www/architecture.html - platform/external/lldb - Gitiles

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       The <strong>LLDB</strong> Debugger
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 	<div id="content">

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 			<div class="post">
 				<h1 class ="postheader">Architecture</h1>
 				<div class="postcontent">

 				   <p>LLDB is a large and complex codebase. This section will help you become more familiar with
 				       the pieces that make up LLDB and give a general overview of the general architecture.</p>
 				</div>
 				<div class="postfooter"></div>
 			</div>
 			<div class="post">
 				<h1 class ="postheader">Code Layout</h1>
 				<div class="postcontent">

 				   <p>LLDB has many code groupings that makeup the source base:</p>
                    <ul>
      					<li><a href="#api">API</a></li>
       					<li><a href="#breakpoint">Breakpoint</a></li>
       					<li><a href="#commands">Commands</a></li>
       					<li><a href="#core">Core</a></li>
       					<li><a href="#dataformatters">DataFormatters</a></li>
        					<li><a href="#expression">Expression</a></li>
        					<li><a href="#host">Host</a></li>
        					<li><a href="#interpreter">Interpreter</a></li>
        					<li><a href="#symbol">Symbol</a></li>
        					<li><a href="#targ">Target</a></li>
        					<li><a href="#utility">Utility</a></li>
    				    </ul>
 				</div>
 				<div class="postfooter"></div>
 			</div>
 			<a name="api"></a>
 			<div class="post">
 				<h1 class ="postheader">API</h1>
 				<div class="postcontent">

 				   <p>The API folder contains the public interface to LLDB.</p>
                    <p>We are currently vending a C++ API. In order to be able to add
   				        methods to this API and allow people to link to our classes,
   				        we have certain rules that we must follow:</p>
                    <ul>
      					<li>Classes can't inherit from any other classes.</li>
       					<li>Classes can't contain virtual methods.</li>
        					<li>Classes should be compatible with script bridging utilities like <a href="http://www.swig.org/">swig</a>.</li>
        					<li>Classes should be lightweight and be backed by a single member. Pointers (or shared pointers) are the preferred choice since they allow changing the contents of the backend without affecting the public object layout.</li>
        					<li>The interface should be as minimal as possible in order to give a complete API.</li>
    				    </ul>
    				    <p>By adhering to these rules we should be able to continue to
    				        vend a C++ API, and make changes to the API as any additional
    				        methods added to these classes will just be a dynamic loader
    				        lookup and they won't affect the class layout (since they
    				        aren't virtual methods, and no members can be added to the
    				        class).</p>
 				</div>
 				<div class="postfooter"></div>
 			</div>
 			<a name="breakpoint"></a>
 			<div class="post">
 				<h1 class ="postheader">Breakpoint</h1>
 				<div class="postcontent">

 				   <p>A collection of classes that implement our breakpoint classes.
 				       Breakpoints are resolved symbolically and always continue to
 				       resolve themselves as your program runs. Whether settings breakpoints
 				       by file and line, by symbol name, by symbol regular expression,
 				       or by address, breakpoints will keep trying to resolve new locations
 				       each time shared libraries are loaded. Breakpoints will of course
 				       unresolve themselves when shared libraries are unloaded. Breakpoints
 				       can also be scoped to be set only in a specific shared library. By
 				       default, breakpoints can be set in any shared library and will continue
 				       to attempt to be resolved with each shared library load.</p>
                    <p>Breakpoint options can be set on the breakpoint,
                        or on the individual locations. This allows flexibility when dealing
                        with breakpoints and allows us to do what the user wants.</p>
 				</div>
 				<div class="postfooter"></div>
 			</div>
 			<a name="commands"></a>
 			<div class="post">
 				<h1 class ="postheader">Commands</h1>
 				<div class="postcontent">

 				   <p>The command source files represent objects that implement
 				       the functionality for all textual commands available
 				       in our command line interface.</p>
                    <p>Every command is backed by a <b>lldb_private::CommandObject</b>
                        or <b>lldb_private::CommandObjectMultiword</b> object.</p>
                    <p><b>lldb_private::CommandObjectMultiword</b> are commands that
                       have subcommands and allow command line commands to be
                       logically grouped into a hierarchy.</p>
                   <p><b>lldb_private::CommandObject</b> command line commands
                       are the objects that implement the functionality of the
                       command. They can optionally define
                      options for themselves, as well as group those options into
                      logical groups that can go together. The help system is
                      tied into these objects and can extract the syntax and
                      option groupings to display appropriate help for each
                      command.</p>
 				</div>
 				<div class="postfooter"></div>
 			</div>
 			<a name="core"></a>
 			<div class="post">
 				<h1 class ="postheader">Core</h1>
 				<div class="postcontent">

 				   <p>The Core source files contain basic functionality that
 				       is required in the debugger. A wide variety of classes
 				       are implemented:</p>

                        <ul>
          					<li>Address (section offset addressing)</li>
           					<li>AddressRange</li>
            					<li>Architecture specification</li>
            					<li>Broadcaster / Event / Listener </li>
            					<li>Communication classes that use Connection objects</li>
            					<li>Uniqued C strings</li>
            					<li>Data extraction</li>
            					<li>File specifications</li>
            					<li>Mangled names</li>
            					<li>Regular expressions</li>
            					<li>Source manager</li>
            					<li>Streams</li>
            					<li>Value objects</li>
        				    </ul>
 				</div>
 				<div class="postfooter"></div>
 			</div>
 			<a name="dataformatters"></a>
 			<div class="post">
 				<h1 class ="postheader">DataFormatters</h1>
 				<div class="postcontent">

 				   <p>A collection of classes that implement the data formatters subsystem.</p>
 				<p>The main entry point for interacting with the LLDB data formatters is the DataVisualization class. It provides
 					a relatively stable front-end interface to ask questions of the data formatters regardless of the internal implementation.</p>
 				<p>For people actively maintaining the data formatters subsystem itself, however, the FormatManager class is the relevant point of entry.
 					This class is subject to more frequent changes as the formatters evolve. Currently, it provides a thin caching layer on top of a list of categories
 					that each export a group of formatters.
 					</p>
 				<p>From an end-user perspective, the "type" LLDB command is the point of access to the data formatters. A large group of generally-useful formatters
 					is provided by default and loaded upon debugger startup.
 				</div>
 				<div class="postfooter"></div>
 			</div>
 			<a name="expression"></a>
 			<div class="post">
 				<h1 class ="postheader">Expression</h1>
 				<div class="postcontent">

 				   <p>Expression parsing files cover everything from evaluating
 				       DWARF expressions, to evaluating expressions using
 				       Clang.</p>
 				   <p>The DWARF expression parser has been heavily modified to
 				       support type promotion, new opcodes needed for evaluating
 				       expressions with symbolic variable references (expression local variables,
 				       program variables), and other operators required by
 				       typical expressions such as assign, address of, float/double/long
 				       double floating point values, casting, and more. The
 				       DWARF expression parser uses a stack of lldb_private::Value
 				       objects. These objects know how to do the standard C type
 				       promotion, and allow for symbolic references to variables
 				       in the program and in the LLDB process (expression local
 				       and expression global variables).</p>
 				    <p>The expression parser uses a full instance of the Clang
 				        compiler in order to accurately evaluate expressions.
 				        Hooks have been put into Clang so that the compiler knows
 				        to ask about identifiers it doesn't know about. Once
 				        expressions have be compiled into an AST, we can then
 				        traverse this AST and either generate a DWARF expression
 				        that contains simple opcodes that can be quickly re-evaluated
 				        each time an expression needs to be evaluated, or JIT'ed
 				        up into code that can be run on the process being debugged.</p>
 				</div>
 				<div class="postfooter"></div>
 			</div>
 			<a name="host"></a>
 			<div class="post">
 				<h1 class ="postheader">Host</h1>
 				<div class="postcontent">

 				   <p>LLDB tries to abstract itself from the host upon which
 				       it is currently running by providing a host abstraction
 				       layer.  This layer involves everything from spawning, detaching,
 				       joining and killing native in-process threads, to getting
 				       current information about the current host.</p>
     				   <p>Host functionality includes abstraction layers for:</p>
                            <ul>
              					<li>Mutexes</li>
               					<li>Conditions</li>
                					<li>Timing functions</li>
                					<li>Thread functions</li>
                					<li>Host target triple</li>
                					<li>Host child process notifications</li>
                					<li>Host specific types</li>
            				    </ul>
 				</div>
 				<div class="postfooter"></div>
 			</div>
 			<a name="interpreter"></a>
 			<div class="post">
 				<h1 class ="postheader">Interpreter</h1>
 				<div class="postcontent">

 				   <p>The interpreter classes are the classes responsible for
 				       being the base classes needed for each command object,
 				       and is responsible for tracking and running command line
 				       commands.</p>
 				</div>
 				<div class="postfooter"></div>
 			</div>
 			<a name="symbol"></a>
 			<div class="post">
 				<h1 class ="postheader">Symbol</h1>
 				<div class="postcontent">
 				   <p>Symbol classes involve everything needed in order to parse
 				       object files and debug symbols. All the needed classes
 				       for compilation units (code and debug info for a source file),
 				       functions, lexical blocks within functions, inlined
 				       functions, types, declaration locations, and variables
 				       are in this section.</p>
 				</div>
 				<div class="postfooter"></div>
 			</div>
 			<a name="targ"></a>
 			<div class="post">
 				<h1 class ="postheader">Target</h1>
 				<div class="postcontent">

 				   <p>Classes that are related to a debug target include:</p>
                        <ul>
        					   <li>Target</li>
         					<li>Process</li>
          					<li>Thread</li>
           					<li>Stack frames</li>
           					<li>Stack frame registers</li>
            					<li>ABI for function calling in process being debugged</li>
            					<li>Execution context batons</li>
        				    </ul>
 				</div>
 				<div class="postfooter"></div>
 			</div>
 			<a name="utility"></a>
 			<div class="post">
 				<h1 class ="postheader">Utility</h1>
 				<div class="postcontent">

 				   <p>Utility files should be as stand alone as possible and
 				       available for LLDB, plug-ins or related
 				       applications to use.</p>
     				   <p>Files found in the Utility section include:</p>
                            <ul>
            					   <li>Pseudo-terminal support</li>
             					<li>Register numbering for specific architectures.</li>
              					<li>String data extractors</li>
            				    </ul>
 				</div>
 				<div class="postfooter"></div>
 			</div>
 		</div>
 	</div>
 </div>
 </body>
 </html>
	<!DOCTYPE html PUBLIC "-//W3C//DTD XHTML 1.0 Transitional//EN" "http://www.w3.org/TR/xhtml1/DTD/xhtml1-transitional.dtd">
	<html xmlns="http://www.w3.org/1999/xhtml">
	<head>
	<meta http-equiv="Content-Type" content="text/html; charset=iso-8859-1" />
	<link href="style.css" rel="stylesheet" type="text/css" />
	<title>LLDB Architecture</title>
	</head>

	<body>
	<div class="www_title">
	The <strong>LLDB</strong> Debugger
	</div>

	<div id="container">
	<div id="content">

	<!--#include virtual="sidebar.incl"-->

	<div id="middle">
	<div class="post">
	<h1 class ="postheader">Architecture</h1>
	<div class="postcontent">

	<p>LLDB is a large and complex codebase. This section will help you become more familiar with
	the pieces that make up LLDB and give a general overview of the general architecture.</p>
	</div>
	<div class="postfooter"></div>
	</div>
	<div class="post">
	<h1 class ="postheader">Code Layout</h1>
	<div class="postcontent">

	<p>LLDB has many code groupings that makeup the source base:</p>
	<ul>
	<li><a href="#api">API</a></li>
	<li><a href="#breakpoint">Breakpoint</a></li>
	<li><a href="#commands">Commands</a></li>
	<li><a href="#core">Core</a></li>
	<li><a href="#dataformatters">DataFormatters</a></li>
	<li><a href="#expression">Expression</a></li>
	<li><a href="#host">Host</a></li>
	<li><a href="#interpreter">Interpreter</a></li>
	<li><a href="#symbol">Symbol</a></li>
	<li><a href="#targ">Target</a></li>
	<li><a href="#utility">Utility</a></li>
	</ul>
	</div>
	<div class="postfooter"></div>
	</div>
	<a name="api"></a>
	<div class="post">
	<h1 class ="postheader">API</h1>
	<div class="postcontent">

	<p>The API folder contains the public interface to LLDB.</p>
	<p>We are currently vending a C++ API. In order to be able to add
	methods to this API and allow people to link to our classes,
	we have certain rules that we must follow:</p>
	<ul>
	<li>Classes can't inherit from any other classes.</li>
	<li>Classes can't contain virtual methods.</li>
	<li>Classes should be compatible with script bridging utilities like <a href="http://www.swig.org/">swig</a>.</li>
	<li>Classes should be lightweight and be backed by a single member. Pointers (or shared pointers) are the preferred choice since they allow changing the contents of the backend without affecting the public object layout.</li>
	<li>The interface should be as minimal as possible in order to give a complete API.</li>
	</ul>
	<p>By adhering to these rules we should be able to continue to
	vend a C++ API, and make changes to the API as any additional
	methods added to these classes will just be a dynamic loader
	lookup and they won't affect the class layout (since they
	aren't virtual methods, and no members can be added to the
	class).</p>
	</div>
	<div class="postfooter"></div>
	</div>
	<a name="breakpoint"></a>
	<div class="post">
	<h1 class ="postheader">Breakpoint</h1>
	<div class="postcontent">

	<p>A collection of classes that implement our breakpoint classes.
	Breakpoints are resolved symbolically and always continue to
	resolve themselves as your program runs. Whether settings breakpoints
	by file and line, by symbol name, by symbol regular expression,
	or by address, breakpoints will keep trying to resolve new locations
	each time shared libraries are loaded. Breakpoints will of course
	unresolve themselves when shared libraries are unloaded. Breakpoints
	can also be scoped to be set only in a specific shared library. By
	default, breakpoints can be set in any shared library and will continue
	to attempt to be resolved with each shared library load.</p>
	<p>Breakpoint options can be set on the breakpoint,
	or on the individual locations. This allows flexibility when dealing
	with breakpoints and allows us to do what the user wants.</p>
	</div>
	<div class="postfooter"></div>
	</div>
	<a name="commands"></a>
	<div class="post">
	<h1 class ="postheader">Commands</h1>
	<div class="postcontent">

	<p>The command source files represent objects that implement
	the functionality for all textual commands available
	in our command line interface.</p>
	<p>Every command is backed by a <b>lldb_private::CommandObject</b>
	or <b>lldb_private::CommandObjectMultiword</b> object.</p>
	<p><b>lldb_private::CommandObjectMultiword</b> are commands that
	have subcommands and allow command line commands to be
	logically grouped into a hierarchy.</p>
	<p><b>lldb_private::CommandObject</b> command line commands
	are the objects that implement the functionality of the
	command. They can optionally define
	options for themselves, as well as group those options into
	logical groups that can go together. The help system is
	tied into these objects and can extract the syntax and
	option groupings to display appropriate help for each
	command.</p>
	</div>
	<div class="postfooter"></div>
	</div>
	<a name="core"></a>
	<div class="post">
	<h1 class ="postheader">Core</h1>
	<div class="postcontent">

	<p>The Core source files contain basic functionality that
	is required in the debugger. A wide variety of classes
	are implemented:</p>

	<ul>
	<li>Address (section offset addressing)</li>
	<li>AddressRange</li>
	<li>Architecture specification</li>
	<li>Broadcaster / Event / Listener </li>
	<li>Communication classes that use Connection objects</li>
	<li>Uniqued C strings</li>
	<li>Data extraction</li>
	<li>File specifications</li>
	<li>Mangled names</li>
	<li>Regular expressions</li>
	<li>Source manager</li>
	<li>Streams</li>
	<li>Value objects</li>
	</ul>
	</div>
	<div class="postfooter"></div>
	</div>
	<a name="dataformatters"></a>
	<div class="post">
	<h1 class ="postheader">DataFormatters</h1>
	<div class="postcontent">

	<p>A collection of classes that implement the data formatters subsystem.</p>
	<p>The main entry point for interacting with the LLDB data formatters is the DataVisualization class. It provides
	a relatively stable front-end interface to ask questions of the data formatters regardless of the internal implementation.</p>
	<p>For people actively maintaining the data formatters subsystem itself, however, the FormatManager class is the relevant point of entry.
	This class is subject to more frequent changes as the formatters evolve. Currently, it provides a thin caching layer on top of a list of categories
	that each export a group of formatters.
	</p>
	<p>From an end-user perspective, the "type" LLDB command is the point of access to the data formatters. A large group of generally-useful formatters
	is provided by default and loaded upon debugger startup.
	</div>
	<div class="postfooter"></div>
	</div>
	<a name="expression"></a>
	<div class="post">
	<h1 class ="postheader">Expression</h1>
	<div class="postcontent">

	<p>Expression parsing files cover everything from evaluating
	DWARF expressions, to evaluating expressions using
	Clang.</p>
	<p>The DWARF expression parser has been heavily modified to
	support type promotion, new opcodes needed for evaluating
	expressions with symbolic variable references (expression local variables,
	program variables), and other operators required by
	typical expressions such as assign, address of, float/double/long
	double floating point values, casting, and more. The
	DWARF expression parser uses a stack of lldb_private::Value
	objects. These objects know how to do the standard C type
	promotion, and allow for symbolic references to variables
	in the program and in the LLDB process (expression local
	and expression global variables).</p>
	<p>The expression parser uses a full instance of the Clang
	compiler in order to accurately evaluate expressions.
	Hooks have been put into Clang so that the compiler knows
	to ask about identifiers it doesn't know about. Once
	expressions have be compiled into an AST, we can then
	traverse this AST and either generate a DWARF expression
	that contains simple opcodes that can be quickly re-evaluated
	each time an expression needs to be evaluated, or JIT'ed
	up into code that can be run on the process being debugged.</p>
	</div>
	<div class="postfooter"></div>
	</div>
	<a name="host"></a>
	<div class="post">
	<h1 class ="postheader">Host</h1>
	<div class="postcontent">

	<p>LLDB tries to abstract itself from the host upon which
	it is currently running by providing a host abstraction
	layer. This layer involves everything from spawning, detaching,
	joining and killing native in-process threads, to getting
	current information about the current host.</p>
	<p>Host functionality includes abstraction layers for:</p>
	<ul>
	<li>Mutexes</li>
	<li>Conditions</li>
	<li>Timing functions</li>
	<li>Thread functions</li>
	<li>Host target triple</li>
	<li>Host child process notifications</li>
	<li>Host specific types</li>
	</ul>
	</div>
	<div class="postfooter"></div>
	</div>
	<a name="interpreter"></a>
	<div class="post">
	<h1 class ="postheader">Interpreter</h1>
	<div class="postcontent">

	<p>The interpreter classes are the classes responsible for
	being the base classes needed for each command object,
	and is responsible for tracking and running command line
	commands.</p>
	</div>
	<div class="postfooter"></div>
	</div>
	<a name="symbol"></a>
	<div class="post">
	<h1 class ="postheader">Symbol</h1>
	<div class="postcontent">
	<p>Symbol classes involve everything needed in order to parse
	object files and debug symbols. All the needed classes
	for compilation units (code and debug info for a source file),
	functions, lexical blocks within functions, inlined
	functions, types, declaration locations, and variables
	are in this section.</p>
	</div>
	<div class="postfooter"></div>
	</div>
	<a name="targ"></a>
	<div class="post">
	<h1 class ="postheader">Target</h1>
	<div class="postcontent">

	<p>Classes that are related to a debug target include:</p>
	<ul>
	<li>Target</li>
	<li>Process</li>
	<li>Thread</li>
	<li>Stack frames</li>
	<li>Stack frame registers</li>
	<li>ABI for function calling in process being debugged</li>
	<li>Execution context batons</li>
	</ul>
	</div>
	<div class="postfooter"></div>
	</div>
	<a name="utility"></a>
	<div class="post">
	<h1 class ="postheader">Utility</h1>
	<div class="postcontent">

	<p>Utility files should be as stand alone as possible and
	available for LLDB, plug-ins or related
	applications to use.</p>
	<p>Files found in the Utility section include:</p>
	<ul>
	<li>Pseudo-terminal support</li>
	<li>Register numbering for specific architectures.</li>
	<li>String data extractors</li>
	</ul>
	</div>
	<div class="postfooter"></div>
	</div>
	</div>
	</div>
	</div>
	</body>
	</html>