qemu: IOPortListener

git-svn-id: https://www4.informatik.uni-erlangen.de/i4svn/danceos/trunk/devel/fail@1622 8c4709b5-6ec9-48aa-a5cd-a96041d1645a
2012-09-12 16:05:18 +00:00
parent 095adbc7e5
commit f795bf63c4
5 changed files with 61 additions and 49 deletions
--- a/src/core/sal/bochs/BochsController.cc
+++ b/src/core/sal/bochs/BochsController.cc
@ -124,7 +124,7 @@ void BochsController::updateBPEventInfo(BX_CPU_C *context, bxICacheEntry_c *cach
 }
 void BochsController::onIOPort(unsigned char data, unsigned port, bool out) {
-	// Check for active breakpoint-events:
+	// Check for active IOPortListeners:
 	io_cache_t &buffer_cache = m_LstList.getIOBuffer();
 	io_cache_t::iterator it = buffer_cache.begin();
 	while (it != buffer_cache.end()) {
@ -139,8 +139,6 @@ void BochsController::onIOPort(unsigned char data, unsigned port, bool out) {
 		it++;
 	}
 	m_LstList.triggerActiveListeners();
 	// Note: SimulatorController::onBreakpoint will not be invoked in this
 	//       implementation.
 }
 void BochsController::save(const std::string& path)
--- a/src/core/sal/qemu/QEMUController.cc
+++ b/src/core/sal/qemu/QEMUController.cc
@ -21,4 +21,23 @@ QEMUController::~QEMUController()
 	delete m_Mem;
 }
 // FIXME: copied from BochsController; remove redundancy!
 void QEMUController::onIOPort(unsigned char data, unsigned port, bool out) {
 	// Check for active IOPortListeners:
 	io_cache_t &buffer_cache = m_LstList.getIOBuffer();
 	io_cache_t::iterator it = buffer_cache.begin();
 	while (it != buffer_cache.end()) {
 		IOPortListener* pIOPt = (*it);
 		if (pIOPt->isMatching(port, out)) {
 			pIOPt->setData(data);
 			it = buffer_cache.makeActive(m_LstList, it);
 			// "it" has already been set to the next element (by calling
 			// makeActive()):
 			continue; // -> skip iterator increment
 		}
 		it++;
 	}
 	m_LstList.triggerActiveListeners();
 }
 } // end-of-namespace: fail
--- a/src/core/sal/qemu/QEMUController.hpp
+++ b/src/core/sal/qemu/QEMUController.hpp
@ -28,12 +28,15 @@ public:
 	QEMUController();
 	~QEMUController();
 	/**
-	 * I/O port communication handler. This method is called from QEMU.  TODO.
+	 * I/O port communication handler. This method is called from QEMU.
 	 * @param data the data transmitted
 	 * @param port the port it was transmitted on
 	 * @param out true if the I/O traffic has been outbound, false otherwise
 	 * FIXME Should this be part of the generic interface?  Inherited from some generic x86 arch class?
 	 * FIXME Access width should be part of the interface.
 	 * FIXME Read/Write should be separate listeners.
 	 */
-	void onIOPort(unsigned char data, unsigned port, bool out) {}
+	void onIOPort(unsigned char data, unsigned port, bool out);
 	/**
 	 * Static internal handler for TimerListeners.  TODO.
 	 */
--- a/src/core/sal/qemu/wrappers.cc
+++ b/src/core/sal/qemu/wrappers.cc
@ -24,4 +24,10 @@ void fail_watchpoint_hit(struct CPUX86State *env, uint64_t addr, int width, int
 	fail::simulator.onMemoryAccess(addr, width, is_write == 1, 0);
 }
 void fail_io(int port, int width, int32_t data, int is_write)
 {
 	// FIXME: width is discarded
 	fail::simulator.onIOPort((unsigned char)data, port, is_write == 1);
 }
 }
--- a/src/experiments/rampage/experiment.cc
+++ b/src/experiments/rampage/experiment.cc
@ -43,56 +43,42 @@ bool RAMpageExperiment::run()
 	MemWriteListener l_mem1(addr1);
 	MemoryManager& mm = simulator.getMemoryManager();
-	while (true) {
+	IOPortListener l_io(0x2f8, true); // ttyS1 aka COM2
 		simulator.addListener(&l_mem1);
 		simulator.resume();
 		unsigned char data = mm.getByte(addr1);
 #if 1
 		//data |= 1 << bit1; // stuck-to-1
 		mm.setByte(addr1, data);
 #elif 0
 		data &= ~(1 << bit1); // stuck-to-0
 		mm.setByte(addr1, data);
 #elif 0
 		data &= ~(1 << bit2); // coupling bit2 := bit1
 		data |= ((data & (1 << bit1)) != 0) << bit2;
 		mm.setByte(addr1, data);
 #elif 0
 		data &= ~(1 << bit2); // coupling bit2 := !bit1
 		data |= ((data & (1 << bit1)) == 0) << bit2;
 		mm.setByte(addr1, data);
 #elif 0
 		unsigned char data2 = mm.getByte(addr2);
 		data2 &= ~(1 << bit2); // coupling addr2:bit2 := !addr1:bit1
 		data2 |= ((data & (1 << bit1)) == 0) << bit2;
 		mm.setByte(addr2, data2);
 #endif
 		log << "access to addr 0x" << std::hex << addr1 << ", FI!" << endl;
 	}
 	/*
 	MemWriteListener l_mem2(addr2);
 	log << "startup" << endl;
 	simulator.addListener(&l_mem1);
-	simulator.addListener(&l_mem2);
+	simulator.addListener(&l_io);
 	while (true) {
-		MemWriteListener *l = static_cast<MemWriteListener*>(simulator.resume());
+		BaseListener *l = simulator.resume();
 		simulator.addListener(l);
 		address_t target;
 		if (l == &l_mem1) {
-			target = addr2;
+			simulator.addListener(&l_mem1);
-		} else {
+			unsigned char data = mm.getByte(addr1);
-			target = addr1;
+#if 1
 			data |= 1 << bit1; // stuck-to-1
 			mm.setByte(addr1, data);
 #elif 0
 			data &= ~(1 << bit1); // stuck-to-0
 			mm.setByte(addr1, data);
 #elif 0
 			data &= ~(1 << bit2); // coupling bit2 := bit1
 			data |= ((data & (1 << bit1)) != 0) << bit2;
 			mm.setByte(addr1, data);
 #elif 0
 			data &= ~(1 << bit2); // coupling bit2 := !bit1
 			data |= ((data & (1 << bit1)) == 0) << bit2;
 			mm.setByte(addr1, data);
 #elif 0
 			unsigned char data2 = mm.getByte(addr2);
 			data2 &= ~(1 << bit2); // coupling addr2:bit2 := !addr1:bit1
 			data2 |= ((data & (1 << bit1)) == 0) << bit2;
 			mm.setByte(addr2, data2);
 #endif
 			log << "access to addr 0x" << std::hex << addr1 << ", FI!" << endl;
 		} else if (l == &l_io) {
 			simulator.addListener(&l_io);
 			std::cout << l_io.getData() << std::endl;
 		}
 		unsigned char data = simulator.getMemoryManager().getByte(l->getWatchAddress());
 		data ^= (
 	}
-	*/
+
 	return true;
 }