/*ident	"@(#)cls4:tools/pt/README.ptenv	1.5" */

/*******************************************************************************
 
C++ source for the C++ Language System, Release 3.0.  This product
is a new release of the original cfront developed in the computer
science research center of AT&T Bell Laboratories.

Copyright (c) 1993  UNIX System Laboratories, Inc.
Copyright (c) 1991, 1992 AT&T and UNIX System Laboratories, Inc.
Copyright (c) 1984, 1989, 1990 AT&T.  All Rights Reserved.

THIS IS UNPUBLISHED PROPRIETARY SOURCE CODE of AT&T and UNIX System
Laboratories, Inc.  The copyright notice above does not evidence
any actual or intended publication of such source code.

*******************************************************************************/
Template Environment Release Notes For 3.0.1
January 1992


INTRODUCTION

This writeup describes the details of installing and using the
template environment for 3.0.1.  It should be read in conjunction
with the papers:

	- Template Instantiation in C++ Release 3.0 - Overview

	- Template Instantiation in C++ Release 3.0 - User Guide

	- Template Instantiation in C++ Release 3.0 - Implementation Notes

and chapter 14 in the Annotated Reference Manual.


INSTALLATION

There are seven parts to the template environment:

	CC		- a modified version

	ptcomp.c	- a C program to handle compile-time actions

	ptlink.c	- a C program to handle link-time actions

	ptutil.c	- utility functions

	pt.h		- header for configuring the environment

	dem.c		- the name demangler, used by ptlink

	dem.h		- header file for the demangler

CC points at the ptcomp and ptlink binaries.  These binaries are
compiled in the makefiles.  However, if you need to do compilation
separately, the steps are:

	$ cc -c ptutil.c

	$ cc ptcomp.c ptutil.o -o ptcomp

	$ cc ptlink.c ptutil.o dem.c -o ptlink

Note that the right setting of CLIP_UNDER is necessary in dem.c (see
the demangler release notes).


CUSTOMIZATION

Necessary customization can be done by editting pt.h.  Any functions
that might be nonportable are in ptutil.c, but you shouldn't have to
edit this file.  What follows is a sequential walkthrough of pt.h.

1.  NMPATH should be set to the path and options required to produce
BSD or SysV.3 style nm output.  Typically this involves specifying -p
as an option (for example, on HP or SysV.4 systems).

2.  If your system has vfork() along with fork(), you should change
the second entry in pt.h.  This will make subprogram invocation go
faster.  vfork() is likely to be available only on BSD derivatives
such as SunOS.

3.  LSPATH should be set to the local path for ls.

4.  SRC_EXT, INC_EXT, OBJ_EXT, ARC_EXT, and DDC_EXT should be set to
the local values for your system.  These are used for files created in
the repository, as well as for template and template argument type
headers.

5.  If your operating system supports long filenames (more than 14
characters), enable LONG_NAMES or say "-DLONG_NAMES" when building
ptlink.  This setting affects the names that are created by ptlink
when it does instantiation; long names are nice but not essential.
Note that even on systems with long name support, the archiver (ar)
may not handle such names, and so object files from the repository
would have to be renamed before an archive library is built.
Typically, only BSD derivatives (HP, Sun) support long names.

6.  There is an option SLOW_SYSTEM that should be set if you don't
want to use the optimized versions of system() or popen() included in
ptutil.c.

7.  ptcomp.c and ptlink.c both assume repository locking.  If you
don't want to use locking (with possible resulting conflicts), #define
NO_LOCK.  Otherwise, choose the lock type fcntl(), lockf(), or flock()
most suitable for your UNIX version.  Note that repository locking is
only as good as the implementation of these system calls for a given
version of UNIX.  Note also that there are stub functions controlled
by NO_LOCK where you can implement your own locking scheme.  LOCK_MAX
and LOCK_SLEEP can be changed to alter the sleep interval between
attempts to get a lock, and the number of lock tries before a fatal
error is given.

8.  Signals are used in a couple of places.  If you don't wish to use
them, to disable interrupts when the repository is being rewritten, or
to facilitate cleanup of objects in the local directory, #define
NO_SIGNAL.


WHAT IF YOU HAVE YOUR OWN CC?

The CC script as distributed has seven commented sections that delimit
PT processing.  These are named:

	# PT environment

	# PT setup

	# PT option parsing 1

	# PT option parsing 2

	# PT option parsing 3

	# PT compile-time actions

	# PT link-time actions

Each section ends with '# end PT'.


CC OPTIONS, CODING CONVENTIONS, EXAMPLES

See the user guide.


TOOLS

The tools mentioned in the user guide are included in the
distribution as tool1 and tool2.


KNOWN PROBLEMS

1.  The instantiation scheme does not work with DENSE (31-character
names).

2.  Literal arguments to templates are assumed to be constant (this is
really a language change).

3.  It is not possible to pass quoted strings using the -I and -D
options to the link phase.  For example, -I" " will not work.

4.  CC does not recognize .i files as being special for template
purposes.  That is, no processing (ptcomp) is done on them.  This may
or may not be changed in the future.  Likewise, the CC -F option has
no effect on instantiation.

5.  On some machine types (Sun SPARC), there are occasional problems
with using fcntl() to lock repositories in /tmp or /usr/tmp.  The
problem appears to be a bug in the kernel lock manager.  The patch
from Sun to fix this problem is #100075-07.


USE OF CHECKSUMS FOR DEPENDENCY MANAGEMENT

The next section describes a feature new to 3.0.1.  It requires a
one-time rebuilding of repositories.  3.0.1 is NOT compatible with 3.0
repositories.  However, if you compile ptlink.c with -DCHECKSUM, you
can get back the old scheme.  The new dependency checking scheme is
roughly 50 times faster than the checksum approach.


NEW DEPENDENCY MANAGEMENT SCHEME

The 3.0 version of the template instantiation system has two schemes
for checking whether instantiated objects are out of date.  The first
scheme is use of checksums on the preprocessed instantiation file
text.  This is accurate but relatively slow.

The second approach is with the -ptt option; timestamps of #included
headers in the instantiation file are compared with the timestamp of
the instantiation object.  This is fast but fails to check for nested
includes.

What follows is a scheme for extending -ptt to handle nested includes.
Note that some build systems such as nmake already provide this
feature; the proposal is for a generic system usable anywhere.

With the current scheme the repository contains an instantiation file
such as Vector__pt__4_i1A.c which is compiled in directed mode to
produce an instantiation object.  For example, this file might
contain:

	#include "Vector.h"
	#include "Vector.c"
	#include "A.h"

-ptt digs out each of these headers and compares its timestamp against
that of Vector__pt__4_i1A.o.

The headers may, however, include other headers, whose timestamps are
not checked.  To discover these other headers requires a cpp pass,
which is no faster than taking a checksum.  Therefore a scheme must be
devised to cache knowledge of the tree of headers implied by a given
instantiation file.  Additionally, it is necessary to store with the
header list the -I and -D options specified to CC.

The cache will be stored with extension .he; for example,
Vector__pt__4_i1A.he.  The first line will be the -I/-D options and
subsequent lines a sorted list of the names of all headers as reported
by cpp.  An object file will be considered out of date if it is older
than any of the headers on the list.  This is in addition to the
checks made to see if all needed members are present in the object.
An object will also be considered out of date if the -I/-D options are
changed from the previous time.

The cache will be rebuilt just before this check if any of the
following are true:

	1.  The cache does not exist.

	2.  Different -I/-D options are used from the previous time.

	3.  The instantiation file is newer than the cache.

	4.  Any of the files listed in the cache do not exist.

	5.  Any of the files listed in the cache are newer than the
	cache.

	6.  The cache is corrupted.

Cache corruption is detected by storing the cumulative length of all
the previous cache lines as the last line of the cache.