*/
-#include <devices/nvram.h>
+#include <palacios/vmm_dev_mgr.h>
#include <palacios/vmm.h>
#include <palacios/vmm_types.h>
+#include <palacios/vmm_lock.h>
-#ifndef DEBUG_NVRAM
+#include <devices/ide.h>
+#include <palacios/vmm_intr.h>
+#include <palacios/vmm_host_events.h>
+#include <palacios/vm_guest.h>
+
+
+#ifndef V3_CONFIG_DEBUG_NVRAM
#undef PrintDebug
#define PrintDebug(fmt, args...)
#endif
#define NVRAM_REG_SHUTDOWN_STATUS 0x0f
#define NVRAM_IBM_HD_DATA 0x12
+#define NVRAM_IDE_TRANSLATION 0x39
#define NVRAM_REG_FLOPPY_TYPE 0x10
#define NVRAM_REG_EQUIPMENT_BYTE 0x14
#define NVRAM_REG_BOOTSEQ_NEW_FIRST 0x3D
#define NVRAM_REG_BOOTSEQ_NEW_SECOND 0x38
+#define CHECKSUM_REGION_FIRST_BYTE 0x10
+#define CHECKSUM_REGION_LAST_BYTE 0x2d
+
struct nvram_internal {
nvram_state_t dev_state;
- uchar_t thereg;
- uchar_t mem_state[NVRAM_REG_MAX];
+ uint8_t thereg;
+ uint8_t mem_state[NVRAM_REG_MAX];
+ uint8_t reg_map[NVRAM_REG_MAX / 8];
+
+ struct vm_device * ide;
- uint_t us; //microseconds - for clock update - zeroed every second
- uint_t pus; //microseconds - for periodic interrupt - cleared every period
+ struct v3_vm_info * vm;
+
+ struct v3_timer *timer;
+
+ v3_lock_t nvram_lock;
+
+ uint64_t us; //microseconds - for clock update - zeroed every second
+ uint64_t pus; //microseconds - for periodic interrupt - cleared every period
};
struct rtc_stata {
- uint_t rate: 4; // clock rate = 65536Hz / 2 rate (0110=1024 Hz)
- uint_t basis: 3; // time base, 010 = 32,768 Hz
- uint_t uip: 1; // 1=update in progress
+ uint8_t rate : 4; // clock rate = 65536Hz / 2 rate (0110=1024 Hz)
+ uint8_t basis : 3; // time base, 010 = 32,768 Hz
+ uint8_t uip : 1; // 1=update in progress
} __attribute__((__packed__)) __attribute__((__aligned__ (1))) ;
struct rtc_statb {
- uint_t sum: 1; // 1=summer (daylight savings)
- uint_t h24: 1; // 1=24h clock
- uint_t dm: 1; // 1=date/time is in bcd, 0=binary
- uint_t rec: 1; // 1=rectangular signal
- uint_t ui: 1; // 1=update interrupt
- uint_t ai: 1; // 1=alarm interrupt
- uint_t pi: 1; // 1=periodic interrupt
- uint_t set: 1; // 1=blocked update
+ uint8_t sum : 1; // 1=summer (daylight savings)
+ uint8_t h24 : 1; // 1=24h clock
+ uint8_t dm : 1; // 0=date/time is in bcd, 1=binary
+ uint8_t rec : 1; // 1=rectangular signal
+ uint8_t ui : 1; // 1=update interrupt
+ uint8_t ai : 1; // 1=alarm interrupt
+ uint8_t pi : 1; // 1=periodic interrupt
+ uint8_t set : 1; // 1=blocked update
} __attribute__((__packed__)) __attribute__((__aligned__ (1))) ;
struct rtc_statc {
- uint_t res: 4; // reserved
- uint_t uf: 1; // 1=source of interrupt is update
- uint_t af: 1; // 1=source of interrupt is alarm interrupt
- uint_t pf: 1; // 1=source of interrupt is periodic interrupt
- uint_t irq: 1; // 1=interrupt requested
+ uint8_t res : 4; // reserved
+ uint8_t uf : 1; // 1=source of interrupt is update
+ uint8_t af : 1; // 1=source of interrupt is alarm interrupt
+ uint8_t pf : 1; // 1=source of interrupt is periodic interrupt
+ uint8_t irq : 1; // 1=interrupt requested
} __attribute__((__packed__)) __attribute__((__aligned__ (1))) ;
struct rtc_statd {
- uint_t res: 7; // reserved
- uint_t val: 1; // 1=cmos ram data is OK
+ uint8_t res : 7; // reserved
+ uint8_t val : 1; // 1=cmos ram data is OK
} __attribute__((__packed__)) __attribute__((__aligned__ (1))) ;
struct bcd_num {
- uchar_t bot : 4;
- uchar_t top : 4;
-};
+ uint8_t bot : 4;
+ uint8_t top : 4;
+} __attribute__((packed));;
-static uchar_t add_to(uchar_t * left, uchar_t * right, uchar_t bcd) {
- uchar_t temp;
+static void set_reg_num(struct nvram_internal * nvram, uint8_t reg_num) {
+ int major = (reg_num / 8);
+ int minor = reg_num % 8;
+
+ nvram->reg_map[major] |= (0x1 << minor);
+}
+
+static int is_reg_set(struct nvram_internal * nvram, uint8_t reg_num) {
+ int major = (reg_num / 8);
+ int minor = reg_num % 8;
+
+ return (nvram->reg_map[major] & (0x1 << minor)) ? 1 : 0;
+}
+
+
+static void set_memory(struct nvram_internal * nvram, uint8_t reg, uint8_t val) {
+ set_reg_num(nvram, reg);
+ nvram->mem_state[reg] = val;
+}
+
+static int get_memory(struct nvram_internal * nvram, uint8_t reg, uint8_t * val) {
+
+ if (!is_reg_set(nvram, reg)) {
+ *val = 0;
+ return -1;
+ }
+
+ *val = nvram->mem_state[reg];
+ return 0;
+}
+
+
+static uint8_t add_to(uint8_t * left, uint8_t * right, uint8_t bcd) {
+ uint8_t temp;
if (bcd) {
struct bcd_num * bl = (struct bcd_num *)left;
struct bcd_num * br = (struct bcd_num *)right;
- uchar_t carry = 0;
+ uint8_t carry = 0;
bl->bot += br->bot;
carry = bl->bot / 0xa;
}
-static uchar_t days_in_month(struct vm_device * dev, uchar_t month, uchar_t bcd) {
+static uint8_t days_in_month(uint8_t month, uint8_t bcd) {
// This completely ignores Julian / Gregorian stuff right now
if (bcd) {
}
-static void update_time(struct vm_device * dev, uint_t period_us) {
- struct nvram_internal * data = (struct nvram_internal *) (dev->private_data);
- struct rtc_stata * stata = (struct rtc_stata *) &((data->mem_state[NVRAM_REG_STAT_A]));
- struct rtc_statb * statb = (struct rtc_statb *) &((data->mem_state[NVRAM_REG_STAT_B]));
- struct rtc_statc * statc = (struct rtc_statc *) &((data->mem_state[NVRAM_REG_STAT_C]));
+static void update_time(struct nvram_internal * data, uint64_t period_us) {
+ struct rtc_stata * stata = (struct rtc_stata *)&((data->mem_state[NVRAM_REG_STAT_A]));
+ struct rtc_statb * statb = (struct rtc_statb *)&((data->mem_state[NVRAM_REG_STAT_B]));
+ struct rtc_statc * statc = (struct rtc_statc *)&((data->mem_state[NVRAM_REG_STAT_C]));
//struct rtc_statd *statd = (struct rtc_statd *) &((data->mem_state[NVRAM_REG_STAT_D]));
- uchar_t * sec = (uchar_t *) &(data->mem_state[NVRAM_REG_SEC]);
- uchar_t * min = (uchar_t *) &(data->mem_state[NVRAM_REG_MIN]);
- uchar_t * hour = (uchar_t *) &(data->mem_state[NVRAM_REG_HOUR]);
- uchar_t * weekday = (uchar_t *) &(data->mem_state[NVRAM_REG_WEEK_DAY]);
- uchar_t * monthday = (uchar_t *) &(data->mem_state[NVRAM_REG_MONTH_DAY]);
- uchar_t * month = (uchar_t *) &(data->mem_state[NVRAM_REG_MONTH]);
- uchar_t * year = (uchar_t *) &(data->mem_state[NVRAM_REG_YEAR]);
- uchar_t * cent = (uchar_t *) &(data->mem_state[NVRAM_REG_IBM_CENTURY_BYTE]);
- uchar_t * seca = (uchar_t *) &(data->mem_state[NVRAM_REG_SEC_ALARM]);
- uchar_t * mina = (uchar_t *) &(data->mem_state[NVRAM_REG_MIN_ALARM]);
- uchar_t * houra = (uchar_t *) &(data->mem_state[NVRAM_REG_HOUR_ALARM]);
- uchar_t hour24;
-
- uchar_t bcd = (statb->dm == 1);
- uchar_t carry = 0;
- uchar_t nextday = 0;
- uint_t periodic_period;
-
- //PrintDebug("nvram: sizeof(struct rtc_stata)=%d\n", sizeof(struct rtc_stata));
-
-
- //PrintDebug("nvram: update_time\n",statb->pi);
+ uint8_t * sec = (uint8_t *)&(data->mem_state[NVRAM_REG_SEC]);
+ uint8_t * min = (uint8_t *)&(data->mem_state[NVRAM_REG_MIN]);
+ uint8_t * hour = (uint8_t *)&(data->mem_state[NVRAM_REG_HOUR]);
+ uint8_t * weekday = (uint8_t *)&(data->mem_state[NVRAM_REG_WEEK_DAY]);
+ uint8_t * monthday = (uint8_t *)&(data->mem_state[NVRAM_REG_MONTH_DAY]);
+ uint8_t * month = (uint8_t *)&(data->mem_state[NVRAM_REG_MONTH]);
+ uint8_t * year = (uint8_t *)&(data->mem_state[NVRAM_REG_YEAR]);
+ uint8_t * cent = (uint8_t *)&(data->mem_state[NVRAM_REG_IBM_CENTURY_BYTE]);
+ uint8_t * cent_ps2 = (uint8_t *)&(data->mem_state[NVRAM_REG_IBM_PS2_CENTURY_BYTE]);
+ uint8_t * seca = (uint8_t *)&(data->mem_state[NVRAM_REG_SEC_ALARM]);
+ uint8_t * mina = (uint8_t *)&(data->mem_state[NVRAM_REG_MIN_ALARM]);
+ uint8_t * houra = (uint8_t *)&(data->mem_state[NVRAM_REG_HOUR_ALARM]);
+ uint8_t hour24;
+
+ uint8_t bcd = (statb->dm == 0);
+ uint8_t carry = 0;
+ uint8_t nextday = 0;
+ uint32_t periodic_period;
+
+ PrintDebug("nvram: update_time by %llu microseocnds\n",period_us);
// We will set these flags on exit
statc->irq = 0;
carry = add_to(sec, &carry, bcd);
if (carry) {
- PrintDebug("nvram: somehow managed to get a carry in second update\n");
+ PrintError("nvram: somehow managed to get a carry in second update\n");
}
if ( (bcd && (*sec == 0x60)) ||
carry = 1;
carry = add_to(min, &carry, bcd);
if (carry) {
- PrintDebug("nvram: somehow managed to get a carry in minute update\n");
+ PrintError("nvram: somehow managed to get a carry in minute update\n");
}
if ( (bcd && (*min == 0x60)) ||
if (hour24 & 0x80) {
hour24 &= 0x8f;
- uchar_t temp = ((bcd) ? 0x12 : 12);
+ uint8_t temp = ((bcd) ? 0x12 : 12);
add_to(&hour24, &temp, bcd);
}
}
carry = 1;
carry = add_to(&hour24, &carry, bcd);
if (carry) {
- PrintDebug("nvram: somehow managed to get a carry in hour update\n");
+ PrintError("nvram: somehow managed to get a carry in hour update\n");
}
if ( (bcd && (hour24 == 0x24)) ||
*weekday %= 0x7; // same regardless of bcd
- if ((*monthday) != days_in_month(dev, *month, bcd)) {
+ if ((*monthday) != days_in_month(*month, bcd)) {
add_to(monthday, &carry, bcd);
} else {
*monthday = 0x1;
*year = 0;
carry = 1;
add_to(cent, &carry, bcd);
+ *cent_ps2 = *cent;
}
}
}
statc->irq = (statc->pf || statc->af || statc->uf);
- //PrintDebug("nvram: time is now: YMDHMS: 0x%x:0x%x:0x%x:0x%x:0x%x,0x%x bcd=%d\n", *year, *month, *monthday, *hour, *min, *sec,bcd);
+ PrintDebug("nvram: time is now: YMDHMS: 0x%x:0x%x:0x%x:0x%x:0x%x,0x%x bcd=%d\n", *year, *month, *monthday, *hour, *min, *sec,bcd);
// Interrupt associated VM, if needed
if (statc->irq) {
PrintDebug("nvram: injecting interrupt\n");
- v3_raise_irq(dev->vm, NVRAM_RTC_IRQ);
+ v3_raise_irq(data->vm, NVRAM_RTC_IRQ);
}
}
-static int handle_timer_event(struct guest_info * info,
- struct v3_timer_event * evt,
- void * priv_data) {
+static void nvram_update_timer(struct guest_info *vm,
+ ullong_t cpu_cycles,
+ ullong_t cpu_freq,
+ void *priv_data)
+{
+ struct nvram_internal *nvram_state = (struct nvram_internal *)priv_data;
+ uint64_t period_us;
- struct vm_device * dev = (struct vm_device *)priv_data;
+
+ // cpu freq in khz
+ period_us = (1000*cpu_cycles/cpu_freq);
- if (dev) {
- update_time(dev, evt->period_us);
- }
-
- return 0;
-}
+ update_time(nvram_state,period_us);
+}
static void set_memory_size(struct nvram_internal * nvram, addr_t bytes) {
// 1. Conventional Mem: 0-640k in K
// 2. Extended Mem: 0-16MB in K
// 3. Big Mem: 0-4G in 64K
+ uint16_t memk;
+ uint16_t mem_chunks;
+ // at most 640K of conventional memory
if (bytes > 640 * 1024) {
- nvram->mem_state[NVRAM_REG_BASE_MEMORY_HIGH] = 0x02;
- nvram->mem_state[NVRAM_REG_BASE_MEMORY_LOW] = 0x80;
+ memk=640;
} else {
- uint16_t memk = bytes * 1024;
- nvram->mem_state[NVRAM_REG_BASE_MEMORY_HIGH] = (memk >> 8) & 0x00ff;
- nvram->mem_state[NVRAM_REG_BASE_MEMORY_LOW] = memk & 0x00ff;
+ memk = bytes/1024;
+ }
- return;
+ set_memory(nvram, NVRAM_REG_BASE_MEMORY_HIGH, (memk >> 8) & 0x00ff);
+ set_memory(nvram, NVRAM_REG_BASE_MEMORY_LOW, memk & 0x00ff);
+
+ // set extended memory - first 1 MB is lost to 640K chunk
+ // extended memory is min(0MB, bytes-1MB)
+ if (bytes < 1024*1024) {
+ // no extended memory
+ memk = 0;
+ } else {
+ memk = (bytes - 1024 * 1024 ) / 1024;
}
- if (bytes > (16 * 1024 * 1024)) {
- // Set extended memory to 15 MB
- nvram->mem_state[NVRAM_REG_EXT_MEMORY_HIGH] = 0x3C;
- nvram->mem_state[NVRAM_REG_EXT_MEMORY_LOW] = 0x00;
- nvram->mem_state[NVRAM_REG_EXT_MEMORY_2ND_HIGH]= 0x3C;
- nvram->mem_state[NVRAM_REG_EXT_MEMORY_2ND_LOW]= 0x00;
+ set_memory(nvram, NVRAM_REG_EXT_MEMORY_HIGH, (memk >> 8) & 0x00ff);
+ set_memory(nvram, NVRAM_REG_EXT_MEMORY_LOW, memk & 0x00ff);
+ set_memory(nvram, NVRAM_REG_EXT_MEMORY_2ND_HIGH, (memk >> 8) & 0x00ff);
+ set_memory(nvram, NVRAM_REG_EXT_MEMORY_2ND_LOW, memk & 0x00ff);
+
+ // Set the extended memory beyond 16 MB in 64k chunks
+ // this is min(0, bytes-16MB)
+ if (bytes<(1024*1024*16)) {
+ mem_chunks=0;
} else {
- uint16_t memk = bytes * 1024;
- nvram->mem_state[NVRAM_REG_EXT_MEMORY_HIGH] = (memk >> 8) & 0x00ff;
- nvram->mem_state[NVRAM_REG_EXT_MEMORY_LOW] = memk & 0x00ff;
- nvram->mem_state[NVRAM_REG_EXT_MEMORY_2ND_HIGH]= (memk >> 8) & 0x00ff;
- nvram->mem_state[NVRAM_REG_EXT_MEMORY_2ND_LOW]= memk & 0x00ff;
+ mem_chunks = (bytes - (1024 * 1024 * 16)) / (1024 * 64);
+ }
+
+ set_memory(nvram, NVRAM_REG_AMI_BIG_MEMORY_HIGH, (mem_chunks >> 8) & 0x00ff);
+ set_memory(nvram, NVRAM_REG_AMI_BIG_MEMORY_LOW, mem_chunks & 0x00ff);
+
+ return;
+}
+
+
+
+static void init_harddrives(struct nvram_internal * nvram) {
+ uint8_t hd_data = 0;
+ uint32_t cyls;
+ uint32_t sects;
+ uint32_t heads;
+ int i = 0;
+ int info_base_reg = 0x1b;
+ int type_reg = 0x19;
+
+ // 0x19 == first drive type
+ // 0x1a == second drive type
+
+ // 0x1b == first drive geometry base
+ // 0x24 == second drive geometry base
- return;
+ // It looks like the BIOS only tracks the disks on the first channel at 0x12?
+ for (i = 0; i < 2; i++) {
+ if (v3_ide_get_geometry(nvram->ide->private_data, 0, i, &cyls, &heads, §s) == 0) {
+
+ int info_reg = info_base_reg + (i * 9);
+
+ set_memory(nvram, type_reg + i, 0x2f);
+
+ set_memory(nvram, info_reg, cyls & 0xff);
+ set_memory(nvram, info_reg + 1, (cyls >> 8) & 0xff);
+ set_memory(nvram, info_reg + 2, heads & 0xff);
+
+ // Write precomp cylinder (1 and 2)
+ set_memory(nvram, info_reg + 3, 0xff);
+ set_memory(nvram, info_reg + 4, 0xff);
+
+ // harddrive control byte
+ set_memory(nvram, info_reg + 5, 0xc0 | ((heads > 8) << 3));
+
+ set_memory(nvram, info_reg + 6, cyls & 0xff);
+ set_memory(nvram, info_reg + 7, (cyls >> 8) & 0xff);
+
+ set_memory(nvram, info_reg + 8, sects & 0xff);
+
+ hd_data |= (0xf0 >> (i * 4));
+ }
}
+ set_memory(nvram, NVRAM_IBM_HD_DATA, hd_data);
+
{
- // Set the extended memory beyond 16 MB in 64k chunks
- uint16_t mem_chunks = (bytes - (1024 * 1024 * 16)) / (1024 * 64);
- nvram->mem_state[NVRAM_REG_AMI_BIG_MEMORY_HIGH] = (mem_chunks >> 8) & 0x00ff;
- nvram->mem_state[NVRAM_REG_AMI_BIG_MEMORY_LOW] = mem_chunks & 0x00ff;
+#define TRANSLATE_NONE 0x0
+#define TRANSLATE_LBA 0x1
+#define TRANSLATE_LARGE 0x2
+#define TRANSLATE_RECHS 0x3
+ // We're going to do LBA translation for everything...
+ uint8_t trans = 0;
+
+ for (i = 0; i < 4; i++) {
+ int chan_num = i / 2;
+ int drive_num = i % 2;
+ uint32_t tmp[3];
+
+ if (v3_ide_get_geometry(nvram->ide->private_data, chan_num, drive_num, &tmp[0], &tmp[1], &tmp[2]) == 0) {
+ trans |= TRANSLATE_LBA << (i * 2);
+ }
+ }
+
+ set_memory(nvram, NVRAM_IDE_TRANSLATION, trans);
}
+}
- return;
+static uint16_t compute_checksum(struct nvram_internal * nvram) {
+ uint16_t checksum = 0;
+ uint8_t reg = 0;
+ uint8_t val = 0;
+
+ /* add all fields between the RTC and the checksum fields */
+ for (reg = CHECKSUM_REGION_FIRST_BYTE; reg < CHECKSUM_REGION_LAST_BYTE; reg++) {
+ /* unset fields are considered zero so get_memory can be ignored */
+ get_memory(nvram, reg, &val);
+ checksum += val;
+ }
+
+ return checksum;
}
-static int init_nvram_state(struct vm_device * dev) {
- struct guest_info * info = dev->vm;
- struct nvram_internal * nvram_state = (struct nvram_internal *)dev->private_data;
-
- memset(nvram_state->mem_state, 0, NVRAM_REG_MAX);
+static int init_nvram_state(struct v3_vm_info * vm, struct nvram_internal * nvram) {
+ uint16_t checksum = 0;
+
+ memset(nvram->mem_state, 0, NVRAM_REG_MAX);
+ memset(nvram->reg_map, 0, NVRAM_REG_MAX / 8);
+
+ v3_lock_init(&(nvram->nvram_lock));
//
// 2 1.44 MB floppy drives
//
#if 1
- nvram_state->mem_state[NVRAM_REG_FLOPPY_TYPE] = 0x44;
+ set_memory(nvram, NVRAM_REG_FLOPPY_TYPE, 0x44);
#else
- nvram_state->mem_state[NVRAM_REG_FLOPPY_TYPE] = 0x00;
+ set_memory(nvram, NVRAM_REG_FLOPPY_TYPE, 0x00);
#endif
//
// For old boot sequence style, do floppy first
//
- nvram_state->mem_state[NVRAM_REG_BOOTSEQ_OLD] = 0x10;
+ set_memory(nvram, NVRAM_REG_BOOTSEQ_OLD, 0x10);
#if 0
// For new boot sequence style, do floppy, cd, then hd
- nvram_state->mem_state[NVRAM_REG_BOOTSEQ_NEW_FIRST] = 0x31;
- nvram_state->mem_state[NVRAM_REG_BOOTSEQ_NEW_SECOND] = 0x20;
+ set_memory(nvram, NVRAM_REG_BOOTSEQ_NEW_FIRST, 0x31);
+ set_memory(nvram, NVRAM_REG_BOOTSEQ_NEW_SECOND, 0x20);
#endif
// For new boot sequence style, do cd, hd, floppy
- nvram_state->mem_state[NVRAM_REG_BOOTSEQ_NEW_FIRST] = 0x23;
- nvram_state->mem_state[NVRAM_REG_BOOTSEQ_NEW_SECOND] = 0x10;
+ set_memory(nvram, NVRAM_REG_BOOTSEQ_NEW_FIRST, 0x23);
+ set_memory(nvram, NVRAM_REG_BOOTSEQ_NEW_SECOND, 0x10);
// Set equipment byte to note 2 floppies, vga display, keyboard,math,floppy
- nvram_state->mem_state[NVRAM_REG_EQUIPMENT_BYTE] = 0x4f;
- // nvram_state->mem_state[NVRAM_REG_EQUIPMENT_BYTE] = 0xf;
+ set_memory(nvram, NVRAM_REG_EQUIPMENT_BYTE, 0x4f);
+ // set_memory(nvram, NVRAM_REG_EQUIPMENT_BYTE, 0xf);
- // This is the harddisk type.... Set accordingly...
- nvram_state->mem_state[NVRAM_IBM_HD_DATA] = 0x20;
-
// Set the shutdown status gently
// soft reset
- nvram_state->mem_state[NVRAM_REG_SHUTDOWN_STATUS] = 0x0;
+ set_memory(nvram, NVRAM_REG_SHUTDOWN_STATUS, 0x0);
// RTC status A
// 00100110 = no update in progress, base=32768 Hz, rate = 1024 Hz
- nvram_state->mem_state[NVRAM_REG_STAT_A] = 0x26;
+ set_memory(nvram, NVRAM_REG_STAT_A, 0x26);
// RTC status B
- // 00000100 = not setting, no interrupts, blocked rect signal, bcd mode, 24 hour, normal time
- nvram_state->mem_state[NVRAM_REG_STAT_B] = 0x06;
+ // 00000010 = not setting, no interrupts, blocked rect signal, bcd mode (bit 3 = 0), 24 hour, normal time
+ set_memory(nvram, NVRAM_REG_STAT_B, 0x02);
// RTC status C
// No IRQ requested, result not do to any source
- nvram_state->mem_state[NVRAM_REG_STAT_C] = 0x00;
+ set_memory(nvram, NVRAM_REG_STAT_C, 0x00);
// RTC status D
// Battery is OK
- nvram_state->mem_state[NVRAM_REG_STAT_D] = 0x80;
+ set_memory(nvram, NVRAM_REG_STAT_D, 0x80);
// january 1, 2008, 00:00:00
- nvram_state->mem_state[NVRAM_REG_MONTH] = 0x1;
- nvram_state->mem_state[NVRAM_REG_MONTH_DAY] = 0x1;
- nvram_state->mem_state[NVRAM_REG_WEEK_DAY] = 0x1;
- nvram_state->mem_state[NVRAM_REG_YEAR] = 0x08;
-
- nvram_state->us = 0;
- nvram_state->pus = 0;
+ set_memory(nvram, NVRAM_REG_SEC, 0x00);
+ set_memory(nvram, NVRAM_REG_SEC_ALARM, 0x00);
+ set_memory(nvram, NVRAM_REG_MIN, 0x00);
+ set_memory(nvram, NVRAM_REG_MIN_ALARM, 0x00);
+ set_memory(nvram, NVRAM_REG_HOUR, 0x00);
+ set_memory(nvram, NVRAM_REG_HOUR_ALARM, 0x00);
+
+ set_memory(nvram, NVRAM_REG_MONTH, 0x01);
+ set_memory(nvram, NVRAM_REG_MONTH_DAY, 0x1);
+ set_memory(nvram, NVRAM_REG_WEEK_DAY, 0x1);
+ set_memory(nvram, NVRAM_REG_YEAR, 0x08);
+ set_memory(nvram, NVRAM_REG_IBM_CENTURY_BYTE, 0x20);
+ set_memory(nvram, NVRAM_REG_IBM_PS2_CENTURY_BYTE, 0x20);
+
+ set_memory(nvram, NVRAM_REG_DIAGNOSTIC_STATUS, 0x00);
+
+ nvram->us = 0;
+ nvram->pus = 0;
- set_memory_size(nvram_state, info->mem_size);
+ set_memory_size(nvram, vm->mem_size);
+ init_harddrives(nvram);
+
+ /* compute checksum (must follow all assignments here) */
+ checksum = compute_checksum(nvram);
+ set_memory(nvram, NVRAM_REG_CSUM_HIGH, (checksum >> 8) & 0xff);
+ set_memory(nvram, NVRAM_REG_CSUM_LOW, checksum & 0xff);
- nvram_state->dev_state = NVRAM_READY;
- nvram_state->thereg = 0;
+
+
+ nvram->dev_state = NVRAM_READY;
+ nvram->thereg = 0;
return 0;
}
-static int nvram_reset_device(struct vm_device * dev) {
-
- return 0;
-}
-
+static int nvram_write_reg_port(struct guest_info * core, uint16_t port,
+ void * src, uint_t length, void * priv_data) {
+ uint8_t reg;
+ struct nvram_internal * data = priv_data;
+ memcpy(®,src,1);
-static int nvram_start_device(struct vm_device * dev) {
- PrintDebug("nvram: start device\n");
- return 0;
-}
-
+ data->thereg = reg & 0x7f; //discard NMI bit if it's there
+
+ PrintDebug("nvram: Writing To NVRAM reg: 0x%x (NMI_disable=%d)\n", data->thereg,reg>>7);
-static int nvram_stop_device(struct vm_device * dev) {
- PrintDebug("nvram: stop device\n");
- return 0;
+ return 1;
}
+static int nvram_read_data_port(struct guest_info * core, uint16_t port,
+ void * dst, uint_t length, void * priv_data) {
+ struct nvram_internal * data = priv_data;
+ addr_t irq_state = v3_lock_irqsave(data->nvram_lock);
-static int nvram_write_reg_port(ushort_t port,
- void * src,
- uint_t length,
- struct vm_device * dev) {
- struct nvram_internal * data = (struct nvram_internal *)dev->private_data;
-
- memcpy(&(data->thereg), src, 1);
- PrintDebug("Writing To NVRAM reg: 0x%x\n", data->thereg);
+ if (get_memory(data, data->thereg, (uint8_t *)dst) == -1) {
+ PrintError("nvram: Register %d (0x%x) Not set - POSSIBLE BUG IN MACHINE INIT - CONTINUING\n", data->thereg, data->thereg);
+ }
- return 1;
-}
-
-static int nvram_read_data_port(ushort_t port,
- void * dst,
- uint_t length,
- struct vm_device * dev) {
- struct nvram_internal * data = (struct nvram_internal *)dev->private_data;
-
- memcpy(dst, &(data->mem_state[data->thereg]), 1);
-
- PrintDebug("nvram_read_data_port(0x%x)=0x%x\n", data->thereg, data->mem_state[data->thereg]);
+ PrintDebug("nvram: nvram_read_data_port(0x%x) = 0x%x\n", data->thereg, *(uint8_t *)dst);
// hack
if (data->thereg == NVRAM_REG_STAT_A) {
data->mem_state[data->thereg] ^= 0x80; // toggle Update in progess
}
+ v3_unlock_irqrestore(data->nvram_lock, irq_state);
return 1;
}
-static int nvram_write_data_port(ushort_t port,
- void * src,
- uint_t length,
- struct vm_device * dev) {
- struct nvram_internal * data = (struct nvram_internal *)dev->private_data;
- memcpy(&(data->mem_state[data->thereg]), src, 1);
+static int nvram_write_data_port(struct guest_info * core, uint16_t port,
+ void * src, uint_t length, void * priv_data) {
- PrintDebug("nvram_write_data_port(0x%x)=0x%x\n", data->thereg, data->mem_state[data->thereg]);
+ struct nvram_internal * data = priv_data;
- return 1;
-}
+ addr_t irq_state = v3_lock_irqsave(data->nvram_lock);
+ set_memory(data, data->thereg, *(uint8_t *)src);
+ v3_unlock_irqrestore(data->nvram_lock, irq_state);
-static int nvram_init_device(struct vm_device * dev) {
- PrintDebug("nvram: init_device\n");
+ PrintDebug("nvram: nvram_write_data_port(0x%x) = 0x%x\n",
+ data->thereg, data->mem_state[data->thereg]);
- init_nvram_state(dev);
+ return 1;
+}
- // hook ports
- v3_dev_hook_io(dev, NVRAM_REG_PORT, NULL, &nvram_write_reg_port);
- v3_dev_hook_io(dev, NVRAM_DATA_PORT, &nvram_read_data_port, &nvram_write_data_port);
-
- v3_hook_host_event(dev->vm, HOST_TIMER_EVT, V3_HOST_EVENT_HANDLER(handle_timer_event), dev);
- return 0;
-}
-static int nvram_deinit_device(struct vm_device * dev) {
- v3_dev_unhook_io(dev, NVRAM_REG_PORT);
- v3_dev_unhook_io(dev, NVRAM_DATA_PORT);
- nvram_reset_device(dev);
+static int nvram_free(struct nvram_internal * nvram_state) {
+
+ // unregister host events
+ struct guest_info *info = &(nvram_state->vm->cores[0]);
+
+ if (nvram_state->timer) {
+ v3_remove_timer(info,nvram_state->timer);
+ }
+
+ V3_Free(nvram_state);
return 0;
}
+static struct v3_timer_ops timer_ops = {
+ .update_timer = nvram_update_timer,
+};
-static struct vm_device_ops dev_ops = {
- .init = nvram_init_device,
- .deinit = nvram_deinit_device,
- .reset = nvram_reset_device,
- .start = nvram_start_device,
- .stop = nvram_stop_device,
+static struct v3_device_ops dev_ops = {
+ .free = (int (*)(void *))nvram_free,
};
-struct vm_device * v3_create_nvram() {
+
+static int nvram_init(struct v3_vm_info * vm, v3_cfg_tree_t * cfg) {
struct nvram_internal * nvram_state = NULL;
+ struct vm_device * ide = v3_find_dev(vm, v3_cfg_val(cfg, "storage"));
+ char * dev_id = v3_cfg_val(cfg, "ID");
+ int ret = 0;
+
+ if (!ide) {
+ PrintError("nvram: Could not find IDE device\n");
+ return -1;
+ }
+ PrintDebug("nvram: init_device\n");
nvram_state = (struct nvram_internal *)V3_Malloc(sizeof(struct nvram_internal) + 1000);
PrintDebug("nvram: internal at %p\n", (void *)nvram_state);
- struct vm_device * device = v3_create_device("NVRAM", &dev_ops, nvram_state);
+ nvram_state->ide = ide;
+ nvram_state->vm = vm;
+
+ struct vm_device * dev = v3_add_device(vm, dev_id, &dev_ops, nvram_state);
+
+ if (dev == NULL) {
+ PrintError("nvram: Could not attach device %s\n", dev_id);
+ V3_Free(nvram_state);
+ return -1;
+ }
+
+ init_nvram_state(vm, nvram_state);
+
+ // hook ports
+ ret |= v3_dev_hook_io(dev, NVRAM_REG_PORT, NULL, &nvram_write_reg_port);
+ ret |= v3_dev_hook_io(dev, NVRAM_DATA_PORT, &nvram_read_data_port, &nvram_write_data_port);
+
+ if (ret != 0) {
+ PrintError("nvram: Error hooking NVRAM IO ports\n");
+ v3_remove_device(dev);
+ return -1;
+ }
+
+ nvram_state->timer = v3_add_timer(&(vm->cores[0]),&timer_ops,nvram_state);
- return device;
+ if (nvram_state->timer == NULL ) {
+ v3_remove_device(dev);
+ return -1;
+ }
+
+ return 0;
}
+
+device_register("NVRAM", nvram_init)