/* * \brief Block-session component * \author Christian Helmuth * \author Stefan Kalkowski * \date 2011-05-20 */ /* * Copyright (C) 2011-2013 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__BLOCK__COMPONENT_H_ #define _INCLUDE__BLOCK__COMPONENT_H_ #include #include #include #include namespace Block { using namespace Genode; class Session_component_base; class Session_component; class Root; }; /** * We have a hen and egg situation that makes this base class necessary. * The Block::Session_rpc_object construction depends on a dataspace for * the packet stream. The dataspace on the other hand is constructed by * the driver, which is created on demand when creating a session. * When creating the driver, and dataspace outside the Session_component * constructor within _create_session of the root component, we would have * to destroy the driver and dataspace within the destructor body of * Session_component, which will lead to problems, because the packet stream * destructors will be called after the shared memory already vanished. */ class Block::Session_component_base { protected: Driver_factory &_driver_factory; Driver &_driver; Ram_dataspace_capability _rq_ds; Session_component_base(Driver_factory &factory, size_t tx_buf_size) : _driver_factory(factory), _driver(*factory.create()), _rq_ds(_driver.alloc_dma_buffer(tx_buf_size)) {} ~Session_component_base() { _driver.free_dma_buffer(_rq_ds); _driver_factory.destroy(&_driver); } }; class Block::Session_component : public Block::Session_component_base, public Block::Driver_session { private: addr_t _rq_phys; Signal_rpc_member _sink_ack; Signal_rpc_member _sink_submit; bool _req_queue_full; bool _ack_queue_full; Packet_descriptor _p_to_handle; unsigned _p_in_fly; /** * Acknowledge a packet already handled */ inline void _ack_packet(Packet_descriptor &packet) { if (!tx_sink()->ready_to_ack()) PERR("Not ready to ack!"); tx_sink()->acknowledge_packet(packet); _p_in_fly--; } /** * Range check packet request */ inline bool _range_check(Packet_descriptor &p) { return p.block_number() + p.block_count() - 1 < _driver.block_count(); } /** * Handle a single request */ void _handle_packet(Packet_descriptor packet) { _p_to_handle = packet; _p_to_handle.succeeded(false); /* ignore invalid packets */ if (!packet.valid() || !_range_check(_p_to_handle)) { _ack_packet(_p_to_handle); return; } try { switch (_p_to_handle.operation()) { case Block::Packet_descriptor::READ: if (_driver.dma_enabled()) _driver.read_dma(packet.block_number(), packet.block_count(), _rq_phys + packet.offset(), _p_to_handle); else _driver.read(packet.block_number(), packet.block_count(), tx_sink()->packet_content(packet), _p_to_handle); break; case Block::Packet_descriptor::WRITE: if (_driver.dma_enabled()) _driver.write_dma(packet.block_number(), packet.block_count(), _rq_phys + packet.offset(), _p_to_handle); else _driver.write(packet.block_number(), packet.block_count(), tx_sink()->packet_content(packet), _p_to_handle); break; default: throw Driver::Io_error(); } } catch (Driver::Request_congestion) { _req_queue_full = true; } catch (Driver::Io_error) { _ack_packet(_p_to_handle); } } /** * Triggered when a packet was placed into the empty submit queue */ void _packet_avail(unsigned) { /* * as long as more packets are available, and we're able to ack * them, and the driver's request queue isn't full, * direct the packet request to the driver backend */ for (_ack_queue_full = (_p_in_fly >= tx_sink()->ack_slots_free()); !_req_queue_full && !_ack_queue_full && tx_sink()->packet_avail(); _ack_queue_full = (++_p_in_fly >= tx_sink()->ack_slots_free())) _handle_packet(tx_sink()->get_packet()); } /** * Triggered when an ack got removed from the full ack queue */ void _ready_to_ack(unsigned) { _packet_avail(0); } public: /** * Constructor * * \param rq_ds shared dataspace for packet stream * \param driver block driver backend * \param driver_factory factory to create and destroy driver objects * \param ep entrypoint handling this session component */ Session_component(Driver_factory &driver_factory, Server::Entrypoint &ep, size_t buf_size) : Session_component_base(driver_factory, buf_size), Driver_session(_rq_ds, ep.rpc_ep()), _rq_phys(Dataspace_client(_rq_ds).phys_addr()), _sink_ack(ep, *this, &Session_component::_ready_to_ack), _sink_submit(ep, *this, &Session_component::_packet_avail), _req_queue_full(false), _p_in_fly(0) { _tx.sigh_ready_to_ack(_sink_ack); _tx.sigh_packet_avail(_sink_submit); _driver.session(this); } ~Session_component() { _driver.session(nullptr); } /** * Acknowledges a packet processed by the driver to the client * * \param packet the packet to acknowledge * \param success indicated whether the processing was successful * * \throw Ack_congestion */ void ack_packet(Packet_descriptor &packet, bool success) { packet.succeeded(success); _ack_packet(packet); if (!_req_queue_full && !_ack_queue_full) return; /* * when the driver's request queue was full, * handle last unprocessed packet taken out of submit queue */ if (_req_queue_full) { _req_queue_full = false; _handle_packet(_p_to_handle); } /* resume packet processing */ _packet_avail(0); } /******************************* ** Block session interface ** *******************************/ void info(sector_t *blk_count, size_t *blk_size, Operations *ops) { *blk_count = _driver.block_count(); *blk_size = _driver.block_size(); *ops = _driver.ops(); } void sync() { _driver.sync(); } }; /** * Root component, handling new session requests */ class Block::Root : public Genode::Root_component { private: Driver_factory &_driver_factory; Server::Entrypoint &_ep; protected: /** * Always returns the singleton block-session component */ Session_component *_create_session(const char *args) { size_t ram_quota = Arg_string::find_arg(args, "ram_quota" ).ulong_value(0); size_t tx_buf_size = Arg_string::find_arg(args, "tx_buf_size").ulong_value(0); /* delete ram quota by the memory needed for the session */ size_t session_size = max((size_t)4096, sizeof(Session_component) + sizeof(Allocator_avl)); if (ram_quota < session_size) throw Root::Quota_exceeded(); /* * Check if donated ram quota suffices for both * communication buffers. Also check both sizes separately * to handle a possible overflow of the sum of both sizes. */ if (tx_buf_size > ram_quota - session_size) { PERR("insufficient 'ram_quota', got %zd, need %zd", ram_quota, tx_buf_size + session_size); throw Root::Quota_exceeded(); } return new (md_alloc()) Session_component(_driver_factory, _ep, tx_buf_size); } public: /** * Constructor * * \param ep entrypoint handling this root component * \param md_alloc allocator to allocate session components * \param driver_factory factory to create and destroy driver backend * \param receiver signal receiver managing signals of the client */ Root(Server::Entrypoint &ep, Allocator *md_alloc, Driver_factory &driver_factory) : Root_component(&ep.rpc_ep(), md_alloc), _driver_factory(driver_factory), _ep(ep) { } }; #endif /* _INCLUDE__BLOCK__COMPONENT_H_ */