freebsd-nq/usr.bin/dtc/fdt.cc
Kyle Evans ca84c67cd0 dtc(1): Update to upstream ea3c233
Highlights of this update:
- /__local_fixups__ is now generated to be GPL dtc and libfdt compliant
- Compiling with -@ will now cause dtc to assign phandles to all labelled
  nodes
- /include/ and /incbin/ now handle absolute paths correctly
- The manpage now has information about overlays, including how to apply
  them and how to generate them
- Syntactic sugar for overlays is now supported, allowing an overlay DTS
  like:

=
/dts-v1/;
/plugin/;

&foo {
    foo,status = "okay";
};
=

to generate a fragment targetting <&foo>.
2018-01-19 21:20:24 +00:00

2021 lines
43 KiB
C++

/*-
* SPDX-License-Identifier: BSD-2-Clause-FreeBSD
*
* Copyright (c) 2013 David Chisnall
* All rights reserved.
*
* This software was developed by SRI International and the University of
* Cambridge Computer Laboratory under DARPA/AFRL contract (FA8750-10-C-0237)
* ("CTSRD"), as part of the DARPA CRASH research programme.
*
* Redistribution and use in source and binary forms, with or without
* modification, are permitted provided that the following conditions
* are met:
* 1. Redistributions of source code must retain the above copyright
* notice, this list of conditions and the following disclaimer.
* 2. Redistributions in binary form must reproduce the above copyright
* notice, this list of conditions and the following disclaimer in the
* documentation and/or other materials provided with the distribution.
*
* THIS SOFTWARE IS PROVIDED BY THE AUTHOR AND CONTRIBUTORS ``AS IS'' AND
* ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE
* IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR PURPOSE
* ARE DISCLAIMED. IN NO EVENT SHALL THE AUTHOR OR CONTRIBUTORS BE LIABLE
* FOR ANY DIRECT, INDIRECT, INCIDENTAL, SPECIAL, EXEMPLARY, OR CONSEQUENTIAL
* DAMAGES (INCLUDING, BUT NOT LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS
* OR SERVICES; LOSS OF USE, DATA, OR PROFITS; OR BUSINESS INTERRUPTION)
* HOWEVER CAUSED AND ON ANY THEORY OF LIABILITY, WHETHER IN CONTRACT, STRICT
* LIABILITY, OR TORT (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY
* OUT OF THE USE OF THIS SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF
* SUCH DAMAGE.
*
* $FreeBSD$
*/
#define __STDC_LIMIT_MACROS 1
#include "fdt.hh"
#include "dtb.hh"
#include <algorithm>
#include <sstream>
#include <ctype.h>
#include <fcntl.h>
#include <inttypes.h>
#include <libgen.h>
#include <stdio.h>
#include <stdlib.h>
#include <unistd.h>
#include <sys/types.h>
#include <sys/stat.h>
#include <errno.h>
using std::string;
namespace dtc
{
namespace fdt
{
uint32_t
property_value::get_as_uint32()
{
if (byte_data.size() != 4)
{
return 0;
}
uint32_t v = 0;
v &= byte_data[0] << 24;
v &= byte_data[1] << 16;
v &= byte_data[2] << 8;
v &= byte_data[3] << 0;
return v;
}
void
property_value::push_to_buffer(byte_buffer &buffer)
{
if (!byte_data.empty())
{
buffer.insert(buffer.end(), byte_data.begin(), byte_data.end());
}
else
{
push_string(buffer, string_data, true);
// Trailing nul
buffer.push_back(0);
}
}
void
property_value::write_dts(FILE *file)
{
resolve_type();
switch (type)
{
default:
assert(0 && "Invalid type");
case STRING:
case STRING_LIST:
case CROSS_REFERENCE:
write_as_string(file);
break;
case PHANDLE:
write_as_cells(file);
break;
case BINARY:
if (byte_data.size() % 4 == 0)
{
write_as_cells(file);
break;
}
write_as_bytes(file);
break;
}
}
void
property_value::resolve_type()
{
if (type != UNKNOWN)
{
return;
}
if (byte_data.empty())
{
type = STRING;
return;
}
if (byte_data.back() == 0)
{
bool is_all_printable = true;
int nuls = 0;
int bytes = 0;
bool lastWasNull = false;
for (auto i : byte_data)
{
bytes++;
is_all_printable &= (i == '\0') || isprint(i);
if (i == '\0')
{
// If there are two nulls in a row, then we're probably binary.
if (lastWasNull)
{
type = BINARY;
return;
}
nuls++;
lastWasNull = true;
}
else
{
lastWasNull = false;
}
if (!is_all_printable)
{
break;
}
}
if ((is_all_printable && (bytes > nuls)) || bytes == 0)
{
type = STRING;
if (nuls > 1)
{
type = STRING_LIST;
}
return;
}
}
type = BINARY;
}
size_t
property_value::size()
{
if (!byte_data.empty())
{
return byte_data.size();
}
return string_data.size() + 1;
}
void
property_value::write_as_string(FILE *file)
{
putc('"', file);
if (byte_data.empty())
{
fputs(string_data.c_str(), file);
}
else
{
bool hasNull = (byte_data.back() == '\0');
// Remove trailing null bytes from the string before printing as dts.
if (hasNull)
{
byte_data.pop_back();
}
for (auto i : byte_data)
{
// FIXME Escape tabs, newlines, and so on.
if (i == '\0')
{
fputs("\", \"", file);
continue;
}
putc(i, file);
}
if (hasNull)
{
byte_data.push_back('\0');
}
}
putc('"', file);
}
void
property_value::write_as_cells(FILE *file)
{
putc('<', file);
assert((byte_data.size() % 4) == 0);
for (auto i=byte_data.begin(), e=byte_data.end(); i!=e ; ++i)
{
uint32_t v = 0;
v = (v << 8) | *i;
++i;
v = (v << 8) | *i;
++i;
v = (v << 8) | *i;
++i;
v = (v << 8) | *i;
fprintf(file, "0x%" PRIx32, v);
if (i+1 != e)
{
putc(' ', file);
}
}
putc('>', file);
}
void
property_value::write_as_bytes(FILE *file)
{
putc('[', file);
for (auto i=byte_data.begin(), e=byte_data.end(); i!=e ; i++)
{
fprintf(file, "%02hhx", *i);
if (i+1 != e)
{
putc(' ', file);
}
}
putc(']', file);
}
void
property::parse_string(text_input_buffer &input)
{
property_value v;
assert(*input == '"');
++input;
std::vector<char> bytes;
bool isEscaped = false;
while (char c = *input)
{
if (c == '"' && !isEscaped)
{
input.consume('"');
break;
}
isEscaped = (c == '\\');
bytes.push_back(c);
++input;
}
v.string_data = string(bytes.begin(), bytes.end());
values.push_back(v);
}
void
property::parse_cells(text_input_buffer &input, int cell_size)
{
assert(*input == '<');
++input;
property_value v;
input.next_token();
while (!input.consume('>'))
{
input.next_token();
// If this is a phandle then we need to get the name of the
// referenced node
if (input.consume('&'))
{
if (cell_size != 32)
{
input.parse_error("reference only permitted in 32-bit arrays");
valid = false;
return;
}
input.next_token();
string referenced;
if (!input.consume('{'))
{
referenced = input.parse_node_name();
}
else
{
referenced = input.parse_to('}');
input.consume('}');
}
if (referenced.empty())
{
input.parse_error("Expected node name");
valid = false;
return;
}
input.next_token();
// If we already have some bytes, make the phandle a
// separate component.
if (!v.byte_data.empty())
{
values.push_back(v);
v = property_value();
}
v.string_data = referenced;
v.type = property_value::PHANDLE;
values.push_back(v);
v = property_value();
}
else
{
//FIXME: We should support labels in the middle
//of these, but we don't.
unsigned long long val;
if (!input.consume_integer_expression(val))
{
input.parse_error("Expected numbers in array of cells");
valid = false;
return;
}
switch (cell_size)
{
case 8:
v.byte_data.push_back(val);
break;
case 16:
push_big_endian(v.byte_data, (uint16_t)val);
break;
case 32:
push_big_endian(v.byte_data, (uint32_t)val);
break;
case 64:
push_big_endian(v.byte_data, (uint64_t)val);
break;
default:
assert(0 && "Invalid cell size!");
}
input.next_token();
}
}
// Don't store an empty string value here.
if (v.byte_data.size() > 0)
{
values.push_back(v);
}
}
void
property::parse_bytes(text_input_buffer &input)
{
assert(*input == '[');
++input;
property_value v;
input.next_token();
while (!input.consume(']'))
{
{
//FIXME: We should support
//labels in the middle of
//these, but we don't.
uint8_t val;
if (!input.consume_hex_byte(val))
{
input.parse_error("Expected hex bytes in array of bytes");
valid = false;
return;
}
v.byte_data.push_back(val);
input.next_token();
}
}
values.push_back(v);
}
void
property::parse_reference(text_input_buffer &input)
{
assert(*input == '&');
++input;
input.next_token();
property_value v;
v.string_data = input.parse_node_name();
if (v.string_data.empty())
{
input.parse_error("Expected node name");
valid = false;
return;
}
v.type = property_value::CROSS_REFERENCE;
values.push_back(v);
}
property::property(input_buffer &structs, input_buffer &strings)
{
uint32_t name_offset;
uint32_t length;
valid = structs.consume_binary(length) &&
structs.consume_binary(name_offset);
if (!valid)
{
fprintf(stderr, "Failed to read property\n");
return;
}
// Find the name
input_buffer name_buffer = strings.buffer_from_offset(name_offset);
if (name_buffer.finished())
{
fprintf(stderr, "Property name offset %" PRIu32
" is past the end of the strings table\n",
name_offset);
valid = false;
return;
}
key = name_buffer.parse_to(0);
// If we're empty, do not push anything as value.
if (!length)
return;
// Read the value
uint8_t byte;
property_value v;
for (uint32_t i=0 ; i<length ; i++)
{
if (!(valid = structs.consume_binary(byte)))
{
fprintf(stderr, "Failed to read property value\n");
return;
}
v.byte_data.push_back(byte);
}
values.push_back(v);
}
void property::parse_define(text_input_buffer &input, define_map *defines)
{
input.consume('$');
if (!defines)
{
input.parse_error("No predefined properties to match name\n");
valid = false;
return;
}
string name = input.parse_property_name();
define_map::iterator found;
if ((name == string()) ||
((found = defines->find(name)) == defines->end()))
{
input.parse_error("Undefined property name\n");
valid = false;
return;
}
values.push_back((*found).second->values[0]);
}
property::property(text_input_buffer &input,
string &&k,
string_set &&l,
bool semicolonTerminated,
define_map *defines) : key(k), labels(l), valid(true)
{
do {
input.next_token();
switch (*input)
{
case '$':
{
parse_define(input, defines);
if (valid)
{
break;
}
}
default:
input.parse_error("Invalid property value.");
valid = false;
return;
case '/':
{
if (input.consume("/incbin/(\""))
{
auto loc = input.location();
std::string filename = input.parse_to('"');
if (!(valid = input.consume('"')))
{
loc.report_error("Syntax error, expected '\"' to terminate /incbin/(");
return;
}
property_value v;
if (!(valid = input.read_binary_file(filename, v.byte_data)))
{
input.parse_error("Cannot open binary include file");
return;
}
if (!(valid &= input.consume(')')))
{
input.parse_error("Syntax error, expected ')' to terminate /incbin/(");
return;
}
values.push_back(v);
break;
}
unsigned long long bits = 0;
valid = input.consume("/bits/");
input.next_token();
valid &= input.consume_integer(bits);
if ((bits != 8) &&
(bits != 16) &&
(bits != 32) &&
(bits != 64)) {
input.parse_error("Invalid size for elements");
valid = false;
}
if (!valid) return;
input.next_token();
if (*input != '<')
{
input.parse_error("/bits/ directive is only valid on arrays");
valid = false;
return;
}
parse_cells(input, bits);
break;
}
case '"':
parse_string(input);
break;
case '<':
parse_cells(input, 32);
break;
case '[':
parse_bytes(input);
break;
case '&':
parse_reference(input);
break;
case ';':
{
break;
}
}
input.next_token();
} while (input.consume(','));
if (semicolonTerminated && !input.consume(';'))
{
input.parse_error("Expected ; at end of property");
valid = false;
}
}
property_ptr
property::parse_dtb(input_buffer &structs, input_buffer &strings)
{
property_ptr p(new property(structs, strings));
if (!p->valid)
{
p = nullptr;
}
return p;
}
property_ptr
property::parse(text_input_buffer &input, string &&key, string_set &&label,
bool semicolonTerminated, define_map *defines)
{
property_ptr p(new property(input,
std::move(key),
std::move(label),
semicolonTerminated,
defines));
if (!p->valid)
{
p = nullptr;
}
return p;
}
void
property::write(dtb::output_writer &writer, dtb::string_table &strings)
{
writer.write_token(dtb::FDT_PROP);
byte_buffer value_buffer;
for (value_iterator i=begin(), e=end() ; i!=e ; ++i)
{
i->push_to_buffer(value_buffer);
}
writer.write_data((uint32_t)value_buffer.size());
writer.write_comment(key);
writer.write_data(strings.add_string(key));
writer.write_data(value_buffer);
}
bool
property_value::try_to_merge(property_value &other)
{
resolve_type();
switch (type)
{
case UNKNOWN:
__builtin_unreachable();
assert(0);
return false;
case EMPTY:
*this = other;
case STRING:
case STRING_LIST:
case CROSS_REFERENCE:
return false;
case PHANDLE:
case BINARY:
if (other.type == PHANDLE || other.type == BINARY)
{
type = BINARY;
byte_data.insert(byte_data.end(), other.byte_data.begin(),
other.byte_data.end());
return true;
}
}
return false;
}
void
property::write_dts(FILE *file, int indent)
{
for (int i=0 ; i<indent ; i++)
{
putc('\t', file);
}
#ifdef PRINT_LABELS
for (auto &l : labels)
{
fputs(l.c_str(), file);
fputs(": ", file);
}
#endif
if (key != string())
{
fputs(key.c_str(), file);
}
if (!values.empty())
{
std::vector<property_value> *vals = &values;
std::vector<property_value> v;
// If we've got multiple values then try to merge them all together.
if (values.size() > 1)
{
vals = &v;
v.push_back(values.front());
for (auto i=(++begin()), e=end() ; i!=e ; ++i)
{
if (!v.back().try_to_merge(*i))
{
v.push_back(*i);
}
}
}
fputs(" = ", file);
for (auto i=vals->begin(), e=vals->end() ; i!=e ; ++i)
{
i->write_dts(file);
if (i+1 != e)
{
putc(',', file);
putc(' ', file);
}
}
}
fputs(";\n", file);
}
size_t
property::offset_of_value(property_value &val)
{
size_t off = 0;
for (auto &v : values)
{
if (&v == &val)
{
return off;
}
off += v.size();
}
return -1;
}
string
node::parse_name(text_input_buffer &input, bool &is_property, const char *error)
{
if (!valid)
{
return string();
}
input.next_token();
if (is_property)
{
return input.parse_property_name();
}
string n = input.parse_node_or_property_name(is_property);
if (n.empty())
{
if (n.empty())
{
input.parse_error(error);
valid = false;
}
}
return n;
}
void
node::visit(std::function<void(node&)> fn)
{
fn(*this);
for (auto &&c : children)
{
c->visit(fn);
}
}
node::node(input_buffer &structs, input_buffer &strings) : valid(true)
{
std::vector<char> bytes;
while (structs[0] != '\0' && structs[0] != '@')
{
bytes.push_back(structs[0]);
++structs;
}
name = string(bytes.begin(), bytes.end());
bytes.clear();
if (structs[0] == '@')
{
++structs;
while (structs[0] != '\0')
{
bytes.push_back(structs[0]);
++structs;
}
unit_address = string(bytes.begin(), bytes.end());
}
++structs;
uint32_t token;
while (structs.consume_binary(token))
{
switch (token)
{
default:
fprintf(stderr, "Unexpected token 0x%" PRIx32
" while parsing node.\n", token);
valid = false;
return;
// Child node, parse it.
case dtb::FDT_BEGIN_NODE:
{
node_ptr child = node::parse_dtb(structs, strings);
if (child == 0)
{
valid = false;
return;
}
children.push_back(std::move(child));
break;
}
// End of this node, no errors.
case dtb::FDT_END_NODE:
return;
// Property, parse it.
case dtb::FDT_PROP:
{
property_ptr prop = property::parse_dtb(structs, strings);
if (prop == 0)
{
valid = false;
return;
}
props.push_back(prop);
break;
}
break;
// End of structs table. Should appear after
// the end of the last node.
case dtb::FDT_END:
fprintf(stderr, "Unexpected FDT_END token while parsing node.\n");
valid = false;
return;
// NOPs are padding. Ignore them.
case dtb::FDT_NOP:
break;
}
}
fprintf(stderr, "Failed to read token from structs table while parsing node.\n");
valid = false;
return;
}
node::node(const string &n,
const std::vector<property_ptr> &p)
: name(n)
{
props.insert(props.begin(), p.begin(), p.end());
}
node_ptr node::create_special_node(const string &name,
const std::vector<property_ptr> &props)
{
node_ptr n(new node(name, props));
return n;
}
node::node(text_input_buffer &input,
string &&n,
std::unordered_set<string> &&l,
string &&a,
define_map *defines)
: labels(l), name(n), unit_address(a), valid(true)
{
if (!input.consume('{'))
{
input.parse_error("Expected { to start new device tree node.\n");
}
input.next_token();
while (valid && !input.consume('}'))
{
// flag set if we find any characters that are only in
// the property name character set, not the node
bool is_property = false;
string child_name, child_address;
std::unordered_set<string> child_labels;
auto parse_delete = [&](const char *expected, bool at)
{
if (child_name == string())
{
input.parse_error(expected);
valid = false;
return;
}
input.next_token();
if (at && input.consume('@'))
{
child_name += '@';
child_name += parse_name(input, is_property, "Expected unit address");
}
if (!input.consume(';'))
{
input.parse_error("Expected semicolon");
valid = false;
return;
}
input.next_token();
};
if (input.consume("/delete-node/"))
{
input.next_token();
child_name = input.parse_node_name();
parse_delete("Expected node name", true);
if (valid)
{
deleted_children.insert(child_name);
}
continue;
}
if (input.consume("/delete-property/"))
{
input.next_token();
child_name = input.parse_property_name();
parse_delete("Expected property name", false);
if (valid)
{
deleted_props.insert(child_name);
}
continue;
}
child_name = parse_name(input, is_property,
"Expected property or node name");
while (input.consume(':'))
{
// Node labels can contain any characters? The
// spec doesn't say, so we guess so...
is_property = false;
child_labels.insert(std::move(child_name));
child_name = parse_name(input, is_property, "Expected property or node name");
}
if (input.consume('@'))
{
child_address = parse_name(input, is_property, "Expected unit address");
}
if (!valid)
{
return;
}
input.next_token();
// If we're parsing a property, then we must actually do that.
if (input.consume('='))
{
property_ptr p = property::parse(input, std::move(child_name),
std::move(child_labels), true, defines);
if (p == 0)
{
valid = false;
}
else
{
props.push_back(p);
}
}
else if (!is_property && *input == ('{'))
{
node_ptr child = node::parse(input, std::move(child_name),
std::move(child_labels), std::move(child_address), defines);
if (child)
{
children.push_back(std::move(child));
}
else
{
valid = false;
}
}
else if (input.consume(';'))
{
props.push_back(property_ptr(new property(std::move(child_name), std::move(child_labels))));
}
else
{
input.parse_error("Error parsing property. Expected property value");
valid = false;
}
input.next_token();
}
input.next_token();
input.consume(';');
}
bool
node::cmp_properties(property_ptr &p1, property_ptr &p2)
{
return p1->get_key() < p2->get_key();
}
bool
node::cmp_children(node_ptr &c1, node_ptr &c2)
{
if (c1->name == c2->name)
{
return c1->unit_address < c2->unit_address;
}
return c1->name < c2->name;
}
void
node::sort()
{
std::sort(property_begin(), property_end(), cmp_properties);
std::sort(child_begin(), child_end(), cmp_children);
for (auto &c : child_nodes())
{
c->sort();
}
}
node_ptr
node::parse(text_input_buffer &input,
string &&name,
string_set &&label,
string &&address,
define_map *defines)
{
node_ptr n(new node(input,
std::move(name),
std::move(label),
std::move(address),
defines));
if (!n->valid)
{
n = 0;
}
return n;
}
node_ptr
node::parse_dtb(input_buffer &structs, input_buffer &strings)
{
node_ptr n(new node(structs, strings));
if (!n->valid)
{
n = 0;
}
return n;
}
property_ptr
node::get_property(const string &key)
{
for (auto &i : props)
{
if (i->get_key() == key)
{
return i;
}
}
return 0;
}
void
node::merge_node(node_ptr &other)
{
for (auto &l : other->labels)
{
labels.insert(l);
}
// Note: this is an O(n*m) operation. It might be sensible to
// optimise this if we find that there are nodes with very
// large numbers of properties, but for typical usage the
// entire vector will fit (easily) into cache, so iterating
// over it repeatedly isn't that expensive.
for (auto &p : other->properties())
{
bool found = false;
for (auto &mp : properties())
{
if (mp->get_key() == p->get_key())
{
mp = p;
found = true;
break;
}
}
if (!found)
{
add_property(p);
}
}
for (auto &c : other->children)
{
bool found = false;
for (auto &i : children)
{
if (i->name == c->name && i->unit_address == c->unit_address)
{
i->merge_node(c);
found = true;
break;
}
}
if (!found)
{
children.push_back(std::move(c));
}
}
children.erase(std::remove_if(children.begin(), children.end(),
[&](const node_ptr &p) {
string full_name = p->name;
if (p->unit_address != string())
{
full_name += '@';
full_name += p->unit_address;
}
if (other->deleted_children.count(full_name) > 0)
{
other->deleted_children.erase(full_name);
return true;
}
return false;
}), children.end());
props.erase(std::remove_if(props.begin(), props.end(),
[&](const property_ptr &p) {
if (other->deleted_props.count(p->get_key()) > 0)
{
other->deleted_props.erase(p->get_key());
return true;
}
return false;
}), props.end());
}
void
node::write(dtb::output_writer &writer, dtb::string_table &strings)
{
writer.write_token(dtb::FDT_BEGIN_NODE);
byte_buffer name_buffer;
push_string(name_buffer, name);
if (unit_address != string())
{
name_buffer.push_back('@');
push_string(name_buffer, unit_address);
}
writer.write_comment(name);
writer.write_data(name_buffer);
writer.write_data((uint8_t)0);
for (auto p : properties())
{
p->write(writer, strings);
}
for (auto &c : child_nodes())
{
c->write(writer, strings);
}
writer.write_token(dtb::FDT_END_NODE);
}
void
node::write_dts(FILE *file, int indent)
{
for (int i=0 ; i<indent ; i++)
{
putc('\t', file);
}
#ifdef PRINT_LABELS
for (auto &label : labels)
{
fprintf(file, "%s: ", label.c_str());
}
#endif
if (name != string())
{
fputs(name.c_str(), file);
}
if (unit_address != string())
{
putc('@', file);
fputs(unit_address.c_str(), file);
}
fputs(" {\n\n", file);
for (auto p : properties())
{
p->write_dts(file, indent+1);
}
for (auto &c : child_nodes())
{
c->write_dts(file, indent+1);
}
for (int i=0 ; i<indent ; i++)
{
putc('\t', file);
}
fputs("};\n", file);
}
void
device_tree::collect_names_recursive(node_ptr &n, node_path &path)
{
path.push_back(std::make_pair(n->name, n->unit_address));
for (const string &name : n->labels)
{
if (name != string())
{
auto iter = node_names.find(name);
if (iter == node_names.end())
{
node_names.insert(std::make_pair(name, n.get()));
node_paths.insert(std::make_pair(name, path));
}
else
{
node_names.erase(iter);
auto i = node_paths.find(name);
if (i != node_paths.end())
{
node_paths.erase(name);
}
fprintf(stderr, "Label not unique: %s. References to this label will not be resolved.\n", name.c_str());
}
}
}
for (auto &c : n->child_nodes())
{
collect_names_recursive(c, path);
}
// Now we collect the phandles and properties that reference
// other nodes.
for (auto &p : n->properties())
{
for (auto &v : *p)
{
if (v.is_phandle())
{
fixups.push_back({path, p, v});
}
if (v.is_cross_reference())
{
cross_references.push_back(&v);
}
}
if ((p->get_key() == "phandle") ||
(p->get_key() == "linux,phandle"))
{
if (p->begin()->byte_data.size() != 4)
{
fprintf(stderr, "Invalid phandle value for node %s. Should be a 4-byte value.\n", n->name.c_str());
valid = false;
}
else
{
uint32_t phandle = p->begin()->get_as_uint32();
used_phandles.insert(std::make_pair(phandle, n.get()));
}
}
}
path.pop_back();
}
void
device_tree::collect_names()
{
node_path p;
node_names.clear();
node_paths.clear();
cross_references.clear();
fixups.clear();
collect_names_recursive(root, p);
}
property_ptr
device_tree::assign_phandle(node *n, uint32_t &phandle)
{
// If there is an existing phandle, use it
property_ptr p = n->get_property("phandle");
if (p == 0)
{
p = n->get_property("linux,phandle");
}
if (p == 0)
{
// Otherwise insert a new phandle node
property_value v;
while (used_phandles.find(phandle) != used_phandles.end())
{
// Note that we only don't need to
// store this phandle in the set,
// because we are monotonically
// increasing the value of phandle and
// so will only ever revisit this value
// if we have used 2^32 phandles, at
// which point our blob won't fit in
// any 32-bit system and we've done
// something badly wrong elsewhere
// already.
phandle++;
}
push_big_endian(v.byte_data, phandle++);
if (phandle_node_name == BOTH || phandle_node_name == LINUX)
{
p.reset(new property("linux,phandle"));
p->add_value(v);
n->add_property(p);
}
if (phandle_node_name == BOTH || phandle_node_name == EPAPR)
{
p.reset(new property("phandle"));
p->add_value(v);
n->add_property(p);
}
}
return (p);
}
void
device_tree::assign_phandles(node_ptr &n, uint32_t &next)
{
if (!n->labels.empty())
{
assign_phandle(n.get(), next);
}
for (auto &c : n->child_nodes())
{
assign_phandles(c, next);
}
}
void
device_tree::resolve_cross_references(uint32_t &phandle)
{
for (auto *pv : cross_references)
{
node_path path = node_paths[pv->string_data];
auto p = path.begin();
auto pe = path.end();
if (p != pe)
{
// Skip the first name in the path. It's always "", and implicitly /
for (++p ; p!=pe ; ++p)
{
pv->byte_data.push_back('/');
push_string(pv->byte_data, p->first);
if (!(p->second.empty()))
{
pv->byte_data.push_back('@');
push_string(pv->byte_data, p->second);
}
}
pv->byte_data.push_back(0);
}
}
std::unordered_map<property_value*, fixup&> phandle_set;
for (auto &i : fixups)
{
phandle_set.insert({&i.val, i});
}
std::vector<std::reference_wrapper<fixup>> sorted_phandles;
root->visit([&](node &n) {
for (auto &p : n.properties())
{
for (auto &v : *p)
{
auto i = phandle_set.find(&v);
if (i != phandle_set.end())
{
sorted_phandles.push_back(i->second);
}
}
}
});
assert(sorted_phandles.size() == fixups.size());
for (auto &i : sorted_phandles)
{
string target_name = i.get().val.string_data;
node *target = nullptr;
string possible;
// If the node name is a path, then look it up by following the path,
// otherwise jump directly to the named node.
if (target_name[0] == '/')
{
string path;
target = root.get();
std::istringstream ss(target_name);
string path_element;
// Read the leading /
std::getline(ss, path_element, '/');
// Iterate over path elements
while (!ss.eof())
{
path += '/';
std::getline(ss, path_element, '/');
std::istringstream nss(path_element);
string node_name, node_address;
std::getline(nss, node_name, '@');
std::getline(nss, node_address, '@');
node *next = nullptr;
for (auto &c : target->child_nodes())
{
if (c->name == node_name)
{
if (c->unit_address == node_address)
{
next = c.get();
break;
}
else
{
possible = path + c->name;
if (c->unit_address != string())
{
possible += '@';
possible += c->unit_address;
}
}
}
}
path += node_name;
if (node_address != string())
{
path += '@';
path += node_address;
}
target = next;
if (target == nullptr)
{
break;
}
}
}
else
{
target = node_names[target_name];
}
if (target == nullptr)
{
if (is_plugin)
{
unresolved_fixups.push_back(i);
continue;
}
else
{
fprintf(stderr, "Failed to find node with label: %s\n", target_name.c_str());
if (possible != string())
{
fprintf(stderr, "Possible intended match: %s\n", possible.c_str());
}
valid = 0;
return;
}
}
// If there is an existing phandle, use it
property_ptr p = assign_phandle(target, phandle);
p->begin()->push_to_buffer(i.get().val.byte_data);
assert(i.get().val.byte_data.size() == 4);
}
}
void
device_tree::parse_file(text_input_buffer &input,
std::vector<node_ptr> &roots,
bool &read_header)
{
input.next_token();
// Read the header
if (input.consume("/dts-v1/;"))
{
read_header = true;
}
input.next_token();
if (input.consume("/plugin/;"))
{
is_plugin = true;
}
input.next_token();
if (!read_header)
{
input.parse_error("Expected /dts-v1/; version string");
}
// Read any memory reservations
while (input.consume("/memreserve/"))
{
unsigned long long start, len;
input.next_token();
// Read the start and length.
if (!(input.consume_integer_expression(start) &&
(input.next_token(),
input.consume_integer_expression(len))))
{
input.parse_error("Expected size on /memreserve/ node.");
}
input.next_token();
input.consume(';');
reservations.push_back(reservation(start, len));
input.next_token();
}
while (valid && !input.finished())
{
node_ptr n;
if (input.consume('/'))
{
input.next_token();
n = node::parse(input, string(), string_set(), string(), &defines);
}
else if (input.consume('&'))
{
input.next_token();
string name = input.parse_node_name();
input.next_token();
n = node::parse(input, std::move(name), string_set(), string(), &defines);
}
else
{
input.parse_error("Failed to find root node /.");
}
if (n)
{
roots.push_back(std::move(n));
}
else
{
valid = false;
}
input.next_token();
}
}
template<class writer> void
device_tree::write(int fd)
{
dtb::string_table st;
dtb::header head;
writer head_writer;
writer reservation_writer;
writer struct_writer;
writer strings_writer;
// Build the reservation table
reservation_writer.write_comment(string("Memory reservations"));
reservation_writer.write_label(string("dt_reserve_map"));
for (auto &i : reservations)
{
reservation_writer.write_comment(string("Reservation start"));
reservation_writer.write_data(i.first);
reservation_writer.write_comment(string("Reservation length"));
reservation_writer.write_data(i.first);
}
// Write n spare reserve map entries, plus the trailing 0.
for (uint32_t i=0 ; i<=spare_reserve_map_entries ; i++)
{
reservation_writer.write_data((uint64_t)0);
reservation_writer.write_data((uint64_t)0);
}
struct_writer.write_comment(string("Device tree"));
struct_writer.write_label(string("dt_struct_start"));
root->write(struct_writer, st);
struct_writer.write_token(dtb::FDT_END);
struct_writer.write_label(string("dt_struct_end"));
st.write(strings_writer);
// Find the strings size before we stick padding on the end.
// Note: We should possibly use a new writer for the padding.
head.size_dt_strings = strings_writer.size();
// Stick the padding in the strings writer, but after the
// marker indicating that it's the end.
// Note: We probably should add a padding call to the writer so
// that the asm back end can write padding directives instead
// of a load of 0 bytes.
for (uint32_t i=0 ; i<blob_padding ; i++)
{
strings_writer.write_data((uint8_t)0);
}
head.totalsize = sizeof(head) + strings_writer.size() +
struct_writer.size() + reservation_writer.size();
while (head.totalsize < minimum_blob_size)
{
head.totalsize++;
strings_writer.write_data((uint8_t)0);
}
head.off_dt_struct = sizeof(head) + reservation_writer.size();;
head.off_dt_strings = head.off_dt_struct + struct_writer.size();
head.off_mem_rsvmap = sizeof(head);
head.boot_cpuid_phys = boot_cpu;
head.size_dt_struct = struct_writer.size();
head.write(head_writer);
head_writer.write_to_file(fd);
reservation_writer.write_to_file(fd);
struct_writer.write_to_file(fd);
strings_writer.write_label(string("dt_blob_end"));
strings_writer.write_to_file(fd);
}
node*
device_tree::referenced_node(property_value &v)
{
if (v.is_phandle())
{
return node_names[v.string_data];
}
if (v.is_binary())
{
return used_phandles[v.get_as_uint32()];
}
return 0;
}
void
device_tree::write_binary(int fd)
{
write<dtb::binary_writer>(fd);
}
void
device_tree::write_asm(int fd)
{
write<dtb::asm_writer>(fd);
}
void
device_tree::write_dts(int fd)
{
FILE *file = fdopen(fd, "w");
fputs("/dts-v1/;\n\n", file);
if (!reservations.empty())
{
const char msg[] = "/memreserve/";
fwrite(msg, sizeof(msg), 1, file);
for (auto &i : reservations)
{
fprintf(file, " %" PRIx64 " %" PRIx64, i.first, i.second);
}
fputs(";\n\n", file);
}
putc('/', file);
putc(' ', file);
root->write_dts(file, 0);
fclose(file);
}
void
device_tree::parse_dtb(const string &fn, FILE *)
{
auto in = input_buffer::buffer_for_file(fn);
if (in == 0)
{
valid = false;
return;
}
input_buffer &input = *in;
dtb::header h;
valid = h.read_dtb(input);
boot_cpu = h.boot_cpuid_phys;
if (h.last_comp_version > 17)
{
fprintf(stderr, "Don't know how to read this version of the device tree blob");
valid = false;
}
if (!valid)
{
return;
}
input_buffer reservation_map =
input.buffer_from_offset(h.off_mem_rsvmap, 0);
uint64_t start, length;
do
{
if (!(reservation_map.consume_binary(start) &&
reservation_map.consume_binary(length)))
{
fprintf(stderr, "Failed to read memory reservation table\n");
valid = false;
return;
}
} while (!((start == 0) && (length == 0)));
input_buffer struct_table =
input.buffer_from_offset(h.off_dt_struct, h.size_dt_struct);
input_buffer strings_table =
input.buffer_from_offset(h.off_dt_strings, h.size_dt_strings);
uint32_t token;
if (!(struct_table.consume_binary(token) &&
(token == dtb::FDT_BEGIN_NODE)))
{
fprintf(stderr, "Expected FDT_BEGIN_NODE token.\n");
valid = false;
return;
}
root = node::parse_dtb(struct_table, strings_table);
if (!(struct_table.consume_binary(token) && (token == dtb::FDT_END)))
{
fprintf(stderr, "Expected FDT_END token after parsing root node.\n");
valid = false;
return;
}
valid = (root != 0);
}
string
device_tree::node_path::to_string() const
{
string path;
auto p = begin();
auto pe = end();
if ((p == pe) || (p+1 == pe))
{
return string("/");
}
// Skip the first name in the path. It's always "", and implicitly /
for (++p ; p!=pe ; ++p)
{
path += '/';
path += p->first;
if (!(p->second.empty()))
{
path += '@';
path += p->second;
}
}
return path;
}
node_ptr
device_tree::create_fragment_wrapper(node_ptr &node, int &fragnum)
{
// In a plugin, we can massage these non-/ root nodes into into a fragment
std::string fragment_address = "fragment@" + std::to_string(fragnum);
++fragnum;
std::vector<property_ptr> symbols;
// Intentionally left empty
node_ptr newroot = node::create_special_node("", symbols);
node_ptr wrapper = node::create_special_node("__overlay__", symbols);
// Generate the fragment with target = <&name>
property_value v;
v.string_data = node->name;
v.type = property_value::PHANDLE;
auto prop = std::make_shared<property>(std::string("target"));
prop->add_value(v);
symbols.push_back(prop);
node_ptr fragment = node::create_special_node(fragment_address, symbols);
wrapper->merge_node(node);
fragment->add_child(std::move(wrapper));
newroot->add_child(std::move(fragment));
return newroot;
}
node_ptr
device_tree::generate_root(node_ptr &node, int &fragnum)
{
string name = node->name;
if (name == string())
{
return std::move(node);
}
else if (!is_plugin)
{
return nullptr;
}
return create_fragment_wrapper(node, fragnum);
}
void
device_tree::reassign_fragment_numbers(node_ptr &node, int &delta)
{
for (auto &c : node->child_nodes())
{
if (c->name == std::string("fragment"))
{
int current_address = std::stoi(c->unit_address, nullptr, 16);
std::ostringstream new_address;
current_address += delta;
// It's possible that we hopped more than one somewhere, so just reset
// delta to the next in sequence.
delta = current_address + 1;
new_address << std::hex << current_address;
c->unit_address = new_address.str();
}
}
}
void
device_tree::parse_dts(const string &fn, FILE *depfile)
{
auto in = input_buffer::buffer_for_file(fn);
if (!in)
{
valid = false;
return;
}
std::vector<node_ptr> roots;
std::unordered_set<string> defnames;
for (auto &i : defines)
{
defnames.insert(i.first);
}
text_input_buffer input(std::move(in),
std::move(defnames),
std::vector<string>(include_paths),
dirname(fn),
depfile);
bool read_header = false;
int fragnum = 0;
parse_file(input, roots, read_header);
switch (roots.size())
{
case 0:
valid = false;
input.parse_error("Failed to find root node /.");
return;
case 1:
root = generate_root(roots[0], fragnum);
if (!root)
{
valid = false;
input.parse_error("Failed to find root node /.");
return;
}
break;
default:
{
root = generate_root(roots[0], fragnum);
if (!root)
{
valid = false;
input.parse_error("Failed to find root node /.");
return;
}
for (auto i=++(roots.begin()), e=roots.end() ; i!=e ; ++i)
{
auto &node = *i;
string name = node->name;
if (name == string())
{
if (is_plugin)
{
// Re-assign any fragment numbers based on a delta of
// fragnum before we merge it
reassign_fragment_numbers(node, fragnum);
}
root->merge_node(node);
}
else
{
auto existing = node_names.find(name);
if (existing == node_names.end())
{
collect_names();
existing = node_names.find(name);
}
if (existing == node_names.end())
{
if (is_plugin)
{
auto fragment = create_fragment_wrapper(node, fragnum);
root->merge_node(fragment);
}
else
{
fprintf(stderr, "Unable to merge node: %s\n", name.c_str());
}
}
else
{
existing->second->merge_node(node);
}
}
}
}
}
collect_names();
uint32_t phandle = 1;
// If we're writing symbols, go ahead and assign phandles to the entire
// tree. We'll do this before we resolve cross references, just to keep
// order semi-predictable and stable.
if (write_symbols)
{
assign_phandles(root, phandle);
}
resolve_cross_references(phandle);
if (write_symbols)
{
std::vector<property_ptr> symbols;
// Create a symbol table. Each label in this device tree may be
// referenced by other plugins, so we create a __symbols__ node inside
// the root that contains mappings (properties) from label names to
// paths.
for (auto &s : node_paths)
{
property_value v;
v.string_data = s.second.to_string();
v.type = property_value::STRING;
string name = s.first;
auto prop = std::make_shared<property>(std::move(name));
prop->add_value(v);
symbols.push_back(prop);
}
root->add_child(node::create_special_node("__symbols__", symbols));
// If this is a plugin, then we also need to create two extra nodes.
// Internal phandles will need to be renumbered to avoid conflicts with
// already-loaded nodes and external references will need to be
// resolved.
if (is_plugin)
{
// Create the fixups entry. This is of the form:
// {target} = {path}:{property name}:{offset}
auto create_fixup_entry = [&](fixup &i, string target)
{
string value = i.path.to_string();
value += ':';
value += i.prop->get_key();
value += ':';
value += std::to_string(i.prop->offset_of_value(i.val));
property_value v;
v.string_data = value;
v.type = property_value::STRING;
auto prop = std::make_shared<property>(std::move(target));
prop->add_value(v);
return prop;
};
// If we have any unresolved phandle references in this plugin,
// then we must update them to 0xdeadbeef and leave a property in
// the /__fixups__ node whose key is the label and whose value is
// as described above.
if (!unresolved_fixups.empty())
{
symbols.clear();
for (auto &i : unresolved_fixups)
{
auto &val = i.get().val;
symbols.push_back(create_fixup_entry(i, val.string_data));
val.byte_data.push_back(0xde);
val.byte_data.push_back(0xad);
val.byte_data.push_back(0xbe);
val.byte_data.push_back(0xef);
val.type = property_value::BINARY;
}
root->add_child(node::create_special_node("__fixups__", symbols));
}
symbols.clear();
// If we have any resolved phandle references in this plugin, then
// we must create a child in the __local_fixups__ node whose path
// matches the node path from the root and whose value contains the
// location of the reference within a property.
// Create a local_fixups node that is initially empty.
node_ptr local_fixups = node::create_special_node("__local_fixups__", symbols);
for (auto &i : fixups)
{
if (!i.val.is_phandle())
{
continue;
}
node *n = local_fixups.get();
for (auto &p : i.path)
{
// Skip the implicit root
if (p.first.empty())
{
continue;
}
bool found = false;
for (auto &c : n->child_nodes())
{
if (c->name == p.first)
{
n = c.get();
found = true;
break;
}
}
if (!found)
{
n->add_child(node::create_special_node(p.first, symbols));
n = (--n->child_end())->get();
}
}
assert(n);
property_value pv;
push_big_endian(pv.byte_data, static_cast<uint32_t>(i.prop->offset_of_value(i.val)));
pv.type = property_value::BINARY;
auto key = i.prop->get_key();
property_ptr prop = n->get_property(key);
// If we don't have an existing property then create one and
// use this property value
if (!prop)
{
prop = std::make_shared<property>(std::move(key));
n->add_property(prop);
prop->add_value(pv);
}
else
{
// If we do have an existing property value, try to append
// this value.
property_value &old_val = *(--prop->end());
if (!old_val.try_to_merge(pv))
{
prop->add_value(pv);
}
}
}
// We've iterated over all fixups, but only emit the
// __local_fixups__ if we found some that were resolved internally.
if (local_fixups->child_begin() != local_fixups->child_end())
{
root->add_child(std::move(local_fixups));
}
}
}
}
bool device_tree::parse_define(const char *def)
{
const char *val = strchr(def, '=');
if (!val)
{
if (strlen(def) != 0)
{
string name(def);
defines[name];
return true;
}
return false;
}
string name(def, val-def);
string name_copy = name;
val++;
std::unique_ptr<input_buffer> raw(new input_buffer(val, strlen(val)));
text_input_buffer in(std::move(raw),
std::unordered_set<string>(),
std::vector<string>(),
string(),
nullptr);
property_ptr p = property::parse(in, std::move(name_copy), string_set(), false);
if (p)
defines[name] = p;
return (bool)p;
}
} // namespace fdt
} // namespace dtc