2 * This file is part of the Palacios Virtual Machine Monitor developed
3 * by the V3VEE Project with funding from the United States National
4 * Science Foundation and the Department of Energy.
6 * The V3VEE Project is a joint project between Northwestern University
7 * and the University of New Mexico. You can find out more at
10 * Copyright (c) 2008, Peter Dinda <pdinda@northwestern.edu>
11 * Copyright (c) 2008, The V3VEE Project <http://www.v3vee.org>
12 * All rights reserved.
14 * Author: Peter Dinda <pdinda@northwestern.edu>
16 * This is free software. You are permitted to use,
17 * redistribute, and modify it as specified in the file "V3VEE_LICENSE".
20 #include <palacios/vmm.h>
21 #include <palacios/vmm_dev_mgr.h>
22 #include <palacios/vmm_types.h>
24 #include <palacios/vmm_ringbuffer.h>
25 #include <palacios/vmm_lock.h>
26 #include <palacios/vmm_intr.h>
27 #include <palacios/vmm_host_events.h>
28 #include <palacios/vm_guest.h>
31 #ifndef CONFIG_DEBUG_KEYBOARD
33 #define PrintDebug(fmt, args...)
36 #define KEYBOARD_DEBUG_80H 0
40 #define KEYBOARD_60H 0x60 // keyboard microcontroller
41 #define KEYBOARD_64H 0x64 // onboard microcontroller
43 #define KEYBOARD_DELAY_80H 0x80 // written for timing
45 #define KEYBOARD_IRQ 0x1
50 // bits for the output port
51 #define OUTPUT_RESET 0x01 // System reset on 0
52 #define OUTPUT_A20 0x02 // A20 gate (1= A20 is gated)
53 #define OUTPUT_RES1 0x04 // reserved
54 #define OUTPUT_RES2 0x08 // reserved
55 #define OUTPUT_OUTPUT_FULL 0x10 // output buffer full
56 #define OUTPUT_INPUT_EMPTY 0x20 // input buffer empty
57 #define OUTPUT_KBD_CLOCK 0x40 // keyboard clock (?)
58 #define OUTPUT_KBD_DATA 0x80 // keyboard data
60 // bits for the input port
62 #define INPUT_RES0 0x01 // reserved
63 #define INPUT_RES1 0x02 // reserved
64 #define INPUT_RES2 0x04 // reserved
65 #define INPUT_RES3 0x08 // reserved
66 #define INPUT_RAM 0x10 // set to 1 if RAM exists?
67 #define INPUT_JUMPER 0x20 // manufacturing jumper?
68 #define INPUT_DISPLAY 0x40 // 0=color, 1=mono
69 #define INPUT_KBD_INHIBIT 0x80 // 1=inhibit keyboard ?
72 #define MOUSE_ACK 0xfa
74 // for queue operations
78 // for queue operations - whether it's data or cmd waiting on 60h
82 // for queue operations - whether this is keyboard or mouse data on 60h
92 uint8_t irq_en : 1; // 1=interrupts enabled
93 uint8_t mouse_irq_en : 1; // 1=interrupts enabled for mouse
94 uint8_t self_test_ok : 1; // 1= self test passed
95 uint8_t override : 1; // MBZ for PS2
96 uint8_t disable : 1; // 1=disabled keyboard
97 uint8_t mouse_disable : 1; // 1=disabled mouse
98 uint8_t translate : 1; // 1=translate to set 1 scancodes (For PC Compatibility)
99 uint8_t rsvd : 1; // must be zero
100 } __attribute__((packed));
101 } __attribute__((packed));
102 } __attribute__((packed));
111 uint8_t out_buf_full : 1; // 1=full (data for system)
112 uint8_t in_buf_full : 1; // 1=full (data for 8042)
113 uint8_t self_test_ok : 1; // 1=self-test-passed
114 uint8_t cmd : 1; // 0=data on 60h, 1=cmd on 64h
115 uint8_t enabled : 1; // 1=keyboard is enabled
116 uint8_t mouse_buf_full : 1; // 1= mouse output buffer full
117 uint8_t timeout_err : 1; // 1=timeout of keybd
118 uint8_t parity_err : 1; // 1=parity error
119 } __attribute__((packed));
120 } __attribute__((packed));
121 } __attribute__((packed));
128 /* This QUEUE_SIZE must be 256 */
129 /* Its designed this way to cause the start/end index to automatically
130 wrap around (2^8 = 256) so an overrun will automatically readjust the
133 #define QUEUE_SIZE 256
135 uint8_t queue[QUEUE_SIZE];
142 struct keyboard_internal {
144 // 0x60 is the port for the keyboard microcontroller
145 // writes are commands
146 // reads from it usually return scancodes
147 // however, it can also return other data
148 // depending on the state of the onboard microcontroller
150 // 0x64 is the port for the onboard microcontroller
151 // writes are commands
155 // state of the onboard microcontroller
156 // this is needed because sometimes 0x60 reads come
157 // from the onboard microcontroller
158 enum {// Normal mode measn we deliver keys
159 // to the vm and accept commands from it
161 // after receiving cmd 0x60
162 // keybaord uC cmd will subsequently arrive
164 // after recieving 0xa5
165 // password arrives on data port, null terminated
167 // after having a d1 sent to 64
168 // we wait for a new output byte on 60
170 // after having a d2 sent to 64
171 // we wait for a new output byte on 60
172 // then make it available as a keystroke
174 // after having a d3 sent to 64
175 // we wait for a new output byte on 60
176 // then make it available as a mouse event
178 // after having a d4 sent to 64
179 // we wait for a new output byte on 60
180 // then send it to the mouse
182 // After the Keyboard LEDs are enabled
183 // we wait for the output byte on 64?
185 // After the Keyboard SET_RATE is called
186 // we wait for the output byte on 64?
192 // Normal mouse state
194 // this is used for setting sample rate
203 struct status_reg status;
205 uint8_t output_byte; // output port of onboard uC (e.g. A20)
206 uint8_t input_byte; // input port of onboard uC
213 struct queue kbd_queue;
214 struct queue mouse_queue;
220 static int update_kb_irq(struct vm_device * dev) {
221 struct keyboard_internal *state = (struct keyboard_internal *)(dev->private_data);
225 state->status.out_buf_full = 0;
226 state->status.mouse_buf_full = 0;
229 // If there is pending Keyboard data then it overrides mouse data
230 if (state->kbd_queue.count > 0) {
231 irq_num = KEYBOARD_IRQ;
232 } else if (state->mouse_queue.count > 0) {
234 state->status.mouse_buf_full = 1;
237 PrintDebug("keyboard: interrupt 0x%d\n", irq_num);
240 // Global output buffer flag (for both Keyboard and mouse)
241 state->status.out_buf_full = 1;
243 if (state->cmd.irq_en == 1) {
244 v3_raise_irq(dev->vm, irq_num);
253 /* Only one byte is read per irq
254 * So if the queue is still full after a data read, we re-raise the irq
255 * If we keep reading an empty queue we return the last queue entry
258 static int push_to_output_queue(struct vm_device * dev, uint8_t value, uint8_t cmd, uint8_t mouse) {
259 struct keyboard_internal * state = (struct keyboard_internal *)(dev->private_data);
260 struct queue * q = NULL;
264 q = &(state->mouse_queue);
266 q = &(state->kbd_queue);
269 if (q->count == QUEUE_SIZE) {
274 state->status.cmd = 1;
276 state->status.cmd = 0;
279 q->queue[q->end++] = value;
290 static int pull_from_output_queue(struct vm_device * dev, uint8_t * value) {
291 struct keyboard_internal * state = (struct keyboard_internal *)(dev->private_data);
292 struct queue * q = NULL;
294 if (state->kbd_queue.count > 0) {
295 q = &(state->kbd_queue);
296 PrintDebug("Reading from Keyboard Queue\n");
297 } else if (state->mouse_queue.count > 0) {
298 q = &(state->mouse_queue);
299 PrintDebug("Reading from Mouse Queue\n");
301 uint8_t idx = state->kbd_queue.start - 1;
302 PrintDebug("No Data in any queue\n");
303 *value = state->kbd_queue.queue[idx];
307 *value = q->queue[q->start++];
311 PrintDebug("Read from Queue: %x\n", *value);
312 PrintDebug("QStart=%d, QEnd=%d\n", q->start, q->end);
320 #include <palacios/vmm_telemetry.h>
323 static int key_event_handler(struct v3_vm_info * vm,
324 struct v3_keyboard_event * evt,
325 void * private_data) {
326 struct vm_device * dev = (struct vm_device *)private_data;
327 struct keyboard_internal *state = (struct keyboard_internal *)(dev->private_data);
329 PrintDebug("keyboard: injected status 0x%x, and scancode 0x%x\n", evt->status, evt->scan_code);
331 if (evt->scan_code == 0x44) { // F10 debug dump
333 for (i = 0; i < vm->num_cores; i++) {
334 v3_print_guest_state(&(vm->cores[i]));
336 // PrintGuestPageTables(info, info->shdw_pg_state.guest_cr3);
338 #ifdef CONFIG_SYMBIOTIC
339 else if (evt->scan_code == 0x43) { // F9 Sym test
340 PrintDebug("Testing sym call\n");
341 sym_arg_t a0 = 0x1111;
342 sym_arg_t a1 = 0x2222;
343 sym_arg_t a2 = 0x3333;
344 sym_arg_t a3 = 0x4444;
345 sym_arg_t a4 = 0x5555;
346 uint64_t call_start = 0;
347 uint64_t call_end = 0;
349 V3_Print("Exits before symcall: %d\n", (uint32_t)info->num_exits);
352 v3_sym_call5(info, SYMCALL_TEST, &a0, &a1, &a2, &a3, &a4);
355 V3_Print("Symcall latency = %d cycles (%d exits)\n", (uint32_t)(call_end - call_start), (uint32_t)info->num_exits);
357 V3_Print("Symcall Test Returned arg0=%x, arg1=%x, arg2=%x, arg3=%x, arg4=%x\n",
358 (uint32_t)a0, (uint32_t)a1, (uint32_t)a2, (uint32_t)a3, (uint32_t)a4);
362 else if (evt->scan_code == 0x42) { // F8 debug toggle
363 extern int v3_dbg_enable;
365 PrintDebug("Toggling Debugging\n");
367 } else if (evt->scan_code == 0x41) { // F7 telemetry dump
368 #ifdef CONFIG_TELEMETRY
369 v3_print_telemetry(vm);
375 addr_t irq_state = v3_lock_irqsave(state->kb_lock);
377 if ( (state->status.enabled == 1) // onboard is enabled
378 && (state->cmd.disable == 0) ) { // keyboard is enabled
380 push_to_output_queue(dev, evt->scan_code, DATA, KEYBOARD);
383 v3_unlock_irqrestore(state->kb_lock, irq_state);
389 static int mouse_event_handler(struct v3_vm_info * vm,
390 struct v3_mouse_event * evt,
391 void * private_data) {
392 struct vm_device * dev = (struct vm_device *)private_data;
393 struct keyboard_internal * state = (struct keyboard_internal *)(dev->private_data);
396 PrintDebug("keyboard: injected mouse packet 0x %x %x %x\n",
397 evt->data[0], evt->data[1], evt->data[2]);
399 addr_t irq_state = v3_lock_irqsave(state->kb_lock);
401 switch (state->mouse_state) {
404 if (state->cmd.mouse_disable == 0) {
405 push_to_output_queue(dev, evt->data[0], DATA, MOUSE);
406 push_to_output_queue(dev, evt->data[1], DATA, MOUSE);
407 push_to_output_queue(dev, evt->data[2], DATA, MOUSE);
411 PrintError("Invalid mouse state\n");
417 v3_unlock_irqrestore(state->kb_lock, irq_state);
423 static int keyboard_reset_device(struct vm_device * dev) {
424 struct keyboard_internal * data = (struct keyboard_internal *)(dev->private_data);
426 memset(data, 0, sizeof(struct keyboard_internal));
428 data->state = NORMAL;
429 data->mouse_state = STREAM;
432 // PS2, keyboard+mouse enabled, generic translation
435 data->cmd.irq_en = 1;
436 data->cmd.mouse_irq_en = 1;
437 data->cmd.self_test_ok = 1;
441 // buffers empty, no errors
442 data->status.val = 0;
444 data->status.self_test_ok = 1; // self-tests passed
445 data->status.enabled = 1;// keyboard ready
449 data->output_byte = 0; // ?
451 data->input_byte = INPUT_RAM; // we have some
452 // also display=color, jumper 0, keyboard enabled
454 PrintDebug("keyboard: reset device\n");
462 static int keyboard_start_device(struct vm_device * dev) {
463 PrintDebug("keyboard: start device\n");
468 static int keyboard_stop_device(struct vm_device * dev) {
469 PrintDebug("keyboard: stop device\n");
475 static int mouse_write_output(struct vm_device * dev, uint8_t data) {
476 struct keyboard_internal * state = (struct keyboard_internal *)(dev->private_data);
478 switch (state->mouse_state) {
483 if (state->mouse_enabled == 0) {
484 push_to_output_queue(dev, 0xfe, DATA, MOUSE) ; // no mouse!
486 push_to_output_queue(dev, MOUSE_ACK, DATA, MOUSE) ;
487 push_to_output_queue(dev, 0xaa, DATA, MOUSE) ;
488 push_to_output_queue(dev, 0x00, DATA, MOUSE) ;
492 /* case 0xfe: //resend */
493 /* PushToOutputQueue(dev, 0xfa, OVERWRITE, DATA, MOUSE) ; */
494 /* PrintDebug(" mouse resend begins "); */
495 /* state->mouse_done_after_ack = 0; */
496 /* state->mouse_needs_ack = 0; */
497 /* state->mouse_state = STREAM1; */
498 /* return 0; // not done */
501 case 0xf6: // set defaults
502 push_to_output_queue(dev, MOUSE_ACK, DATA, MOUSE) ;
503 PrintDebug(" mouse set defaults ");
507 case 0xf5: // disable data reporting
508 push_to_output_queue(dev, MOUSE_ACK, DATA, MOUSE) ;
509 PrintDebug(" mouse disable data reporting ");
512 case 0xf4: // enable data reporting
513 push_to_output_queue(dev, MOUSE_ACK, DATA, MOUSE) ;
514 PrintDebug(" mouse enable data reporting ");
517 case 0xf3: // set sample rate
518 push_to_output_queue(dev, MOUSE_ACK, DATA, MOUSE) ;
519 state->mouse_state = SAMPLE;
520 PrintDebug(" mouse set sample rate begins ");
523 case 0xf2: // get device id
524 push_to_output_queue(dev, MOUSE_ACK, DATA, MOUSE) ;
525 push_to_output_queue(dev, 0x0, DATA, MOUSE);
526 PrintDebug(" mouse get device id begins ");
529 case 0xf0: // set remote mode
530 push_to_output_queue(dev, MOUSE_ACK, DATA, MOUSE) ;
531 PrintDebug(" mouse set remote mode ");
534 case 0xee: // set wrap mode
535 push_to_output_queue(dev, MOUSE_ACK, DATA, MOUSE) ;
536 PrintError(" mouse set wrap mode (ignored) ");
539 case 0xec: // reset wrap mode
540 push_to_output_queue(dev, MOUSE_ACK, DATA, MOUSE) ;
541 PrintError(" mouse reset wrap mode (ignored) ");
544 case 0xeb: // read data
545 push_to_output_queue(dev, MOUSE_ACK, DATA, MOUSE) ;
546 PrintError(" mouse switch to wrap mode (ignored) ");
549 case 0xea: // set stream mode
550 push_to_output_queue(dev, MOUSE_ACK, DATA, MOUSE) ;
551 PrintDebug(" mouse set stream mode ");
554 case 0xe9: // status request
555 push_to_output_queue(dev, MOUSE_ACK, DATA, MOUSE) ;
556 push_to_output_queue(dev, 0x00, DATA, MOUSE);
557 push_to_output_queue(dev, 0x00, DATA, MOUSE);
558 push_to_output_queue(dev, 0x00, DATA, MOUSE);
559 PrintDebug(" mouse status request begins ");
562 case 0xe8: // set resolution
563 push_to_output_queue(dev, MOUSE_ACK, DATA, MOUSE) ;
564 PrintDebug(" mouse set resolution begins ");
565 state->mouse_state = SET_RES;
568 case 0xe7: // set scaling 2:1
569 push_to_output_queue(dev, MOUSE_ACK, DATA, MOUSE) ;
570 PrintDebug(" mouse set scaling 2:1 ");
573 case 0xe6: // set scaling 1:1
574 push_to_output_queue(dev, MOUSE_ACK, DATA, MOUSE) ;
575 PrintDebug(" mouse set scaling 1:1 ");
579 PrintDebug(" receiving unknown mouse command (0x%x) in acceptable state ", data);
587 PrintDebug(" receiving mouse output in unhandled state (0x%x) ", state->mouse_state);
596 #if KEYBOARD_DEBUG_80H
597 static int keyboard_write_delay(ushort_t port, void * src, uint_t length, struct vm_device * dev) {
600 PrintDebug("keyboard: write of 0x%x to 80h\n", *((uint8_t*)src));
603 PrintDebug("keyboard: write of >1 byte to 80h\n", *((uint8_t*)src));
608 static int keyboard_read_delay(struct guest_info * core, ushort_t port, void * dest, uint_t length, struct vm_device * dev) {
611 *(uint8_t *)dest = v3_inb(port);
613 PrintDebug("keyboard: read of 0x%x from 80h\n", *((uint8_t*)dest));
617 PrintDebug("keyboard: read of >1 byte from 80h\n");
628 static int keyboard_write_command(struct guest_info * core, ushort_t port, void * src, uint_t length, struct vm_device * dev) {
629 struct keyboard_internal * state = (struct keyboard_internal *)(dev->private_data);
630 uint8_t cmd = *(uint8_t *)src;
632 // Should always be single byte write
634 PrintError("keyboard: write of >1 bytes (%d) to 64h\n", length);
639 addr_t irq_state = v3_lock_irqsave(state->kb_lock);
641 if (state->state != NORMAL) {
642 PrintDebug("keyboard: warning - receiving command on 64h but state != NORMAL\n");
645 PrintDebug("keyboard: command 0x%x on 64h\n", cmd);
648 case 0x20: // READ COMMAND BYTE (returned in 60h)
649 push_to_output_queue(dev, state->cmd.val, COMMAND, KEYBOARD);
650 PrintDebug("keyboard: command byte 0x%x returned\n", state->cmd.val);
653 case 0x60: // WRITE COMMAND BYTE (read from 60h)
654 state->state = WRITING_CMD_BYTE; // we need to make sure we send the next 0x60 byte appropriately
655 PrintDebug("keyboard: prepare to write command byte\n");
658 // case 0x90-9f - write to output port (?)
660 case 0xa1: // Get version number
661 push_to_output_queue(dev, 0x00, COMMAND, KEYBOARD);
662 PrintDebug("keyboard: version number 0x0 returned\n");
665 case 0xa4: // is password installed? send result to 0x60
666 // we don't support passwords
667 push_to_output_queue(dev, 0xf1, COMMAND, KEYBOARD);
668 PrintDebug("keyboard: password not installed\n");
671 case 0xa5: // new password will arrive on 0x60
672 state->state = TRANSMIT_PASSWD;
673 PrintDebug("keyboard: pepare to transmit password\n");
676 case 0xa6: // check passwd;
677 // since we do not support passwords, we will simply ignore this
678 // the implication is that any password check immediately succeeds
679 // with a blank password
680 PrintDebug("keyboard: password check succeeded\n");
683 case 0xa7: // disable mouse
684 state->cmd.mouse_disable = 1;
685 PrintDebug("keyboard: mouse disabled\n");
688 case 0xa8: // enable mouse
689 state->cmd.mouse_disable = 0;
690 PrintDebug("keyboard: mouse enabled\n");
693 case 0xa9: // mouse interface test (always succeeds)
694 push_to_output_queue(dev, 0x00, COMMAND, KEYBOARD);
695 PrintDebug("keyboard: mouse interface test succeeded\n");
698 case 0xaa: // controller self test (always succeeds)
699 push_to_output_queue(dev, 0x55, COMMAND, KEYBOARD);
700 PrintDebug("keyboard: controller self test succeeded\n");
703 case 0xab: // keyboard interface test (always succeeds)
704 push_to_output_queue(dev, 0, COMMAND, KEYBOARD);
705 PrintDebug("keyboard: keyboard interface test succeeded\n");
708 case 0xad: // disable keyboard
709 state->cmd.disable = 1;
710 PrintDebug("keyboard: keyboard disabled\n");
713 case 0xae: // enable keyboard
714 state->cmd.disable = 0;
715 PrintDebug("keyboard: keyboard enabled\n");
718 case 0xaf: // get version
719 push_to_output_queue(dev, 0x00, COMMAND, KEYBOARD);
720 PrintDebug("keyboard: version 0 returned \n");
723 case 0xd0: // return microcontroller output on 60h
724 push_to_output_queue(dev, state->output_byte, COMMAND, KEYBOARD);
725 PrintDebug("keyboard: output byte 0x%x returned\n", state->output_byte);
728 case 0xd1: // request to write next byte on 60h to the microcontroller output port
729 state->state = WRITING_OUTPUT_PORT;
730 PrintDebug("keyboard: prepare to write output byte\n");
733 case 0xd2: // write keyboard buffer (inject key)
734 state->state = INJECTING_KEY;
735 PrintDebug("keyboard: prepare to inject key\n");
738 case 0xd3: // write mouse buffer (inject mouse)
739 state->state = INJECTING_MOUSE;
740 PrintDebug("keyboard: prepare to inject mouse\n");
743 case 0xd4: // write mouse device (command to mouse?)
744 state->state = IN_MOUSE;
745 PrintDebug("keyboard: prepare to inject mouse command\n");
748 case 0xc0: // read input port
749 push_to_output_queue(dev, state->input_byte, COMMAND, KEYBOARD);
750 PrintDebug("keyboard: input byte 0x%x returned\n", state->input_byte);
753 case 0xc1: //copy input port lsn to status msn
754 state->status.val &= 0x0f;
755 state->status.val |= (state->input_byte & 0xf) << 4;
756 PrintDebug("keyboard: copied input byte low 4 bits to status reg hi 4 bits\n");
759 case 0xc2: // copy input port msn to status msn
760 state->status.val &= 0x0f;
761 state->status.val |= (state->input_byte & 0xf0);
762 PrintDebug("keyboard: copied input byte hi 4 bits to status reg hi 4 bits\n");
765 case 0xe0: // read test port
766 push_to_output_queue(dev, state->output_byte >> 6, COMMAND, KEYBOARD);
767 PrintDebug("keyboard: read 0x%x from test port\n", state->output_byte >> 6);
771 case 0xf0: // pulse output port
772 case 0xf1: // this should pulse 0..3 of cmd_byte on output port
773 case 0xf2: // instead of what is currently in output_byte (I think)
774 case 0xf3: // main effect is taht if bit zero is zero
775 case 0xf4: // should cause reset
776 case 0xf5: // I doubt anything more recent than a 286 running
777 case 0xf6: // OS2 with the penalty box will care
787 PrintDebug("keyboard: ignoring pulse of 0x%x (low=pulsed) on output port\n", (cmd & 0xf));
790 // case ac diagonstic - returns 16 bytes from keyboard microcontroler on 60h
792 PrintDebug("keyboard: ignoring command (unimplemented)\n");
796 v3_unlock_irqrestore(state->kb_lock, irq_state);
801 static int keyboard_read_status(struct guest_info * core, ushort_t port, void * dest, uint_t length, struct vm_device * dev) {
802 struct keyboard_internal *state = (struct keyboard_internal *)(dev->private_data);
805 PrintError("keyboard: >1 byte read for status (64h)\n");
809 PrintDebug("keyboard: read status (64h): ");
811 addr_t irq_state = v3_lock_irqsave(state->kb_lock);
813 *(uint8_t *)dest = state->status.val;
815 v3_unlock_irqrestore(state->kb_lock, irq_state);
817 PrintDebug("0x%x\n", *(uint8_t *)dest);
822 static int keyboard_write_output(struct guest_info * core, ushort_t port, void * src, uint_t length, struct vm_device * dev) {
823 struct keyboard_internal *state = (struct keyboard_internal *)(dev->private_data);
827 PrintError("keyboard: write of 60h with >1 byte\n");
831 uint8_t data = *(uint8_t *)src;
833 PrintDebug("keyboard: output 0x%x on 60h\n", data);
835 addr_t irq_state = v3_lock_irqsave(state->kb_lock);
837 switch (state->state) {
838 case WRITING_CMD_BYTE:
839 state->cmd.val = data;
840 state->state = NORMAL;
841 PrintDebug("keyboard: wrote new command byte 0x%x\n", state->cmd.val);
844 case WRITING_OUTPUT_PORT:
845 state->output_byte = data;
846 state->state = NORMAL;
847 PrintDebug("keyboard: wrote new output byte 0x%x\n", state->output_byte);
851 push_to_output_queue(dev, data, COMMAND, KEYBOARD); // probably should be a call to deliver_key_to_vmm()
852 state->state = NORMAL;
853 PrintDebug("keyboard: injected key 0x%x\n", data);
856 case INJECTING_MOUSE:
857 push_to_output_queue(dev, data, DATA, MOUSE);
858 // PrintDebug("keyboard: ignoring injected mouse event 0x%x\n", data);
859 PrintDebug("keyboard: injected mouse event 0x%x\n", data);
860 state->state = NORMAL;
864 PrintDebug("keyboard: mouse action: ");
865 if (mouse_write_output(dev, data)) {
866 state->state = NORMAL;
871 case TRANSMIT_PASSWD:
874 PrintDebug("keyboard: ignoring password character 0x%x\n",data);
877 state->state = NORMAL;
878 PrintDebug("keyboard: done with password\n");
883 PrintDebug("Keyboard: LEDs being set...\n");
884 push_to_output_queue(dev, 0xfa, COMMAND, KEYBOARD);
885 state->state = NORMAL;
889 PrintDebug("Keyboard: Rate being set...\n");
890 push_to_output_queue(dev, 0xfa, COMMAND, KEYBOARD);
891 state->state = NORMAL;
896 // command is being sent to keyboard controller
899 push_to_output_queue(dev, 0xfa, COMMAND, KEYBOARD); // ack
900 push_to_output_queue(dev, 0xaa, COMMAND, KEYBOARD);
901 PrintDebug("keyboard: reset complete and acked\n");
904 case 0xf5: // disable scanning
905 case 0xf4: // enable scanning
907 push_to_output_queue(dev, 0xfa, COMMAND, KEYBOARD);
908 // should do something here... PAD
909 PrintDebug("keyboard: %s scanning done and acked\n", (data == 0xf5) ? "disable" : "enable");
913 push_to_output_queue(dev, 0xfa, COMMAND, KEYBOARD);
914 state->state = SET_RATE;
917 case 0xf2: // get keyboard ID
918 push_to_output_queue(dev, 0xfa, COMMAND, KEYBOARD);
919 push_to_output_queue(dev, 0xab, COMMAND, KEYBOARD);
920 push_to_output_queue(dev, 0x83, COMMAND, KEYBOARD);
921 PrintDebug("Keyboard: Requesting Keyboard ID\n");
924 case 0xed: // enable keyboard LEDs
925 push_to_output_queue(dev, 0xfa, COMMAND, KEYBOARD);
926 state->state = SET_LEDS;
930 case 0xfd: // set key type make
931 case 0xfc: // set key typ make/break
932 case 0xfb: // set key type typematic
933 case 0xfa: // set all typematic make/break/typematic
934 case 0xf9: // set all make
935 case 0xf8: // set all make/break
936 case 0xf7: // set all typemaktic
937 case 0xf6: // set defaults
938 PrintError("keyboard: unhandled known command 0x%x on output buffer (60h)\n", data);
943 PrintError("keyboard: unhandled unknown command 0x%x on output buffer (60h)\n", data);
944 state->status.out_buf_full = 1;
952 v3_unlock_irqrestore(state->kb_lock, irq_state);
957 static int keyboard_read_input(struct guest_info * core, ushort_t port, void * dest, uint_t length, struct vm_device * dev) {
958 struct keyboard_internal * state = (struct keyboard_internal *)(dev->private_data);
961 PrintError("keyboard: unknown size read from input (60h)\n");
965 addr_t irq_state = v3_lock_irqsave(state->kb_lock);
967 pull_from_output_queue(dev, (uint8_t *)dest);
969 v3_unlock_irqrestore(state->kb_lock, irq_state);
971 PrintDebug("keyboard: read from input (60h): 0x%x\n", *(uint8_t *)dest);
981 static int keyboard_free(struct vm_device * dev) {
983 v3_dev_unhook_io(dev, KEYBOARD_60H);
984 v3_dev_unhook_io(dev, KEYBOARD_64H);
985 #if KEYBOARD_DEBUG_80H
986 v3_dev_unhook_io(dev, KEYBOARD_DELAY_80H);
988 keyboard_reset_device(dev);
996 static struct v3_device_ops dev_ops = {
997 .free = keyboard_free,
998 .reset = keyboard_reset_device,
999 .start = keyboard_start_device,
1000 .stop = keyboard_stop_device,
1006 static int keyboard_init(struct v3_vm_info * vm, v3_cfg_tree_t * cfg) {
1007 struct keyboard_internal * keyboard_state = NULL;
1008 char * name = v3_cfg_val(cfg, "name");
1010 PrintDebug("keyboard: init_device\n");
1012 keyboard_state = (struct keyboard_internal *)V3_Malloc(sizeof(struct keyboard_internal));
1014 keyboard_state->mouse_queue.start = 0;
1015 keyboard_state->mouse_queue.end = 0;
1016 keyboard_state->mouse_queue.count = 0;
1018 keyboard_state->kbd_queue.start = 0;
1019 keyboard_state->kbd_queue.end = 0;
1020 keyboard_state->kbd_queue.count = 0;
1022 keyboard_state->mouse_enabled = 0;
1024 struct vm_device * dev = v3_allocate_device(name, &dev_ops, keyboard_state);
1026 if (v3_attach_device(vm, dev) == -1) {
1027 PrintError("Could not attach device %s\n", name);
1032 keyboard_reset_device(dev);
1035 v3_lock_init(&(keyboard_state->kb_lock));
1039 v3_dev_hook_io(dev, KEYBOARD_64H, &keyboard_read_status, &keyboard_write_command);
1040 v3_dev_hook_io(dev, KEYBOARD_60H, &keyboard_read_input, &keyboard_write_output);
1042 v3_hook_host_event(vm, HOST_KEYBOARD_EVT, V3_HOST_EVENT_HANDLER(key_event_handler), dev);
1043 v3_hook_host_event(vm, HOST_MOUSE_EVT, V3_HOST_EVENT_HANDLER(mouse_event_handler), dev);
1046 #if KEYBOARD_DEBUG_80H
1047 v3_dev_hook_io(dev, KEYBOARD_DELAY_80H, &keyboard_read_delay, &keyboard_write_delay);
1052 // We do not hook the IRQ here. Instead, the underlying device driver
1053 // is responsible to call us back
1060 device_register("KEYBOARD", keyboard_init)