`, then
|
|
|
the syntax object is armed and not its parts. If the property value is
|
|
|
`'transparent`, then the syntax object’s parts are armed. If the
|
|
|
property value is `'transparent-binding`, then the syntax object’s parts
|
|
|
and the sub-parts of the second part \(as for `define-values` and
|
|
|
`define-syntaxes`\) are armed. The `'transparent` and
|
|
|
`'transparent-binding` modes trigger recursive property checking at the
|
|
|
parts, so that armings can be pushed arbitrarily deeply into a
|
|
|
transformer’s result.
|
|
|
|
|
|
#### 2.7.2. Taints and Code Inspectors
|
|
|
|
|
|
Tools that are intended to be privileged \(such as a debugging
|
|
|
transformer\) must disarm dye packs in expanded programs. Privilege is
|
|
|
granted through _code inspectors_. Each dye pack records an inspector,
|
|
|
and a syntax object can be disarmed using a sufficiently powerful
|
|
|
inspector.
|
|
|
|
|
|
When a module is declared, the declaration captures the current value of
|
|
|
the `current-code-inspector` parameter. The captured inspector is used
|
|
|
when `syntax-protect` is applied by a macro transformer that is defined
|
|
|
within the module. A tool can disarm the resulting syntax object by
|
|
|
supplying `syntax-disarm` with an inspector that is the same or a
|
|
|
super-inspector of the module’s inspector. Untrusted code is ultimately
|
|
|
run after setting `current-code-inspector` to a less powerful inspector
|
|
|
\(after trusted code, such as debugging tools, have been loaded\).
|
|
|
|
|
|
With this arrangement, macro-generating macros require some care, since
|
|
|
the generating macro may embed syntax objects in the generated macro
|
|
|
that need to have the generating module’s protection level, rather than
|
|
|
the protection level of the module that contains the generated macro. To
|
|
|
avoid this problem, use the module’s declaration-time inspector, which
|
|
|
is accessible as `(variable-reference->module-declaration-inspector
|
|
|
(#%variable-reference))`, and use it to define a variant of
|
|
|
`syntax-protect`.
|
|
|
|
|
|
For example, suppose that the `go` macro is implemented through a macro:
|
|
|
|
|
|
```racket
|
|
|
#lang racket
|
|
|
(provide def-go)
|
|
|
|
|
|
(define (unchecked-go n x)
|
|
|
(+ n 17))
|
|
|
|
|
|
(define-syntax (def-go stx)
|
|
|
(syntax-case stx ()
|
|
|
[(_ go)
|
|
|
(protect-syntax
|
|
|
#'(define-syntax (go stx)
|
|
|
(syntax-case stx ()
|
|
|
[(_ x)
|
|
|
(protect-syntax #'(unchecked-go 8 x))])))]))
|
|
|
```
|
|
|
|
|
|
When `def-go` is used inside another module to define `go`, and when the
|
|
|
`go`-defining module is at a different protection level than the
|
|
|
`def-go`-defining module, the generated macro’s use of `protect-syntax`
|
|
|
is not right. The use of `unchecked-go` should be protected at the
|
|
|
level of the `def-go`-defining module, not the `go`-defining module.
|
|
|
|
|
|
The solution is to define and use `go-syntax-protect`, instead:
|
|
|
|
|
|
```racket
|
|
|
#lang racket
|
|
|
(provide def-go)
|
|
|
|
|
|
(define (unchecked-go n x)
|
|
|
(+ n 17))
|
|
|
|
|
|
(define-for-syntax go-syntax-protect
|
|
|
(let ([insp (variable-reference->module-declaration-inspector
|
|
|
(#%variable-reference))])
|
|
|
(lambda (stx) (syntax-arm stx insp))))
|
|
|
|
|
|
(define-syntax (def-go stx)
|
|
|
(syntax-case stx ()
|
|
|
[(_ go)
|
|
|
(protect-syntax
|
|
|
#'(define-syntax (go stx)
|
|
|
(syntax-case stx ()
|
|
|
[(_ x)
|
|
|
(go-syntax-protect #'(unchecked-go 8 x))])))]))
|
|
|
```
|
|
|
|
|
|
#### 2.7.3. Protected Exports
|
|
|
|
|
|
Sometimes, a module needs to export bindings to some modules—other
|
|
|
modules that are at the same trust level as the exporting module—but
|
|
|
prevent access from untrusted modules. Such exports should use the
|
|
|
`protect-out` form in `provide`. For example, `ffi/unsafe` exports all
|
|
|
of its unsafe bindings as _protected_ in this sense.
|
|
|
|
|
|
Code inspectors, again, provide the mechanism for determining which
|
|
|
modules are trusted and which are untrusted. When a module is declared,
|
|
|
the value of `current-code-inspector` is associated to the module
|
|
|
declaration. When a module is instantiated \(i.e., when the body of the
|
|
|
declaration is actually executed\), a sub-inspector is created to guard
|
|
|
the module’s exports. Access to the module’s protected exports requires
|
|
|
a code inspector higher in the inspector hierarchy than the module’s
|
|
|
instantiation inspector; note that a module’s declaration inspector is
|
|
|
always higher than its instantiation inspector, so modules are declared
|
|
|
with the same code inspector can access each other’s exports.
|
|
|
|
|
|
Syntax-object constants within a module, such as literal identifiers in
|
|
|
a template, retain the inspector of their source module. In this way, a
|
|
|
macro from a trusted module can be used within an untrusted module, and
|
|
|
protected identifiers in the macro expansion still work, even through
|
|
|
they ultimately appear in an untrusted module. Naturally, such
|
|
|
identifiers should be armed, so that they cannot be extracted from the
|
|
|
macro expansion and abused by untrusted code.
|
|
|
|
|
|
Compiled code from a `".zo"` file is inherently untrustworthy,
|
|
|
unfortunately, since it can be synthesized by means other than
|
|
|
`compile`. When compiled code is written to a `".zo"` file,
|
|
|
syntax-object constants within the compiled code lose their inspectors.
|
|
|
All syntax-object constants within compiled code acquire the enclosing
|
|
|
module’s declaration-time inspector when the code is loaded.
|
|
|
|
|
|
## 3. Module Instantiations and Visits
|
|
|
|
|
|
Modules often contain just function and structure-type definitions, in
|
|
|
which case the module itself behaves in a purely functional way, and the
|
|
|
time when the functions are created is not observable. If a module’s
|
|
|
top-level expressions include side effects, however, then the timing of
|
|
|
the effects can matter. The distinction between module declaration and
|
|
|
instantiation provides some control over that timing. The concept of
|
|
|
module visits further explains the interaction of effects with macro
|
|
|
implementations.
|
|
|
|
|
|
### 3.1. Declaration versus Instantiation
|
|
|
|
|
|
Declaring a module does not immediately evaluate expressions in the
|
|
|
module’s body. For example, evaluating
|
|
|
|
|
|
```racket
|
|
|
> (module number-n racket/base
|
|
|
(provide n)
|
|
|
(define n (random 10))
|
|
|
(printf "picked ~a\n" n))
|
|
|
```
|
|
|
|
|
|
declares the module `number-n`, but it doesn’t immediately pick a random
|
|
|
number for `n` or display the number. A `require` of `number-n` causes
|
|
|
the module to be _instantiated_ \(i.e., it triggers an
|
|
|
_instantiation_\), which implies that the expressions in the body of the
|
|
|
module are evaluated:
|
|
|
|
|
|
```racket
|
|
|
> (require 'number-n)
|
|
|
picked 5
|
|
|
> n
|
|
|
5
|
|
|
```
|
|
|
|
|
|
After a module is instantiated in a particular namespace, further
|
|
|
`require`s of the module use the same instance, as opposed to
|
|
|
instantiating the module again:
|
|
|
|
|
|
```racket
|
|
|
> (require 'number-n)
|
|
|
> n
|
|
|
5
|
|
|
> (module use-n racket/base
|
|
|
(require 'number-n)
|
|
|
(printf "still ~a\n" n))
|
|
|
> (require 'use-n)
|
|
|
still 5
|
|
|
```
|
|
|
|
|
|
The `dynamic-require` function, like `require`, triggers instantion of a
|
|
|
module if it is not already instantiated, so `dynamic-require` with `#f`
|
|
|
as a second argument is useful to just trigger the instantion effects of
|
|
|
a module:
|
|
|
|
|
|
```racket
|
|
|
> (module use-n-again racket/base
|
|
|
(require 'number-n)
|
|
|
(printf "also still ~a\n" n))
|
|
|
> (dynamic-require ''use-n-again #f)
|
|
|
also still 5
|
|
|
```
|
|
|
|
|
|
Instantiation of modules by `require` is transitive. That is, if
|
|
|
`require` of a module instantiates it, then any module `require`d by
|
|
|
that one is also instantiated \(if it’s not instantiated already\):
|
|
|
|
|
|
```racket
|
|
|
> (module number-m racket/base
|
|
|
(provide m)
|
|
|
(define m (random 10))
|
|
|
(printf "picked ~a\n" m))
|
|
|
> (module use-m racket/base
|
|
|
(require 'number-m)
|
|
|
(printf "still ~a\n" m))
|
|
|
> (require 'use-m)
|
|
|
picked 0
|
|
|
still 0
|
|
|
```
|
|
|
|
|
|
### 3.2. Compile-Time Instantiation
|
|
|
|
|
|
In the same way that declaring a module does not by itself instantiate a
|
|
|
module, declaring a module that `require`s another module does not by
|
|
|
itself instantiate the `require`d module, as illustrated in the
|
|
|
preceding example. However, declaring a module _does_ expand and compile
|
|
|
the module. If a module imports another with `(require (for-syntax
|
|
|
....))`, then module that is imported `for-syntax` must be instantiated
|
|
|
during expansion:
|
|
|
|
|
|
```racket
|
|
|
> (module number-p racket/base
|
|
|
(provide p)
|
|
|
(define p (random 10))
|
|
|
(printf "picked ~a\n" p))
|
|
|
> (module use-p-at-compile-time racket/base
|
|
|
(require (for-syntax racket/base
|
|
|
'number-p))
|
|
|
(define-syntax (pm stx)
|
|
|
#`#,p)
|
|
|
(printf "was ~a at compile time\n" (pm)))
|
|
|
picked 1
|
|
|
```
|
|
|
|
|
|
Unlike run-time instantiation in a namespace, when a module is used
|
|
|
`for-syntax` for another module expansion in the same namespace, the
|
|
|
`for-syntax`ed module is instantiated separately for each expansion.
|
|
|
Continuing the previous example, if `number-p` is used a second time
|
|
|
`for-syntax`, then a second random number is selected for a new `p`:
|
|
|
|
|
|
```racket
|
|
|
> (module use-p-again-at-compile-time racket/base
|
|
|
(require (for-syntax racket/base
|
|
|
'number-p))
|
|
|
(define-syntax (pm stx)
|
|
|
#`#,p)
|
|
|
(printf "was ~a at second compile time\n" (pm)))
|
|
|
picked 3
|
|
|
```
|
|
|
|
|
|
Separate compile-time instantiations of `number-p` helps prevent
|
|
|
accidental propagation of effects from one module’s compilation to
|
|
|
another module’s compilation. Preventing those effects make compilation
|
|
|
reliably separate and more deterministic.
|
|
|
|
|
|
The expanded forms of `use-p-at-compile-time` and
|
|
|
`use-p-again-at-compile-time` record the number that was selected each
|
|
|
time, so those two different numbers are printed when the modules are
|
|
|
instantiated:
|
|
|
|
|
|
```racket
|
|
|
> (dynamic-require ''use-p-at-compile-time #f)
|
|
|
was 1 at compile time
|
|
|
> (dynamic-require ''use-p-again-at-compile-time #f)
|
|
|
was 3 at second compile time
|
|
|
```
|
|
|
|
|
|
A namespace’s top level behaves like a separate module, where multiple
|
|
|
interactions in the top level conceptually extend a single expansion of
|
|
|
the module. So, when using `(require (for-syntax ....))` twice in the
|
|
|
top level, the second use does not trigger a new compile-time instance:
|
|
|
|
|
|
```racket
|
|
|
> (begin (require (for-syntax 'number-p)) 'done)
|
|
|
picked 4
|
|
|
'done
|
|
|
> (begin (require (for-syntax 'number-p)) 'done-again)
|
|
|
'done-again
|
|
|
```
|
|
|
|
|
|
However, a run-time instance of a module is kept separate from all
|
|
|
compile-time instances, including at the top level, so a
|
|
|
non-`for-syntax` use of `number-p` will pick another random number:
|
|
|
|
|
|
```racket
|
|
|
> (require 'number-p)
|
|
|
picked 5
|
|
|
```
|
|
|
|
|
|
### 3.3. Visiting Modules
|
|
|
|
|
|
When a module `provide`s a macro for use by other modules, the other
|
|
|
modules use the macro by directly `require`ing the macro provider—i.e.,
|
|
|
without `for-syntax`. That’s because the macro is being imported for use
|
|
|
in a run-time position \(even though the macro’s implementation lives at
|
|
|
compile time\), while `for-syntax` would import a binding for use in
|
|
|
compile-time position.
|
|
|
|
|
|
The module implementing a macro, meanwhile, might `require` another
|
|
|
module `for-syntax` to implement the macro. The `for-syntax` module
|
|
|
needs a compile-time instantiation during any module expansion that
|
|
|
might use the macro. That requirement sets up a kind of transitivity
|
|
|
through `require` that is similar to instantiation transitivity, but
|
|
|
“off by one” at the point where the `for-syntax` shift occurs in the
|
|
|
chain.
|
|
|
|
|
|
Here’s an example to make that scenario concrete:
|
|
|
|
|
|
```racket
|
|
|
> (module number-q racket/base
|
|
|
(provide q)
|
|
|
(define q (random 10))
|
|
|
(printf "picked ~a\n" q))
|
|
|
> (module use-q-at-compile-time racket/base
|
|
|
(require (for-syntax racket/base
|
|
|
'number-q))
|
|
|
(provide qm)
|
|
|
(define-syntax (qm stx)
|
|
|
#`#,q)
|
|
|
(printf "was ~a at compile time\n" (qm)))
|
|
|
picked 7
|
|
|
> (module use-qm racket/base
|
|
|
(require 'use-q-at-compile-time)
|
|
|
(printf "was ~a at second compile time\n" (qm)))
|
|
|
picked 4
|
|
|
> (dynamic-require ''use-qm #f)
|
|
|
was 7 at compile time
|
|
|
was 4 at second compile time
|
|
|
```
|
|
|
|
|
|
In this example, when `use-q-at-compile-time` is expanded and compiled,
|
|
|
`number-q` is instantiated once. In this case, that instantion is needed
|
|
|
to expand the `(qm)` macro, but the module system would proactively
|
|
|
create a compile-time instantiation of `number-q` even if the `qm` macro
|
|
|
turned out not to be used.
|
|
|
|
|
|
Then, as `use-qm` is expanded and compiled, a second compile-time
|
|
|
instantiation of `number-q` is created. That compile-time instantion is
|
|
|
needed to expand the `(qm)` form within `use-qm`.
|
|
|
|
|
|
Instantiating `use-qm` correctly reports the number that was picked
|
|
|
during that second module’s compilation. First, though, the `require` of
|
|
|
`use-q-at-compile-time` in `use-qm` triggers a transitive instantiation
|
|
|
of `use-q-at-compile-time`, which correctly reports the number that was
|
|
|
picked in its compilation.
|
|
|
|
|
|
Overall, the example illustrates a transitive effect of `require` that
|
|
|
we had already seen:
|
|
|
|
|
|
* When a module is instantiated, the run-time expressions in its
|
|
|
body are evaluated.
|
|
|
|
|
|
* When a module is instantiated, then any module that it `require`s
|
|
|
\(without `for-syntax`\) is also instantiated.
|
|
|
|
|
|
This rule does not explain the compile-time instantiations of
|
|
|
`number-q`, however. To explain that, we need a new word, _visit_, for
|
|
|
the concept that we saw in Compile-Time Instantiation:
|
|
|
|
|
|
* When a module is visited, the compile-time expressions \(such as
|
|
|
macro definition\) in its body are evaluated.
|
|
|
|
|
|
* As a module is expanded, it is visited.
|
|
|
|
|
|
* When a module is visited, then any module that it `require`s
|
|
|
\(without `for-syntax`\) is also visited.
|
|
|
|
|
|
* When a module is visited, then any module that it `require`s
|
|
|
`for-syntax` is instantiated at compile time.
|
|
|
|
|
|
Note that when visiting one module causes a compile-time instantion of
|
|
|
another module, the transitiveness of instantiated through regular
|
|
|
`require`s can trigger more compile-time instantiations. Instantiation
|
|
|
itself won’t trigger further visits, however, because any instantiated
|
|
|
module has already been expanded and compiled.
|
|
|
|
|
|
The compile-time expressions of a module that are evaluated by visiting
|
|
|
include both the right-hand sides of `define-syntax` forms and the body
|
|
|
of `begin-for-syntax` forms. That’s why a randomly selected number is
|
|
|
printed immediately in the following example:
|
|
|
|
|
|
```racket
|
|
|
> (module compile-time-number racket/base
|
|
|
(require (for-syntax racket/base))
|
|
|
(begin-for-syntax
|
|
|
(printf "picked ~a\n" (random)))
|
|
|
(printf "running\n"))
|
|
|
picked 0.25549265186825576
|
|
|
```
|
|
|
|
|
|
Instantiating the module evaluates only the run-time expressions, which
|
|
|
prints “running” but not a new random number:
|
|
|
|
|
|
```racket
|
|
|
> (dynamic-require ''compile-time-number #f)
|
|
|
running
|
|
|
```
|
|
|
|
|
|
The description of instantiates and visit above is phrased in terms of
|
|
|
normal `require`s and `for-syntax` `require`s, but a more precise
|
|
|
specification is in terms of module phases. For example, if module `A`
|
|
|
has `(require (for-syntax B))` and module `B` has `(require
|
|
|
(for-template C))`, then module `C` is instantiated when module `A` is
|
|
|
instantiated, because the `for-syntax` and `for-template` shifts cancel.
|
|
|
We have not yet specified what happens with `for-meta 2` for when
|
|
|
`for-syntax`es combine; we leave that to the next section, Lazy Visits
|
|
|
via Available Modules.
|
|
|
|
|
|
If you think of the top-level as a kind of module that is continuously
|
|
|
expanded, the above rules imply that `require` of another module at the
|
|
|
top level both instantiates and visits the other module \(if it is not
|
|
|
already instantiated and visited\). That’s roughly true, but the visit
|
|
|
is made lazy in a way that is also explained in the next section, Lazy
|
|
|
Visits via Available Modules.
|
|
|
|
|
|
Meanwhile, `dynamic-require` only instantiates a module; it does not
|
|
|
visit the module. That simplification is why some of the preceding
|
|
|
examples use `dynamic-require` instead of `require`. The extra visits of
|
|
|
a top-level `require` would make the earlier examples less clear.
|
|
|
|
|
|
### 3.4. Lazy Visits via Available Modules
|
|
|
|
|
|
A top-level `require` of a module does not actually visit the module.
|
|
|
Instead, it makes the module _available_. An available module will be
|
|
|
visited when a future expression needs to be expanded in the same
|
|
|
context. The next expression may or may not involve some imported macro
|
|
|
that needs its compile-time helpers evaluated by visiting, but the
|
|
|
module system proactively visits the module, just in case.
|
|
|
|
|
|
In the following example, a random number is picked as a result of
|
|
|
visiting a module’s own body while that module is being expanded. A
|
|
|
`require` of the module instantiates it, printing “running”, and also
|
|
|
makes the module available. Evaluating any other expression implies
|
|
|
expanding the expression, and that expansion triggers a visit of the
|
|
|
available module—which picks another random number:
|
|
|
|
|
|
```racket
|
|
|
> (module another-compile-time-number racket/base
|
|
|
(require (for-syntax racket/base))
|
|
|
(begin-for-syntax
|
|
|
(printf "picked ~a\n" (random)))
|
|
|
(printf "running\n"))
|
|
|
picked 0.3634379786893492
|
|
|
> (require 'another-compile-time-number)
|
|
|
running
|
|
|
> 'next
|
|
|
picked 0.5057086679589476
|
|
|
'next
|
|
|
> 'another
|
|
|
'another
|
|
|
```
|
|
|
|
|
|
> Beware that the expander flattens the content of a top-level `begin`
|
|
|
> into the top level as soon as the `begin` is discovered. So, `(begin
|
|
|
> (require 'another-compile-time-number) 'next)` would still have printed
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> “picked” before “next“.
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The final evaluation of `'another` also visits any available modules,
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but no modules were made newly available by simply evaluating `'next`.
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When a module `require`s another module using `for-meta n` for some `n`
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greater than 1, the `require`d module is made available at phase `n`. A
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module that is available at phase `n` is visited when some expression at
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phase `n`_-_1__ is expanded.
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To help illustrate, the following examples use
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`(variable-reference->module-base-phase (#%variable-reference))`, which
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|
returns a number for the phase at which the enclosing module is
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|
instantiated:
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|
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|
```racket
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|
> (module show-phase racket/base
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|
(printf "running at ~a\n"
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|
(variable-reference->module-base-phase (#%variable-reference))))
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|
> (require 'show-phase)
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|
running at 0
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|
> (module use-at-phase-1 racket/base
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|
(require (for-syntax 'show-phase)))
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|
running at 1
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|
> (module unused-at-phase-2 racket/base
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|
(require (for-meta 2 'show-phase)))
|
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|
```
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For the last module above, `show-phase` is made available at phase 2,
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|
but no expressions within the module are ever expanded at phase 1, so
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|
there’s no phase-2 printout. The following module includes a phase-1
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|
expression after the phase-2 `require`, so there’s a printout:
|
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|
|
|
|
```racket
|
|
|
> (module use-at-phase-2 racket/base
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|
(require (for-meta 2 'show-phase)
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|
(for-syntax racket/base))
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|
|
(define-syntax x 'ok))
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|
running at 2
|
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|
```
|
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|
If we `require` the module `use-at-phase-1` at the top level, then
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|
`show-phase` is made available at phase 1. Evaluating another expression
|
|
|
causes `use-at-phase-1` to be visited, which in turn instantitates
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|
|
`show-phase`:
|
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|
|
|
|
```racket
|
|
|
> (require 'use-at-phase-1)
|
|
|
> 'next
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|
running at 1
|
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|
'next
|
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|
```
|
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|
A `require` of `use-at-phase-2` is similar, except that `show-phase` is
|
|
|
made available at phase 2, so it is not instantiated until some
|
|
|
expression is expanded at phase 1:
|
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|
|
|
|
```racket
|
|
|
> (require 'use-at-phase-2)
|
|
|
> 'next
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|
'next
|
|
|
> (require (for-syntax racket/base))
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|
|
> (begin-for-syntax 'compile-time-next)
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|
|
running at 2
|
|
|
```
|