_content/lib/godoc/analysis/help.html - website - Git at Google

 <!--{
         "Title": "Static analysis features of godoc"
 }-->

 <style>
   span.err { 'font-size:120%; color:darkred; background-color: yellow; }
   img.ss { margin-left: 1in; } /* screenshot */
   img.dotted { border: thin dotted; }
 </style>

 <!-- Images were grabbed from Chrome/Linux at 150% zoom, and are
      displayed at 66% of natural size.  This allows users to zoom a
      little before seeing pixels. -->

 <p>
   When invoked with the <code>-analysis</code> flag, godoc performs
   static analysis on the Go packages it indexes and displays the
   results in the source and package views.  This document provides a
   brief tour of these features.
 </p>

 <h2>Type analysis features</h2>
 <p>
   <code>godoc -analysis=type</code> performs static checking similar
   to that done by a compiler: it detects ill-formed programs, resolves
   each identifier to the entity it denotes, computes the type of each
   expression and the method set of each type, and determines which
   types are assignable to each interface type.

   <b>Type analysis</b> is relatively quick, requiring about 10 seconds for
   the &gt;200 packages of the standard library, for example.
 </p>

 <h3>Compiler errors</h3>
 <p>
   If any source file contains a compilation error, the source view
   will highlight the errant location in red.  Hovering over it
   displays the error message.
 </p>
 <img class="ss" width='811' src='error1.png'><br/>

 <h3>Identifier resolution</h3>
 <p>
   In the source view, every referring identifier is annotated with
   information about the language entity it refers to: a package,
   constant, variable, type, function or statement label.

   Hovering over the identifier reveals the entity's kind and type
   (e.g. <code>var x int</code> or <code>func f
   func(int) string</code>).
 </p>
 <img class="ss" width='652' src='ident-field.png'><br/>
 <br/>
 <img class="ss" width='652' src='ident-func.png'>
 <p>
   Clicking the link takes you to the entity's definition.
 </p>
 <img class="ss" width='652' src='ident-def.png'><br/>

 <h3>Type information: size/alignment, method set, interfaces</h3>
 <p>
   Clicking on the identifier that defines a named type causes a panel
   to appear, displaying information about the named type, including
   its size and alignment in bytes, its
   <a href="/ref/spec#Method_sets">method set</a>, and its
   <i>implements</i> relation: the set of types T that are assignable to
   or from this type U where at least one of T or U is an interface.

   This example shows information about <code>net/rpc.methodType</code>.
 </p>
 <img class="ss" width='470' src='typeinfo-src.png'>
 <p>
   The method set includes not only the declared methods of the type,
   but also any methods "promoted" from anonymous fields of structs,
   such as <code>sync.Mutex</code> in this example.

   In addition, the receiver type is displayed as <code>*T</code> or
   <code>T</code> depending on whether it requires the address or just
   a copy of the receiver value.
 </p>
 <p>
   The method set and <i>implements</i> relation are also available
   via the package view.
 </p>
 <img class="ss dotted" width='716' src='typeinfo-pkg.png'>

 <h2>Pointer analysis features</h2>
 <p>
   <code>godoc -analysis=pointer</code> additionally performs a precise
   whole-program <b>pointer analysis</b>.  In other words, it
   approximates the set of memory locations to which each
   reference&mdash;not just vars of kind <code>*T</code>, but also
   <code>[]T</code>, <code>func</code>, <code>map</code>,
   <code>chan</code>, and <code>interface</code>&mdash;may refer.  This
   information reveals the possible destinations of each dynamic call
   (via a <code>func</code> variable or interface method), and the
   relationship between send and receive operations on the same
   channel.
 </p>
 <p>
   Compared to type analysis, pointer analysis requires more time and
   memory, and is impractical for code bases exceeding a million lines.
 </p>

 <h3>Call graph navigation</h3>
 <p>
   When pointer analysis is complete, the source view annotates the
   code with <b>callers</b> and <b>callees</b> information: callers
   information is associated with the <code>func</code> keyword that
   declares a function, and callees information is associated with the
   open paren '<span style="color: darkblue"><code>(</code></span>' of
   a function call.
 </p>
 <p>
   In this example, hovering over the declaration of the
   <code>rot13</code> function (defined in strings/strings_test.go)
   reveals that it is called in exactly one place.
 </p>
 <img class="ss" width='612' src='callers1.png'>
 <p>
   Clicking the link navigates to the sole caller.  (If there were
   multiple callers, a list of choices would be displayed first.)
 </p>
 <img class="ss" width='680' src='callers2.png'>
 <p>
   Notice that hovering over this call reveals that there are 19
   possible callees at this site, of which our <code>rot13</code>
   function was just one: this is a dynamic call through a variable of
   type <code>func(rune) rune</code>.

   Clicking on the call brings up the list of all 19 potential callees,
   shown truncated.  Many of them are anonymous functions.
 </p>
 <img class="ss" width='564' src='call3.png'>
 <p>
   Pointer analysis gives a very precise approximation of the call
   graph compared to type-based techniques.

   As a case in point, the next example shows the dynamic call inside
   the <code>testing</code> package responsible for calling all
   user-defined functions named <code>Example<i>XYZ</i></code>.
 </p>
 <img class="ss" width='361' src='call-eg.png'>
 <p>
   Recall that all such functions have type <code>func()</code>,
   i.e. no arguments and no results.  A type-based approximation could
   only conclude that this call might dispatch to any function matching
   that type&mdash;and these are very numerous in most
   programs&mdash;but pointer analysis can track the flow of specific
   <code>func</code> values through the testing package.

   As an indication of its precision, the result contains only
   functions whose name starts with <code>Example</code>.
 </p>

 <h3>Intra-package call graph</h3>
 <p>
   The same call graph information is presented in a very different way
   in the package view.  For each package, an interactive tree view
   allows exploration of the call graph as it relates to just that
   package; all functions from other packages are elided.

   The roots of the tree are the external entry points of the package:
   not only its exported functions, but also any unexported or
   anonymous functions that are called (dynamically) from outside the
   package.
 </p>
 <p>
   This example shows the entry points of the
   <code>path/filepath</code> package, with the call graph for
   <code>Glob</code> expanded several levels
 </p>
 <img class="ss dotted" width='501' src='ipcg-pkg.png'>
 <p>
   Notice that the nodes for Glob and Join appear multiple times: the
   tree is a partial unrolling of a cyclic graph; the full unrolling
   is in general infinite.
 </p>
 <p>
   For each function documented in the package view, another
   interactive tree view allows exploration of the same graph starting
   at that function.

   This is a portion of the internal graph of
   <code>net/http.ListenAndServe</code>.
 </p>
 <img class="ss dotted" width='455' src='ipcg-func.png'>

 <h3>Channel peers (send ↔ receive)</h3>
 <p>
   Because concurrent Go programs use channels to pass not just values
   but also control between different goroutines, it is natural when
   reading Go code to want to navigate from a channel send to the
   corresponding receive so as to understand the sequence of events.
 </p>
 <p>
   Godoc annotates every channel operation&mdash;make, send, range,
   receive, close&mdash;with a link to a panel displaying information
   about other operations that might alias the same channel.
 </p>
 <p>
   This example, from the tests of <code>net/http</code>, shows a send
   operation on a <code>chan bool</code>.
 </p>
 <img class="ss" width='811' src='chan1.png'>
 <p>
   Clicking on the <code>&lt;-</code> send operator reveals that this
   channel is made at a unique location (line 332) and that there are
   three receive operations that might read this value.

   It hardly needs pointing out that some channel element types are
   very widely used (e.g. struct{}, bool, int, interface{}) and that a
   typical Go program might contain dozens of receive operations on a
   value of type <code>chan bool</code>; yet the pointer analysis is
   able to distinguish operations on channels at a much finer precision
   than based on their type alone.
 </p>
 <p>
   Notice also that the send occurs in a different (anonymous) function
   from the outer one containing the <code>make</code> and the receive
   operations.
 </p>
 <p>
   Here's another example of send on a different <code>chan
   bool</code>, also in package <code>net/http</code>:
 </p>
 <img class="ss" width='774' src='chan2a.png'>
 <p>
   The analysis finds just one receive operation that might receive
   from this channel, in the test for this feature.
 </p>
 <img class="ss" width='737' src='chan2b.png'>

 <h2>Known issues</h2>
 <p>
   All analysis results pertain to exactly
   one configuration (e.g. amd64 linux).  Files that are conditionally
   compiled based on different platforms or build tags are not visible
   to the analysis.
 </p>
 <p>
   Files that <code>import "C"</code> require
   preprocessing by the cgo tool.  The file offsets after preprocessing
   do not align with the unpreprocessed file, so markup is misaligned.
 </p>
 <p>
   Files are not periodically re-analyzed.
   If the files change underneath the running server, the displayed
   markup is misaligned.
 </p>
 <p>
   Additional issues are listed at
   <a href='https://go.googlesource.com/tools/+/master/godoc/analysis/README'>tools/godoc/analysis/README</a>.
 </p>
	<!--{
	"Title": "Static analysis features of godoc"
	}-->

	<style>
	span.err { 'font-size:120%; color:darkred; background-color: yellow; }
	img.ss { margin-left: 1in; } /* screenshot */
	img.dotted { border: thin dotted; }
	</style>

	<!-- Images were grabbed from Chrome/Linux at 150% zoom, and are
	displayed at 66% of natural size. This allows users to zoom a
	little before seeing pixels. -->

	<p>
	When invoked with the <code>-analysis</code> flag, godoc performs
	static analysis on the Go packages it indexes and displays the
	results in the source and package views. This document provides a
	brief tour of these features.
	</p>

	<h2>Type analysis features</h2>
	<p>
	<code>godoc -analysis=type</code> performs static checking similar
	to that done by a compiler: it detects ill-formed programs, resolves
	each identifier to the entity it denotes, computes the type of each
	expression and the method set of each type, and determines which
	types are assignable to each interface type.

	<b>Type analysis</b> is relatively quick, requiring about 10 seconds for
	the >200 packages of the standard library, for example.
	</p>

	<h3>Compiler errors</h3>
	<p>
	If any source file contains a compilation error, the source view
	will highlight the errant location in red. Hovering over it
	displays the error message.
	</p>
	<img class="ss" width='811' src='error1.png'><br/>

	<h3>Identifier resolution</h3>
	<p>
	In the source view, every referring identifier is annotated with
	information about the language entity it refers to: a package,
	constant, variable, type, function or statement label.

	Hovering over the identifier reveals the entity's kind and type
	(e.g. <code>var x int</code> or <code>func f
	func(int) string</code>).
	</p>
	<img class="ss" width='652' src='ident-field.png'><br/>
	<br/>
	<img class="ss" width='652' src='ident-func.png'>
	<p>
	Clicking the link takes you to the entity's definition.
	</p>
	<img class="ss" width='652' src='ident-def.png'><br/>

	<h3>Type information: size/alignment, method set, interfaces</h3>
	<p>
	Clicking on the identifier that defines a named type causes a panel
	to appear, displaying information about the named type, including
	its size and alignment in bytes, its
	<a href="/ref/spec#Method_sets">method set</a>, and its
	<i>implements</i> relation: the set of types T that are assignable to
	or from this type U where at least one of T or U is an interface.

	This example shows information about <code>net/rpc.methodType</code>.
	</p>
	<img class="ss" width='470' src='typeinfo-src.png'>
	<p>
	The method set includes not only the declared methods of the type,
	but also any methods "promoted" from anonymous fields of structs,
	such as <code>sync.Mutex</code> in this example.

	In addition, the receiver type is displayed as <code>*T</code> or
	<code>T</code> depending on whether it requires the address or just
	a copy of the receiver value.
	</p>
	<p>
	The method set and <i>implements</i> relation are also available
	via the package view.
	</p>
	<img class="ss dotted" width='716' src='typeinfo-pkg.png'>

	<h2>Pointer analysis features</h2>
	<p>
	<code>godoc -analysis=pointer</code> additionally performs a precise
	whole-program <b>pointer analysis</b>. In other words, it
	approximates the set of memory locations to which each
	reference—not just vars of kind <code>*T</code>, but also
	<code>[]T</code>, <code>func</code>, <code>map</code>,
	<code>chan</code>, and <code>interface</code>—may refer. This
	information reveals the possible destinations of each dynamic call
	(via a <code>func</code> variable or interface method), and the
	relationship between send and receive operations on the same
	channel.
	</p>
	<p>
	Compared to type analysis, pointer analysis requires more time and
	memory, and is impractical for code bases exceeding a million lines.
	</p>

	<h3>Call graph navigation</h3>
	<p>
	When pointer analysis is complete, the source view annotates the
	code with <b>callers</b> and <b>callees</b> information: callers
	information is associated with the <code>func</code> keyword that
	declares a function, and callees information is associated with the
	open paren '<span style="color: darkblue"><code>(</code></span>' of
	a function call.
	</p>
	<p>
	In this example, hovering over the declaration of the
	<code>rot13</code> function (defined in strings/strings_test.go)
	reveals that it is called in exactly one place.
	</p>
	<img class="ss" width='612' src='callers1.png'>
	<p>
	Clicking the link navigates to the sole caller. (If there were
	multiple callers, a list of choices would be displayed first.)
	</p>
	<img class="ss" width='680' src='callers2.png'>
	<p>
	Notice that hovering over this call reveals that there are 19
	possible callees at this site, of which our <code>rot13</code>
	function was just one: this is a dynamic call through a variable of
	type <code>func(rune) rune</code>.

	Clicking on the call brings up the list of all 19 potential callees,
	shown truncated. Many of them are anonymous functions.
	</p>
	<img class="ss" width='564' src='call3.png'>
	<p>
	Pointer analysis gives a very precise approximation of the call
	graph compared to type-based techniques.

	As a case in point, the next example shows the dynamic call inside
	the <code>testing</code> package responsible for calling all
	user-defined functions named <code>Example<i>XYZ</i></code>.
	</p>
	<img class="ss" width='361' src='call-eg.png'>
	<p>
	Recall that all such functions have type <code>func()</code>,
	i.e. no arguments and no results. A type-based approximation could
	only conclude that this call might dispatch to any function matching
	that type—and these are very numerous in most
	programs—but pointer analysis can track the flow of specific
	<code>func</code> values through the testing package.

	As an indication of its precision, the result contains only
	functions whose name starts with <code>Example</code>.
	</p>

	<h3>Intra-package call graph</h3>
	<p>
	The same call graph information is presented in a very different way
	in the package view. For each package, an interactive tree view
	allows exploration of the call graph as it relates to just that
	package; all functions from other packages are elided.

	The roots of the tree are the external entry points of the package:
	not only its exported functions, but also any unexported or
	anonymous functions that are called (dynamically) from outside the
	package.
	</p>
	<p>
	This example shows the entry points of the
	<code>path/filepath</code> package, with the call graph for
	<code>Glob</code> expanded several levels
	</p>
	<img class="ss dotted" width='501' src='ipcg-pkg.png'>
	<p>
	Notice that the nodes for Glob and Join appear multiple times: the
	tree is a partial unrolling of a cyclic graph; the full unrolling
	is in general infinite.
	</p>
	<p>
	For each function documented in the package view, another
	interactive tree view allows exploration of the same graph starting
	at that function.

	This is a portion of the internal graph of
	<code>net/http.ListenAndServe</code>.
	</p>
	<img class="ss dotted" width='455' src='ipcg-func.png'>

	<h3>Channel peers (send ↔ receive)</h3>
	<p>
	Because concurrent Go programs use channels to pass not just values
	but also control between different goroutines, it is natural when
	reading Go code to want to navigate from a channel send to the
	corresponding receive so as to understand the sequence of events.
	</p>
	<p>
	Godoc annotates every channel operation—make, send, range,
	receive, close—with a link to a panel displaying information
	about other operations that might alias the same channel.
	</p>
	<p>
	This example, from the tests of <code>net/http</code>, shows a send
	operation on a <code>chan bool</code>.
	</p>
	<img class="ss" width='811' src='chan1.png'>
	<p>
	Clicking on the <code><-</code> send operator reveals that this
	channel is made at a unique location (line 332) and that there are
	three receive operations that might read this value.

	It hardly needs pointing out that some channel element types are
	very widely used (e.g. struct{}, bool, int, interface{}) and that a
	typical Go program might contain dozens of receive operations on a
	value of type <code>chan bool</code>; yet the pointer analysis is
	able to distinguish operations on channels at a much finer precision
	than based on their type alone.
	</p>
	<p>
	Notice also that the send occurs in a different (anonymous) function
	from the outer one containing the <code>make</code> and the receive
	operations.
	</p>
	<p>
	Here's another example of send on a different <code>chan
	bool</code>, also in package <code>net/http</code>:
	</p>
	<img class="ss" width='774' src='chan2a.png'>
	<p>
	The analysis finds just one receive operation that might receive
	from this channel, in the test for this feature.
	</p>
	<img class="ss" width='737' src='chan2b.png'>

	<h2>Known issues</h2>
	<p>
	All analysis results pertain to exactly
	one configuration (e.g. amd64 linux). Files that are conditionally
	compiled based on different platforms or build tags are not visible
	to the analysis.
	</p>
	<p>
	Files that <code>import "C"</code> require
	preprocessing by the cgo tool. The file offsets after preprocessing
	do not align with the unpreprocessed file, so markup is misaligned.
	</p>
	<p>
	Files are not periodically re-analyzed.
	If the files change underneath the running server, the displayed
	markup is misaligned.
	</p>
	<p>
	Additional issues are listed at
	<a href='https://go.googlesource.com/tools/+/master/godoc/analysis/README'>tools/godoc/analysis/README</a>.
	</p>