xemu/hw/mips/mips_malta.c

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/*
* QEMU Malta board support
*
* Copyright (c) 2006 Aurelien Jarno
*
* Permission is hereby granted, free of charge, to any person obtaining a copy
* of this software and associated documentation files (the "Software"), to deal
* in the Software without restriction, including without limitation the rights
* to use, copy, modify, merge, publish, distribute, sublicense, and/or sell
* copies of the Software, and to permit persons to whom the Software is
* furnished to do so, subject to the following conditions:
*
* The above copyright notice and this permission notice shall be included in
* all copies or substantial portions of the Software.
*
* THE SOFTWARE IS PROVIDED "AS IS", WITHOUT WARRANTY OF ANY KIND, EXPRESS OR
* IMPLIED, INCLUDING BUT NOT LIMITED TO THE WARRANTIES OF MERCHANTABILITY,
* FITNESS FOR A PARTICULAR PURPOSE AND NONINFRINGEMENT. IN NO EVENT SHALL
* THE AUTHORS OR COPYRIGHT HOLDERS BE LIABLE FOR ANY CLAIM, DAMAGES OR OTHER
* LIABILITY, WHETHER IN AN ACTION OF CONTRACT, TORT OR OTHERWISE, ARISING FROM,
* OUT OF OR IN CONNECTION WITH THE SOFTWARE OR THE USE OR OTHER DEALINGS IN
* THE SOFTWARE.
*/
#include "qemu/osdep.h"
#include "qemu-common.h"
#include "cpu.h"
#include "hw/hw.h"
#include "hw/i386/pc.h"
#include "hw/char/serial.h"
#include "hw/block/fdc.h"
#include "net/net.h"
#include "hw/boards.h"
#include "hw/i2c/smbus.h"
#include "sysemu/block-backend.h"
#include "hw/block/flash.h"
#include "hw/mips/mips.h"
#include "hw/mips/cpudevs.h"
#include "hw/pci/pci.h"
#include "sysemu/sysemu.h"
#include "sysemu/arch_init.h"
#include "qemu/log.h"
#include "hw/mips/bios.h"
#include "hw/ide.h"
#include "hw/loader.h"
#include "elf.h"
#include "hw/timer/mc146818rtc.h"
#include "hw/timer/i8254.h"
#include "sysemu/blockdev.h"
#include "exec/address-spaces.h"
#include "hw/sysbus.h" /* SysBusDevice */
#include "qemu/host-utils.h"
#include "sysemu/qtest.h"
#include "qemu/error-report.h"
#include "hw/empty_slot.h"
#include "sysemu/kvm.h"
#include "exec/semihost.h"
#include "hw/mips/cps.h"
//#define DEBUG_BOARD_INIT
#define ENVP_ADDR 0x80002000l
#define ENVP_NB_ENTRIES 16
#define ENVP_ENTRY_SIZE 256
/* Hardware addresses */
#define FLASH_ADDRESS 0x1e000000ULL
#define FPGA_ADDRESS 0x1f000000ULL
#define RESET_ADDRESS 0x1fc00000ULL
#define FLASH_SIZE 0x400000
#define MAX_IDE_BUS 2
typedef struct {
MemoryRegion iomem;
MemoryRegion iomem_lo; /* 0 - 0x900 */
MemoryRegion iomem_hi; /* 0xa00 - 0x100000 */
uint32_t leds;
uint32_t brk;
uint32_t gpout;
uint32_t i2cin;
uint32_t i2coe;
uint32_t i2cout;
uint32_t i2csel;
CharBackend display;
char display_text[9];
SerialState *uart;
bool display_inited;
} MaltaFPGAState;
#define TYPE_MIPS_MALTA "mips-malta"
#define MIPS_MALTA(obj) OBJECT_CHECK(MaltaState, (obj), TYPE_MIPS_MALTA)
typedef struct {
SysBusDevice parent_obj;
MIPSCPSState *cps;
qemu_irq *i8259;
} MaltaState;
static ISADevice *pit;
static struct _loaderparams {
int ram_size, ram_low_size;
const char *kernel_filename;
const char *kernel_cmdline;
const char *initrd_filename;
} loaderparams;
/* Malta FPGA */
static void malta_fpga_update_display(void *opaque)
{
char leds_text[9];
int i;
MaltaFPGAState *s = opaque;
for (i = 7 ; i >= 0 ; i--) {
if (s->leds & (1 << i))
leds_text[i] = '#';
else
leds_text[i] = ' ';
}
leds_text[8] = '\0';
qemu_chr_fe_printf(&s->display, "\e[H\n\n|\e[32m%-8.8s\e[00m|\r\n",
leds_text);
qemu_chr_fe_printf(&s->display, "\n\n\n\n|\e[31m%-8.8s\e[00m|",
s->display_text);
}
/*
* EEPROM 24C01 / 24C02 emulation.
*
* Emulation for serial EEPROMs:
* 24C01 - 1024 bit (128 x 8)
* 24C02 - 2048 bit (256 x 8)
*
* Typical device names include Microchip 24C02SC or SGS Thomson ST24C02.
*/
//~ #define DEBUG
#if defined(DEBUG)
# define logout(fmt, ...) fprintf(stderr, "MALTA\t%-24s" fmt, __func__, ## __VA_ARGS__)
#else
# define logout(fmt, ...) ((void)0)
#endif
struct _eeprom24c0x_t {
uint8_t tick;
uint8_t address;
uint8_t command;
uint8_t ack;
uint8_t scl;
uint8_t sda;
uint8_t data;
//~ uint16_t size;
uint8_t contents[256];
};
typedef struct _eeprom24c0x_t eeprom24c0x_t;
static eeprom24c0x_t spd_eeprom = {
.contents = {
/* 00000000: */ 0x80,0x08,0xFF,0x0D,0x0A,0xFF,0x40,0x00,
/* 00000008: */ 0x01,0x75,0x54,0x00,0x82,0x08,0x00,0x01,
/* 00000010: */ 0x8F,0x04,0x02,0x01,0x01,0x00,0x00,0x00,
/* 00000018: */ 0x00,0x00,0x00,0x14,0x0F,0x14,0x2D,0xFF,
/* 00000020: */ 0x15,0x08,0x15,0x08,0x00,0x00,0x00,0x00,
/* 00000028: */ 0x00,0x00,0x00,0x00,0x00,0x00,0x00,0x00,
/* 00000030: */ 0x00,0x00,0x00,0x00,0x00,0x00,0x00,0x00,
/* 00000038: */ 0x00,0x00,0x00,0x00,0x00,0x00,0x12,0xD0,
/* 00000040: */ 0x00,0x00,0x00,0x00,0x00,0x00,0x00,0x00,
/* 00000048: */ 0x00,0x00,0x00,0x00,0x00,0x00,0x00,0x00,
/* 00000050: */ 0x00,0x00,0x00,0x00,0x00,0x00,0x00,0x00,
/* 00000058: */ 0x00,0x00,0x00,0x00,0x00,0x00,0x00,0x00,
/* 00000060: */ 0x00,0x00,0x00,0x00,0x00,0x00,0x00,0x00,
/* 00000068: */ 0x00,0x00,0x00,0x00,0x00,0x00,0x00,0x00,
/* 00000070: */ 0x00,0x00,0x00,0x00,0x00,0x00,0x00,0x00,
/* 00000078: */ 0x00,0x00,0x00,0x00,0x00,0x00,0x64,0xF4,
},
};
static void generate_eeprom_spd(uint8_t *eeprom, ram_addr_t ram_size)
{
enum { SDR = 0x4, DDR2 = 0x8 } type;
uint8_t *spd = spd_eeprom.contents;
uint8_t nbanks = 0;
uint16_t density = 0;
int i;
/* work in terms of MB */
ram_size >>= 20;
while ((ram_size >= 4) && (nbanks <= 2)) {
int sz_log2 = MIN(31 - clz32(ram_size), 14);
nbanks++;
density |= 1 << (sz_log2 - 2);
ram_size -= 1 << sz_log2;
}
/* split to 2 banks if possible */
if ((nbanks == 1) && (density > 1)) {
nbanks++;
density >>= 1;
}
if (density & 0xff00) {
density = (density & 0xe0) | ((density >> 8) & 0x1f);
type = DDR2;
} else if (!(density & 0x1f)) {
type = DDR2;
} else {
type = SDR;
}
if (ram_size) {
fprintf(stderr, "Warning: SPD cannot represent final %dMB"
" of SDRAM\n", (int)ram_size);
}
/* fill in SPD memory information */
spd[2] = type;
spd[5] = nbanks;
spd[31] = density;
/* checksum */
spd[63] = 0;
for (i = 0; i < 63; i++) {
spd[63] += spd[i];
}
/* copy for SMBUS */
memcpy(eeprom, spd, sizeof(spd_eeprom.contents));
}
static void generate_eeprom_serial(uint8_t *eeprom)
{
int i, pos = 0;
uint8_t mac[6] = { 0x00 };
uint8_t sn[5] = { 0x01, 0x23, 0x45, 0x67, 0x89 };
/* version */
eeprom[pos++] = 0x01;
/* count */
eeprom[pos++] = 0x02;
/* MAC address */
eeprom[pos++] = 0x01; /* MAC */
eeprom[pos++] = 0x06; /* length */
memcpy(&eeprom[pos], mac, sizeof(mac));
pos += sizeof(mac);
/* serial number */
eeprom[pos++] = 0x02; /* serial */
eeprom[pos++] = 0x05; /* length */
memcpy(&eeprom[pos], sn, sizeof(sn));
pos += sizeof(sn);
/* checksum */
eeprom[pos] = 0;
for (i = 0; i < pos; i++) {
eeprom[pos] += eeprom[i];
}
}
static uint8_t eeprom24c0x_read(eeprom24c0x_t *eeprom)
{
logout("%u: scl = %u, sda = %u, data = 0x%02x\n",
eeprom->tick, eeprom->scl, eeprom->sda, eeprom->data);
return eeprom->sda;
}
static void eeprom24c0x_write(eeprom24c0x_t *eeprom, int scl, int sda)
{
if (eeprom->scl && scl && (eeprom->sda != sda)) {
logout("%u: scl = %u->%u, sda = %u->%u i2c %s\n",
eeprom->tick, eeprom->scl, scl, eeprom->sda, sda,
sda ? "stop" : "start");
if (!sda) {
eeprom->tick = 1;
eeprom->command = 0;
}
} else if (eeprom->tick == 0 && !eeprom->ack) {
/* Waiting for start. */
logout("%u: scl = %u->%u, sda = %u->%u wait for i2c start\n",
eeprom->tick, eeprom->scl, scl, eeprom->sda, sda);
} else if (!eeprom->scl && scl) {
logout("%u: scl = %u->%u, sda = %u->%u trigger bit\n",
eeprom->tick, eeprom->scl, scl, eeprom->sda, sda);
if (eeprom->ack) {
logout("\ti2c ack bit = 0\n");
sda = 0;
eeprom->ack = 0;
} else if (eeprom->sda == sda) {
uint8_t bit = (sda != 0);
logout("\ti2c bit = %d\n", bit);
if (eeprom->tick < 9) {
eeprom->command <<= 1;
eeprom->command += bit;
eeprom->tick++;
if (eeprom->tick == 9) {
logout("\tcommand 0x%04x, %s\n", eeprom->command,
bit ? "read" : "write");
eeprom->ack = 1;
}
} else if (eeprom->tick < 17) {
if (eeprom->command & 1) {
sda = ((eeprom->data & 0x80) != 0);
}
eeprom->address <<= 1;
eeprom->address += bit;
eeprom->tick++;
eeprom->data <<= 1;
if (eeprom->tick == 17) {
eeprom->data = eeprom->contents[eeprom->address];
logout("\taddress 0x%04x, data 0x%02x\n",
eeprom->address, eeprom->data);
eeprom->ack = 1;
eeprom->tick = 0;
}
} else if (eeprom->tick >= 17) {
sda = 0;
}
} else {
logout("\tsda changed with raising scl\n");
}
} else {
logout("%u: scl = %u->%u, sda = %u->%u\n", eeprom->tick, eeprom->scl,
scl, eeprom->sda, sda);
}
eeprom->scl = scl;
eeprom->sda = sda;
}
static uint64_t malta_fpga_read(void *opaque, hwaddr addr,
unsigned size)
{
MaltaFPGAState *s = opaque;
uint32_t val = 0;
uint32_t saddr;
saddr = (addr & 0xfffff);
switch (saddr) {
/* SWITCH Register */
case 0x00200:
val = 0x00000000; /* All switches closed */
break;
/* STATUS Register */
case 0x00208:
#ifdef TARGET_WORDS_BIGENDIAN
val = 0x00000012;
#else
val = 0x00000010;
#endif
break;
/* JMPRS Register */
case 0x00210:
val = 0x00;
break;
/* LEDBAR Register */
case 0x00408:
val = s->leds;
break;
/* BRKRES Register */
case 0x00508:
val = s->brk;
break;
/* UART Registers are handled directly by the serial device */
/* GPOUT Register */
case 0x00a00:
val = s->gpout;
break;
/* XXX: implement a real I2C controller */
/* GPINP Register */
case 0x00a08:
/* IN = OUT until a real I2C control is implemented */
if (s->i2csel)
val = s->i2cout;
else
val = 0x00;
break;
/* I2CINP Register */
case 0x00b00:
val = ((s->i2cin & ~1) | eeprom24c0x_read(&spd_eeprom));
break;
/* I2COE Register */
case 0x00b08:
val = s->i2coe;
break;
/* I2COUT Register */
case 0x00b10:
val = s->i2cout;
break;
/* I2CSEL Register */
case 0x00b18:
val = s->i2csel;
break;
default:
#if 0
printf ("malta_fpga_read: Bad register offset 0x" TARGET_FMT_lx "\n",
addr);
#endif
break;
}
return val;
}
static void malta_fpga_write(void *opaque, hwaddr addr,
uint64_t val, unsigned size)
{
MaltaFPGAState *s = opaque;
uint32_t saddr;
saddr = (addr & 0xfffff);
switch (saddr) {
/* SWITCH Register */
case 0x00200:
break;
/* JMPRS Register */
case 0x00210:
break;
/* LEDBAR Register */
case 0x00408:
s->leds = val & 0xff;
malta_fpga_update_display(s);
break;
/* ASCIIWORD Register */
case 0x00410:
snprintf(s->display_text, 9, "%08X", (uint32_t)val);
malta_fpga_update_display(s);
break;
/* ASCIIPOS0 to ASCIIPOS7 Registers */
case 0x00418:
case 0x00420:
case 0x00428:
case 0x00430:
case 0x00438:
case 0x00440:
case 0x00448:
case 0x00450:
s->display_text[(saddr - 0x00418) >> 3] = (char) val;
malta_fpga_update_display(s);
break;
/* SOFTRES Register */
case 0x00500:
if (val == 0x42)
qemu_system_reset_request(SHUTDOWN_CAUSE_GUEST_RESET);
break;
/* BRKRES Register */
case 0x00508:
s->brk = val & 0xff;
break;
/* UART Registers are handled directly by the serial device */
/* GPOUT Register */
case 0x00a00:
s->gpout = val & 0xff;
break;
/* I2COE Register */
case 0x00b08:
s->i2coe = val & 0x03;
break;
/* I2COUT Register */
case 0x00b10:
eeprom24c0x_write(&spd_eeprom, val & 0x02, val & 0x01);
s->i2cout = val;
break;
/* I2CSEL Register */
case 0x00b18:
s->i2csel = val & 0x01;
break;
default:
#if 0
printf ("malta_fpga_write: Bad register offset 0x" TARGET_FMT_lx "\n",
addr);
#endif
break;
}
}
static const MemoryRegionOps malta_fpga_ops = {
.read = malta_fpga_read,
.write = malta_fpga_write,
.endianness = DEVICE_NATIVE_ENDIAN,
};
static void malta_fpga_reset(void *opaque)
{
MaltaFPGAState *s = opaque;
s->leds = 0x00;
s->brk = 0x0a;
s->gpout = 0x00;
s->i2cin = 0x3;
s->i2coe = 0x0;
s->i2cout = 0x3;
s->i2csel = 0x1;
s->display_text[8] = '\0';
snprintf(s->display_text, 9, " ");
}
static void malta_fgpa_display_event(void *opaque, int event)
{
MaltaFPGAState *s = opaque;
if (event == CHR_EVENT_OPENED && !s->display_inited) {
qemu_chr_fe_printf(&s->display, "\e[HMalta LEDBAR\r\n");
qemu_chr_fe_printf(&s->display, "+--------+\r\n");
qemu_chr_fe_printf(&s->display, "+ +\r\n");
qemu_chr_fe_printf(&s->display, "+--------+\r\n");
qemu_chr_fe_printf(&s->display, "\n");
qemu_chr_fe_printf(&s->display, "Malta ASCII\r\n");
qemu_chr_fe_printf(&s->display, "+--------+\r\n");
qemu_chr_fe_printf(&s->display, "+ +\r\n");
qemu_chr_fe_printf(&s->display, "+--------+\r\n");
s->display_inited = true;
}
}
static MaltaFPGAState *malta_fpga_init(MemoryRegion *address_space,
hwaddr base, qemu_irq uart_irq, Chardev *uart_chr)
{
MaltaFPGAState *s;
Chardev *chr;
s = (MaltaFPGAState *)g_malloc0(sizeof(MaltaFPGAState));
memory_region_init_io(&s->iomem, NULL, &malta_fpga_ops, s,
"malta-fpga", 0x100000);
memory_region_init_alias(&s->iomem_lo, NULL, "malta-fpga",
&s->iomem, 0, 0x900);
memory_region_init_alias(&s->iomem_hi, NULL, "malta-fpga",
&s->iomem, 0xa00, 0x10000-0xa00);
memory_region_add_subregion(address_space, base, &s->iomem_lo);
memory_region_add_subregion(address_space, base + 0xa00, &s->iomem_hi);
chr = qemu_chr_new("fpga", "vc:320x200");
qemu_chr_fe_init(&s->display, chr, NULL);
qemu_chr_fe_set_handlers(&s->display, NULL, NULL,
malta_fgpa_display_event, s, NULL, true);
s->uart = serial_mm_init(address_space, base + 0x900, 3, uart_irq,
230400, uart_chr, DEVICE_NATIVE_ENDIAN);
malta_fpga_reset(s);
qemu_register_reset(malta_fpga_reset, s);
return s;
}
/* Network support */
static void network_init(PCIBus *pci_bus)
{
int i;
for(i = 0; i < nb_nics; i++) {
NICInfo *nd = &nd_table[i];
const char *default_devaddr = NULL;
if (i == 0 && (!nd->model || strcmp(nd->model, "pcnet") == 0))
/* The malta board has a PCNet card using PCI SLOT 11 */
default_devaddr = "0b";
pci_nic_init_nofail(nd, pci_bus, "pcnet", default_devaddr);
}
}
/* ROM and pseudo bootloader
The following code implements a very very simple bootloader. It first
loads the registers a0 to a3 to the values expected by the OS, and
then jump at the kernel address.
The bootloader should pass the locations of the kernel arguments and
environment variables tables. Those tables contain the 32-bit address
of NULL terminated strings. The environment variables table should be
terminated by a NULL address.
For a simpler implementation, the number of kernel arguments is fixed
to two (the name of the kernel and the command line), and the two
tables are actually the same one.
The registers a0 to a3 should contain the following values:
a0 - number of kernel arguments
a1 - 32-bit address of the kernel arguments table
a2 - 32-bit address of the environment variables table
a3 - RAM size in bytes
*/
static void write_bootloader(uint8_t *base, int64_t run_addr,
int64_t kernel_entry)
{
uint32_t *p;
/* Small bootloader */
p = (uint32_t *)base;
stl_p(p++, 0x08000000 | /* j 0x1fc00580 */
((run_addr + 0x580) & 0x0fffffff) >> 2);
stl_p(p++, 0x00000000); /* nop */
/* YAMON service vector */
stl_p(base + 0x500, run_addr + 0x0580); /* start: */
stl_p(base + 0x504, run_addr + 0x083c); /* print_count: */
stl_p(base + 0x520, run_addr + 0x0580); /* start: */
stl_p(base + 0x52c, run_addr + 0x0800); /* flush_cache: */
stl_p(base + 0x534, run_addr + 0x0808); /* print: */
stl_p(base + 0x538, run_addr + 0x0800); /* reg_cpu_isr: */
stl_p(base + 0x53c, run_addr + 0x0800); /* unred_cpu_isr: */
stl_p(base + 0x540, run_addr + 0x0800); /* reg_ic_isr: */
stl_p(base + 0x544, run_addr + 0x0800); /* unred_ic_isr: */
stl_p(base + 0x548, run_addr + 0x0800); /* reg_esr: */
stl_p(base + 0x54c, run_addr + 0x0800); /* unreg_esr: */
stl_p(base + 0x550, run_addr + 0x0800); /* getchar: */
stl_p(base + 0x554, run_addr + 0x0800); /* syscon_read: */
/* Second part of the bootloader */
p = (uint32_t *) (base + 0x580);
if (semihosting_get_argc()) {
/* Preserve a0 content as arguments have been passed */
stl_p(p++, 0x00000000); /* nop */
} else {
stl_p(p++, 0x24040002); /* addiu a0, zero, 2 */
}
stl_p(p++, 0x3c1d0000 | (((ENVP_ADDR - 64) >> 16) & 0xffff)); /* lui sp, high(ENVP_ADDR) */
stl_p(p++, 0x37bd0000 | ((ENVP_ADDR - 64) & 0xffff)); /* ori sp, sp, low(ENVP_ADDR) */
stl_p(p++, 0x3c050000 | ((ENVP_ADDR >> 16) & 0xffff)); /* lui a1, high(ENVP_ADDR) */
stl_p(p++, 0x34a50000 | (ENVP_ADDR & 0xffff)); /* ori a1, a1, low(ENVP_ADDR) */
stl_p(p++, 0x3c060000 | (((ENVP_ADDR + 8) >> 16) & 0xffff)); /* lui a2, high(ENVP_ADDR + 8) */
stl_p(p++, 0x34c60000 | ((ENVP_ADDR + 8) & 0xffff)); /* ori a2, a2, low(ENVP_ADDR + 8) */
stl_p(p++, 0x3c070000 | (loaderparams.ram_low_size >> 16)); /* lui a3, high(ram_low_size) */
stl_p(p++, 0x34e70000 | (loaderparams.ram_low_size & 0xffff)); /* ori a3, a3, low(ram_low_size) */
/* Load BAR registers as done by YAMON */
stl_p(p++, 0x3c09b400); /* lui t1, 0xb400 */
#ifdef TARGET_WORDS_BIGENDIAN
stl_p(p++, 0x3c08df00); /* lui t0, 0xdf00 */
#else
stl_p(p++, 0x340800df); /* ori t0, r0, 0x00df */
#endif
stl_p(p++, 0xad280068); /* sw t0, 0x0068(t1) */
stl_p(p++, 0x3c09bbe0); /* lui t1, 0xbbe0 */
#ifdef TARGET_WORDS_BIGENDIAN
stl_p(p++, 0x3c08c000); /* lui t0, 0xc000 */
#else
stl_p(p++, 0x340800c0); /* ori t0, r0, 0x00c0 */
#endif
stl_p(p++, 0xad280048); /* sw t0, 0x0048(t1) */
#ifdef TARGET_WORDS_BIGENDIAN
stl_p(p++, 0x3c084000); /* lui t0, 0x4000 */
#else
stl_p(p++, 0x34080040); /* ori t0, r0, 0x0040 */
#endif
stl_p(p++, 0xad280050); /* sw t0, 0x0050(t1) */
#ifdef TARGET_WORDS_BIGENDIAN
stl_p(p++, 0x3c088000); /* lui t0, 0x8000 */
#else
stl_p(p++, 0x34080080); /* ori t0, r0, 0x0080 */
#endif
stl_p(p++, 0xad280058); /* sw t0, 0x0058(t1) */
#ifdef TARGET_WORDS_BIGENDIAN
stl_p(p++, 0x3c083f00); /* lui t0, 0x3f00 */
#else
stl_p(p++, 0x3408003f); /* ori t0, r0, 0x003f */
#endif
stl_p(p++, 0xad280060); /* sw t0, 0x0060(t1) */
#ifdef TARGET_WORDS_BIGENDIAN
stl_p(p++, 0x3c08c100); /* lui t0, 0xc100 */
#else
stl_p(p++, 0x340800c1); /* ori t0, r0, 0x00c1 */
#endif
stl_p(p++, 0xad280080); /* sw t0, 0x0080(t1) */
#ifdef TARGET_WORDS_BIGENDIAN
stl_p(p++, 0x3c085e00); /* lui t0, 0x5e00 */
#else
stl_p(p++, 0x3408005e); /* ori t0, r0, 0x005e */
#endif
stl_p(p++, 0xad280088); /* sw t0, 0x0088(t1) */
/* Jump to kernel code */
stl_p(p++, 0x3c1f0000 | ((kernel_entry >> 16) & 0xffff)); /* lui ra, high(kernel_entry) */
stl_p(p++, 0x37ff0000 | (kernel_entry & 0xffff)); /* ori ra, ra, low(kernel_entry) */
stl_p(p++, 0x03e00009); /* jalr ra */
stl_p(p++, 0x00000000); /* nop */
/* YAMON subroutines */
p = (uint32_t *) (base + 0x800);
stl_p(p++, 0x03e00009); /* jalr ra */
stl_p(p++, 0x24020000); /* li v0,0 */
/* 808 YAMON print */
stl_p(p++, 0x03e06821); /* move t5,ra */
stl_p(p++, 0x00805821); /* move t3,a0 */
stl_p(p++, 0x00a05021); /* move t2,a1 */
stl_p(p++, 0x91440000); /* lbu a0,0(t2) */
stl_p(p++, 0x254a0001); /* addiu t2,t2,1 */
stl_p(p++, 0x10800005); /* beqz a0,834 */
stl_p(p++, 0x00000000); /* nop */
stl_p(p++, 0x0ff0021c); /* jal 870 */
stl_p(p++, 0x00000000); /* nop */
stl_p(p++, 0x1000fff9); /* b 814 */
stl_p(p++, 0x00000000); /* nop */
stl_p(p++, 0x01a00009); /* jalr t5 */
stl_p(p++, 0x01602021); /* move a0,t3 */
/* 0x83c YAMON print_count */
stl_p(p++, 0x03e06821); /* move t5,ra */
stl_p(p++, 0x00805821); /* move t3,a0 */
stl_p(p++, 0x00a05021); /* move t2,a1 */
stl_p(p++, 0x00c06021); /* move t4,a2 */
stl_p(p++, 0x91440000); /* lbu a0,0(t2) */
stl_p(p++, 0x0ff0021c); /* jal 870 */
stl_p(p++, 0x00000000); /* nop */
stl_p(p++, 0x254a0001); /* addiu t2,t2,1 */
stl_p(p++, 0x258cffff); /* addiu t4,t4,-1 */
stl_p(p++, 0x1580fffa); /* bnez t4,84c */
stl_p(p++, 0x00000000); /* nop */
stl_p(p++, 0x01a00009); /* jalr t5 */
stl_p(p++, 0x01602021); /* move a0,t3 */
/* 0x870 */
stl_p(p++, 0x3c08b800); /* lui t0,0xb400 */
stl_p(p++, 0x350803f8); /* ori t0,t0,0x3f8 */
stl_p(p++, 0x91090005); /* lbu t1,5(t0) */
stl_p(p++, 0x00000000); /* nop */
stl_p(p++, 0x31290040); /* andi t1,t1,0x40 */
stl_p(p++, 0x1120fffc); /* beqz t1,878 <outch+0x8> */
stl_p(p++, 0x00000000); /* nop */
stl_p(p++, 0x03e00009); /* jalr ra */
stl_p(p++, 0xa1040000); /* sb a0,0(t0) */
}
static void GCC_FMT_ATTR(3, 4) prom_set(uint32_t* prom_buf, int index,
const char *string, ...)
{
va_list ap;
int32_t table_addr;
if (index >= ENVP_NB_ENTRIES)
return;
if (string == NULL) {
prom_buf[index] = 0;
return;
}
table_addr = sizeof(int32_t) * ENVP_NB_ENTRIES + index * ENVP_ENTRY_SIZE;
prom_buf[index] = tswap32(ENVP_ADDR + table_addr);
va_start(ap, string);
vsnprintf((char *)prom_buf + table_addr, ENVP_ENTRY_SIZE, string, ap);
va_end(ap);
}
/* Kernel */
static int64_t load_kernel (void)
{
int64_t kernel_entry, kernel_high;
long initrd_size;
ram_addr_t initrd_offset;
int big_endian;
uint32_t *prom_buf;
long prom_size;
int prom_index = 0;
uint64_t (*xlate_to_kseg0) (void *opaque, uint64_t addr);
#ifdef TARGET_WORDS_BIGENDIAN
big_endian = 1;
#else
big_endian = 0;
#endif
if (load_elf(loaderparams.kernel_filename, cpu_mips_kseg0_to_phys, NULL,
(uint64_t *)&kernel_entry, NULL, (uint64_t *)&kernel_high,
big_endian, EM_MIPS, 1, 0) < 0) {
fprintf(stderr, "qemu: could not load kernel '%s'\n",
loaderparams.kernel_filename);
exit(1);
}
/* Sanity check where the kernel has been linked */
if (kvm_enabled()) {
if (kernel_entry & 0x80000000ll) {
error_report("KVM guest kernels must be linked in useg. "
"Did you forget to enable CONFIG_KVM_GUEST?");
exit(1);
}
xlate_to_kseg0 = cpu_mips_kvm_um_phys_to_kseg0;
} else {
if (!(kernel_entry & 0x80000000ll)) {
error_report("KVM guest kernels aren't supported with TCG. "
"Did you unintentionally enable CONFIG_KVM_GUEST?");
exit(1);
}
xlate_to_kseg0 = cpu_mips_phys_to_kseg0;
}
/* load initrd */
initrd_size = 0;
initrd_offset = 0;
if (loaderparams.initrd_filename) {
initrd_size = get_image_size (loaderparams.initrd_filename);
if (initrd_size > 0) {
initrd_offset = (kernel_high + ~INITRD_PAGE_MASK) & INITRD_PAGE_MASK;
if (initrd_offset + initrd_size > ram_size) {
fprintf(stderr,
"qemu: memory too small for initial ram disk '%s'\n",
loaderparams.initrd_filename);
exit(1);
}
initrd_size = load_image_targphys(loaderparams.initrd_filename,
initrd_offset,
ram_size - initrd_offset);
}
if (initrd_size == (target_ulong) -1) {
fprintf(stderr, "qemu: could not load initial ram disk '%s'\n",
loaderparams.initrd_filename);
exit(1);
}
}
/* Setup prom parameters. */
prom_size = ENVP_NB_ENTRIES * (sizeof(int32_t) + ENVP_ENTRY_SIZE);
prom_buf = g_malloc(prom_size);
prom_set(prom_buf, prom_index++, "%s", loaderparams.kernel_filename);
if (initrd_size > 0) {
prom_set(prom_buf, prom_index++, "rd_start=0x%" PRIx64 " rd_size=%li %s",
xlate_to_kseg0(NULL, initrd_offset), initrd_size,
loaderparams.kernel_cmdline);
} else {
prom_set(prom_buf, prom_index++, "%s", loaderparams.kernel_cmdline);
}
prom_set(prom_buf, prom_index++, "memsize");
prom_set(prom_buf, prom_index++, "%u", loaderparams.ram_low_size);
prom_set(prom_buf, prom_index++, "ememsize");
prom_set(prom_buf, prom_index++, "%u", loaderparams.ram_size);
prom_set(prom_buf, prom_index++, "modetty0");
prom_set(prom_buf, prom_index++, "38400n8r");
prom_set(prom_buf, prom_index++, NULL);
rom_add_blob_fixed("prom", prom_buf, prom_size,
cpu_mips_kseg0_to_phys(NULL, ENVP_ADDR));
g_free(prom_buf);
return kernel_entry;
}
static void malta_mips_config(MIPSCPU *cpu)
{
CPUMIPSState *env = &cpu->env;
CPUState *cs = CPU(cpu);
env->mvp->CP0_MVPConf0 |= ((smp_cpus - 1) << CP0MVPC0_PVPE) |
((smp_cpus * cs->nr_threads - 1) << CP0MVPC0_PTC);
}
static void main_cpu_reset(void *opaque)
{
MIPSCPU *cpu = opaque;
CPUMIPSState *env = &cpu->env;
cpu_reset(CPU(cpu));
/* The bootloader does not need to be rewritten as it is located in a
read only location. The kernel location and the arguments table
location does not change. */
if (loaderparams.kernel_filename) {
env->CP0_Status &= ~(1 << CP0St_ERL);
}
malta_mips_config(cpu);
if (kvm_enabled()) {
/* Start running from the bootloader we wrote to end of RAM */
env->active_tc.PC = 0x40000000 + loaderparams.ram_low_size;
}
}
static void create_cpu_without_cps(const char *cpu_model,
qemu_irq *cbus_irq, qemu_irq *i8259_irq)
{
CPUMIPSState *env;
MIPSCPU *cpu;
int i;
for (i = 0; i < smp_cpus; i++) {
cpu = cpu_mips_init(cpu_model);
if (cpu == NULL) {
fprintf(stderr, "Unable to find CPU definition\n");
exit(1);
}
/* Init internal devices */
cpu_mips_irq_init_cpu(cpu);
cpu_mips_clock_init(cpu);
qemu_register_reset(main_cpu_reset, cpu);
}
cpu = MIPS_CPU(first_cpu);
env = &cpu->env;
*i8259_irq = env->irq[2];
*cbus_irq = env->irq[4];
}
static void create_cps(MaltaState *s, const char *cpu_model,
qemu_irq *cbus_irq, qemu_irq *i8259_irq)
{
Error *err = NULL;
s->cps = g_new0(MIPSCPSState, 1);
object_initialize(s->cps, sizeof(MIPSCPSState), TYPE_MIPS_CPS);
qdev_set_parent_bus(DEVICE(s->cps), sysbus_get_default());
object_property_set_str(OBJECT(s->cps), cpu_model, "cpu-model", &err);
object_property_set_int(OBJECT(s->cps), smp_cpus, "num-vp", &err);
object_property_set_bool(OBJECT(s->cps), true, "realized", &err);
if (err != NULL) {
error_report("%s", error_get_pretty(err));
exit(1);
}
sysbus_mmio_map_overlap(SYS_BUS_DEVICE(s->cps), 0, 0, 1);
*i8259_irq = get_cps_irq(s->cps, 3);
*cbus_irq = NULL;
}
static void create_cpu(MaltaState *s, const char *cpu_model,
qemu_irq *cbus_irq, qemu_irq *i8259_irq)
{
if (cpu_model == NULL) {
#ifdef TARGET_MIPS64
cpu_model = "20Kc";
#else
cpu_model = "24Kf";
#endif
}
if ((smp_cpus > 1) && cpu_supports_cps_smp(cpu_model)) {
create_cps(s, cpu_model, cbus_irq, i8259_irq);
} else {
create_cpu_without_cps(cpu_model, cbus_irq, i8259_irq);
}
}
static
void mips_malta_init(MachineState *machine)
{
ram_addr_t ram_size = machine->ram_size;
ram_addr_t ram_low_size;
const char *kernel_filename = machine->kernel_filename;
const char *kernel_cmdline = machine->kernel_cmdline;
const char *initrd_filename = machine->initrd_filename;
char *filename;
pflash_t *fl;
MemoryRegion *system_memory = get_system_memory();
mips_malta: support up to 2GiB RAM A Malta board can support up to 2GiB of RAM. Since the unmapped kseg0/1 regions are only 512MiB large & the latter 256MiB of those are taken up by the IO region, access to RAM beyond 256MiB must be done through a mapped region. In the case of a Linux guest this means we need to use highmem. The mainline Linux kernel does not support highmem for Malta at this time, however this can be tested using the linux-mti-3.8 kernel branch available from: git://git.linux-mips.org/pub/scm/linux-mti.git You should be able to boot a Linux kernel built from the linux-mti-3.8 branch, with CONFIG_HIGHMEM enabled, using 2GiB RAM by passing "-m 2G" to QEMU and appending the following kernel parameters: mem=256m@0x0 mem=256m@0x90000000 mem=1536m@0x20000000 Note that the upper half of the physical address space of a Malta mirrors the lower half (hence the 2GiB limit) except that the IO region (0x10000000-0x1fffffff in the lower half) is not mirrored in the upper half. That is, physical addresses 0x90000000-0x9fffffff access RAM rather than the IO region, resulting in a physical address space resembling the following: 0x00000000 -> 0x0fffffff RAM 0x10000000 -> 0x1fffffff I/O 0x20000000 -> 0x7fffffff RAM 0x80000000 -> 0x8fffffff RAM (mirror of 0x00000000 -> 0x0fffffff) 0x90000000 -> 0x9fffffff RAM 0xa0000000 -> 0xffffffff RAM (mirror of 0x20000000 -> 0x7fffffff) The second mem parameter provided to the kernel above accesses the second 256MiB of RAM through the upper half of the physical address space, making use of the aliasing described above in order to avoid the IO region and use the whole 2GiB RAM. The memory setup may be seen as 'backwards' in this commit since the 'real' memory is mapped in the upper half of the physical address space and the lower half contains the aliases. On real hardware it would be typical to see the upper half of the physical address space as the alias since the bus addresses generated match the lower half of the physical address space. However since the memory accessible in the upper half of the physical address space is uninterrupted by the IO region it is easiest to map the RAM as a whole there, and functionally it makes no difference to the target code. Due to the requirements of accessing the second 256MiB of RAM through a mapping to the upper half of the physical address space it is usual for the bootloader to indicate a maximum of 256MiB memory to a kernel. This allows kernels which do not support such access to boot on systems with more than 256MiB of RAM. It is also the behaviour assumed by Linux. QEMUs small generated bootloader is modified to provide this behaviour. Signed-off-by: Paul Burton <paul.burton@imgtec.com> Signed-off-by: Yongbok Kim <yongbok.kim@imgtec.com> Reviewed-by: Aurelien Jarno <aurelien@aurel32.net> Signed-off-by: Aurelien Jarno <aurelien@aurel32.net>
2013-09-06 12:57:44 +00:00
MemoryRegion *ram_high = g_new(MemoryRegion, 1);
MemoryRegion *ram_low_preio = g_new(MemoryRegion, 1);
MemoryRegion *ram_low_postio;
MemoryRegion *bios, *bios_copy = g_new(MemoryRegion, 1);
target_long bios_size = FLASH_SIZE;
const size_t smbus_eeprom_size = 8 * 256;
uint8_t *smbus_eeprom_buf = g_malloc0(smbus_eeprom_size);
int64_t kernel_entry, bootloader_run_addr;
PCIBus *pci_bus;
ISABus *isa_bus;
qemu_irq *isa_irq;
qemu_irq cbus_irq, i8259_irq;
int piix4_devfn;
I2CBus *smbus;
int i;
DriveInfo *dinfo;
DriveInfo *hd[MAX_IDE_BUS * MAX_IDE_DEVS];
DriveInfo *fd[MAX_FD];
int fl_idx = 0;
int fl_sectors = bios_size >> 16;
int be;
DeviceState *dev = qdev_create(NULL, TYPE_MIPS_MALTA);
MaltaState *s = MIPS_MALTA(dev);
/* The whole address space decoded by the GT-64120A doesn't generate
exception when accessing invalid memory. Create an empty slot to
emulate this feature. */
empty_slot_init(0, 0x20000000);
qdev_init_nofail(dev);
/* Make sure the first 3 serial ports are associated with a device. */
for(i = 0; i < 3; i++) {
if (!serial_hds[i]) {
char label[32];
snprintf(label, sizeof(label), "serial%d", i);
serial_hds[i] = qemu_chr_new(label, "null");
}
}
/* create CPU */
create_cpu(s, machine->cpu_model, &cbus_irq, &i8259_irq);
/* allocate RAM */
mips_malta: support up to 2GiB RAM A Malta board can support up to 2GiB of RAM. Since the unmapped kseg0/1 regions are only 512MiB large & the latter 256MiB of those are taken up by the IO region, access to RAM beyond 256MiB must be done through a mapped region. In the case of a Linux guest this means we need to use highmem. The mainline Linux kernel does not support highmem for Malta at this time, however this can be tested using the linux-mti-3.8 kernel branch available from: git://git.linux-mips.org/pub/scm/linux-mti.git You should be able to boot a Linux kernel built from the linux-mti-3.8 branch, with CONFIG_HIGHMEM enabled, using 2GiB RAM by passing "-m 2G" to QEMU and appending the following kernel parameters: mem=256m@0x0 mem=256m@0x90000000 mem=1536m@0x20000000 Note that the upper half of the physical address space of a Malta mirrors the lower half (hence the 2GiB limit) except that the IO region (0x10000000-0x1fffffff in the lower half) is not mirrored in the upper half. That is, physical addresses 0x90000000-0x9fffffff access RAM rather than the IO region, resulting in a physical address space resembling the following: 0x00000000 -> 0x0fffffff RAM 0x10000000 -> 0x1fffffff I/O 0x20000000 -> 0x7fffffff RAM 0x80000000 -> 0x8fffffff RAM (mirror of 0x00000000 -> 0x0fffffff) 0x90000000 -> 0x9fffffff RAM 0xa0000000 -> 0xffffffff RAM (mirror of 0x20000000 -> 0x7fffffff) The second mem parameter provided to the kernel above accesses the second 256MiB of RAM through the upper half of the physical address space, making use of the aliasing described above in order to avoid the IO region and use the whole 2GiB RAM. The memory setup may be seen as 'backwards' in this commit since the 'real' memory is mapped in the upper half of the physical address space and the lower half contains the aliases. On real hardware it would be typical to see the upper half of the physical address space as the alias since the bus addresses generated match the lower half of the physical address space. However since the memory accessible in the upper half of the physical address space is uninterrupted by the IO region it is easiest to map the RAM as a whole there, and functionally it makes no difference to the target code. Due to the requirements of accessing the second 256MiB of RAM through a mapping to the upper half of the physical address space it is usual for the bootloader to indicate a maximum of 256MiB memory to a kernel. This allows kernels which do not support such access to boot on systems with more than 256MiB of RAM. It is also the behaviour assumed by Linux. QEMUs small generated bootloader is modified to provide this behaviour. Signed-off-by: Paul Burton <paul.burton@imgtec.com> Signed-off-by: Yongbok Kim <yongbok.kim@imgtec.com> Reviewed-by: Aurelien Jarno <aurelien@aurel32.net> Signed-off-by: Aurelien Jarno <aurelien@aurel32.net>
2013-09-06 12:57:44 +00:00
if (ram_size > (2048u << 20)) {
fprintf(stderr,
mips_malta: support up to 2GiB RAM A Malta board can support up to 2GiB of RAM. Since the unmapped kseg0/1 regions are only 512MiB large & the latter 256MiB of those are taken up by the IO region, access to RAM beyond 256MiB must be done through a mapped region. In the case of a Linux guest this means we need to use highmem. The mainline Linux kernel does not support highmem for Malta at this time, however this can be tested using the linux-mti-3.8 kernel branch available from: git://git.linux-mips.org/pub/scm/linux-mti.git You should be able to boot a Linux kernel built from the linux-mti-3.8 branch, with CONFIG_HIGHMEM enabled, using 2GiB RAM by passing "-m 2G" to QEMU and appending the following kernel parameters: mem=256m@0x0 mem=256m@0x90000000 mem=1536m@0x20000000 Note that the upper half of the physical address space of a Malta mirrors the lower half (hence the 2GiB limit) except that the IO region (0x10000000-0x1fffffff in the lower half) is not mirrored in the upper half. That is, physical addresses 0x90000000-0x9fffffff access RAM rather than the IO region, resulting in a physical address space resembling the following: 0x00000000 -> 0x0fffffff RAM 0x10000000 -> 0x1fffffff I/O 0x20000000 -> 0x7fffffff RAM 0x80000000 -> 0x8fffffff RAM (mirror of 0x00000000 -> 0x0fffffff) 0x90000000 -> 0x9fffffff RAM 0xa0000000 -> 0xffffffff RAM (mirror of 0x20000000 -> 0x7fffffff) The second mem parameter provided to the kernel above accesses the second 256MiB of RAM through the upper half of the physical address space, making use of the aliasing described above in order to avoid the IO region and use the whole 2GiB RAM. The memory setup may be seen as 'backwards' in this commit since the 'real' memory is mapped in the upper half of the physical address space and the lower half contains the aliases. On real hardware it would be typical to see the upper half of the physical address space as the alias since the bus addresses generated match the lower half of the physical address space. However since the memory accessible in the upper half of the physical address space is uninterrupted by the IO region it is easiest to map the RAM as a whole there, and functionally it makes no difference to the target code. Due to the requirements of accessing the second 256MiB of RAM through a mapping to the upper half of the physical address space it is usual for the bootloader to indicate a maximum of 256MiB memory to a kernel. This allows kernels which do not support such access to boot on systems with more than 256MiB of RAM. It is also the behaviour assumed by Linux. QEMUs small generated bootloader is modified to provide this behaviour. Signed-off-by: Paul Burton <paul.burton@imgtec.com> Signed-off-by: Yongbok Kim <yongbok.kim@imgtec.com> Reviewed-by: Aurelien Jarno <aurelien@aurel32.net> Signed-off-by: Aurelien Jarno <aurelien@aurel32.net>
2013-09-06 12:57:44 +00:00
"qemu: Too much memory for this machine: %d MB, maximum 2048 MB\n",
((unsigned int)ram_size / (1 << 20)));
exit(1);
}
mips_malta: support up to 2GiB RAM A Malta board can support up to 2GiB of RAM. Since the unmapped kseg0/1 regions are only 512MiB large & the latter 256MiB of those are taken up by the IO region, access to RAM beyond 256MiB must be done through a mapped region. In the case of a Linux guest this means we need to use highmem. The mainline Linux kernel does not support highmem for Malta at this time, however this can be tested using the linux-mti-3.8 kernel branch available from: git://git.linux-mips.org/pub/scm/linux-mti.git You should be able to boot a Linux kernel built from the linux-mti-3.8 branch, with CONFIG_HIGHMEM enabled, using 2GiB RAM by passing "-m 2G" to QEMU and appending the following kernel parameters: mem=256m@0x0 mem=256m@0x90000000 mem=1536m@0x20000000 Note that the upper half of the physical address space of a Malta mirrors the lower half (hence the 2GiB limit) except that the IO region (0x10000000-0x1fffffff in the lower half) is not mirrored in the upper half. That is, physical addresses 0x90000000-0x9fffffff access RAM rather than the IO region, resulting in a physical address space resembling the following: 0x00000000 -> 0x0fffffff RAM 0x10000000 -> 0x1fffffff I/O 0x20000000 -> 0x7fffffff RAM 0x80000000 -> 0x8fffffff RAM (mirror of 0x00000000 -> 0x0fffffff) 0x90000000 -> 0x9fffffff RAM 0xa0000000 -> 0xffffffff RAM (mirror of 0x20000000 -> 0x7fffffff) The second mem parameter provided to the kernel above accesses the second 256MiB of RAM through the upper half of the physical address space, making use of the aliasing described above in order to avoid the IO region and use the whole 2GiB RAM. The memory setup may be seen as 'backwards' in this commit since the 'real' memory is mapped in the upper half of the physical address space and the lower half contains the aliases. On real hardware it would be typical to see the upper half of the physical address space as the alias since the bus addresses generated match the lower half of the physical address space. However since the memory accessible in the upper half of the physical address space is uninterrupted by the IO region it is easiest to map the RAM as a whole there, and functionally it makes no difference to the target code. Due to the requirements of accessing the second 256MiB of RAM through a mapping to the upper half of the physical address space it is usual for the bootloader to indicate a maximum of 256MiB memory to a kernel. This allows kernels which do not support such access to boot on systems with more than 256MiB of RAM. It is also the behaviour assumed by Linux. QEMUs small generated bootloader is modified to provide this behaviour. Signed-off-by: Paul Burton <paul.burton@imgtec.com> Signed-off-by: Yongbok Kim <yongbok.kim@imgtec.com> Reviewed-by: Aurelien Jarno <aurelien@aurel32.net> Signed-off-by: Aurelien Jarno <aurelien@aurel32.net>
2013-09-06 12:57:44 +00:00
/* register RAM at high address where it is undisturbed by IO */
memory_region_allocate_system_memory(ram_high, NULL, "mips_malta.ram",
ram_size);
mips_malta: support up to 2GiB RAM A Malta board can support up to 2GiB of RAM. Since the unmapped kseg0/1 regions are only 512MiB large & the latter 256MiB of those are taken up by the IO region, access to RAM beyond 256MiB must be done through a mapped region. In the case of a Linux guest this means we need to use highmem. The mainline Linux kernel does not support highmem for Malta at this time, however this can be tested using the linux-mti-3.8 kernel branch available from: git://git.linux-mips.org/pub/scm/linux-mti.git You should be able to boot a Linux kernel built from the linux-mti-3.8 branch, with CONFIG_HIGHMEM enabled, using 2GiB RAM by passing "-m 2G" to QEMU and appending the following kernel parameters: mem=256m@0x0 mem=256m@0x90000000 mem=1536m@0x20000000 Note that the upper half of the physical address space of a Malta mirrors the lower half (hence the 2GiB limit) except that the IO region (0x10000000-0x1fffffff in the lower half) is not mirrored in the upper half. That is, physical addresses 0x90000000-0x9fffffff access RAM rather than the IO region, resulting in a physical address space resembling the following: 0x00000000 -> 0x0fffffff RAM 0x10000000 -> 0x1fffffff I/O 0x20000000 -> 0x7fffffff RAM 0x80000000 -> 0x8fffffff RAM (mirror of 0x00000000 -> 0x0fffffff) 0x90000000 -> 0x9fffffff RAM 0xa0000000 -> 0xffffffff RAM (mirror of 0x20000000 -> 0x7fffffff) The second mem parameter provided to the kernel above accesses the second 256MiB of RAM through the upper half of the physical address space, making use of the aliasing described above in order to avoid the IO region and use the whole 2GiB RAM. The memory setup may be seen as 'backwards' in this commit since the 'real' memory is mapped in the upper half of the physical address space and the lower half contains the aliases. On real hardware it would be typical to see the upper half of the physical address space as the alias since the bus addresses generated match the lower half of the physical address space. However since the memory accessible in the upper half of the physical address space is uninterrupted by the IO region it is easiest to map the RAM as a whole there, and functionally it makes no difference to the target code. Due to the requirements of accessing the second 256MiB of RAM through a mapping to the upper half of the physical address space it is usual for the bootloader to indicate a maximum of 256MiB memory to a kernel. This allows kernels which do not support such access to boot on systems with more than 256MiB of RAM. It is also the behaviour assumed by Linux. QEMUs small generated bootloader is modified to provide this behaviour. Signed-off-by: Paul Burton <paul.burton@imgtec.com> Signed-off-by: Yongbok Kim <yongbok.kim@imgtec.com> Reviewed-by: Aurelien Jarno <aurelien@aurel32.net> Signed-off-by: Aurelien Jarno <aurelien@aurel32.net>
2013-09-06 12:57:44 +00:00
memory_region_add_subregion(system_memory, 0x80000000, ram_high);
/* alias for pre IO hole access */
memory_region_init_alias(ram_low_preio, NULL, "mips_malta_low_preio.ram",
ram_high, 0, MIN(ram_size, (256 << 20)));
memory_region_add_subregion(system_memory, 0, ram_low_preio);
/* alias for post IO hole access, if there is enough RAM */
if (ram_size > (512 << 20)) {
ram_low_postio = g_new(MemoryRegion, 1);
memory_region_init_alias(ram_low_postio, NULL,
"mips_malta_low_postio.ram",
ram_high, 512 << 20,
ram_size - (512 << 20));
memory_region_add_subregion(system_memory, 512 << 20, ram_low_postio);
}
/* generate SPD EEPROM data */
generate_eeprom_spd(&smbus_eeprom_buf[0 * 256], ram_size);
generate_eeprom_serial(&smbus_eeprom_buf[6 * 256]);
#ifdef TARGET_WORDS_BIGENDIAN
be = 1;
#else
be = 0;
#endif
/* FPGA */
/* The CBUS UART is attached to the MIPS CPU INT2 pin, ie interrupt 4 */
malta_fpga_init(system_memory, FPGA_ADDRESS, cbus_irq, serial_hds[2]);
/* Load firmware in flash / BIOS. */
dinfo = drive_get(IF_PFLASH, 0, fl_idx);
#ifdef DEBUG_BOARD_INIT
if (dinfo) {
printf("Register parallel flash %d size " TARGET_FMT_lx " at "
"addr %08llx '%s' %x\n",
fl_idx, bios_size, FLASH_ADDRESS,
blk_name(dinfo->bdrv), fl_sectors);
}
#endif
fl = pflash_cfi01_register(FLASH_ADDRESS, NULL, "mips_malta.bios",
BIOS_SIZE,
dinfo ? blk_by_legacy_dinfo(dinfo) : NULL,
65536, fl_sectors,
4, 0x0000, 0x0000, 0x0000, 0x0000, be);
bios = pflash_cfi01_get_memory(fl);
fl_idx++;
if (kernel_filename) {
ram_low_size = MIN(ram_size, 256 << 20);
/* For KVM we reserve 1MB of RAM for running bootloader */
if (kvm_enabled()) {
ram_low_size -= 0x100000;
bootloader_run_addr = 0x40000000 + ram_low_size;
} else {
bootloader_run_addr = 0xbfc00000;
}
/* Write a small bootloader to the flash location. */
loaderparams.ram_size = ram_size;
loaderparams.ram_low_size = ram_low_size;
loaderparams.kernel_filename = kernel_filename;
loaderparams.kernel_cmdline = kernel_cmdline;
loaderparams.initrd_filename = initrd_filename;
kernel_entry = load_kernel();
write_bootloader(memory_region_get_ram_ptr(bios),
bootloader_run_addr, kernel_entry);
if (kvm_enabled()) {
/* Write the bootloader code @ the end of RAM, 1MB reserved */
write_bootloader(memory_region_get_ram_ptr(ram_low_preio) +
ram_low_size,
bootloader_run_addr, kernel_entry);
}
} else {
/* The flash region isn't executable from a KVM guest */
if (kvm_enabled()) {
error_report("KVM enabled but no -kernel argument was specified. "
"Booting from flash is not supported with KVM.");
exit(1);
}
/* Load firmware from flash. */
if (!dinfo) {
/* Load a BIOS image. */
if (bios_name == NULL) {
bios_name = BIOS_FILENAME;
}
filename = qemu_find_file(QEMU_FILE_TYPE_BIOS, bios_name);
if (filename) {
bios_size = load_image_targphys(filename, FLASH_ADDRESS,
BIOS_SIZE);
g_free(filename);
} else {
bios_size = -1;
}
if ((bios_size < 0 || bios_size > BIOS_SIZE) &&
!kernel_filename && !qtest_enabled()) {
error_report("Could not load MIPS bios '%s', and no "
"-kernel argument was specified", bios_name);
exit(1);
}
}
/* In little endian mode the 32bit words in the bios are swapped,
a neat trick which allows bi-endian firmware. */
#ifndef TARGET_WORDS_BIGENDIAN
{
uint32_t *end, *addr = rom_ptr(FLASH_ADDRESS);
if (!addr) {
addr = memory_region_get_ram_ptr(bios);
}
end = (void *)addr + MIN(bios_size, 0x3e0000);
while (addr < end) {
bswap32s(addr);
addr++;
}
}
#endif
}
/*
* Map the BIOS at a 2nd physical location, as on the real board.
* Copy it so that we can patch in the MIPS revision, which cannot be
* handled by an overlapping region as the resulting ROM code subpage
* regions are not executable.
*/
memory_region_init_ram(bios_copy, NULL, "bios.1fc", BIOS_SIZE,
Fix bad error handling after memory_region_init_ram() Symptom: $ qemu-system-x86_64 -m 10000000 Unexpected error in ram_block_add() at /work/armbru/qemu/exec.c:1456: upstream-qemu: cannot set up guest memory 'pc.ram': Cannot allocate memory Aborted (core dumped) Root cause: commit ef701d7 screwed up handling of out-of-memory conditions. Before the commit, we report the error and exit(1), in one place, ram_block_add(). The commit lifts the error handling up the call chain some, to three places. Fine. Except it uses &error_abort in these places, changing the behavior from exit(1) to abort(), and thus undoing the work of commit 3922825 "exec: Don't abort when we can't allocate guest memory". The three places are: * memory_region_init_ram() Commit 4994653 (right after commit ef701d7) lifted the error handling further, through memory_region_init_ram(), multiplying the incorrect use of &error_abort. Later on, imitation of existing (bad) code may have created more. * memory_region_init_ram_ptr() The &error_abort is still there. * memory_region_init_rom_device() Doesn't need fixing, because commit 33e0eb5 (soon after commit ef701d7) lifted the error handling further, and in the process changed it from &error_abort to passing it up the call chain. Correct, because the callers are realize() methods. Fix the error handling after memory_region_init_ram() with a Coccinelle semantic patch: @r@ expression mr, owner, name, size, err; position p; @@ memory_region_init_ram(mr, owner, name, size, ( - &error_abort + &error_fatal | err@p ) ); @script:python@ p << r.p; @@ print "%s:%s:%s" % (p[0].file, p[0].line, p[0].column) When the last argument is &error_abort, it gets replaced by &error_fatal. This is the fix. If the last argument is anything else, its position is reported. This lets us check the fix is complete. Four positions get reported: * ram_backend_memory_alloc() Error is passed up the call chain, ultimately through user_creatable_complete(). As far as I can tell, it's callers all handle the error sanely. * fsl_imx25_realize(), fsl_imx31_realize(), dp8393x_realize() DeviceClass.realize() methods, errors handled sanely further up the call chain. We're good. Test case again behaves: $ qemu-system-x86_64 -m 10000000 qemu-system-x86_64: cannot set up guest memory 'pc.ram': Cannot allocate memory [Exit 1 ] The next commits will repair the rest of commit ef701d7's damage. Signed-off-by: Markus Armbruster <armbru@redhat.com> Message-Id: <1441983105-26376-3-git-send-email-armbru@redhat.com> Reviewed-by: Peter Crosthwaite <crosthwaite.peter@gmail.com>
2015-09-11 14:51:43 +00:00
&error_fatal);
if (!rom_copy(memory_region_get_ram_ptr(bios_copy),
FLASH_ADDRESS, BIOS_SIZE)) {
memcpy(memory_region_get_ram_ptr(bios_copy),
memory_region_get_ram_ptr(bios), BIOS_SIZE);
}
memory_region_set_readonly(bios_copy, true);
memory_region_add_subregion(system_memory, RESET_ADDRESS, bios_copy);
/* Board ID = 0x420 (Malta Board with CoreLV) */
stl_p(memory_region_get_ram_ptr(bios_copy) + 0x10, 0x00000420);
/*
* We have a circular dependency problem: pci_bus depends on isa_irq,
* isa_irq is provided by i8259, i8259 depends on ISA, ISA depends
* on piix4, and piix4 depends on pci_bus. To stop the cycle we have
* qemu_irq_proxy() adds an extra bit of indirection, allowing us
* to resolve the isa_irq -> i8259 dependency after i8259 is initialized.
*/
isa_irq = qemu_irq_proxy(&s->i8259, 16);
/* Northbridge */
pci_bus = gt64120_register(isa_irq);
/* Southbridge */
ide_drive_get(hd, ARRAY_SIZE(hd));
piix4_devfn = piix4_init(pci_bus, &isa_bus, 80);
/* Interrupt controller */
/* The 8259 is attached to the MIPS CPU INT0 pin, ie interrupt 2 */
s->i8259 = i8259_init(isa_bus, i8259_irq);
isa_bus_irqs(isa_bus, s->i8259);
pci_piix4_ide_init(pci_bus, hd, piix4_devfn + 1);
pci_create_simple(pci_bus, piix4_devfn + 2, "piix4-usb-uhci");
smbus = piix4_pm_init(pci_bus, piix4_devfn + 3, 0x1100,
isa_get_irq(NULL, 9), NULL, 0, NULL);
smbus_eeprom_init(smbus, 8, smbus_eeprom_buf, smbus_eeprom_size);
g_free(smbus_eeprom_buf);
pit = pit_init(isa_bus, 0x40, 0, NULL);
DMA_init(isa_bus, 0);
/* Super I/O */
isa_create_simple(isa_bus, "i8042");
rtc_init(isa_bus, 2000, NULL);
serial_hds_isa_init(isa_bus, 0, 2);
parallel_hds_isa_init(isa_bus, 1);
for(i = 0; i < MAX_FD; i++) {
fd[i] = drive_get(IF_FLOPPY, 0, i);
}
fdctrl_init_isa(isa_bus, fd);
/* Network card */
network_init(pci_bus);
/* Optional PCI video card */
pci_vga_init(pci_bus);
}
static int mips_malta_sysbus_device_init(SysBusDevice *sysbusdev)
{
return 0;
}
static void mips_malta_class_init(ObjectClass *klass, void *data)
{
SysBusDeviceClass *k = SYS_BUS_DEVICE_CLASS(klass);
k->init = mips_malta_sysbus_device_init;
}
static const TypeInfo mips_malta_device = {
.name = TYPE_MIPS_MALTA,
.parent = TYPE_SYS_BUS_DEVICE,
.instance_size = sizeof(MaltaState),
.class_init = mips_malta_class_init,
};
static void mips_malta_machine_init(MachineClass *mc)
{
mc->desc = "MIPS Malta Core LV";
mc->init = mips_malta_init;
mc->block_default_type = IF_IDE;
mc->max_cpus = 16;
mc->is_default = 1;
}
DEFINE_MACHINE("malta", mips_malta_machine_init)
static void mips_malta_register_types(void)
{
type_register_static(&mips_malta_device);
}
type_init(mips_malta_register_types)