1234567891011121314151617181920212223242526272829303132333435363738394041424344454647484950515253545556575859606162636465666768697071727374757677787980818283848586878889909192939495969798991001011021031041051061071081091101111121131141151161171181191201211221231241251261271281291301311321331341351361371381391401411421431441451461471481491501511521531541551561571581591601611621631641651661671681691701711721731741751761771781791801811821831841851861871881891901911921931941951961971981992002012022032042052062072082092102112122132142152162172182192202212222232242252262272282292302312322332342352362372382392402412422432442452462472482492502512522532542552562572582592602612622632642652662672682692702712722732742752762772782792802812822832842852862872882892902912922932942952962972982993003013023033043053063073083093103113123133143153163173183193203213223233243253263273283293303313323333343353363373383393403413423433443453463473483493503513523533543553563573583593603613623633643653663673683693703713723733743753763773783793803813823833843853863873883893903913923933943953963973983994004014024034044054064074084094104114124134144154164174184194204214224234244254264274284294304314324334344354364374384394404414424434444454464474484494504514524534544554564574584594604614624634644654664674684694704714724734744754764774784794804814824834844854864874884894904914924934944954964974984995005015025035045055065075085095105115125135145155165175185195205215225235245255265275285295305315325335345355365375385395405415425435445455465475485495505515525535545555565575585595605615625635645655665675685695705715725735745755765775785795805815825835845855865875885895905915925935945955965975985996006016026036046056066076086096106116126136146156166176186196206216226236246256266276286296306316326336346356366376386396406416426436446456466476486496506516526536546556566576586596606616626636646656666676686696706716726736746756766776786796806816826836846856866876886896906916926936946956966976986997007017027037047057067077087097107117127137147157167177187197207217227237247257267277287297307317327337347357367377387397407417427437447457467477487497507517527537547557567577587597607617627637647657667677687697707717727737747757767777787797807817827837847857867877887897907917927937947957967977987998008018028038048058068078088098108118128138148158168178188198208218228238248258268278288298308318328338348358368378388398408418428438448458468478488498508518528538548558568578588598608618628638648658668678688698708718728738748758768778788798808818828838848858868878888898908918928938948958968978988999009019029039049059069079089099109119129139149159169179189199209219229239249259269279289299309319329339349359369379389399409419429439449459469479489499509519529539549559569579589599609619629639649659669679689699709719729739749759769779789799809819829839849859869879889899909919929939949959969979989991000100110021003100410051006100710081009101010111012101310141015101610171018101910201021102210231024102510261027102810291030103110321033103410351036103710381039104010411042104310441045104610471048104910501051105210531054105510561057105810591060106110621063106410651066106710681069107010711072107310741075107610771078107910801081108210831084108510861087108810891090109110921093109410951096109710981099110011011102110311041105110611071108110911101111111211131114111511161117111811191120112111221123112411251126112711281129113011311132113311341135113611371138113911401141114211431144114511461147114811491150115111521153115411551156115711581159116011611162116311641165116611671168116911701171117211731174117511761177117811791180118111821183118411851186118711881189119011911192119311941195119611971198119912001201120212031204120512061207120812091210121112121213121412151216121712181219122012211222122312241225122612271228122912301231123212331234123512361237123812391240124112421243124412451246124712481249125012511252125312541255125612571258125912601261126212631264126512661267126812691270127112721273127412751276127712781279128012811282128312841285128612871288128912901291129212931294129512961297129812991300130113021303130413051306130713081309131013111312131313141315131613171318131913201321132213231324132513261327132813291330133113321333133413351336133713381339134013411342134313441345134613471348134913501351135213531354135513561357135813591360136113621363136413651366136713681369137013711372137313741375137613771378137913801381138213831384138513861387138813891390139113921393139413951396139713981399140014011402140314041405140614071408140914101411141214131414141514161417141814191420142114221423142414251426142714281429143014311432143314341435143614371438143914401441144214431444144514461447144814491450145114521453145414551456145714581459146014611462146314641465146614671468146914701471147214731474147514761477147814791480148114821483148414851486148714881489149014911492149314941495149614971498149915001501150215031504150515061507150815091510151115121513151415151516151715181519152015211522152315241525152615271528152915301531153215331534153515361537153815391540154115421543154415451546154715481549155015511552155315541555155615571558155915601561156215631564156515661567156815691570157115721573157415751576157715781579158015811582158315841585158615871588158915901591159215931594 |
- <html>
- <title>
- data
- </title>
- <body BGCOLOR="#FFFFFF" TEXT="#000000" LINK="#0000FF" VLINK="#330088" ALINK="#FF0044">
- <H1>Maintaining Files on Plan 9 with Mk
- </H1>
- <DL><DD><I>Andrew G. Hume<br>
- andrew@research.att.com<br>
- Bob Flandrena<br>
- bobf@plan9.bell-labs.com<br>
- </I></DL>
- <DL><DD><H4>ABSTRACT</H4>
- <P>
- <TT>Mk</TT>
- is a tool
- for describing and maintaining dependencies between
- files.
- It is similar to the
- UNIX program
- <TT>make</TT>,
- but provides several extensions.
- <TT>Mk</TT>'<TT>s</TT>
- flexible rule specifications, implied
- dependency derivation, and parallel
- execution of maintenance actions are
- well-suited to the Plan 9 environment.
- Almost all Plan 9 maintenance procedures
- are automated using
- <TT>mk</TT>.
- </DL>
- </P>
- <H4>1 Introduction
- </H4>
- <P>
- This document describes how
- <TT>mk</TT>,
- a program functionally similar to
- <TT>make</TT>
- [Feld79],
- is used to maintain dependencies between
- files in Plan 9.
- <TT>Mk</TT>
- provides several extensions to the
- capabilities of its predecessor that work
- well in Plan 9's distributed, multi-architecture
- environment. It
- exploits the power of multiprocessors by executing
- maintenance actions in parallel and interacts with
- the Plan 9 command interpreter
- <TT>rc</TT>
- to provide a powerful set of maintenance tools.
- It accepts pattern-based dependency specifications
- that are not limited to describing
- rules for program construction.
- The result is a tool that is flexible enough to
- perform many maintenance tasks including
- database maintenance,
- hardware design, and document production.
- </P>
- <P>
- This document begins by discussing
- the syntax of the control file,
- the pattern matching capabilities, and
- the special rules for maintaining archives.
- A brief description of
- <TT>mk</TT>'<TT>s</TT>
- algorithm for deriving dependencies
- is followed by a discussion
- of the conventions used to resolve ambiguous
- specifications. The final sections
- describe parallel execution
- and special features.
- </P>
- <P>
- An earlier paper [Hume87]
- provides a detailed discussion of
- <TT>mk</TT>'<TT>s</TT>
- design and an appendix summarizes
- the differences between
- <TT>mk</TT>
- and
- <TT>make</TT>.
- </P>
- <H4>2 The <TT>Mkfile</TT>
- </H4>
- <P>
- <TT>Mk</TT>
- reads a file describing relationships among files
- and executes commands to bring the files up to date.
- The specification file, called a
- <TT>mkfile</TT>,
- contains three types of statements:
- assignments, includes, and rules.
- Assignment and include statements are similar
- to those in C.
- Rules specify dependencies between a
- <I>target</I>
- and its
- <I>prerequisites</I>.
- When the target and prerequisites are files, their
- modification times determine if they
- are out of date. Rules often contain a
- <I>recipe</I>,
- an
- <A href="/magic/man2html/1/rc"><I>rc</I>(1)
- </A>script that produces the target from
- the prerequisites.
- </P>
- <P>
- This simple
- <TT>mkfile</TT>
- produces an executable
- from a C source file:
- <DL><DT><DD><TT><PRE>
- CC=pcc
- f1: f1.c
- <I>CC -o f1 f1.c
- </PRE></TT></DL>
- The first line assigns the name of the portable ANSI/POSIX compiler
- to the
- </I><TT>mk</TT><I>
- variable
- </I><TT>CC</TT><I>;
- subsequent references of the form
- </I><TT></TT><I>CC</I><TT>
- select this compiler.
- The only rule specifies a dependence between the target file
- </TT><TT>f1</TT><TT>
- and the prerequisite file
- </TT><TT>f1.c</TT><TT>.
- If the target does not exist or if the
- prerequisite has been modified more recently than
- the target,
- </TT><TT>mk</TT><TT>
- passes the recipe to
- </TT><TT>rc</TT><TT>
- for execution. Here,
- </TT><TT>f1.c</TT><TT>
- is compiled and loaded to produce
- </TT><TT>f1</TT><TT>.
- </P>
- </TT><P>
- The native Plan 9 environment
- requires executables for
- all architectures, not only the current one.
- The Plan 9 version of the same
- <TT>mkfile</TT>
- looks like:
- <DL><DT><DD><TT><PRE>
- </<I>objtype/mkfile
- f1: f1.</I>O
- <I>LD </I>LDFLAGS -o f1 f1.<I>O
- f1.</I>O: f1.c
- <I>CC </I>CFLAGS f1.c
- </PRE></TT></DL>
- The first line is an include statement
- that replaces itself with the contents of the file
- <TT>/</TT><I>objtype/mkfile</I><TT>.
- The variable
- </TT><TT></TT><TT>objtype</TT><TT>
- is inherited from the environment and
- contains the name of the target architecture.
- The prototype
- </TT><TT>mkfile</TT><TT>
- for that architecture defines architecture-specific variables:
- </TT><TT>CC</TT><TT>
- and
- </TT><TT>LD</TT><TT>
- are the names of the compiler and loader,
- </TT><TT>O</TT><TT>
- is the code character of the architecture.
- The rules compile the source file into an object
- file and invoke the loader to produce
- </TT><TT>f1</TT><TT>.
- Invoking
- </TT><TT>mk</TT><TT>
- from the command line as follows
- <DL><DT><DD><TT><PRE>
- % objtype=mips mk
- vc -w f1.c
- vl </TT><I>LDFLAGS -o f1 f1.k
- %
- </PRE></TT></DL>
- produces the
- </I><TT>mips</TT><I>
- executable of program
- </I><TT>f1</TT><I>
- regardless of the current architecture type.
- </P>
- </I><P>
- We can extend the
- <TT>mkfile</TT>
- to build two programs:
- <DL><DT><DD><TT><PRE>
- </objtype/mkfile
- ALL=f1 f2
- all:V: <I>ALL
- f1: f1.</I>O
- <I>LD </I>LDFLAGS -o f1 f1.<I>O
- f1.</I>O: f1.c
- <I>CC </I>CFLAGS f1.c
- f2: f2.<I>O
- </I>LD <I>LDFLAGS -o f2 f2.</I>O
- f2.<I>O: f2.c
- </I>CC <I>CFLAGS f2.c
- </PRE></TT></DL>
- The target
- </I><TT>all</TT><I>,
- modified by the
- </I><I>attribute</I><I>
- </I><TT>V</TT><I>,
- builds both programs.
- The attribute identifies
- </I><TT>all</TT><I>
- as a dummy target that is
- not related to a file of the same name;
- its precise effect is explained later.
- This example describes cascading dependencies:
- the first target depends on another which depends on a third and
- so on.
- Here, individual rules build each
- program; later we'll see how to do this with a
- general rule.
- </P>
- </I><H4>3 Variables and the environment
- </H4>
- <P>
- <TT>Mk</TT>
- does not distinguish between its
- internal variables and
- <TT>rc</TT>
- variables in the environment.
- When
- <TT>mk</TT>
- starts, it imports each environment variable into a
- <TT>mk</TT>
- variable of the same name. Before executing a recipe,
- <TT>mk</TT>
- exports all variables, including those
- inherited from the environment,
- to the environment in which
- <TT>rc</TT>
- executes the recipe.
- </P>
- <P>
- There are several ways for a
- variable to take a value.
- It can be set with an assignment statement,
- inherited from the environment, or specified
- on the command line.
- <TT>Mk</TT>
- also maintains several special internal variables
- that are described in
- <A href="/magic/man2html/1/mk"><I>mk</I>(1).
- </A>Assignments have the following decreasing order of precedence:
- </P>
- <br> <br>
- <DL><DT><DD>
- 1) Command line assignment
- <br>
- 2) Assignment statement
- <br>
- 3) Imported from the environment
- <br>
- 4) Implicitly set by <TT>mk</TT>
- </DL>
- <br> <br>
- For example, a command line assignment overrides
- a value imported from the environment.
- <P>
- All variable values are strings. They can be
- used for pattern matching and
- comparison but not for arithmetic.
- A
- <I>list</I>
- is a string containing several values separated by
- white space. Each member is
- handled individually during pattern matching,
- target selection, and prerequisite evaluation.
- </P>
- <P>
- A
- <I>namelist</I>
- is a list produced by
- transforming the members of an existing list.
- The transform applies a pattern to each member,
- replacing each matched string with a new string,
- much as in the substitute command in
- <A href="/magic/man2html/1/sam"><I>sam</I>(1)
- </A>or
- <A href="/magic/man2html/1/ed"><I>ed</I>(1).
- </A>The syntax is
- <DL><DT><DD><TT><PRE>
- {<I>var</I>:A%B=C%D}
- </PRE></TT></DL>
- where
- <I>var</I>
- is a variable.
- The pattern
- <TT>A%B</TT>
- matches a member beginning with the string
- <I>A</I>
- and ending with the string
- <I>B</I>
- with any string in between;
- it behaves like the regular expression
- <TT>A.*B</TT>.
- When a member of the
- <I>var</I>
- list
- matches this pattern,
- the string
- <I>C</I>
- replaces
- <I>A</I>,
- <I>D</I>
- replaces
- <I>B</I>,
- and the matched string replaces itself.
- Any of
- <I>A</I>,
- <I>B</I>,
- <I>C</I>,
- or
- <I>D</I>
- may be the empty string. In effect, a namelist is
- generated by applying the
- <A href="/magic/man2html/1/ed"><I>ed</I>(1)
- </A>substitute command
- <DL><DT><DD><TT><PRE>
- s/<I>A</I>(.*)<I>B</I>/<I>C</I>\1<I>D</I>/
- </PRE></TT></DL>
- to each member of a variable list.
- </P>
- <P>
- Namelists are useful for generating
- a list based on a predictable transformation.
- For example,
- <DL><DT><DD><TT><PRE>
- SRC=a.c b.c c.c
- OBJ=<I>{SRC:%.c=%.v}
- </PRE></TT></DL>
- assigns the list </I><TT>(a.v b.v c.v)</TT><I> to
- </I><TT>OBJ</TT><I>.
- A namelist may be used anywhere a variable is allowed
- except in a recipe.
- </P>
- </I><P>
- Command output is assigned to a variable
- using the normal
- <TT>rc</TT>
- syntax:
- <DL><DT><DD><TT><PRE>
- var=`{rc command}
- </PRE></TT></DL>
- The command executes in an environment populated
- with previously assigned variables, including those
- inherited from
- <TT>mk</TT>'<TT>s</TT>
- execution environment.
- The command may
- be arbitrarily complex; for example,
- <DL><DT><DD><TT><PRE>
- TARG=`{ls -d *.[cy] | sed 's/..//'}
- </PRE></TT></DL>
- assigns a list of the C and yacc source files in the current
- directory, stripped of their suffix, to the variable
- <TT>TARG</TT>.
- </P>
- <H4>4 The include statement
- </H4>
- <P>
- The include statement
- replaces itself with the contents of a file.
- It is functionally similar to the C
- <TT>#include</TT>
- statement but uses a different syntax:
- <DL><DT><DD><TT><PRE>
- <<I>filename</I>
- </PRE></TT></DL>
- The contents of the file are evaluated
- as they are read.
- An include statement may be used anywhere except
- in a recipe.
- </P>
- <P>
- Unlike
- <TT>make</TT>,
- <TT>mk</TT>
- has no built-in rules. Instead,
- the include statement allows generic rules
- to be imported from a prototype
- <TT>mkfile</TT>;
- most Plan 9
- <TT>mkfiles</TT>
- use this approach [Flan95].
- </P>
- <H4>5 Rules
- </H4>
- <P>
- A rule has four elements: targets,
- prerequisites, attributes, and a recipe.
- It has the form:
- <DL><DT><DD><TT><PRE>
- <I>targets</I>:<I>attributes</I>:<I>prerequisites</I>
- <I>recipe</I>
- </PRE></TT></DL>
- The first line, containing the
- targets, attributes, and prerequisites is
- the
- <I>rule header</I>;
- it
- must begin at the left margin.
- The recipe contains zero or more lines,
- each of which begins with white space.
- One or more targets must be specified but the
- attributes, prerequisites, and recipe are optional.
- A rule specifies
- a dependency between the target(s) and its prerequisite(s),
- the recipe brings the target(s)
- up to date with the prerequisite(s) and
- attributes modify
- <TT>mk</TT>'<TT>s</TT>
- evaluation of the dependency.
- </P>
- <P>
- Normally the target is a file that depends
- on one or more prerequisite files.
- <TT>Mk</TT>
- compares the modification times of each target
- and each prerequisite; a target is considered out of date
- when it does not exist or when a prerequisite has been modified
- more recently.
- When a target is out of date,
- <TT>mk</TT>
- executes the
- recipe to bring it up to date.
- When the recipe completes,
- the modification time of the target is checked and
- used in later dependency evaluations.
- If the recipe does not update the target,
- evaluation continues with the out of date target.
- </P>
- <P>
- A prerequisite of one rule
- may be the target of another. When
- this happens, the rules cascade
- to define a multi-step procedure.
- For example,
- an executable target depends on prerequisite
- object files, each of which is a target
- in a rule with a C source file as the prerequisite.
- <TT>Mk</TT>
- follows a chain of dependencies until it encounters
- a prerequisite that is not a target of another rule
- or it finds a target that
- is up to date. It then
- executes the recipes in reverse order to produce
- the desired target.
- </P>
- <P>
- The rule header is evaluated when the rule is read.
- Variables are replaced by their values, namelists are
- generated, and
- commands are replaced by their
- output at this time.
- </P>
- <P>
- Most attributes modify
- <TT>mk</TT>'<TT>s</TT>
- evaluation of a rule.
- An attribute is usually a single letter but some
- are more complicated.
- This paper only discusses commonly used attributes;
- see
- <A href="/magic/man2html/1/mk"><I>mk</I>(1)
- </A>for a complete list.
- </P>
- <P>
- The
- <TT>V</TT>
- attribute identifies a
- <I>virtual</I>
- target;
- that is, a target that is not a file.
- For example,
- <DL><DT><DD><TT><PRE>
- clean:V:
- rm *.<I>O </I>O.out
- </PRE></TT></DL>
- removes executables and compiler intermediate files.
- The target is virtual because it does not refer to a file named
- <TT>clean</TT>.
- Without the attribute, the recipe would not be
- executed if a file named
- <TT>clean</TT>
- existed.
- The
- <TT>Q</TT>
- attribute
- silences the printing of a recipe before
- execution.
- It is useful when the output of a recipe is
- similar to the recipe:
- <DL><DT><DD><TT><PRE>
- default:QV:
- echo 'No default target; use mk all or mk install'
- </PRE></TT></DL>
- </P>
- <P>
- The recipe is an
- <TT>rc</TT>
- script. It is optional but when it is
- missing, the rule is handled specially, as described later.
- Unlike
- <TT>make</TT>,
- <TT>mk</TT>
- executes recipes without interpretation.
- After
- stripping the first white space character from each line
- it passes the entire recipe to
- <TT>rc</TT>
- on standard input.
- Since
- <TT>mk</TT>
- does not interpret a recipe,
- escape conventions are exactly those of
- <TT>rc</TT>.
- Scripts for
- <TT>awk</TT>
- and
- <TT>sed</TT>
- commands can be embedded exactly as they would
- be entered from the command line.
- <TT>Mk</TT>
- invokes
- <TT>rc</TT>
- with the
- <TT>-e</TT>
- flag, which causes
- <TT>rc</TT>
- to stop if any command
- in the recipe exits with a non-zero status; the
- <TT>E</TT>
- attribute overrides this behavior and allows
- <TT>rc</TT>
- to continue executing in the face of errors.
- Before a recipe is executed, variables are exported
- to the environment where they are available to
- <TT>rc</TT>.
- Commands in the recipe may not read from
- standard input because
- <TT>mk</TT>
- uses it internally.
- </P>
- <P>
- References to a variable can yield different
- values depending on the location of the
- reference in the
- <TT>mkfile</TT>.
- <TT>Mk</TT>
- resolves variable references
- in assignment statements and rule headers
- when the statement is read. Variable references
- in recipes are evaluated by
- <TT>rc</TT>
- when the recipe is executed; this
- happens after the entire
- <TT>mkfile</TT>
- has been read. The value of a variable in a recipe
- is the last value assigned in the file. For example,
- <DL><DT><DD><TT><PRE>
- STRING=all
- all:VQ:
- echo <I>STRING
- STRING=none
- </PRE></TT></DL>
- produces the message
- </I><TT>none</TT><I>.
- A variable assignment in a recipe
- does not affect the value of the variable in the
- </I><TT>mkfile</TT><I>
- for two reasons.
- First,
- </I><TT>mk</TT><I>
- does not import values from
- the environment when a recipe completes;
- one recipe cannot pass a value through
- the environment to another recipe.
- Second, no recipe is executed until
- </I><TT>mk</TT><I>
- has completed its evaluation, so even if a variable
- were changed,
- it would not affect the dependency evaluation.
- </P>
- </I><H4>6 Metarules
- </H4>
- <P>
- A
- <I>metarule</I>
- is a rule based on a pattern.
- The pattern selects a class of target(s) and
- identifies related prerequisites.
- <TT>Mk</TT>
- metarules may select targets and prerequisites
- based on any criterion that can be described by a pattern, not just
- the suffix transformations associated with program
- construction.
- </P>
- <P>
- Metarule patterns are either
- <I>intrinsic</I>
- or regular expressions conforming to the
- syntax of
- <A href="/magic/man2html/6/regexp"><I>regexp</I>(6).
- </A>The intrinsic patterns are shorthand
- for common regular expressions.
- The intrinsic pattern
- <TT>%</TT>
- matches one or more of anything; it is equivalent to
- the regular expression
- <TT>`.+'</TT>.
- The other intrinsic pattern,
- <TT>&</TT>,
- matches one or more of any characters except <TT>`/'</TT>
- and <TT>`.'</TT>.
- It matches a portion of a path and is
- equivalent to the regular expression
- <TT>`[^./]+'</TT>.
- An intrinsic pattern in a prerequisite references
- the string matched by the same intrinsic pattern in the target.
- For example, the rule
- <DL><DT><DD><TT><PRE>
- %.v: %.c
- </PRE></TT></DL>
- says that a file ending in
- <TT>.v</TT>
- depends on a file of the same name with a
- <TT>.c</TT>
- suffix:
- <TT>foo.v</TT>
- depends on
- <TT>foo.c</TT>,
- <TT>bar.v</TT>
- depends on
- <TT>bar.c</TT>,
- and so on.
- The string matched by an intrinsic pattern in the target
- is supplied to the recipe in the variable
- <TT></TT>stem<TT>.
- Thus the rule
- <DL><DT><DD><TT><PRE>
- %.</TT><I>O: %.c
- </I><TT>CC </TT><I>CFLAGS </I><TT>stem.c
- </PRE></TT></DL>
- creates an object file for the target architecture from
- a similarly named C source file. If several object
- files are out of date, the rule is applied repeatedly and
- </TT><TT></TT><I>stem</I><TT>
- refers to each file in turn.
- Since there is only one
- </TT><TT>stem</TT><TT>
- variable, there can only be one
- </TT><TT>%</TT><TT>
- or
- </TT><TT>&</TT><TT>
- pattern in a target;
- the pattern
- </TT><TT>%-%.c</TT><TT>
- is illegal.
- </P>
- </TT><P>
- Metarules simplify the
- <TT>mkfile</TT>
- for building programs
- <TT>f1</TT>
- and
- <TT>f2</TT>:
- <DL><DT><DD><TT><PRE>
- </objtype/mkfile
- ALL=f1 f2
- all:V: <I>ALL
- %: %.</I>O
- <I>LD -o </I>target <I>prereq
- %.</I>O: %.c
- <I>CC </I>CFLAGS <I>stem.c
- clean:V:
- rm -f </I>ALL *.[<I>OS]
- </PRE></TT></DL>
- (The variable
- </I><TT></TT><I>OS</I><TT>
- is a list of code characters for all architectures.)
- Here, metarules specify
- compile and load steps for all C source files.
- The loader rule relies on two internal variables
- set by
- </TT><TT>mk</TT><TT>
- during evaluation of the rule:
- </TT><TT></TT><I>target</I><TT>
- is the name of the target(s) and
- </TT><TT></TT><TT>prereq</TT><TT>
- the name of all prerequisite(s).
- Metarules allow this
- </TT><TT>mkfile</TT><TT>
- to be easily extended; a new program
- is supported by adding its name to the third line.
- </P>
- </TT><P>
- A regular expression metarule must have an
- <TT>R</TT>
- attribute.
- Prerequisites may reference matching substrings in
- the target using the form
- <TT>\</TT><I>n</I><TT></TT><I>
- where
- </I><I>n</I><I>
- is a digit from 1 to 9 specifying the
- </I><I>n</I><I>th
- parenthesized sub-expression. In a recipe,
- </I><TT></TT><I>stem</I><I>n</I><I></I><I>
- is the equivalent reference.
- For example, a compile rule could be
- specified using regular expressions:
- <DL><DT><DD><TT><PRE>
- (.+)\.</I>O:R: \1.c
- <I>CC </I>CFLAGS <I>stem1.c
- </PRE></TT></DL>
- Here,
- </I><TT>\1</TT><I>
- and
- </I><TT></TT><I>stem1</I><TT>
- refer to the name of the target object file without the
- suffix. The variable
- </TT><TT></TT><I>stem</I><TT>
- associated with an intrinsic pattern is undefined
- in a regular expression metarule.
- </P>
- </TT><H4>7 Archives
- </H4>
- <P>
- <TT>Mk</TT>
- provides a special mechanism for maintaining an archive.
- An archive member is referenced using the form
- <TT></TT><I>lib</I><TT>(</TT><I>file</I><TT>)</TT><I>
- where
- </I><I>lib</I><I>
- is the name of the archive and
- </I><I>file</I><I>
- is the name of the member. Two rules define the
- dependency between an object file and its membership
- in an archive:
- <DL><DT><DD><TT><PRE>
- </I>LIB(foo.8):N: foo.8
- <I>LIB: </I>LIB(foo.8)
- ar rv <I>LIB foo.8
- </PRE></TT></DL>
- The first rule establishes a dependency between the
- archive member and the object file.
- Normally,
- </I><TT>mk</TT><I>
- detects an error when a target does not exist and the rule
- contains no recipe; the
- </I><TT>N</TT><I>
- attribute overrides this behavior because the subsequent rule
- updates the member.
- The second
- rule establishes the dependency between the member and
- the archive; its recipe inserts the member
- into the archive.
- This two-step specification allows the modification time
- of the archive
- to represent the state of its members. Other rules
- can then specify the archive as a prerequisite instead of
- listing each member.
- </P>
- </I><P>
- A metarule generalizes library maintenance:
- <DL><DT><DD><TT><PRE>
- LIB=lib.a
- OBJS=etoa.O atoe.<I>O ebcdic.</I>O
- <I>LIB(%):N: %
- </I>LIB: <I>{OBJS:%=</I>LIB(%)}
- ar rv <I>LIB </I>OBJS
- </PRE></TT></DL>
- The namelist prerequisite of the
- <TT></TT><I>LIB</I><TT>
- target generates archive member names for each object file name;
- for example,
- </TT><TT>etoa.</TT><TT>O</TT><TT>
- becomes
- </TT><TT>lib.a(etoa.</TT><I>O)</I><TT>.
- This formulation always updates all members.
- This is acceptable for a small archive, but may
- be slow for a big one.
- The rule
- <DL><DT><DD><TT><PRE>
- </TT><I>LIB: </I><I>{OBJS:%=</I><I>LIB(%)}
- ar rv </I><I>LIB `{membername </I><I>newprereq}
- </PRE></TT></DL>
- only updates out of date object files.
- The internal variable
- </I><TT></TT><I>newprereq</I><TT>
- contains the names of the out of
- date prerequisites. The
- </TT><TT>rc</TT><TT>
- script
- </TT><TT>membername</TT><TT>
- transforms an archive member specification into a file name:
- it translates
- </TT><TT>lib.a(etoa.</TT><TT>O)</TT><TT>
- into
- </TT><TT>etoa.</TT><I>O</I><TT>.
- </P>
- </TT><P>
- The
- <TT>mkfile</TT>
- <DL><DT><DD><TT><PRE>
- </objtype/mkfile
- LIB=lib.a
- OBJS=etoa.<I>O atoe.</I>O ebcdic.<I>O
- prog: main.</I>O <I>LIB
- </I>LD -o <I>target </I>prereq
- <I>LIB(%):N: %
- </I>LIB: <I>{OBJS:%=</I>LIB(%)}
- ar rv <I>LIB </I>OBJS
- </PRE></TT></DL>
- builds a program by loading it with a library.
- </P>
- <H4>8 Evaluation algorithm
- </H4>
- <P>
- For each target of interest,
- <TT>mk</TT>
- uses the rules in a
- <TT>mkfile</TT>
- to build a data
- structure called a dependency graph. The nodes of
- the graph represent targets and prerequisites;
- a directed arc
- from one node to another indicates that
- the file associated with the first node depends
- on the file associated with the second.
- When the
- <TT>mkfile</TT>
- has been completely read, the graph is analyzed.
- In the first step, implied dependencies are resolved by
- computing the
- <I>transitive closure</I>
- of the graph.
- This calculation extends the graph to include all
- targets that are potentially
- derivable from the rules in the
- <TT>mkfile</TT>.
- Next the graph is checked for cycles;
- <TT>make</TT>
- accepts cyclic dependencies, but
- <TT>mk</TT>
- does not allow them.
- Subsequent steps
- prune subgraphs that are irrelevant for producing the
- desired target and verify that there is only one way
- to build it.
- The recipes associated with the
- nodes on the longest path between the
- target and an out of date prerequisite
- are then executed in reverse order.
- </P>
- <P>
- The transitive closure calculation is sensitive to
- metarules; the patterns often select many potential targets
- and cause the graph to grow rapidly.
- Fortunately,
- dependencies associated with the desired target
- usually form a small part of the graph, so, after
- pruning, analysis is tractable.
- For example, the rules
- <DL><DT><DD><TT><PRE>
- %: x.%
- recipe1
- x.%: %.k
- recipe2
- %.k: %.f
- recipe3
- </PRE></TT></DL>
- produce a graph with four nodes for each file in the
- current directory.
- If the desired target is
- <TT>foo</TT>,
- <TT>mk</TT>
- detects the dependency between it
- and the original file
- <TT>foo.f</TT>
- through intermediate dependencies on
- <TT>foo.k</TT>
- and
- <TT>x.foo</TT>.
- Nodes associated with other files are deleted during pruning because
- they are irrelevant to the production of
- <TT>foo</TT>.
- </P>
- <P>
- <TT>Mk</TT>
- avoids infinite cycles by evaluating
- each metarule once.
- Thus, the rule
- <DL><DT><DD><TT><PRE>
- %: %.z
- cp <I>prereq </I>prereq.z
- </PRE></TT></DL>
- copies the prerequisite file once.
- </P>
- <H4>9 Conventions for evaluating rules
- </H4>
- <P>
- There must be only one
- way to build each target. However, during evaluation
- metarule patterns often select potential targets that
- conflict with the
- targets of other rules.
- <TT>Mk</TT>
- uses several conventions to resolve ambiguities
- and to select the proper dependencies.
- </P>
- <P>
- When a target selects more than one rule,
- <TT>mk</TT>
- chooses a regular rule
- over a metarule.
- For example, the
- <TT>mkfile</TT>
- <DL><DT><DD><TT><PRE>
- </<I>objtype/mkfile
- FILES=f1.</I>O f2.<I>O f3.</I>O
- prog: <I>FILES
- </I>LD -o <I>target </I>prereq
- %.<I>O: %.c
- </I>CC <I>CFLAGS </I>stem.c
- f2.<I>O: f2.c
- </I>CC f2.c
- </PRE></TT></DL>
- contains two rules that could build
- <TT>f2.</TT><I>O</I><TT>.
- </TT><TT>Mk</TT><TT>
- selects the last rule because its target,
- </TT><TT>f2.</TT><TT>O</TT><TT>,
- is explicitly specified, while the
- </TT><TT>%.</TT><I>O</I><TT>
- rule is a metarule. In effect,
- the explicit rule for
- </TT><TT>f2.</TT><TT>O</TT><TT>
- overrides the general rule for building object files from
- C source files.
- </P>
- </TT><P>
- When a rule has a target and prerequisites but no recipe,
- those prerequisites are added to all other rules with
- recipes that have the same target.
- All prerequisites, regardless of where they were specified, are
- exported to the recipe in variable
- <TT></TT><I>prereq</I><TT>.
- For example, in
- <DL><DT><DD><TT><PRE>
- </</TT>objtype/mkfile
- FILES=f1.<I>O f2.</I>O f3.<I>O
- prog: </I>FILES
- <I>LD -o </I>target <I>prereq
- %.</I>O: hdr.h
- %.<I>O: %.c
- </I>CC <I>CFLAGS </I>stem.c
- </PRE></TT></DL>
- the second rule adds
- <TT>hdr.h</TT>
- as a prerequisite of the compile metarule;
- an object file produced from a C source file
- depends on
- <TT>hdr.h</TT>
- as well as the source file. Notice that the recipe of
- the compile rule uses
- <TT></TT><I>stem.c</I><TT>
- instead of
- </TT><TT></TT><TT>prereq</TT><TT>
- because the latter specification would attempt to compile
- </TT><TT>hdr.h</TT><TT>.
- </P>
- </TT><P>
- When a target is virtual and there is no other rule with
- the same target,
- <TT>mk</TT>
- evaluates each prerequisite.
- For example, adding the rule
- <DL><DT><DD><TT><PRE>
- all:V: prog
- </PRE></TT></DL>
- to the preceding example builds the executable
- when either
- <TT>prog</TT>
- or
- <TT>all</TT>
- is the specified target. In effect, the
- <TT>all</TT>
- target is an alias for
- <TT>prog</TT>.
- </P>
- <P>
- When two rules have identical rule headers and both have
- recipes, the later rule replaces the former one.
- For example,
- if a file named
- <TT>mkrules</TT>
- contains
- <DL><DT><DD><TT><PRE>
- <I>O.out: </I>OFILES
- <I>LD </I>LFLAGS <I>OFILES
- %.</I>O: %.c
- <I>CC </I>CFLAGS <I>stem.c
- </PRE></TT></DL>
- the
- </I><TT>mkfile</TT><I>
- <DL><DT><DD><TT><PRE>
- OFILES=f1.</I>O f2.<I>O f3.</I>O
- <mkrules
- <I>O.out: </I>OFILES
- <I>LD </I>LFLAGS -l <I>OFILES -lbio -lc
- </PRE></TT></DL>
- overrides the general loader rule with a special
- rule using a non-standard library search sequence.
- A rule is neutralized by overriding it with a rule
- with a null recipe:
- <DL><DT><DD><TT><PRE>
- <mkrules
- </I>O.out:Q: <I>OFILES
- ;
- </PRE></TT></DL>
- The
- </I><TT>Q</TT><I>
- attribute suppresses the printing of the semicolon.
- </P>
- </I><P>
- When a rule has no prerequisites, the recipe is executed
- only when the target does not exist. For example,
- <DL><DT><DD><TT><PRE>
- marker:
- touch target
- </PRE></TT></DL>
- defines a rule to manage a marker file.
- If the file exists, it is considered up to date
- regardless of its modification time.
- When a virtual target has no prerequisites the
- recipe is always executed.
- The
- <TT>clean</TT>
- rule is of this type:
- <DL><DT><DD><TT><PRE>
- clean:V:
- rm -f [<I>OS].out *.[</I>OS]
- </PRE></TT></DL>
- When a rule without prerequisites has multiple targets, the
- extra targets are aliases for the rule.
- For example, in
- <DL><DT><DD><TT><PRE>
- clean tidy nuke:V:
- rm -f [<I>OS].out *.[</I>OS]
- </PRE></TT></DL>
- the
- rule can be invoked by any of three names.
- The first rule in a
- <TT>mkfile</TT>
- is handled specially:
- when
- <TT>mk</TT>
- is invoked without a command line target
- all targets of the first non-metarule are built.
- If that rule has multiple targets, the recipe
- is executed once for each target; normally, the recipe
- of a rule with multiple targets is only executed once.
- </P>
- <P>
- A rule applies to a target only when its prerequisites
- exist or can be derived. More than one rule may have the
- same target as long as only one rule with a recipe
- remains applicable after the dependency evaluation completes.
- For example, consider a program built from C
- and assembler source files. Two rules produce
- object files:
- <DL><DT><DD><TT><PRE>
- %.<I>O: %.c
- </I>CC <I>CFLAGS </I>stem.c
- %.<I>O: %.s
- </I>AS <I>AFLAGS </I>stem.s
- </PRE></TT></DL>
- As long as there are not two source files with names like
- <TT></TT><I>foo</I><TT>.c</TT><I>
- and
- </I><TT></TT><I>foo</I><TT>.s</TT><I>,
- </I><TT>mk</TT><I>
- can unambiguously select the proper rule.
- If both files exist,
- the rules are ambiguous
- and
- </I><TT>mk</TT><I>
- exits with an error message.
- </P>
- </I><P>
- In Plan 9, many programs consist of portable code stored
- in one directory and architecture-specific source stored in
- another.
- For example, the
- <TT>mkfile</TT>
- <DL><DT><DD><TT><PRE>
- </<I>objtype/mkfile
- FILES=f1.</I>O f2.<I>O f3.</I>O f3.<I>O
- prog: </I>FILES
- <I>LD -o </I>target <I>prereq
- %.</I>O: %.<I>c
- </I>CC <I>CFLAGS </I>stem.c
- %.<I>O: ../port/%.c
- </I>CC <I>CFLAGS ../port/</I>stem.c
- </PRE></TT></DL>
- builds the program named
- <TT>prog</TT>
- using portable code in directory
- <TT>../port</TT>
- and architecture-specific code in the current directory.
- As long as the
- names of the C source files in
- <TT>../port</TT>
- do not conflict with the names of files in the current directory,
- <TT>mk</TT>
- selects the appropriate rule to build the object file.
- If like-named files exist in both directories, the
- specification is ambiguous and an explicit target
- must be specified to resolve the ambiguity.
- For example,
- adding the rule
- <DL><DT><DD><TT><PRE>
- f2.<I>O: f2.c
- </I>CC <I>CFLAGS </I>f2.c
- </PRE></TT></DL>
- to the previous
- <TT>mkfile</TT>
- uses the architecture-specific version of
- <TT>f2.c</TT>
- instead of the portable one.
- Here, the explicit rule unambiguously
- documents which of the
- like-named source files is used to build the program.
- </P>
- <P>
- <TT>Mk</TT>'<TT></TT>s
- heuristics can produce unintended results
- when rules are not carefully specified.
- For example, the rules that build
- object files from C or assembler source files
- <DL><DT><DD><TT><PRE>
- %.<I>O: %.c
- </I>CC <I>CFLAGS </I>stem.c
- %.<I>O: %.s
- </I>AS <I>AFLAGS </I>stem.s
- </PRE></TT></DL>
- illustrate a subtle pratfall.
- Adding a header file dependency to the compile rule
- <DL><DT><DD><TT><PRE>
- %.<I>O: %.c hdr.h
- </I>CC <I>CFLAGS </I>stem.c
- </PRE></TT></DL>
- produces the error message
- <DL><DT><DD><TT><PRE>
- <TT>don't know how to make '</TT><I>file</I><TT>.c'</TT><I>
- </PRE></TT></DL>
- when </I><I>file</I><I>.s is an assembler
- source file.
- This occurs because
- </I><TT></TT><I>file</I><TT>.s</TT><I>
- satisfies the assemble rule and
- </I><TT>hdr.h</TT><I>
- satisfies the compile rule, so
- either rule can potentially produce the target.
- When a prerequisite exists or can be
- derived,
- all other prerequisites in that
- rule header must exist or be derivable; here,
- the existence of
- </I><TT>hdr.h</TT><I>
- forces the evaluation of a C source file.
- Specifying the dependencies in different
- rules avoids this interpretation:
- <DL><DT><DD><TT><PRE>
- %.</I><I>O: hdr.h
- %.</I><I>O: %.c
- </I><I>CC </I><I>CFLAGS </I><I>stem.c
- </PRE></TT></DL>
- Although
- </I><TT>hdr.h</TT><I>
- is an additional prerequisite of the compile rule,
- the two rules are evaluated independently and
- the existence of the C source file is not linked
- to the existence of the header file.
- However, this specification describes a different
- dependency. Originally, only object
- files derived from C files depended on
- </I><TT>hdr.h</TT><I>;
- now all object files, including those built
- from assembler source, depend on the header file.
- </P>
- </I><P>
- Metarule patterns should be as restrictive as possible to
- prevent conflicts with other rules.
- Consider the
- <TT>mkfile</TT>
- <DL><DT><DD><TT><PRE>
- </objtype/mkfile
- BIN=/<I>objtype/bin
- PROG=foo
- install:V: </I>BIN/<I>PROG
- %: %.c
- </I>CC <I>stem.c
- </I>LD -o <I>target </I>stem.<I>O
- </I>BIN/%: %
- mv <I>stem </I>target
- </PRE></TT></DL>
- The first target builds an executable
- in the local directory; the second
- installs it in the directory
- of executables for the architecture.
- Invoking
- <TT>mk</TT>
- with the
- <TT>install</TT>
- target produces:
- <DL><DT><DD><TT><PRE>
- mk: ambiguous recipes for /mips/bin/foo:
- /mips/bin/foo <-(mkfile:8)- /mips/bin/foo.c <-(mkfile:12)- foo.c
- /mips/bin/foo <-(mkfile:12)- foo <-(mkfile:8)- foo.c
- </PRE></TT></DL>
- The prerequisite of the
- <TT>install</TT>
- rule,
- <TT></TT><I>BIN/</I><TT>PROG</TT><I>,
- matches both metarules because the
- </I><TT>%</TT><I>
- pattern matches everything.
- The
- </I><TT>&</TT><I>
- pattern restricts the compile rule to files in the
- current directory and avoids the conflict:
- <DL><DT><DD><TT><PRE>
- &: &.c
- </I><I>CC </I><I>stem.c
- </I><I>LD -o </I><I>target </I><I>stem.</I><I>O
- </PRE></TT></DL>
- </P>
- </I><H4>10 Missing intermediates
- </H4>
- <P>
- <TT>Mk</TT>
- does not build a missing intermediate file if a target
- is up to date with the prerequisites of the intermediate.
- For example,
- when an executable is up to date with its source file,
- <TT>mk</TT>
- does not compile the source to create a missing object file.
- The evaluation only applies
- when a target is considered up to date by pretending that the
- intermediate exists. Thus, it does not apply
- when the intermediate is a command line target
- or when it has no prerequisites.
- </P>
- <P>
- This capability is useful for
- maintaining archives. We can modify the archive
- update recipe to remove object files after
- they are archived:
- <DL><DT><DD><TT><PRE>
- <I>LIB(%):N: %
- </I>LIB: <I>{OBJS:%=</I>LIB(%)}
- names=`{membername <I>newprereq}
- ar rv </I>LIB <I>names
- rm -f </I>names
- </PRE></TT></DL>
- A subsequent
- <TT>mk</TT>
- does not remake the object files as long as the members
- of the archive remain up to date with the source files.
- The
- <TT>-i</TT>
- command line option overrides this behavior
- and causes all intermediates to be built.
- </P>
- <H4>11 Alternative out-of-date determination
- </H4>
- <P>
- Sometimes the modification time is not useful
- for deciding when a target and prerequisite are out of date.
- The
- <TT>P</TT>
- attribute replaces the default mechanism with the result of
- a command. The command immediately follows the attribute
- and is repeatedly executed with each
- target and each prerequisite as its arguments;
- if its exit status is non-zero, they are considered out of date
- and the recipe is executed. Consider the
- <TT>mkfile</TT>
- <DL><DT><DD><TT><PRE>
- foo.ref:Pcmp -s: foo
- cp <I>prereq </I>target
- </PRE></TT></DL>
- The command
- <DL><DT><DD><TT><PRE>
- cmp -s foo.ref foo
- </PRE></TT></DL>
- is executed and if
- <TT>foo.ref</TT>
- differs from
- <TT>foo</TT>,
- the latter file is copied to the former.
- </P>
- <H4>12 Parallel processing
- </H4>
- <P>
- When possible,
- <TT>mk</TT>
- executes recipes in parallel.
- The variable
- <TT></TT><I>NPROC</I><TT>
- specifies the maximum number of simultaneously executing
- recipes.
- Normally it is imported from the environment,
- where the system has set it to the number of available processors.
- It can be decreased by assigning a new
- value and can be set to 1 to force single-threaded recipe execution.
- This is necessary when several targets access
- a common resource such as
- a status file or data base.
- When there is no dependency between targets,
- </TT><TT>mk</TT><TT>
- assumes the
- recipes can be
- executed concurrently.
- Normally, this allows
- multiple prerequisites to be built simultaneously;
- for example, the object file prerequisites of
- a load rule can be produced by compiling the source files in parallel.
- </TT><TT>Mk</TT><TT>
- does not define the order of execution of independent recipes.
- When the prerequisites of a rule are not independent,
- the dependencies between them should be specified in a rule or the
- </TT><TT>mkfile</TT><TT>
- should be single-threaded.
- For example, the archive update rules
- <DL><DT><DD><TT><PRE>
- </TT>LIB(%):N: %
- <I>LIB: </I>{OBJS:%=<I>LIB(%)}
- ar rv </I>LIB `{membername <I>newprereq}
- </PRE></TT></DL>
- compile source files in parallel but update
- all members of the archive at once.
- It is a mistake to merge the two rules
- <DL><DT><DD><TT><PRE>
- </I>LIB(%): %
- ar rv <I>LIB </I>stem
- </PRE></TT></DL>
- because an
- <TT>ar</TT>
- command is executed for every
- member of the library. Not only is this
- inefficient, but the archive is updated
- in parallel, making interference likely.
- </P>
- <P>
- The
- <TT></TT><I>nproc</I><TT>
- environment variable contains a number associated
- with the processor executing a recipe.
- It can be used to create unique
- names when the
- recipe may be executing simultaneously on several processors.
- Other maintenance tools provide mechanisms to control recipe
- scheduling explicitly [Cmel86], but
- </TT><TT>mk</TT>'<TT>s</TT>
- general rules are sufficient for all but the most unusual cases.
- </P>
- <H4>13 Deleting target files on errors
- </H4>
- <P>
- The
- <TT>D</TT>
- attribute
- causes
- <TT>mk</TT>
- to remove the target file when a
- recipe terminates prematurely.
- The error message describing the
- termination condition warns
- of the deletion.
- A partially built file is doubly dangerous:
- it is not only wrong, but is also
- considered to be up to date so
- a subsequent
- <TT>mk</TT>
- will not rebuild it. For example,
- <DL><DT><DD><TT><PRE>
- pic.out:D: mk.ms
- pic prereq | tbl | troff -ms > <I>target
- </PRE></TT></DL>
- produces the message
- <DL><DT><DD><TT><PRE>
- </I><TT>mk: pic mk.ms | ... : exit status=rc 685: deleting 'pic.out'</TT><I>
- </PRE></TT></DL>
- if any program in the recipe exits with an error status.
- </P>
- </I><H4>14 Unspecified dependencies
- </H4>
- <P>
- The
- <TT>-w</TT>
- command line flag forces the
- files following the flag to be treated
- as if they were just modified.
- We can use this flag with a command that selects files
- to force a build based on the selection criterion.
- For example, if the declaration of
- a global variable named
- <I>var</I>
- is changed in a header file,
- all source files that reference
- it can be rebuilt with the command
- <DL><DT><DD><TT><PRE>
- mk -w`{grep -l <I>var</I> *.[cyl]}
- </PRE></TT></DL>
- </P>
- <H4>15 Conclusion
- </H4>
- <P>
- There are many programs related to
- <TT>make</TT>,
- each choosing a different balance between
- specialization and generality.
- <TT>Mk</TT>
- emphasizes generality but allows
- customization through its pattern specifications and
- include facilities.
- </P>
- <P>
- Plan 9 presents a difficult maintenance environment
- with its heterogeneous
- architectures and languages.
- <TT>Mk</TT>'<TT>s</TT>
- flexible specification language and simple
- interaction with
- <TT>rc</TT>
- work well in this environment.
- As a result,
- Plan 9 relies on
- <TT>mk</TT>
- to automate almost all maintenance.
- Tasks as diverse as updating the
- network data base, producing the manual,
- or building a release are expressed as
- <TT>mk</TT>
- procedures.
- </P>
- <H4>16 References
- </H4>
- <br> <br>
- [Cmel86] R. F. Cmelik,
- ``Concurrent Make: A Distributed Program in Concurrent C'',
- AT&T Bell Laboratories Technical Report, 1986.
- <br> <br>
- [Feld79] S. I. Feldman,
- ``Make ­ a program for maintaining computer programs'',
- Software Practice & Experience ,
- 1979
- Vol 9 #4,
- pp. 255-266.
- <br> <br>
- [Flan95] Bob Flandrena,
- ``Plan 9 Mkfiles'',
- this volume.
- <br> <br>
- [Hume87] A. G. Hume,
- ``Mk: A Successor to Make'',
- USENIX Summer Conf. Proc.,
- Phoenix, Az.
- <H4>17 Appendix: Differences between
- <TT>make</TT>
- and
- <TT>mk</TT>
- </H4>
- <P>
- The differences between
- <TT>mk</TT>
- and
- <TT>make</TT>
- are:
- </P>
- <UL>
- <LI>
- <TT>Make</TT>
- builds targets when it needs them, allowing systematic use of side effects.
- <TT>Mk</TT>
- constructs the entire dependency graph before building any target.
- <LI>
- <TT>Make</TT>
- supports suffix rules and
- <TT>%</TT>
- metarules.
- <TT>Mk</TT>
- supports
- <TT>%</TT>
- and regular expression metarules.
- (Older versions of
- <TT>make</TT>
- support only suffix rules.)
- <LI>
- <TT>Mk</TT>
- performs transitive closure on metarules,
- <TT>make</TT>
- does not.
- <LI>
- <TT>Make</TT>
- supports cyclic dependencies,
- <TT>mk</TT>
- does not.
- <LI>
- <TT>Make</TT>
- evaluates recipes one line at a time, replacing variables by their values and
- executing some commands internally.
- <TT>Mk</TT>
- passes the entire recipe to the shell without
- interpretation or internal execution.
- <LI>
- <TT>Make</TT>
- supports parallel execution of single-line recipes when building
- the prerequisites for specified targets.
- <TT>Mk</TT>
- supports parallel execution of all recipes.
- (Older versions of
- <TT>make</TT>
- did not support parallel execution.)
- <LI>
- <TT>Make</TT>
- uses special targets (beginning with a period)
- to indicate special processing.
- <TT>Mk</TT>
- uses attributes to modify rule evaluation.
- <LI>
- <TT>Mk</TT>
- supports virtual
- targets that are independent of the file system.
- <LI>
- <TT>Mk</TT>
- allows non-standard out-of-date determination,
- <TT>make</TT>
- does not.
- </ul>
- <P>
- It is usually easy to convert a
- <TT>makefile</TT>
- to or from an equivalent
- <TT>mkfile</TT>.
- </P>
- <br> <br>
- <A href=http://www.lucent.com/copyright.html>
- Copyright</A> © 2004 Lucent Technologies Inc. All rights reserved.
- </body></html>
|