mirror of
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Thanks to c.emil.hessman@gmail.com for pointing out the error. R=golang-dev, bradfitz CC=golang-dev https://golang.org/cl/12572043
650 lines
18 KiB
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650 lines
18 KiB
HTML
<!--{
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"Title": "The Laws of Reflection",
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"Template": true
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}-->
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<p>
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Reflection in computing is the
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ability of a program to examine its own structure, particularly
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through types; it's a form of metaprogramming. It's also a great
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source of confusion.
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</p>
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<p>
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In this article we attempt to clarify things by explaining how
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reflection works in Go. Each language's reflection model is
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different (and many languages don't support it at all), but
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this article is about Go, so for the rest of this article the word
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"reflection" should be taken to mean "reflection in Go".
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</p>
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<p><b>Types and interfaces</b></p>
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<p>
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Because reflection builds on the type system, let's start with a
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refresher about types in Go.
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</p>
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<p>
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Go is statically typed. Every variable has a static type, that is,
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exactly one type known and fixed at compile time: <code>int</code>,
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<code>float32</code>, <code>*MyType</code>, <code>[]byte</code>,
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and so on. If we declare
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</p>
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{{code "/doc/progs/interface.go" `/type MyInt/` `/STOP/`}}
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<p>
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then <code>i</code> has type <code>int</code> and <code>j</code>
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has type <code>MyInt</code>. The variables <code>i</code> and
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<code>j</code> have distinct static types and, although they have
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the same underlying type, they cannot be assigned to one another
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without a conversion.
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</p>
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<p>
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One important category of type is interface types, which represent
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fixed sets of methods. An interface variable can store any concrete
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(non-interface) value as long as that value implements the
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interface's methods. A well-known pair of examples is
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<code>io.Reader</code> and <code>io.Writer</code>, the types
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<code>Reader</code> and <code>Writer</code> from the
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<a href="/pkg/io/">io package</a>:
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</p>
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{{code "/doc/progs/interface.go" `/// Reader/` `/STOP/`}}
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<p>
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Any type that implements a <code>Read</code> (or
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<code>Write</code>) method with this signature is said to implement
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<code>io.Reader</code> (or <code>io.Writer</code>). For the
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purposes of this discussion, that means that a variable of type
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<code>io.Reader</code> can hold any value whose type has a
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<code>Read</code> method:
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</p>
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{{code "/doc/progs/interface.go" `/func readers/` `/STOP/`}}
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<p>
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It's important to be clear that whatever concrete value
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<code>r</code> may hold, <code>r</code>'s type is always
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<code>io.Reader</code>: Go is statically typed and the static type
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of <code>r</code> is <code>io.Reader</code>.</p>
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<p>
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An extremely important example of an interface type is the empty
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interface:
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</p>
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<pre>
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interface{}
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</pre>
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<p>
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It represents the empty set of methods and is satisfied by any
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value at all, since any value has zero or more methods.
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</p>
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<p>
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Some people say that Go's interfaces are dynamically typed, but
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that is misleading. They are statically typed: a variable of
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interface type always has the same static type, and even though at
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run time the value stored in the interface variable may change
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type, that value will always satisfy the interface.
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</p>
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<p>
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We need to be precise about all this because reflection and
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interfaces are closely related.
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</p>
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<p><b>The representation of an interface</b></p>
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<p>
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Russ Cox has written a
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<a href="http://research.swtch.com/2009/12/go-data-structures-interfaces.html">detailed blog post</a>
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about the representation of interface values in Go. It's not necessary to
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repeat the full story here, but a simplified summary is in order.
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</p>
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<p>
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A variable of interface type stores a pair: the concrete value
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assigned to the variable, and that value's type descriptor.
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To be more precise, the value is the underlying concrete data item
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that implements the interface and the type describes the full type
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of that item. For instance, after
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</p>
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{{code "/doc/progs/interface.go" `/func typeAssertions/` `/STOP/`}}
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<p>
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<code>r</code> contains, schematically, the (value, type) pair,
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(<code>tty</code>, <code>*os.File</code>). Notice that the type
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<code>*os.File</code> implements methods other than
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<code>Read</code>; even though the interface value provides access
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only to the <code>Read</code> method, the value inside carries all
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the type information about that value. That's why we can do things
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like this:
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</p>
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{{code "/doc/progs/interface.go" `/var w io.Writer/` `/STOP/`}}
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<p>
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The expression in this assignment is a type assertion; what it
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asserts is that the item inside <code>r</code> also implements
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<code>io.Writer</code>, and so we can assign it to <code>w</code>.
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After the assignment, <code>w</code> will contain the pair
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(<code>tty</code>, <code>*os.File</code>). That's the same pair as
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was held in <code>r</code>. The static type of the interface
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determines what methods may be invoked with an interface variable,
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even though the concrete value inside may have a larger set of
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methods.
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</p>
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<p>
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Continuing, we can do this:
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</p>
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{{code "/doc/progs/interface.go" `/var empty interface{}/` `/STOP/`}}
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<p>
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and our empty interface value, <code>empty</code>, will again contain
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that same pair, (<code>tty</code>, <code>*os.File</code>). That's
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handy: an empty interface can hold any value and contains all the
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information we could ever need about that value.
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</p>
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<p>
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(We don't need a type assertion here because it's known statically
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that <code>w</code> satisfies the empty interface. In the example
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where we moved a value from a <code>Reader</code> to a
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<code>Writer</code>, we needed to be explicit and use a type
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assertion because <code>Writer</code>'s methods are not a
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subset of <code>Reader</code>'s.)
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</p>
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<p>
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One important detail is that the pair inside an interface always
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has the form (value, concrete type) and cannot have the form
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(value, interface type). Interfaces do not hold interface
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values.
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</p>
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<p>
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Now we're ready to reflect.
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</p>
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<p><b>The first law of reflection</b></p>
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<p><b>1. Reflection goes from interface value to reflection object.</b></p>
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<p>
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At the basic level, reflection is just a mechanism to examine the
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type and value pair stored inside an interface variable. To get
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started, there are two types we need to know about in
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<a href="/pkg/reflect/">package reflect</a>:
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<a href="/pkg/reflect/#Type">Type</a> and
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<a href="/pkg/reflect/#Value">Value</a>. Those two types
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give access to the contents of an interface variable, and two
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simple functions, called <code>reflect.TypeOf</code> and
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<code>reflect.ValueOf</code>, retrieve <code>reflect.Type</code>
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and <code>reflect.Value</code> pieces out of an interface value.
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(Also, from the <code>reflect.Value</code> it's easy to get
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to the <code>reflect.Type</code>, but let's keep the
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<code>Value</code> and <code>Type</code> concepts separate for
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now.)
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</p>
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<p>
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Let's start with <code>TypeOf</code>:
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</p>
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{{code "/doc/progs/interface2.go" `/package main/` `/STOP main/`}}
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<p>
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This program prints
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</p>
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<pre>
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type: float64
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</pre>
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<p>
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You might be wondering where the interface is here, since the program looks
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like it's passing the <code>float64</code> variable <code>x</code>, not an
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interface value, to <code>reflect.TypeOf</code>. But it's there; as
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<a href="/pkg/reflect/#TypeOf">godoc reports</a>, the signature of
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<code>reflect.TypeOf</code> includes an empty interface:
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</p>
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<pre>
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// TypeOf returns the reflection Type of the value in the interface{}.
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func TypeOf(i interface{}) Type
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</pre>
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<p>
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When we call <code>reflect.TypeOf(x)</code>, <code>x</code> is
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first stored in an empty interface, which is then passed as the
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argument; <code>reflect.TypeOf</code> unpacks that empty interface
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to recover the type information.
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</p>
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<p>
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The <code>reflect.ValueOf</code> function, of course, recovers the
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value (from here on we'll elide the boilerplate and focus just on
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the executable code):
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</p>
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{{code "/doc/progs/interface2.go" `/START f9/` `/STOP/`}}
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<p>
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prints
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</p>
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<pre>
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value: <float64 Value>
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</pre>
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<p>
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Both <code>reflect.Type</code> and <code>reflect.Value</code> have
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lots of methods to let us examine and manipulate them. One
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important example is that <code>Value</code> has a
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<code>Type</code> method that returns the <code>Type</code> of a
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<code>reflect.Value</code>. Another is that both <code>Type</code>
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and <code>Value</code> have a <code>Kind</code> method that returns
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a constant indicating what sort of item is stored:
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<code>Uint</code>, <code>Float64</code>, <code>Slice</code>, and so
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on. Also methods on <code>Value</code> with names like
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<code>Int</code> and <code>Float</code> let us grab values (as
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<code>int64</code> and <code>float64</code>) stored inside:
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</p>
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{{code "/doc/progs/interface2.go" `/START f1/` `/STOP/`}}
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<p>
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prints
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</p>
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<pre>
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type: float64
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kind is float64: true
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value: 3.4
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</pre>
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<p>
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There are also methods like <code>SetInt</code> and
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<code>SetFloat</code> but to use them we need to understand
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settability, the subject of the third law of reflection, discussed
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below.
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</p>
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<p>
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The reflection library has a couple of properties worth singling
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out. First, to keep the API simple, the "getter" and "setter"
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methods of <code>Value</code> operate on the largest type that can
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hold the value: <code>int64</code> for all the signed integers, for
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instance. That is, the <code>Int</code> method of
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<code>Value</code> returns an <code>int64</code> and the
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<code>SetInt</code> value takes an <code>int64</code>; it may be
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necessary to convert to the actual type involved:
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</p>
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{{code "/doc/progs/interface2.go" `/START f2/` `/STOP/`}}
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<p>
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The second property is that the <code>Kind</code> of a reflection
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object describes the underlying type, not the static type. If a
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reflection object contains a value of a user-defined integer type,
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as in
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</p>
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{{code "/doc/progs/interface2.go" `/START f3/` `/STOP/`}}
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<p>
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the <code>Kind</code> of <code>v</code> is still
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<code>reflect.Int</code>, even though the static type of
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<code>x</code> is <code>MyInt</code>, not <code>int</code>. In
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other words, the <code>Kind</code> cannot discriminate an int from
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a <code>MyInt</code> even though the <code>Type</code> can.
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</p>
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<p><b>The second law of reflection</b></p>
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<p><b>2. Reflection goes from reflection object to interface
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value.</b></p>
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<p>
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Like physical reflection, reflection in Go generates its own
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inverse.
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</p>
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<p>
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Given a <code>reflect.Value</code> we can recover an interface
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value using the <code>Interface</code> method; in effect the method
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packs the type and value information back into an interface
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representation and returns the result:
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</p>
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<pre>
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// Interface returns v's value as an interface{}.
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func (v Value) Interface() interface{}
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</pre>
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<p>
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As a consequence we can say
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</p>
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{{code "/doc/progs/interface2.go" `/START f3b/` `/STOP/`}}
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<p>
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to print the <code>float64</code> value represented by the
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reflection object <code>v</code>.
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</p>
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<p>
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We can do even better, though. The arguments to
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<code>fmt.Println</code>, <code>fmt.Printf</code> and so on are all
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passed as empty interface values, which are then unpacked by the
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<code>fmt</code> package internally just as we have been doing in
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the previous examples. Therefore all it takes to print the contents
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of a <code>reflect.Value</code> correctly is to pass the result of
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the <code>Interface</code> method to the formatted print
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routine:
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</p>
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{{code "/doc/progs/interface2.go" `/START f3c/` `/STOP/`}}
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<p>
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(Why not <code>fmt.Println(v)</code>? Because <code>v</code> is a
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<code>reflect.Value</code>; we want the concrete value it holds.)
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Since our value is a <code>float64</code>, we can even use a
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floating-point format if we want:
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</p>
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{{code "/doc/progs/interface2.go" `/START f3d/` `/STOP/`}}
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<p>
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and get in this case
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</p>
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<pre>
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3.4e+00
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</pre>
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<p>
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Again, there's no need to type-assert the result of
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<code>v.Interface()</code> to <code>float64</code>; the empty
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interface value has the concrete value's type information inside
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and <code>Printf</code> will recover it.
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</p>
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<p>
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In short, the <code>Interface</code> method is the inverse of the
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<code>ValueOf</code> function, except that its result is always of
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static type <code>interface{}</code>.
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</p>
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<p>
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Reiterating: Reflection goes from interface values to reflection
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objects and back again.
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</p>
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<p><b>The third law of reflection</b></p>
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<p><b>3. To modify a reflection object, the value must be settable.</b></p>
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<p>
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The third law is the most subtle and confusing, but it's easy
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enough to understand if we start from first principles.
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</p>
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<p>
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Here is some code that does not work, but is worth studying.
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</p>
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{{code "/doc/progs/interface2.go" `/START f4/` `/STOP/`}}
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<p>
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If you run this code, it will panic with the cryptic message
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</p>
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<pre>
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panic: reflect.Value.SetFloat using unaddressable value
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</pre>
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<p>
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The problem is not that the value <code>7.1</code> is not
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addressable; it's that <code>v</code> is not settable. Settability
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is a property of a reflection <code>Value</code>, and not all
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reflection <code>Values</code> have it.
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</p>
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<p>
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The <code>CanSet</code> method of <code>Value</code> reports the
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settability of a <code>Value</code>; in our case,
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</p>
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{{code "/doc/progs/interface2.go" `/START f5/` `/STOP/`}}
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<p>
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prints
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</p>
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<pre>
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settability of v: false
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</pre>
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<p>
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It is an error to call a <code>Set</code> method on an non-settable
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<code>Value</code>. But what is settability?
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</p>
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<p>
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Settability is a bit like addressability, but stricter. It's the
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property that a reflection object can modify the actual storage
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that was used to create the reflection object. Settability is
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determined by whether the reflection object holds the original
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item. When we say
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</p>
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{{code "/doc/progs/interface2.go" `/START f6/` `/STOP/`}}
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<p>
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we pass a <em>copy</em> of <code>x</code> to
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<code>reflect.ValueOf</code>, so the interface value created as the
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argument to <code>reflect.ValueOf</code> is a <em>copy</em> of
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<code>x</code>, not <code>x</code> itself. Thus, if the
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statement
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</p>
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{{code "/doc/progs/interface2.go" `/START f6b/` `/STOP/`}}
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<p>
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were allowed to succeed, it would not update <code>x</code>, even
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though <code>v</code> looks like it was created from
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<code>x</code>. Instead, it would update the copy of <code>x</code>
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stored inside the reflection value and <code>x</code> itself would
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be unaffected. That would be confusing and useless, so it is
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illegal, and settability is the property used to avoid this
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issue.
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</p>
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<p>
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If this seems bizarre, it's not. It's actually a familiar situation
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in unusual garb. Think of passing <code>x</code> to a
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function:
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</p>
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<pre>
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f(x)
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</pre>
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<p>
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We would not expect <code>f</code> to be able to modify
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<code>x</code> because we passed a copy of <code>x</code>'s value,
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not <code>x</code> itself. If we want <code>f</code> to modify
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<code>x</code> directly we must pass our function the address of
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<code>x</code> (that is, a pointer to <code>x</code>):</p>
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<p>
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<code>f(&x)</code>
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</p>
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<p>
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This is straightforward and familiar, and reflection works the same
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way. If we want to modify <code>x</code> by reflection, we must
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give the reflection library a pointer to the value we want to
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modify.
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</p>
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<p>
|
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Let's do that. First we initialize <code>x</code> as usual
|
|
and then create a reflection value that points to it, called
|
|
<code>p</code>.
|
|
</p>
|
|
|
|
{{code "/doc/progs/interface2.go" `/START f7/` `/STOP/`}}
|
|
|
|
<p>
|
|
The output so far is
|
|
</p>
|
|
|
|
<pre>
|
|
type of p: *float64
|
|
settability of p: false
|
|
</pre>
|
|
|
|
<p>
|
|
The reflection object <code>p</code> isn't settable, but it's not
|
|
<code>p</code> we want to set, it's (in effect) <code>*p</code>. To
|
|
get to what <code>p</code> points to, we call the <code>Elem</code>
|
|
method of <code>Value</code>, which indirects through the pointer,
|
|
and save the result in a reflection <code>Value</code> called
|
|
<code>v</code>:
|
|
</p>
|
|
|
|
{{code "/doc/progs/interface2.go" `/START f7b/` `/STOP/`}}
|
|
|
|
<p>
|
|
Now <code>v</code> is a settable reflection object, as the output
|
|
demonstrates,
|
|
</p>
|
|
|
|
<pre>
|
|
settability of v: true
|
|
</pre>
|
|
|
|
<p>
|
|
and since it represents <code>x</code>, we are finally able to use
|
|
<code>v.SetFloat</code> to modify the value of
|
|
<code>x</code>:
|
|
</p>
|
|
|
|
{{code "/doc/progs/interface2.go" `/START f7c/` `/STOP/`}}
|
|
|
|
<p>
|
|
The output, as expected, is
|
|
</p>
|
|
|
|
<pre>
|
|
7.1
|
|
7.1
|
|
</pre>
|
|
|
|
<p>
|
|
Reflection can be hard to understand but it's doing exactly what
|
|
the language does, albeit through reflection <code>Types</code> and
|
|
<code>Values</code> that can disguise what's going on. Just keep in
|
|
mind that reflection Values need the address of something in order
|
|
to modify what they represent.
|
|
</p>
|
|
|
|
<p><b>Structs</b></p>
|
|
|
|
<p>
|
|
In our previous example <code>v</code> wasn't a pointer itself, it
|
|
was just derived from one. A common way for this situation to arise
|
|
is when using reflection to modify the fields of a structure. As
|
|
long as we have the address of the structure, we can modify its
|
|
fields.
|
|
</p>
|
|
|
|
<p>
|
|
Here's a simple example that analyzes a struct value, <code>t</code>. We create
|
|
the reflection object with the address of the struct because we'll want to
|
|
modify it later. Then we set <code>typeOfT</code> to its type and iterate over
|
|
the fields using straightforward method calls
|
|
(see <a href="/pkg/reflect/">package reflect</a> for details).
|
|
Note that we extract the names of the fields from the struct type, but the
|
|
fields themselves are regular <code>reflect.Value</code> objects.
|
|
</p>
|
|
|
|
{{code "/doc/progs/interface2.go" `/START f8/` `/STOP/`}}
|
|
|
|
<p>
|
|
The output of this program is
|
|
</p>
|
|
|
|
<pre>
|
|
0: A int = 23
|
|
1: B string = skidoo
|
|
</pre>
|
|
|
|
<p>
|
|
There's one more point about settability introduced in
|
|
passing here: the field names of <code>T</code> are upper case
|
|
(exported) because only exported fields of a struct are
|
|
settable.
|
|
</p>
|
|
|
|
<p>
|
|
Because <code>s</code> contains a settable reflection object, we
|
|
can modify the fields of the structure.
|
|
</p>
|
|
|
|
{{code "/doc/progs/interface2.go" `/START f8b/` `/STOP/`}}
|
|
|
|
<p>
|
|
And here's the result:
|
|
</p>
|
|
|
|
<pre>
|
|
t is now {77 Sunset Strip}
|
|
</pre>
|
|
|
|
<p>
|
|
If we modified the program so that <code>s</code> was created from
|
|
<code>t</code>, not <code>&t</code>, the calls to
|
|
<code>SetInt</code> and <code>SetString</code> would fail as the
|
|
fields of <code>t</code> would not be settable.
|
|
</p>
|
|
|
|
<p><b>Conclusion</b></p>
|
|
|
|
<p>
|
|
Here again are the laws of reflection:
|
|
</p>
|
|
|
|
<ol>
|
|
<li>Reflection goes from interface value to reflection
|
|
object.</li>
|
|
<li>Reflection goes from reflection object to interface
|
|
value.</li>
|
|
<li>To modify a reflection object, the value must be settable.</li>
|
|
</ol>
|
|
|
|
<p>
|
|
Once you understand these laws reflection in Go becomes much easier
|
|
to use, although it remains subtle. It's a powerful tool that
|
|
should be used with care and avoided unless strictly
|
|
necessary.
|
|
</p>
|
|
|
|
<p>
|
|
There's plenty more to reflection that we haven't covered —
|
|
sending and receiving on channels, allocating memory, using slices
|
|
and maps, calling methods and functions — but this post is
|
|
long enough. We'll cover some of those topics in a later
|
|
article.
|
|
</p>
|