forked from OSchip/llvm-project
587 lines
29 KiB
HTML
Executable File
587 lines
29 KiB
HTML
Executable File
<!DOCTYPE html PUBLIC "-//W3C//DTD XHTML 1.0 Transitional//EN" "http://www.w3.org/TR/xhtml1/DTD/xhtml1-transitional.dtd">
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<html xmlns="http://www.w3.org/1999/xhtml">
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<head>
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<meta http-equiv="Content-Type" content="text/html; charset=iso-8859-1" />
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<link href="style.css" rel="stylesheet" type="text/css" />
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<title>LLDB Example - Python Scripting to Debug a Problem</title>
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</head>
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<body>
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<div class="www_title">
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Example - Using Scripting and Python to Debug in LLDB
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</div>
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<div id="container">
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<div id="content">
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<!--#include virtual="sidebar.incl"-->
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<div id="middle">
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<div class="post">
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<h1 class ="postheader">Introduction</h1>
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<div class="postcontent">
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<p>LLDB has been structured from the beginning to be scriptable in two ways
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-- a Unix Python session can initiate/run a debug session non-interactively
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using LLDB; and within the LLDB debugger tool, Python scripts can be used to
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help with many tasks, including inspecting program data, iterating over
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containers and determining if a breakpoint should stop execution or continue.
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This document will show how to do some of these things by going through an
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example, explaining how to use Python scripting to find a bug in a program
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that searches for text in a large binary tree.</p>
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</div>
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<div class="postfooter"></div>
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<div class="post">
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<h1 class ="postheader">The Test Program and Input</h1>
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<div class="postcontent">
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<p>We have a simple C program (dictionary.c) that reads in a text file, and
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stores all the words from the file in a Binary Search Tree, sorted
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alphabetically. It then enters a loop prompting the user for a word, searching
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for the word in the tree (using Binary Search), and reporting to the user
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whether or not it found the word in the tree.</p>
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<p>The input text file we are using to test our program contains the text for
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William Shakespeare's famous tragedy "Romeo and Juliet".</p>
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</div>
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<div class="postfooter"></div>
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<div class="post">
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<h1 class ="postheader">The Bug</h1>
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<div class="postcontent">
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<p>When we try running our program, we find there is a problem. While it
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successfully finds some of the words we would expect to find, such as "love"
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or "sun", it fails to find the word "Romeo", which MUST be in the input text
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file:</p>
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<code color=#ff0000>
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% ./dictionary Romeo-and-Juliet.txt<br>
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Dictionary loaded.<br>
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Enter search word: love<br>
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Yes!<br>
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Enter search word: sun<br>
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Yes!<br>
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Enter search word: Romeo<br>
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No!<br>
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Enter search word: ^D<br>
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%<br>
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</code>
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</div>
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<div class="postfooter"></div>
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<div class="post">
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<h1 class ="postheader">Is the word in our tree: Using Depth First Search</h1>
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<div class="postcontent">
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<p>Our first job is to determine if the word "Romeo" actually got inserted into
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the tree or not. Since "Romeo and Juliet" has thousands of words, trying to
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examine our binary search tree by hand is completely impractical. Therefore we
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will write a Python script to search the tree for us. We will write a recursive
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Depth First Search function that traverses the entire tree searching for a word,
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and maintaining information about the path from the root of the tree to the
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current node. If it finds the word in the tree, it returns the path from the
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root to the node containing the word. This is what our DFS function in Python
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would look like, with line numbers added for easy reference in later
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explanations:</p>
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<code>
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<pre><tt>
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1: def DFS (root, word, cur_path):
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2: root_word_ptr = root.GetChildMemberWithName ("word")
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3: left_child_ptr = root.GetChildMemberWithName ("left")
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4: right_child_ptr = root.GetChildMemberWithName ("right")
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5: root_word = root_word_ptr.GetSummary()
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6: end = len (root_word) - 1
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7: if root_word[0] == '"' and root_word[end] == '"':
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8: root_word = root_word[1:end]
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9: end = len (root_word) - 1
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10: if root_word[0] == '\'' and root_word[end] == '\'':
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11: root_word = root_word[1:end]
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12: if root_word == word:
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13: return cur_path
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14: elif word < root_word:
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15: if left_child_ptr.GetValue() == None:
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16: return ""
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17: else:
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18: cur_path = cur_path + "L"
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19: return DFS (left_child_ptr, word, cur_path)
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20: else:
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21: if right_child_ptr.GetValue() == None:
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22: return ""
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23: else:
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24: cur_path = cur_path + "R"
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25: return DFS (right_child_ptr, word, cur_path)
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</tt></pre>
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</code>
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</div>
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<div class="postfooter"></div>
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<div class="post">
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<h1 class ="postheader"><a name="accessing-variables">Accessing & Manipulating <strong>Program</strong> Variables in Python</a>
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</h1>
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<div class="postcontent">
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<p>Before we can call any Python function on any of our program's variables, we
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need to get the variable into a form that Python can access. To show you how to
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do this we will look at the parameters for the DFS function. The first
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parameter is going to be a node in our binary search tree, put into a Python
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variable. The second parameter is the word we are searching for (a string), and
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the third parameter is a string representing the path from the root of the tree
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to our current node.</p>
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<p>The most interesting parameter is the first one, the Python variable that
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needs to contain a node in our search tree. How can we take a variable out of
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our program and put it into a Python variable? What kind of Python variable
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will it be? The answers are to use the LLDB API functions, provided as part of
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the LLDB Python module. Running Python from inside LLDB, LLDB will
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automatically give us our current frame object as a Python variable,
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"lldb.frame". This variable has the type "SBFrame" (see the LLDB API for
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more information about SBFrame objects). One of the things we can do with a
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frame object, is to ask it to find and return its local variable. We will call
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the API function "FindVariable" on the lldb.frame object to give us our
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dictionary variable as a Python variable:</p>
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<code>
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root = lldb.frame.FindVariable ("dictionary")
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</code>
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<p>The line above, executed in the Python script interpreter in LLDB, asks the
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current frame to find the variable named "dictionary" and return it. We then
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store the returned value in the Python variable named "root". This answers the
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question of HOW to get the variable, but it still doesn't explain WHAT actually
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gets put into "root". If you examine the LLDB API, you will find that the
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SBFrame method "FindVariable" returns an object of type SBValue. SBValue
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objects are used, among other things, to wrap up program variables and values.
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There are many useful methods defined in the SBValue class to allow you to get
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information or children values out of SBValues. For complete information, see
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the header file <a href="http://llvm.org/svn/llvm-project/lldb/trunk/include/lldb/API/SBValue.h">SBValue.h</a>. The
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SBValue methods that we use in our DFS function are
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<code>GetChildMemberWithName()</code>,
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<code>GetSummary()</code>, and <code>GetValue()</code>.</p>
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</div>
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<div class="postfooter"></div>
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<div class="post">
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<h1 class ="postheader">Explaining Depth First Search Script in Detail</h1>
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<div class="postcontent">
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<p><strong>"DFS" Overview.</strong> Before diving into the details of this
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code, it would be best to give a high-level overview of what it does. The nodes
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in our binary search tree were defined to have type <code>tree_node *</code>,
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which is defined as:
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<code>
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<pre><tt>typedef struct tree_node
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{
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const char *word;
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struct tree_node *left;
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struct tree_node *right;
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} tree_node;</tt></pre></code>
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<p>Lines 2-11 of DFS are getting data out of the current tree node and getting
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ready to do the actual search; lines 12-25 are the actual depth-first search.
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Lines 2-4 of our DFS function get the <code>word</code>, <code>left</code> and
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<code>right</code> fields out of the current node and store them in Python
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variables. Since <code>root_word_ptr</code> is a pointer to our word, and we
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want the actual word, line 5 calls <code>GetSummary()</code> to get a string
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containing the value out of the pointer. Since <code>GetSummary()</code> adds
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quotes around its result, lines 6-11 strip surrounding quotes off the word.</p>
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<p>Line 12 checks to see if the word in the current node is the one we are
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searching for. If so, we are done, and line 13 returns the current path.
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Otherwise, line 14 checks to see if we should go left (search word comes before
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the current word). If we decide to go left, line 15 checks to see if the left
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pointer child is NULL ("None" is the Python equivalent of NULL). If the left
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pointer is NULL, then the word is not in this tree and we return an empty path
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(line 16). Otherwise, we add an "L" to the end of our current path string, to
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indicate we are going left (line 18), and then recurse on the left child (line
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19). Lines 20-25 are the same as lines 14-19, except for going right rather
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than going left.</p>
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<p>One other note: Typing something as long as our DFS function directly into
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the interpreter can be difficult, as making a single typing mistake means having
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to start all over. Therefore we recommend doing as we have done: Writing your
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longer, more complicated script functions in a separate file (in this case
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tree_utils.py) and then importing it into your LLDB Python interpreter.</p>
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</div>
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<div class="postfooter"></div>
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<div class="post">
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<h1 class ="postheader">Seeing the DFS Script in Action</h1>
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<div class="postcontent">
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<p>At this point we are ready to use the DFS function to see if the word "Romeo"
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is in our tree or not. To actually use it in LLDB on our dictionary program,
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you would do something like this:</p>
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<code>
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% <strong>lldb</strong><br>
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(lldb) <strong>process attach -n "dictionary"</strong><br>
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Architecture set to: x86_64.<br>
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Process 521 stopped<br>
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* thread #1: tid = 0x2c03, 0x00007fff86c8bea0 libSystem.B.dylib`read$NOCANCEL + 8, stop reason = signal SIGSTOP<br>
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frame #0: 0x00007fff86c8bea0 libSystem.B.dylib`read$NOCANCEL + 8<br>
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(lldb) <strong>breakpoint set -n find_word</strong><br>
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Breakpoint created: 1: name = 'find_word', locations = 1, resolved = 1<br>
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(lldb) <strong>continue</strong><br>
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Process 521 resuming<br>
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Process 521 stopped<br>
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* thread #1: tid = 0x2c03, 0x0000000100001830 dictionary`find_word + 16 <br>
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at dictionary.c:105, stop reason = breakpoint 1.1<br>
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frame #0: 0x0000000100001830 dictionary`find_word + 16 at dictionary.c:105<br>
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102 int<br>
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103 find_word (tree_node *dictionary, char *word)<br>
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104 {<br>
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-> 105 if (!word || !dictionary)<br>
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106 return 0;<br>
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107 <br>
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108 int compare_value = strcmp (word, dictionary->word);<br>
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(lldb) <strong>script</strong><br>
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Python Interactive Interpreter. To exit, type 'quit()', 'exit()' or Ctrl-D.<br>
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>>> <strong>import tree_utils</strong><br>
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>>> <strong>root = lldb.frame.FindVariable ("dictionary")</strong><br>
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>>> <strong>current_path = ""</strong><br>
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>>> <strong>path = tree_utils.DFS (root, "Romeo", current_path)</strong><br>
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>>> <strong>print path</strong><br>
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LLRRL<br>
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>>> <strong>^D</strong><br>
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(lldb) <br>
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</code>
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<p>The first bit of code above shows starting lldb, attaching to the dictionary
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program, and getting to the find_word function in LLDB. The interesting part
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(as far as this example is concerned) begins when we enter the
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<code>script</code> command and drop into the embedded interactive Python
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interpreter. We will go over this Python code line by line. The first line</p>
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<code>
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import tree_utils
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</code>
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<p>imports the file where we wrote our DFS function, tree_utils.py, into Python.
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Notice that to import the file we leave off the ".py" extension. We can now
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call any function in that file, giving it the prefix "tree_utils.", so that
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Python knows where to look for the function. The line</p>
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<code>
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root = lldb.frame.FindVariable ("dictionary")
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</code>
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<p>gets our program variable "dictionary" (which contains the binary search
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tree) and puts it into the Python variable "root". See
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<a href="#accessing-variables">Accessing & Manipulating Program Variables in Python</a>
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above for more details about how this works. The next line is</p>
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<code>
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current_path = ""
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</code>
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<p>This line initializes the current_path from the root of the tree to our
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current node. Since we are starting at the root of the tree, our current path
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starts as an empty string. As we go right and left through the tree, the DFS
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function will append an 'R' or an 'L' to the current path, as appropriate. The
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line</p>
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<code>
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path = tree_utils.DFS (root, "Romeo", current_path)
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</code>
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<p>calls our DFS function (prefixing it with the module name so that Python can
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find it). We pass in our binary tree stored in the variable <code>root</code>,
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the word we are searching for, and our current path. We assign whatever path
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the DFS function returns to the Python variable <code>path</code>.</p>
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<p>Finally, we want to see if the word was found or not, and if so we want to
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see the path through the tree to the word. So we do</p>
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<code>
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print path
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</code>
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<p>From this we can see that the word "Romeo" was indeed found in the tree, and
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the path from the root of the tree to the node containing "Romeo" is
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left-left-right-right-left.</p>
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</div>
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<div class="postfooter"></div>
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<div class="post">
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<h1 class ="postheader">What next? Using Breakpoint Command Scripts...</h1>
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<div class="postcontent">
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<p>We are halfway to figuring out what the problem is. We know the word we are
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looking for is in the binary tree, and we know exactly where it is in the binary
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tree. Now we need to figure out why our binary search algorithm is not finding
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the word. We will do this using breakpoint command scripts.</p>
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<p>The idea is as follows. The binary search algorithm has two main decision
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points: the decision to follow the right branch; and, the decision to follow
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the left branch. We will set a breakpoint at each of these decision points, and
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attach a Python breakpoint command script to each breakpoint. The breakpoint
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commands will use the global <code>path</code> Python variable that we got from
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our DFS function. Each time one of these decision breakpoints is hit, the script
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will compare the actual decision with the decision the front of the
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<code>path</code> variable says should be made (the first character of the
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path). If the actual decision and the path agree, then the front character is
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stripped off the path, and execution is resumed. In this case the user never
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even sees the breakpoint being hit. But if the decision differs from what the
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path says it should be, then the script prints out a message and does NOT resume
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execution, leaving the user sitting at the first point where a wrong decision is
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being made.</p>
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</div>
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<div class="postfooter"></div>
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<div class="post">
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<h1 class ="postheader">Side Note: Python Breakpoint Command Scripts are NOT What They Seem</h1>
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<div class="postcontent">
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</div>
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<div class="postfooter"></div>
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<p>What do we mean by that? When you enter a Python breakpoint command in LLDB,
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it appears that you are entering one or more plain lines of Python. BUT LLDB
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then takes what you entered and wraps it into a Python FUNCTION (just like using
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the "def" Python command). It automatically gives the function an obscure,
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unique, hard-to-stumble-across function name, and gives it two parameters:
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<code>frame</code> and <code>bp_loc</code>. When the breakpoint gets hit, LLDB
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wraps up the frame object where the breakpoint was hit, and the breakpoint
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location object for the breakpoint that was hit, and puts them into Python
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variables for you. It then calls the Python function that was created for the
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breakpoint command, and passes in the frame and breakpoint location objects.</p>
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<p>So, being practical, what does this mean for you when you write your Python
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breakpoint commands? It means that there are two things you need to keep in
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mind: 1. If you want to access any Python variables created outside your script,
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<strong>you must declare such variables to be global</strong>. If you do not
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declare them as global, then the Python function will treat them as local
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variables, and you will get unexpected behavior. 2. <strong>All Python
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breakpoint command scripts automatically have a <code>frame</code> and a
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<code>bp_loc</code> variable.</strong> The variables are pre-loaded by LLDB
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with the correct context for the breakpoint. You do not have to use these
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variables, but they are there if you want them.</p>
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</div>
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<div class="postfooter"></div>
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<div class="post">
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<h1 class ="postheader">The Decision Point Breakpoint Commands</h1>
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<div class="postcontent">
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<p>This is what the Python breakpoint command script would look like for the
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decision to go right:<p>
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<code><pre><tt>
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global path
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if path[0] == 'R':
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path = path[1:]
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thread = frame.GetThread()
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process = thread.GetProcess()
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process.Continue()
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else:
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print "Here is the problem; going right, should go left!"
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</tt></pre></code>
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<p>Just as a reminder, LLDB is going to take this script and wrap it up in a
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function, like this:</p>
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<code><pre><tt>
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def some_unique_and_obscure_function_name (frame, bp_loc):
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global path
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if path[0] == 'R':
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path = path[1:]
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thread = frame.GetThread()
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process = thread.GetProcess()
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process.Continue()
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else:
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print "Here is the problem; going right, should go left!"
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</tt></pre></code>
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<p>LLDB will call the function, passing in the correct frame and breakpoint
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location whenever the breakpoint gets hit. There are several things to notice
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about this function. The first one is that we are accessing and updating a
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piece of state (the <code>path</code> variable), and actually conditioning our
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behavior based upon this variable. Since the variable was defined outside of
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our script (and therefore outside of the corresponding function) we need to tell
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Python that we are accessing a global variable. That is what the first line of
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the script does. Next we check where the path says we should go and compare it to
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our decision (recall that we are at the breakpoint for the decision to go
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right). If the path agrees with our decision, then we strip the first character
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off of the path.</p>
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<p>Since the decision matched the path, we want to resume execution. To do this
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we make use of the <code>frame</code> parameter that LLDB guarantees will be
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there for us. We use LLDB API functions to get the current thread from the
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current frame, and then to get the process from the thread. Once we have the
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process, we tell it to resume execution (using the <code>Continue()</code> API
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function).</p>
|
|
|
|
<p>If the decision to go right does not agree with the path, then we do not
|
|
resume execution. We allow the breakpoint to remain stopped (by doing nothing),
|
|
and we print an informational message telling the user we have found the
|
|
problem, and what the problem is.</p>
|
|
|
|
</div>
|
|
<div class="postfooter"></div>
|
|
|
|
<div class="post">
|
|
<h1 class ="postheader">Actually Using the Breakpoint Commands</h1>
|
|
<div class="postcontent">
|
|
|
|
<p>Now we will look at what happens when we actually use these breakpoint
|
|
commands on our program. Doing a <code>source list -n find_word</code> shows
|
|
us the function containing our two decision points. Looking at the code below,
|
|
we see that we want to set our breakpoints on lines 113 and 115:</p>
|
|
|
|
<code><pre><tt>
|
|
(lldb) source list -n find_word
|
|
File: /Volumes/Data/HD2/carolinetice/Desktop/LLDB-Web-Examples/dictionary.c.
|
|
101
|
|
102 int
|
|
103 find_word (tree_node *dictionary, char *word)
|
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104 {
|
|
105 if (!word || !dictionary)
|
|
106 return 0;
|
|
107
|
|
108 int compare_value = strcmp (word, dictionary->word);
|
|
109
|
|
110 if (compare_value == 0)
|
|
111 return 1;
|
|
112 else if (compare_value < 0)
|
|
113 return find_word (dictionary->left, word);
|
|
114 else
|
|
115 return find_word (dictionary->right, word);
|
|
116 }
|
|
117
|
|
</tt></pre></code>
|
|
|
|
<p>So, we set our breakpoints, enter our breakpoint command scripts, and see
|
|
what happens:<p>
|
|
|
|
<code><pre><tt>
|
|
(lldb) breakpoint set -l 113
|
|
Breakpoint created: 2: file ='dictionary.c', line = 113, locations = 1, resolved = 1
|
|
(lldb) breakpoint set -l 115
|
|
Breakpoint created: 3: file ='dictionary.c', line = 115, locations = 1, resolved = 1
|
|
(lldb) breakpoint command add -s python 2
|
|
Enter your Python command(s). Type 'DONE' to end.
|
|
> global path
|
|
> if (path[0] == 'L'):
|
|
> path = path[1:]
|
|
> thread = frame.GetThread()
|
|
> process = thread.GetProcess()
|
|
> process.Continue()
|
|
> else:
|
|
> print "Here is the problem. Going left, should go right!"
|
|
> DONE
|
|
(lldb) breakpoint command add -s python 3
|
|
Enter your Python command(s). Type 'DONE' to end.
|
|
> global path
|
|
> if (path[0] == 'R'):
|
|
> path = path[1:]
|
|
> thread = frame.GetThread()
|
|
> process = thread.GetProcess()
|
|
> process.Continue()
|
|
> else:
|
|
> print "Here is the problem. Going right, should go left!"
|
|
> DONE
|
|
(lldb) continue
|
|
Process 696 resuming
|
|
Here is the problem. Going right, should go left!
|
|
Process 696 stopped
|
|
* thread #1: tid = 0x2d03, 0x000000010000189f dictionary`find_word + 127 at dictionary.c:115, stop reason = breakpoint 3.1
|
|
frame #0: 0x000000010000189f dictionary`find_word + 127 at dictionary.c:115
|
|
112 else if (compare_value < 0)
|
|
113 return find_word (dictionary->left, word);
|
|
114 else
|
|
-> 115 return find_word (dictionary->right, word);
|
|
116 }
|
|
117
|
|
118 void
|
|
(lldb)
|
|
</tt></pre></code>
|
|
|
|
|
|
<p>After setting our breakpoints, adding our breakpoint commands and continuing,
|
|
we run for a little bit and then hit one of our breakpoints, printing out the
|
|
error message from the breakpoint command. Apparently at this point the the
|
|
tree, our search algorithm decided to go right, but our path says the node we
|
|
want is to the left. Examining the word at the node where we stopped, and our
|
|
search word, we see:</p>
|
|
|
|
<code>
|
|
(lldb) expr dictionary->word<br>
|
|
(const char *) $1 = 0x0000000100100080 "dramatis"<br>
|
|
(lldb) expr word<br>
|
|
(char *) $2 = 0x00007fff5fbff108 "romeo"<br>
|
|
</code>
|
|
|
|
<p>So the word at our current node is "dramatis", and the word we are searching
|
|
for is "romeo". "romeo" comes after "dramatis" alphabetically, so it seems like
|
|
going right would be the correct decision. Let's ask Python what it thinks the
|
|
path from the current node to our word is:</p>
|
|
|
|
<code>
|
|
(lldb) script print path<br>
|
|
LLRRL<br>
|
|
</code>
|
|
|
|
<p>According to Python we need to go left-left-right-right-left from our current
|
|
node to find the word we are looking for. Let's double check our tree, and see
|
|
what word it has at that node:</p>
|
|
|
|
<code>
|
|
(lldb) expr dictionary->left->left->right->right->left->word<br>
|
|
(const char *) $4 = 0x0000000100100880 "Romeo"<br>
|
|
</code>
|
|
|
|
<p>So the word we are searching for is "romeo" and the word at our DFS location
|
|
is "Romeo". Aha! One is uppercase and the other is lowercase: We seem to have
|
|
a case conversion problem somewhere in our program (we do).</p>
|
|
|
|
<p>This is the end of our example on how you might use Python scripting in LLDB
|
|
to help you find bugs in your program.</p>
|
|
|
|
</div>
|
|
<div class="postfooter"></div>
|
|
|
|
<div class="post">
|
|
<h1 class ="postheader">Source Files for The Example</h1>
|
|
<div class="postcontent">
|
|
|
|
|
|
</div>
|
|
<div class="postfooter"></div>
|
|
|
|
<p> The complete code for the Dictionary program (with case-conversion bug),
|
|
the DFS function and other Python script examples (tree_utils.py) used for this
|
|
example are available via following file links:</p>
|
|
|
|
<a href="http://llvm.org/svn/llvm-project/lldb/trunk/examples/scripting/tree_utils.py">tree_utils.py</a> - Example Python functions using LLDB's API, including DFS<br>
|
|
<a href="http://llvm.org/svn/llvm-project/lldb/trunk/examples/scripting/dictionary.c">dictionary.c</a> - Sample dictionary program, with bug<br>
|
|
|
|
<p>The text for "Romeo and Juliet" can be obtained from the Gutenberg Project
|
|
(http://www.gutenberg.org).</p>
|
|
</div>
|
|
</div>
|
|
</div>
|
|
</div>
|
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</body>
|
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</html>
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