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1	2 ?First release candidate for NetBSD 9.0 available!	3	4	5	6	7
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martin (NetBSD Blog)

Since the start of the release process four months ago a lot of improvements went into the branch - more than 500 pullups were processed!

This includes usbnet (a common framework for usb ethernet drivers), aarch64 stability enhancements and lots of new hardware support, installer/sysinst fixes and changes to the NVMM (hardware virtualization) interface.

We hope this will lead to the best NetBSD release ever (only to be topped by NetBSD 10 next year).

Here are a few highlights of the new release:

Support for Arm AArch64 (64-bit Armv8-A) machines, including "Arm ServerReady" compliant machines (SBBR+SBSA)
Enhanced hardware support for Armv7-A
Updated GPU drivers (e.g. support for Intel Kabylake)
Enhanced virtualization support
Support for hardware-accelerated virtualization (NVMM)
Support for Performance Monitoring Counters
Support for Kernel ASLR
Support several kernel sanitizers (KLEAK, KASAN, KUBSAN)
Support for userland sanitizers
Audit of the network stack
Many improvements in NPF
Updated ZFS
Reworked error handling and NCQ support in the SATA subsystem
Support a common framework for USB Ethernet drivers (usbnet)

You can download binaries of NetBSD 9.0_RC1 from our Fastly-provided CDN.

For more details refer to the official release announcement.

Please help us out by testing 9.0_RC1. We love any and all feedback. Report problems through the usual channels (submit a PR or write to the appropriate list). More general feedback is welcome, please mail releng. Your input will help us put the finishing touches on what promises to be a great release!

Enjoy!

Martin

Posted Monday afternoon, December 2nd, 2019 Tags: blog

Kamil Rytarowski (NetBSD Blog)

This report was written by Maciej Grochowski as a part of developing the AFL+KCOV project.

This report is a continuation of my previous work on Fuzzing Filesystems via AFL. You can find previous posts where I described the fuzzing (part1, part2) or my EuroBSDcon presentation.
In this part, we won't talk too much about fuzzing itself but I want to describe the process of finding root causes of File system issues and my recent work trying to improve this process.
This story begins with a mount issue that I found during my very first run of the AFL, and I presented it during my talk on EuroBSDcon in Lillehammer.

Invisible Mount point

afl-fuzz: /dev/vnd0: opendisk: Device busy That was the first error that I saw on my setup after couple of seconds of AFL run.
I was not sure what exactly was the problem and thought that mount wrapper might cause a problem.
Although after a long troubleshooting session I realized that this might be my first found issue.
To give the reader a better understanding of the problem without digging too deeply into fuzzer setup or mount process.
Let's assume that we have some broken file system image exposed as a block device visible as a /dev/wd1a.

The device can be easily mounted on mount point mnt1, however when we try to unmount it we get an error: error: ls: /mnt1: No such file or directory, and if we try to use raw system call unmount(2) it also end up with the similar error.

However, we can see clearly that the mount point exists with the mount command:

# mount
/dev/wd0a on / type ffs(local)
...
tmpfson /var/shmtype tmpfs(local)
/dev/vnd0 on /mnt1 type ffs(local)

Thust any lstat(2) based command is trying to convince us that no such directory exists.

# ls / | grep mnt
mnt
mnt1

# ls -alh /mnt1
ls: /mnt1: No such file or directory
# stat /mnt1
stat: /mnt1: lstat: No such file or directory

To understand what is happening we need to dig a little bit deeper than with standard bash tools.
First of all mnt1 is a folder created on the root partition at a local filesystem so getdents(2) or dirent(3) should show it as a entry inside dentry structure on the disk.
Raw getdents syscall is great tool for checking directory content because it reads the data from the directory structure on disk.

# ./getdents  /
|inode_nr|rec_len|file_type|name_len(name)|
#:   2,      16,    IFDIR,       1 (.)
#:   2,      16,    IFDIR,       2 (..)
#:   5,      24,    IFREG,       6 (.cshrc)
#:   6,      24,    IFREG,       8 (.profile)
#:   7,      24,    IFREG,       8 (boot.cfg)
#: 3574272,  24,    IFDIR,       3 (etc)
...
#: 3872128,  24,    IFDIR,       3 (mnt)
#: 5315584,  24,    IFDIR,       4 (mnt1)

Getdentries confirms that we have mnt1 as a directory inside the root of our system fs.
But, we cannot execute lstat, unmount or any other system-call that require a path to this file.
A quick look on definitions of these system calls show their structure:

unmount(const char *dir, int flags);
stat(const char *path, struct stat *sb);
lstat(const char *path, struct stat *sb);
open(const char *path, int flags, ...);

All of these function take as an argument path to the file, which as we know will endup in vfs lookup.
How about something that uses filedescryptor? Can we even obtain it?
As we saw earlier running open(2) on path also returns EACCES.
Looks like without digging inside VFS lookup we will not be able to understand the issue.

Get Filesystem Root

After some debugging and code walk I found the place that caused error.
VFS during the name resolution needs to check and switch FS in case of embedded mount points.
After the new filesystem is found VFS_ROOT is issued on that particular mount point.
VFS_ROOT is translated in case of FFS to the ufs_root which calls vcache with fixed value equal to the inode number of root inode which is 2 for UFS.

#define UFS_ROOTINO     ((ino_t)2)

Below listning with the code of ufs_root from ufs/ufs/ufs_vfsops.c.

int
ufs_root(struct mount *mp, struct vnode **vpp)
{
...
        if ((error = VFS_VGET(mp, (ino_t)UFS_ROOTINO, &nvp)) != 0)
               return (error);

By using the debugger, I was able to make sure that the entry with number 2 after hashing does not exist in the vcache.
As a next step, I wanted to check the Root inode on the given filesystem image.
Filesystem debuggers are good tools to do such checks. NetBSD comes with FSDB which is general-purpose filesystem debugger.
Nonetheless, by default FSDB links against fsck_ffs which makes it tied to the FFS.

Filesystem Debugger for the help!

Filesystem debugger is a tool designed to browse on-disk structure and values of particular entries. It helps in understanding the Filesystems issues by giving particular values that the system reads from the disk. Unfortunately, current fsdb_ffs is a bit limited in the amount of information that it exposes.
Example output of trying to browse damaged root inode on corrupted FS.

# fsdb -dnF -f ./filesystem.out

** ./filesystem.out (NO WRITE)
superblock mismatches
...
BAD SUPER BLOCK: VALUES IN SUPER BLOCK DISAGREE WITH THOSE IN FIRST ALTERNATE                                     
clean = 0
isappleufs = 0, dirblksiz = 512
Editing file system `./filesystem.out'
Last Mounted on /mnt
current inode 2: unallocated inode

fsdb (inum: 2)> print
command `print
'
current inode 2: unallocated inode

FSDB Plugin: Print Formatted

Fortunately, fsdb_ffs leaves all necessary interfaces to allows accessing this data with small effort.
I implemented a simple plugin that allows browsing all values inside: inodes, superblock and cylinder groups on FFS. There are still a couple of todos that have to be finished, but the current version allows us to review inodes.

fsdb (inum: 2)> pf inode number=2 format=ufs1
command `pf inode number=2 format=ufs1
'
Disk format ufs1inode 2 block: 512
 ---------------------------- 
di_mode: 0x0                    di_nlink: 0x0
di_size: 0x0                    di_atime: 0x0
di_atimensec: 0x0               di_mtime: 0x0
di_mtimensec: 0x0               di_ctime: 0x0
di_ctimensec: 0x0               di_flags: 0x0
di_blocks: 0x0                  di_gen: 0x6c3122e2
di_uid: 0x0                     di_gid: 0x0
di_modrev: 0x0
 --- inode.di_oldids ---

We can see that the Filesystem image got wiped out most of the root inode fields.
For comparison, if we will take a look at root inode from freshly created FS we will see the proper structure.
Based on that we can quickly realize that fields: di_mode, di_nlink, di_size, di_blocks are different and can be the root cause.

Disk format ufs1 inode: 2 block: 512
 ---------------------------- 
di_mode: 0x41ed                 di_nlink: 0x2
di_size: 0x200                  di_atime: 0x0
di_atimensec: 0x0               di_mtime: 0x0
di_mtimensec: 0x0               di_ctime: 0x0
di_ctimensec: 0x0               di_flags: 0x0
di_blocks: 0x1                  di_gen: 0x68881d2c
di_uid: 0x0                     di_gid: 0x0
di_modrev: 0x0
 --- inode.di_oldids ---

From FSDB and incore to source code

First we will summarize what we already know:

unmount fails in namei operation failure due to the corrupted FS
Filesystem has corrupted root inode
Corrupted root inode has fields: di_mode, di_nlink, di_size, di_blocks set to zero

Now we can find a place where inodes are loaded from the disk, this function for FFS is ffs_init_vnode(ump, vp, ino);.
This function is called during the loading vnode in vfs layer inside ffs_loadvnode.
Quick walkthrough through ffs_loadvnode expose the usage of the field i_mode:

         error = ffs_init_vnode(ump, vp, ino);                                                                                                                                                                                     
         if (error)                                                                                                                                                                                                                
                return error;                                                                                                                                                                                                     
                                                                                                                                                                                                                                   
         ip = VTOI(vp);                                                                                                                                                                                                            
         if (ip->i_mode == 0) {                                                                                                                                                                                                    
                 ffs_deinit_vnode(ump, vp);                                                                                                                                                                                        
                                                                                                                                                                                                                                   
                 return ENOENT;                                                                                                                                                                                                    
         }

This seems to be a source of our problem. Whenever we are loading inode from disk to obtain the vnode, we validate if i_mode is non zero.
In our case root inode is wiped out, what results that vnode is dropped and an error returned.
So simply we cannot load any inode with i_mode set to the zero, inode number 2 called root is no different here. Due to that the VFS_LOADVNODE operation always fails, so lookup does and name resolution will return ENOENT error. To fix this issue we need a root inode validation on mount step, I created such validation and tested against corrupted filesystem image.
The mount return error, which proved the observation that such validation would help.

Conclusions

The following post is a continuation of the project: "Fuzzing Filesystems with kcov and AFL".
I presented how fuzzed bugs, which do not always show up as system panics, can be analyzed, and what tools a programmer can use.
Above the investigation described the very first bug that I found by fuzzing mount(2) with Afl+kcov.
During that root cause analysis, I realized the need for better tools for debugging Filesystem related issues.
Because of that reason, I added small functionality pf (print-formatted) into the fsdb(8), to allow walking through the on-disk structures. The described bug was reported with proposed fix based on validation of the root inode on kern-tech mailing list.

Future work

Tools: I am still progressing with the fuzzing of mount process, however, I do not only focus on the finding bugs but also on tools that can be used for debugging and also doing regression tests. I am planning to add better support for browsing blocks on inode into the fsdb-pf, as well as write functionality that would allow more testing and potential recovery easier.
Fuzzing: In next post, I will show a remote setup of AFL with an example of usage.
I got a suggestion to take a look at FreeBSD UFS security checks on mount(2) done by McKusick. I think is worth it to see what else is validated and we can port to NetBSD FFS.

Posted Wednesday evening, November 27th, 2019 Tags: blog

William J. Coldwell (NetBSD Blog)

Per the membership voting, we have seated the new Board of Directors of the NetBSD Foundation:

Taylor R. Campbell <riastadh@>
William J. Coldwell <billc@>
Michael van Elst <mlelstv@>
Thomas Klausner <wiz@>
Cherry G. Mathew <cherry@>
Pierre Pronchery <khorben@>
Leonardo Taccari <leot@>

We would like to thank Makoto Fujiwara <mef@> and Jeremy C. Reed <reed@> for their service on the Board of Directors during their term(s).

The new Board of Directors have voted in the executive officers for The NetBSD Foundation:

President:	William J. Coldwell
Vice President:	Pierre Pronchery
Secretary:	Christos Zoulas
Assistant Secretary:	Thomas Klausner
Treasurer:	Christos Zoulas
Assistant Treasurer:	Taylor R. Campbell

Thanks to everyone that voted and we look forward to a great 2020.

Posted late Wednesday evening, November 20th, 2019 Tags: blog

William J. Coldwell (NetBSD Blog)

Per the membership voting, we have seated the new Board of Directors of the NetBSD Foundation:

Taylor R. Campbell <riastadh@>
William J. Coldwell <billc@>
Michael van Elst <mlelstv@>
Thomas Klausner <wiz@>
Cherry G. Mathew <cherry@>
Pierre Pronchery <khorben@>
Leonardo Taccari <leot@>

We would like to thank Makoto Fujiwara <mef@> and Jeremy C. Reed <reed@> for their service on the Board of Directors during their term(s).

The new Board of Directors have voted in the executive officers for The NetBSD Foundation:

President:	William J. Coldwell
Vice President:	Pierre Pronchery
Secretary:	Christos Zoulas
Assistant Secretary:	Thomas Klausner
Treasurer:	Christos Zoulas
Assistant Treasurer:	Taylor R. Campbell

Thanks to everyone that voted and we look forward to a great 2020.

Posted late Wednesday evening, November 20th, 2019 Tags: blog

Michał Górny (NetBSD Blog)

Upstream describes LLDB as a next generation, high-performance debugger. It is built on top of LLVM/Clang toolchain, and features great integration with it. At the moment, it primarily supports debugging C, C++ and ObjC code, and there is interest in extending it to more languages.

In February, I have started working on LLDB, as contracted by the NetBSD Foundation. So far I've been working on reenabling continuous integration, squashing bugs, improving NetBSD core file support, extending NetBSD's ptrace interface to cover more register types and fix compat32 issues and fixing watchpoint support. Then, I've started working on improving thread support which is taking longer than expected. You can read more about that in my September 2019 report.

So far the number of issues uncovered while enabling proper threading support has stopped me from merging the work-in-progress patches. However, I've finally reached the point where I believe that the current work can be merged and the remaining problems can be resolved afterwards. More on that and other LLVM-related events happening during the last month in this report.

LLVM news and buildbot status update

LLVM switched to git

Probably the most important event to note is that the LLVM project has switched from Subversion to git, and moved their repositories to GitHub. While the original plan provided for maintaining the old repositories as read-only mirrors, as of today this still hasn't been implemented. For this reason, we were forced to quickly switch buildbot to the git monorepo.

The buildbot is operational now, and seems to be handling git correctly. However, it is connected to the staging server for the time being. Its URL changed to http://lab.llvm.org:8014/builders/netbsd-amd64 (i.e. the port from 8011 to 8014).

Monthly regression report

Now for the usual list of 'what they broke this time'.

LLDB has been given a new API for handling files, in particular for passing them to Python scripts. The change of API has caused some 'bad file descriptor' errors, e.g.:

ERROR: test_SBDebugger (TestDefaultConstructorForAPIObjects.APIDefaultConstructorTestCase)
----------------------------------------------------------------------
Traceback (most recent call last):
  File "/data/motus/netbsd8/netbsd8/llvm/tools/lldb/packages/Python/lldbsuite/test/decorators.py", line 343, in wrapper
    return func(self, *args, **kwargs)
  File "/data/motus/netbsd8/netbsd8/llvm/tools/lldb/packages/Python/lldbsuite/test/python_api/default-constructor/TestDefaultConstructorForAPIObjects.py", line 133, in test_SBDebugger
    sb_debugger.fuzz_obj(obj)
  File "/data/motus/netbsd8/netbsd8/llvm/tools/lldb/packages/Python/lldbsuite/test/python_api/default-constructor/sb_debugger.py", line 13, in fuzz_obj
    obj.SetInputFileHandle(None, True)
  File "/data/motus/netbsd8/netbsd8/build/lib/python2.7/site-packages/lldb/__init__.py", line 3890, in SetInputFileHandle
    self.SetInputFile(SBFile.Create(file, borrow=True))
  File "/data/motus/netbsd8/netbsd8/build/lib/python2.7/site-packages/lldb/__init__.py", line 5418, in Create
    return cls.MakeBorrowed(file)
  File "/data/motus/netbsd8/netbsd8/build/lib/python2.7/site-packages/lldb/__init__.py", line 5379, in MakeBorrowed
    return _lldb.SBFile_MakeBorrowed(BORROWED)
IOError: [Errno 9] Bad file descriptor
Config=x86_64-/data/motus/netbsd8/netbsd8/build/bin/clang-10
----------------------------------------------------------------------

I've been able to determine that the error was produced by flush() method call invoked on a file descriptor referring to stdin. Appropriately, I've fixed the type conversion method not to flush read-only fds.

Afterwards, Lawrence D'Anna was able to find and fix another fflush() issue.

A newly added test revealed that platform process list -v command on NetBSD missed listing the process name. I've fixed it to provide Arg0 in process info.

Another new test failed due to our target not implementing ShellExpandArguments() API. Apparently the only target actually implementing it is Darwin, so I've just marked TestCustomShell XFAIL on all BSD targets.

LLDB upstream was forced to reintroduce readline module override that aims to prevent readline and libedit from being loaded into a single program simultaneously. This module failed to build on NetBSD. I've discovered that the original was meant to be built on Linux only, and since the problem still doesn't affect other platforms, I've made it Linux-only again.

libunwind build has been changed to link using the C compiler rather than C++. This caused some libc++ failures on NetBSD. The author has reverted the change for now, and is looking for a better way of resolving the problem.

Finally, I have disabled another OpenMP test that caused NetBSD to hang. While ideally I'd like to have the underlying kernel problem fixed, this is non-trivial and I prefer to focus on LLDB right now.

New LLD work

I've been asked to rebase my LLD patches for the new code. While doing it, I've finally committed the -z nognustack option patch from January.

In the meantime, Kamil's been working on finally resolving the long-standing impasse on LLD design. He is working on a new NetBSD-specific frontend to LLD that would satisfy our system-wide linker requirements without modifying the standard driver used by other platforms.

Upgrade to NetBSD 9 beta

Our recent work, especially the work on threading support has required a number of fixes in the NetBSD kernel. Those fixes were backported to NetBSD 9 branch but not to 8. The 8 kernel used by the buildbot was therefore suboptimal for testing new features. Furthermore, with the 9.0 release coming soon-ish, it became necessary to start actively testing it for regressions.

The buildbot has been upgraded to NetBSD 9 beta on 2019-11-06. Initially, the upgrade has caused LLDB to start crashing on startup. I have not been able to pinpoint the exact issue yet. However, I've established that it happens with -O3 optimization level only, and I've worked it around by switching the build to -O2. I am planning to look into the problem more once the buildbot is restored fully.

The upgrade to nb9 has caused 4 LLDB tests to start succeeding, and 6 to start failing. Namely:

********************
Unexpected Passing Tests (4):
    lldb-api :: commands/watchpoints/watchpoint_commands/condition/TestWatchpointConditionCmd.py
    lldb-api :: commands/watchpoints/watchpoint_commands/command/TestWatchpointCommandPython.py
    lldb-api :: lang/c/bitfields/TestBitfields.py
    lldb-api :: commands/watchpoints/watchpoint_commands/command/TestWatchpointCommandLLDB.py

********************
Failing Tests (6):
    lldb-shell :: Reproducer/Functionalities/TestExpressionEvaluation.test
    lldb-api :: commands/expression/call-restarts/TestCallThatRestarts.py
    lldb-api :: functionalities/signal/handle-segv/TestHandleSegv.py
    lldb-unit :: tools/lldb-server/tests/./LLDBServerTests/StandardStartupTest.TestStopReplyContainsThreadPcs
    lldb-api :: functionalities/inferior-crashing/TestInferiorCrashingStep.py
    lldb-api :: functionalities/signal/TestSendSignal.py

I am going to start investigating the new failures shortly.

Further LLDB threading work

Fixes to register support

Enabling thread support revealed a problem in register API introspection specific to NetBSD. The API responsible for passing registers in groups to Python was unable to name some of the groups on NetBSD, and the null names have caused the TestRegistersIterator to fail. Threading support made this specifically visible by replacing a regular test failure with Python code error.

In order to resolve the problem, I had to describe all supported register sets in NetBSD register context. The code was roughly based on the Linux equivalent, modified to match register sets used by our ptrace() API. Interestingly, I had to also include MPX registers that are currently unimplemented, as otherwise LLDB implicitly put them in an anonymous group.

While at it, I've also changed the register set numbering to match the more common ordering, in order to avoid issues in the future.

Finished basic thread support patch

I've finally completed and submitted the patch for NetBSD thread support. Besides fixing a few mistakes, I've implemented thread affinity support for all relevant SIGTRAP events (breakpoints, traces, hardware watchpoints) and removed incomplete hardware breakpoint stub that caused LLDB to crash.

In its current form, this patch combines three changes essential to correct support of threaded programs:

It enables reporting of new and exited threads, and maintains debugged thread list based on that.
It modifies the signal (generic and SIGTRAP) handling functions to read the thread identifier and associate the event with correct thread(s). Previously, all events were assigned to all threads.
It updates the process resuming function to support controlling the state (running, single-stepping, stopped) of individual threads, and raising a signal either to the whole process or to a single thread. Previously, the code used only the requested action for the first thread and populated it to all threads in the process.

Proper watchpoint support in multi-threaded programs

I've submitted a separate patch to copy watchpoints to newly-created threads. This is necessary due to the design of Debug Register support in NetBSD. Quoting the ptrace(2) manpage:

debug registers are only per-LWP, not per-process globally

debug registers must not be inherited after (v)forking a process

debug registers must not be inherited after forking a thread

a debugger is responsible to set global watchpoints/breakpoints with the debug registers, to achieve this PTRACE_LWP_CREATE / PTRACE_LWP_EXIT event monitoring function is designed to be used

LLDB supports per-process watchpoints only at the moment. To fit this into NetBSD model, we need to monitor new threads and copy watchpoints to them. Since LLDB does not keep explicit watchpoint information at the moment (it relies on querying debug registers), the proposed implementation verbosely copies dbregs from the currently selected thread (all existing threads should have the same dbregs).

Fixed support for concurrent watchpoint triggers

The final problem I've been investigating was a server crash with the new code when multiple watchpoints were triggered concurrently. My final patch aims to fix handling concurrent watchpoint events.

When a watchpoint is triggered, the kernel delivers SIGTRAP with TRAP_DBREG to the debugger. The debugger investigates DR6 register of the specified thread in order to determine which watchpoint was triggered, and reports it. When multiple watchpoints are triggered simultaneously, the kernel reports that as series of successive SIGTRAPs. Normally, that works just fine.

However, on x86 watchpoint triggers are reported before the instruction is executed. For this reason, LLDB temporarily disables the breakpoint, single-steps and reenables it. The problem with that is that the GDB protocol doesn't control watchpoints per thread, so the operation disables and reenables the watchpoint on all threads. As a side effect of this, DR6 is cleared everywhere.

Now, if multiple watchpoints were triggered concurrently, DR6 is set on all relevant threads. However, after handling SIGTRAP on the first one, the disable/reenable (or more specifically, remove/readd) wipes DR6 on all threads. The handler for next SIGTRAP can't establish the correct watchpoint number, and starts looking for breakpoints. Since hardware breakpoints are not implemented, the relevant method returns an error and lldb-server eventually exits.

There are two problems to be solved there. Firstly, lldb-server should not exit in this circumstances. This is already solved in the first patch as mentioned above. Secondly, we need to be able to handle concurrent watchpoint hits independently of the clear/set packets. This is solved by this patch.

There are multiple different approaches to this problem. I've chosen to remodel clear/set watchpoint method in order to prevent it from resetting DR6 if the same watchpoint is being restored, as the alternatives (such as pre-storing DR6 on the first SIGTRAP) have more corner conditions to be concerned about.

The current design of these two methods assumes that the 'clear' method clears both the triggered state in DR6 and control bits in DR7, while the 'set' method sets the address in DR0..3, and the control bits in DR7.

The new design limits the 'clear' method to disabling the watchpoint by clearing the enable bit in DR7. The remaining bits, as well as trigger status and address are preserved. The 'set' method uses them to determine whether a new watchpoint is being set, or the previous one merely reenabled. In the latter case, it just updates DR7, while preserving the previous trigger. In the former, it updates all registers and clears the trigger from DR6.

This solution effectively prevents the disable/reenable logic of LLDB from clearing concurrent watchpoint hits, and therefore makes it possible for the SIGTRAP handler to report them correctly. If the user manually replaces the watchpoint with another one, DR6 is cleared and LLDB does not associate the concurrent trigger to the watchpoint that no longer exists.

Thread status summary

The current version of the patches fixes approximately 47 test failures, and causes approximately 4 new test failures and 2 hanging tests. There is around 7 new flaky tests, related to signals concurrent with breakpoints or watchpoints.

Future plans

The first immediate goal is to investigate and resolve test suite regressions related to NetBSD 9 upgrade. The second goal is to get the threading patches merged, and simultaneously work on resolving the remaining test failures and hangs.

When that's done, I'd like to finally move on with the remaining TODO items. Those are:

Add support to backtrace through signal trampoline and extend the support to libexecinfo, unwind implementations (LLVM, nongnu). Examine adding CFI support to interfaces that need it to provide more stable backtraces (both kernel and userland).
Add support for i386 and aarch64 targets.
Stabilize LLDB and address breaking tests from the test suite.
Merge LLDB with the base system (under LLVM-style distribution).

This work is sponsored by The NetBSD Foundation

The NetBSD Foundation is a non-profit organization and welcomes any donations to help us continue funding projects and services to the open-source community. Please consider visiting the following URL to chip in what you can:

https://netbsd.org/donations/#how-to-donate

Posted Saturday night, November 9th, 2019 Tags: blog