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2 # This script contains two trivial examples of simple "scripted step" classes.
3 # To fully understand how the lldb "Thread Plan" architecture works, read the
4 # comments at the beginning of ThreadPlan.h in the lldb sources. The python
5 # interface is a reduced version of the full internal mechanism, but captures
6 # most of the power with a much simpler interface.
7 #
8 # But I'll attempt a brief summary here.
9 # Stepping in lldb is done independently for each thread. Moreover, the stepping
10 # operations are stackable. So for instance if you did a "step over", and in
11 # the course of stepping over you hit a breakpoint, stopped and stepped again,
12 # the first "step-over" would be suspended, and the new step operation would
13 # be enqueued. Then if that step over caused the program to hit another breakpoint,
14 # lldb would again suspend the second step and return control to the user, so
15 # now there are two pending step overs. Etc. with all the other stepping
16 # operations. Then if you hit "continue" the bottom-most step-over would complete,
17 # and another continue would complete the first "step-over".
18 #
19 # lldb represents this system with a stack of "Thread Plans". Each time a new
20 # stepping operation is requested, a new plan is pushed on the stack. When the
21 # operation completes, it is pushed off the stack.
22 #
23 # The bottom-most plan in the stack is the immediate controller of stepping,
24 # most importantly, when the process resumes, the bottom most plan will get
25 # asked whether to set the program running freely, or to instruction-single-step
26 # the current thread. In the scripted interface, you indicate this by returning
27 # False or True respectively from the should_step method.
28 #
29 # Each time the process stops the thread plan stack for each thread that stopped
30 # "for a reason", Ii.e. a single-step completed on that thread, or a breakpoint
31 # was hit), is queried to determine how to proceed, starting from the most
32 # recently pushed plan, in two stages:
33 #
34 # 1) Each plan is asked if it "explains" the stop. The first plan to claim the
35 # stop wins. In scripted Thread Plans, this is done by returning True from
36 # the "explains_stop method. This is how, for instance, control is returned
37 # to the User when the "step-over" plan hits a breakpoint. The step-over
38 # plan doesn't explain the breakpoint stop, so it returns false, and the
39 # breakpoint hit is propagated up the stack to the "base" thread plan, which
40 # is the one that handles random breakpoint hits.
41 #
42 # 2) Then the plan that won the first round is asked if the process should stop.
43 # This is done in the "should_stop" method. The scripted plans actually do
44 # three jobs in should_stop:
45 # a) They determine if they have completed their job or not. If they have
46 # they indicate that by calling SetPlanComplete on their thread plan.
47 # b) They decide whether they want to return control to the user or not.
48 # They do this by returning True or False respectively.
49 # c) If they are not done, they set up whatever machinery they will use
50 # the next time the thread continues.
51 #
52 # Note that deciding to return control to the user, and deciding your plan
53 # is done, are orthgonal operations. You could set up the next phase of
54 # stepping, and then return True from should_stop, and when the user next
55 # "continued" the process your plan would resume control. Of course, the
56 # user might also "step-over" or some other operation that would push a
57 # different plan, which would take control till it was done.
58 #
59 # One other detail you should be aware of, if the plan below you on the
60 # stack was done, then it will be popped and the next plan will take control
61 # and its "should_stop" will be called.
62 #
63 # Note also, there should be another method called when your plan is popped,
64 # to allow you to do whatever cleanup is required. I haven't gotten to that
65 # yet. For now you should do that at the same time you mark your plan complete.
66 #
67 # 3) After the round of negotiation over whether to stop or not is done, all the
68 # plans get asked if they are "stale". If they are say they are stale
69 # then they will get popped. This question is asked with the "is_stale" method.
70 #
71 # This is useful, for instance, in the FinishPrintAndContinue plan. What might
72 # happen here is that after continuing but before the finish is done, the program
73 # could hit another breakpoint and stop. Then the user could use the step
74 # command repeatedly until they leave the frame of interest by stepping.
75 # In that case, the step plan is the one that will be responsible for stopping,
76 # and the finish plan won't be asked should_stop, it will just be asked if it
77 # is stale. In this case, if the step_out plan that the FinishPrintAndContinue
78 # plan is driving is stale, so is ours, and it is time to do our printing.
79 #
80 # Both examples show stepping through an address range for 20 bytes from the
81 # current PC. The first one does it by single stepping and checking a condition.
82 # It doesn't, however handle the case where you step into another frame while
83 # still in the current range in the starting frame.
84 #
85 # That is better handled in the second example by using the built-in StepOverRange
86 # thread plan.
87 #
88 # To use these stepping modes, you would do:
89 #
90 # (lldb) command script import scripted_step.py
91 # (lldb) thread step-scripted -C scripted_step.SimpleStep
92 # or
93 #
94 # (lldb) thread step-scripted -C scripted_step.StepWithPlan
96 import lldb
106 # We are stepping, so if we stop for any other reason, it isn't
107 # because of us.
109 return True
111 return False
118 return True
120 return False
123 return True
135 # Since all I'm doing is running a plan, I will only ever get askedthis
136 # if myplan doesn't explain the stop, and in that caseI don'teither.
137 return False
142 return True
144 return False
147 return False
149 # Here's another example which does "step over" through the current function,
150 # and when it stops at each line, it checks some condition (in this example the
151 # value of a variable) and stops if that condition is true.
171 # We are stepping, so if we stop for any other reason, it isn't
172 # because of us.
173 return False
177 return False
182 return True
184 # This part checks the condition. In this case we are expecting
185 # some integer variable called "a", and will stop when it is 20.
190 return True
196 return True
200 return True
203 return False
206 return True
208 # Here's an example that steps out of the current frame, gathers some information
209 # and then continues. The information in this case is rax. Currently the thread
210 # plans are not a safe place to call lldb command-line commands, so the information
211 # is gathered through SB API calls.
225 return True
227 return False
230 return False
236 return False