# How to write loop in a Makefile?

I want to execute the following commands:

./a.out 1
./a.out 2
./a.out 3
./a.out 4
.
.
. and so on


How to write this thing as a loop in a Makefile?

The following will do it if, as I assume by your use of ./a.out, you're on a UNIX-type platform.

for number in 1 2 3 4 ; do \
./a.out $$number ; \ done  Test as follows: target: for number in 1 2 3 4 ; do \ echo$$number ; \
done


produces:

1
2
3
4


For bigger ranges, use:

target:
number=1 ; while [[ $$number -le 10 ]] ; do \ echo$$number ; \
((number = number + 1)) ; \
done


This outputs 1 through 10 inclusive, just change the while terminating condition from 10 to 1000 for a much larger range as indicated in your comment.

Nested loops can be done thus:

target:
num1=1 ; while [[ $$num1 -le 4 ]] ; do \ num2=1 ; while [[$$num2 -le 3 ]] ; do \
echo $$num1$$num2 ; \
((num2 = num2 + 1)) ; \
done ; \
((num1 = num1 + 1)) ; \
done


producing:

1 1
1 2
1 3
2 1
2 2
2 3
3 1
3 2
3 3
4 1
4 2
4 3

• Since you're assuming his shell recognizes ((...)), why not use the much simpler for ((i = 0; i < WHATEVER; ++i)); do ...; done ? Sep 29, 2009 at 7:13
• Note that the seq command which generates a sequence of numbers exists on most (all?) unix systems, so you can write for number in seq 1 1000; do echo $$number; done (Put a single backtick on each side of the seq command, not two, I don't know how to format this correctly using stackoverflow's syntax) Sep 23, 2013 at 10:31 • Thanks, I was missing the double$$ to reference the for loop variable. Oct 4, 2013 at 14:40
• can someone explain the need for the double $$and the line continuation character /? I'm new to makefiles but I don't see this kind of encoding anywhere else Sep 24, 2019 at 19:11 • @Jonz: the line continuation character is because make normally treats each line as a thing to run in a separate sub-shell. Without continuation, it would try to run a subshell with just (for example) for number in 1 2 3 4 ; do, without the rest of the loop. With it, it effectively becomes a single line of the form while something ; do something ; done, which is a complete statement. The $$ question is answered here: stackoverflow.com/questions/26564825/…, with the code seemingly extracted from this very answer :-) Sep 25, 2019 at 0:26

If you're using GNU make, you could try

NUMBERS = 1 2 3 4
doit:
$(foreach var,$(NUMBERS),./a.out $(var);)  which will generate and execute ./a.out 1; ./a.out 2; ./a.out 3; ./a.out 4;  • This answer is IMHO better, cause it does not require to use any shell, it's pure makefile (even if it's GNU-specific). Jan 21, 2011 at 16:08 • the semicolon is crucial otherwise only the first iteration will execute May 18, 2012 at 19:55 • This solution hides the exit code of ./a.out 1. ./a.out 2 will be executed regardless. Apr 29, 2013 at 10:11 • This is not a better answer, because the built in foreach function has limitations on how many elements can be looped over, compared to using the while function in the shell instead. Jun 18, 2014 at 9:02 • @Alexander: As the message says, that's not a limit in GNU make's foreach, but in the exec system call used by the shell to invoke ls. There is no limit, other than memory, for the number of arguments to foreach. The script and make file that you point to clearly don't do the same thing, and it is pretty clear why you see the behavior you mention. Again it has nothing to do with limits in the foreach function. Jun 22, 2014 at 23:22 THE major reason to use make IMHO is the -j flag. make -j5 will run 5 shell commands at once. This is good if you have 4 CPUs say, and a good test of any makefile. Basically, you want make to see something like: .PHONY: all all: job1 job2 job3 .PHONY: job1 job1: ; ./a.out 1 .PHONY: job2 job2: ; ./a.out 2 .PHONY: job3 job3: ; ./a.out 3  This is -j friendly (a good sign). Can you spot the boiler-plate? We could write: .PHONY: all job1 job2 job3 all: job1 job2 job3 job1 job2 job3: job%: ./a.out$*


for the same effect (yes, this is the same as the previous formulation as far as make is concerned, just a bit more compact).

A further bit of parameterisation so that you can specify a limit on the command-line (tedious as make does not have any good arithmetic macros, so I'll cheat here and use $(shell ...)) LAST := 1000 NUMBERS :=$(shell seq 1 ${LAST}) JOBS :=$(addprefix job,${NUMBERS}) .PHONY: all${JOBS}
all: ${JOBS} ; echo "$@ success"
${JOBS}: job%: ; ./a.out$*


You run this with make -j5 LAST=550, with LAST defaulting to 1000.

• This is definitely the best answer, for the reason that bobbogo mentioned (-j).
– dbn
Oct 4, 2012 at 23:28
• Any particular reason this uses .PHONY suffixes? Are they required for anything?
– Seb
Dec 11, 2012 at 15:14
• @seb: Without .PHONY: all, make will look for a file called all. If such a file exists, make then checks that file's last-changed-time, and the makefile will almost certainly not do what you intended. The .PHONY declaration tells make that all is a symbolic target. Make will therefore consider the all target to always be out of date. Perfect. See the manual. Dec 12, 2012 at 15:34
• How does this line work: ${JOBS}: job%: What is the second semicolon for? I didn't see anything in gnu.org/software/make/manual/make.htm – Joe May 6, 2014 at 5:19 • @JoeS gnu.org/software/make/manual/make.html#Static-Pattern (I think you meant What is the 2nd *colon* for). Do not confuse them with the un-nice (IMHO) Pattern Rules. Static pattern rules are really useful whenever the list of targets can be matched by one of make's noddy patterns (same applies to the dependencies). Here I use one just for the convenience that whatever matched the % in the rule is available as $* in the recipe. May 6, 2014 at 15:04

I realize the question is several years old, but this post may still be of use to someone as it demonstrates an approach which differs from the above, and isn't reliant upon either shell operations nor a need for the developer to schpeel out a hardcoded string of numeric values.

the $(eval ....) builtin macro is your friend. Or can be at least. define ITERATE$(eval ITERATE_COUNT :=)\
$(if$(filter ${1},0),,\$(call ITERATE_DO,${1},${2})\
)
endef

define ITERATE_DO
$(if$(word ${1},${ITERATE_COUNT}),,\
$(eval ITERATE_COUNT+=.)\$(info ${2}$(words ${ITERATE_COUNT}))\$(call ITERATE_DO,${1},${2})\
)
endef

default:
$(call ITERATE,5,somecmd)$(call ITERATE,0,nocmd)
$(info$(call ITERATE,8,someothercmd)


That's a simplistic example. It won't scale pretty for large values -- it works, but as the ITERATE_COUNT string will increase by 2 characters (space and dot) for each iteration, as you get up into the thousands, it takes progressively longer to count the words. As written, it doesn't handle nested iteration (you'd need a separate iteration function and counter to do so). This is purely gnu make, no shell requirement (though obviously the OP was looking to run a program each time -- here, I'm merely displaying a message). The if within ITERATE is intended to catch the value 0, because $(word...) will error out otherwise. Note that the growing string to serve as a counter is employed because the$(words...) builtin can provide an arabic count, but that make does not otherwise support math operations (You cannot assign 1+1 to something and get 2, unless you're invoking something from the shell to accomplish it for you, or using an equally convoluted macro operation). This works great for an INCREMENTAL counter, not so well for a DECREMENT one however.

I don't use this myself, but recently, I had need to write a recursive function to evaluate library dependencies across a multi-binary, multi-library build environment where you need to know to bring in OTHER libraries when you include some library which itself has other dependencies (some of which vary depending on build parameters), and I use an $(eval) and counter method similar to the above (in my case, the counter is used to ensure we don't somehow go into an endless loop, and also as a diagnostic to report how much iteration was necessary). Something else worth nothing, though not significant to the OP's Q:$(eval...) provides a method to circumvent make's internal abhorrence to circular references, which is all good and fine to enforce when a variable is a macro type (intialized with =), versus an immediate assignment (initialized with :=). There are times you want to be able to use a variable within its own assignment, and $(eval...) will enable you to do that. The important thing to consider here is that at the time you run the eval, the variable gets resolved, and that part which is resolved is no longer treated as a macro. If you know what you're doing and you're trying to use a variable on the RHS of an assignment to itself, this is generally what you want to happen anyway.  SOMESTRING = foo # will error. Comment out and re-run SOMESTRING = pre-${SOMESTRING}

# works
$(eval SOMESTRING = pre${SOMESTRING}

default:
@echo ${SOMESTRING}  Happy make'ing. For cross-platform support, make the command separator (for executing multiple commands on the same line) configurable. If you're using MinGW on a Windows platform for example, the command separator is &: NUMBERS = 1 2 3 4 CMDSEP = & doit:$(foreach number,$(NUMBERS),./a.out$(number) $(CMDSEP))  This executes the concatenated commands in one line: ./a.out 1 & ./a.out 2 & ./a.out 3 & ./a.out 4 &  As mentioned elsewhere, on a *nix platform use CMDSEP = ;. This is not really a pure answer to the question, but an intelligent way to work around such problems: instead of writing a complex file, simply delegate control to for instance a bash script like: makefile foo : bar.cpp baz.h bash script.sh  and script.sh looks like: for number in 1 2 3 4 do ./a.out$number
done

• I have got stuck at a step while writing a Makefile. I have following code : set_var: @ NUM=0 ; while [[ $$NUM < 1 ]]; do \ echo "I am here"; \ echo$$NUM dump$${NUM}.txt; \ var="SSA_CORE$${NUM}_MAINEXEC" ; \ echo $$var ; \ var1=eval echo \$${$(var)}; \ echo $$var1; \ (( NUM = NUM + 1)); \ done all:set_var here SSA_CORE0_MAINEXEC is an environment variable which is already set.So I want that value to get evaluated or printed using variable var1. I tried it as shown above but not working. pLease help. Jan 17, 2014 at 8:38 • This is indeed an easy workaround, however it keeps you from using the nice "make -j 4" option to have processes run in parallel. Jul 19, 2018 at 20:35 • @TabeaKischka: indeed. It was not the "recommended" way, but it is more meant if one needs some features that are not offered by a Makefile, then one can fallback to an implementation in bash and thus use the features. The loop is one of the features for which this can be demonstrated. Jul 19, 2018 at 20:48 Maybe you can use: xxx: for i in seq 1 4; do ./a.out$$i; done;  You can use set -e as a prefix for the for-loop. Example: all: set -e; for a in 1 2 3; do /bin/false; echo $$a; done  make will exit immediately with an exit code <> 0. Although the GNUmake table toolkit has a true while loop (whatever that means in GNUmake programming with its two or three phases of execution), if the thing which is needed is an iterative list, there is a simple solution with interval. For the fun of it, we convert the numbers to hex too: include gmtt/gmtt.mk # generate a list of 20 numbers, starting at 3 with an increment of 5 NUMBER_LIST := (call interval,3,20,5) # convert the numbers in hexadecimal (0x0 as first operand forces arithmetic result to hex) and strip '0x' NUMBER_LIST_IN_HEX := (foreach n,(NUMBER_LIST),(call lstrip,(call add,0x0,(n)),0x)) # finally create the filenames with a simple patsubst FILE_LIST := (patsubst %,./a%.out,(NUMBER_LIST_IN_HEX)) (info (FILE_LIST))  Output: ./a3.out ./a8.out ./ad.out ./a12.out ./a17.out ./a1c.out ./a21.out ./a26.out ./a2b.out ./a30.out ./a35.out ./a3a.out ./a3f.out ./a44.out ./a49.out ./a4e.out ./a53.out ./a58.out ./a5d.out ./a62.out  # Dynamically assign variables in the loop The promblem with the for number in 1 2 3 4 ; do \ ...-solution is, that no variables can be assigned within the loop. (eval VAR=...) can only be used, if the content of the assignment is known at the beginning of the target execution. If the assignment depends on the loop-variable, VAR will be empty. To circumvent this issue, one can use the target functionality to model a loop. The following example takes the n-th file from SRC / OBJ and processes them together. Using this construction you can even use (eval ...) to process the loop variable, as demonstrated with VAR3. makefile SRC = f1.c f2.cpp f3.cpp OBJ = f1.o f2.o f3.o SRC2 = (addsuffix _,(SRC)) JOIN = (join (SRC2),(OBJ)) PHONY: all all : info loop loop : (JOIN) (JOIN) : @# LOOP - CONTENT @echo "TARGET: @" (eval VAR1=(word 1,(subst _, ,@))) @echo "VAR1: "(VAR1) (eval VAR2=(word 2,(subst _, ,@))) @echo "VAR2: "(VAR2) (eval VAR3=(subst .o,.x,(VAR2))) @echo "You can even substitute you loop variable VAR3: "(VAR3) #g++ -o (VAR2) (VAR1) @echo PHONY: info info: @printf "\n" @echo "JOIN: "(JOIN) @printf "\n"  output  make JOIN: f1.c_f1.o f2.cpp_f2.o f3.cpp_f3.o TARGET: f1.c_f1.o VAR1: f1.c VAR2: f1.o You can even substitute you loop variable VAR3: f1.x #g++ -o f1.o f1.c TARGET: f2.cpp_f2.o VAR1: f2.cpp VAR2: f2.o You can even substitute you loop variable VAR3: f2.x #g++ -o f2.o f2.cpp TARGET: f3.cpp_f3.o VAR1: f3.cpp VAR2: f3.o You can even substitute you loop variable VAR3: f3.x #g++ -o f3.o f3.cpp  A simple, shell/platform-independent, pure macro solution is ... # GNU make (gmake) compatible; ref: <https://www.gnu.org/software/make/manual> define EOL () endef %sequence = (if (word {1},{2}),(wordlist 1,{1},{2}),(call %sequence,{1},{2} (words _ {2}))) .PHONY: target target: (foreach i,(call %sequence,10),./a.out {i}{EOL})  This answer, just as that of @Vroomfondel aims to circumvent the loop problem in an elegant way. My take is to let make generate the loop itself as an imported makefile like this: include Loop.mk Loop.mk:Loop.sh Loop.sh > @  The shell script can the be as advanced as you like but a minimal working example could be #!/bin/bash LoopTargets="" NoTargest=5 for Target in seq NoTargest ; do File="target_{Target}.dat" echo File:data_script.sh echo '\t'./data_script.ss Target LoopTargets="LoopTargets File" done echo;echo;echo LoopTargets:=LoopTargets  which generates the file target_1.dat:data_script.sh ./data_script.ss 1 target_2.dat:data_script.sh ./data_script.ss 2 target_3.dat:data_script.sh ./data_script.ss 3 target_4.dat:data_script.sh ./data_script.ss 4 target_5.dat:data_script.sh ./data_script.ss 5 LoopTargets:= target_1.dat target_2.dat target_3.dat target_4.dat target_5.dat  And advantage there is that make can itself keep track of which files have been generated and which ones need to be (re)generated. As such, this also enables make to use the -j flag for parallelization. This worked for me: NUM=4 a-out: for (( i=1; i<={NUM}; i++ )) \ do \ ./a.out$$i ; \ done  #I have a bunch of files that follow the naming convention #soxfile1 soxfile1.o soxfile1.sh soxfile1.ini soxfile1.txt soxfile1.err #soxfile2 soxfile2.o soxfile2.sh soxfile2.ini soxfile2.txt soxfile2.err #sox... .... ..... .... .... .... #in the makefile, only select the soxfile1.. soxfile2... to install dir #My GNU makefile solution follows: tgt=/usr/local/bin/ #need to use sudo tgt2=/backup/myapplication/ #regular backup install: for var in $$(ls -f sox* | grep -v '\.' ) ; \ do \ sudo cp -f$$var${TGT} ;     \
cp -f  var ${TGT2} ; \ done #The ls command selects all the soxfile* including the *.something #The grep command rejects names with a dot in it, leaving #My desired executable files in a list.  ## Version ## Code files :=$(wildcard ./*.txt ./**/*.go */**/*.js )

showFileFunc = echo "$(abspath${1})\${2}" delFileFunc = del "$(abspath ${1})\${2}"
cmdSplit = &
targetDisplay:
$(foreach curFile,${files}, ${call showFileFunc,${dir $(curFile)},${notdir $(curFile)}}${cmdSplit})
targetDelete:
$(foreach curFile,${files}, ${call delFileFunc,${dir $(curFile)},${notdir $(curFile)}}${cmdSplit})


### Test Directory

Makefile
📝1.txt
📂 myDir
- 📝foo.go
- 📝bar.go
- 📂subDir
- 📝qoo.js


### Test CMD & output

make showFile -s

output:
"C:/...\1.txt"
"C:/.../myDir\bar.go"
"C:/.../myDir\foo.go"          // since .//**.js
"C:/.../myDir/subDir\qoo.js"   // .//**.js can't but */**/*.js is OK