aboutsummaryrefslogtreecommitdiff
path: root/gas
diff options
context:
space:
mode:
authorJoel Brobecker <brobecker@adacore.com>2017-11-21 13:42:48 -0800
committerJoel Brobecker <brobecker@adacore.com>2017-11-21 14:30:55 -0800
commite02544b292a3d537b43ae9cff890ea040b944d01 (patch)
treeabd55a477799b3733bb6bbeee7809fb2fdf8082e /gas
parentd6251545e230b243abe60e334bb3f78c5e564fa1 (diff)
downloadgdb-e02544b292a3d537b43ae9cff890ea040b944d01.zip
gdb-e02544b292a3d537b43ae9cff890ea040b944d01.tar.gz
gdb-e02544b292a3d537b43ae9cff890ea040b944d01.tar.bz2
watchpoint regression debugging with remote protocol (bare metal)
We have noticed a regression in our watchpoint support when debugging through the remote protocol a program running on a bare metal platform, when the program uses what we call the Ravenscar Runtime. This runtime is a subset of the Ada runtime defined by the Ravenscar Profile. One of the nice things about this runtime is that it provides tasking, which is equivalent to the concept of threads in C (it is actually often mapped to threads, when available). For bare metal targets, however, there is no OS, and therefore no thread layer. What we did, then, was add a ravenscar-thread layer, which has insider knowledge of the runtime to get the list of threads, but also all necessary info to perform thread switching. For the record, the commit which caused the regression is: commit 799a2abe613be0645b84f5aaa050f2f91e6ae3f7 Date: Mon Nov 30 16:05:16 2015 +0000 Subject: remote: stop reason and watchpoint data address per thread Running local-watch-wrong-thread.exp with "maint set target-non-stop on" exposes that gdb/remote.c only records whether the target stopped for a breakpoint/watchpoint plus the watchpoint data address *for the last reported remote event*. But in non-stop mode, we need to keep that info per-thread, as each thread can end up with its own last-status pending. Our testcase is very simple. We have a package defining a global variable named "Watch"... package Pck is Watch : Integer := 1974; end Pck; ... and a main subprogram which changes its value procedure Foo is begin Pck.Watch := Pck.Watch + 1; end Foo; To reproduce, we built our program as usual, started it in QEMU, and then connected GDB to QEMU... (gdb) target remote :4444 (gdb) break _ada_foo (gdb) cont <--- this is to make sure the program is started and the variable we want to watch is initialized ... at which point we try to use a watchpoint on our global variable: (gdb) watch watch ... but, upon resuming the execution with a "cont", we expected to get a watchpoint-hit notification, such as... (gdb) cont Hardware watchpoint 2: watch Old value = 1974 New value = 1975 0xfff00258 in foo () at /[...]/foo.adb:6 6 end Foo; ... but unfortunately, we get a SIGTRAP instead: (gdb) cont Program received signal SIGTRAP, Trace/breakpoint trap. foo () at /[...]/foo.adb:6 6 end Foo; What happens is that, on the one hand, the change in remote.c now stores the watchpoint-hit notification info in the thread that received it; and on the other hand, we have a ravenscar-thread layer which manages the thread list on top of the remote protocol layer. The two of them get disconnected, and this eventually results in GDB not realizing that we hit a watchpoint. Below is how: First, once connected and just before inserting our watchpoint, we have the ravenscar-thread layer which built the list of threads by extracting some info from inferior memory, giving us the following two threads: (gdb) info threads Id Target Id Frame 1 Thread 0 "0Q@" (Ravenscar task) foo () at /[...]/foo.adb:5 * 2 Thread 0x24618 (Ravenscar task) foo () at /[...]/foo.adb:5 The first thread is the only thread QEMU told GDB about. The second one is a thread that the ravenscar-thread added. QEMU has now way to know about those threads, since they are really embedded inside the program; that's why we have the ravenscar layer, which uses inside-knowledge to extract the list of threads. Next, we insert a watchpoint, which applies to all threads. No problem so far. Then, we continue; meaning that GDB sends a Z2 packet to QEMU to get the watchpoint inserted, then a vCont to resume the program's execution. The program hits the watchpoints, and thererfore QEMU reports it back: Packet received: T05thread:01;watch:000022c4; Since QEMU knows about one thread and one thread only, it stands to reason that it would say that the event applies to thread:01, which is our first thread in the "info threads" listing. That thread has a ptid of {42000, lwp=1, tid=0}. This is where Pedro's change kicks in: Seeing this event, and having determined that the event was reported for thread 01, and therefore ptid {42000, lwp=1, tid=0}, it saves the watchpoint-hit event info in the private area of that thread/ptid. Once this is done, remote.c's event-wait layer returns. Enter the ravenscar-thread layer of the event-wait, which does a little dance to delegate the wait to underlying layers with ptids that those layers know about, and then when the target_beneath's to_wait is done, tries to figure out which thread is now the active thread. The code looks like this: 1. inferior_ptid = base_ptid; 2. beneath->to_wait (beneath, base_ptid, status, 0); 3. [...] 4. ravenscar_update_inferior_ptid (); 5. 6. return inferior_ptid; Line 1 is where we reset inferior_ptid to the ptid that the target_beneath layer knows about, allowing us to then call its to_wait implementation (line 2). And then, upon return, we call ravenscar_update_inferior_ptid, which reads inferior memory to determine which thread is actually active, setting inferior_ptid accordingly. Then we return that inferior_ptid (which, again, neither QEMU and therefore nor the remote.c layer knows about). Upon return, we eventually arrive to the part where we try to handle the inferior event: we discover that we got a SIGTRAP and, as part of its handling, we call watchpoints_triggered, which calls target_stopped_by_watchpoint, which eventually remote_stopped_by_watchpoint, where Pedro's change kicks in again: struct thread_info *thread = inferior_thread (); return (thread->priv != NULL && thread->priv->stop_reason == TARGET_STOPPED_BY_WATCHPOINT); Because the ravenscar-thread layer changed the inferior_ptid to the ptid of the active thread, inferior_thread now returns the private data of that thread. This is not the thread that QEMU reported the watchpoint-hit on, and thus, the function returns "no watchpoint hit, mister". Hence GDB not understanding the SIGTRAP, thus reporting it verbatim. The way we chose to fix the issue is by making sure that the ravenscar-thread layer doesn't let the remote layer be called with inferior_ptid being set to a thread that the remote layer does not know about. gdb/ChangeLog: * ravenscar-thread.c (ravenscar_stopped_by_sw_breakpoint) (ravenscar_stopped_by_hw_breakpoint, ravenscar_stopped_by_watchpoint) (ravenscar_stopped_data_address, ravenscar_core_of_thread): New functions. (init_ravenscar_thread_ops): Set the to_stopped_by_sw_breakpoint, to_stopped_by_hw_breakpoint, to_stopped_by_watchpoint, to_stopped_data_address and to_core_of_thread fields of ravenscar_ops.
Diffstat (limited to 'gas')
0 files changed, 0 insertions, 0 deletions