This repository contains a device driver for the Arm(R) Ethos(TM)-U NPU.
The source code comes with a CMake based build system. The driver is expected to be cross compiled for any of the supported Arm Cortex(R)-M CPUs, which requires the user to configure the build to match their system configuration.
One such requirement is to define the target CPU, normally by setting
CMAKE_SYSTEM_PROCESSOR
. Note that when using the toolchain files provided
in core_platform,
the variable TARGET_CPU
must be used instead of CMAKE_SYSTEM_PROCESSOR
.
Target CPU is specified on the form "cortex-m", for example: "cortex-m55+nodsp+nofp".
Similarly the target NPU configuration is
controlled by setting ETHOSU_TARGET_NPU_CONFIG
, for example "ethos-u55-128".
The build configuration can be defined either in the toolchain file or by passing options on the command line.
$ cmake -B build \
-DCMAKE_TOOLCHAIN_FILE=<toolchain> \
-DCMAKE_SYSTEM_PROCESSOR=cortex-m<nr><features> \
-DETHOSU_TARGET_NPU_CONFIG=ethos-u<nr>-<macs>
$ cmake --build build
or when using toolchain files from core_platform
$ cmake -B build \
-DCMAKE_TOOLCHAIN_FILE=<core_platform_toolchain> \
-DTARGET_CPU=cortex-m<nr><features> \
-DETHOSU_TARGET_NPU_CONFIG=ethos-u<nr>-<macs>
$ cmake --build build
The driver APIs are defined in include/ethosu_driver.h
and the related types
in include/ethosu_types.h
. Inferences can be invoked in two manners:
synchronously or asynchronously. The two types of invocation can be freely mixed
in a single application.
A typical usage of the driver can be the following:
// reserve a driver to be used (this call could block until a driver is available)
struct ethosu_driver *drv = ethosu_reserve_driver();
...
// run one or more inferences
int result = ethosu_invoke(drv,
custom_data_ptr,
custom_data_size,
base_addr,
base_addr_size,
num_base_addr);
...
// release the driver for others to use
ethosu_release_driver(drv);
A typical usage of the driver can be the following:
// reserve a driver to be used (this call could block until a driver is available)
struct ethosu_driver *drv = ethosu_reserve_driver();
...
// run one or more inferences
int result = ethosu_invoke_async(drv,
custom_data_ptr,
custom_data_size,
base_addr,
base_addr_size,
num_base_addr,
user_arg);
...
// do some other work
...
int ret;
do {
// true = blocking, false = non-blocking
// ret > 0 means inference not completed (only for non-blocking mode)
ret = ethosu_wait(drv, <true|false>);
} while(ret > 0);
...
// release the driver for others to use
ethosu_release_driver(drv);
Note that if ethosu_wait
is invoked from a different thread and concurrently
with ethosu_invoke_async
, the user is responsible to guarantee that
ethosu_wait
is called after a successful completion of ethosu_invoke_async
.
Otherwise ethosu_wait
might fail and not actually wait for the inference
completion.
In order to use a driver it first needs to be initialized by calling the init
function, which will also register the handle in the list of available drivers.
A driver can be torn down by using the deinit
function, which also removes the
driver from the list.
The correct mapping is one driver per NPU device. Note that the NPUs must have the same configuration, indeed the NPU configuration can be only one, which is defined at compile time.
The driver is structured in two main parts: the driver, which is responsible to provide an unified API to the user; and the device part, which deals with the details at the hardware level.
In order to do its task the driver needs a device implementation. There could be multiple device implementation for different hardware model and/or configurations. Note that the driver can be compiled to target only one NPU configuration by specializing the device part at compile time.
For running the driver on Arm CPUs which are configured with data cache, the cache maintenance functions in the driver are exported with weakly linked symbols that should be overridden. An example implementation using the CMSIS primitives found in cachel1_armv7.h could be as below:
extern "C" {
void ethosu_flush_dcache(uint32_t *p, size_t bytes) {
if (p)
SCB_CleanDCache_by_Addr(p, bytes);
else
SCB_CleanDCache();
}
void ethosu_invalidate_dcache(uint32_t *p, size_t bytes) {
if (p)
SCB_InvalidateDCache_by_Addr(p, bytes);
else
SCB_InvalidateDCache();
}
}
To ensure the correct functionality of the driver mutexes and semaphores are used internally. The default implementations of mutexes and semaphores are designed for a single-threaded baremetal environment. Hence for integration in environemnts where multi-threading is possible, e.g., RTOS, the user is responsible to provide implementation for mutexes and semaphores to be used by the driver.
The mutex and semaphores are used as synchronisation mechanisms and unless specified, the timeout is required to be 'forever'.
The driver allows for an RTOS to set a timeout for the NPU interrupt semaphore.
The timeout can be set with the CMake variable ETHOSU_INFERENCE_TIMEOUT
, which
is then used as timeout
argument for the interrupt semaphore take call. Note
that the unit is implementation defined, the value is shipped as is to the
ethosu_semaphore_take()
function and an override implementation should cast it
to the appropriate type and/or convert it to the unit desired.
A macro ETHOSU_SEMAPHORE_WAIT_FOREVER
is defined in the driver header file,
and should be made sure to map to the RTOS' equivalent of
'no timeout/wait forever'. Inference timeout value defaults to this if left
unset. The macro is used internally in the driver for the available NPU's, thus
the driver does NOT support setting a timeout other than forever when waiting
for an NPU to become available (global ethosu_semaphore).
The mutex and semaphore APIs are defined as weak linked functions that can be overridden by the user. The APIs are the usual ones and described below:
// create a mutex by returning back a handle
void *ethosu_mutex_create(void);
// lock the given mutex
int ethosu_mutex_lock(void *mutex);
// unlock the given mutex
int ethosu_mutex_unlock(void *mutex);
// create a (binary) semaphore by returning back a handle
void *ethosu_semaphore_create(void);
// take from the given semaphore, accepting a timeout (unit impl. defined)
int ethosu_semaphore_take(void *sem, uint64_t timeout);
// give from the given semaphore
int ethosu_semaphore_give(void *sem);
The driver provide weak linked functions as hooks to receive callbacks whenever an inference begins and ends. The user can override such functions when needed. To avoid memory leaks, any allocations done in the ethosu_inference_begin() must be balanced by a corresponding free of the memory in the ethosu_inference_end() callback.
The end callback will always be called if the begin callback has been called, including in the event of an interrupt semaphore take timeout.
void ethosu_inference_begin(struct ethosu_driver *drv, void *user_arg);
void ethosu_inference_end(struct ethosu_driver *drv, void *user_arg);
Note that the void *user_arg
pointer passed to invoke() function is the same
pointer passed to the begin() and end() callbacks. For example:
void my_function() {
...
struct my_data data = {...};
int result = int ethosu_invoke_v3(drv,
custom_data_ptr,
custom_data_size,
base_addr,
base_addr_size,
num_base_addr,
(void *)&data);
....
}
void ethosu_inference_begin(struct ethosu_driver *drv, void *user_arg) {
struct my_data *data = (struct my_data*) user_arg;
// use drv and data here
}
void ethosu_inference_end(struct ethosu_driver *drv, void *user_arg) {
struct my_data *data = (struct my_data*) user_arg;
// use drv and data here
}
The Arm Ethos-U core driver is provided under an Apache-2.0 license. Please see LICENSE.txt for more information.
The Arm Ethos-U project welcomes contributions under the Apache-2.0 license.
Before we can accept your contribution, you need to certify its origin and give us your permission. For this process we use the Developer Certificate of Origin (DCO) V1.1 (https://developercertificate.org).
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Author: John Doe \<[email protected]\>
Date: Mon Feb 29 12:12:12 2016 +0000
Title of the commit
Short description of the change.
Signed-off-by: John Doe [email protected]
Signed-off-by: Foo Bar [email protected]
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