307 lines
13 KiB
Plaintext
307 lines
13 KiB
Plaintext
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.\" Copyright (c) 1982, 1993
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.\" The Regents of the University of California. All rights reserved.
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.\"
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.\" Redistribution and use in source and binary forms, with or without
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.\" modification, are permitted provided that the following conditions
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.\" are met:
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.\" 1. Redistributions of source code must retain the above copyright
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.\" notice, this list of conditions and the following disclaimer.
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.\" 2. Redistributions in binary form must reproduce the above copyright
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.\" notice, this list of conditions and the following disclaimer in the
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.\" documentation and/or other materials provided with the distribution.
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.\" 3. All advertising materials mentioning features or use of this software
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.\" must display the following acknowledgement:
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.\" This product includes software developed by the University of
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.\" California, Berkeley and its contributors.
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.\" 4. Neither the name of the University nor the names of its contributors
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.\" may be used to endorse or promote products derived from this software
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.\" without specific prior written permission.
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.\"
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.\" THIS SOFTWARE IS PROVIDED BY THE REGENTS AND CONTRIBUTORS ``AS IS'' AND
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.\" ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE
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.\" IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR PURPOSE
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.\" ARE DISCLAIMED. IN NO EVENT SHALL THE REGENTS OR CONTRIBUTORS BE LIABLE
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.\" FOR ANY DIRECT, INDIRECT, INCIDENTAL, SPECIAL, EXEMPLARY, OR CONSEQUENTIAL
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.\" DAMAGES (INCLUDING, BUT NOT LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS
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.\" OR SERVICES; LOSS OF USE, DATA, OR PROFITS; OR BUSINESS INTERRUPTION)
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.\" HOWEVER CAUSED AND ON ANY THEORY OF LIABILITY, WHETHER IN CONTRACT, STRICT
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.\" LIABILITY, OR TORT (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY
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.\" OUT OF THE USE OF THIS SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF
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.\" SUCH DAMAGE.
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.\"
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.\" @(#)present.me 8.1 (Berkeley) 6/8/93
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.\"
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.sh 1 "Data Presentation"
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.pp
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The data is presented to the user in two different formats.
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The first presentation simply lists the routines
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without regard to the amount of time their descendants use.
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The second presentation incorporates the call graph of the
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program.
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.sh 2 "The Flat Profile
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.pp
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The flat profile consists of a list of all the routines
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that are called during execution of the program,
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with the count of the number of times they are called
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and the number of seconds of execution time for which they
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are themselves accountable.
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The routines are listed in decreasing order of execution time.
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A list of the routines that are never called during execution of
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the program is also available
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to verify that nothing important is omitted by
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this execution.
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The flat profile gives a quick overview of the routines that are used,
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and shows the routines that are themselves responsible
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for large fractions of the execution time.
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In practice,
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this profile usually shows that no single function
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is overwhelmingly responsible for
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the total time of the program.
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Notice that for this profile,
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the individual times sum to the total execution time.
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.sh 2 "The Call Graph Profile"
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.sz 10
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.(z
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.TS
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box center;
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c c c c c l l
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c c c c c l l
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c c c c c l l
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l n n n c l l.
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called/total \ \ parents
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index %time self descendants called+self name index
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called/total \ \ children
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_
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0.20 1.20 4/10 \ \ \s-1CALLER1\s+1 [7]
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0.30 1.80 6/10 \ \ \s-1CALLER2\s+1 [1]
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[2] 41.5 0.50 3.00 10+4 \s-1EXAMPLE\s+1 [2]
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1.50 1.00 20/40 \ \ \s-1SUB1\s+1 <cycle1> [4]
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0.00 0.50 1/5 \ \ \s-1SUB2\s+1 [9]
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0.00 0.00 0/5 \ \ \s-1SUB3\s+1 [11]
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.TE
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.ce 2
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Profile entry for \s-1EXAMPLE\s+1.
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Figure 4.
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.)z
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.pp
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Ideally, we would like to print the call graph of the program,
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but we are limited by the two-dimensional nature of our output
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devices.
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We cannot assume that a call graph is planar,
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and even if it is, that we can print a planar version of it.
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Instead, we choose to list each routine,
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together with information about
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the routines that are its direct parents and children.
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This listing presents a window into the call graph.
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Based on our experience,
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both parent information and child information
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is important,
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and should be available without searching
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through the output.
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.pp
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The major entries of the call graph profile are the entries from the
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flat profile, augmented by the time propagated to each
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routine from its descendants.
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This profile is sorted by the sum of the time for the routine
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itself plus the time inherited from its descendants.
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The profile shows which of the higher level routines
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spend large portions of the total execution time
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in the routines that they call.
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For each routine, we show the amount of time passed by each child
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to the routine, which includes time for the child itself
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and for the descendants of the child
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(and thus the descendants of the routine).
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We also show the percentage these times represent of the total time
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accounted to the child.
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Similarly, the parents of each routine are listed,
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along with time,
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and percentage of total routine time,
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propagated to each one.
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.pp
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Cycles are handled as single entities.
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The cycle as a whole is shown as though it were a single routine,
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except that members of the cycle are listed in place of the children.
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Although the number of calls of each member
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from within the cycle are shown,
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they do not affect time propagation.
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When a child is a member of a cycle,
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the time shown is the appropriate fraction of the time
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for the whole cycle.
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Self-recursive routines have their calls broken
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down into calls from the outside and self-recursive calls.
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Only the outside calls affect the propagation of time.
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.pp
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The following example is a typical fragment of a call graph.
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.(b
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.so pres1.pic
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.)b
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The entry in the call graph profile listing for this example is
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shown in Figure 4.
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.pp
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The entry is for routine \s-1EXAMPLE\s+1, which has
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the Caller routines as its parents,
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and the Sub routines as its children.
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The reader should keep in mind that all information
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is given \fIwith respect to \s-1EXAMPLE\s+1\fP.
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The index in the first column shows that \s-1EXAMPLE\s+1
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is the second entry in the profile listing.
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The \s-1EXAMPLE\s+1 routine is called ten times, four times by \s-1CALLER1\s+1,
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and six times by \s-1CALLER2\s+1.
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Consequently 40% of \s-1EXAMPLE\s+1's time is propagated to \s-1CALLER1\s+1,
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and 60% of \s-1EXAMPLE\s+1's time is propagated to \s-1CALLER2\s+1.
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The self and descendant fields of the parents
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show the amount of self and descendant time \s-1EXAMPLE\s+1
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propagates to them (but not the time used by
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the parents directly).
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Note that \s-1EXAMPLE\s+1 calls itself recursively four times.
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The routine \s-1EXAMPLE\s+1 calls routine \s-1SUB1\s+1 twenty times, \s-1SUB2\s+1 once,
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and never calls \s-1SUB3\s+1.
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Since \s-1SUB2\s+1 is called a total of five times,
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20% of its self and descendant time is propagated to \s-1EXAMPLE\s+1's
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descendant time field.
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Because \s-1SUB1\s+1 is a member of \fIcycle 1\fR,
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the self and descendant times
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and call count fraction
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are those for the cycle as a whole.
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Since cycle 1 is called a total of forty times
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(not counting calls among members of the cycle),
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it propagates 50% of the cycle's self and descendant
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time to \s-1EXAMPLE\s+1's descendant time field.
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Finally each name is followed by an index that shows
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where on the listing to find the entry for that routine.
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.sh 1 "Using the Profiles"
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.pp
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The profiler is a useful tool for improving
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a set of routines that implement an abstraction.
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It can be helpful in identifying poorly coded routines,
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and in evaluating the new algorithms and code that replace them.
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Taking full advantage of the profiler
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requires a careful examination of the call graph profile,
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and a thorough knowledge of the abstractions underlying
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the program.
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.pp
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The easiest optimization that can be performed
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is a small change
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to a control construct or data structure that improves the
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running time of the program.
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An obvious starting point
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is a routine that is called many times.
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For example, suppose an output
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routine is the only parent
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of a routine that formats the data.
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If this format routine is expanded inline in the
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output routine, the overhead of a function call and
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return can be saved for each datum that needs to be formatted.
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.pp
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The drawback to inline expansion is that the data abstractions
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in the program may become less parameterized,
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hence less clearly defined.
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The profiling will also become less useful since the loss of
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routines will make its output more granular.
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For example,
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if the symbol table functions ``lookup'', ``insert'', and ``delete''
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are all merged into a single parameterized routine,
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it will be impossible to determine the costs
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of any one of these individual functions from the profile.
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.pp
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Further potential for optimization lies in routines that
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implement data abstractions whose total execution
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time is long.
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For example, a lookup routine might be called only a few
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times, but use an inefficient linear search algorithm,
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that might be replaced with a binary search.
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Alternately, the discovery that a rehashing function is being
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called excessively, can lead to a different
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hash function or a larger hash table.
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If the data abstraction function cannot easily be speeded up,
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it may be advantageous to cache its results,
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and eliminate the need to rerun
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it for identical inputs.
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These and other ideas for program improvement are discussed in
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[Bentley81].
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.pp
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This tool is best used in an iterative approach:
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profiling the program,
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eliminating one bottleneck,
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then finding some other part of the program
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that begins to dominate execution time.
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For instance, we have used \fBgprof\fR on itself;
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eliminating, rewriting, and inline expanding routines,
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until reading
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data files (hardly a target for optimization!)
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represents the dominating factor in its execution time.
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.pp
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Certain types of programs are not easily analyzed by \fBgprof\fR.
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They are typified by programs that exhibit a large degree of
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recursion, such as recursive descent compilers.
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The problem is that most of the major routines are grouped
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into a single monolithic cycle.
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As in the symbol table abstraction that is placed
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in one routine,
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it is impossible to distinguish which members of the cycle are
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responsible for the execution time.
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Unfortunately there are no easy modifications to these programs that
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make them amenable to analysis.
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.pp
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A completely different use of the profiler is to analyze the control
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flow of an unfamiliar program.
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If you receive a program from another user that you need to modify
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in some small way,
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it is often unclear where the changes need to be made.
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By running the program on an example and then using \fBgprof\fR,
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you can get a view of the structure of the program.
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.pp
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Consider an example in which you need to change the output format
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of the program.
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For purposes of this example suppose that the call graph
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of the output portion of the program has the following structure:
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.(b
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.so pres2.pic
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.)b
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Initially you look through the \fBgprof\fR
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output for the system call ``\s-1WRITE\s+1''.
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The format routine you will need to change is probably
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among the parents of the ``\s-1WRITE\s+1'' procedure.
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The next step is to look at the profile entry for each
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of parents of ``\s-1WRITE\s+1'',
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in this example either ``\s-1FORMAT1\s+1'' or ``\s-1FORMAT2\s+1'',
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to determine which one to change.
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Each format routine will have one or more parents,
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in this example ``\s-1CALC1\s+1'', ``\s-1CALC2\s+1'', and ``\s-1CALC3\s+1''.
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By inspecting the source code for each of these routines
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you can determine which format routine generates the output that
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you wish to modify.
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Since the \fBgprof\fR entry shows all the
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potential calls to the format routine you intend to change,
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you can determine if your modifications will affect output that
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should be left alone.
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If you desire to change the output of ``\s-1CALC2\s+1'', but not ``\s-1CALC3\s+1'',
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then formatting routine ``\s-1FORMAT2\s+1'' needs to be split
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into two separate routines,
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one of which implements the new format.
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You can then retarget just the call by ``\s-1CALC2\s+1''
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that needs the new format.
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It should be noted that the static call information is particularly
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useful here since the test case you run probably will not
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exercise the entire program.
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.sh 1 "Conclusions"
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.pp
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We have created a profiler that aids in the evaluation
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of modular programs.
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For each routine in the program,
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the profile shows the extent to which that routine
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helps support various abstractions,
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and how that routine uses other abstractions.
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The profile accurately assesses the cost of routines
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at all levels of the program decomposition.
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The profiler is easily used,
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and can be compiled into the program without any prior planning by
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the programmer.
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It adds only five to thirty percent execution overhead to the program
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being profiled,
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produces no additional output until after the program finishes,
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and allows the program to be measured in its actual environment.
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Finally, the profiler runs on a time-sharing system
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using only the normal services provided by the operating system
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and compilers.
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