X-Git-Url: http://v3vee.org/palacios/gitweb/gitweb.cgi?a=blobdiff_plain;f=palacios%2Fsrc%2Fdevices%2Fnvram.c;h=1244f90355af20ad5159f61033dfb2c3d0cc197a;hb=4bc3ee757b44d3e466fd89e348106c47fa5511ee;hp=e811ec271d487afdfb1d80f2db275cfb764e72d3;hpb=570ad6257ed18fbbc840c17a600f12f2dc44b010;p=palacios.git diff --git a/palacios/src/devices/nvram.c b/palacios/src/devices/nvram.c index e811ec2..1244f90 100644 --- a/palacios/src/devices/nvram.c +++ b/palacios/src/devices/nvram.c @@ -1,13 +1,38 @@ +/* + * This file is part of the Palacios Virtual Machine Monitor developed + * by the V3VEE Project with funding from the United States National + * Science Foundation and the Department of Energy. + * + * The V3VEE Project is a joint project between Northwestern University + * and the University of New Mexico. You can find out more at + * http://www.v3vee.org + * + * Copyright (c) 2008, Peter Dinda + * Copyright (c) 2008, The V3VEE Project + * All rights reserved. + * + * Author: Peter Dinda + * + * This is free software. You are permitted to use, + * redistribute, and modify it as specified in the file "V3VEE_LICENSE". + */ + + #include #include #include -extern struct vmm_os_hooks *os_hooks; + +#ifndef DEBUG_NVRAM +#undef PrintDebug +#define PrintDebug(fmt, args...) +#endif #define NVRAM_REG_PORT 0x70 #define NVRAM_DATA_PORT 0x71 +#define NVRAM_RTC_IRQ 0x8 typedef enum {NVRAM_READY, NVRAM_REG_POSTED} nvram_state_t; @@ -17,7 +42,7 @@ typedef enum {NVRAM_READY, NVRAM_REG_POSTED} nvram_state_t; // These are borrowed from Bochs, which borrowed from -// Ralf Brown's interupt list +// Ralf Brown's interupt list, and extended #define NVRAM_REG_SEC 0x00 #define NVRAM_REG_SEC_ALARM 0x01 #define NVRAM_REG_MIN 0x02 @@ -34,115 +59,589 @@ typedef enum {NVRAM_READY, NVRAM_REG_POSTED} nvram_state_t; #define NVRAM_REG_STAT_D 0x0d #define NVRAM_REG_DIAGNOSTIC_STATUS 0x0e #define NVRAM_REG_SHUTDOWN_STATUS 0x0f + +#define NVRAM_IBM_HD_DATA 0x12 + +#define NVRAM_REG_FLOPPY_TYPE 0x10 #define NVRAM_REG_EQUIPMENT_BYTE 0x14 + +#define NVRAM_REG_BASE_MEMORY_HIGH 0x16 +#define NVRAM_REG_BASE_MEMORY_LOW 0x15 + +#define NVRAM_REG_EXT_MEMORY_HIGH 0x18 +#define NVRAM_REG_EXT_MEMORY_LOW 0x17 + +#define NVRAM_REG_EXT_MEMORY_2ND_HIGH 0x31 +#define NVRAM_REG_EXT_MEMORY_2ND_LOW 0x30 + +#define NVRAM_REG_BOOTSEQ_OLD 0x2d + +#define NVRAM_REG_AMI_BIG_MEMORY_HIGH 0x35 +#define NVRAM_REG_AMI_BIG_MEMORY_LOW 0x34 + #define NVRAM_REG_CSUM_HIGH 0x2e #define NVRAM_REG_CSUM_LOW 0x2f #define NVRAM_REG_IBM_CENTURY_BYTE 0x32 #define NVRAM_REG_IBM_PS2_CENTURY_BYTE 0x37 +#define NVRAM_REG_BOOTSEQ_NEW_FIRST 0x3D +#define NVRAM_REG_BOOTSEQ_NEW_SECOND 0x38 struct nvram_internal { - nvram_state_t dev_state; - uchar_t thereg; - uchar_t mem_state[NVRAM_REG_MAX]; + nvram_state_t dev_state; + uchar_t thereg; + uchar_t mem_state[NVRAM_REG_MAX]; + + uint_t us; //microseconds - for clock update - zeroed every second + uint_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 +} __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 +} __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 +} __attribute__((__packed__)) __attribute__((__aligned__ (1))) ; + +struct rtc_statd { + uint_t res: 7; // reserved + uint_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; +}; + + + +static uchar_t add_to(uchar_t * left, uchar_t * right, uchar_t bcd) { + uchar_t temp; + + if (bcd) { + struct bcd_num * bl = (struct bcd_num *)left; + struct bcd_num * br = (struct bcd_num *)right; + uchar_t carry = 0; + + bl->bot += br->bot; + carry = bl->bot / 0xa; + bl->bot %= 0xa; + + bl->top += carry + br->top; + carry = bl->top / 0xa; + bl->top %= 0xa; + + return carry; + } else { + temp = *left; + *left += *right; + + if (*left < temp) { + return 1; + } else { + return 0; + } + } +} + + +static uchar_t days_in_month(struct vm_device * dev, uchar_t month, uchar_t bcd) { + // This completely ignores Julian / Gregorian stuff right now + + if (bcd) { + + switch (month) + { + case 0x1: //jan + case 0x3: //march + case 0x5: //may + case 0x7: //july + case 0x8: //aug + case 0x10: //oct + case 0x12: //dec + return 0x31; + break; + case 0x4: //april + case 0x6: //june + case 0x9: //sept + case 0x11: //nov + return 0x30; + break; + case 0x2: //feb + return 0x28; + break; + default: + return 0x30; + } + + } else { + + switch (month) + { + case 1: //jan + case 3: //march + case 5: //may + case 7: //july + case 8: //aug + case 10: //oct + case 12: //dec + return 31; + break; + case 4: //april + case 6: //june + case 9: //sept + case 11: //nov + return 30; + break; + case 2: //feb + return 28; + break; + default: + return 30; + } + } +} + + +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])); + //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); + + // We will set these flags on exit + statc->irq = 0; + statc->pf = 0; + statc->af = 0; + statc->uf = 0; + + // We will reset us after one second + data->us += period_us; + // We will reset pus after one periodic_period + data->pus += period_us; + + if (data->us > 1000000) { + carry = 1; + carry = add_to(sec, &carry, bcd); + + if (carry) { + PrintDebug("nvram: somehow managed to get a carry in second update\n"); + } + + if ( (bcd && (*sec == 0x60)) || + ((!bcd) && (*sec == 60))) { + + *sec = 0; + + carry = 1; + carry = add_to(min, &carry, bcd); + if (carry) { + PrintDebug("nvram: somehow managed to get a carry in minute update\n"); + } + + if ( (bcd && (*min == 0x60)) || + ((!bcd) && (*min == 60))) { + + *min = 0; + hour24 = *hour; + + if (!(statb->h24)) { + + if (hour24 & 0x80) { + hour24 &= 0x8f; + uchar_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"); + } + + if ( (bcd && (hour24 == 0x24)) || + ((!bcd) && (hour24 == 24))) { + carry = 1; + nextday = 1; + hour24 = 0; + } else { + carry = 0; + } + + + if (statb->h24) { + *hour = hour24; + } else { + if ( (bcd && (hour24 < 0x12)) || + ((!bcd) && (hour24 < 12))) { + *hour = hour24; + + } else { + + if (!bcd) { + *hour = (hour24 - 12) | 0x80; + } else { + *hour = hour24; + struct bcd_num * n = (struct bcd_num *)hour; + + if (n->bot < 0x2) { + n->top--; + n->bot += 0xa; + } + + n->bot -= 0x2; + n->top -= 0x1; + } + } + } + + // now see if we need to carry into the days and further + if (nextday) { + carry = 1; + add_to(weekday, &carry, bcd); + + *weekday %= 0x7; // same regardless of bcd + + if ((*monthday) != days_in_month(dev, *month, bcd)) { + add_to(monthday, &carry, bcd); + } else { + *monthday = 0x1; + + carry = 1; + add_to(month, &carry, bcd); + + if ( (bcd && (*month == 0x13)) || + ((!bcd) && (*month == 13))) { + *month = 1; // same for both + + carry = 1; + carry = add_to(year, &carry, bcd); + + if ( (bcd && carry) || + ((!bcd) && (*year == 100))) { + *year = 0; + carry = 1; + add_to(cent, &carry, bcd); + } + } + } + } + } + } + + + data->us -= 1000000; + // OK, now check for the alarm, if it is set to interrupt + if (statb->ai) { + if ((*sec == *seca) && (*min == *mina) && (*hour == *houra)) { + statc->af = 1; + PrintDebug("nvram: interrupt on alarm\n"); + } + } + } + + if (statb->pi) { + periodic_period = 1000000 / (65536 / (0x1 << stata->rate)); + if (data->pus >= periodic_period) { + statc->pf = 1; + data->pus -= periodic_period; + PrintDebug("nvram: interrupt on periodic\n"); + } + } + + if (statb->ui) { + statc->uf = 1; + PrintDebug("nvram: interrupt on update\n"); + } + + 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); + + // Interrupt associated VM, if needed + if (statc->irq) { + PrintDebug("nvram: injecting interrupt\n"); + v3_raise_irq(dev->vm, NVRAM_RTC_IRQ); + } +} + + +static int handle_timer_event(struct guest_info * info, + struct v3_timer_event * evt, + void * priv_data) { + + struct vm_device * dev = (struct vm_device *)priv_data; + + if (dev) { + update_time(dev, evt->period_us); + } + + return 0; +} + +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 + + if (bytes > 640 * 1024) { + nvram->mem_state[NVRAM_REG_BASE_MEMORY_HIGH] = 0x02; + nvram->mem_state[NVRAM_REG_BASE_MEMORY_LOW] = 0x80; + } 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; + + return; + } + + 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; + } 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; + + return; + } + + { + // 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; + } + + return; +} -int nvram_reset_device(struct vm_device * dev) -{ - struct nvram_internal *data = (struct nvram_internal *) dev->private_data; +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); + + // + // 2 1.44 MB floppy drives + // +#if 1 + nvram_state->mem_state[NVRAM_REG_FLOPPY_TYPE] = 0x44; +#else + nvram_state->mem_state[NVRAM_REG_FLOPPY_TYPE] = 0x00; +#endif + + // + // For old boot sequence style, do floppy first + // + nvram_state->mem_state[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; +#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; + - data->dev_state = NVRAM_READY; - data->thereg=0; + // 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; - return 0; + // 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; + + + // RTC status A + // 00100110 = no update in progress, base=32768 Hz, rate = 1024 Hz + nvram_state->mem_state[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; + + + // RTC status C + // No IRQ requested, result not do to any source + nvram_state->mem_state[NVRAM_REG_STAT_C] = 0x00; + + // RTC status D + // Battery is OK + nvram_state->mem_state[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_size(nvram_state, info->mem_size); + + nvram_state->dev_state = NVRAM_READY; + nvram_state->thereg = 0; + + return 0; +} + + + + +static int nvram_reset_device(struct vm_device * dev) { + + return 0; } -int nvram_start_device(struct vm_device *dev) -{ - return 0; +static int nvram_start_device(struct vm_device * dev) { + PrintDebug("nvram: start device\n"); + return 0; } -int nvram_stop_device(struct vm_device *dev) -{ - return 0; +static int nvram_stop_device(struct vm_device * dev) { + PrintDebug("nvram: stop device\n"); + return 0; } -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; +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); - memcpy(&(data->thereg), src, 1); - return 0; + 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; -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); - 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]); - return 0; + // hack + if (data->thereg == NVRAM_REG_STAT_A) { + data->mem_state[data->thereg] ^= 0x80; // toggle Update in progess + } + + + return 1; } -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; +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); - memcpy(&(data->mem_state[data->thereg]), src, 1); + PrintDebug("nvram_write_data_port(0x%x)=0x%x\n", data->thereg, data->mem_state[data->thereg]); - return 0; + return 1; } -int nvram_init_device(struct vm_device * dev) { - struct nvram_internal *data = (struct nvram_internal *) dev->private_data; - - memset(data->mem_state, 0, NVRAM_REG_MAX); +static int nvram_init_device(struct vm_device * dev) { + PrintDebug("nvram: init_device\n"); - nvram_reset_device(dev); + init_nvram_state(dev); - // hook ports - dev_hook_io(dev, NVRAM_REG_PORT, NULL, &nvram_write_reg_port); - dev_hook_io(dev, NVRAM_DATA_PORT, &nvram_read_data_port, &nvram_write_data_port); + // 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); - return 0; -} - -int nvram_deinit_device(struct vm_device *dev) -{ + v3_hook_host_event(dev->vm, HOST_TIMER_EVT, V3_HOST_EVENT_HANDLER(handle_timer_event), dev); + return 0; +} - dev_unhook_io(dev, NVRAM_REG_PORT); - dev_unhook_io(dev, NVRAM_DATA_PORT); +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); - return 0; + nvram_reset_device(dev); + return 0; } @@ -150,19 +649,24 @@ int nvram_deinit_device(struct vm_device *dev) 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, + .init = nvram_init_device, + .deinit = nvram_deinit_device, + .reset = nvram_reset_device, + .start = nvram_start_device, + .stop = nvram_stop_device, }; -struct vm_device *nvram_create() { - struct nvram_internal * nvram_state = os_hooks->malloc(sizeof(struct nvram_internal)); - struct vm_device *device = create_device("NVRAM", &dev_ops, nvram_state); +struct vm_device * v3_create_nvram() { + struct nvram_internal * nvram_state = NULL; + + 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); - return device; + return device; }