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eCos SMP Support
================
eCos contains support for limited Symmetric Multi-Processing
(SMP). This is only available on selected architectures and platforms.
This first part of this document describes the platform-independent
parts of the SMP support. Annexes at the end of this document describe
any details that are specific to a particular platform.
Target Hardware Limitations
---------------------------
To allow a reasonable implementation of SMP, and to reduce the
disruption to the existing source base, a number of assumptions have
been made about the features of the target hardware.
- Modest multiprocessing. The typical number of CPUs supported is two
to four, with an upper limit around eight. While there are no
inherent limits in the code, hardware and algorithmic limitations
will probably become significant beyond this point.
- SMP synchronization support. The hardware must supply a mechanism to
allow software on two CPUs to synchronize. This is normally provided
as part of the instruction set in the form of test-and-set,
compare-and-swap or load-link/store-conditional instructions. An
alternative approach is the provision of hardware semaphore
registers which can be used to serialize implementations of these
operations. Whatever hardware facilities are available, they are
used in eCos to implement spinlocks.
- Coherent caches. It is assumed that no extra effort will be required
to access shared memory from any processor. This means that either
there are no caches, they are shared by all processors, or are
maintained in a coherent state by the hardware. It would be too
disruptive to the eCos sources if every memory access had to be
bracketed by cache load/flush operations. Any hardware that requires
this is not supported.
- Uniform addressing. It is assumed that all memory that is
shared between CPUs is addressed at the same location from all
CPUs. Like non-coherent caches, dealing with CPU-specific address
translation is considered too disruptive to the eCos source
base. This does not, however, preclude systems with non-uniform
access costs for different CPUs.
- Uniform device addressing. As with access to memory, it is assumed
that all devices are equally accessible to all CPUs. Since device
access is often made from thread contexts, it is not possible to
restrict access to device control registers to certain CPUs, since
there is currently no support for binding or migrating threads to CPUs.
- Interrupt routing. The target hardware must have an interrupt
controller that can route interrupts to specific CPUs. It is
acceptable for all interrupts to be delivered to just one CPU, or
for some interrupts to be bound to specific CPUs, or for some
interrupts to be local to each CPU. At present dynamic routing,
where a different CPU may be chosen each time an interrupt is
delivered, is not supported. ECos cannot support hardware where all
interrupts are delivered to all CPUs simultaneously with the
expectation that software will resolve any conflicts.
- Inter-CPU interrupts. A mechanism to allow one CPU to interrupt
another is needed. This is necessary so that events on one CPU can
cause rescheduling on other CPUs.
- CPU Identifiers. Code running on a CPU must be able to determine
which CPU it is running on. The CPU Id is usually provided either in
a CPU status register, or in a register associated with the
inter-CPU interrupt delivery subsystem. Ecos expects CPU Ids to be
small positive integers, although alternative representations, such
as bitmaps, can be converted relatively easily. Complex mechanisms
for getting the CPU Id cannot be supported. Getting the CPU Id must
be a cheap operation, since it is done often, and in performance
critical places such as interrupt handlers and the scheduler.
Kernel Support
--------------
This section describes how SMP is handled in the kernel, and where
system behaviour differs from a single CPU system.
System Startup
~~~~~~~~~~~~~~
System startup takes place on only one CPU, called the primary
CPU. All other CPUs, the secondary CPUs, are either placed in
suspended state at reset, or are captured by the HAL and put into
a spin as they start up.
The primary CPU is responsible for copying the DATA segment and
zeroing the BSS (if required), calling HAL variant and platform
initialization routines and invoking constructors. It then calls
cyg_start() to enter the application. The application may then create
extra threads and other objects.
It is only when the application calls Cyg_Scheduler::start() that the
secondary CPUs are initialized. This routine scans the list of
available secondary CPUs and calls HAL_SMP_CPU_START() to start each one.
Finally it calls Cyg_Scheduler::start_cpu().
Each secondary CPU starts in the HAL, where it completes any per-CPU
initialization before calling into the kernel at
cyg_kernel_cpu_startup(). Here it claims the scheduler lock and calls
Cyg_Scheduler::start_cpu().
Cyg_Scheduler::start_cpu() is common to both the primary and secondary
CPUs. The first thing this code does is to install an interrupt object
for this CPU's inter-CPU interrupt. From this point on the code is the
same as for the single CPU case: an initial thread is chosen and
entered.
From this point on the CPUs are all equal, eCos makes no further
distinction between the primary and secondary CPUs. However, the
hardware may still distinguish them as far as interrupt delivery is
concerned.
Scheduling
~~~~~~~~~~
To function correctly an operating system kernel must protect its
vital data structures, such as the run queues, from concurrent
access. In a single CPU system the only concurrent activities to worry
about are asynchronous interrupts. The kernel can easily guard its
data structures against these by disabling interrupts. However, in a
multi-CPU system, this is inadequate since it does not block access by
other CPUs.
The eCos kernel protects its vital data structures using the scheduler
lock. In single CPU systems this is a simple counter that is
atomically incremented to acquire the lock and decremented to release
it. If the lock is decremented to zero then the scheduler may be
invoked to choose a different thread to run. Because interrupts may
continue to be serviced while the scheduler lock is claimed, ISRs are
not allowed to access kernel data structures, or call kernel routines
that can. Instead all such operations are deferred to an associated
DSR routine that is run during the lock release operation, when the
data structures are in a consistent state.
By choosing a kernel locking mechanism that does not rely on interrupt
manipulation to protect data structures, it is easier to convert eCos
to SMP than would otherwise be the case. The principal change needed to
make eCos SMP-safe is to convert the scheduler lock into a nestable
spin lock. This is done by adding a spinlock and a CPU id to the
original counter.
The algorithm for acquiring the scheduler lock is very simple. If the
scheduler lock's CPU id matches the current CPU then it can increment
the counter and continue. If it does not match, the CPU must spin on
the spinlock, after which it may increment the counter and store its
own identity in the CPU id.
To release the lock, the counter is decremented. If it goes to zero
the CPU id value must be set to NONE and the spinlock cleared.
To protect these sequences against interrupts, they must be performed
with interrupts disabled. However, since these are very short code
sequences, they will not have an adverse effect on the interrupt
latency.
Beyond converting the scheduler lock, further preparing the kernel for
SMP is a relatively minor matter. The main changes are to convert
various scalar housekeeping variables into arrays indexed by CPU
id. These include the current thread pointer, the need_reschedule
flag and the timeslice counter.
At present only the Multi-Level Queue (MLQ) scheduler is capable of
supporting SMP configurations. The main change made to this scheduler
is to cope with having several threads in execution at the same
time. Running threads are marked with the CPU they are executing on.
When scheduling a thread, the scheduler skips past any running threads
until it finds a thread that is pending. While not a constant-time
algorithm, as in the single CPU case, this is still deterministic,
since the worst case time is bounded by the number of CPUs in the
system.
A second change to the scheduler is in the code used to decide when
the scheduler should be called to choose a new thread. The scheduler
attempts to keep the *n* CPUs running the *n* highest priority
threads. Since an event or interrupt on one CPU may require a
reschedule on another CPU, there must be a mechanism for deciding
this. The algorithm currently implemented is very simple. Given a
thread that has just been awakened (or had its priority changed), the
scheduler scans the CPUs, starting with the one it is currently
running on, for a current thread that is of lower priority than the
new one. If one is found then a reschedule interrupt is sent to that
CPU and the scan continues, but now using the current thread of the
rescheduled CPU as the candidate thread. In this way the new thread
gets to run as quickly as possible, hopefully on the current CPU, and
the remaining CPUs will pick up the remaining highest priority
threads as a consequence of processing the reschedule interrupt.
The final change to the scheduler is in the handling of
timeslicing. Only one CPU receives timer interrupts, although all CPUs
must handle timeslicing. To make this work, the CPU that receives the
timer interrupt decrements the timeslice counter for all CPUs, not
just its own. If the counter for a CPU reaches zero, then it sends a
timeslice interrupt to that CPU. On receiving the interrupt the
destination CPU enters the scheduler and looks for another thread at
the same priority to run. This is somewhat more efficient than
distributing clock ticks to all CPUs, since the interrupt is only
needed when a timeslice occurs.
Device Drivers
~~~~~~~~~~~~~~
The main area where the SMP nature of a system will be most apparent
is in device drivers. It is quite possible for the ISR, DSR and thread
components of a device driver to execute on different CPUs. For this
reason it is much more important that SMP-capable device drivers use
the driver API routines correctly.
Synchronization between threads and DSRs continues to require that the
thread-side code use cyg_drv_dsr_lock() and cyg_drv_dsr_unlock() to
protect access to shared data. Synchronization between ISRs and DSRs
or threads requires that access to sensitive data be protected, in all
places, by calls to cyg_drv_isr_lock() and cyg_drv_isr_unlock().
The ISR lock, for SMP systems, not only disables local interrupts, but
also acquires a spinlock to protect against concurrent access from
other CPUs. This is necessary because ISRs are not run with the
scheduler lock claimed. Hence they can run in parallel with other
components of the device driver.
The ISR lock provided by the driver API is just a shared spinlock that
is available for use by all drivers. If a driver needs to implement a
finer grain of locking, it can use private spinlocks, accessed via the
cyg_drv_spinlock_*() functions (see API later).
API Extensions
--------------
In general, the SMP support is invisible to application code. All
synchronization and communication operations function exactly as
before. The main area where code needs to be SMP aware is in the
handling of interrupt routing, and in the synchronization of ISRs,
DSRs and threads.
The following sections contain brief descriptions of the API
extensions added for SMP support. More details will be found in the
Kernel C API and Device Driver API documentation.
Interrupt Routing
~~~~~~~~~~~~~~~~~
Two new functions have been added to the Kernel API and the device
driver API to do interrupt routing. These are:
void cyg_interrupt_set_cpu( cyg_vector_t vector, cyg_cpu_t cpu );
void cyg_drv_interrupt_set_cpu( cyg_vector_t vector, cyg_cpu_t cpu );
cyg_cpu_t cyg_interrupt_get_cpu( cyg_vector_t vector );
cyg_cpu_t cyg_drv_interrupt_get_cpu( cyg_vector_t vector );
the *_set_cpu() functions cause the given interrupt to be handled by
the nominated CPU.
The *_get_cpu() functions return the CPU to which the vector is
routed.
Although not currently supported, special values for the cpu argument
may be used to indicate that the interrupt is being routed dynamically
or is CPU-local.
Once a vector has been routed to a new CPU, all other interrupt
masking and configuration operations are relative to that CPU, where
relevant.
Synchronization
~~~~~~~~~~~~~~~
All existing synchronization mechanisms work as before in an SMP
system. Additional synchronization mechanisms have been added to
provide explicit synchronization for SMP.
A set of functions have been added to the Kernel and device driver
APIs to provide spinlocks:
void cyg_spinlock_init( cyg_spinlock_t *lock, cyg_bool_t locked );
void cyg_drv_spinlock_init( cyg_spinlock_t *lock, cyg_bool_t locked );
void cyg_spinlock_destroy( cyg_spinlock_t *lock );
void cyg_drv_spinlock_destroy( cyg_spinlock_t *lock );
void cyg_spinlock_spin( cyg_spinlock_t *lock );
void cyg_drv_spinlock_spin( cyg_spinlock_t *lock );
void cyg_spinlock_clear( cyg_spinlock_t *lock );
void cyg_drv_spinlock_clear( cyg_spinlock_t *lock );
cyg_bool_t cyg_spinlock_try( cyg_spinlock_t *lock );
cyg_bool_t cyg_drv_spinlock_try( cyg_spinlock_t *lock );
cyg_bool_t cyg_spinlock_test( cyg_spinlock_t *lock );
cyg_bool_t cyg_drv_spinlock_test( cyg_spinlock_t *lock );
void cyg_spinlock_spin_intsave( cyg_spinlock_t *lock,
cyg_addrword_t *istate );
void cyg_drv_spinlock_spin_intsave( cyg_spinlock_t *lock,
cyg_addrword_t *istate );
void cyg_spinlock_clear_intsave( cyg_spinlock_t *lock,
cyg_addrword_t istate );
void cyg_drv_spinlock_clear_intsave( cyg_spinlock_t *lock,
cyg_addrword_t istate );
The *_init() functions initialize the lock, to either locked or clear,
and the *_destroy() functions destroy the lock. Init() should be called
before the lock is used and destroy() should be called when it is
finished with.
The *_spin() functions will cause the calling CPU to spin until it can
claim the lock and the *_clear() functions clear the lock so that the
next CPU can claim it. The *_try() functions attempts to claim the lock
but returns false if it cannot. The *_test() functions simply return
the state of the lock.
None of these functions will necessarily block interrupts while they
spin. If the spinlock is only to be used between threads on different
CPUs, or in circumstances where it is known that the relevant
interrupts are disabled, then these functions will suffice. However,
if the spinlock is also to be used from an ISR, which may be called at
any point, a straightforward spinlock may result in deadlock. Hence
the *_intsave() variants are supplied to disable interrupts while the
lock is held.
The *_spin_intsave() function disables interrupts, saving the current
state in *istate, and then claims the lock. The *_clear_intsave()
function clears the spinlock and restores the interrupt enable state
from *istate.
HAL Support
-----------
SMP support in any platform depends on the HAL supplying the
appropriate operations. All HAL SMP support is defined in the
hal_smp.h header (and if necessary var_smp.h and plf_smp.h).
SMP support falls into a number of functional groups.
CPU Control
~~~~~~~~~~~
This group consists of descriptive and control macros for managing the
CPUs in an SMP system.
HAL_SMP_CPU_TYPE A type that can contain a CPU id. A CPU id is
usually a small integer that is used to index
arrays of variables that are managed on an
per-CPU basis.
HAL_SMP_CPU_MAX The maximum number of CPUs that can be
supported. This is used to provide the size of
any arrays that have an element per CPU.
HAL_SMP_CPU_COUNT() Returns the number of CPUs currently
operational. This may differ from
HAL_SMP_CPU_MAX depending on the runtime
environment.
HAL_SMP_CPU_THIS() Returns the CPU id of the current CPU.
HAL_SMP_CPU_NONE A value that does not match any real CPU
id. This is uses where a CPU type variable
must be set to a nul value.
HAL_SMP_CPU_START( cpu )
Starts the given CPU executing at a defined
HAL entry point. After performing any HAL
level initialization, the CPU calls up into
the kernel at cyg_kernel_cpu_startup().
HAL_SMP_CPU_RESCHEDULE_INTERRUPT( cpu, wait )
Sends the CPU a reschedule interrupt, and if
_wait_ is non-zero, waits for an
acknowledgment. The interrupted CPU should
call cyg_scheduler_set_need_reschedule() in
its DSR to cause the reschedule to occur.
HAL_SMP_CPU_TIMESLICE_INTERRUPT( cpu, wait )
Sends the CPU a timeslice interrupt, and if
_wait_ is non-zero, waits for an
acknowledgment. The interrupted CPU should
call cyg_scheduler_timeslice_cpu() to cause
the timeslice event to be processed.
Test-and-set Support
~~~~~~~~~~~~~~~~~~~~
Test-and-set is the foundation of the SMP synchronization
mechanisms.
HAL_TAS_TYPE The type for all test-and-set variables. The
test-and-set macros only support operations on
a single bit (usually the least significant
bit) of this location. This allows for maximum
flexibility in the implementation.
HAL_TAS_SET( tas, oldb )
Performs a test and set operation on the
location _tas_. _oldb_ will contain *true* if
the location was already set, and *false* if
it was clear.
HAL_TAS_CLEAR( tas, oldb )
Performs a test and clear operation on the
location _tas_. _oldb_ will contain *true* if
the location was already set, and *false* if
it was clear.
Spinlocks
~~~~~~~~~
Spinlocks provide inter-CPU locking. Normally they will be implemented
on top of the test-and-set mechanism above, but may also be
implemented by other means if, for example, the hardware has more
direct support for spinlocks.
HAL_SPINLOCK_TYPE The type for all spinlock variables.
HAL_SPINLOCK_INIT_CLEAR A value that may be assigned to a spinlock
variable to initialize it to clear.
HAL_SPINLOCK_INIT_SET A value that may be assigned to a spinlock
variable to initialize it to set.
HAL_SPINLOCK_SPIN( lock )
The caller spins in a busy loop waiting for
the lock to become clear. It then sets it and
continues. This is all handled atomically, so
that there are no race conditions between CPUs.
HAL_SPINLOCK_CLEAR( lock )
The caller clears the lock. One of any waiting
spinners will then be able to proceed.
HAL_SPINLOCK_TRY( lock, val )
Attempts to set the lock. The value put in
_val_ will be *true* if the lock was
claimed successfully, and *false* if it was
not.
HAL_SPINLOCK_TEST( lock, val )
Tests the current value of the lock. The value
put in _val_ will be *true* if the lock is
claimed and *false* of it is clear.
Scheduler Lock
~~~~~~~~~~~~~~
The scheduler lock is the main protection for all kernel data
structures. By default the kernel implements the scheduler lock itself
using a spinlock. However, if spinlocks cannot be supported by the
hardware, or there is a more efficient implementation available, the
HAL may provide macros to implement the scheduler lock.
HAL_SMP_SCHEDLOCK_DATA_TYPE
A data type, possibly a structure, that
contains any data items needed by the
scheduler lock implementation. A variable of
this type will be instantiated as a static
member of the Cyg_Scheduler_SchedLock class
and passed to all the following macros.
HAL_SMP_SCHEDLOCK_INIT( lock, data )
Initialize the scheduler lock. The _lock_
argument is the scheduler lock counter and the
_data_ argument is a variable of
HAL_SMP_SCHEDLOCK_DATA_TYPE type.
HAL_SMP_SCHEDLOCK_INC( lock, data )
Increment the scheduler lock. The first
increment of the lock from zero to one for any
CPU may cause it to wait until the lock is
zeroed by another CPU. Subsequent increments
should be less expensive since this CPU
already holds the lock.
HAL_SMP_SCHEDLOCK_ZERO( lock, data )
Zero the scheduler lock. This operation will
also clear the lock so that other CPUs may
claim it.
HAL_SMP_SCHEDLOCK_SET( lock, data, new )
Set the lock to a different value, in
_new_. This is only called when the lock is
already known to be owned by the current
CPU. It is never called to zero the lock, or
to increment it from zero.
Interrupt Routing
~~~~~~~~~~~~~~~~~
The routing of interrupts to different CPUs is supported by two new
interfaces in hal_intr.h.
Once an interrupt has been routed to a new CPU, the existing vector
masking and configuration operations should take account of the CPU
routing. For example, if the operation is not invoked on the
destination CPU itself, then the HAL may need to arrange to transfer
the operation to the destination CPU for correct application.
HAL_INTERRUPT_SET_CPU( vector, cpu )
Route the interrupt for the given _vector_ to
the given _cpu_.
HAL_INTERRUPT_GET_CPU( vector, cpu )
Set _cpu_ to the id of the CPU to which this
vector is routed.
Annex 1 - Pentium SMP Support
=============================
ECos supports SMP working on Pentium class IA32 CPUs with integrated
SMP support. It uses the per-CPU APIC's and the IOAPIC to provide CPU
control and identification, and to distribute interrupts. Only PCI
interrupts that map into the ISA interrupt space are currently
supported. The code relies on the MP Configuration Table supplied by
the BIOS to discover the number of CPUs, IOAPIC location and interrupt
assignments - hardware based MP configuration discovery is
not currently supported.
Inter-CPU interrupts are mapped into interrupt vectors from 64
up. Each CPU has its own vector at 64+CPUID.
Interrupt delivery is initially configured to deliver all interrupts
to the initial CPU. HAL_INTERRUPT_SET_CPU() currently only supports
the ability to deliver interrupts to specific CPUs, dynamic CPU
selection is not currently supported.
eCos has only been tested in a dual processor configuration. While the
code has been written to handle an arbitrary number of CPUs, this has
not been tested.
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