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This is a total conversion of SciTECO to plain C (GNU C11).
The chance was taken to improve a lot of internal datastructures,
fix fundamental bugs and lay the foundations of future features.
The GTK user interface is now in an useable state!
All changes have been squashed together.
The language itself has almost not changed at all, except for:
* Detection of string terminators (usually Escape) now takes
the string building characters into account.
A string is only terminated outside of string building characters.
In other words, you can now for instance write
I^EQ[Hello$world]$
This removes one of the last bits of shellisms which is out of
place in SciTECO where no tokenization/lexing is performed.
Consequently, the current termination character can also be
escaped using ^Q/^R.
This is used by auto completions to make sure that strings
are inserted verbatim and without unwanted sideeffects.
* All strings can now safely contain null-characters
(see also: 8-bit cleanliness).
The null-character itself (^@) is not (yet) a valid SciTECO
command, though.
An incomplete list of changes:
* We got rid of the BSD headers for RB trees and lists/queues.
The problem with them was that they used a form of metaprogramming
only to gain a bit of type safety. It also resulted in less
readble code. This was a C++ desease.
The new code avoids metaprogramming only to gain type safety.
The BSD tree.h has been replaced by rb3ptr by Jens Stimpfle
(https://github.com/jstimpfle/rb3ptr).
This implementation is also more memory efficient than BSD's.
The BSD list.h and queue.h has been replaced with a custom
src/list.h.
* Fixed crashes, performance issues and compatibility issues with
the Gtk 3 User Interface.
It is now more or less ready for general use.
The GDK lock is no longer used to avoid using deprecated functions.
On the downside, the new implementation (driving the Gtk event loop
stepwise) is even slower than the old one.
A few glitches remain (see TODO), but it is hoped that they will
be resolved by the Scintilla update which will be performed soon.
* A lot of program units have been split up, so they are shorter
and easier to maintain: core-commands.c, qreg-commands.c,
goto-commands.c, file-utils.h.
* Parser states are simply structs of callbacks now.
They still use a kind of polymorphy using a preprocessor trick.
TECO_DEFINE_STATE() takes an initializer list that will be
merged with the default list of field initializers.
To "subclass" states, you can simply define new macros that add
initializers to existing macros.
* Parsers no longer have a "transitions" table but the input_cb()
may use switch-case statements.
There are also teco_machine_main_transition_t now which can
be used to implement simple transitions. Additionally, you
can specify functions to execute during transitions.
This largely avoids long switch-case-statements.
* Parsers are embeddable/reusable now, at least in parse-only mode.
This does not currently bring any advantages but may later
be used to write a Scintilla lexer for TECO syntax highlighting.
Once parsers are fully embeddable, it will also be possible
to run TECO macros in a kind of coroutine which would allow
them to process string arguments in real time.
* undo.[ch] still uses metaprogramming extensively but via
the C preprocessor of course. On the downside, most undo
token generators must be initiated explicitly (theoretically
we could have used embedded functions / trampolines to
instantiate automatically but this has turned out to be
dangereous).
There is a TECO_DEFINE_UNDO_CALL() to generate closures for
arbitrary functions now (ie. to call an arbitrary function
at undo-time). This simplified a lot of code and is much
shorter than manually pushing undo tokens in many cases.
* Instead of the ridiculous C++ Curiously Recurring Template
Pattern to achieve static polymorphy for user interface
implementations, we now simply declare all functions to
implement in interface.h and link in the implementations.
This is possible since we no longer hace to define
interface subclasses (all state is static variables in
the interface's *.c files).
* Headers are now significantly shorter than in C++ since
we can often hide more of our "class" implementations.
* Memory counting is based on dlmalloc for most platforms now.
Unfortunately, there is no malloc implementation that
provides an efficient constant-time memory counter that
is guaranteed to decrease when freeing memory.
But since we use a defined malloc implementation now,
malloc_usable_size() can be used safely for tracking memory use.
malloc() replacement is very tricky on Windows, so we
use a poll thread on Windows. This can also be enabled
on other supported platforms using --disable-malloc-replacement.
All in all, I'm still not pleased with the state of memory
limiting. It is a mess.
* Error handling uses GError now. This has the advantage that
the GError codes can be reused once we support error catching
in the SciTECO language.
* Added a few more test suite cases.
* Haiku is no longer supported as builds are instable and
I did not manage to debug them - quite possibly Haiku bugs
were responsible.
* Glib v2.44 or later are now required.
The GTK UI requires Gtk+ v3.12 or later now.
The GtkFlowBox fallback and sciteco-wrapper workaround are
no longer required.
* We now extensively use the GCC/Clang-specific g_auto
feature (automatic deallocations when leaving the current
code block).
* Updated copyright to 2021.
SciTECO has been in continuous development, even though there
have been no commits since 2018.
* Since these changes are so significant, the target release has
been set to v2.0.
It is planned that beginning with v3.0, the language will be
kept stable.
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detect EMCurses
* Emscripten can be used (theoretically) to build a host-only platform-independant version
of SciTECO (running under node.js instead of the browser).
* I ported netbsd-curses with Emscripten for that purpose. Therefore, adaptions for running
in the browser are restricted to EMcurses now.
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* Array allocations were not properly accounted since the compiler
would call the replacement new() which assumes that it would
always be called along with the replacement sized-deletion.
This is not true for array new[] allocations resulting in
a constant increase of memory_usage and unrecoverable situations.
This problem however could be fixed in principle by avoiding
memory counting for arrays or falling back to malloc_usable_size.
* The bigger problem was that some STLs (new_allocator) are broken, calling the
non-sized delete for regular new() calls which could in principle
be matched by sized-delete.
This is also the reason why I had to provide a non-sized
delete replacement, which in reality intoduced memory leaks.
* Since adding checks for the broken compiler versions or a configure-time
check that tries to detect these broken systems seems tedious,
I simply removed that optimization.
* This means we always have to rely on malloc_usable_size() now
for non-SciTECO-object memory measurement.
* Perhaps in the future, there should be an option for allowing
portable measurement at the cost of memory usage, by prefixing
each memory chunk with the chunk size.
Maintainers could then decide to optimize their build for "speed"
at the cost of memory overhead.
* Another solution to this non-ending odyssey might be to introduce
our own allocator, replacing malloc(), and allowing our own
precise measurements.
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Automakefiles could be simplified by updating CXXFLAGS
in configure.ac instead.
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support
* Since netbsd-curses can act as a drop-in replacement to ncurses,
SciTECO builds with --with-interface=ncurses as well.
However, it is unintuitive for users to build with ncurses support
when actually linking against netbsd-curses; so another option has been added.
* The UNIX/TTY specific code (which works with both ncurses and netbsd-curses)
was selected when NCURSES was detected at build-time.
This does not work for netbsd-curses, so we define a new symbol
NETBSD_CURSES. At build-time, a CURSES_TTY macro may now be defined.
* This effectively fixes the stdio in interactive mode, window titles
and the XTerm clipboard support for netbsd-curses.
Some minor features like the reduced ESCDELAY are still broken.
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been shown to be unacceptably broken, so the fallback implementation has been improved
* mallinfo() is not only broken on 64-bit systems but slows things
down linearilly to the memory size of the process.
E.g. after 500000<%A>, SciTECO will act sluggish! Shutting down
afterwards can take minutes...
mallinfo() was thus finally discarded as a memory measurement
technique.
* Evaluating /proc/self/statm? has also been evaluated and discarded
because doing this frequently is even slower.
* Instead, the fallback implementation has been drastically improved:
* If possible use C++14 global sized deallocators, allowing memory measurements
across the entire C++ code base with minimal runtime overhead.
Since we only depend on C++11, a lengthy Autoconf check had to be introduced.
* Use malloc_usable_size() with global non-sized deallocators to
measure the approx. memory usage of the entire process (at least
the ones done via C++).
The cheaper C++11 sized deallocators implemented via SciTECO::Object still
have precedence, so this affects Scintilla code only.
* With both improvements the test case
sciteco -e '<@EU[X^E\a]"^E\a"%a>'
is handled sufficiently well now on glibc and performance is much better
now.
* The jemalloc-specific technique has been removed since it no longer
brings any benefits compared to the improved fallback technique.
Even the case of using malloc_usable_size() in strict C++ mode is
up to 3 times faster.
* The new fallback implementation might actually be good enough for
Windows as well if some MSVCRT-specific support is added, like
using _msize() instead of malloc_usable_size().
This must be tested and benchmarked, so we keep the Windows-specific
implementation for the time being.
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and added a FreeBSD/jemalloc-specific implementation
* largely reverts 39cfc573, but leaves in minor and documentation
changes.
* further experimentation of memory limiting using malloc() wrapping
has shown additional problems, like dlsym() calling malloc-functions,
further reducing the implementation to glibc-specific means.
This means there had been no implementation for FreeBSD and checks
would have to rely on undocumented internal implementation details
of different libcs, which is not a good thing.
* Other problems have been identified, like having to wrap calloc(),
guarding against underruns and multi-thread safety had been identified
but could be worked around.
* A technique by calculating the memory usage as sbrk(0) - &end
has been shown to be effective enough, at least on glibc.
However even on glibc it has shortcomings since malloc() will
somtimes use mmap() for allocations and the technique
relies on implementation details of the libc.
Furthermore another malloc_trim(0) had to be added to the error
recovery in interactive mode, since glibc does not adjust the program break
automatically (to avoid syscalls I presume).
* On FreeBSD/jemalloc, the sbrk(0) method totally fails because jemalloc
exclusively allocates via mmap() -> that solution was discarded as well.
* Since all evaluated techniques turn out to be highly platform
specific, I reverted to the simple and stable platform-specific
mallinfo() API on Linux.
* On FreeBSD/jemalloc, it's possible to use mallctl("stats.allocated")
for the same purpose - so it works there, too now.
It's slower than the other techniques, though.
* A lengthy discussion has been added to memory.cpp, so that we
do not repeat the previous mistakes.
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portable and faster hack
* Works by "hooking" into malloc() and friends and counting the
usable heap object sizes with malloc_usable_size().
Thus, it has no memory-overhead.
* Will work at least on Linux and (Free)BSD.
Other UNIXoid systems may work as well - this is tested by ./configure.
* Usually faster than even the fallback implementation since the
memory limit is hit earlier.
* A similar approach could be tried on Windows (TODO).
* A proper memory-limiting counting all malloc()s in the system can make
a huge difference as this test case shows:
sciteco -e '<@EU[X^E\a]"^E\a"%a>'
It will allocate gigabytes before hitting the 500MB memory limit...
* Fixed the UNIX-function checks on BSDs.
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* especially to improve building on FreeBSD 11
* We need GNU Make, yet alone because Scintilla/Scinterm
needs it. We now document that dependency and added
an Autoconf check from the autoconf-archive.
We make sure that the build process is invoked with GNU make
by generating only GNUmakefiles.
The Makefile.am files have not been renamed, so this
change can be rolled back easily.
* Some GNU-Make-specific autoreconf warnings have still been
resolved. But not all of them, as this would have been
unelegant and we need GNU Make anyway.
* Declare ACLOCAL_AMFLAGS to appease autoreconf
* Added an explicit check for C++11 from the autoconf-archives.
In general we should support building with every C++11 compiler
that is sufficiently GNU-like.
* Do not use `sed` for inplace editing, as different sed-implementations
have mutually incompatible syntax for this.
Instead of declaring and checking a dependency on GNU sed,
we simply use SciTECO for the editing task.
This improves code portability on BSDs.
* Similarily, BSD/POSIX `cmp` is supported now.
This fixes the test suite on BSD without declaring a
dependency on the GNU coreutils.
* Simplified sciteco-wrapper generation.
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performance issues with memory measurements
* Fixed build problems on Windows
* g_slice on Windows has been shown to be of little use either
and it does not work well with the GetProcessMemoryInfo()
measurements.
Also, it brings the same problem as on Glibc: Not even command-line
termination returns the memory to the OS.
Therefore, we don't use g_slice at all and commented on it.
* The custom Linux and Windows memory measurement approaches
have been shown to be inefficient.
As a workaround, scripts disable memory limiting.
* A better approach -- but it will only work on Glibc -- might
be to hook into malloc(), realloc() and free() globally
and use the malloc_usable_size() of a heap object for
memory measurements. This will be relatively precise and cheap.
* We still need the "Object" base class in order to measure
memory usage as a fallback approach.
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* we were basing the glib allocators on throwing std::bad_alloc just like
the C++ operators. However, this always was unsafe since we were throwing
exceptions across plain-C frames (Glib).
Also, the memory vtable has been deprecated in Glib, resulting in
ugly warnings.
* Instead, we now let the C++ new/delete operators work like Glib
by basing them on g_malloc/g_slice.
This means they will assert and the application will terminate
abnormally in case of OOM. OOMs cannot be handled properly anyway, so it is
more important to have a good memory limiting mechanism.
* Memory limiting has been completely revised.
Instead of approximating undo stack sizes using virtual methods
(which is unprecise and comes with a performance penalty),
we now use a common base class SciTECO::Object to count the memory
required by all objects allocated within SciTECO.
This is less precise than using global replacement new/deletes
which would allow us to control allocations in all C++ code including
Scintilla, but they are only supported as of C++14 (GCC 5) and adding compile-time
checks would be cumbersome.
In any case, we're missing Glib allocations (esp. strings).
* As a platform-specific extension, on Linux/glibc we use mallinfo()
to count the exact memory usage of the process.
On Windows, we use GetProcessMemoryInfo() -- the latter implementation
is currently UNTESTED.
* We use g_malloc() for new/delete operators when there is
malloc_trim() since g_slice does not free heap chunks properly
(probably does its own mmap()ing), rendering malloc_trim() ineffective.
We've also benchmarked g_slice on Linux/glib (malloc_trim() shouldn't
be available elsewhere) and found that it brings no significant
performance benefit.
On all other platforms, we use g_slice since it is assumed
that it at least does not hurt.
The new g_slice based allocators should be tested on MSVCRT
since I assume that they bring a significant performance benefit
on Windows.
* Memory limiting does now work in batch mode as well and is still
enabled by default.
* The old UndoTokenWithSize CRTP hack could be removed.
UndoStack operations should be a bit faster now.
But on the other hand, there will be an overhead due to repeated
memory limit checking on every processed character.
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* the new "?" (help) command can be used to look up
help topics.
* help topics are index from $SCITECOPATH/women/*.woman.tec
files.
* looking up a help topic opens the corresponding "womanpage"
and jumps to the position of the topic (it acts like an anchor
into the document).
* styling is performed by *.woman.tec files.
* Setting up the Scintilla view and munging the *.tec file
is performed by the new "woman.tes" lexer.
On supporting UIs (Gtk), womanpages are shown in a variable-width
font.
* Woman pages are usually not hand-written, but generated from manpages.
A special Groff post-processor grosciteco has been introduced for this
purpose. It is much like grotty, but can output SciTECO macros for styling
the document (ie. the *.woman.tec files).
It is documented in its own man-page.
* grosciteco also introduces sciteco.tmac - special Troff macros
for controlling the formatting of the document in SciTECO.
It also defines .SCITECO_TOPIC which can be used to mark up
help topics/terms in Troff markup.
* Woman pages are generated/formatted by grosciteco at compile-time, so
they will work on platforms without Groff (ie. as on windows).
* Groff has been added as a hard compile-time requirement.
* The sciteco(1) and sciteco(7) man pages have been augmented with
help topic anchors.
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* Allows us to check for the Gob2 version at ./configure time
* this file ships with Gob2 installations, so in most cases
it could be found without shipping it with SciTECO.
* Autoconf is built such that source distributions will contain
all additional external macros compiled in aclocal.m4.
* However if somebody builds from Git, he/she would still
expect the ./configure checks to produce meaningful results
even if not all dependencies are installed properly.
It therefore seems to be good practice to include all
external M4 macros (gob2.m4) as a fallback with the source tree.
* /usr/share/aclocal contains many more useful m4 macros.
However since we can depend on pkg-config e.g. for finding
Gtk+ and Glib, I won't use those macros as else I would
have to bundle them to achieve the same kind of ./configure
robustness.
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* makes sense since it already extracted information from ./configure
that is usually substituted.
* it already had to be run from a configured build directory
* it required the source tree directory, which had to be overwritten
on the Make command line when using an out-of-source build dir.
This is no longer necessary.
* It is still a stand-alone Makefile to keep it isolated from the main
build system, although it could certainly be translated to Automake.
* the generated file will now be called distribute.mk to signify
that it is a Makefile.
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* Autotest ships with Autoconf, so it's available already
and relatively easy to integrate into an Autotools package.
* This is attached to `make check` using some Automake magic.
* The test suite will only call the built SciTECO for the time being.
But using tests/Makefile.am, custom programs could be easily
built.
* Since it uses the target sciteco, it cannot work in cross-compile
environments.
* The test suite tests/testsuite.at should be used for regression
tests at least: Whenever there is a bug, a test case should be
added to testsuite.at.
Later this might be split up into multiple includes for regressions
other tests.
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* Usually, Scintilla will now be built with -O2
* this can improve performance significantly over the standard Scintilla -Os
(up to 10%).
* this also allows link-time-optimizing both Scintilla and SciTECO
(which are linked statically) by adding -flto to CFLAGS, CXXFLAGS and LDFLAGS.
Link-time-optimization will both reduce the total binary size
and improve performance slightly since scintilla_send_message() can be
inlined.
An -O3 optimized Scintilla when linked with LTO results in an only 300kb
larger SciTECO binary.
* the highest possible optimization thus requires the following maintainer
flags on the ./configure command line:
CFLAGS="-O3 -mtune=native -march=native -flto"
CXXFLAGS="-O3 -mtune=native -march=native -flto"
LDFLAGS="-flto"
* Windows and Debian builds use link-time-optimization now.
On Windows - where we link in everything statically - building
the dependant libraries with -flto could improve performance
even more.
* Debian builds respect the default hardening flags of the build
server now. This should ensure that SciTECO is built for the
correct architecture at the recommended optimization level etc.
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* use libtool convenience libraries as much as possible
(for all static libraries except Scintilla)
* improves separation of language and user interface implementations
(e.g. the Gtk widgets are not interesting for the rest of SciTECO)
* the Curses popup widget can now be factored out of interface-curses.cpp
* some common CPPFLAGS are now defined by ./configure via AM_CPPFLAGS,
so they don't have to be repeated in each submodule.
* fixed building the Curses UI: GTK_FLOW_BOX_FALLBACK conditional
must always be defined.
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* depend on Gtk+ 3.10. If necessary older versions should also
be supportable. GtkOverlay was already introduced in v3.2
* A fallback for GtkFlowBox is compiled in if the Gtk installation
is too old. This applies even to Ubuntu 14.04 which still runs
Gtk v3.10.
* the threading the Gtk UI is left as it is for the time being
even though the synchronization mechanism has been deprecated.
Alternative approaches have to be tried out and benchmarked.
* Completely revamped the GtkInfoPopup widget.
It is now as powerful as the Curses UI's popup widget.
* A GtkOverlay is used instead of the top-level window hack
in the Gtk2 version.
* GtkFlowBox is used to lay out the columns of the popup.
* I had to work around restrictions of GtkScrolledWindow
by writing my own poor-mans scrolled window which handles
size requests correctly.
* The popup window no longer overflows the screen size,
instead we scroll.
* Scrolling pagewise is finally supported. Wraps at the
end of a list just like the Curses UI.
* Instead of using only two stock icons, we now use
GIO to get file and directory icons for the current theme.
This looks even better.
* The GtkFlowBox allows selections which can be used for mouse
interaction later. But this is not yet implemented.
* Theming of the popup widget and command line is still
not performed correctly.
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* Haiku can be handled like UNIX in most respects
since it is POSIX compliant, has a UNIX-like terminal
emulator and uses ncurses.
* still the Glib platform macro is G_OS_HAIKU instead of
G_OS_UNIX, so the preprocessor conditionals had to be adapted.
* the only functional difference between a Haiku and UNIX build
is the default SCITECOCONFIG path.
We use the config path returned by Glib instead of $HOME,
so .teco_ini will be in ~/config/settings on Haiku.
Other UNIX ports appear to use the same conventions.
* Some Haiku-specific restrictions still apply:
* Haiku's terminal is xterm-compatible, but only supports
8 colors. Therefore only the terminal.tes color scheme
can be used and the terminal must be set up to
"Use bright instead of bold text".
* The terminal has artifacts. This appears to be a Haiku
bug and affects other curses applications as well.
* GTK is yet unsupported on Haiku, so there may never be
a GUI port (unless someone writes a QT GUI for SciTECO).
* SciTECO cannot be built with the legacy gcc2 used for
BeOS compatibility on Haiku. This would require too many
changes for an obsolete platform.
BeOS and the x86_gcc2 platform of Haiku will therefore
never be supported.
The PPC and ARM platforms of Haiku should work but are untested.
* a HaikuPorts recipe will be provided for the next regular
SciTECO release. This should hopefully allow installation via
HaikuDepot.
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* enabled via --with-interface=xcurses, so we can configure
it automatically via xcurses-config.
This also adds XCURSES_CFLAGS and XCURSES_LIBS.
* The X11 window class name is set to "SciTECO".
X11 resource overrides can currently not be set via
sciteco's command line. The user may use .Xdefaults though.
* interruptions via CTRL+C are currently not supported.
Apparently, XCurses also does send SIGINT in cbreak() mode.
An XCurses-specific hack would be cumbersome.
* ~InterfaceCurses() should probably be rewritten.
Curses cleanup should be completely in restore_batch() as
the destructor may be called after Curses-cleanup handlers.
E.g. isendwin() SEGFAULTs on XCurses when called from the
destructor.
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* requires a recent patch to Scinterm
* can be overwritten in SciTECO's build system via NCURSES_CFLAGS or
PDCURSES_CFLAGS.
* NCURSES_LIBS has also been introduced. The check for ncurses
will now use pkg-config if available.
* eases multiple builds with different Curses variants
(e.g. when cross-compiling for Windows)
* pass more toolchain variables into Scintilla build process (CC and RANLIB).
This should fix Cross-compiling Scintilla/Gtk
* Pass GTK cflags into Scintilla/Gtk build system.
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minimum version
* it was necessary to increase the upstream version so I could
upload new versions to launchpad while debugging PPA build issues.
* ChangeLog finalized for v0.6.4
* SciTECO requires at least libglib v2.28 (but that's only a guess)
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* allows us to link against PDCurses/win32a statically.
It requires additional Windows DLLs (gdi32 and comdlg32) and since
there's no PDCurses configuration mechanism, it is easiest to set
the PDCurses linker flags using a PDCURSES_LIBS env variable.
* This is only possible since Scintilla links statically, we do the
linking of the binary and can provide the linker flags.
It is still not possible to overwrite the CFLAGS used for PDCurses
without modifying the Scinterm Makefile.
* Using PDCURSES_LIBS we can get rid of --with-interface=emcurses since
if library checks fail with EMscripten, we can simply define
PDCURSES_LIBS="-lpdcurses"
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the MSVCRT versions are not glibc-compatible and we do not
actually need glibc compatible versions, as all allocations
are done through the libglib wrappers.
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* activated via bit 4 of the ED flag (enabled by default)
* automatic EOL guessing on file loading and translation to LFs.
* works with files that have inconsistent EOL sequences.
* automatic translation to original EOL sequences on file saving
* works with inconsistent EOL sequences in the buffer.
This should usually not happen if the file was read in with
automatic EOL translation enabled.
* also works with the EC and EG commands
* performance is OK, depending on the file being translated.
When reading files with UNIX EOLs, the overhead is minimal
typically-sized files. For DOS EOLs the overhead is larger
but still acceptable.
* Return (line feed) is now an immediate editing command.
This centralizes EOL sequence insertion.
Later, other features like auto-indent could be added to
the editing command.
* get_eol() has been moved to main.cpp (now called
get_eol_seq()
* Warn if file ownership could not be preserved when
saving files.
* IOView has been almost completely rewritten based
on GIOChannels. The EOL translation code is also in IOView.
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* sciteco.ico contains a 16 color 16px, a 255 color 32px and
a true color 48px version of the icon.
The first ones are good for legacy Windows versions like 2000,
while the latter one should be preferred by Windows >= 7.
* Also added the 48px version as a PNG for Linux.
But it is not installed currently, as there is no standardized
place for it and it wouldn't do much good in /usr/share/sciteco.
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* This adds the -all-static libtool option and can be used to
link a static sciteco binary (or at least link in as few as possible
dynamic libraries)
* Esp. useful on MinGW to link in all dependant libraries (glib, libintl,
libiconv, libpdcurses, ...) statically.
A static .exe is much smaller than a dynamically linked plus all the
DLLs and is easier to relocate.
* This does not guarantee that ALL libraries are linked in dynamically.
E.g. on MinGW, the sciteco.exe will still link to MSVCRT and the Windows
system DLLs, but they already ship with Windows.
* On MinGW, even a static build will still require the gspawn-win32-helper-console.exe
which is used by glib to implement g_spawn with redirection.
We cannot get around that.
* It would be better to let this be decided by the package builder using
the standard env variables like LDFLAGS. However, this does not seem to
work well with libtool. It IS possible to define LDFLAGS="-all-static" when
calling make but this approach sucks.
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* PDCurses build system produces static libraries that cannot be
found by Autoconf (pdcurses.a) and often files have the wrong
permissions.
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* The PACKAGE_URL_DEV is also mentioned in --help output and sciteco(1)
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* has been changed in Scinterm some time ago
* I don't know if defining this makes actually any difference,
but Jinx does it.
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* this is a Linux/glibc-only optimization
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$SCITECOPATH on Windows
* $SCITECOCONFIG has been introduced, so have a macro-accessible location
for the profile, buffer session etc.
This is set to the program dir on Windows. That way, the config files
will be found, regardless of the current working dir, but it may also
be set up for Unix-like environments on Windows.
* $SCITECOPATH defaults to the program dir + "/lib" now on Windows.
* The default profile is now always called ".teco_ini". Also on Windows.
Platform differences like this would need to be documented.
* The sample teco.ini has been renamed to "sample.teco_ini" for clarity
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* does not change ./configure parameters
You still have to specifiy --with-interface=ncurses for
the Curses interface with default settings
* the "NCurses" UI was used for many different Curses
variants, so plain "Curses" is a better name.
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The SciTECO language changes often and the build system scripts are
adapted accordingly. If bootstrapping is disabled by default on systems
that already have SciTECO, building recent Git versions will fail often
due to macro errors. This is not easy to see and correct for users.
Also the build-time overhead for `sciteco-minimal` is minimal. The
--disable-bootstrap option is mostly useful when cross-compiling
SciTECO.
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this should simplify building SciTECO for new users
* compiler and archiver are passed down from Autoconf,
so cross-compiling should work transparently
* `make clean` will also clean the Scintilla source tree
* there is no longer any need for "source bundles" as
tar balls also contain Scintilla/Scinterm now
* building from Git is not much more difficult than building
from a tar ball
* The versions of Scintilla/Scinterm embedded as submodules
already contain all the patches necessary (currently none are
necessary), so there's no need to have patch files in the
repository
* INSTALL instructions have been rewritten
* the --with-scintilla and --with-scinterm site-config options
have been kept. But they should be rarely necessary now.
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by building with Emscripten support, SciTECO may be
embedded into web pages.
* sciteco.html is not a piece of documentation but a sample SciTECO embedding
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* there was a compile-time race condition that could result in the GObjects not being built (with Gob2).
So I removed the symbols generation from BUILT_SOURCES.
* apparently either Scintilla depends on gmodule since I last tested or the gtk+-2.0 pkg-config package
no longer includes gmodule, so we must explicitly depend on it
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* some build environments (like XCode) do not have a GNU readlink by default
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so no additional --with-scintilla is necessary when building from
a source bundle
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* fixes gcc-4.4 which does not have -Wno-mismatched-tags and no -Wunknown-warning
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* will be useful for Windows builds since Windows users usally do not have
a man-page formatter/reader
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* solely for generating developer docs
* disabled by default even if Doxygen is installed
* Doxygen comments are not used currently
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