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/*
*
*/
#undef BOOTSTRAP
#include "config.h"
#include "libopenbios/bindings.h"
#include "arch/common/nvram.h"
#include "drivers/drivers.h"
#include "libc/diskio.h"
#include "libc/vsprintf.h"
#include "libopenbios/ofmem.h"
#include "libopenbios/sys_info.h"
#include "openprom.h"
#include "boot.h"
#include "context.h"
uint32_t kernel_image;
uint32_t kernel_size;
uint32_t qemu_cmdline;
uint32_t cmdline_size;
char boot_device;
const void *romvec;
static struct linux_mlist_v0 *totphyslist, *availlist, *prommaplist;
static void setup_romvec(void)
{
/* SPARC32 is slightly unusual in that before invoking any loaders, a romvec array
needs to be set up to pass certain parameters using a C struct. Hence this function
extracts the relevant boot information and places it in obp_arg. */
int intprop, proplen, target, device, i;
unsigned int *intprop_ptr;
phandle_t chosen;
char *prop, *id, *name;
static char bootpathbuf[128], bootargsbuf[128], buf[128];
struct linux_mlist_v0 **pp;
/* Get the stdin and stdout paths */
chosen = find_dev("/chosen");
intprop = get_int_property(chosen, "stdin", &proplen);
PUSH(intprop);
fword("get-instance-path");
((struct linux_romvec *)romvec)->pv_stdin = pop_fstr_copy();
intprop = get_int_property(chosen, "stdout", &proplen);
PUSH(intprop);
fword("get-instance-path");
((struct linux_romvec *)romvec)->pv_stdout = pop_fstr_copy();
/* Get the name of the selected boot device, along with the device and unit number */
prop = get_property(chosen, "bootpath", &proplen);
strncpy(bootpathbuf, prop, proplen);
prop = get_property(chosen, "bootargs", &proplen);
strncpy(bootargsbuf, prop, proplen);
/* Set bootpath pointer used in romvec table to the bootpath */
push_str(bootpathbuf);
fword("pathres-resolve-aliases");
bootpath = pop_fstr_copy();
printk("bootpath: %s\n", bootpath);
/* Now do some work to get hold of the target, partition etc. */
push_str(bootpathbuf);
feval("open-dev");
feval("ihandle>boot-device-handle drop to my-self");
push_str("name");
fword("get-my-property");
POP();
name = pop_fstr_copy();
if (!strncmp(name, "sd", 2)) {
/*
Old-style SunOS disk paths are given in the form:
sd(c,t,d):s
where:
c = controller (Nth controller in system, usually 0)
t = target (my-unit phys.hi)
d = device/LUN (my-unit phys.lo)
s = slice/partition (my-args)
*/
/* Controller currently always 0 */
obp_arg.boot_dev_ctrl = 0;
/* Get the target, device and slice */
fword("my-unit");
target = POP();
device = POP();
fword("my-args");
id = pop_fstr_copy();
if (id != NULL) {
snprintf(buf, sizeof(buf), "sd(0,%d,%d):%c", target, device, id[0]);
obp_arg.dev_partition = id[0] - 'a';
} else {
snprintf(buf, sizeof(buf), "sd(0,%d,%d)", target, device);
obp_arg.dev_partition = 0;
}
obp_arg.boot_dev_unit = target;
obp_arg.boot_dev[0] = buf[0];
obp_arg.boot_dev[1] = buf[1];
obp_arg.argv[0] = buf;
obp_arg.argv[1] = bootargsbuf;
} else if (!strncmp(name, "SUNW,fdtwo", 10)) {
obp_arg.boot_dev_ctrl = 0;
obp_arg.boot_dev_unit = 0;
obp_arg.dev_partition = 0;
strcpy(buf, "fd()");
obp_arg.boot_dev[0] = buf[0];
obp_arg.boot_dev[1] = buf[1];
obp_arg.argv[0] = buf;
obp_arg.argv[1] = bootargsbuf;
} else if (!strncmp(name, "le", 2)) {
obp_arg.boot_dev_ctrl = 0;
obp_arg.boot_dev_unit = 0;
obp_arg.dev_partition = 0;
strcpy(buf, "le()");
obp_arg.boot_dev[0] = buf[0];
obp_arg.boot_dev[1] = buf[1];
obp_arg.argv[0] = buf;
obp_arg.argv[1] = bootargsbuf;
}
/* Generate the totphys (total memory available) list */
prop = get_property(s_phandle_memory, "reg", &proplen);
intprop_ptr = (unsigned int *)prop;
for (pp = &totphyslist, i = 0; i < (proplen / sizeof(int)); pp = &(**pp).theres_more, i+=3) {
*pp = (struct linux_mlist_v0 *)malloc(sizeof(struct linux_mlist_v0));
(**pp).theres_more = NULL;
(**pp).start_adr = (char *)intprop_ptr[1];
(**pp).num_bytes = intprop_ptr[2];
intprop_ptr += 3;
}
/* Generate the avail (physical memory available) list */
prop = get_property(s_phandle_memory, "available", &proplen);
intprop_ptr = (unsigned int *)prop;
for (pp = &availlist, i = 0; i < (proplen / sizeof(int)); pp = &(**pp).theres_more, i+=3) {
*pp = (struct linux_mlist_v0 *)malloc(sizeof(struct linux_mlist_v0));
(**pp).theres_more = NULL;
(**pp).start_adr = (char *)intprop_ptr[1];
(**pp).num_bytes = intprop_ptr[2];
intprop_ptr += 3;
}
/* Generate the prommap (taken virtual memory) list from inverse of available */
prop = get_property(s_phandle_mmu, "available", &proplen);
intprop_ptr = (unsigned int *)prop;
for (pp = &prommaplist, i = 0; i < (proplen / sizeof(int)); pp = &(**pp).theres_more, i+=3) {
*pp = (struct linux_mlist_v0 *)malloc(sizeof(struct linux_mlist_v0));
(**pp).theres_more = NULL;
(**pp).start_adr = (char *)(intprop_ptr[1] + intprop_ptr[2]);
if (i + 3 < (proplen / sizeof(int))) {
/* Size from next entry */
(**pp).num_bytes = (intprop_ptr[4] + intprop_ptr[5]) - (intprop_ptr[1] + intprop_ptr[2]);
} else {
/* Tail (size from top of virtual memory) */
(**pp).num_bytes = 0xffffffffUL - (intprop_ptr[1] + intprop_ptr[2]) + 1;
}
intprop_ptr += 3;
}
/* Finally set the memory properties */
((struct linux_romvec *)romvec)->pv_v0mem.v0_totphys = &totphyslist;
((struct linux_romvec *)romvec)->pv_v0mem.v0_available = &availlist;
((struct linux_romvec *)romvec)->pv_v0mem.v0_prommap = &prommaplist;
}
void go(void)
{
ucell address, type, size;
int image_retval = 0;
/* Get the entry point and the type (see forth/debugging/client.fs) */
feval("saved-program-state >sps.entry @");
address = POP();
feval("saved-program-state >sps.file-type @");
type = POP();
feval("saved-program-state >sps.file-size @");
size = POP();
setup_romvec();
printk("\nJumping to entry point " FMT_ucellx " for type " FMT_ucellx "...\n", address, type);
switch (type) {
case 0x0:
/* Start ELF boot image */
image_retval = start_elf((unsigned long)address,
(unsigned long)romvec);
break;
case 0x1:
/* Start ELF image */
image_retval = start_elf((unsigned long)address,
(unsigned long)romvec);
break;
case 0x5:
/* Start a.out image */
image_retval = start_elf((unsigned long)address,
(unsigned long)romvec);
break;
case 0x10:
/* Start Fcode image */
printk("Evaluating FCode...\n");
PUSH(address);
PUSH(1);
fword("byte-load");
image_retval = 0;
break;
case 0x11:
/* Start Forth image */
PUSH(address);
PUSH(size);
fword("eval2");
image_retval = 0;
break;
}
printk("Image returned with return value %#x\n", image_retval);
}
void boot(void)
{
/* Boot preloaded kernel */
if (kernel_size) {
printk("[sparc] Kernel already loaded\n");
start_elf(kernel_image, (unsigned long)romvec);
}
}
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