2010-11-11 Jakub Jelinek <jakub@redhat.com>
[official-gcc.git] / gcc / ada / s-stausa.ads
blob1cd78ea0465136a47d43fc94f111e30d12363be7
1 ------------------------------------------------------------------------------
2 -- --
3 -- GNU ADA RUN-TIME LIBRARY (GNARL) COMPONENTS --
4 -- --
5 -- S Y S T E M - S T A C K _ U S A G E --
6 -- --
7 -- S p e c --
8 -- --
9 -- Copyright (C) 2004-2010, Free Software Foundation, Inc. --
10 -- --
11 -- GNARL is free software; you can redistribute it and/or modify it under --
12 -- terms of the GNU General Public License as published by the Free Soft- --
13 -- ware Foundation; either version 3, or (at your option) any later ver- --
14 -- sion. GNAT is distributed in the hope that it will be useful, but WITH- --
15 -- OUT ANY WARRANTY; without even the implied warranty of MERCHANTABILITY --
16 -- or FITNESS FOR A PARTICULAR PURPOSE. --
17 -- --
18 -- As a special exception under Section 7 of GPL version 3, you are granted --
19 -- additional permissions described in the GCC Runtime Library Exception, --
20 -- version 3.1, as published by the Free Software Foundation. --
21 -- --
22 -- You should have received a copy of the GNU General Public License and --
23 -- a copy of the GCC Runtime Library Exception along with this program; --
24 -- see the files COPYING3 and COPYING.RUNTIME respectively. If not, see --
25 -- <http://www.gnu.org/licenses/>. --
26 -- --
27 -- GNARL was developed by the GNARL team at Florida State University. --
28 -- Extensive contributions were provided by Ada Core Technologies, Inc. --
29 -- --
30 ------------------------------------------------------------------------------
32 with System;
33 with System.Storage_Elements;
34 with System.Address_To_Access_Conversions;
35 with Interfaces;
37 package System.Stack_Usage is
38 pragma Preelaborate;
40 package SSE renames System.Storage_Elements;
42 subtype Stack_Address is SSE.Integer_Address;
43 -- Address on the stack
45 function To_Stack_Address
46 (Value : System.Address) return Stack_Address
47 renames System.Storage_Elements.To_Integer;
49 Task_Name_Length : constant := 32;
50 -- The maximum length of task name displayed.
51 -- ??? Consider merging this variable with Max_Task_Image_Length.
53 type Task_Result is record
54 Task_Name : String (1 .. Task_Name_Length);
56 Value : Natural;
57 -- Amount of stack used. The value is calculated on the basis of the
58 -- mechanism used by GNAT to allocate it, and it is NOT a precise value.
60 Variation : Natural;
61 -- Possible variation in the amount of used stack. The real stack usage
62 -- may vary in the range Value +/- Variation
64 Max_Size : Natural;
65 end record;
67 type Result_Array_Type is array (Positive range <>) of Task_Result;
69 type Stack_Analyzer is private;
70 -- Type of the stack analyzer tool. It is used to fill a portion of the
71 -- stack with Pattern, and to compute the stack used after some execution.
73 -- Usage:
75 -- A typical use of the package is something like:
77 -- A : Stack_Analyzer;
79 -- task T is
80 -- pragma Storage_Size (A_Storage_Size);
81 -- end T;
83 -- [...]
85 -- Bottom_Of_Stack : aliased Integer;
86 -- -- Bottom_Of_Stack'Address will be used as an approximation of
87 -- -- the bottom of stack. A good practise is to avoid allocating
88 -- -- other local variables on this stack, as it would degrade
89 -- -- the quality of this approximation.
91 -- begin
92 -- Initialize_Analyzer (A,
93 -- "Task t",
94 -- A_Storage_Size - A_Guard,
95 -- A_Guard
96 -- To_Stack_Address (Bottom_Of_Stack'Address));
97 -- Fill_Stack (A);
98 -- Some_User_Code;
99 -- Compute_Result (A);
100 -- Report_Result (A);
101 -- end T;
103 -- Errors:
105 -- We are instrumenting the code to measure the stack used by the user
106 -- code. This method has a number of systematic errors, but several methods
107 -- can be used to evaluate or reduce those errors. Here are those errors
108 -- and the strategy that we use to deal with them:
110 -- Bottom offset:
112 -- Description: The procedure used to fill the stack with a given
113 -- pattern will itself have a stack frame. The value of the stack
114 -- pointer in this procedure is, therefore, different from the value
115 -- before the call to the instrumentation procedure.
117 -- Strategy: The user of this package should measure the bottom of stack
118 -- before the call to Fill_Stack and pass it in parameter.
120 -- Instrumentation threshold at writing:
122 -- Description: The procedure used to fill the stack with a given
123 -- pattern will itself have a stack frame. Therefore, it will
124 -- fill the stack after this stack frame. This part of the stack will
125 -- appear as used in the final measure.
127 -- Strategy: As the user passes the value of the bottom of stack to
128 -- the instrumentation to deal with the bottom offset error, and as
129 -- the instrumentation procedure knows where the pattern filling start
130 -- on the stack, the difference between the two values is the minimum
131 -- stack usage that the method can measure. If, when the results are
132 -- computed, the pattern zone has been left untouched, we conclude
133 -- that the stack usage is inferior to this minimum stack usage.
135 -- Instrumentation threshold at reading:
137 -- Description: The procedure used to read the stack at the end of the
138 -- execution clobbers the stack by allocating its stack frame. If this
139 -- stack frame is bigger than the total stack used by the user code at
140 -- this point, it will increase the measured stack size.
142 -- Strategy: We could augment this stack frame and see if it changes the
143 -- measure. However, this error should be negligible.
145 -- Pattern zone overflow:
147 -- Description: The stack grows outer than the topmost bound of the
148 -- pattern zone. In that case, the topmost region modified in the
149 -- pattern is not the maximum value of the stack pointer during the
150 -- execution.
152 -- Strategy: At the end of the execution, the difference between the
153 -- topmost memory region modified in the pattern zone and the
154 -- topmost bound of the pattern zone can be understood as the
155 -- biggest allocation that the method could have detect, provided
156 -- that there is no "Untouched allocated zone" error and no "Pattern
157 -- usage in user code" error. If no object in the user code is likely
158 -- to have this size, this is not likely to happen.
160 -- Pattern usage in user code:
162 -- Description: The pattern can be found in the object of the user code.
163 -- Therefore, the address space where this object has been allocated
164 -- will appear as untouched.
166 -- Strategy: Choose a pattern that is uncommon. 16#0000_0000# is the
167 -- worst choice; 16#DEAD_BEEF# can be a good one. A good choice is an
168 -- address which is not a multiple of 2, and which is not in the
169 -- target address space. You can also change the pattern to see if it
170 -- changes the measure. Note that this error *very* rarely influence
171 -- the measure of the total stack usage: to have some influence, the
172 -- pattern has to be used in the object that has been allocated on the
173 -- topmost address of the used stack.
175 -- Stack overflow:
177 -- Description: The pattern zone does not fit on the stack. This may
178 -- lead to an erroneous execution.
180 -- Strategy: Specify a storage size that is bigger than the size of the
181 -- pattern. 2 times bigger should be enough.
183 -- Augmentation of the user stack frames:
185 -- Description: The use of instrumentation object or procedure may
186 -- augment the stack frame of the caller.
188 -- Strategy: Do *not* inline the instrumentation procedures. Do *not*
189 -- allocate the Stack_Analyzer object on the stack.
191 -- Untouched allocated zone:
193 -- Description: The user code may allocate objects that it will never
194 -- touch. In that case, the pattern will not be changed.
196 -- Strategy: There are no way to detect this error. Fortunately, this
197 -- error is really rare, and it is most probably a bug in the user
198 -- code, e.g. some uninitialized variable. It is (most of the time)
199 -- harmless: it influences the measure only if the untouched allocated
200 -- zone happens to be located at the topmost value of the stack
201 -- pointer for the whole execution.
203 procedure Initialize (Buffer_Size : Natural);
204 pragma Export (C, Initialize, "__gnat_stack_usage_initialize");
205 -- Initializes the size of the buffer that stores the results. Only the
206 -- first Buffer_Size results are stored. Any results that do not fit in
207 -- this buffer will be displayed on the fly.
209 procedure Fill_Stack (Analyzer : in out Stack_Analyzer);
210 -- Fill an area of the stack with the pattern Analyzer.Pattern. The size
211 -- of this area is Analyzer.Size. After the call to this procedure,
212 -- the memory will look like that:
214 -- Stack growing
215 -- ----------------------------------------------------------------------->
216 -- |<---------------------->|<----------------------------------->|
217 -- | Stack frame | Memory filled with Analyzer.Pattern |
218 -- | of Fill_Stack | |
219 -- | (deallocated at | |
220 -- | the end of the call) | |
221 -- ^ | ^
222 -- Analyzer.Bottom_Of_Stack | Analyzer.Top_Pattern_Mark
223 -- ^
224 -- Analyzer.Bottom_Pattern_Mark
227 procedure Initialize_Analyzer
228 (Analyzer : in out Stack_Analyzer;
229 Task_Name : String;
230 My_Stack_Size : Natural;
231 Max_Pattern_Size : Natural;
232 Bottom : Stack_Address;
233 Top : Stack_Address;
234 Pattern : Interfaces.Unsigned_32 := 16#DEAD_BEEF#);
235 -- Should be called before any use of a Stack_Analyzer, to initialize it.
236 -- Max_Pattern_Size is the size of the pattern zone, might be smaller than
237 -- the full stack size in order to take into account e.g. the secondary
238 -- stack and a guard against overflow. The actual size taken will be
239 -- readjusted with data already used at the time the stack is actually
240 -- filled.
242 Is_Enabled : Boolean := False;
243 -- When this flag is true, then stack analysis is enabled
245 procedure Compute_Result (Analyzer : in out Stack_Analyzer);
246 -- Read the pattern zone and deduce the stack usage. It should be called
247 -- from the same frame as Fill_Stack. If Analyzer.Probe is not null, an
248 -- array of Unsigned_32 with Analyzer.Probe elements is allocated on
249 -- Compute_Result's stack frame. Probe can be used to detect the error:
250 -- "instrumentation threshold at reading". See above. After the call
251 -- to this procedure, the memory will look like:
253 -- Stack growing
254 -- ----------------------------------------------------------------------->
255 -- |<---------------------->|<-------------->|<--------->|<--------->|
256 -- | Stack frame | Array of | used | Memory |
257 -- | of Compute_Result | Analyzer.Probe | during | filled |
258 -- | (deallocated at | elements | the | with |
259 -- | the end of the call) | | execution | pattern |
260 -- | ^ | | |
261 -- | Bottom_Pattern_Mark | | |
262 -- | | |
263 -- |<----------------------------------------------------> |
264 -- Stack used ^
265 -- Top_Pattern_Mark
267 procedure Report_Result (Analyzer : Stack_Analyzer);
268 -- Store the results of the computation in memory, at the address
269 -- corresponding to the symbol __gnat_stack_usage_results. This is not
270 -- done inside Compute_Result in order to use as less stack as possible
271 -- within a task.
273 procedure Output_Results;
274 -- Print the results computed so far on the standard output. Should be
275 -- called when all tasks are dead.
277 pragma Export (C, Output_Results, "__gnat_stack_usage_output_results");
279 private
281 package Unsigned_32_Addr is
282 new System.Address_To_Access_Conversions (Interfaces.Unsigned_32);
284 subtype Pattern_Type is Interfaces.Unsigned_32;
285 Bytes_Per_Pattern : constant := Pattern_Type'Object_Size / Storage_Unit;
287 type Stack_Analyzer is record
288 Task_Name : String (1 .. Task_Name_Length);
289 -- Name of the task
291 Stack_Size : Natural;
292 -- Entire size of the analyzed stack
294 Pattern_Size : Natural;
295 -- Size of the pattern zone
297 Pattern : Pattern_Type;
298 -- Pattern used to recognize untouched memory
300 Bottom_Pattern_Mark : Stack_Address;
301 -- Bound of the pattern area on the stack closest to the bottom
303 Top_Pattern_Mark : Stack_Address;
304 -- Topmost bound of the pattern area on the stack
306 Topmost_Touched_Mark : Stack_Address;
307 -- Topmost address of the pattern area whose value it is pointing
308 -- at has been modified during execution. If the systematic error are
309 -- compensated, it is the topmost value of the stack pointer during
310 -- the execution.
312 Bottom_Of_Stack : Stack_Address;
313 -- Address of the bottom of the stack, as given by the caller of
314 -- Initialize_Analyzer.
316 Stack_Overlay_Address : System.Address;
317 -- Address of the stack abstraction object we overlay over a
318 -- task's real stack, typically a pattern-initialized array.
320 Result_Id : Positive;
321 -- Id of the result. If less than value given to gnatbind -u corresponds
322 -- to the location in the result array of result for the current task.
323 end record;
325 Environment_Task_Analyzer : Stack_Analyzer;
327 Compute_Environment_Task : Boolean;
329 type Result_Array_Ptr is access all Result_Array_Type;
331 Result_Array : Result_Array_Ptr;
332 pragma Export (C, Result_Array, "__gnat_stack_usage_results");
333 -- Exported in order to have an easy accessible symbol in when debugging
335 Next_Id : Positive := 1;
336 -- Id of the next stack analyzer
338 function Stack_Size
339 (SP_Low : Stack_Address;
340 SP_High : Stack_Address) return Natural;
341 pragma Inline (Stack_Size);
342 -- Return the size of a portion of stack delimited by SP_High and SP_Low
343 -- (), i.e. the difference between SP_High and SP_Low. The storage element
344 -- pointed by SP_Low is not included in the size. Inlined to reduce the
345 -- size of the stack used by the instrumentation code.
347 end System.Stack_Usage;