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I have a question about sed efficiency in bash. I have a pipelined series of sed statements, e.g.:

var1="Some string of text"

var2=$(echo "$var1" | sed 's/pattern1/replacement1/g' | sed 's/pattern2/replacement2/g' | sed 's/pattern3/replacement3/g' | sed 's/pattern4/replacement4' | sed 's/pattern5/replacement5/g')

Assuming no inputs depend on edited output from an earlier sed pipe, am I better off scripting the above with expression statements instead? For example:

var2=$(echo "$var1" | sed -e's/pattern1/replacement1/g' -e's/pattern2/replacement2/g' -e's/pattern3/replacement3/g' -e's/pattern4/replacement4/g' -e's/pattern5/replacement5/g')

Is there any efficiency to be gained here?

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5 Answers 5

up vote 8 down vote accepted

Short Answer

Using multiple expressions will be faster than using multiple pipelines, because you there's additional overhead in creating pipelines and forking sed processes. However, it's rarely enough of a difference to matter in practice.


Using multiple expressions is faster than multiple pipelines, but probably not enough to matter for the average use case. Using your example, the average difference in execution speed was only two-thousandths of a second, which is not enough to get excited about.

# Average run with multiple pipelines.
$ time {
    echo "$var1" | 
    sed 's/pattern1/replacement1/g' |
    sed 's/pattern2/replacement2/g' |
    sed 's/pattern3/replacement3/g' |
    sed 's/pattern4/replacement4/g' |
    sed 's/pattern5/replacement5/g'
Some string of text

real        0m0.007s
user        0m0.000s
sys         0m0.004s

# Average run with multiple expressions.
$ time {
    echo "$var1" | sed \
    -e 's/pattern1/replacement1/g' \
    -e 's/pattern2/replacement2/g' \
    -e 's/pattern3/replacement3/g' \
    -e 's/pattern4/replacement4/g' \
    -e 's/pattern5/replacement5/g'
Some string of text

real        0m0.005s
user        0m0.000s
sys         0m0.000s

Granted, this isn't testing against a large input file, thousands of input files, or running in a loop with tens of thousands of iterations. Still, it seems safe to say that the difference is small enough to be irrelevant for most common situations.

Uncommon situations are a different story. In such cases, benchmarking will help you determine whether replacing pipes with in-line expressions is a valuable optimization for that use case.

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Thanks for the answer. –  Zack Jul 25 '12 at 4:40
N.B. /pattern/s//replacement/g is faster and more efficient. –  potong Jul 25 '12 at 6:17
@potong, I have no trouble imagining that /p/ s//r/g is faster than s/p/r/g (particularly if the input is a long string with many replacements and no line breaks) but on the other hand I also have no trouble imagining that s/p/r/g might be handled exactly like /p/ s//r/g, and also expect that if lines are short and several RE's intermixed it will make no practical difference. Do you have measurements to prove “faster and more efficient” claim, or a sed code snippet? –  jwpat7 Sep 16 '12 at 15:40

Most of the overhead in sed tends to be processing regular expressions but you're processing the same number of regular expressions in each of your examples.

Consider that the operating system needs to construct std and stdout for each element of the pipe. Sed also takes memory in your system, and the OS must allocate that memory for each instance of sed -- whether that's one instance or four.

Here's my assessment:

$ jot -r 1000000 1 10000 | time sed 's/1/_/g' | time sed 's/2/_/g' | time sed 's/3/_/g' | time sed 's/4/_/g' >/dev/null 
        2.38 real         0.84 user         0.01 sys
        2.38 real         0.84 user         0.01 sys
        2.39 real         0.85 user         0.01 sys
        2.39 real         0.85 user         0.01 sys
$ jot -r 1000000 1 10000 | time sed 's/1/_/g;s/2/_/g;s/3/_/g;s/4/_/g' >/dev/null
        2.71 real         2.57 user         0.02 sys
$ jot -r 1000000 1 10000 | time sed 's/1/_/g;s/2/_/g;s/3/_/g;s/4/_/g' >/dev/null
        2.71 real         2.56 user         0.02 sys
$ jot -r 1000000 1 10000 | time sed 's/1/_/g;s/2/_/g;s/3/_/g;s/4/_/g' >/dev/null
        2.71 real         2.57 user         0.02 sys
$ jot -r 1000000 1 10000 | time sed 's/1/_/g;s/2/_/g;s/3/_/g;s/4/_/g' >/dev/null
        2.74 real         2.57 user         0.02 sys
$ dc
.84 2* .85 2* + p

And since 3.38 > 2.57, les time is taken up if you use a single instance of sed.

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Yes. You'll avoid the overhead of starting sed anew each time.

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You can probably measure the efficiency to gauge the different. Perhaps using time command. Empirically, -e will be more efficient though.

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As noted in ghoti's answer, your examples have the same number of regular expressions in either case (separate invocations of sed vs a series of -e expressions), but OS overhead includes pipeline and process setup and memory allocation for each instance of sed. For a handful of invocations the OS overhead isn't be worth worrying about, but if the number is thousands or more, it might be.

Anyhow, computer efficiency aside, programmer efficiency often is a more important concern. Both ways shown so far are clumsy and slow to enter. It is easier (at least with GNU sed) to use a semicolon-separated sed command list instead of numerous separate -e strings. An example follows.

$ var1="Some p1 string p2 of p3 text p4 etc"
$ var2=$(echo "$var1" | sed 's/p1/a1/g; s/p2/b2/g; s/p3/c3/g; s/p4/d4/; s/p5/e5/g')
$ echo $var2
Some a1 string b2 of c3 text d4 etc

Unfortunately I don't see semicolon-as-sed-command-separator listed in sed documentation, and don't know whether this is available in other versions than GNU sed.

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