2
0
mirror of https://github.com/edk2-porting/linux-next.git synced 2024-12-16 01:04:08 +08:00
linux-next/scripts/dtc/treesource.c
Rob Herring 3eb619b2f7 scripts/dtc: Update to upstream version v1.6.0-11-g9d7888cbf19c
Sync with upstream dtc primarily to pickup the I2C bus check fixes. The
interrupt_provider check is noisy, so turn it off for now.

This adds the following commits from upstream:

9d7888cbf19c dtc: Consider one-character strings as strings
8259d59f59de checks: Improve i2c reg property checking
fdabcf2980a4 checks: Remove warning for I2C_OWN_SLAVE_ADDRESS
2478b1652c8d libfdt: add extern "C" for C++
f68bfc2668b2 libfdt: trivial typo fix
7be250b4d059 libfdt: Correct condition for reordering blocks
81e0919a3e21 checks: Add interrupt provider test
85e5d839847a Makefile: when building libfdt only, do not add unneeded deps
b28464a550c5 Fix some potential unaligned accesses in dtc

Signed-off-by: Rob Herring <robh@kernel.org>
2020-06-30 08:42:26 -06:00

346 lines
6.8 KiB
C

// SPDX-License-Identifier: GPL-2.0-or-later
/*
* (C) Copyright David Gibson <dwg@au1.ibm.com>, IBM Corporation. 2005.
*/
#include "dtc.h"
#include "srcpos.h"
extern FILE *yyin;
extern int yyparse(void);
extern YYLTYPE yylloc;
struct dt_info *parser_output;
bool treesource_error;
struct dt_info *dt_from_source(const char *fname)
{
parser_output = NULL;
treesource_error = false;
srcfile_push(fname);
yyin = current_srcfile->f;
yylloc.file = current_srcfile;
if (yyparse() != 0)
die("Unable to parse input tree\n");
if (treesource_error)
die("Syntax error parsing input tree\n");
return parser_output;
}
static void write_prefix(FILE *f, int level)
{
int i;
for (i = 0; i < level; i++)
fputc('\t', f);
}
static bool isstring(char c)
{
return (isprint((unsigned char)c)
|| (c == '\0')
|| strchr("\a\b\t\n\v\f\r", c));
}
static void write_propval_string(FILE *f, const char *s, size_t len)
{
const char *end = s + len - 1;
if (!len)
return;
assert(*end == '\0');
fprintf(f, "\"");
while (s < end) {
char c = *s++;
switch (c) {
case '\a':
fprintf(f, "\\a");
break;
case '\b':
fprintf(f, "\\b");
break;
case '\t':
fprintf(f, "\\t");
break;
case '\n':
fprintf(f, "\\n");
break;
case '\v':
fprintf(f, "\\v");
break;
case '\f':
fprintf(f, "\\f");
break;
case '\r':
fprintf(f, "\\r");
break;
case '\\':
fprintf(f, "\\\\");
break;
case '\"':
fprintf(f, "\\\"");
break;
case '\0':
fprintf(f, "\\0");
break;
default:
if (isprint((unsigned char)c))
fprintf(f, "%c", c);
else
fprintf(f, "\\x%02"PRIx8, c);
}
}
fprintf(f, "\"");
}
static void write_propval_int(FILE *f, const char *p, size_t len, size_t width)
{
const char *end = p + len;
assert(len % width == 0);
for (; p < end; p += width) {
switch (width) {
case 1:
fprintf(f, "%02"PRIx8, *(const uint8_t*)p);
break;
case 2:
fprintf(f, "0x%02"PRIx16, dtb_ld16(p));
break;
case 4:
fprintf(f, "0x%02"PRIx32, dtb_ld32(p));
break;
case 8:
fprintf(f, "0x%02"PRIx64, dtb_ld64(p));
break;
}
if (p + width < end)
fputc(' ', f);
}
}
static bool has_data_type_information(struct marker *m)
{
return m->type >= TYPE_UINT8;
}
static struct marker *next_type_marker(struct marker *m)
{
while (m && !has_data_type_information(m))
m = m->next;
return m;
}
size_t type_marker_length(struct marker *m)
{
struct marker *next = next_type_marker(m->next);
if (next)
return next->offset - m->offset;
return 0;
}
static const char *delim_start[] = {
[TYPE_UINT8] = "[",
[TYPE_UINT16] = "/bits/ 16 <",
[TYPE_UINT32] = "<",
[TYPE_UINT64] = "/bits/ 64 <",
[TYPE_STRING] = "",
};
static const char *delim_end[] = {
[TYPE_UINT8] = "]",
[TYPE_UINT16] = ">",
[TYPE_UINT32] = ">",
[TYPE_UINT64] = ">",
[TYPE_STRING] = "",
};
static enum markertype guess_value_type(struct property *prop)
{
int len = prop->val.len;
const char *p = prop->val.val;
struct marker *m = prop->val.markers;
int nnotstring = 0, nnul = 0;
int nnotstringlbl = 0, nnotcelllbl = 0;
int i;
for (i = 0; i < len; i++) {
if (! isstring(p[i]))
nnotstring++;
if (p[i] == '\0')
nnul++;
}
for_each_marker_of_type(m, LABEL) {
if ((m->offset > 0) && (prop->val.val[m->offset - 1] != '\0'))
nnotstringlbl++;
if ((m->offset % sizeof(cell_t)) != 0)
nnotcelllbl++;
}
if ((p[len-1] == '\0') && (nnotstring == 0) && (nnul <= (len-nnul))
&& (nnotstringlbl == 0)) {
return TYPE_STRING;
} else if (((len % sizeof(cell_t)) == 0) && (nnotcelllbl == 0)) {
return TYPE_UINT32;
}
return TYPE_UINT8;
}
static void write_propval(FILE *f, struct property *prop)
{
size_t len = prop->val.len;
struct marker *m = prop->val.markers;
struct marker dummy_marker;
enum markertype emit_type = TYPE_NONE;
char *srcstr;
if (len == 0) {
fprintf(f, ";");
if (annotate) {
srcstr = srcpos_string_first(prop->srcpos, annotate);
if (srcstr) {
fprintf(f, " /* %s */", srcstr);
free(srcstr);
}
}
fprintf(f, "\n");
return;
}
fprintf(f, " =");
if (!next_type_marker(m)) {
/* data type information missing, need to guess */
dummy_marker.type = guess_value_type(prop);
dummy_marker.next = prop->val.markers;
dummy_marker.offset = 0;
dummy_marker.ref = NULL;
m = &dummy_marker;
}
for_each_marker(m) {
size_t chunk_len = (m->next ? m->next->offset : len) - m->offset;
size_t data_len = type_marker_length(m) ? : len - m->offset;
const char *p = &prop->val.val[m->offset];
if (has_data_type_information(m)) {
emit_type = m->type;
fprintf(f, " %s", delim_start[emit_type]);
} else if (m->type == LABEL)
fprintf(f, " %s:", m->ref);
else if (m->offset)
fputc(' ', f);
if (emit_type == TYPE_NONE) {
assert(chunk_len == 0);
continue;
}
switch(emit_type) {
case TYPE_UINT16:
write_propval_int(f, p, chunk_len, 2);
break;
case TYPE_UINT32:
write_propval_int(f, p, chunk_len, 4);
break;
case TYPE_UINT64:
write_propval_int(f, p, chunk_len, 8);
break;
case TYPE_STRING:
write_propval_string(f, p, chunk_len);
break;
default:
write_propval_int(f, p, chunk_len, 1);
}
if (chunk_len == data_len) {
size_t pos = m->offset + chunk_len;
fprintf(f, pos == len ? "%s" : "%s,",
delim_end[emit_type] ? : "");
emit_type = TYPE_NONE;
}
}
fprintf(f, ";");
if (annotate) {
srcstr = srcpos_string_first(prop->srcpos, annotate);
if (srcstr) {
fprintf(f, " /* %s */", srcstr);
free(srcstr);
}
}
fprintf(f, "\n");
}
static void write_tree_source_node(FILE *f, struct node *tree, int level)
{
struct property *prop;
struct node *child;
struct label *l;
char *srcstr;
write_prefix(f, level);
for_each_label(tree->labels, l)
fprintf(f, "%s: ", l->label);
if (tree->name && (*tree->name))
fprintf(f, "%s {", tree->name);
else
fprintf(f, "/ {");
if (annotate) {
srcstr = srcpos_string_first(tree->srcpos, annotate);
if (srcstr) {
fprintf(f, " /* %s */", srcstr);
free(srcstr);
}
}
fprintf(f, "\n");
for_each_property(tree, prop) {
write_prefix(f, level+1);
for_each_label(prop->labels, l)
fprintf(f, "%s: ", l->label);
fprintf(f, "%s", prop->name);
write_propval(f, prop);
}
for_each_child(tree, child) {
fprintf(f, "\n");
write_tree_source_node(f, child, level+1);
}
write_prefix(f, level);
fprintf(f, "};");
if (annotate) {
srcstr = srcpos_string_last(tree->srcpos, annotate);
if (srcstr) {
fprintf(f, " /* %s */", srcstr);
free(srcstr);
}
}
fprintf(f, "\n");
}
void dt_to_source(FILE *f, struct dt_info *dti)
{
struct reserve_info *re;
fprintf(f, "/dts-v1/;\n\n");
for (re = dti->reservelist; re; re = re->next) {
struct label *l;
for_each_label(re->labels, l)
fprintf(f, "%s: ", l->label);
fprintf(f, "/memreserve/\t0x%016llx 0x%016llx;\n",
(unsigned long long)re->address,
(unsigned long long)re->size);
}
write_tree_source_node(f, dti->dt, 0);
}