kernel-fxtec-pro1x/scripts/dtc/flattree.c
David Gibson 9fffb55f66 Move dtc and libfdt sources from arch/powerpc/boot to scripts/dtc
The powerpc kernel always requires an Open Firmware like device tree
to supply device information.  On systems without OF, this comes from
a flattened device tree blob.  This blob is usually generated by dtc,
a tool which compiles a text description of the device tree into the
flattened format used by the kernel.  Sometimes, the bootwrapper makes
small changes to the pre-compiled device tree blob (e.g. filling in
the size of RAM).  To do this it uses the libfdt library.

Because these are only used on powerpc, the code for both these tools
is included under arch/powerpc/boot (these were imported and are
periodically updated from the upstream dtc tree).

However, the microblaze architecture, currently being prepared for
merging to mainline also uses dtc to produce device tree blobs.  A few
other archs have also mentioned some interest in using dtc.
Therefore, this patch moves dtc and libfdt from arch/powerpc into
scripts, where it can be used by any architecture.

The vast bulk of this patch is a literal move, the rest is adjusting
the various Makefiles to use dtc and libfdt correctly from their new
locations.

Signed-off-by: David Gibson <david@gibson.dropbear.id.au>
Signed-off-by: Linus Torvalds <torvalds@linux-foundation.org>
2009-05-02 16:52:26 -07:00

906 lines
21 KiB
C

/*
* (C) Copyright David Gibson <dwg@au1.ibm.com>, IBM Corporation. 2005.
*
*
* This program is free software; you can redistribute it and/or
* modify it under the terms of the GNU General Public License as
* published by the Free Software Foundation; either version 2 of the
* License, or (at your option) any later version.
*
* This program is distributed in the hope that it will be useful,
* but WITHOUT ANY WARRANTY; without even the implied warranty of
* MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the GNU
* General Public License for more details.
*
* You should have received a copy of the GNU General Public License
* along with this program; if not, write to the Free Software
* Foundation, Inc., 59 Temple Place, Suite 330, Boston, MA 02111-1307
* USA
*/
#include "dtc.h"
#include "srcpos.h"
#define FTF_FULLPATH 0x1
#define FTF_VARALIGN 0x2
#define FTF_NAMEPROPS 0x4
#define FTF_BOOTCPUID 0x8
#define FTF_STRTABSIZE 0x10
#define FTF_STRUCTSIZE 0x20
#define FTF_NOPS 0x40
static struct version_info {
int version;
int last_comp_version;
int hdr_size;
int flags;
} version_table[] = {
{1, 1, FDT_V1_SIZE,
FTF_FULLPATH|FTF_VARALIGN|FTF_NAMEPROPS},
{2, 1, FDT_V2_SIZE,
FTF_FULLPATH|FTF_VARALIGN|FTF_NAMEPROPS|FTF_BOOTCPUID},
{3, 1, FDT_V3_SIZE,
FTF_FULLPATH|FTF_VARALIGN|FTF_NAMEPROPS|FTF_BOOTCPUID|FTF_STRTABSIZE},
{16, 16, FDT_V3_SIZE,
FTF_BOOTCPUID|FTF_STRTABSIZE|FTF_NOPS},
{17, 16, FDT_V17_SIZE,
FTF_BOOTCPUID|FTF_STRTABSIZE|FTF_STRUCTSIZE|FTF_NOPS},
};
struct emitter {
void (*cell)(void *, cell_t);
void (*string)(void *, char *, int);
void (*align)(void *, int);
void (*data)(void *, struct data);
void (*beginnode)(void *, const char *);
void (*endnode)(void *, const char *);
void (*property)(void *, const char *);
};
static void bin_emit_cell(void *e, cell_t val)
{
struct data *dtbuf = e;
*dtbuf = data_append_cell(*dtbuf, val);
}
static void bin_emit_string(void *e, char *str, int len)
{
struct data *dtbuf = e;
if (len == 0)
len = strlen(str);
*dtbuf = data_append_data(*dtbuf, str, len);
*dtbuf = data_append_byte(*dtbuf, '\0');
}
static void bin_emit_align(void *e, int a)
{
struct data *dtbuf = e;
*dtbuf = data_append_align(*dtbuf, a);
}
static void bin_emit_data(void *e, struct data d)
{
struct data *dtbuf = e;
*dtbuf = data_append_data(*dtbuf, d.val, d.len);
}
static void bin_emit_beginnode(void *e, const char *label)
{
bin_emit_cell(e, FDT_BEGIN_NODE);
}
static void bin_emit_endnode(void *e, const char *label)
{
bin_emit_cell(e, FDT_END_NODE);
}
static void bin_emit_property(void *e, const char *label)
{
bin_emit_cell(e, FDT_PROP);
}
static struct emitter bin_emitter = {
.cell = bin_emit_cell,
.string = bin_emit_string,
.align = bin_emit_align,
.data = bin_emit_data,
.beginnode = bin_emit_beginnode,
.endnode = bin_emit_endnode,
.property = bin_emit_property,
};
static void emit_label(FILE *f, const char *prefix, const char *label)
{
fprintf(f, "\t.globl\t%s_%s\n", prefix, label);
fprintf(f, "%s_%s:\n", prefix, label);
fprintf(f, "_%s_%s:\n", prefix, label);
}
static void emit_offset_label(FILE *f, const char *label, int offset)
{
fprintf(f, "\t.globl\t%s\n", label);
fprintf(f, "%s\t= . + %d\n", label, offset);
}
static void asm_emit_cell(void *e, cell_t val)
{
FILE *f = e;
fprintf(f, "\t.long\t0x%x\n", val);
}
static void asm_emit_string(void *e, char *str, int len)
{
FILE *f = e;
char c = 0;
if (len != 0) {
/* XXX: ewww */
c = str[len];
str[len] = '\0';
}
fprintf(f, "\t.string\t\"%s\"\n", str);
if (len != 0) {
str[len] = c;
}
}
static void asm_emit_align(void *e, int a)
{
FILE *f = e;
fprintf(f, "\t.balign\t%d\n", a);
}
static void asm_emit_data(void *e, struct data d)
{
FILE *f = e;
int off = 0;
struct marker *m = d.markers;
for_each_marker_of_type(m, LABEL)
emit_offset_label(f, m->ref, m->offset);
while ((d.len - off) >= sizeof(uint32_t)) {
fprintf(f, "\t.long\t0x%x\n",
fdt32_to_cpu(*((uint32_t *)(d.val+off))));
off += sizeof(uint32_t);
}
while ((d.len - off) >= 1) {
fprintf(f, "\t.byte\t0x%hhx\n", d.val[off]);
off += 1;
}
assert(off == d.len);
}
static void asm_emit_beginnode(void *e, const char *label)
{
FILE *f = e;
if (label) {
fprintf(f, "\t.globl\t%s\n", label);
fprintf(f, "%s:\n", label);
}
fprintf(f, "\t.long\tFDT_BEGIN_NODE\n");
}
static void asm_emit_endnode(void *e, const char *label)
{
FILE *f = e;
fprintf(f, "\t.long\tFDT_END_NODE\n");
if (label) {
fprintf(f, "\t.globl\t%s_end\n", label);
fprintf(f, "%s_end:\n", label);
}
}
static void asm_emit_property(void *e, const char *label)
{
FILE *f = e;
if (label) {
fprintf(f, "\t.globl\t%s\n", label);
fprintf(f, "%s:\n", label);
}
fprintf(f, "\t.long\tFDT_PROP\n");
}
static struct emitter asm_emitter = {
.cell = asm_emit_cell,
.string = asm_emit_string,
.align = asm_emit_align,
.data = asm_emit_data,
.beginnode = asm_emit_beginnode,
.endnode = asm_emit_endnode,
.property = asm_emit_property,
};
static int stringtable_insert(struct data *d, const char *str)
{
int i;
/* FIXME: do this more efficiently? */
for (i = 0; i < d->len; i++) {
if (streq(str, d->val + i))
return i;
}
*d = data_append_data(*d, str, strlen(str)+1);
return i;
}
static void flatten_tree(struct node *tree, struct emitter *emit,
void *etarget, struct data *strbuf,
struct version_info *vi)
{
struct property *prop;
struct node *child;
int seen_name_prop = 0;
emit->beginnode(etarget, tree->label);
if (vi->flags & FTF_FULLPATH)
emit->string(etarget, tree->fullpath, 0);
else
emit->string(etarget, tree->name, 0);
emit->align(etarget, sizeof(cell_t));
for_each_property(tree, prop) {
int nameoff;
if (streq(prop->name, "name"))
seen_name_prop = 1;
nameoff = stringtable_insert(strbuf, prop->name);
emit->property(etarget, prop->label);
emit->cell(etarget, prop->val.len);
emit->cell(etarget, nameoff);
if ((vi->flags & FTF_VARALIGN) && (prop->val.len >= 8))
emit->align(etarget, 8);
emit->data(etarget, prop->val);
emit->align(etarget, sizeof(cell_t));
}
if ((vi->flags & FTF_NAMEPROPS) && !seen_name_prop) {
emit->property(etarget, NULL);
emit->cell(etarget, tree->basenamelen+1);
emit->cell(etarget, stringtable_insert(strbuf, "name"));
if ((vi->flags & FTF_VARALIGN) && ((tree->basenamelen+1) >= 8))
emit->align(etarget, 8);
emit->string(etarget, tree->name, tree->basenamelen);
emit->align(etarget, sizeof(cell_t));
}
for_each_child(tree, child) {
flatten_tree(child, emit, etarget, strbuf, vi);
}
emit->endnode(etarget, tree->label);
}
static struct data flatten_reserve_list(struct reserve_info *reservelist,
struct version_info *vi)
{
struct reserve_info *re;
struct data d = empty_data;
static struct fdt_reserve_entry null_re = {0,0};
int j;
for (re = reservelist; re; re = re->next) {
d = data_append_re(d, &re->re);
}
/*
* Add additional reserved slots if the user asked for them.
*/
for (j = 0; j < reservenum; j++) {
d = data_append_re(d, &null_re);
}
return d;
}
static void make_fdt_header(struct fdt_header *fdt,
struct version_info *vi,
int reservesize, int dtsize, int strsize,
int boot_cpuid_phys)
{
int reserve_off;
reservesize += sizeof(struct fdt_reserve_entry);
memset(fdt, 0xff, sizeof(*fdt));
fdt->magic = cpu_to_fdt32(FDT_MAGIC);
fdt->version = cpu_to_fdt32(vi->version);
fdt->last_comp_version = cpu_to_fdt32(vi->last_comp_version);
/* Reserve map should be doubleword aligned */
reserve_off = ALIGN(vi->hdr_size, 8);
fdt->off_mem_rsvmap = cpu_to_fdt32(reserve_off);
fdt->off_dt_struct = cpu_to_fdt32(reserve_off + reservesize);
fdt->off_dt_strings = cpu_to_fdt32(reserve_off + reservesize
+ dtsize);
fdt->totalsize = cpu_to_fdt32(reserve_off + reservesize + dtsize + strsize);
if (vi->flags & FTF_BOOTCPUID)
fdt->boot_cpuid_phys = cpu_to_fdt32(boot_cpuid_phys);
if (vi->flags & FTF_STRTABSIZE)
fdt->size_dt_strings = cpu_to_fdt32(strsize);
if (vi->flags & FTF_STRUCTSIZE)
fdt->size_dt_struct = cpu_to_fdt32(dtsize);
}
void dt_to_blob(FILE *f, struct boot_info *bi, int version)
{
struct version_info *vi = NULL;
int i;
struct data blob = empty_data;
struct data reservebuf = empty_data;
struct data dtbuf = empty_data;
struct data strbuf = empty_data;
struct fdt_header fdt;
int padlen = 0;
for (i = 0; i < ARRAY_SIZE(version_table); i++) {
if (version_table[i].version == version)
vi = &version_table[i];
}
if (!vi)
die("Unknown device tree blob version %d\n", version);
flatten_tree(bi->dt, &bin_emitter, &dtbuf, &strbuf, vi);
bin_emit_cell(&dtbuf, FDT_END);
reservebuf = flatten_reserve_list(bi->reservelist, vi);
/* Make header */
make_fdt_header(&fdt, vi, reservebuf.len, dtbuf.len, strbuf.len,
bi->boot_cpuid_phys);
/*
* If the user asked for more space than is used, adjust the totalsize.
*/
if (minsize > 0) {
padlen = minsize - fdt32_to_cpu(fdt.totalsize);
if ((padlen < 0) && (quiet < 1))
fprintf(stderr,
"Warning: blob size %d >= minimum size %d\n",
fdt32_to_cpu(fdt.totalsize), minsize);
}
if (padsize > 0)
padlen = padsize;
if (padlen > 0) {
int tsize = fdt32_to_cpu(fdt.totalsize);
tsize += padlen;
fdt.totalsize = cpu_to_fdt32(tsize);
}
/*
* Assemble the blob: start with the header, add with alignment
* the reserve buffer, add the reserve map terminating zeroes,
* the device tree itself, and finally the strings.
*/
blob = data_append_data(blob, &fdt, vi->hdr_size);
blob = data_append_align(blob, 8);
blob = data_merge(blob, reservebuf);
blob = data_append_zeroes(blob, sizeof(struct fdt_reserve_entry));
blob = data_merge(blob, dtbuf);
blob = data_merge(blob, strbuf);
/*
* If the user asked for more space than is used, pad out the blob.
*/
if (padlen > 0)
blob = data_append_zeroes(blob, padlen);
fwrite(blob.val, blob.len, 1, f);
if (ferror(f))
die("Error writing device tree blob: %s\n", strerror(errno));
/*
* data_merge() frees the right-hand element so only the blob
* remains to be freed.
*/
data_free(blob);
}
static void dump_stringtable_asm(FILE *f, struct data strbuf)
{
const char *p;
int len;
p = strbuf.val;
while (p < (strbuf.val + strbuf.len)) {
len = strlen(p);
fprintf(f, "\t.string \"%s\"\n", p);
p += len+1;
}
}
void dt_to_asm(FILE *f, struct boot_info *bi, int version)
{
struct version_info *vi = NULL;
int i;
struct data strbuf = empty_data;
struct reserve_info *re;
const char *symprefix = "dt";
for (i = 0; i < ARRAY_SIZE(version_table); i++) {
if (version_table[i].version == version)
vi = &version_table[i];
}
if (!vi)
die("Unknown device tree blob version %d\n", version);
fprintf(f, "/* autogenerated by dtc, do not edit */\n\n");
fprintf(f, "#define FDT_MAGIC 0x%x\n", FDT_MAGIC);
fprintf(f, "#define FDT_BEGIN_NODE 0x%x\n", FDT_BEGIN_NODE);
fprintf(f, "#define FDT_END_NODE 0x%x\n", FDT_END_NODE);
fprintf(f, "#define FDT_PROP 0x%x\n", FDT_PROP);
fprintf(f, "#define FDT_END 0x%x\n", FDT_END);
fprintf(f, "\n");
emit_label(f, symprefix, "blob_start");
emit_label(f, symprefix, "header");
fprintf(f, "\t.long\tFDT_MAGIC\t\t\t\t/* magic */\n");
fprintf(f, "\t.long\t_%s_blob_abs_end - _%s_blob_start\t/* totalsize */\n",
symprefix, symprefix);
fprintf(f, "\t.long\t_%s_struct_start - _%s_blob_start\t/* off_dt_struct */\n",
symprefix, symprefix);
fprintf(f, "\t.long\t_%s_strings_start - _%s_blob_start\t/* off_dt_strings */\n",
symprefix, symprefix);
fprintf(f, "\t.long\t_%s_reserve_map - _%s_blob_start\t/* off_dt_strings */\n",
symprefix, symprefix);
fprintf(f, "\t.long\t%d\t\t\t\t\t/* version */\n", vi->version);
fprintf(f, "\t.long\t%d\t\t\t\t\t/* last_comp_version */\n",
vi->last_comp_version);
if (vi->flags & FTF_BOOTCPUID)
fprintf(f, "\t.long\t%i\t\t\t\t\t/* boot_cpuid_phys */\n",
bi->boot_cpuid_phys);
if (vi->flags & FTF_STRTABSIZE)
fprintf(f, "\t.long\t_%s_strings_end - _%s_strings_start\t/* size_dt_strings */\n",
symprefix, symprefix);
if (vi->flags & FTF_STRUCTSIZE)
fprintf(f, "\t.long\t_%s_struct_end - _%s_struct_start\t/* size_dt_struct */\n",
symprefix, symprefix);
/*
* Reserve map entries.
* Align the reserve map to a doubleword boundary.
* Each entry is an (address, size) pair of u64 values.
* Always supply a zero-sized temination entry.
*/
asm_emit_align(f, 8);
emit_label(f, symprefix, "reserve_map");
fprintf(f, "/* Memory reserve map from source file */\n");
/*
* Use .long on high and low halfs of u64s to avoid .quad
* as it appears .quad isn't available in some assemblers.
*/
for (re = bi->reservelist; re; re = re->next) {
if (re->label) {
fprintf(f, "\t.globl\t%s\n", re->label);
fprintf(f, "%s:\n", re->label);
}
fprintf(f, "\t.long\t0x%08x, 0x%08x\n",
(unsigned int)(re->re.address >> 32),
(unsigned int)(re->re.address & 0xffffffff));
fprintf(f, "\t.long\t0x%08x, 0x%08x\n",
(unsigned int)(re->re.size >> 32),
(unsigned int)(re->re.size & 0xffffffff));
}
for (i = 0; i < reservenum; i++) {
fprintf(f, "\t.long\t0, 0\n\t.long\t0, 0\n");
}
fprintf(f, "\t.long\t0, 0\n\t.long\t0, 0\n");
emit_label(f, symprefix, "struct_start");
flatten_tree(bi->dt, &asm_emitter, f, &strbuf, vi);
fprintf(f, "\t.long\tFDT_END\n");
emit_label(f, symprefix, "struct_end");
emit_label(f, symprefix, "strings_start");
dump_stringtable_asm(f, strbuf);
emit_label(f, symprefix, "strings_end");
emit_label(f, symprefix, "blob_end");
/*
* If the user asked for more space than is used, pad it out.
*/
if (minsize > 0) {
fprintf(f, "\t.space\t%d - (_%s_blob_end - _%s_blob_start), 0\n",
minsize, symprefix, symprefix);
}
if (padsize > 0) {
fprintf(f, "\t.space\t%d, 0\n", padsize);
}
emit_label(f, symprefix, "blob_abs_end");
data_free(strbuf);
}
struct inbuf {
char *base, *limit, *ptr;
};
static void inbuf_init(struct inbuf *inb, void *base, void *limit)
{
inb->base = base;
inb->limit = limit;
inb->ptr = inb->base;
}
static void flat_read_chunk(struct inbuf *inb, void *p, int len)
{
if ((inb->ptr + len) > inb->limit)
die("Premature end of data parsing flat device tree\n");
memcpy(p, inb->ptr, len);
inb->ptr += len;
}
static uint32_t flat_read_word(struct inbuf *inb)
{
uint32_t val;
assert(((inb->ptr - inb->base) % sizeof(val)) == 0);
flat_read_chunk(inb, &val, sizeof(val));
return fdt32_to_cpu(val);
}
static void flat_realign(struct inbuf *inb, int align)
{
int off = inb->ptr - inb->base;
inb->ptr = inb->base + ALIGN(off, align);
if (inb->ptr > inb->limit)
die("Premature end of data parsing flat device tree\n");
}
static char *flat_read_string(struct inbuf *inb)
{
int len = 0;
const char *p = inb->ptr;
char *str;
do {
if (p >= inb->limit)
die("Premature end of data parsing flat device tree\n");
len++;
} while ((*p++) != '\0');
str = strdup(inb->ptr);
inb->ptr += len;
flat_realign(inb, sizeof(uint32_t));
return str;
}
static struct data flat_read_data(struct inbuf *inb, int len)
{
struct data d = empty_data;
if (len == 0)
return empty_data;
d = data_grow_for(d, len);
d.len = len;
flat_read_chunk(inb, d.val, len);
flat_realign(inb, sizeof(uint32_t));
return d;
}
static char *flat_read_stringtable(struct inbuf *inb, int offset)
{
const char *p;
p = inb->base + offset;
while (1) {
if (p >= inb->limit || p < inb->base)
die("String offset %d overruns string table\n",
offset);
if (*p == '\0')
break;
p++;
}
return strdup(inb->base + offset);
}
static struct property *flat_read_property(struct inbuf *dtbuf,
struct inbuf *strbuf, int flags)
{
uint32_t proplen, stroff;
char *name;
struct data val;
proplen = flat_read_word(dtbuf);
stroff = flat_read_word(dtbuf);
name = flat_read_stringtable(strbuf, stroff);
if ((flags & FTF_VARALIGN) && (proplen >= 8))
flat_realign(dtbuf, 8);
val = flat_read_data(dtbuf, proplen);
return build_property(name, val, NULL);
}
static struct reserve_info *flat_read_mem_reserve(struct inbuf *inb)
{
struct reserve_info *reservelist = NULL;
struct reserve_info *new;
const char *p;
struct fdt_reserve_entry re;
/*
* Each entry is a pair of u64 (addr, size) values for 4 cell_t's.
* List terminates at an entry with size equal to zero.
*
* First pass, count entries.
*/
p = inb->ptr;
while (1) {
flat_read_chunk(inb, &re, sizeof(re));
re.address = fdt64_to_cpu(re.address);
re.size = fdt64_to_cpu(re.size);
if (re.size == 0)
break;
new = build_reserve_entry(re.address, re.size, NULL);
reservelist = add_reserve_entry(reservelist, new);
}
return reservelist;
}
static char *nodename_from_path(const char *ppath, const char *cpath)
{
int plen;
plen = strlen(ppath);
if (!strneq(ppath, cpath, plen))
die("Path \"%s\" is not valid as a child of \"%s\"\n",
cpath, ppath);
/* root node is a special case */
if (!streq(ppath, "/"))
plen++;
return strdup(cpath + plen);
}
static struct node *unflatten_tree(struct inbuf *dtbuf,
struct inbuf *strbuf,
const char *parent_flatname, int flags)
{
struct node *node;
char *flatname;
uint32_t val;
node = build_node(NULL, NULL);
flatname = flat_read_string(dtbuf);
if (flags & FTF_FULLPATH)
node->name = nodename_from_path(parent_flatname, flatname);
else
node->name = flatname;
do {
struct property *prop;
struct node *child;
val = flat_read_word(dtbuf);
switch (val) {
case FDT_PROP:
if (node->children)
fprintf(stderr, "Warning: Flat tree input has "
"subnodes preceding a property.\n");
prop = flat_read_property(dtbuf, strbuf, flags);
add_property(node, prop);
break;
case FDT_BEGIN_NODE:
child = unflatten_tree(dtbuf,strbuf, flatname, flags);
add_child(node, child);
break;
case FDT_END_NODE:
break;
case FDT_END:
die("Premature FDT_END in device tree blob\n");
break;
case FDT_NOP:
if (!(flags & FTF_NOPS))
fprintf(stderr, "Warning: NOP tag found in flat tree"
" version <16\n");
/* Ignore */
break;
default:
die("Invalid opcode word %08x in device tree blob\n",
val);
}
} while (val != FDT_END_NODE);
return node;
}
struct boot_info *dt_from_blob(const char *fname)
{
struct dtc_file *dtcf;
uint32_t magic, totalsize, version, size_dt, boot_cpuid_phys;
uint32_t off_dt, off_str, off_mem_rsvmap;
int rc;
char *blob;
struct fdt_header *fdt;
char *p;
struct inbuf dtbuf, strbuf;
struct inbuf memresvbuf;
int sizeleft;
struct reserve_info *reservelist;
struct node *tree;
uint32_t val;
int flags = 0;
dtcf = dtc_open_file(fname, NULL);
rc = fread(&magic, sizeof(magic), 1, dtcf->file);
if (ferror(dtcf->file))
die("Error reading DT blob magic number: %s\n",
strerror(errno));
if (rc < 1) {
if (feof(dtcf->file))
die("EOF reading DT blob magic number\n");
else
die("Mysterious short read reading magic number\n");
}
magic = fdt32_to_cpu(magic);
if (magic != FDT_MAGIC)
die("Blob has incorrect magic number\n");
rc = fread(&totalsize, sizeof(totalsize), 1, dtcf->file);
if (ferror(dtcf->file))
die("Error reading DT blob size: %s\n", strerror(errno));
if (rc < 1) {
if (feof(dtcf->file))
die("EOF reading DT blob size\n");
else
die("Mysterious short read reading blob size\n");
}
totalsize = fdt32_to_cpu(totalsize);
if (totalsize < FDT_V1_SIZE)
die("DT blob size (%d) is too small\n", totalsize);
blob = xmalloc(totalsize);
fdt = (struct fdt_header *)blob;
fdt->magic = cpu_to_fdt32(magic);
fdt->totalsize = cpu_to_fdt32(totalsize);
sizeleft = totalsize - sizeof(magic) - sizeof(totalsize);
p = blob + sizeof(magic) + sizeof(totalsize);
while (sizeleft) {
if (feof(dtcf->file))
die("EOF before reading %d bytes of DT blob\n",
totalsize);
rc = fread(p, 1, sizeleft, dtcf->file);
if (ferror(dtcf->file))
die("Error reading DT blob: %s\n",
strerror(errno));
sizeleft -= rc;
p += rc;
}
off_dt = fdt32_to_cpu(fdt->off_dt_struct);
off_str = fdt32_to_cpu(fdt->off_dt_strings);
off_mem_rsvmap = fdt32_to_cpu(fdt->off_mem_rsvmap);
version = fdt32_to_cpu(fdt->version);
boot_cpuid_phys = fdt32_to_cpu(fdt->boot_cpuid_phys);
if (off_mem_rsvmap >= totalsize)
die("Mem Reserve structure offset exceeds total size\n");
if (off_dt >= totalsize)
die("DT structure offset exceeds total size\n");
if (off_str > totalsize)
die("String table offset exceeds total size\n");
if (version >= 3) {
uint32_t size_str = fdt32_to_cpu(fdt->size_dt_strings);
if (off_str+size_str > totalsize)
die("String table extends past total size\n");
inbuf_init(&strbuf, blob + off_str, blob + off_str + size_str);
} else {
inbuf_init(&strbuf, blob + off_str, blob + totalsize);
}
if (version >= 17) {
size_dt = fdt32_to_cpu(fdt->size_dt_struct);
if (off_dt+size_dt > totalsize)
die("Structure block extends past total size\n");
}
if (version < 16) {
flags |= FTF_FULLPATH | FTF_NAMEPROPS | FTF_VARALIGN;
} else {
flags |= FTF_NOPS;
}
inbuf_init(&memresvbuf,
blob + off_mem_rsvmap, blob + totalsize);
inbuf_init(&dtbuf, blob + off_dt, blob + totalsize);
reservelist = flat_read_mem_reserve(&memresvbuf);
val = flat_read_word(&dtbuf);
if (val != FDT_BEGIN_NODE)
die("Device tree blob doesn't begin with FDT_BEGIN_NODE (begins with 0x%08x)\n", val);
tree = unflatten_tree(&dtbuf, &strbuf, "", flags);
val = flat_read_word(&dtbuf);
if (val != FDT_END)
die("Device tree blob doesn't end with FDT_END\n");
free(blob);
dtc_close_file(dtcf);
return build_boot_info(reservelist, tree, boot_cpuid_phys);
}