genode/base-nova/include/cpu_session/client.h

/*
 * \brief  Client-side cpu session NOVA extension
 * \author Alexander Boettcher
 * \date   2012-07-27
 */

/*
 * Copyright (C) 2012-2013 Genode Labs GmbH
 *
 * This file is part of the Genode OS framework, which is distributed
 * under the terms of the GNU General Public License version 2.
 */

#ifndef _INCLUDE__CPU_SESSION__CLIENT_H_
#define _INCLUDE__CPU_SESSION__CLIENT_H_

#include <base/rpc_client.h>
#include <base/thread.h>

#include <cpu_session/capability.h>

#include <nova_cpu_session/nova_cpu_session.h>

namespace Genode {

	struct Cpu_session_client : Rpc_client<Nova_cpu_session>
	{
		explicit Cpu_session_client(Cpu_session_capability session)
		: Rpc_client<Nova_cpu_session>(static_cap_cast<Nova_cpu_session>(session)) { }

		Thread_capability create_thread(Name const &name, addr_t utcb = 0) {
			return call<Rpc_create_thread>(name, utcb); }

		Ram_dataspace_capability utcb(Thread_capability thread) {
			return call<Rpc_utcb>(thread); }

		void kill_thread(Thread_capability thread) {
			call<Rpc_kill_thread>(thread); }

		int set_pager(Thread_capability thread, Pager_capability pager) {
			return call<Rpc_set_pager>(thread, pager); }

		int start(Thread_capability thread, addr_t ip, addr_t sp) {
			return call<Rpc_start>(thread, ip, sp); }

		void pause(Thread_capability thread)
		{
			Native_capability block = call<Rpc_pause_sync>(thread);
			if (!block.valid())
				return;

			Nova::sm_ctrl(block.local_name(), Nova::SEMAPHORE_DOWN);

			Nova::revoke(Nova::Obj_crd(block.local_name(), 0));
			cap_selector_allocator()->free(block.local_name(), 0);
		}

		void resume(Thread_capability thread) {
			call<Rpc_resume>(thread); }

		void cancel_blocking(Thread_capability thread) {
			call<Rpc_cancel_blocking>(thread); }

		Thread_state state(Thread_capability thread) {
			return call<Rpc_get_state>(thread); }

		void state(Thread_capability thread, Thread_state const &state) {
			call<Rpc_set_state>(thread, state); }

		void exception_handler(Thread_capability thread, Signal_context_capability handler) {
			call<Rpc_exception_handler>(thread, handler); }

		void single_step(Thread_capability thread, bool enable) {
			call<Rpc_single_step>(thread, enable); }

		Native_capability native_cap(Thread_capability cap) {
			return call<Rpc_native_cap>(cap); }

		Affinity::Space affinity_space() const {
			return call<Rpc_affinity_space>(); }

		void affinity(Thread_capability thread, Affinity::Location location) {
			call<Rpc_affinity>(thread, location); }

		private:

			Native_capability pause_sync(Thread_capability target) {
				return Native_capability::invalid_cap(); }
	};
}

#endif /* _INCLUDE__CPU_SESSION__CLIENT_H_ */
NOVA: extend cpu_session for base-nova 2012-08-08 17:12:10 +02:00			`/*`
			`* \brief Client-side cpu session NOVA extension`
			`* \author Alexander Boettcher`
			`* \date 2012-07-27`
			`*/`

			`/*`
Update copyright headers to 2013 2013-01-10 21:44:47 +01:00			`* Copyright (C) 2012-2013 Genode Labs GmbH`
NOVA: extend cpu_session for base-nova 2012-08-08 17:12:10 +02:00			`*`
			`* This file is part of the Genode OS framework, which is distributed`
			`* under the terms of the GNU General Public License version 2.`
			`*/`

NOVA: extend cpu_session with synchronous pause The kernel provides a "recall" feature issued on threads to force a thread into an exception. In the exception the current state of the thread can be obtained and its execution can be halted/paused. However, the recall exception is only delivered when the next time the thread would leave the kernel. That means the delivery is asynchronous and Genode has to wait until the exception triggered. Waiting for the exception can either be done in the cpu_session service or outside the service in the protection domain of the caller. It turned out that waiting inside the cpu_service is prone to deadlock the system. The cpu_session interface is one of many session interfaces handled by the same thread inside Core. Deadlock situation: * The caller (thread_c) to pause some thread_p manages to establish the call to the cpu_session thread_s of Core but get be interrupted before issuing the actual pause (recall) command. * Now the - to be recalled thread_p - is scheduled and tries to invoke another service of Core, like making log output. * Since the Core thread_s is handling the session request of thread_c, the kernel uses the timeslice of thread_p to help to finish the request handled by thread_s. * Thread_s issues the actual pause/recall on thread_p and blocks inside Core to wait for the recall exception to be issued. * thread_p will leave not the kernel before finishing it actual IPC with thread_s which is blocked waiting for thread_p. That is the reason why the waiting/blocking for the recall exception taking place must be done on NOVA in the context of the caller (thread_1). Introduce a pause_sync call to the cpu_session which returns a semaphore capability to the caller. The caller blocks on the semaphore and is woken up when the pager of thread_p receives the recall exception with the state of thread_p. 2012-08-24 09:29:54 +02:00			`#ifndef _INCLUDE__CPU_SESSION__CLIENT_H_`
			`#define _INCLUDE__CPU_SESSION__CLIENT_H_`

			`#include <base/rpc_client.h>`
			`#include <base/thread.h>`

			`#include <cpu_session/capability.h>`
NOVA: extend cpu_session for base-nova 2012-08-08 17:12:10 +02:00
			`#include <nova_cpu_session/nova_cpu_session.h>`

			`namespace Genode {`

NOVA: extend cpu_session with synchronous pause The kernel provides a "recall" feature issued on threads to force a thread into an exception. In the exception the current state of the thread can be obtained and its execution can be halted/paused. However, the recall exception is only delivered when the next time the thread would leave the kernel. That means the delivery is asynchronous and Genode has to wait until the exception triggered. Waiting for the exception can either be done in the cpu_session service or outside the service in the protection domain of the caller. It turned out that waiting inside the cpu_service is prone to deadlock the system. The cpu_session interface is one of many session interfaces handled by the same thread inside Core. Deadlock situation: * The caller (thread_c) to pause some thread_p manages to establish the call to the cpu_session thread_s of Core but get be interrupted before issuing the actual pause (recall) command. * Now the - to be recalled thread_p - is scheduled and tries to invoke another service of Core, like making log output. * Since the Core thread_s is handling the session request of thread_c, the kernel uses the timeslice of thread_p to help to finish the request handled by thread_s. * Thread_s issues the actual pause/recall on thread_p and blocks inside Core to wait for the recall exception to be issued. * thread_p will leave not the kernel before finishing it actual IPC with thread_s which is blocked waiting for thread_p. That is the reason why the waiting/blocking for the recall exception taking place must be done on NOVA in the context of the caller (thread_1). Introduce a pause_sync call to the cpu_session which returns a semaphore capability to the caller. The caller blocks on the semaphore and is woken up when the pager of thread_p receives the recall exception with the state of thread_p. 2012-08-24 09:29:54 +02:00			`struct Cpu_session_client : Rpc_client<Nova_cpu_session>`
NOVA: extend cpu_session for base-nova 2012-08-08 17:12:10 +02:00			`{`
NOVA: extend cpu_session with synchronous pause The kernel provides a "recall" feature issued on threads to force a thread into an exception. In the exception the current state of the thread can be obtained and its execution can be halted/paused. However, the recall exception is only delivered when the next time the thread would leave the kernel. That means the delivery is asynchronous and Genode has to wait until the exception triggered. Waiting for the exception can either be done in the cpu_session service or outside the service in the protection domain of the caller. It turned out that waiting inside the cpu_service is prone to deadlock the system. The cpu_session interface is one of many session interfaces handled by the same thread inside Core. Deadlock situation: * The caller (thread_c) to pause some thread_p manages to establish the call to the cpu_session thread_s of Core but get be interrupted before issuing the actual pause (recall) command. * Now the - to be recalled thread_p - is scheduled and tries to invoke another service of Core, like making log output. * Since the Core thread_s is handling the session request of thread_c, the kernel uses the timeslice of thread_p to help to finish the request handled by thread_s. * Thread_s issues the actual pause/recall on thread_p and blocks inside Core to wait for the recall exception to be issued. * thread_p will leave not the kernel before finishing it actual IPC with thread_s which is blocked waiting for thread_p. That is the reason why the waiting/blocking for the recall exception taking place must be done on NOVA in the context of the caller (thread_1). Introduce a pause_sync call to the cpu_session which returns a semaphore capability to the caller. The caller blocks on the semaphore and is woken up when the pager of thread_p receives the recall exception with the state of thread_p. 2012-08-24 09:29:54 +02:00			`explicit Cpu_session_client(Cpu_session_capability session)`
NOVA: extend cpu_session for base-nova 2012-08-08 17:12:10 +02:00			`: Rpc_client<Nova_cpu_session>(static_cap_cast<Nova_cpu_session>(session)) { }`

			`Thread_capability create_thread(Name const &name, addr_t utcb = 0) {`
			`return call<Rpc_create_thread>(name, utcb); }`

			`Ram_dataspace_capability utcb(Thread_capability thread) {`
			`return call<Rpc_utcb>(thread); }`

			`void kill_thread(Thread_capability thread) {`
			`call<Rpc_kill_thread>(thread); }`

			`int set_pager(Thread_capability thread, Pager_capability pager) {`
			`return call<Rpc_set_pager>(thread, pager); }`

			`int start(Thread_capability thread, addr_t ip, addr_t sp) {`
			`return call<Rpc_start>(thread, ip, sp); }`

NOVA: extend cpu_session with synchronous pause The kernel provides a "recall" feature issued on threads to force a thread into an exception. In the exception the current state of the thread can be obtained and its execution can be halted/paused. However, the recall exception is only delivered when the next time the thread would leave the kernel. That means the delivery is asynchronous and Genode has to wait until the exception triggered. Waiting for the exception can either be done in the cpu_session service or outside the service in the protection domain of the caller. It turned out that waiting inside the cpu_service is prone to deadlock the system. The cpu_session interface is one of many session interfaces handled by the same thread inside Core. Deadlock situation: * The caller (thread_c) to pause some thread_p manages to establish the call to the cpu_session thread_s of Core but get be interrupted before issuing the actual pause (recall) command. * Now the - to be recalled thread_p - is scheduled and tries to invoke another service of Core, like making log output. * Since the Core thread_s is handling the session request of thread_c, the kernel uses the timeslice of thread_p to help to finish the request handled by thread_s. * Thread_s issues the actual pause/recall on thread_p and blocks inside Core to wait for the recall exception to be issued. * thread_p will leave not the kernel before finishing it actual IPC with thread_s which is blocked waiting for thread_p. That is the reason why the waiting/blocking for the recall exception taking place must be done on NOVA in the context of the caller (thread_1). Introduce a pause_sync call to the cpu_session which returns a semaphore capability to the caller. The caller blocks on the semaphore and is woken up when the pager of thread_p receives the recall exception with the state of thread_p. 2012-08-24 09:29:54 +02:00			`void pause(Thread_capability thread)`
			`{`
			`Native_capability block = call<Rpc_pause_sync>(thread);`
			`if (!block.valid())`
			`return;`

			`Nova::sm_ctrl(block.local_name(), Nova::SEMAPHORE_DOWN);`

			`Nova::revoke(Nova::Obj_crd(block.local_name(), 0));`
			`cap_selector_allocator()->free(block.local_name(), 0);`
			`}`
NOVA: extend cpu_session for base-nova 2012-08-08 17:12:10 +02:00
			`void resume(Thread_capability thread) {`
			`call<Rpc_resume>(thread); }`

			`void cancel_blocking(Thread_capability thread) {`
			`call<Rpc_cancel_blocking>(thread); }`

cpu_session: Access thread state by value 2012-11-12 17:48:18 +01:00			`Thread_state state(Thread_capability thread) {`
			`return call<Rpc_get_state>(thread); }`

			`void state(Thread_capability thread, Thread_state const &state) {`
			`call<Rpc_set_state>(thread, state); }`
NOVA: extend cpu_session for base-nova 2012-08-08 17:12:10 +02:00
			`void exception_handler(Thread_capability thread, Signal_context_capability handler) {`
			`call<Rpc_exception_handler>(thread, handler); }`

			`void single_step(Thread_capability thread, bool enable) {`
			`call<Rpc_single_step>(thread, enable); }`

			`Native_capability native_cap(Thread_capability cap) {`
			`return call<Rpc_native_cap>(cap); }`

Express affinities via Cartesian coordinates This patch introduces new types for expressing CPU affinities. Instead of dealing with physical CPU numbers, affinities are expressed as rectangles in a grid of virtual CPU nodes. This clears the way to conveniently assign sets of adjacent CPUs to subsystems, each of them managing their respective viewport of the coordinate space. By using 2D Cartesian coordinates, the locality of CPU nodes can be modeled for different topologies such as SMP (simple Nx1 grid), grids of NUMA nodes, or ring topologies. 2013-08-07 22:16:58 +02:00			`Affinity::Space affinity_space() const {`
			`return call<Rpc_affinity_space>(); }`
Extend Cpu_session with thread-affinity API This patch introduces the functions 'affinity' and 'num_cpus' to the CPU session interface. The interface extension will allow the assignment of individual threads to CPUs. At this point, it is just a stub with no actual platform support. 2012-09-04 17:32:55 +02:00
Express affinities via Cartesian coordinates This patch introduces new types for expressing CPU affinities. Instead of dealing with physical CPU numbers, affinities are expressed as rectangles in a grid of virtual CPU nodes. This clears the way to conveniently assign sets of adjacent CPUs to subsystems, each of them managing their respective viewport of the coordinate space. By using 2D Cartesian coordinates, the locality of CPU nodes can be modeled for different topologies such as SMP (simple Nx1 grid), grids of NUMA nodes, or ring topologies. 2013-08-07 22:16:58 +02:00			`void affinity(Thread_capability thread, Affinity::Location location) {`
			`call<Rpc_affinity>(thread, location); }`
Extend Cpu_session with thread-affinity API This patch introduces the functions 'affinity' and 'num_cpus' to the CPU session interface. The interface extension will allow the assignment of individual threads to CPUs. At this point, it is just a stub with no actual platform support. 2012-09-04 17:32:55 +02:00
NOVA: extend cpu_session with synchronous pause The kernel provides a "recall" feature issued on threads to force a thread into an exception. In the exception the current state of the thread can be obtained and its execution can be halted/paused. However, the recall exception is only delivered when the next time the thread would leave the kernel. That means the delivery is asynchronous and Genode has to wait until the exception triggered. Waiting for the exception can either be done in the cpu_session service or outside the service in the protection domain of the caller. It turned out that waiting inside the cpu_service is prone to deadlock the system. The cpu_session interface is one of many session interfaces handled by the same thread inside Core. Deadlock situation: * The caller (thread_c) to pause some thread_p manages to establish the call to the cpu_session thread_s of Core but get be interrupted before issuing the actual pause (recall) command. * Now the - to be recalled thread_p - is scheduled and tries to invoke another service of Core, like making log output. * Since the Core thread_s is handling the session request of thread_c, the kernel uses the timeslice of thread_p to help to finish the request handled by thread_s. * Thread_s issues the actual pause/recall on thread_p and blocks inside Core to wait for the recall exception to be issued. * thread_p will leave not the kernel before finishing it actual IPC with thread_s which is blocked waiting for thread_p. That is the reason why the waiting/blocking for the recall exception taking place must be done on NOVA in the context of the caller (thread_1). Introduce a pause_sync call to the cpu_session which returns a semaphore capability to the caller. The caller blocks on the semaphore and is woken up when the pager of thread_p receives the recall exception with the state of thread_p. 2012-08-24 09:29:54 +02:00			`private:`

Express affinities via Cartesian coordinates This patch introduces new types for expressing CPU affinities. Instead of dealing with physical CPU numbers, affinities are expressed as rectangles in a grid of virtual CPU nodes. This clears the way to conveniently assign sets of adjacent CPUs to subsystems, each of them managing their respective viewport of the coordinate space. By using 2D Cartesian coordinates, the locality of CPU nodes can be modeled for different topologies such as SMP (simple Nx1 grid), grids of NUMA nodes, or ring topologies. 2013-08-07 22:16:58 +02:00			`Native_capability pause_sync(Thread_capability target) {`
			`return Native_capability::invalid_cap(); }`
NOVA: extend cpu_session for base-nova 2012-08-08 17:12:10 +02:00			`};`
			`}`

NOVA: extend cpu_session with synchronous pause The kernel provides a "recall" feature issued on threads to force a thread into an exception. In the exception the current state of the thread can be obtained and its execution can be halted/paused. However, the recall exception is only delivered when the next time the thread would leave the kernel. That means the delivery is asynchronous and Genode has to wait until the exception triggered. Waiting for the exception can either be done in the cpu_session service or outside the service in the protection domain of the caller. It turned out that waiting inside the cpu_service is prone to deadlock the system. The cpu_session interface is one of many session interfaces handled by the same thread inside Core. Deadlock situation: * The caller (thread_c) to pause some thread_p manages to establish the call to the cpu_session thread_s of Core but get be interrupted before issuing the actual pause (recall) command. * Now the - to be recalled thread_p - is scheduled and tries to invoke another service of Core, like making log output. * Since the Core thread_s is handling the session request of thread_c, the kernel uses the timeslice of thread_p to help to finish the request handled by thread_s. * Thread_s issues the actual pause/recall on thread_p and blocks inside Core to wait for the recall exception to be issued. * thread_p will leave not the kernel before finishing it actual IPC with thread_s which is blocked waiting for thread_p. That is the reason why the waiting/blocking for the recall exception taking place must be done on NOVA in the context of the caller (thread_1). Introduce a pause_sync call to the cpu_session which returns a semaphore capability to the caller. The caller blocks on the semaphore and is woken up when the pager of thread_p receives the recall exception with the state of thread_p. 2012-08-24 09:29:54 +02:00			`#endif /* _INCLUDE__CPU_SESSION__CLIENT_H_ */`