This patch increases init's preserved RAM and capability quota to
account for a current limitation of init with respect to the creation of
sessions to parent services:
In contrast to regular routed services, sessions to parent services are
created via 'Env::session'. The implementation of 'Env::session'
automatically upgrades session quotas on demand, which is the desired
behavior for regular 'Connection' objects. However, for sessions
established on the behalf of init's children, we would need to reflect
the error condition to the child instead of resolving it locally within
init (by subsidizing the session with init's quota). This patch leaves
this issue unresolved but fixes the symptom for the bomb test. It is
meant as an interim solution until the handling of parent sessions is
revised.
This patch decouples the error handling of the quota transfers
and the actual session creation. In the previous version, an error in
the 'initiate_request' phase would leave the local scope via an
exception without disarming the transfer guard objects. This way,
the guard destructors would attempt the returning of session quota in
addition to the explicit call of '_revert_quota_and_destroy' as done in
the error handling of the 'initiate_request' operation.
In the presence of a session-creation error in the 'initiate_request'
phase, session quota would eventually be returned twice. This patch
removes the intertwined error handling of both phases in a way that the
guards of the first phase (quota transfer) are no longer present in the
second phase (initiate_request).
This patch makes sure that the initial PD session limit (as defined by
the client-provided session quota) is preserved over the entire lifetime
of the PD session. That means, it cannot be transferred to other PD
sessions. Otherwise, it may be impossive to hand back all the static
session quota to the PD-session client at session-destruction time
because parts of the initial quota would no longer belong to the
session.
Note that the initial limit can still be used for allocations within the
PD session as those allocations are automatically reverted at
session-destruction time.
The implementations of the lock and C++ guards tests depend on
thread-execution priorities, which produces false negatives of the whole
thread test on platforms without priority support.
On QEMU, NOVA uses the pretty unstable TSC emulation as primary time
source. Thus, timeouts do not trigger with the common precision (< 50
ms). Use an error tolerance of 200 ms for this platform constellation.
Ref #2400
Apparently this construct leads to a compiler errors like
error: second operand to the conditional operator is of type ‘void’, but
the third operand is neither a throw-expression nor of type ‘void’
The fast polling test uses one timer session for raw 'elapsed_ms' calls
and another one for potentially interpolated 'curr_time' calls. It then
compares the two results against each other. However, until now, the
test did not consider that the duration of the session construction may
create a remarkable shift between the local times of the two sessions.
This shift is now determined and compensated before doing any
comparison.
Ref #2400
The multiple-handlers test was checking if handlers at one signal were
activated in a fair manner. But on Qemu, the error tolerance of one was
too small in rare cases (2 of 100 runs). However, having multiple
handlers for the same signal context can be considered deprecated
anyway. With the recommended Signal_handler wrapper for signal sessions,
you can't use this feature. Thus, we removed the multiple-handlers test.
Fixes#2450
The recently implemented capability resource trading scheme unfortunately
broke the automated capability memory upgrade mechanism needed by base-hw
kernel/core. This commit splits the capability memory upgrade mechanism
from the PD session ram_quota upgrade, and moves that functionality
into a separate Pd_session::Native_pd interface.
Ref #2398
We incorrectly used 'unsigned long' (which is 32 or 64 bit depending on
the CPU architecture) for a timestamp (which is always 64 bit) in the
timer-connection implementation.
Ref #2435
On platforms were we do not have local time interpolation we can simply
skip the first test stage in the timeout test. This way, we can at least
test the rest.
Fixes#2435
On ARM, we do not have a component-local hardware time-source. The ARM
performance counter has no reliable frequency as the ARM idle command
halts the counter. Thus, we do not do local time interpolation on ARM.
Except we're on the HW kernel. In this case we can read out the kernel
time instead.
Ref #2435
