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=== Passing target to make sub-module === |
=== Passing target to make sub-module === |
Revision as of 12:50, 6 July 2020
make is an utility that determines automatically which pieces of a program need to be recompiled, and issues the commands to rebuild them. make uses a file called Makefile, which describes the relationships among files in the program.
References
- Recursive Make Considered Harmful
This papers explains that cutting big projects into smaller Makefiles that are called recursively greatly increase the build time, even when nothing changed. Instead it advices toinclude
smaller Makefiles in a master one, such that the dependency tree is complete.
Tools related to Make:
Some alternatives to Make:
- redo, a replacement for Make, based on ideas from Daniel J. Bernstein
- A post motivating why it could be the new build system that might replace Make
- Some even says redo could be the new Git of build systems (also [1])
- ... but some does not agree...
- Ninja, a simple Make-like alternative, where scripts are intended to be generated by other tools.
Quick Reference
Automatic Variables
$@ | Target of the rule (if multi target, the one that cause the rule's command to run) |
$% | Target member name, when target is an archive member |
$< | Name of 1st prerequisite |
$? | All newer prerequisites (more recent than the target) |
$^ | All prerequisites |
$+ | All prerequisites, incl. duplicates |
$* | The stem with which the rule matched (e.g. if target is dir/a.foo.b, a pattern like a.%.b gives a stem dir/foo) |
$(@D) | $(@F) | Resp. the directory (w/o trailing /) and filename part of the target |
$(*D) | $(*F) | Resp. the directory (w/o trailing /) and filename part of the stem |
$(<D) | $(<F) | Resp. the directory (w/o trailing /) and filename part of the 1st prerequisite |
$(^D) | $(^F) | Resp. the directory (w/o trailing /) and filename part of the all prerequisite |
$(+D) | $(+F) | Resp. the directory (w/o trailing /) and filename part of the all prerequisites, incl. duplicates |
$(?D) | $(?F) | Resp. the directory (w/o trailing /) and filename part of the newer prerequisites |
How to Use Variables
- Recursive vs. simple expansion
# Recursive expansion
CFLAGS = $(INCLUDES) -O
INCLUDES = -Ifoo -Ibar
all:
echo $(CFLAGS) # will echo '-Ifoo -Ibar -O'
# Simple expansion
x := foo
y := $(x) bar # expansion occurs here, once for all (y = foo bar)
x := later # y still = foo bar
- Substitution References
foo = a.o b.o c.o
bar = $(foo:.o=.c) # bar = a.c b.c c.c
- Using % (equiv. to
$(patsubst %.c,%.o,$(foo))
:
foo = a.o b.o c.o
bar = $(foo:%.o=%.c) # bar = a.c b.c c.c
- Setting variables
Variables can be defined with =
(recursively expanded variable), :=
(simply expanded variable), ?=
(set if not set) or using keyword override
.
This is illustrated in the script below.
ARG = ----
override ARGO = ----
ARGQ ?= ----
ENV = ----
override ENVO = ----
ENVQ ?= ----
all:
@echo " = over ?= # xxxx means variable was overridden."
@echo "ENV: $(ENV) $(ENVO) $(ENVQ)"
@echo "ARG: $(ARG) $(ARGO) $(ARGQ)"
@printf "%-20s %-20s %-20s\n" "$(origin ARG)" "$(origin ARGO)" "$(origin ARGQ)"
@printf "%-20s %-20s %-20s\n" "$(origin ENV)" "$(origin ENVO)" "$(origin ENVQ)"
This produces the following output:
ENV=xxxx ENVO=xxxx ENVQ=xxxx make ARG=xxxx ARGO=xxxx ARGQ=xxxx
# = over ?= # xxxx means variable was overridden.
# ENV: ---- ---- xxxx
# ARG: xxxx ---- xxxx
# file override environment
# command line override command line
Use flag -e
to have environment variables to take precedence over file variables:
ENV=xxxx ENVO=xxxx ENVQ=xxxx make -e ARG=xxxx ARGO=xxxx ARGQ=xxxx
# = over ?= # xxxx means variable was overridden.
# ENV: xxxx ---- xxxx
# ARG: xxxx ---- xxxx
# environment override override environment
# command line override command line
Note that ?=
is actually a shorthand notation:
FOO ?= bar
# is exactly equivalent to this (see section The origin Function):
ifeq ($(origin FOO), undefined)
FOO = bar
endif
So we can get the same for simply expanded variables:
ifeq ($(origin FOO), undefined)
FOO := bar # aka. FOO ?:= bar
endif
Functions for Filenames
- $(dir names...)
- Extract the directory part
- $(notdir names...)
- Extract the not-directory part
- $(suffix names...)
- Extract the suffix of each file name (incl. the period .)
- $(basename names...)
- Extract the basename of each file name
- $(addsuffix suffix,names...)
- Append the value of suffix to each file name.
$(addsuffix .c,foo bar) # Produces 'foo.c bar.c'
- $(addprefix prefix,names...)
$(addprefix src/,foo bar) # Produces 'src/foo src/bar'
- $(join list1,list2)
- $(wildcard pattern)
- $(realpath names...)
- $(abspath names...)
Rules
all:
@echo About to make distribution files # @ : disable command echoing
-rm $(file) # - : don't stop on error (ignore)
Tips
Automatic Prerequisites
A standard solution (inspired from Makefile manual):
# - see http://www.gnu.org/software/make/manual/make.html#Automatic-Prerequisites
# - Note that .d files are automatically regenerated because of the include command below.
# - Only 1 .d file generated, indep. of defines. So if include files depend on defines, the .d files will *NOT* be updated.
# - Note that we add *both* .o and .d files as targets (-MT flag). So any changes in the dependencies will regenerate both
# .d and .o files.
-include $(SOURCES:.cpp=.d)
%.d: %.cpp
$(CPP) $(CFLAGS) $(INCPATHS) -MM -MT $*.o -MT $*.d -MF $@ $<
A more advanced solution, where object files are stored in directory $(VARDIR), and have a suffix $(VARIANT):
# - see http://www.gnu.org/software/make/manual/make.html#Automatic-Prerequisites
# - Note that .d files are automatically regenerated because of the include command below.
# - Only 1 .d file generated, indep. of defines. So if include files depend on defines, the .d files will *NOT* be updated.
# - [CHANGES] .o and .d files are stored in directory $(VARDIR)/, and .o have suffix $(VARIANT)
-include $(addprefix $(VARDIR)/, $(notdir $(SOURCES:.cpp=.d) ) )
$(VARDIR)/%.d: $(SRCDIR)/%.cpp
$(CPP) $(CFLAGS) $(INCPATHS) -MM -MT $(VARDIR)/$*$$"(VARIANT)".o -MT $*.d -MF $@ $<
Limitations and Other solutions:
- Only one .d file generated, indep. of $(DEFINES), so if $(DEFINES) changed, and include files depends on these defines, the .d files will not be updated.
- A solution would be to name the .d files according to relevant defines, as we do for the .o files
- Instead of adding both .d and .o files to the target, one could leave the .d file as the only target, and add .d file as an extra dependency to the .o file.
Yet another solution, where .d are generated along with .o files:
SOURCES = …
OBJECTS = $(SOURCES:.c:.o)
ifeq "$(notdir $(CC)" "armcc"
# armcc will generate windows path. We use sed to fix the paths. Unfiltered deps are written to .ud files
# so that these are never included even if makefile is interrupted right after $(CC) (e.g. compilation errors)
%.o: %.c Makefile
$(CC) $(CFLAGS) --unix_depend_format --depend $(@:.o=.ud) -c $< -o $@
@sed -r 's!\\!/!g; s!([a-zA-Z]):/!/cygdrive/\1/!g' $(@:.o=.ud) > $(@:.o=.d)
else
# assuming 'gcc'
%.o: %.c Makefile
$(CC) $(CFLAGS) -MMD -c $< -o $@
endif
# Create dependency file names from object names
DEPFILES = $(OBJECTS:.o=.d)
# Include the dependency files – if these do not exists, make will ignore them
-include $(DEPFILES)
Adding prefixes
SOURCES = src/foo.c src/bar.c
all:
@echo $(addprefix subdir/,$(SOURCES)) # Use 'addprefix' function - clearer
@echo $(foreach V,$(SOURCES),subdir/$(V)) # Using 'foreach' - powerful but less clear
@echo $(SOURCES:%=subdir/%) # Using substitution - even more clear when...
@echo $(SOURCES:%.c=obj/%.o) # ... changing ext as well
Conditionals
There are several types of conditionals in make:
- Functions for conditionals
- These are like regular if-then instructions, and can be used along with Automatic Variables (i.e.
$@ $?
...).
main.zip:: nfc.zip $(JAVA_SRC) Makefile
$(if $(filter %.java,$?),echo 'Indenting (savagely) your code...'; uncrustify --no-backup -c indent.uncrustify.prefs $(filter %.java,$?))
- Conditional Parts of Makefiles
- These are like conditional directives in C preprocessor. From the documentation:
make evaluates conditionals when it reads a makefile. Consequently, you cannot use automatic variables in the tests of conditionals because they are not defined until recipes are run (see Automatic Variables).
#Conditianals in rule recipes:
libs_for_gcc = -lgnu
normal_libs =
foo: $(objects)
ifeq ($(CC),gcc)
$(CC) -o foo $(objects) $(libs_for_gcc)
else
$(CC) -o foo $(objects) $(normal_libs)
endif
#Conditionals in variable definitions:
ifeq ($(CC),gcc)
libs=$(libs_for_gcc)
else
libs=$(normal_libs)
endif
foo: $(objects)
$(CC) -o foo $(objects) $(libs)
Echo while 1st pass expansion
To have make echo some information while in the 1st pass expansion phase (i.e. before running target recipe), one can use a dummy variable and $(shell ...)
function:
x := $(shell echo >&2 'ARM Based Posix system with J9DROP libraries')
However a standard echo works as well:
$(shell echo >&2 'ARM Based Posix system with J9DROP libraries')
Note that >&2
is necessary otherwise you get a strange error missing separator
from make.
Alternatively one can use info
:
$(info This is an information message.)
Change directory permanently
Reference: [2]
CHDIR_SHELL := $(SHELL)
$(info CHDIR_SHELL is $(CHDIR_SHELL))
define chdir
$(eval _D=$(firstword $(1) $(@D)))
$(info $(MAKE): cd $(_D)) $(eval SHELL = cd $(_D); $(CHDIR_SHELL))
endef
# Can change permanently directory during the 1st pass...
$(eval cd some_dir2; /bin/sh)
$(shell echo >&2 NOW PWD is $$PWD)
all:
# Or in a rule recipe...
$(call chdir,some_dir)
echo "I'm now always in some_dir"
echo gcc -Wall -o myTest myTest.c
echo $$PWD
some_dir/myTest:
$(call chdir)
echo "I'm now always in some_dir"
echo gcc -Wall -o myTest myTest.c
echo $$PWD
Using Function Variables
Function variables can either be defined by assigned or using define... endef
construct.
Assignments must be deferred (i.e. =
and not :-
), so that function is not evaluated at the time it is defined but only when used. Also if it contains comment symbol (#
), these must be escaped:
makefilecfg = $(shell echo "Creating configuration file '$R$(MAKEFILE_CFG)$Z'." >&2; \
mkdir -p $(BAD) >&2; \
echo "\# Common Platform custom configuration file." >$(MAKEFILE_CFG) ;\
echo "\# CP build system includes this file to know which components/variants to build." >>$(MAKEFILE_CFG); \
echo "\# See file 'tools/checkcfg.mk' for list of available components/variants." >>$(MAKEFILE_CFG); \
echo "CPU :=$(CPU)" >>$(MAKEFILE_CFG); \
echo "OSAL:=$(OSAL)" >>$(MAKEFILE_CFG); \
echo "JAVA:=$(JAVA)" >>$(MAKEFILE_CFG); \
echo "NFC :=$(NFC)" >>$(MAKEFILE_CFG); \
echo "" >&2; \
echo "You can now run '$Gmake$Z' to build the project with this configuration," >&2; \
echo "or first edit the configuration file to customize this build." >&2 )
all:
@(call $(makefilecfg))
The define... endef
is a bit simpler:
define makefilecfg
$(shell echo "Creating configuration file '$R$(MAKEFILE_CFG)$Z'." >&2;
mkdir -p $(BAD) >&2;
echo "# Common Platform custom configuration file." >$(MAKEFILE_CFG);
echo "# CP build system includes this file to know which components/variants to build." >>$(MAKEFILE_CFG);
echo "# See file 'tools/checkcfg.mk' for list of available components/variants." >>$(MAKEFILE_CFG);
echo "CPU :=$(CPU)" >>$(MAKEFILE_CFG);
echo "OSAL:=$(OSAL)" >>$(MAKEFILE_CFG);
echo "JAVA:=$(JAVA)" >>$(MAKEFILE_CFG);
echo "NFC :=$(NFC)" >>$(MAKEFILE_CFG) )
endef
all:
@(call $(makefilecfg))
Use $(info ...) instead of $(shell echo ...)
Use $(info ...)
instead of $(shell echo ...)
to print information message. The later invokes a new shell process for each printed message, and is notably slower on Cygwin platform for instance.
Test whether a file exists
ifeq "$(wildcard $(FILENAME))" ""
$(error File $(FILENAME) does not exist.)
endif
Substitute space character into comma
Due to make syntax rules, converting a space-separated list into a comma-separated one is not straightforward. From GNU Make manual (§8.1):
Commas and unmatched parentheses or braces cannot appear in the text of an argument as written; leading spaces cannot appear in the text of the first argument as written. These characters can be put into the argument value by variable substitution. First define variables comma and space whose values are isolated comma and space characters, then substitute these variables where such characters are wanted [...]
The trick given in the manual is as follows:
comma:= ,
empty:=
space:= $(empty) $(empty)
foo:= a b c
bar:= $(subst $(space),$(comma),$(foo))
# bar is now 'a,b,c'.
Escaping space, comma and other characters
As seen in the previous tip, one need to use a trick to pass spaces or commas as function parameters. Make however is very liberal regarding variable name, and one can even use a variable name that consists in a space character [3]:
# Defining the $ or $( ) variable which has the value =
empty :=
space := $(empty) $(empty)
$(space) := $(space)
# Defining the $, or $(,) variable which has the value =
comma := ,
$(comma) := ,
# Defining the $= or $(=) variable which has the value =
equals := =
$(equals) := =
# Define the $# or $(#) variable which has the value #
hash := \#
$(hash) := \#
# Define the $: or $(:) variable which has the value :
colon := :
$(colon) := :
# Define the $($$) variable which has the value $
dollar := $$
$(dollar) := $$
; := ;
% := %
For instance:
$(info [$( )] [$ ] [$(,)] [$,] [$(=)] [$=])
bar:= $(subst $ ,$,,$(foo))
Regarding space, some developers say at [4] that the following trick does not work:
# The following might not work (space would actually contain a newline?)
space :=
space +=
Define multi-line strings
The best method is to use the define ... endef
construct and export the variable, and then reference it as a shell variable with $$VARIABLE
(see [5]):
define USAGE_TEXT
Usage: ...
Option:
First this and that
Second Can refer to make $(variable) too
endef
export USAGE_TEXT
usage:
@echo >&2 "$$USAGE_TEXT"
Using $(USAGE_TEXT)
would not work, or require escaping the end of line, add '\n', and use echo -e
.
Alternatively, for warning messages, we can do $(warning $(USAGE_TEXT))
.
Passing target to make sub-module
The same technique is illustrated in Make Manual at §3.6. We provide a default recipe to unknown target through a catch-all pattern rule, hence catching in $@ the name of the target given on the command-line.
# file 'Makefile'
first:
@echo target $@
# There is always an implicit 'make Makefile' issued by make.
# We add this target so that it is not caught by generic rule below
Makefile:
@echo special target $@
# Try 'make second; touch second; make second'
# Thanks to force, target 'second' is always done
%: force
@echo target $@
@$(MAKE) $@ -f Makefile.mk # pass $@ as target to Makefile.mk
# Don't forget semi-colon
force: ;
third:
@echo target $@
Color messages
# We first fefine ESC - \033 doesn't work in $(info ...). The 2nd one is a verbatim escape char. The last one is most portable (dash and bash)
# ... then we define the color code. DO NOT ADD TRAILING COMMENTS OR THIS WILL ADD TRAILING SPACES.
# ESC := \033
# ESC := ^[
# ESC := $(shell echo "\033")
ESC := $(shell printf '\e')
R := $(ESC)[0;31m
G := $(ESC)[0;32m
B := $(ESC)[0;34m
Z := $(ESC)[0;0m
$(info A $Rcolorful $Zand $Gbeautiful $Bmessage$Z!)
all:
echo "$Rcolorful $Zand $Gbeautiful $Bmessage$Z!"
Note that using \033
only works in shell echo
command. The other two commands works in both $(info ...)
and shell echo
command.
Color messages only if output to a tty
See my answer on StackOverflow
- Detect TTY in a custom make script
We simply write a simple shell script that intercepts the call to the native make, detects the TTY, and defines a variable appropriately. The main advantages of this solution:
- simplicity,
- works for echo, $(info ...) and alike, $(shell ...) commands,
- no modification required in the recipes,
- no extra process spawned at each echo, which on some platform can be quite slow (eg. Cygwin).
ifdef IS_TTY
# DO NOT ADD TRAILING COMMENTS OR THIS WILL FAIL BECAUSE OF TRAILING SPACES
ESC := $(shell printf '\e')
R := $(ESC)[31m
Z := $(ESC)[0;0m
endif
$(info [info ] $Rred$Z black)
$(shell echo >&2 "[shell ] $Rred$Z black")
all:
@echo "[recipe] $Rred$Z black"
Example of custom make script to add in path (eg. /usr/local/bin/make):
#! /bin/bash
[ -t 1 ] && IS_TTY=1 || IS_TTY=0
exec /usr/bin/make IS_TTY=$IS_TTY "$@"
This method provides the expected output in all these cases:
make # Colored
make >&2 # Colored
make | cat # NOT colored
make >tmp && cat tmp # NOT colored
- Detect in recipe and call the Makefile recursively
In some cases, it might not be possible to intercept the call to make or replace it with a custom script. In this solution, we fix that limitation by detecting the TTY in a first pass, and then calling the same Makefile recursively with the appropriate variable set.
ifndef IS_TTY
.SILENT:
%:
@[ -t 1 ] && IS_TTY=1 || IS_TTY=0; $(MAKE) IS_TTY=$$IS_TTY "$@"
xyz:
@[ -t 1 ] && IS_TTY=1 || IS_TTY=0; $(MAKE) IS_TTY=$$IS_TTY
else
ifeq ($(IS_TTY),1)
# DO NOT ADD TRAILING COMMENTS OR THIS WILL FAIL BECAUSE OF TRAILING SPACES
ESC := $(shell printf '\e')
R := $(ESC)[31m
Z := $(ESC)[0;0m
endif
$(info [info ] $Rred$Z black)
$(shell echo >&2 "[shell ] $Rred$Z black")
recursive:
@echo "[recipe] $Rred$Z black"
endif
- Strip the escape sequences at each echo
We test at each echo command whether the output is a TTY, and we strip the escape sequences if not so (using https://superuser.com/questions/380772/removing-ansi-color-codes-from-text-stream). To reduce the spam on the line, we use a make variable $(STRIPESC). The solution is quite simple, but it only works for echo command, and spawns an extra process at each echo. It also requires to edit every recipe with an echo.
# DO NOT ADD TRAILING COMMENTS OR THIS WILL FAIL BECAUSE OF TRAILING SPACES
ESC := $(shell printf '\e')
R := $(ESC)[31m
Z := $(ESC)[0;0m
STRIPESC:=( [ -t 1 ] && cat || sed 's/\x1b\[[0-9;]*m//g' )
# $(info ...) not supported
# $(shell echo >&2 ...) not supported
if_tty:
@echo "[recipe] $Rred$Z black" | $(STRIPESC)
- Use an external echo command to strip escape sequences
This is similar to the solution above except that the syntax is a bit more lightweight. The pros/cons are the same. Also, in the example below, I generate the external echo in the makefile itself. In a standard build, you would provide this command as an external tool in some standard path.
# DO NOT ADD TRAILING COMMENTS OR THIS WILL FAIL BECAUSE OF TRAILING SPACES
ESC := $(shell printf '\e')
R := $(ESC)[31m
Z := $(ESC)[0;0m
$(shell echo "#! /bin/bash" > echotty)
$(shell echo '[ -t 1 ] && echo "$$@" || echo "$$@" | sed "s/\x1b\[[0-9;]*m//g"' >> echotty)
$(shell chmod a+x echotty)
# $(info ...)
# $(shell echo >&2 ...)
.PHONY: echotty
echotty:
@./echotty "[recipe] $Rred$Z black"
Detect if Make runs in an interactive shell
This one is simpler, and simply consists in testing whether FD 0 is a TTY [6]:
INTERACTIVE:=$(shell [ -t 0 ] && echo 1)
ifdef INTERACTIVE
# is a terminal
else
# cron job
endif
Silent make by default, unless verbose requested
Make by default has echoing, i.e. it prints recipe command before executing them. This can be silented by
- Prefixing command with
@
- Using option
--silent
or-s
- Using special target
.SILENT
A much better way is to disable echoing by default, and print relevant commands only in some case [7]:
#Silent unless verbose (also for sub-make calls)
ifndef VERBOSE
.SILENT:
endif
# Same but syntax trick
$(VERBOSE).SILENT:
# Same but using MAKEFLAGS
ifndef VERBOSE
MAKEFLAGS += --silent
endif
Doing a make VERBOSE=1
will print the recipe commands (unless if they are prefixed with @
). All the tricks above also affect sub-make calls.
Subst a variable only if defined
Note that by default pattern substitution only occurs if the given variable is not empty:
$(shell touch foo.ld foo.c bar.c)
FOO=foo.ld
all: foo bar
foo: foo.c foo.c $(FOO)
@echo gcc $(FOO:%=-T %) $(filter %.c,$^) -o $@
@echo gcc $(patsubst %,-T %,$(filter %.ld,$^)) $(filter %.c,$^) -o $@
bar: bar.c $(BAR)
@echo gcc $(BAR:%=-T %) $(filter %.c,$^) -o $@
@echo gcc $(patsubst %,-T %,$(filter %.ld,$^)) $(filter %.c,$^) -o $@
This produces:
gcc -T foo.ld foo.c bar.c -o foo
gcc -T foo.ld foo.c bar.c -o foo
gcc bar.c -o bar
gcc bar.c -o bar
Enable or disable parallel build with MAKEFLAGS
Add flags -j
to MAKEFLAGS. When there are many targets, it is better to limit a bit the number of parallel jobs (eg. -j64
).
Be careful that not all Makefile are designed to run in parallel. Ideally, to be prevent parallel execution, the Makefile must contain the .NOTPARALLEL
target:
# This will prevent parallel execution of this Makefile
.NOTPARALLEL:
To preserve output consistency, we can also use -O
to buffer output. For long build, -O
often means there will be no output for a long time, so a better compromise is -Oline
, which at least preserve output consistency for most parsers (like IDE that parses make output for errors).
export MAKEFLAGS="-j64 -Oline" # 64 jobs, preserve line consistency
make
Alternatively we can add -Onone
to MAKEFLAGS
# Make sure output-sync (-Oline) is disabled
MAKEFLAGS += -Onone
To disable parallel build for one target only:
# We don't want buffer when debugging
.PHONY: gdb gdb-nobuf
gdb: MAKEFLAGS+=-Onone
gdb: $(APP)
$(MAKE) gdb-nobuf
gdb-nobuf:
gdb $(APP)
Use ccache to cache build objects
See ccache.
Use target specific variable
One can define custom variables that are defined only for specific targets. The recipe syntax requires that variables be defined independently of other dependencies.
target: SOME_VAR = SOME_VALUE
target: src_a.c src_b.c
$(CC) $^ -o $@
Note that variables are defined on a separate line. To have the variable exported in the environment, use export
keyword:
target: SOME_VAR = SOME_VALUE
target: src_a.c src_b.c
$(CC) $^ -o $@
Disable implicit rules
Implicit rules are those that are defined by default in Make (like .c to .o conversion.
To disable them, just redefine .SUFFIXES
variable:
.SUFFIXES:
Detect if running on Linux or Windows
We can use OS
variable on Windows, but we cannot use OSTYPE
on Linux (not defined in Makefile). So from Stackoverflow, the source of all wisdom:
ifeq ($(OS),Windows_NT)
CCFLAGS += -D WIN32
ifeq ($(PROCESSOR_ARCHITEW6432),AMD64)
CCFLAGS += -D AMD64
else
ifeq ($(PROCESSOR_ARCHITECTURE),AMD64)
CCFLAGS += -D AMD64
endif
ifeq ($(PROCESSOR_ARCHITECTURE),x86)
CCFLAGS += -D IA32
endif
endif
else
UNAME_S := $(shell uname -s)
ifeq ($(UNAME_S),Linux)
CCFLAGS += -D LINUX
endif
ifeq ($(UNAME_S),Darwin)
CCFLAGS += -D OSX
endif
UNAME_P := $(shell uname -p)
ifeq ($(UNAME_P),x86_64)
CCFLAGS += -D AMD64
endif
ifneq ($(filter %86,$(UNAME_P)),)
CCFLAGS += -D IA32
endif
ifneq ($(filter arm%,$(UNAME_P)),)
CCFLAGS += -D ARM
endif
endif
Frequent Mistakes
- Use TABS to prefix commands in rules, *NOT* SPACES
- Each rule in a makefile gives the set of commands that must be executed to build a given target from a given set of dependencies. These commands MUST be indented with a TAB character, not with SPACES. So make sure that the editor does not automatically change these tabs into spaces.
- Don't call sub-project Makefile, include it
- Calling subproject makefiles, so-called recursive make, has a huge performance penalty however the build (see Recursive Make Considered Harmful)
- Don't add space around = (equal sign) in variable substitution
- Do
$(SOURCES:%.c=%.o)
, not$(SOURCES:%.c = %.o)
- Use COMMA to separate parameters in $(call), not SPACE
- Do
$(call FCT,$(param))
, not. The later will fail silently!$(call FCT $(param))
- Use
$(shell echo ...)
outside of a recipe - Using
$(shell echo ...)
in the body of the Makefile will generate an errorMissing separator
, because the output of the shell command is injected as is in the Makefile. Instead, either redirect with$(shell echo &2 ...)
, or use$(info $(shell echo ...))
, but oftentimes$(shell echo )
is superfluous. [8]
Bugs
- Bugs: bug #30312, $(abspath ...) fails with Windows UNC Paths (fixed in v3.82)
Temporary fix:
ABS_DIRS := $(filter /%,$(DIRS)) $(abspath $(filter-out /%,$(DIRS)))