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unified: initial unified kernel implementation Summary of what this includes: initialization: Copy from nano_init.c, with the following changes: - the main thread is the continuation of the init thread, but an idle thread is created as well - _main() initializes threads in groups and starts the EXE group - the ready queues are initialized - the main thread is marked as non-essential once the system init is done - a weak main() symbol is provided if the application does not provide a main() function scheduler: Not an exhaustive list, but basically provide primitives for: - adding/removing a thread to/from a wait queue - adding/removing a thread to/from the ready queue - marking thread as ready - locking/unlocking the scheduler - instead of locking interrupts - getting/setting thread priority - checking what state (coop/preempt) a thread is currenlty running in - rescheduling threads - finding what thread is the next to run - yielding/sleeping/aborting sleep - finding the current thread threads: - Add operationns on threads, such as creating and starting them. standardized handling of kernel object return codes: - Kernel objects now cause _Swap() to return the following values: 0 => operation successful -EAGAIN => operation timed out -Exxxxx => operation failed for another reason - The thread's swap_data field can be used to return any additional information required to complete the operation, such as the actual result of a successful operation. timeouts: - same as nano timeouts, renamed to simply 'timeouts' - the kernel is still tick-based, but objects take timeout values in ms for forward compatibility with a tickless kernel. semaphores: - Port of the nanokernel semaphores, which have the same basic behaviour as the microkernel ones. Semaphore groups are not yet implemented. - These semaphores are enhanced in that they accept an initial count and a count limit. This allows configuring them as binary semaphores, and also provisioning them without having to "give" the semaphore multiple times before using them. mutexes: - Straight port of the microkernel mutexes. An init function is added to allow defining them at runtime. pipes: - straight port timers: - amalgamation of nano and micro timers, with all functionalities intact. events: - re-implementation, using semaphores and workqueues. mailboxes: - straight port message queues: - straight port of microkernel FIFOs memory maps: - straight port workqueues: - Basically, have all APIs follow the k_ naming rule, and use the _timeout subsystem from the unified kernel directory, and not the _nano_timeout one. stacks: - Port of the nanokernel stacks. They can now have multiple threads pending on them and threads can wait with a timeout. LIFOs: - Straight port of the nanokernel LIFOs. FIFOs: - Straight port of the nanokernel FIFOs. Work by: Dmitriy Korovkin <dmitriy.korovkin@windriver.com> Peter Mitsis <peter.mitsis@windriver.com> Allan Stephens <allan.stephens@windriver.com> Benjamin Walsh <benjamin.walsh@windriver.com> Change-Id: Id3cadb3694484ab2ca467889cfb029be3cd3a7d6 Signed-off-by: Benjamin Walsh <benjamin.walsh@windriver.com>
2016-09-03 06:55:39 +08:00
/*
* Copyright (c) 2010-2016 Wind River Systems, Inc.
*
license: Replace Apache boilerplate with SPDX tag Replace the existing Apache 2.0 boilerplate header with an SPDX tag throughout the zephyr code tree. This patch was generated via a script run over the master branch. Also updated doc/porting/application.rst that had a dependency on line numbers in a literal include. Manually updated subsys/logging/sys_log.c that had a malformed header in the original file. Also cleanup several cases that already had a SPDX tag and we either got a duplicate or missed updating. Jira: ZEP-1457 Change-Id: I6131a1d4ee0e58f5b938300c2d2fc77d2e69572c Signed-off-by: David B. Kinder <david.b.kinder@intel.com> Signed-off-by: Kumar Gala <kumar.gala@linaro.org>
2017-01-19 09:01:01 +08:00
* SPDX-License-Identifier: Apache-2.0
unified: initial unified kernel implementation Summary of what this includes: initialization: Copy from nano_init.c, with the following changes: - the main thread is the continuation of the init thread, but an idle thread is created as well - _main() initializes threads in groups and starts the EXE group - the ready queues are initialized - the main thread is marked as non-essential once the system init is done - a weak main() symbol is provided if the application does not provide a main() function scheduler: Not an exhaustive list, but basically provide primitives for: - adding/removing a thread to/from a wait queue - adding/removing a thread to/from the ready queue - marking thread as ready - locking/unlocking the scheduler - instead of locking interrupts - getting/setting thread priority - checking what state (coop/preempt) a thread is currenlty running in - rescheduling threads - finding what thread is the next to run - yielding/sleeping/aborting sleep - finding the current thread threads: - Add operationns on threads, such as creating and starting them. standardized handling of kernel object return codes: - Kernel objects now cause _Swap() to return the following values: 0 => operation successful -EAGAIN => operation timed out -Exxxxx => operation failed for another reason - The thread's swap_data field can be used to return any additional information required to complete the operation, such as the actual result of a successful operation. timeouts: - same as nano timeouts, renamed to simply 'timeouts' - the kernel is still tick-based, but objects take timeout values in ms for forward compatibility with a tickless kernel. semaphores: - Port of the nanokernel semaphores, which have the same basic behaviour as the microkernel ones. Semaphore groups are not yet implemented. - These semaphores are enhanced in that they accept an initial count and a count limit. This allows configuring them as binary semaphores, and also provisioning them without having to "give" the semaphore multiple times before using them. mutexes: - Straight port of the microkernel mutexes. An init function is added to allow defining them at runtime. pipes: - straight port timers: - amalgamation of nano and micro timers, with all functionalities intact. events: - re-implementation, using semaphores and workqueues. mailboxes: - straight port message queues: - straight port of microkernel FIFOs memory maps: - straight port workqueues: - Basically, have all APIs follow the k_ naming rule, and use the _timeout subsystem from the unified kernel directory, and not the _nano_timeout one. stacks: - Port of the nanokernel stacks. They can now have multiple threads pending on them and threads can wait with a timeout. LIFOs: - Straight port of the nanokernel LIFOs. FIFOs: - Straight port of the nanokernel FIFOs. Work by: Dmitriy Korovkin <dmitriy.korovkin@windriver.com> Peter Mitsis <peter.mitsis@windriver.com> Allan Stephens <allan.stephens@windriver.com> Benjamin Walsh <benjamin.walsh@windriver.com> Change-Id: Id3cadb3694484ab2ca467889cfb029be3cd3a7d6 Signed-off-by: Benjamin Walsh <benjamin.walsh@windriver.com>
2016-09-03 06:55:39 +08:00
*/
/**
* @brief fixed-size stack object
*/
#include <kernel.h>
kernel/arch: consolidate tTCS and TNANO definitions There was a lot of duplication between architectures for the definition of threads and the "nanokernel" guts. These have been consolidated. Now, a common file kernel/unified/include/kernel_structs.h holds the common definitions. Architectures provide two files to complement it: kernel_arch_data.h and kernel_arch_func.h. The first one contains at least the struct _thread_arch and struct _kernel_arch data structures, as well as the struct _callee_saved and struct _caller_saved register layouts. The second file contains anything that needs what is provided by the common stuff in kernel_structs.h. Those two files are only meant to be included in kernel_structs.h in very specific locations. The thread data structure has been separated into three major parts: common struct _thread_base and struct k_thread, and arch-specific struct _thread_arch. The first and third ones are included in the second. The struct s_NANO data structure has been split into two: common struct _kernel and arch-specific struct _kernel_arch. The latter is included in the former. Offsets files have also changed: nano_offsets.h has been renamed kernel_offsets.h and is still included by the arch-specific offsets.c. Also, since the thread and kernel data structures are now made of sub-structures, offsets have to be added to make up the full offset. Some of these additions have been consolidated in shorter symbols, available from kernel/unified/include/offsets_short.h, which includes an arch-specific offsets_arch_short.h. Most of the code include offsets_short.h now instead of offsets.h. Change-Id: I084645cb7e6db8db69aeaaf162963fe157045d5a Signed-off-by: Benjamin Walsh <benjamin.walsh@windriver.com>
2016-11-08 23:36:50 +08:00
#include <kernel_structs.h>
debug: move debug features from misc to subsys/debug Change-Id: I446be0202325cf3cead7ce3024ca2047e3f7660d Signed-off-by: Anas Nashif <anas.nashif@intel.com>
2016-12-18 02:18:45 +08:00
#include <debug/object_tracing_common.h>
unified: initial unified kernel implementation Summary of what this includes: initialization: Copy from nano_init.c, with the following changes: - the main thread is the continuation of the init thread, but an idle thread is created as well - _main() initializes threads in groups and starts the EXE group - the ready queues are initialized - the main thread is marked as non-essential once the system init is done - a weak main() symbol is provided if the application does not provide a main() function scheduler: Not an exhaustive list, but basically provide primitives for: - adding/removing a thread to/from a wait queue - adding/removing a thread to/from the ready queue - marking thread as ready - locking/unlocking the scheduler - instead of locking interrupts - getting/setting thread priority - checking what state (coop/preempt) a thread is currenlty running in - rescheduling threads - finding what thread is the next to run - yielding/sleeping/aborting sleep - finding the current thread threads: - Add operationns on threads, such as creating and starting them. standardized handling of kernel object return codes: - Kernel objects now cause _Swap() to return the following values: 0 => operation successful -EAGAIN => operation timed out -Exxxxx => operation failed for another reason - The thread's swap_data field can be used to return any additional information required to complete the operation, such as the actual result of a successful operation. timeouts: - same as nano timeouts, renamed to simply 'timeouts' - the kernel is still tick-based, but objects take timeout values in ms for forward compatibility with a tickless kernel. semaphores: - Port of the nanokernel semaphores, which have the same basic behaviour as the microkernel ones. Semaphore groups are not yet implemented. - These semaphores are enhanced in that they accept an initial count and a count limit. This allows configuring them as binary semaphores, and also provisioning them without having to "give" the semaphore multiple times before using them. mutexes: - Straight port of the microkernel mutexes. An init function is added to allow defining them at runtime. pipes: - straight port timers: - amalgamation of nano and micro timers, with all functionalities intact. events: - re-implementation, using semaphores and workqueues. mailboxes: - straight port message queues: - straight port of microkernel FIFOs memory maps: - straight port workqueues: - Basically, have all APIs follow the k_ naming rule, and use the _timeout subsystem from the unified kernel directory, and not the _nano_timeout one. stacks: - Port of the nanokernel stacks. They can now have multiple threads pending on them and threads can wait with a timeout. LIFOs: - Straight port of the nanokernel LIFOs. FIFOs: - Straight port of the nanokernel FIFOs. Work by: Dmitriy Korovkin <dmitriy.korovkin@windriver.com> Peter Mitsis <peter.mitsis@windriver.com> Allan Stephens <allan.stephens@windriver.com> Benjamin Walsh <benjamin.walsh@windriver.com> Change-Id: Id3cadb3694484ab2ca467889cfb029be3cd3a7d6 Signed-off-by: Benjamin Walsh <benjamin.walsh@windriver.com>
2016-09-03 06:55:39 +08:00
#include <toolchain.h>
linker: move all linker headers to include/linker Signed-off-by: Anas Nashif <anas.nashif@intel.com>
2017-06-17 23:30:47 +08:00
#include <linker/sections.h>
unified: rename sched.h to ksched.h Build breaks when enabling CONFIG_NEWLIB_LIBC because it has its own sched.h file. This is a bad symptom of a greater issue: the build system passes many '-I<path>' options to the compiler, and that allows including header files by simply specifying their names (when located somewhere else than <zephyr>/include/) and can cause clashes when several files in different locations have the same name, like in this case. Fixes ZEP-1062. Change-Id: I81d1d69ee6669a609cd0c420b1b8f870d17dcb67 Signed-off-by: Benjamin Walsh <benjamin.walsh@windriver.com>
2016-10-13 22:31:48 +08:00
#include <ksched.h>
unified: initial unified kernel implementation Summary of what this includes: initialization: Copy from nano_init.c, with the following changes: - the main thread is the continuation of the init thread, but an idle thread is created as well - _main() initializes threads in groups and starts the EXE group - the ready queues are initialized - the main thread is marked as non-essential once the system init is done - a weak main() symbol is provided if the application does not provide a main() function scheduler: Not an exhaustive list, but basically provide primitives for: - adding/removing a thread to/from a wait queue - adding/removing a thread to/from the ready queue - marking thread as ready - locking/unlocking the scheduler - instead of locking interrupts - getting/setting thread priority - checking what state (coop/preempt) a thread is currenlty running in - rescheduling threads - finding what thread is the next to run - yielding/sleeping/aborting sleep - finding the current thread threads: - Add operationns on threads, such as creating and starting them. standardized handling of kernel object return codes: - Kernel objects now cause _Swap() to return the following values: 0 => operation successful -EAGAIN => operation timed out -Exxxxx => operation failed for another reason - The thread's swap_data field can be used to return any additional information required to complete the operation, such as the actual result of a successful operation. timeouts: - same as nano timeouts, renamed to simply 'timeouts' - the kernel is still tick-based, but objects take timeout values in ms for forward compatibility with a tickless kernel. semaphores: - Port of the nanokernel semaphores, which have the same basic behaviour as the microkernel ones. Semaphore groups are not yet implemented. - These semaphores are enhanced in that they accept an initial count and a count limit. This allows configuring them as binary semaphores, and also provisioning them without having to "give" the semaphore multiple times before using them. mutexes: - Straight port of the microkernel mutexes. An init function is added to allow defining them at runtime. pipes: - straight port timers: - amalgamation of nano and micro timers, with all functionalities intact. events: - re-implementation, using semaphores and workqueues. mailboxes: - straight port message queues: - straight port of microkernel FIFOs memory maps: - straight port workqueues: - Basically, have all APIs follow the k_ naming rule, and use the _timeout subsystem from the unified kernel directory, and not the _nano_timeout one. stacks: - Port of the nanokernel stacks. They can now have multiple threads pending on them and threads can wait with a timeout. LIFOs: - Straight port of the nanokernel LIFOs. FIFOs: - Straight port of the nanokernel FIFOs. Work by: Dmitriy Korovkin <dmitriy.korovkin@windriver.com> Peter Mitsis <peter.mitsis@windriver.com> Allan Stephens <allan.stephens@windriver.com> Benjamin Walsh <benjamin.walsh@windriver.com> Change-Id: Id3cadb3694484ab2ca467889cfb029be3cd3a7d6 Signed-off-by: Benjamin Walsh <benjamin.walsh@windriver.com>
2016-09-03 06:55:39 +08:00
#include <wait_q.h>
#include <misc/__assert.h>
unified: Add object tracing support for kernel objects Defines an object tracing list for each kernel object type that supports object tracing, and ensures that both statically and dynamically defined objects are added to the appropriate list. Ensure that each static kernel object is grouped together with the other static objects of the same type. Revise the initialization function for each kernel type (or create it, if needed) so that each static object is added to the object tracing list for its associated type. Note 1: Threads are handled a bit differently than other kernel object types. A statically-defined thread is added to the thread list when the thread is started, not when the kernel initializes. Also, a thread is removed from the thread list when the thread terminates or aborts, unlike other types of kernel objects which are never removed from an object tracing list. (Such support would require the creation of APIs to "uninitialize" the kernel object.) Note 2: The list head variables for all kernel object types are now explicitly defined. However, the list head variable for the ring buffer type continues to be implicitly defined for the time being, since it isn't considered to be an core kernel object type. Change-Id: Ie24d41023e05b3598dc6b344e6871a9692bba02d Signed-off-by: Allan Stephens <allan.stephens@windriver.com>
2016-10-20 05:10:46 +08:00
#include <init.h>
kernel: convert stack APIs to system calls Signed-off-by: Andrew Boie <andrew.p.boie@intel.com>
2017-09-30 07:42:07 +08:00
#include <syscall_handler.h>
unified: Add object tracing support for kernel objects Defines an object tracing list for each kernel object type that supports object tracing, and ensures that both statically and dynamically defined objects are added to the appropriate list. Ensure that each static kernel object is grouped together with the other static objects of the same type. Revise the initialization function for each kernel type (or create it, if needed) so that each static object is added to the object tracing list for its associated type. Note 1: Threads are handled a bit differently than other kernel object types. A statically-defined thread is added to the thread list when the thread is started, not when the kernel initializes. Also, a thread is removed from the thread list when the thread terminates or aborts, unlike other types of kernel objects which are never removed from an object tracing list. (Such support would require the creation of APIs to "uninitialize" the kernel object.) Note 2: The list head variables for all kernel object types are now explicitly defined. However, the list head variable for the ring buffer type continues to be implicitly defined for the time being, since it isn't considered to be an core kernel object type. Change-Id: Ie24d41023e05b3598dc6b344e6871a9692bba02d Signed-off-by: Allan Stephens <allan.stephens@windriver.com>
2016-10-20 05:10:46 +08:00
extern struct k_stack _k_stack_list_start[];
extern struct k_stack _k_stack_list_end[];
tracing: rename CONFIG_DEBUG_TRACING_KERNEL_OBJECTS Use a short name for this option CONFIG_OBJECT_TRACING. Change-Id: Id27de7ef9ca299492b6b7d2324d9f5bcf8059a31 Signed-off-by: Anas Nashif <anas.nashif@intel.com>
2016-12-18 19:57:45 +08:00
#ifdef CONFIG_OBJECT_TRACING
unified: Add object tracing support for kernel objects Defines an object tracing list for each kernel object type that supports object tracing, and ensures that both statically and dynamically defined objects are added to the appropriate list. Ensure that each static kernel object is grouped together with the other static objects of the same type. Revise the initialization function for each kernel type (or create it, if needed) so that each static object is added to the object tracing list for its associated type. Note 1: Threads are handled a bit differently than other kernel object types. A statically-defined thread is added to the thread list when the thread is started, not when the kernel initializes. Also, a thread is removed from the thread list when the thread terminates or aborts, unlike other types of kernel objects which are never removed from an object tracing list. (Such support would require the creation of APIs to "uninitialize" the kernel object.) Note 2: The list head variables for all kernel object types are now explicitly defined. However, the list head variable for the ring buffer type continues to be implicitly defined for the time being, since it isn't considered to be an core kernel object type. Change-Id: Ie24d41023e05b3598dc6b344e6871a9692bba02d Signed-off-by: Allan Stephens <allan.stephens@windriver.com>
2016-10-20 05:10:46 +08:00
kernel: make sure that CONFIG_OBJECT_TRACING structs are properly ifdef'ed Fixes sparse warnings: <snip>/zephyr/kernel/timer.c:15:16: warning: symbol '_trace_list_k_timer' was not declared. Should it be static? <snip>/zephyr/kernel/sem.c:32:14: warning: symbol'_trace_list_k_sem' was not declared. Should it be static? <snip>/zephyr/kernel/stack.c:24:16: warning: symbol '_trace_list_k_stack' was not declared. Should it be static? <snip>/zephyr/kernel/queue.c:27:16: warning: symbol '_trace_list_k_queue' was not declared. Should it be static? <snip>/zephyr/kernel/pipes.c:40:15: warning: symbol '_trace_list_k_pipe' was not declared. Should it be static? <snip>/zephyr/kernel/mutex.c:46:16: warning: symbol '_trace_list_k_mutex' was not declared. Should it be static? <snip>/zephyr/kernel/msg_q.c:26:15: warning: symbol '_trace_list_k_msgq' was not declared. Should it be static? <snip>/zephyr/kernel/mem_slab.c:20:19: warning: symbol '_trace_list_k_mem_slab' was not declared. Should it be static? <snip>/zephyr/kernel/mailbox.c:53:15: warning: symbol '_trace_list_k_mbox' was not declared. Should it be static? Change-Id: I42d55aea9855b9c1dd560852ca033c9a19f1ac21 Signed-off-by: Maciek Borzecki <maciek.borzecki@gmail.com>
2017-05-18 18:16:45 +08:00
struct k_stack *_trace_list_k_stack;
unified: Add object tracing support for kernel objects Defines an object tracing list for each kernel object type that supports object tracing, and ensures that both statically and dynamically defined objects are added to the appropriate list. Ensure that each static kernel object is grouped together with the other static objects of the same type. Revise the initialization function for each kernel type (or create it, if needed) so that each static object is added to the object tracing list for its associated type. Note 1: Threads are handled a bit differently than other kernel object types. A statically-defined thread is added to the thread list when the thread is started, not when the kernel initializes. Also, a thread is removed from the thread list when the thread terminates or aborts, unlike other types of kernel objects which are never removed from an object tracing list. (Such support would require the creation of APIs to "uninitialize" the kernel object.) Note 2: The list head variables for all kernel object types are now explicitly defined. However, the list head variable for the ring buffer type continues to be implicitly defined for the time being, since it isn't considered to be an core kernel object type. Change-Id: Ie24d41023e05b3598dc6b344e6871a9692bba02d Signed-off-by: Allan Stephens <allan.stephens@windriver.com>
2016-10-20 05:10:46 +08:00
/*
* Complete initialization of statically defined stacks.
*/
static int init_stack_module(struct device *dev)
{
ARG_UNUSED(dev);
struct k_stack *stack;
for (stack = _k_stack_list_start; stack < _k_stack_list_end; stack++) {
SYS_TRACING_OBJ_INIT(k_stack, stack);
}
return 0;
}
kernel: deprecate old init levels PRIMARY, SECONDARY, NANOKERNEL, MICROKERNEL init levels are now deprecated. New init levels introduced: PRE_KERNEL_1, PRE_KERNEL_2, POST_KERNEL to replace them. Most existing code has instances of PRIMARY replaced with PRE_KERNEL_1, SECONDARY with POST_KERNEL as SECONDARY has had a longstanding bug where the documentation specified SECONDARY ran before the kernel started up, but actually ran afterwards. Change-Id: I771bc634e9caf7f17dbf214a270bc9967eed7d32 Signed-off-by: Andrew Boie <andrew.p.boie@intel.com>
2016-11-09 03:06:55 +08:00
SYS_INIT(init_stack_module, PRE_KERNEL_1, CONFIG_KERNEL_INIT_PRIORITY_OBJECTS);
unified: Add object tracing support for kernel objects Defines an object tracing list for each kernel object type that supports object tracing, and ensures that both statically and dynamically defined objects are added to the appropriate list. Ensure that each static kernel object is grouped together with the other static objects of the same type. Revise the initialization function for each kernel type (or create it, if needed) so that each static object is added to the object tracing list for its associated type. Note 1: Threads are handled a bit differently than other kernel object types. A statically-defined thread is added to the thread list when the thread is started, not when the kernel initializes. Also, a thread is removed from the thread list when the thread terminates or aborts, unlike other types of kernel objects which are never removed from an object tracing list. (Such support would require the creation of APIs to "uninitialize" the kernel object.) Note 2: The list head variables for all kernel object types are now explicitly defined. However, the list head variable for the ring buffer type continues to be implicitly defined for the time being, since it isn't considered to be an core kernel object type. Change-Id: Ie24d41023e05b3598dc6b344e6871a9692bba02d Signed-off-by: Allan Stephens <allan.stephens@windriver.com>
2016-10-20 05:10:46 +08:00
tracing: rename CONFIG_DEBUG_TRACING_KERNEL_OBJECTS Use a short name for this option CONFIG_OBJECT_TRACING. Change-Id: Id27de7ef9ca299492b6b7d2324d9f5bcf8059a31 Signed-off-by: Anas Nashif <anas.nashif@intel.com>
2016-12-18 19:57:45 +08:00
#endif /* CONFIG_OBJECT_TRACING */
unified: initial unified kernel implementation Summary of what this includes: initialization: Copy from nano_init.c, with the following changes: - the main thread is the continuation of the init thread, but an idle thread is created as well - _main() initializes threads in groups and starts the EXE group - the ready queues are initialized - the main thread is marked as non-essential once the system init is done - a weak main() symbol is provided if the application does not provide a main() function scheduler: Not an exhaustive list, but basically provide primitives for: - adding/removing a thread to/from a wait queue - adding/removing a thread to/from the ready queue - marking thread as ready - locking/unlocking the scheduler - instead of locking interrupts - getting/setting thread priority - checking what state (coop/preempt) a thread is currenlty running in - rescheduling threads - finding what thread is the next to run - yielding/sleeping/aborting sleep - finding the current thread threads: - Add operationns on threads, such as creating and starting them. standardized handling of kernel object return codes: - Kernel objects now cause _Swap() to return the following values: 0 => operation successful -EAGAIN => operation timed out -Exxxxx => operation failed for another reason - The thread's swap_data field can be used to return any additional information required to complete the operation, such as the actual result of a successful operation. timeouts: - same as nano timeouts, renamed to simply 'timeouts' - the kernel is still tick-based, but objects take timeout values in ms for forward compatibility with a tickless kernel. semaphores: - Port of the nanokernel semaphores, which have the same basic behaviour as the microkernel ones. Semaphore groups are not yet implemented. - These semaphores are enhanced in that they accept an initial count and a count limit. This allows configuring them as binary semaphores, and also provisioning them without having to "give" the semaphore multiple times before using them. mutexes: - Straight port of the microkernel mutexes. An init function is added to allow defining them at runtime. pipes: - straight port timers: - amalgamation of nano and micro timers, with all functionalities intact. events: - re-implementation, using semaphores and workqueues. mailboxes: - straight port message queues: - straight port of microkernel FIFOs memory maps: - straight port workqueues: - Basically, have all APIs follow the k_ naming rule, and use the _timeout subsystem from the unified kernel directory, and not the _nano_timeout one. stacks: - Port of the nanokernel stacks. They can now have multiple threads pending on them and threads can wait with a timeout. LIFOs: - Straight port of the nanokernel LIFOs. FIFOs: - Straight port of the nanokernel FIFOs. Work by: Dmitriy Korovkin <dmitriy.korovkin@windriver.com> Peter Mitsis <peter.mitsis@windriver.com> Allan Stephens <allan.stephens@windriver.com> Benjamin Walsh <benjamin.walsh@windriver.com> Change-Id: Id3cadb3694484ab2ca467889cfb029be3cd3a7d6 Signed-off-by: Benjamin Walsh <benjamin.walsh@windriver.com>
2016-09-03 06:55:39 +08:00
kernel: stacks: add k_stack_alloc() init Similar to what has been done with pipes and message queues, user mode can't be trusted to provide a buffer for the kernel to use. Remove k_stack_init() as a syscall and offer k_stack_alloc_init() which allocates a buffer from the caller's resource pool. Fixes #7285 Signed-off-by: Andrew Boie <andrew.p.boie@intel.com>
2018-05-03 08:44:39 +08:00
void k_stack_init(struct k_stack *stack, u32_t *buffer,
kernel: MISRA C: Fixes a few MISRA C issues. MISRA C guideline compliance for various rules. Signed-off-by: Adithya Baglody <adithya.nagaraj.baglody@intel.com>
2018-10-15 14:18:51 +08:00
u32_t num_entries)
unified: initial unified kernel implementation Summary of what this includes: initialization: Copy from nano_init.c, with the following changes: - the main thread is the continuation of the init thread, but an idle thread is created as well - _main() initializes threads in groups and starts the EXE group - the ready queues are initialized - the main thread is marked as non-essential once the system init is done - a weak main() symbol is provided if the application does not provide a main() function scheduler: Not an exhaustive list, but basically provide primitives for: - adding/removing a thread to/from a wait queue - adding/removing a thread to/from the ready queue - marking thread as ready - locking/unlocking the scheduler - instead of locking interrupts - getting/setting thread priority - checking what state (coop/preempt) a thread is currenlty running in - rescheduling threads - finding what thread is the next to run - yielding/sleeping/aborting sleep - finding the current thread threads: - Add operationns on threads, such as creating and starting them. standardized handling of kernel object return codes: - Kernel objects now cause _Swap() to return the following values: 0 => operation successful -EAGAIN => operation timed out -Exxxxx => operation failed for another reason - The thread's swap_data field can be used to return any additional information required to complete the operation, such as the actual result of a successful operation. timeouts: - same as nano timeouts, renamed to simply 'timeouts' - the kernel is still tick-based, but objects take timeout values in ms for forward compatibility with a tickless kernel. semaphores: - Port of the nanokernel semaphores, which have the same basic behaviour as the microkernel ones. Semaphore groups are not yet implemented. - These semaphores are enhanced in that they accept an initial count and a count limit. This allows configuring them as binary semaphores, and also provisioning them without having to "give" the semaphore multiple times before using them. mutexes: - Straight port of the microkernel mutexes. An init function is added to allow defining them at runtime. pipes: - straight port timers: - amalgamation of nano and micro timers, with all functionalities intact. events: - re-implementation, using semaphores and workqueues. mailboxes: - straight port message queues: - straight port of microkernel FIFOs memory maps: - straight port workqueues: - Basically, have all APIs follow the k_ naming rule, and use the _timeout subsystem from the unified kernel directory, and not the _nano_timeout one. stacks: - Port of the nanokernel stacks. They can now have multiple threads pending on them and threads can wait with a timeout. LIFOs: - Straight port of the nanokernel LIFOs. FIFOs: - Straight port of the nanokernel FIFOs. Work by: Dmitriy Korovkin <dmitriy.korovkin@windriver.com> Peter Mitsis <peter.mitsis@windriver.com> Allan Stephens <allan.stephens@windriver.com> Benjamin Walsh <benjamin.walsh@windriver.com> Change-Id: Id3cadb3694484ab2ca467889cfb029be3cd3a7d6 Signed-off-by: Benjamin Walsh <benjamin.walsh@windriver.com>
2016-09-03 06:55:39 +08:00
{
kernel: Fix sloppy wait queue API There were multiple spots where code was using the _wait_q_t abstraction as a synonym for a dlist and doing direct list management on them with the dlist APIs. Refactor _wait_q_t into a proper opaque struct (not a typedef for sys_dlist_t) and write a simple wrapper API for the existing usages. Now replacement of wait_q with a different data structure is much cleaner. Note that there were some SYS_DLIST_FOR_EACH_SAFE loops in mailbox.c that got replaced by the normal/non-safe macro. While these loops do mutate the list in the code body, they always do an early return in those circumstances instead of returning into the macro'd for() loop, so the _SAFE usage was needless. Signed-off-by: Andy Ross <andrew.j.ross@intel.com>
2018-05-11 02:10:34 +08:00
_waitq_init(&stack->wait_q);
kernel: MISRA C: Fixes a few MISRA C issues. MISRA C guideline compliance for various rules. Signed-off-by: Adithya Baglody <adithya.nagaraj.baglody@intel.com>
2018-10-15 14:18:51 +08:00
stack->base = buffer;
stack->next = buffer;
unified: initial unified kernel implementation Summary of what this includes: initialization: Copy from nano_init.c, with the following changes: - the main thread is the continuation of the init thread, but an idle thread is created as well - _main() initializes threads in groups and starts the EXE group - the ready queues are initialized - the main thread is marked as non-essential once the system init is done - a weak main() symbol is provided if the application does not provide a main() function scheduler: Not an exhaustive list, but basically provide primitives for: - adding/removing a thread to/from a wait queue - adding/removing a thread to/from the ready queue - marking thread as ready - locking/unlocking the scheduler - instead of locking interrupts - getting/setting thread priority - checking what state (coop/preempt) a thread is currenlty running in - rescheduling threads - finding what thread is the next to run - yielding/sleeping/aborting sleep - finding the current thread threads: - Add operationns on threads, such as creating and starting them. standardized handling of kernel object return codes: - Kernel objects now cause _Swap() to return the following values: 0 => operation successful -EAGAIN => operation timed out -Exxxxx => operation failed for another reason - The thread's swap_data field can be used to return any additional information required to complete the operation, such as the actual result of a successful operation. timeouts: - same as nano timeouts, renamed to simply 'timeouts' - the kernel is still tick-based, but objects take timeout values in ms for forward compatibility with a tickless kernel. semaphores: - Port of the nanokernel semaphores, which have the same basic behaviour as the microkernel ones. Semaphore groups are not yet implemented. - These semaphores are enhanced in that they accept an initial count and a count limit. This allows configuring them as binary semaphores, and also provisioning them without having to "give" the semaphore multiple times before using them. mutexes: - Straight port of the microkernel mutexes. An init function is added to allow defining them at runtime. pipes: - straight port timers: - amalgamation of nano and micro timers, with all functionalities intact. events: - re-implementation, using semaphores and workqueues. mailboxes: - straight port message queues: - straight port of microkernel FIFOs memory maps: - straight port workqueues: - Basically, have all APIs follow the k_ naming rule, and use the _timeout subsystem from the unified kernel directory, and not the _nano_timeout one. stacks: - Port of the nanokernel stacks. They can now have multiple threads pending on them and threads can wait with a timeout. LIFOs: - Straight port of the nanokernel LIFOs. FIFOs: - Straight port of the nanokernel FIFOs. Work by: Dmitriy Korovkin <dmitriy.korovkin@windriver.com> Peter Mitsis <peter.mitsis@windriver.com> Allan Stephens <allan.stephens@windriver.com> Benjamin Walsh <benjamin.walsh@windriver.com> Change-Id: Id3cadb3694484ab2ca467889cfb029be3cd3a7d6 Signed-off-by: Benjamin Walsh <benjamin.walsh@windriver.com>
2016-09-03 06:55:39 +08:00
stack->top = stack->base + num_entries;
SYS_TRACING_OBJ_INIT(k_stack, stack);
kernel: introduce object validation mechanism All system calls made from userspace which involve pointers to kernel objects (including device drivers) will need to have those pointers validated; userspace should never be able to crash the kernel by passing it garbage. The actual validation with _k_object_validate() will be in the system call receiver code, which doesn't exist yet. - CONFIG_USERSPACE introduced. We are somewhat far away from having an end-to-end implementation, but at least need a Kconfig symbol to guard the incoming code with. Formal documentation doesn't exist yet either, but will appear later down the road once the implementation is mostly finalized. - In the memory region for RAM, the data section has been moved last, past bss and noinit. This ensures that inserting generated tables with addresses of kernel objects does not change the addresses of those objects (which would make the table invalid) - The DWARF debug information in the generated ELF binary is parsed to fetch the locations of all kernel objects and pass this to gperf to create a perfect hash table of their memory addresses. - The generated gperf code doesn't know that we are exclusively working with memory addresses and uses memory inefficently. A post-processing script process_gperf.py adjusts the generated code before it is compiled to work with pointer values directly and not strings containing them. - _k_object_init() calls inserted into the init functions for the set of kernel object types we are going to support so far Issue: ZEP-2187 Signed-off-by: Andrew Boie <andrew.p.boie@intel.com>
2017-08-23 04:15:23 +08:00
_k_object_init(stack);
unified: initial unified kernel implementation Summary of what this includes: initialization: Copy from nano_init.c, with the following changes: - the main thread is the continuation of the init thread, but an idle thread is created as well - _main() initializes threads in groups and starts the EXE group - the ready queues are initialized - the main thread is marked as non-essential once the system init is done - a weak main() symbol is provided if the application does not provide a main() function scheduler: Not an exhaustive list, but basically provide primitives for: - adding/removing a thread to/from a wait queue - adding/removing a thread to/from the ready queue - marking thread as ready - locking/unlocking the scheduler - instead of locking interrupts - getting/setting thread priority - checking what state (coop/preempt) a thread is currenlty running in - rescheduling threads - finding what thread is the next to run - yielding/sleeping/aborting sleep - finding the current thread threads: - Add operationns on threads, such as creating and starting them. standardized handling of kernel object return codes: - Kernel objects now cause _Swap() to return the following values: 0 => operation successful -EAGAIN => operation timed out -Exxxxx => operation failed for another reason - The thread's swap_data field can be used to return any additional information required to complete the operation, such as the actual result of a successful operation. timeouts: - same as nano timeouts, renamed to simply 'timeouts' - the kernel is still tick-based, but objects take timeout values in ms for forward compatibility with a tickless kernel. semaphores: - Port of the nanokernel semaphores, which have the same basic behaviour as the microkernel ones. Semaphore groups are not yet implemented. - These semaphores are enhanced in that they accept an initial count and a count limit. This allows configuring them as binary semaphores, and also provisioning them without having to "give" the semaphore multiple times before using them. mutexes: - Straight port of the microkernel mutexes. An init function is added to allow defining them at runtime. pipes: - straight port timers: - amalgamation of nano and micro timers, with all functionalities intact. events: - re-implementation, using semaphores and workqueues. mailboxes: - straight port message queues: - straight port of microkernel FIFOs memory maps: - straight port workqueues: - Basically, have all APIs follow the k_ naming rule, and use the _timeout subsystem from the unified kernel directory, and not the _nano_timeout one. stacks: - Port of the nanokernel stacks. They can now have multiple threads pending on them and threads can wait with a timeout. LIFOs: - Straight port of the nanokernel LIFOs. FIFOs: - Straight port of the nanokernel FIFOs. Work by: Dmitriy Korovkin <dmitriy.korovkin@windriver.com> Peter Mitsis <peter.mitsis@windriver.com> Allan Stephens <allan.stephens@windriver.com> Benjamin Walsh <benjamin.walsh@windriver.com> Change-Id: Id3cadb3694484ab2ca467889cfb029be3cd3a7d6 Signed-off-by: Benjamin Walsh <benjamin.walsh@windriver.com>
2016-09-03 06:55:39 +08:00
}
kernel: MISRA C: Fixes a few MISRA C issues. MISRA C guideline compliance for various rules. Signed-off-by: Adithya Baglody <adithya.nagaraj.baglody@intel.com>
2018-10-15 14:18:51 +08:00
s32_t _impl_k_stack_alloc_init(struct k_stack *stack, u32_t num_entries)
kernel: stacks: add k_stack_alloc() init Similar to what has been done with pipes and message queues, user mode can't be trusted to provide a buffer for the kernel to use. Remove k_stack_init() as a syscall and offer k_stack_alloc_init() which allocates a buffer from the caller's resource pool. Fixes #7285 Signed-off-by: Andrew Boie <andrew.p.boie@intel.com>
2018-05-03 08:44:39 +08:00
{
void *buffer;
kernel: MISRA C: Fixes a few MISRA C issues. MISRA C guideline compliance for various rules. Signed-off-by: Adithya Baglody <adithya.nagaraj.baglody@intel.com>
2018-10-15 14:18:51 +08:00
s32_t ret;
kernel: stacks: add k_stack_alloc() init Similar to what has been done with pipes and message queues, user mode can't be trusted to provide a buffer for the kernel to use. Remove k_stack_init() as a syscall and offer k_stack_alloc_init() which allocates a buffer from the caller's resource pool. Fixes #7285 Signed-off-by: Andrew Boie <andrew.p.boie@intel.com>
2018-05-03 08:44:39 +08:00
buffer = z_thread_malloc(num_entries);
kernel: Explicitly comparing pointer with NULL MISRA-C rule: 14.4 Signed-off-by: Flavio Ceolin <flavio.ceolin@intel.com>
2018-09-21 07:30:45 +08:00
if (buffer != NULL) {
kernel: stacks: add k_stack_alloc() init Similar to what has been done with pipes and message queues, user mode can't be trusted to provide a buffer for the kernel to use. Remove k_stack_init() as a syscall and offer k_stack_alloc_init() which allocates a buffer from the caller's resource pool. Fixes #7285 Signed-off-by: Andrew Boie <andrew.p.boie@intel.com>
2018-05-03 08:44:39 +08:00
k_stack_init(stack, buffer, num_entries);
stack->flags = K_STACK_FLAG_ALLOC;
kernel: MISRA C: Fixes a few MISRA C issues. MISRA C guideline compliance for various rules. Signed-off-by: Adithya Baglody <adithya.nagaraj.baglody@intel.com>
2018-10-15 14:18:51 +08:00
ret = (s32_t)0;
kernel: stacks: add k_stack_alloc() init Similar to what has been done with pipes and message queues, user mode can't be trusted to provide a buffer for the kernel to use. Remove k_stack_init() as a syscall and offer k_stack_alloc_init() which allocates a buffer from the caller's resource pool. Fixes #7285 Signed-off-by: Andrew Boie <andrew.p.boie@intel.com>
2018-05-03 08:44:39 +08:00
} else {
ret = -ENOMEM;
}
return ret;
}
kernel: convert stack APIs to system calls Signed-off-by: Andrew Boie <andrew.p.boie@intel.com>
2017-09-30 07:42:07 +08:00
#ifdef CONFIG_USERSPACE
syscalls: remove policy from handler checks The various macros to do checks in system call handlers all implictly would generate a kernel oops if a check failed. This is undesirable for a few reasons: * System call handlers that acquire resources in the handler have no good recourse for cleanup if a check fails. * In some cases we may want to propagate a return value back to the caller instead of just killing the calling thread, even though the base API doesn't do these checks. These macros now all return a value, if nonzero is returned the check failed. K_OOPS() now wraps these calls to generate a kernel oops. At the moment, the policy for all APIs has not changed. They still all oops upon a failed check/ The macros now use the Z_ notation for private APIs. Signed-off-by: Andrew Boie <andrew.p.boie@intel.com>
2018-05-05 06:57:57 +08:00
Z_SYSCALL_HANDLER(k_stack_alloc_init, stack, num_entries)
kernel: convert stack APIs to system calls Signed-off-by: Andrew Boie <andrew.p.boie@intel.com>
2017-09-30 07:42:07 +08:00
{
syscalls: remove policy from handler checks The various macros to do checks in system call handlers all implictly would generate a kernel oops if a check failed. This is undesirable for a few reasons: * System call handlers that acquire resources in the handler have no good recourse for cleanup if a check fails. * In some cases we may want to propagate a return value back to the caller instead of just killing the calling thread, even though the base API doesn't do these checks. These macros now all return a value, if nonzero is returned the check failed. K_OOPS() now wraps these calls to generate a kernel oops. At the moment, the policy for all APIs has not changed. They still all oops upon a failed check/ The macros now use the Z_ notation for private APIs. Signed-off-by: Andrew Boie <andrew.p.boie@intel.com>
2018-05-05 06:57:57 +08:00
Z_OOPS(Z_SYSCALL_OBJ_NEVER_INIT(stack, K_OBJ_STACK));
Z_OOPS(Z_SYSCALL_VERIFY(num_entries > 0));
kernel: convert stack APIs to system calls Signed-off-by: Andrew Boie <andrew.p.boie@intel.com>
2017-09-30 07:42:07 +08:00
kernel: Fix k_stack_alloc_init behavior The implementation of this syscall can return either 0 or -ENOMEM, but when USERSPACE is enabled and it is called through syscall it always return 0. Just change this syscall implementation to return the value of _impl_k_stack_alloc_init Signed-off-by: Flavio Ceolin <flavio.ceolin@intel.com>
2018-09-13 14:03:05 +08:00
return _impl_k_stack_alloc_init((struct k_stack *)stack, num_entries);
kernel: convert stack APIs to system calls Signed-off-by: Andrew Boie <andrew.p.boie@intel.com>
2017-09-30 07:42:07 +08:00
}
#endif
kernel: stacks: add k_stack_alloc() init Similar to what has been done with pipes and message queues, user mode can't be trusted to provide a buffer for the kernel to use. Remove k_stack_init() as a syscall and offer k_stack_alloc_init() which allocates a buffer from the caller's resource pool. Fixes #7285 Signed-off-by: Andrew Boie <andrew.p.boie@intel.com>
2018-05-03 08:44:39 +08:00
void k_stack_cleanup(struct k_stack *stack)
{
kernel: MISRA C: Fixes a few MISRA C issues. MISRA C guideline compliance for various rules. Signed-off-by: Adithya Baglody <adithya.nagaraj.baglody@intel.com>
2018-10-15 14:18:51 +08:00
__ASSERT_NO_MSG(_waitq_head(&stack->wait_q) == NULL);
kernel: stacks: add k_stack_alloc() init Similar to what has been done with pipes and message queues, user mode can't be trusted to provide a buffer for the kernel to use. Remove k_stack_init() as a syscall and offer k_stack_alloc_init() which allocates a buffer from the caller's resource pool. Fixes #7285 Signed-off-by: Andrew Boie <andrew.p.boie@intel.com>
2018-05-03 08:44:39 +08:00
kernel: MISRA C: Fixes a few MISRA C issues. MISRA C guideline compliance for various rules. Signed-off-by: Adithya Baglody <adithya.nagaraj.baglody@intel.com>
2018-10-15 14:18:51 +08:00
if ((stack->flags & K_STACK_FLAG_ALLOC) != (u8_t)0) {
kernel: stacks: add k_stack_alloc() init Similar to what has been done with pipes and message queues, user mode can't be trusted to provide a buffer for the kernel to use. Remove k_stack_init() as a syscall and offer k_stack_alloc_init() which allocates a buffer from the caller's resource pool. Fixes #7285 Signed-off-by: Andrew Boie <andrew.p.boie@intel.com>
2018-05-03 08:44:39 +08:00
k_free(stack->base);
stack->base = NULL;
stack->flags &= ~K_STACK_FLAG_ALLOC;
}
}
kernel: convert stack APIs to system calls Signed-off-by: Andrew Boie <andrew.p.boie@intel.com>
2017-09-30 07:42:07 +08:00
void _impl_k_stack_push(struct k_stack *stack, u32_t data)
unified: initial unified kernel implementation Summary of what this includes: initialization: Copy from nano_init.c, with the following changes: - the main thread is the continuation of the init thread, but an idle thread is created as well - _main() initializes threads in groups and starts the EXE group - the ready queues are initialized - the main thread is marked as non-essential once the system init is done - a weak main() symbol is provided if the application does not provide a main() function scheduler: Not an exhaustive list, but basically provide primitives for: - adding/removing a thread to/from a wait queue - adding/removing a thread to/from the ready queue - marking thread as ready - locking/unlocking the scheduler - instead of locking interrupts - getting/setting thread priority - checking what state (coop/preempt) a thread is currenlty running in - rescheduling threads - finding what thread is the next to run - yielding/sleeping/aborting sleep - finding the current thread threads: - Add operationns on threads, such as creating and starting them. standardized handling of kernel object return codes: - Kernel objects now cause _Swap() to return the following values: 0 => operation successful -EAGAIN => operation timed out -Exxxxx => operation failed for another reason - The thread's swap_data field can be used to return any additional information required to complete the operation, such as the actual result of a successful operation. timeouts: - same as nano timeouts, renamed to simply 'timeouts' - the kernel is still tick-based, but objects take timeout values in ms for forward compatibility with a tickless kernel. semaphores: - Port of the nanokernel semaphores, which have the same basic behaviour as the microkernel ones. Semaphore groups are not yet implemented. - These semaphores are enhanced in that they accept an initial count and a count limit. This allows configuring them as binary semaphores, and also provisioning them without having to "give" the semaphore multiple times before using them. mutexes: - Straight port of the microkernel mutexes. An init function is added to allow defining them at runtime. pipes: - straight port timers: - amalgamation of nano and micro timers, with all functionalities intact. events: - re-implementation, using semaphores and workqueues. mailboxes: - straight port message queues: - straight port of microkernel FIFOs memory maps: - straight port workqueues: - Basically, have all APIs follow the k_ naming rule, and use the _timeout subsystem from the unified kernel directory, and not the _nano_timeout one. stacks: - Port of the nanokernel stacks. They can now have multiple threads pending on them and threads can wait with a timeout. LIFOs: - Straight port of the nanokernel LIFOs. FIFOs: - Straight port of the nanokernel FIFOs. Work by: Dmitriy Korovkin <dmitriy.korovkin@windriver.com> Peter Mitsis <peter.mitsis@windriver.com> Allan Stephens <allan.stephens@windriver.com> Benjamin Walsh <benjamin.walsh@windriver.com> Change-Id: Id3cadb3694484ab2ca467889cfb029be3cd3a7d6 Signed-off-by: Benjamin Walsh <benjamin.walsh@windriver.com>
2016-09-03 06:55:39 +08:00
{
struct k_thread *first_pending_thread;
kernel: MISRA C: Fixes a few MISRA C issues. MISRA C guideline compliance for various rules. Signed-off-by: Adithya Baglody <adithya.nagaraj.baglody@intel.com>
2018-10-15 14:18:51 +08:00
u32_t key;
unified: initial unified kernel implementation Summary of what this includes: initialization: Copy from nano_init.c, with the following changes: - the main thread is the continuation of the init thread, but an idle thread is created as well - _main() initializes threads in groups and starts the EXE group - the ready queues are initialized - the main thread is marked as non-essential once the system init is done - a weak main() symbol is provided if the application does not provide a main() function scheduler: Not an exhaustive list, but basically provide primitives for: - adding/removing a thread to/from a wait queue - adding/removing a thread to/from the ready queue - marking thread as ready - locking/unlocking the scheduler - instead of locking interrupts - getting/setting thread priority - checking what state (coop/preempt) a thread is currenlty running in - rescheduling threads - finding what thread is the next to run - yielding/sleeping/aborting sleep - finding the current thread threads: - Add operationns on threads, such as creating and starting them. standardized handling of kernel object return codes: - Kernel objects now cause _Swap() to return the following values: 0 => operation successful -EAGAIN => operation timed out -Exxxxx => operation failed for another reason - The thread's swap_data field can be used to return any additional information required to complete the operation, such as the actual result of a successful operation. timeouts: - same as nano timeouts, renamed to simply 'timeouts' - the kernel is still tick-based, but objects take timeout values in ms for forward compatibility with a tickless kernel. semaphores: - Port of the nanokernel semaphores, which have the same basic behaviour as the microkernel ones. Semaphore groups are not yet implemented. - These semaphores are enhanced in that they accept an initial count and a count limit. This allows configuring them as binary semaphores, and also provisioning them without having to "give" the semaphore multiple times before using them. mutexes: - Straight port of the microkernel mutexes. An init function is added to allow defining them at runtime. pipes: - straight port timers: - amalgamation of nano and micro timers, with all functionalities intact. events: - re-implementation, using semaphores and workqueues. mailboxes: - straight port message queues: - straight port of microkernel FIFOs memory maps: - straight port workqueues: - Basically, have all APIs follow the k_ naming rule, and use the _timeout subsystem from the unified kernel directory, and not the _nano_timeout one. stacks: - Port of the nanokernel stacks. They can now have multiple threads pending on them and threads can wait with a timeout. LIFOs: - Straight port of the nanokernel LIFOs. FIFOs: - Straight port of the nanokernel FIFOs. Work by: Dmitriy Korovkin <dmitriy.korovkin@windriver.com> Peter Mitsis <peter.mitsis@windriver.com> Allan Stephens <allan.stephens@windriver.com> Benjamin Walsh <benjamin.walsh@windriver.com> Change-Id: Id3cadb3694484ab2ca467889cfb029be3cd3a7d6 Signed-off-by: Benjamin Walsh <benjamin.walsh@windriver.com>
2016-09-03 06:55:39 +08:00
__ASSERT(stack->next != stack->top, "stack is full");
key = irq_lock();
first_pending_thread = _unpend_first_thread(&stack->wait_q);
kernel: Explicitly comparing pointer with NULL MISRA-C rule: 14.4 Signed-off-by: Flavio Ceolin <flavio.ceolin@intel.com>
2018-09-21 07:30:45 +08:00
if (first_pending_thread != NULL) {
unified: initial unified kernel implementation Summary of what this includes: initialization: Copy from nano_init.c, with the following changes: - the main thread is the continuation of the init thread, but an idle thread is created as well - _main() initializes threads in groups and starts the EXE group - the ready queues are initialized - the main thread is marked as non-essential once the system init is done - a weak main() symbol is provided if the application does not provide a main() function scheduler: Not an exhaustive list, but basically provide primitives for: - adding/removing a thread to/from a wait queue - adding/removing a thread to/from the ready queue - marking thread as ready - locking/unlocking the scheduler - instead of locking interrupts - getting/setting thread priority - checking what state (coop/preempt) a thread is currenlty running in - rescheduling threads - finding what thread is the next to run - yielding/sleeping/aborting sleep - finding the current thread threads: - Add operationns on threads, such as creating and starting them. standardized handling of kernel object return codes: - Kernel objects now cause _Swap() to return the following values: 0 => operation successful -EAGAIN => operation timed out -Exxxxx => operation failed for another reason - The thread's swap_data field can be used to return any additional information required to complete the operation, such as the actual result of a successful operation. timeouts: - same as nano timeouts, renamed to simply 'timeouts' - the kernel is still tick-based, but objects take timeout values in ms for forward compatibility with a tickless kernel. semaphores: - Port of the nanokernel semaphores, which have the same basic behaviour as the microkernel ones. Semaphore groups are not yet implemented. - These semaphores are enhanced in that they accept an initial count and a count limit. This allows configuring them as binary semaphores, and also provisioning them without having to "give" the semaphore multiple times before using them. mutexes: - Straight port of the microkernel mutexes. An init function is added to allow defining them at runtime. pipes: - straight port timers: - amalgamation of nano and micro timers, with all functionalities intact. events: - re-implementation, using semaphores and workqueues. mailboxes: - straight port message queues: - straight port of microkernel FIFOs memory maps: - straight port workqueues: - Basically, have all APIs follow the k_ naming rule, and use the _timeout subsystem from the unified kernel directory, and not the _nano_timeout one. stacks: - Port of the nanokernel stacks. They can now have multiple threads pending on them and threads can wait with a timeout. LIFOs: - Straight port of the nanokernel LIFOs. FIFOs: - Straight port of the nanokernel FIFOs. Work by: Dmitriy Korovkin <dmitriy.korovkin@windriver.com> Peter Mitsis <peter.mitsis@windriver.com> Allan Stephens <allan.stephens@windriver.com> Benjamin Walsh <benjamin.walsh@windriver.com> Change-Id: Id3cadb3694484ab2ca467889cfb029be3cd3a7d6 Signed-off-by: Benjamin Walsh <benjamin.walsh@windriver.com>
2016-09-03 06:55:39 +08:00
_ready_thread(first_pending_thread);
_set_thread_return_value_with_data(first_pending_thread,
0, (void *)data);
kernel: Clean up _unpend_thread() API Almost everywhere this was called, it was immediately followed by _abort_thread_timeout(), for obvious reasons. The only exceptions were in timeout and k_timer expiration (unifying these two would be another good cleanup), which are peripheral parts of the scheduler and can plausibly use a more "internal" API. So make the common case the default, and expose the old behavior as _unpend_thread_no_timeout(). (Along with identical changes for _unpend_first_thread) Saves code bytes and simplifies scheduler surface area for future synchronization work. Signed-off-by: Andy Ross <andrew.j.ross@intel.com>
2018-04-03 09:24:58 +08:00
_reschedule(key);
kernel: Scheduler refactoring: use _reschedule_*() always There was a somewhat promiscuous pattern in the kernel where IPC mechanisms would do something that might effect the current thread choice, then check _must_switch_threads() (or occasionally __must_switch_threads -- don't ask, the distinction is being replaced by real English words), sometimes _is_in_isr() (but not always, even in contexts where that looks like it would be a mistake), and then call _Swap() if everything is OK, otherwise releasing the irq_lock(). Sometimes this was done directly, sometimes via the inverted test, sometimes (poll, heh) by doing the test when the thread state was modified and then needlessly passing the result up the call stack to the point of the _Swap(). And some places were just calling _reschedule_threads(), which did all this already. Unify all this madness. The old _reschedule_threads() function has split into two variants: _reschedule_yield() and _reschedule_noyield(). The latter is the "normal" one that respects the cooperative priority of the current thread (i.e. it won't switch out even if there is a higher priority thread ready -- the current thread has to pend itself first), the former is used in the handful of places where code was doing a swap unconditionally, just to preserve precise behavior across the refactor. I'm not at all convinced it should exist... Signed-off-by: Andy Ross <andrew.j.ross@intel.com>
2018-03-27 01:54:40 +08:00
return;
unified: initial unified kernel implementation Summary of what this includes: initialization: Copy from nano_init.c, with the following changes: - the main thread is the continuation of the init thread, but an idle thread is created as well - _main() initializes threads in groups and starts the EXE group - the ready queues are initialized - the main thread is marked as non-essential once the system init is done - a weak main() symbol is provided if the application does not provide a main() function scheduler: Not an exhaustive list, but basically provide primitives for: - adding/removing a thread to/from a wait queue - adding/removing a thread to/from the ready queue - marking thread as ready - locking/unlocking the scheduler - instead of locking interrupts - getting/setting thread priority - checking what state (coop/preempt) a thread is currenlty running in - rescheduling threads - finding what thread is the next to run - yielding/sleeping/aborting sleep - finding the current thread threads: - Add operationns on threads, such as creating and starting them. standardized handling of kernel object return codes: - Kernel objects now cause _Swap() to return the following values: 0 => operation successful -EAGAIN => operation timed out -Exxxxx => operation failed for another reason - The thread's swap_data field can be used to return any additional information required to complete the operation, such as the actual result of a successful operation. timeouts: - same as nano timeouts, renamed to simply 'timeouts' - the kernel is still tick-based, but objects take timeout values in ms for forward compatibility with a tickless kernel. semaphores: - Port of the nanokernel semaphores, which have the same basic behaviour as the microkernel ones. Semaphore groups are not yet implemented. - These semaphores are enhanced in that they accept an initial count and a count limit. This allows configuring them as binary semaphores, and also provisioning them without having to "give" the semaphore multiple times before using them. mutexes: - Straight port of the microkernel mutexes. An init function is added to allow defining them at runtime. pipes: - straight port timers: - amalgamation of nano and micro timers, with all functionalities intact. events: - re-implementation, using semaphores and workqueues. mailboxes: - straight port message queues: - straight port of microkernel FIFOs memory maps: - straight port workqueues: - Basically, have all APIs follow the k_ naming rule, and use the _timeout subsystem from the unified kernel directory, and not the _nano_timeout one. stacks: - Port of the nanokernel stacks. They can now have multiple threads pending on them and threads can wait with a timeout. LIFOs: - Straight port of the nanokernel LIFOs. FIFOs: - Straight port of the nanokernel FIFOs. Work by: Dmitriy Korovkin <dmitriy.korovkin@windriver.com> Peter Mitsis <peter.mitsis@windriver.com> Allan Stephens <allan.stephens@windriver.com> Benjamin Walsh <benjamin.walsh@windriver.com> Change-Id: Id3cadb3694484ab2ca467889cfb029be3cd3a7d6 Signed-off-by: Benjamin Walsh <benjamin.walsh@windriver.com>
2016-09-03 06:55:39 +08:00
} else {
*(stack->next) = data;
stack->next++;
kernel: Scheduler refactoring: use _reschedule_*() always There was a somewhat promiscuous pattern in the kernel where IPC mechanisms would do something that might effect the current thread choice, then check _must_switch_threads() (or occasionally __must_switch_threads -- don't ask, the distinction is being replaced by real English words), sometimes _is_in_isr() (but not always, even in contexts where that looks like it would be a mistake), and then call _Swap() if everything is OK, otherwise releasing the irq_lock(). Sometimes this was done directly, sometimes via the inverted test, sometimes (poll, heh) by doing the test when the thread state was modified and then needlessly passing the result up the call stack to the point of the _Swap(). And some places were just calling _reschedule_threads(), which did all this already. Unify all this madness. The old _reschedule_threads() function has split into two variants: _reschedule_yield() and _reschedule_noyield(). The latter is the "normal" one that respects the cooperative priority of the current thread (i.e. it won't switch out even if there is a higher priority thread ready -- the current thread has to pend itself first), the former is used in the handful of places where code was doing a swap unconditionally, just to preserve precise behavior across the refactor. I'm not at all convinced it should exist... Signed-off-by: Andy Ross <andrew.j.ross@intel.com>
2018-03-27 01:54:40 +08:00
irq_unlock(key);
unified: initial unified kernel implementation Summary of what this includes: initialization: Copy from nano_init.c, with the following changes: - the main thread is the continuation of the init thread, but an idle thread is created as well - _main() initializes threads in groups and starts the EXE group - the ready queues are initialized - the main thread is marked as non-essential once the system init is done - a weak main() symbol is provided if the application does not provide a main() function scheduler: Not an exhaustive list, but basically provide primitives for: - adding/removing a thread to/from a wait queue - adding/removing a thread to/from the ready queue - marking thread as ready - locking/unlocking the scheduler - instead of locking interrupts - getting/setting thread priority - checking what state (coop/preempt) a thread is currenlty running in - rescheduling threads - finding what thread is the next to run - yielding/sleeping/aborting sleep - finding the current thread threads: - Add operationns on threads, such as creating and starting them. standardized handling of kernel object return codes: - Kernel objects now cause _Swap() to return the following values: 0 => operation successful -EAGAIN => operation timed out -Exxxxx => operation failed for another reason - The thread's swap_data field can be used to return any additional information required to complete the operation, such as the actual result of a successful operation. timeouts: - same as nano timeouts, renamed to simply 'timeouts' - the kernel is still tick-based, but objects take timeout values in ms for forward compatibility with a tickless kernel. semaphores: - Port of the nanokernel semaphores, which have the same basic behaviour as the microkernel ones. Semaphore groups are not yet implemented. - These semaphores are enhanced in that they accept an initial count and a count limit. This allows configuring them as binary semaphores, and also provisioning them without having to "give" the semaphore multiple times before using them. mutexes: - Straight port of the microkernel mutexes. An init function is added to allow defining them at runtime. pipes: - straight port timers: - amalgamation of nano and micro timers, with all functionalities intact. events: - re-implementation, using semaphores and workqueues. mailboxes: - straight port message queues: - straight port of microkernel FIFOs memory maps: - straight port workqueues: - Basically, have all APIs follow the k_ naming rule, and use the _timeout subsystem from the unified kernel directory, and not the _nano_timeout one. stacks: - Port of the nanokernel stacks. They can now have multiple threads pending on them and threads can wait with a timeout. LIFOs: - Straight port of the nanokernel LIFOs. FIFOs: - Straight port of the nanokernel FIFOs. Work by: Dmitriy Korovkin <dmitriy.korovkin@windriver.com> Peter Mitsis <peter.mitsis@windriver.com> Allan Stephens <allan.stephens@windriver.com> Benjamin Walsh <benjamin.walsh@windriver.com> Change-Id: Id3cadb3694484ab2ca467889cfb029be3cd3a7d6 Signed-off-by: Benjamin Walsh <benjamin.walsh@windriver.com>
2016-09-03 06:55:39 +08:00
}
}
kernel: convert stack APIs to system calls Signed-off-by: Andrew Boie <andrew.p.boie@intel.com>
2017-09-30 07:42:07 +08:00
#ifdef CONFIG_USERSPACE
syscalls: remove policy from handler checks The various macros to do checks in system call handlers all implictly would generate a kernel oops if a check failed. This is undesirable for a few reasons: * System call handlers that acquire resources in the handler have no good recourse for cleanup if a check fails. * In some cases we may want to propagate a return value back to the caller instead of just killing the calling thread, even though the base API doesn't do these checks. These macros now all return a value, if nonzero is returned the check failed. K_OOPS() now wraps these calls to generate a kernel oops. At the moment, the policy for all APIs has not changed. They still all oops upon a failed check/ The macros now use the Z_ notation for private APIs. Signed-off-by: Andrew Boie <andrew.p.boie@intel.com>
2018-05-05 06:57:57 +08:00
Z_SYSCALL_HANDLER(k_stack_push, stack_p, data)
kernel: convert stack APIs to system calls Signed-off-by: Andrew Boie <andrew.p.boie@intel.com>
2017-09-30 07:42:07 +08:00
{
struct k_stack *stack = (struct k_stack *)stack_p;
syscalls: remove policy from handler checks The various macros to do checks in system call handlers all implictly would generate a kernel oops if a check failed. This is undesirable for a few reasons: * System call handlers that acquire resources in the handler have no good recourse for cleanup if a check fails. * In some cases we may want to propagate a return value back to the caller instead of just killing the calling thread, even though the base API doesn't do these checks. These macros now all return a value, if nonzero is returned the check failed. K_OOPS() now wraps these calls to generate a kernel oops. At the moment, the policy for all APIs has not changed. They still all oops upon a failed check/ The macros now use the Z_ notation for private APIs. Signed-off-by: Andrew Boie <andrew.p.boie@intel.com>
2018-05-05 06:57:57 +08:00
Z_OOPS(Z_SYSCALL_OBJ(stack, K_OBJ_STACK));
Z_OOPS(Z_SYSCALL_VERIFY_MSG(stack->next != stack->top,
"stack is full"));
kernel: convert stack APIs to system calls Signed-off-by: Andrew Boie <andrew.p.boie@intel.com>
2017-09-30 07:42:07 +08:00
_impl_k_stack_push(stack, data);
return 0;
}
#endif
int _impl_k_stack_pop(struct k_stack *stack, u32_t *data, s32_t timeout)
unified: initial unified kernel implementation Summary of what this includes: initialization: Copy from nano_init.c, with the following changes: - the main thread is the continuation of the init thread, but an idle thread is created as well - _main() initializes threads in groups and starts the EXE group - the ready queues are initialized - the main thread is marked as non-essential once the system init is done - a weak main() symbol is provided if the application does not provide a main() function scheduler: Not an exhaustive list, but basically provide primitives for: - adding/removing a thread to/from a wait queue - adding/removing a thread to/from the ready queue - marking thread as ready - locking/unlocking the scheduler - instead of locking interrupts - getting/setting thread priority - checking what state (coop/preempt) a thread is currenlty running in - rescheduling threads - finding what thread is the next to run - yielding/sleeping/aborting sleep - finding the current thread threads: - Add operationns on threads, such as creating and starting them. standardized handling of kernel object return codes: - Kernel objects now cause _Swap() to return the following values: 0 => operation successful -EAGAIN => operation timed out -Exxxxx => operation failed for another reason - The thread's swap_data field can be used to return any additional information required to complete the operation, such as the actual result of a successful operation. timeouts: - same as nano timeouts, renamed to simply 'timeouts' - the kernel is still tick-based, but objects take timeout values in ms for forward compatibility with a tickless kernel. semaphores: - Port of the nanokernel semaphores, which have the same basic behaviour as the microkernel ones. Semaphore groups are not yet implemented. - These semaphores are enhanced in that they accept an initial count and a count limit. This allows configuring them as binary semaphores, and also provisioning them without having to "give" the semaphore multiple times before using them. mutexes: - Straight port of the microkernel mutexes. An init function is added to allow defining them at runtime. pipes: - straight port timers: - amalgamation of nano and micro timers, with all functionalities intact. events: - re-implementation, using semaphores and workqueues. mailboxes: - straight port message queues: - straight port of microkernel FIFOs memory maps: - straight port workqueues: - Basically, have all APIs follow the k_ naming rule, and use the _timeout subsystem from the unified kernel directory, and not the _nano_timeout one. stacks: - Port of the nanokernel stacks. They can now have multiple threads pending on them and threads can wait with a timeout. LIFOs: - Straight port of the nanokernel LIFOs. FIFOs: - Straight port of the nanokernel FIFOs. Work by: Dmitriy Korovkin <dmitriy.korovkin@windriver.com> Peter Mitsis <peter.mitsis@windriver.com> Allan Stephens <allan.stephens@windriver.com> Benjamin Walsh <benjamin.walsh@windriver.com> Change-Id: Id3cadb3694484ab2ca467889cfb029be3cd3a7d6 Signed-off-by: Benjamin Walsh <benjamin.walsh@windriver.com>
2016-09-03 06:55:39 +08:00
{
kernel: MISRA C: Fixes a few MISRA C issues. MISRA C guideline compliance for various rules. Signed-off-by: Adithya Baglody <adithya.nagaraj.baglody@intel.com>
2018-10-15 14:18:51 +08:00
u32_t key;
unified: initial unified kernel implementation Summary of what this includes: initialization: Copy from nano_init.c, with the following changes: - the main thread is the continuation of the init thread, but an idle thread is created as well - _main() initializes threads in groups and starts the EXE group - the ready queues are initialized - the main thread is marked as non-essential once the system init is done - a weak main() symbol is provided if the application does not provide a main() function scheduler: Not an exhaustive list, but basically provide primitives for: - adding/removing a thread to/from a wait queue - adding/removing a thread to/from the ready queue - marking thread as ready - locking/unlocking the scheduler - instead of locking interrupts - getting/setting thread priority - checking what state (coop/preempt) a thread is currenlty running in - rescheduling threads - finding what thread is the next to run - yielding/sleeping/aborting sleep - finding the current thread threads: - Add operationns on threads, such as creating and starting them. standardized handling of kernel object return codes: - Kernel objects now cause _Swap() to return the following values: 0 => operation successful -EAGAIN => operation timed out -Exxxxx => operation failed for another reason - The thread's swap_data field can be used to return any additional information required to complete the operation, such as the actual result of a successful operation. timeouts: - same as nano timeouts, renamed to simply 'timeouts' - the kernel is still tick-based, but objects take timeout values in ms for forward compatibility with a tickless kernel. semaphores: - Port of the nanokernel semaphores, which have the same basic behaviour as the microkernel ones. Semaphore groups are not yet implemented. - These semaphores are enhanced in that they accept an initial count and a count limit. This allows configuring them as binary semaphores, and also provisioning them without having to "give" the semaphore multiple times before using them. mutexes: - Straight port of the microkernel mutexes. An init function is added to allow defining them at runtime. pipes: - straight port timers: - amalgamation of nano and micro timers, with all functionalities intact. events: - re-implementation, using semaphores and workqueues. mailboxes: - straight port message queues: - straight port of microkernel FIFOs memory maps: - straight port workqueues: - Basically, have all APIs follow the k_ naming rule, and use the _timeout subsystem from the unified kernel directory, and not the _nano_timeout one. stacks: - Port of the nanokernel stacks. They can now have multiple threads pending on them and threads can wait with a timeout. LIFOs: - Straight port of the nanokernel LIFOs. FIFOs: - Straight port of the nanokernel FIFOs. Work by: Dmitriy Korovkin <dmitriy.korovkin@windriver.com> Peter Mitsis <peter.mitsis@windriver.com> Allan Stephens <allan.stephens@windriver.com> Benjamin Walsh <benjamin.walsh@windriver.com> Change-Id: Id3cadb3694484ab2ca467889cfb029be3cd3a7d6 Signed-off-by: Benjamin Walsh <benjamin.walsh@windriver.com>
2016-09-03 06:55:39 +08:00
int result;
key = irq_lock();
if (likely(stack->next > stack->base)) {
stack->next--;
*data = *(stack->next);
irq_unlock(key);
return 0;
}
if (timeout == K_NO_WAIT) {
irq_unlock(key);
return -EBUSY;
}
kernel: Refactor, unifying _pend_current_thread() + _Swap() idiom Everywhere the current thread is pended, the code is going to have to do a _Swap() soon afterward, yet the scheduler API exposed these as separate steps. Unify this pattern everywhere it appears, which saves some code bytes and gets _Swap() out of the general scheduler API at zero cost. Signed-off-by: Andy Ross <andrew.j.ross@intel.com>
2018-03-27 02:58:10 +08:00
result = _pend_current_thread(key, &stack->wait_q, timeout);
kernel: stack: Making if's body a compound statement MISRA-C rule 15.6 Signed-off-by: Flavio Ceolin <flavio.ceolin@intel.com>
2018-11-02 11:50:25 +08:00
if (result == -EAGAIN) {
kernel: stack: Fix k_stack_pop api _pend_current_thread can return any arbitrary value set by _set_thred_return_value(), it happens that most cases set 0. This function can not rely on this behavior otherwise it may return an invalid value and/or not set data's value. Signed-off-by: Flavio Ceolin <flavio.ceolin@intel.com>
2018-09-14 02:43:59 +08:00
return -EAGAIN;
kernel: stack: Making if's body a compound statement MISRA-C rule 15.6 Signed-off-by: Flavio Ceolin <flavio.ceolin@intel.com>
2018-11-02 11:50:25 +08:00
}
unified: initial unified kernel implementation Summary of what this includes: initialization: Copy from nano_init.c, with the following changes: - the main thread is the continuation of the init thread, but an idle thread is created as well - _main() initializes threads in groups and starts the EXE group - the ready queues are initialized - the main thread is marked as non-essential once the system init is done - a weak main() symbol is provided if the application does not provide a main() function scheduler: Not an exhaustive list, but basically provide primitives for: - adding/removing a thread to/from a wait queue - adding/removing a thread to/from the ready queue - marking thread as ready - locking/unlocking the scheduler - instead of locking interrupts - getting/setting thread priority - checking what state (coop/preempt) a thread is currenlty running in - rescheduling threads - finding what thread is the next to run - yielding/sleeping/aborting sleep - finding the current thread threads: - Add operationns on threads, such as creating and starting them. standardized handling of kernel object return codes: - Kernel objects now cause _Swap() to return the following values: 0 => operation successful -EAGAIN => operation timed out -Exxxxx => operation failed for another reason - The thread's swap_data field can be used to return any additional information required to complete the operation, such as the actual result of a successful operation. timeouts: - same as nano timeouts, renamed to simply 'timeouts' - the kernel is still tick-based, but objects take timeout values in ms for forward compatibility with a tickless kernel. semaphores: - Port of the nanokernel semaphores, which have the same basic behaviour as the microkernel ones. Semaphore groups are not yet implemented. - These semaphores are enhanced in that they accept an initial count and a count limit. This allows configuring them as binary semaphores, and also provisioning them without having to "give" the semaphore multiple times before using them. mutexes: - Straight port of the microkernel mutexes. An init function is added to allow defining them at runtime. pipes: - straight port timers: - amalgamation of nano and micro timers, with all functionalities intact. events: - re-implementation, using semaphores and workqueues. mailboxes: - straight port message queues: - straight port of microkernel FIFOs memory maps: - straight port workqueues: - Basically, have all APIs follow the k_ naming rule, and use the _timeout subsystem from the unified kernel directory, and not the _nano_timeout one. stacks: - Port of the nanokernel stacks. They can now have multiple threads pending on them and threads can wait with a timeout. LIFOs: - Straight port of the nanokernel LIFOs. FIFOs: - Straight port of the nanokernel FIFOs. Work by: Dmitriy Korovkin <dmitriy.korovkin@windriver.com> Peter Mitsis <peter.mitsis@windriver.com> Allan Stephens <allan.stephens@windriver.com> Benjamin Walsh <benjamin.walsh@windriver.com> Change-Id: Id3cadb3694484ab2ca467889cfb029be3cd3a7d6 Signed-off-by: Benjamin Walsh <benjamin.walsh@windriver.com>
2016-09-03 06:55:39 +08:00
kernel: stack: Fix k_stack_pop api _pend_current_thread can return any arbitrary value set by _set_thred_return_value(), it happens that most cases set 0. This function can not rely on this behavior otherwise it may return an invalid value and/or not set data's value. Signed-off-by: Flavio Ceolin <flavio.ceolin@intel.com>
2018-09-14 02:43:59 +08:00
*data = (u32_t)_current->base.swap_data;
return 0;
unified: initial unified kernel implementation Summary of what this includes: initialization: Copy from nano_init.c, with the following changes: - the main thread is the continuation of the init thread, but an idle thread is created as well - _main() initializes threads in groups and starts the EXE group - the ready queues are initialized - the main thread is marked as non-essential once the system init is done - a weak main() symbol is provided if the application does not provide a main() function scheduler: Not an exhaustive list, but basically provide primitives for: - adding/removing a thread to/from a wait queue - adding/removing a thread to/from the ready queue - marking thread as ready - locking/unlocking the scheduler - instead of locking interrupts - getting/setting thread priority - checking what state (coop/preempt) a thread is currenlty running in - rescheduling threads - finding what thread is the next to run - yielding/sleeping/aborting sleep - finding the current thread threads: - Add operationns on threads, such as creating and starting them. standardized handling of kernel object return codes: - Kernel objects now cause _Swap() to return the following values: 0 => operation successful -EAGAIN => operation timed out -Exxxxx => operation failed for another reason - The thread's swap_data field can be used to return any additional information required to complete the operation, such as the actual result of a successful operation. timeouts: - same as nano timeouts, renamed to simply 'timeouts' - the kernel is still tick-based, but objects take timeout values in ms for forward compatibility with a tickless kernel. semaphores: - Port of the nanokernel semaphores, which have the same basic behaviour as the microkernel ones. Semaphore groups are not yet implemented. - These semaphores are enhanced in that they accept an initial count and a count limit. This allows configuring them as binary semaphores, and also provisioning them without having to "give" the semaphore multiple times before using them. mutexes: - Straight port of the microkernel mutexes. An init function is added to allow defining them at runtime. pipes: - straight port timers: - amalgamation of nano and micro timers, with all functionalities intact. events: - re-implementation, using semaphores and workqueues. mailboxes: - straight port message queues: - straight port of microkernel FIFOs memory maps: - straight port workqueues: - Basically, have all APIs follow the k_ naming rule, and use the _timeout subsystem from the unified kernel directory, and not the _nano_timeout one. stacks: - Port of the nanokernel stacks. They can now have multiple threads pending on them and threads can wait with a timeout. LIFOs: - Straight port of the nanokernel LIFOs. FIFOs: - Straight port of the nanokernel FIFOs. Work by: Dmitriy Korovkin <dmitriy.korovkin@windriver.com> Peter Mitsis <peter.mitsis@windriver.com> Allan Stephens <allan.stephens@windriver.com> Benjamin Walsh <benjamin.walsh@windriver.com> Change-Id: Id3cadb3694484ab2ca467889cfb029be3cd3a7d6 Signed-off-by: Benjamin Walsh <benjamin.walsh@windriver.com>
2016-09-03 06:55:39 +08:00
}
kernel: convert stack APIs to system calls Signed-off-by: Andrew Boie <andrew.p.boie@intel.com>
2017-09-30 07:42:07 +08:00
#ifdef CONFIG_USERSPACE
syscalls: remove policy from handler checks The various macros to do checks in system call handlers all implictly would generate a kernel oops if a check failed. This is undesirable for a few reasons: * System call handlers that acquire resources in the handler have no good recourse for cleanup if a check fails. * In some cases we may want to propagate a return value back to the caller instead of just killing the calling thread, even though the base API doesn't do these checks. These macros now all return a value, if nonzero is returned the check failed. K_OOPS() now wraps these calls to generate a kernel oops. At the moment, the policy for all APIs has not changed. They still all oops upon a failed check/ The macros now use the Z_ notation for private APIs. Signed-off-by: Andrew Boie <andrew.p.boie@intel.com>
2018-05-05 06:57:57 +08:00
Z_SYSCALL_HANDLER(k_stack_pop, stack, data, timeout)
kernel: convert stack APIs to system calls Signed-off-by: Andrew Boie <andrew.p.boie@intel.com>
2017-09-30 07:42:07 +08:00
{
syscalls: remove policy from handler checks The various macros to do checks in system call handlers all implictly would generate a kernel oops if a check failed. This is undesirable for a few reasons: * System call handlers that acquire resources in the handler have no good recourse for cleanup if a check fails. * In some cases we may want to propagate a return value back to the caller instead of just killing the calling thread, even though the base API doesn't do these checks. These macros now all return a value, if nonzero is returned the check failed. K_OOPS() now wraps these calls to generate a kernel oops. At the moment, the policy for all APIs has not changed. They still all oops upon a failed check/ The macros now use the Z_ notation for private APIs. Signed-off-by: Andrew Boie <andrew.p.boie@intel.com>
2018-05-05 06:57:57 +08:00
Z_OOPS(Z_SYSCALL_OBJ(stack, K_OBJ_STACK));
Z_OOPS(Z_SYSCALL_MEMORY_WRITE(data, sizeof(u32_t)));
kernel: convert stack APIs to system calls Signed-off-by: Andrew Boie <andrew.p.boie@intel.com>
2017-09-30 07:42:07 +08:00
return _impl_k_stack_pop((struct k_stack *)stack, (u32_t *)data,
timeout);
}
#endif