path: root/tools/dtoc/dtb_platdata.py

#!/usr/bin/python
#
# Copyright (C) 2017 Google, Inc
# Written by Simon Glass <sjg@chromium.org>
#
# SPDX-License-Identifier:	GPL-2.0+
#

"""Device tree to platform data class

This supports converting device tree data to C structures definitions and
static data.
"""

import copy
import sys

import fdt
import fdt_util

# When we see these properties we ignore them - i.e. do not create a structure member
PROP_IGNORE_LIST = [
    '#address-cells',
    '#gpio-cells',
    '#size-cells',
    'compatible',
    'linux,phandle',
    "status",
    'phandle',
    'u-boot,dm-pre-reloc',
    'u-boot,dm-tpl',
    'u-boot,dm-spl',
]

# C type declarations for the tyues we support
TYPE_NAMES = {
    fdt.TYPE_INT: 'fdt32_t',
    fdt.TYPE_BYTE: 'unsigned char',
    fdt.TYPE_STRING: 'const char *',
    fdt.TYPE_BOOL: 'bool',
    fdt.TYPE_INT64: 'fdt64_t',
}

STRUCT_PREFIX = 'dtd_'
VAL_PREFIX = 'dtv_'

def conv_name_to_c(name):
    """Convert a device-tree name to a C identifier

    This uses multiple replace() calls instead of re.sub() since it is faster
    (400ms for 1m calls versus 1000ms for the 're' version).

    Args:
        name:   Name to convert
    Return:
        String containing the C version of this name
    """
    new = name.replace('@', '_at_')
    new = new.replace('-', '_')
    new = new.replace(',', '_')
    new = new.replace('.', '_')
    return new

def tab_to(num_tabs, line):
    """Append tabs to a line of text to reach a tab stop.

    Args:
        num_tabs: Tab stop to obtain (0 = column 0, 1 = column 8, etc.)
        line: Line of text to append to

    Returns:
        line with the correct number of tabs appeneded. If the line already
        extends past that tab stop then a single space is appended.
    """
    if len(line) >= num_tabs * 8:
        return line + ' '
    return line + '\t' * (num_tabs - len(line) // 8)

def get_value(ftype, value):
    """Get a value as a C expression

    For integers this returns a byte-swapped (little-endian) hex string
    For bytes this returns a hex string, e.g. 0x12
    For strings this returns a literal string enclosed in quotes
    For booleans this return 'true'

    Args:
        type: Data type (fdt_util)
        value: Data value, as a string of bytes
    """
    if ftype == fdt.TYPE_INT:
        return '%#x' % fdt_util.fdt32_to_cpu(value)
    elif ftype == fdt.TYPE_BYTE:
        return '%#x' % ord(value[0])
    elif ftype == fdt.TYPE_STRING:
        return '"%s"' % value
    elif ftype == fdt.TYPE_BOOL:
        return 'true'
    elif ftype == fdt.TYPE_INT64:
        return '%#x' % value

def get_compat_name(node):
    """Get a node's first compatible string as a C identifier

    Args:
        node: Node object to check
    Return:
        Tuple:
            C identifier for the first compatible string
            List of C identifiers for all the other compatible strings
                (possibly empty)
    """
    compat = node.props['compatible'].value
    aliases = []
    if isinstance(compat, list):
        compat, aliases = compat[0], compat[1:]
    return conv_name_to_c(compat), [conv_name_to_c(a) for a in aliases]


class DtbPlatdata(object):
    """Provide a means to convert device tree binary data to platform data

    The output of this process is C structures which can be used in space-
    constrained encvironments where the ~3KB code overhead of device tree
    code is not affordable.

    Properties:
        _fdt: Fdt object, referencing the device tree
        _dtb_fname: Filename of the input device tree binary file
        _valid_nodes: A list of Node object with compatible strings
        _include_disabled: true to include nodes marked status = "disabled"
        _outfile: The current output file (sys.stdout or a real file)
        _lines: Stashed list of output lines for outputting in the future
    """
    def __init__(self, dtb_fname, include_disabled):
        self._fdt = None
        self._dtb_fname = dtb_fname
        self._valid_nodes = None
        self._include_disabled = include_disabled
        self._outfile = None
        self._lines = []
        self._aliases = {}

    def setup_output(self, fname):
        """Set up the output destination

        Once this is done, future calls to self.out() will output to this
        file.

        Args:
            fname: Filename to send output to, or '-' for stdout
        """
        if fname == '-':
            self._outfile = sys.stdout
        else:
            self._outfile = open(fname, 'w')

    def out(self, line):
        """Output a string to the output file

        Args:
            line: String to output
        """
        self._outfile.write(line)

    def buf(self, line):
        """Buffer up a string to send later

        Args:
            line: String to add to our 'buffer' list
        """
        self._lines.append(line)

    def get_buf(self):
        """Get the contents of the output buffer, and clear it

        Returns:
            The output buffer, which is then cleared for future use
        """
        lines = self._lines
        self._lines = []
        return lines

    def is_phandle(self, prop):
	"""Check if a node contains phandles

	We have no reliable way of detecting whether a node uses a phandle
	or not. As an interim measure, use a list of known property names.

	Args:
	    prop: Prop object to check
	Return:
	    True if the object value contains phandles, else False
	"""
	if prop.name in ['clocks']:
	    return True
	return False

    def scan_dtb(self):
        """Scan the device tree to obtain a tree of nodes and properties

        Once this is done, self._fdt.GetRoot() can be called to obtain the
        device tree root node, and progress from there.
        """
        self._fdt = fdt.FdtScan(self._dtb_fname)

    def scan_node(self, root):
        """Scan a node and subnodes to build a tree of node and phandle info

        This adds each node to self._valid_nodes.

        Args:
            root: Root node for scan
        """
        for node in root.subnodes:
            if 'compatible' in node.props:
                status = node.props.get('status')
                if (not self._include_disabled and not status or
                        status.value != 'disabled'):
                    self._valid_nodes.append(node)

            # recurse to handle any subnodes
            self.scan_node(node)

    def scan_tree(self):
        """Scan the device tree for useful information

        This fills in the following properties:
            _valid_nodes: A list of nodes we wish to consider include in the
                platform data
        """
        self._valid_nodes = []
        return self.scan_node(self._fdt.GetRoot())

    @staticmethod
    def get_num_cells(node):
        """Get the number of cells in addresses and sizes for this node

        Args:
            node: Node to check

        Returns:
            Tuple:
                Number of address cells for this node
                Number of size cells for this node
        """
        parent = node.parent
        na, ns = 2, 2
        if parent:
            na_prop = parent.props.get('#address-cells')
            ns_prop = parent.props.get('#size-cells')
            if na_prop:
                na = fdt_util.fdt32_to_cpu(na_prop.value)
            if ns_prop:
                ns = fdt_util.fdt32_to_cpu(ns_prop.value)
        return na, ns

    def scan_reg_sizes(self):
        """Scan for 64-bit 'reg' properties and update the values

        This finds 'reg' properties with 64-bit data and converts the value to
        an array of 64-values. This allows it to be output in a way that the
        C code can read.
        """
        for node in self._valid_nodes:
            reg = node.props.get('reg')
            if not reg:
                continue
            na, ns = self.get_num_cells(node)
            total = na + ns

            if reg.type != fdt.TYPE_INT:
                raise ValueError("Node '%s' reg property is not an int")
            if len(reg.value) % total:
                raise ValueError("Node '%s' reg property has %d cells "
                        'which is not a multiple of na + ns = %d + %d)' %
                        (node.name, len(reg.value), na, ns))
            reg.na = na
            reg.ns = ns
            if na != 1 or ns != 1:
                reg.type = fdt.TYPE_INT64
                i = 0
                new_value = []
                val = reg.value
                if not isinstance(val, list):
                    val = [val]
                while i < len(val):
                    addr = fdt_util.fdt_cells_to_cpu(val[i:], reg.na)
                    i += na
                    size = fdt_util.fdt_cells_to_cpu(val[i:], reg.ns)
                    i += ns
                    new_value += [addr, size]
                reg.value = new_value

    def scan_structs(self):
        """Scan the device tree building up the C structures we will use.

        Build a dict keyed by C struct name containing a dict of Prop
        object for each struct field (keyed by property name). Where the
        same struct appears multiple times, try to use the 'widest'
        property, i.e. the one with a type which can express all others.

        Once the widest property is determined, all other properties are
        updated to match that width.
        """
        structs = {}
        for node in self._valid_nodes:
            node_name, _ = get_compat_name(node)
            fields = {}

            # Get a list of all the valid properties in this node.
            for name, prop in node.props.items():
                if name not in PROP_IGNORE_LIST and name[0] != '#':
                    fields[name] = copy.deepcopy(prop)

            # If we've seen this node_name before, update the existing struct.
            if node_name in structs:
                struct = structs[node_name]
                for name, prop in fields.items():
                    oldprop = struct.get(name)
                    if oldprop:
                        oldprop.Widen(prop)
                    else:
                        struct[name] = prop

            # Otherwise store this as a new struct.
            else:
                structs[node_name] = fields

        upto = 0
        for node in self._valid_nodes:
            node_name, _ = get_compat_name(node)
            struct = structs[node_name]
            for name, prop in node.props.items():
                if name not in PROP_IGNORE_LIST and name[0] != '#':
                    prop.Widen(struct[name])
            upto += 1

            struct_name, aliases = get_compat_name(node)
            for alias in aliases:
                self._aliases[alias] = struct_name

        return structs

    def scan_phandles(self):
        """Figure out what phandles each node uses

        We need to be careful when outputing nodes that use phandles since
        they must come after the declaration of the phandles in the C file.
        Otherwise we get a compiler error since the phandle struct is not yet
        declared.

        This function adds to each node a list of phandle nodes that the node
        depends on. This allows us to output things in the right order.
        """
        for node in self._valid_nodes:
            node.phandles = set()
            for pname, prop in node.props.items():
                if pname in PROP_IGNORE_LIST or pname[0] == '#':
                    continue
                if isinstance(prop.value, list):
                    if self.is_phandle(prop):
                        # Process the list as pairs of (phandle, id)
                        value_it = iter(prop.value)
                        for phandle_cell, _ in zip(value_it, value_it):
                            phandle = fdt_util.fdt32_to_cpu(phandle_cell)
                            target_node = self._fdt.phandle_to_node[phandle]
                            node.phandles.add(target_node)


    def generate_structs(self, structs):
        """Generate struct defintions for the platform data

        This writes out the body of a header file consisting of structure
        definitions for node in self._valid_nodes. See the documentation in
        README.of-plat for more information.
        """
        self.out('#include <stdbool.h>\n')
        self.out('#include <libfdt.h>\n')

        # Output the struct definition
        for name in sorted(structs):
            self.out('struct %s%s {\n' % (STRUCT_PREFIX, name))
            for pname in sorted(structs[name]):
                prop = structs[name][pname]
                if self.is_phandle(prop):
                    # For phandles, include a reference to the target
                    self.out('\t%s%s[%d]' % (tab_to(2, 'struct phandle_2_cell'),
                                             conv_name_to_c(prop.name),
                                             len(prop.value) / 2))
                else:
                    ptype = TYPE_NAMES[prop.type]
                    self.out('\t%s%s' % (tab_to(2, ptype),
                                         conv_name_to_c(prop.name)))
                    if isinstance(prop.value, list):
                        self.out('[%d]' % len(prop.value))
                self.out(';\n')
            self.out('};\n')

        for alias, struct_name in self._aliases.iteritems():
            self.out('#define %s%s %s%s\n'% (STRUCT_PREFIX, alias,
                                             STRUCT_PREFIX, struct_name))

    def output_node(self, node):
        """Output the C code for a node

        Args:
            node: node to output
        """
        struct_name, _ = get_compat_name(node)
        var_name = conv_name_to_c(node.name)
        self.buf('static struct %s%s %s%s = {\n' %
                 (STRUCT_PREFIX, struct_name, VAL_PREFIX, var_name))
        for pname, prop in node.props.items():
            if pname in PROP_IGNORE_LIST or pname[0] == '#':
                continue
            member_name = conv_name_to_c(prop.name)
            self.buf('\t%s= ' % tab_to(3, '.' + member_name))

            # Special handling for lists
            if isinstance(prop.value, list):
                self.buf('{')
                vals = []
                # For phandles, output a reference to the platform data
                # of the target node.
                if self.is_phandle(prop):
                    # Process the list as pairs of (phandle, id)
                    value_it = iter(prop.value)
                    for phandle_cell, id_cell in zip(value_it, value_it):
                        phandle = fdt_util.fdt32_to_cpu(phandle_cell)
                        id_num = fdt_util.fdt32_to_cpu(id_cell)
                        target_node = self._fdt.phandle_to_node[phandle]
                        name = conv_name_to_c(target_node.name)
                        vals.append('{&%s%s, %d}' % (VAL_PREFIX, name, id_num))
                else:
                    for val in prop.value:
                        vals.append(get_value(prop.type, val))

                # Put 8 values per line to avoid very long lines.
                for i in xrange(0, len(vals), 8):
                    if i:
                        self.buf(',\n\t\t')
                    self.buf(', '.join(vals[i:i + 8]))
                self.buf('}')
            else:
                self.buf(get_value(prop.type, prop.value))
            self.buf(',\n')
        self.buf('};\n')

        # Add a device declaration
        self.buf('U_BOOT_DEVICE(%s) = {\n' % var_name)
        self.buf('\t.name\t\t= "%s",\n' % struct_name)
        self.buf('\t.platdata\t= &%s%s,\n' % (VAL_PREFIX, var_name))
        self.buf('\t.platdata_size\t= sizeof(%s%s),\n' % (VAL_PREFIX, var_name))
        self.buf('};\n')
        self.buf('\n')

        self.out(''.join(self.get_buf()))

    def generate_tables(self):
        """Generate device defintions for the platform data

        This writes out C platform data initialisation data and
        U_BOOT_DEVICE() declarations for each valid node. Where a node has
        multiple compatible strings, a #define is used to make them equivalent.

        See the documentation in doc/driver-model/of-plat.txt for more
        information.
        """
        self.out('#include <common.h>\n')
        self.out('#include <dm.h>\n')
        self.out('#include <dt-structs.h>\n')
        self.out('\n')
        nodes_to_output = list(self._valid_nodes)

        # Keep outputing nodes until there is none left
        while nodes_to_output:
            node = nodes_to_output[0]
            # Output all the node's dependencies first
            for req_node in node.phandles:
                if req_node in nodes_to_output:
                    self.output_node(req_node)
                    nodes_to_output.remove(req_node)
            self.output_node(node)
            nodes_to_output.remove(node)


def run_steps(args, dtb_file, include_disabled, output):
    """Run all the steps of the dtoc tool

    Args:
        args: List of non-option arguments provided to the problem
        dtb_file: Filename of dtb file to process
        include_disabled: True to include disabled nodes
        output: Name of output file
    """
    if not args:
        raise ValueError('Please specify a command: struct, platdata')

    plat = DtbPlatdata(dtb_file, include_disabled)
    plat.scan_dtb()
    plat.scan_tree()
    plat.scan_reg_sizes()
    plat.setup_output(output)
    structs = plat.scan_structs()
    plat.scan_phandles()

    for cmd in args[0].split(','):
        if cmd == 'struct':
            plat.generate_structs(structs)
        elif cmd == 'platdata':
            plat.generate_tables()
        else:
            raise ValueError("Unknown command '%s': (use: struct, platdata)" %
                             cmd)