path: root/src/amd/vulkan/radv_entrypoints_gen.py

# coding=utf-8
#
# Copyright © 2015, 2017 Intel Corporation
#
# Permission is hereby granted, free of charge, to any person obtaining a
# copy of this software and associated documentation files (the "Software"),
# to deal in the Software without restriction, including without limitation
# the rights to use, copy, modify, merge, publish, distribute, sublicense,
# and/or sell copies of the Software, and to permit persons to whom the
# Software is furnished to do so, subject to the following conditions:
#
# The above copyright notice and this permission notice (including the next
# paragraph) shall be included in all copies or substantial portions of the
# Software.
#
# THE SOFTWARE IS PROVIDED "AS IS", WITHOUT WARRANTY OF ANY KIND, EXPRESS OR
# IMPLIED, INCLUDING BUT NOT LIMITED TO THE WARRANTIES OF MERCHANTABILITY,
# FITNESS FOR A PARTICULAR PURPOSE AND NONINFRINGEMENT.  IN NO EVENT SHALL
# THE AUTHORS OR COPYRIGHT HOLDERS BE LIABLE FOR ANY CLAIM, DAMAGES OR OTHER
# LIABILITY, WHETHER IN AN ACTION OF CONTRACT, TORT OR OTHERWISE, ARISING
# FROM, OUT OF OR IN CONNECTION WITH THE SOFTWARE OR THE USE OR OTHER DEALINGS
# IN THE SOFTWARE.
#

import argparse
import functools
import math
import os
import xml.etree.cElementTree as et

from collections import OrderedDict, namedtuple
from mako.template import Template

from radv_extensions import *

# We generate a static hash table for entry point lookup
# (vkGetProcAddress). We use a linear congruential generator for our hash
# function and a power-of-two size table. The prime numbers are determined
# experimentally.

LAYERS = [
    'radv',
    'sqtt'
]

TEMPLATE_H = Template("""\
/* This file generated from ${filename}, don't edit directly. */

struct radv_instance_dispatch_table {
   union {
      void *entrypoints[${len(instance_entrypoints)}];
      struct {
      % for e in instance_entrypoints:
        % if e.guard is not None:
#ifdef ${e.guard}
          PFN_${e.name} ${e.name};
#else
          void *${e.name};
# endif
        % else:
          PFN_${e.name} ${e.name};
        % endif
      % endfor
      };
   };
};

struct radv_physical_device_dispatch_table {
   union {
      void *entrypoints[${len(physical_device_entrypoints)}];
      struct {
      % for e in physical_device_entrypoints:
        % if e.guard is not None:
#ifdef ${e.guard}
          PFN_${e.name} ${e.name};
#else
          void *${e.name};
# endif
        % else:
          PFN_${e.name} ${e.name};
        % endif
      % endfor
      };
   };
};

struct radv_device_dispatch_table {
   union {
      void *entrypoints[${len(device_entrypoints)}];
      struct {
      % for e in device_entrypoints:
        % if e.guard is not None:
#ifdef ${e.guard}
          PFN_${e.name} ${e.name};
#else
          void *${e.name};
# endif
        % else:
          PFN_${e.name} ${e.name};
        % endif
      % endfor
      };
   };
};

extern const struct radv_instance_dispatch_table radv_instance_dispatch_table;
%for layer in LAYERS:
extern const struct radv_physical_device_dispatch_table ${layer}_physical_device_dispatch_table;
%endfor
%for layer in LAYERS:
extern const struct radv_device_dispatch_table ${layer}_device_dispatch_table;
%endfor

% for e in instance_entrypoints:
  % if e.alias and e.alias.enabled:
    <% continue %>
  % endif
  % if e.guard is not None:
#ifdef ${e.guard}
  % endif
  ${e.return_type} ${e.prefixed_name('radv')}(${e.decl_params()});
  % if e.guard is not None:
#endif // ${e.guard}
  % endif
% endfor

% for e in physical_device_entrypoints:
  % if e.alias:
    <% continue %>
  % endif
  % if e.guard is not None:
#ifdef ${e.guard}
  % endif
  % for layer in LAYERS:
  ${e.return_type} ${e.prefixed_name(layer)}(${e.decl_params()});
  % endfor
  % if e.guard is not None:
#endif // ${e.guard}
  % endif
% endfor

% for e in device_entrypoints:
  % if e.alias and e.alias.enabled:
    <% continue %>
  % endif
  % if e.guard is not None:
#ifdef ${e.guard}
  % endif
  % for layer in LAYERS:
  ${e.return_type} ${e.prefixed_name(layer)}(${e.decl_params()});
  % endfor
  % if e.guard is not None:
#endif // ${e.guard}
  % endif
% endfor
""", output_encoding='utf-8')

TEMPLATE_C = Template(u"""\
/*
 * Copyright © 2015 Intel Corporation
 *
 * Permission is hereby granted, free of charge, to any person obtaining a
 * copy of this software and associated documentation files (the "Software"),
 * to deal in the Software without restriction, including without limitation
 * the rights to use, copy, modify, merge, publish, distribute, sublicense,
 * and/or sell copies of the Software, and to permit persons to whom the
 * Software is furnished to do so, subject to the following conditions:
 *
 * The above copyright notice and this permission notice (including the next
 * paragraph) shall be included in all copies or substantial portions of the
 * Software.
 *
 * THE SOFTWARE IS PROVIDED "AS IS", WITHOUT WARRANTY OF ANY KIND, EXPRESS OR
 * IMPLIED, INCLUDING BUT NOT LIMITED TO THE WARRANTIES OF MERCHANTABILITY,
 * FITNESS FOR A PARTICULAR PURPOSE AND NONINFRINGEMENT.  IN NO EVENT SHALL
 * THE AUTHORS OR COPYRIGHT HOLDERS BE LIABLE FOR ANY CLAIM, DAMAGES OR OTHER
 * LIABILITY, WHETHER IN AN ACTION OF CONTRACT, TORT OR OTHERWISE, ARISING
 * FROM, OUT OF OR IN CONNECTION WITH THE SOFTWARE OR THE USE OR OTHER DEALINGS
 * IN THE SOFTWARE.
 */

/* This file generated from ${filename}, don't edit directly. */

#include "radv_private.h"

#include "util/macros.h"

struct string_map_entry {
   uint32_t name;
   uint32_t hash;
   uint32_t num;
};

/* We use a big string constant to avoid lots of reloctions from the entry
 * point table to lots of little strings. The entries in the entry point table
 * store the index into this big string.
 */

<%def name="strmap(strmap, prefix)">
static const char ${prefix}_strings[] =
% for s in strmap.sorted_strings:
    "${s.string}\\0"
% endfor
;

static const struct string_map_entry ${prefix}_string_map_entries[] = {
% for s in strmap.sorted_strings:
    { ${s.offset}, ${'{:0=#8x}'.format(s.hash)}, ${s.num} }, /* ${s.string} */
% endfor
};

/* Hash table stats:
 * size ${len(strmap.sorted_strings)} entries
 * collisions entries:
% for i in range(10):
 *     ${i}${'+' if i == 9 else ' '}     ${strmap.collisions[i]}
% endfor
 */

#define none 0xffff
static const uint16_t ${prefix}_string_map[${strmap.hash_size}] = {
% for e in strmap.mapping:
    ${ '{:0=#6x}'.format(e) if e >= 0 else 'none' },
% endfor
};

static int
${prefix}_string_map_lookup(const char *str)
{
    static const uint32_t prime_factor = ${strmap.prime_factor};
    static const uint32_t prime_step = ${strmap.prime_step};
    const struct string_map_entry *e;
    uint32_t hash, h;
    uint16_t i;
    const char *p;

    hash = 0;
    for (p = str; *p; p++)
        hash = hash * prime_factor + *p;

    h = hash;
    while (1) {
        i = ${prefix}_string_map[h & ${strmap.hash_mask}];
        if (i == none)
           return -1;
        e = &${prefix}_string_map_entries[i];
        if (e->hash == hash && strcmp(str, ${prefix}_strings + e->name) == 0)
            return e->num;
        h += prime_step;
    }

    return -1;
}

static const char *
${prefix}_entry_name(int num)
{
   for (int i = 0; i < ARRAY_SIZE(${prefix}_string_map_entries); i++) {
      if (${prefix}_string_map_entries[i].num == num)
         return &${prefix}_strings[${prefix}_string_map_entries[i].name];
   }
   return NULL;
}
</%def>

${strmap(instance_strmap, 'instance')}
${strmap(physical_device_strmap, 'physical_device')}
${strmap(device_strmap, 'device')}

/* Weak aliases for all potential implementations. These will resolve to
 * NULL if they're not defined, which lets the resolve_entrypoint() function
 * either pick the correct entry point.
 */

% for e in instance_entrypoints:
  % if e.alias and e.alias.enabled:
    <% continue %>
  % endif
  % if e.guard is not None:
#ifdef ${e.guard}
  % endif
  ${e.return_type} ${e.prefixed_name('radv')}(${e.decl_params()}) __attribute__ ((weak));
  % if e.guard is not None:
#endif // ${e.guard}
  % endif
% endfor

const struct radv_instance_dispatch_table radv_instance_dispatch_table = {
% for e in instance_entrypoints:
  % if e.guard is not None:
#ifdef ${e.guard}
  % endif
  .${e.name} = ${e.prefixed_name('radv')},
  % if e.guard is not None:
#endif // ${e.guard}
  % endif
% endfor
};

% for e in physical_device_entrypoints:
  % if e.alias and e.alias.enabled:
    <% continue %>
  % endif
  % if e.guard is not None:
#ifdef ${e.guard}
  % endif
  ${e.return_type} ${e.prefixed_name('radv')}(${e.decl_params()}) __attribute__ ((weak));
  % if e.guard is not None:
#endif // ${e.guard}
  % endif
% endfor

const struct radv_physical_device_dispatch_table radv_physical_device_dispatch_table = {
% for e in physical_device_entrypoints:
  % if e.guard is not None:
#ifdef ${e.guard}
  % endif
  .${e.name} = ${e.prefixed_name('radv')},
  % if e.guard is not None:
#endif // ${e.guard}
  % endif
% endfor
};


% for layer in LAYERS:
  % for e in device_entrypoints:
    % if e.alias and e.alias.enabled:
      <% continue %>
    % endif
    % if e.guard is not None:
#ifdef ${e.guard}
    % endif
    % if layer == 'radv':
      ${e.return_type} __attribute__ ((weak))
      ${e.prefixed_name('radv')}(${e.decl_params()})
      {
        % if e.params[0].type == 'VkDevice':
          RADV_FROM_HANDLE(radv_device, radv_device, ${e.params[0].name});
          return radv_device->dispatch.${e.name}(${e.call_params()});
        % elif e.params[0].type == 'VkCommandBuffer':
          RADV_FROM_HANDLE(radv_cmd_buffer, radv_cmd_buffer, ${e.params[0].name});
          return radv_cmd_buffer->device->dispatch.${e.name}(${e.call_params()});
        % elif e.params[0].type == 'VkQueue':
          RADV_FROM_HANDLE(radv_queue, radv_queue, ${e.params[0].name});
          return radv_queue->device->dispatch.${e.name}(${e.call_params()});
        % else:
          assert(!"Unhandled device child trampoline case: ${e.params[0].type}");
        % endif
      }
    % else:
      ${e.return_type} ${e.prefixed_name(layer)}(${e.decl_params()}) __attribute__ ((weak));
    % endif
    % if e.guard is not None:
#endif // ${e.guard}
    % endif
  % endfor

  const struct radv_device_dispatch_table ${layer}_device_dispatch_table = {
  % for e in device_entrypoints:
    % if e.guard is not None:
#ifdef ${e.guard}
    % endif
    .${e.name} = ${e.prefixed_name(layer)},
    % if e.guard is not None:
#endif // ${e.guard}
    % endif
  % endfor
  };
% endfor


/** Return true if the core version or extension in which the given entrypoint
 * is defined is enabled.
 *
 * If device is NULL, all device extensions are considered enabled.
 */
bool
radv_instance_entrypoint_is_enabled(int index, uint32_t core_version,
                                   const struct radv_instance_extension_table *instance)
{
   switch (index) {
% for e in instance_entrypoints:
   case ${e.num}:
      /* ${e.name} */
   % if e.core_version:
      return ${e.core_version.c_vk_version()} <= core_version;
   % elif e.extensions:
     % for ext in e.extensions:
        % if ext.type == 'instance':
      if (instance->${ext.name[3:]}) return true;
        % else:
      /* All device extensions are considered enabled at the instance level */
      return true;
        % endif
     % endfor
      return false;
   % else:
      return true;
   % endif
% endfor
   default:
      return false;
   }
}

/** Return true if the core version or extension in which the given entrypoint
 * is defined is enabled.
 *
 * If device is NULL, all device extensions are considered enabled.
 */
bool
radv_physical_device_entrypoint_is_enabled(int index, uint32_t core_version,
                                          const struct radv_instance_extension_table *instance)
{
   switch (index) {
% for e in physical_device_entrypoints:
   case ${e.num}:
      /* ${e.name} */
   % if e.core_version:
      return ${e.core_version.c_vk_version()} <= core_version;
   % elif e.extensions:
     % for ext in e.extensions:
        % if ext.type == 'instance':
      if (instance->${ext.name[3:]}) return true;
        % else:
      /* All device extensions are considered enabled at the instance level */
      return true;
        % endif
     % endfor
      return false;
   % else:
      return true;
   % endif
% endfor
   default:
      return false;
   }
}

/** Return true if the core version or extension in which the given entrypoint
 * is defined is enabled.
 *
 * If device is NULL, all device extensions are considered enabled.
 */
bool
radv_device_entrypoint_is_enabled(int index, uint32_t core_version,
                                 const struct radv_instance_extension_table *instance,
                                 const struct radv_device_extension_table *device)
{
   switch (index) {
% for e in device_entrypoints:
   case ${e.num}:
      /* ${e.name} */
   % if e.core_version:
      return ${e.core_version.c_vk_version()} <= core_version;
   % elif e.extensions:
     % for ext in e.extensions:
        % if ext.type == 'instance':
           <% assert False %>
        % else:
      if (!device || device->${ext.name[3:]}) return true;
        % endif
     % endfor
      return false;
   % else:
      return true;
   % endif
% endfor
   default:
      return false;
   }
}

int
radv_get_instance_entrypoint_index(const char *name)
{
   return instance_string_map_lookup(name);
}

int
radv_get_physical_device_entrypoint_index(const char *name)
{
   return physical_device_string_map_lookup(name);
}

int
radv_get_device_entrypoint_index(const char *name)
{
   return device_string_map_lookup(name);
}

const char *
radv_get_instance_entry_name(int index)
{
   return instance_entry_name(index);
}

const char *
radv_get_physical_device_entry_name(int index)
{
   return physical_device_entry_name(index);
}

const char *
radv_get_device_entry_name(int index)
{
   return device_entry_name(index);
}

static void * __attribute__ ((noinline))
radv_resolve_device_entrypoint(uint32_t index)
{
    return radv_device_dispatch_table.entrypoints[index];
}

void *
radv_lookup_entrypoint(const char *name)
{
   int idx = radv_get_instance_entrypoint_index(name);
   if (idx >= 0)
      return radv_instance_dispatch_table.entrypoints[idx];

   idx = radv_get_physical_device_entrypoint_index(name);
   if (idx >= 0)
      return radv_physical_device_dispatch_table.entrypoints[idx];

   idx = radv_get_device_entrypoint_index(name);
   if (idx >= 0)
      return radv_resolve_device_entrypoint(idx);

   return NULL;
}""", output_encoding='utf-8')

U32_MASK = 2**32 - 1

PRIME_FACTOR = 5024183
PRIME_STEP = 19

def round_to_pow2(x):
    return 2**int(math.ceil(math.log(x, 2)))

class StringIntMapEntry(object):
    def __init__(self, string, num):
        self.string = string
        self.num = num

        # Calculate the same hash value that we will calculate in C.
        h = 0
        for c in string:
            h = ((h * PRIME_FACTOR) + ord(c)) & U32_MASK
        self.hash = h

        self.offset = None

class StringIntMap(object):
    def __init__(self):
        self.baked = False
        self.strings = dict()

    def add_string(self, string, num):
        assert not self.baked
        assert string not in self.strings
        assert num >= 0 and num < 2**31
        self.strings[string] = StringIntMapEntry(string, num)

    def bake(self):
        self.sorted_strings = \
            sorted(self.strings.values(), key=lambda x: x.string)
        offset = 0
        for entry in self.sorted_strings:
            entry.offset = offset
            offset += len(entry.string) + 1

        # Save off some values that we'll need in C
        self.hash_size = round_to_pow2(len(self.strings) * 1.25)
        self.hash_mask = self.hash_size - 1
        self.prime_factor = PRIME_FACTOR
        self.prime_step = PRIME_STEP

        self.mapping = [-1] * self.hash_size
        self.collisions = [0] * 10
        for idx, s in enumerate(self.sorted_strings):
            level = 0
            h = s.hash
            while self.mapping[h & self.hash_mask] >= 0:
                h = h + PRIME_STEP
                level = level + 1
            self.collisions[min(level, 9)] += 1
            self.mapping[h & self.hash_mask] = idx

EntrypointParam = namedtuple('EntrypointParam', 'type name decl')

class EntrypointBase(object):
    def __init__(self, name):
        self.name = name
        self.alias = None
        self.guard = None
        self.enabled = False
        self.num = None
        # Extensions which require this entrypoint
        self.core_version = None
        self.extensions = []

    def prefixed_name(self, prefix):
        assert self.name.startswith('vk')
        return prefix + '_' + self.name[2:]

class Entrypoint(EntrypointBase):
    def __init__(self, name, return_type, params, guard = None):
        super(Entrypoint, self).__init__(name)
        self.return_type = return_type
        self.params = params
        self.guard = guard

    def is_physical_device_entrypoint(self):
        return self.params[0].type in ('VkPhysicalDevice', )

    def is_device_entrypoint(self):
        return self.params[0].type in ('VkDevice', 'VkCommandBuffer', 'VkQueue')

    def decl_params(self):
        return ', '.join(p.decl for p in self.params)

    def call_params(self):
        return ', '.join(p.name for p in self.params)

class EntrypointAlias(EntrypointBase):
    def __init__(self, name, entrypoint):
        super(EntrypointAlias, self).__init__(name)
        self.alias = entrypoint

    def is_physical_device_entrypoint(self):
        return self.alias.is_physical_device_entrypoint()

    def is_device_entrypoint(self):
        return self.alias.is_device_entrypoint()

    def prefixed_name(self, prefix):
        if self.alias.enabled:
            return self.alias.prefixed_name(prefix)
        return super(EntrypointAlias, self).prefixed_name(prefix)

    @property
    def params(self):
        return self.alias.params

    @property
    def return_type(self):
        return self.alias.return_type

    def decl_params(self):
        return self.alias.decl_params()

    def call_params(self):
        return self.alias.call_params()

def get_entrypoints(doc, entrypoints_to_defines):
    """Extract the entry points from the registry."""
    entrypoints = OrderedDict()

    for command in doc.findall('./commands/command'):
       if 'alias' in command.attrib:
           alias = command.attrib['name']
           target = command.attrib['alias']
           entrypoints[alias] = EntrypointAlias(alias, entrypoints[target])
       else:
           name = command.find('./proto/name').text
           ret_type = command.find('./proto/type').text
           params = [EntrypointParam(
               type = p.find('./type').text,
               name = p.find('./name').text,
               decl = ''.join(p.itertext())
           ) for p in command.findall('./param')]
           guard = entrypoints_to_defines.get(name)
           # They really need to be unique
           assert name not in entrypoints
           entrypoints[name] = Entrypoint(name, ret_type, params, guard)

    for feature in doc.findall('./feature'):
        assert feature.attrib['api'] == 'vulkan'
        version = VkVersion(feature.attrib['number'])
        if version > MAX_API_VERSION:
            continue

        for command in feature.findall('./require/command'):
            e = entrypoints[command.attrib['name']]
            e.enabled = True
            assert e.core_version is None
            e.core_version = version

    supported_exts = dict((ext.name, ext) for ext in EXTENSIONS)
    for extension in doc.findall('.extensions/extension'):
        ext_name = extension.attrib['name']
        if ext_name not in supported_exts:
            continue

        ext = supported_exts[ext_name]
        ext.type = extension.attrib['type']

        for command in extension.findall('./require/command'):
            e = entrypoints[command.attrib['name']]
            e.enabled = True
            assert e.core_version is None
            e.extensions.append(ext)

    # if the base command is not supported by the driver yet, don't alias aliases
    for e in entrypoints.values():
        if e.alias and not e.alias.enabled:
            e_clone = copy.deepcopy(e.alias)
            e_clone.enabled = True
            e_clone.name = e.name
            entrypoints[e.name] = e_clone

    return [e for e in entrypoints.values() if e.enabled]


def get_entrypoints_defines(doc):
    """Maps entry points to extension defines."""
    entrypoints_to_defines = {}

    platform_define = {}
    for platform in doc.findall('./platforms/platform'):
        name = platform.attrib['name']
        define = platform.attrib['protect']
        platform_define[name] = define

    for extension in doc.findall('./extensions/extension[@platform]'):
        platform = extension.attrib['platform']
        define = platform_define[platform]

        for entrypoint in extension.findall('./require/command'):
            fullname = entrypoint.attrib['name']
            entrypoints_to_defines[fullname] = define

    return entrypoints_to_defines

def main():
    parser = argparse.ArgumentParser()
    parser.add_argument('--outdir', help='Where to write the files.',
                        required=True)
    parser.add_argument('--xml',
                        help='Vulkan API XML file.',
                        required=True,
                        action='append',
                        dest='xml_files')
    args = parser.parse_args()

    entrypoints = []

    for filename in args.xml_files:
        doc = et.parse(filename)
        entrypoints += get_entrypoints(doc, get_entrypoints_defines(doc))

    device_entrypoints = []
    physical_device_entrypoints = []
    instance_entrypoints = []
    for e in entrypoints:
        if e.is_device_entrypoint():
            device_entrypoints.append(e)
        elif e.is_physical_device_entrypoint():
            physical_device_entrypoints.append(e)
        else:
            instance_entrypoints.append(e)

    device_strmap = StringIntMap()
    for num, e in enumerate(device_entrypoints):
        device_strmap.add_string(e.name, num)
        e.num = num
    device_strmap.bake()

    physical_device_strmap = StringIntMap()
    for num, e in enumerate(physical_device_entrypoints):
        physical_device_strmap.add_string(e.name, num)
        e.num = num
    physical_device_strmap.bake()

    instance_strmap = StringIntMap()
    for num, e in enumerate(instance_entrypoints):
        instance_strmap.add_string(e.name, num)
        e.num = num
    instance_strmap.bake()

    # For outputting entrypoints.h we generate a radv_EntryPoint() prototype
    # per entry point.
    try:
        with open(os.path.join(args.outdir, 'radv_entrypoints.h'), 'wb') as f:
            f.write(TEMPLATE_H.render(instance_entrypoints=instance_entrypoints,
                                      physical_device_entrypoints=physical_device_entrypoints,
                                      device_entrypoints=device_entrypoints,
                                      LAYERS=LAYERS,
                                      filename=os.path.basename(__file__)))
        with open(os.path.join(args.outdir, 'radv_entrypoints.c'), 'wb') as f:
            f.write(TEMPLATE_C.render(instance_entrypoints=instance_entrypoints,
                                      physical_device_entrypoints=physical_device_entrypoints,
                                      device_entrypoints=device_entrypoints,
                                      LAYERS=LAYERS,
                                      instance_strmap=instance_strmap,
                                      physical_device_strmap=physical_device_strmap,
                                      device_strmap=device_strmap,
                                      filename=os.path.basename(__file__)))
    except Exception:
        # In the event there's an error, this imports some helpers from mako
        # to print a useful stack trace and prints it, then exits with
        # status 1, if python is run with debug; otherwise it just raises
        # the exception
        if __debug__:
            import sys
            from mako import exceptions
            sys.stderr.write(exceptions.text_error_template().render() + '\n')
            sys.exit(1)
        raise


if __name__ == '__main__':
    main()