kc3-lang/angle/src/libANGLE/gen_overlay_widgets.py

• Show log

  Commit

• Hash : 48b928d9
  Author :
  Date : 2022-06-07T16:21:04
  

  Vulkan: Overlay widgets for pipeline cache/hit stats
  
  Bug: angleproject:5881
  Change-Id: I1893e6b76a5a73ea51b67bc4ee8a5d5dfc54166e
  Reviewed-on: https://chromium-review.googlesource.com/c/angle/angle/+/3689604
  Reviewed-by: Jamie Madill <jmadill@chromium.org>
  Reviewed-by: Yuxin Hu <yuxinhu@google.com>
  Commit-Queue: Shahbaz Youssefi <syoussefi@chromium.org>
  

Download

• src/libANGLE/gen_overlay_widgets.py

• #! /usr/bin/python3
  
  # Copyright 2019 The ANGLE Project Authors. All rights reserved.
  # Use of this source code is governed by a BSD-style license that can be
  # found in the LICENSE file.
  #
  # gen_overlay_widgets.py:
  #  Code generation for overlay widgets.  Should be run when the widgets declaration file,
  #  overlay_widgets.json, is changed.
  #  NOTE: don't run this script directly. Run scripts/run_code_generation.py.
  
  import json
  import os
  import sys
  
  OUT_SOURCE_FILE_NAME = 'Overlay_autogen.cpp'
  OUT_HEADER_FILE_NAME = 'Overlay_autogen.h'
  
  IN_JSON_FILE_NAME = 'overlay_widgets.json'
  
  OUT_SOURCE_FILE_TEMPLATE = u"""// GENERATED FILE - DO NOT EDIT.
  // Generated by {script_name} using data from {input_file_name}.
  //
  // Copyright 2019 The ANGLE Project Authors. All rights reserved.
  // Use of this source code is governed by a BSD-style license that can be
  // found in the LICENSE file.
  //
  // {out_file_name}:
  //   Autogenerated overlay widget declarations.
  
  #include "libANGLE/renderer/driver_utils.h"
  #include "libANGLE/Overlay.h"
  #include "libANGLE/OverlayWidgets.h"
  #include "libANGLE/Overlay_font_autogen.h"
  
  namespace gl
  {{
  using namespace overlay;
  
  namespace
  {{
  int GetFontSize(int fontSize, bool largeFont)
  {{
      if (largeFont && fontSize > 0)
      {{
          return fontSize - 1;
      }}
      return fontSize;
  }}
  }}  // anonymous namespace
  
  void Overlay::initOverlayWidgets()
  {{
      const bool kLargeFont = rx::IsAndroid();
  
      {init_widgets}
  }}
  
  }}  // namespace gl
  
  """
  
  OUT_HEADER_FILE_TEMPLATE = u"""// GENERATED FILE - DO NOT EDIT.
  // Generated by {script_name} using data from {input_file_name}.
  //
  // Copyright 2019 The ANGLE Project Authors. All rights reserved.
  // Use of this source code is governed by a BSD-style license that can be
  // found in the LICENSE file.
  //
  // {out_file_name}:
  //   Autogenerated overlay widget declarations.
  
  namespace gl
  {{
  enum class WidgetId
  {{
  {widget_ids}
      InvalidEnum,
      EnumCount = InvalidEnum,
  }};
  
  // We can use this "X" macro to generate multiple code patterns.
  #define ANGLE_WIDGET_ID_X(PROC) \
  {widget_x_defs}
  
  }}  // namespace gl
  """
  
  WIDGET_INIT_TEMPLATE = u"""{{
  const int32_t fontSize = GetFontSize({font_size}, kLargeFont);
  const int32_t offsetX = {offset_x};
  const int32_t offsetY = {offset_y};
  const int32_t width = {width};
  const int32_t height = {height};
  
  widget->{subwidget}type          = WidgetType::{type};
  widget->{subwidget}fontSize      = fontSize;
  widget->{subwidget}coords[0]     = {coord0};
  widget->{subwidget}coords[1]     = {coord1};
  widget->{subwidget}coords[2]     = {coord2};
  widget->{subwidget}coords[3]     = {coord3};
  widget->{subwidget}color[0]      = {color_r}f;
  widget->{subwidget}color[1]      = {color_g}f;
  widget->{subwidget}color[2]      = {color_b}f;
  widget->{subwidget}color[3]      = {color_a}f;
  widget->{subwidget}matchToWidget = {match_to};
  }}
  """
  
  WIDGET_ID_TEMPLATE = """    // {comment}
      {name},
  """
  
  
  def extract_type_and_constructor(properties):
      constructor = properties['type']
      args_separated = constructor.split('(', 1)
      if len(args_separated) == 1:
          return constructor, constructor
  
      type_no_constructor = args_separated[0]
      return type_no_constructor, constructor
  
  
  def get_font_size_constant(properties):
      return 'kFontMip' + properties['font'].capitalize()
  
  
  def is_graph_type(type):
      return type == 'RunningGraph' or type == 'RunningHistogram'
  
  
  def is_text_type(type):
      return not is_graph_type(type)
  
  
  class OverlayWidget:
  
      def __init__(self, properties, is_graph_description=False):
          if not is_graph_description:
              self.name = properties['name']
          self.type, self.constructor = extract_type_and_constructor(properties)
          self.extract_common(properties)
  
          if is_graph_type(self.type):
              description_properties = properties['description']
              description_properties['type'] = 'Text'
              self.description = OverlayWidget(description_properties, True)
  
      def extract_common(self, properties):
          self.color = properties['color']
          self.coords = properties['coords']
          self.match_to = properties.get('match_to', None)
          if is_graph_type(self.type):
              self.bar_width = properties['bar_width']
              self.height = properties['height']
          else:
              self.font = get_font_size_constant(properties)
              self.length = properties['length']
  
          self.negative_alignment = [False, False]
  
  
  def get_relative_coord_widget(coord, widgets_so_far):
      if not isinstance(coord, str):
          return None
  
      coord_split = coord.split('.')
      widget = widgets_so_far[coord_split[0]]
      if len(coord_split) > 3:
          widget = widget.description
  
      return widget
  
  
  def parse_relative_coord(coord):
  
      # The input coordinate (widget.coord[axis]) is either:
      #
      # - a number
      # - other_widget.edge.mode:
      #   * edge is in {left, right} or {top, bottom} based on axis
      #   * mode is in {align, adjacent}
      # - other_widget.desc.edge.mode: this is similar to other_widget.edge.mode, except
      #                                it refers to a graph widget's description widget
      #
      # This function parses the last two possibilities.
      if not isinstance(coord, str):
          return None, None, None
  
      coord_split = coord.split('.')
      coords_expr = 'mState.mOverlayWidgets[WidgetId::' + coord_split[0] + ']'
      if len(coord_split) > 3:
          assert len(coord_split) == 4 and coord_split[1] == 'desc'
          coords_expr += '->getDescriptionWidget()'
      coords_expr += '->coords'
  
      edge = coord_split[-2]
      mode = coord_split[-1]
  
      return coords_expr, edge, mode
  
  
  def is_negative_coord(coords, axis, widgets_so_far):
  
      other_widget = get_relative_coord_widget(coords[axis], widgets_so_far)
      if other_widget is not None:
          # We simply need to know if other_widget's coordinate is negative or not.
          return other_widget.negative_alignment[axis]
  
      return coords[axis] < 0
  
  
  def set_alignment_flags(overlay_widget, widgets_so_far):
      overlay_widget.negative_alignment[0] = is_negative_coord(overlay_widget.coords, 0,
                                                               widgets_so_far)
      overlay_widget.negative_alignment[1] = is_negative_coord(overlay_widget.coords, 1,
                                                               widgets_so_far)
  
      if is_graph_type(overlay_widget.type):
          set_alignment_flags(overlay_widget.description, widgets_so_far)
  
  
  def get_offset_helper(widget, axis, smaller_coord_side):
      # Assume axis is X.  This function returns two values:
      # - An offset where the bounding box is placed at,
      # - Whether this offset is for the left or right edge.
      #
      # The input coordinate (widget.coord[axis]) is either:
      #
      # - a number: in this case, the offset is that number, and its sign
      #             determines whether this refers to the left or right edge of
      #             the bounding box.
      # - other_widget[.desc].edge.mode: this has multiple possibilities:
      #   * edge=left, mode=align: the offset is other_widget[.desc].left, the edge is left.
      #   * edge=left, mode=adjacent: the offset is other_widget[.desc].left, the edge is right.
      #   * edge=right, mode=align: the offset is other_widget[.desc].right, the edge is right.
      #   * edge=right, mode=adjacent: the offset is other_widget[.desc].right, the edge is left.
      #
      # The case for the Y axis is similar, with the edge values being top or bottom.
  
      coord = widget.coords[axis]
  
      other_coords_expr, relative_edge, relative_mode = parse_relative_coord(coord)
      if other_coords_expr is None:
          is_left = coord >= 0
          return coord, is_left
  
      is_left = relative_edge == smaller_coord_side
      is_align = relative_mode == 'align'
  
      other_widget_coord_index = axis + (0 if is_left else 2)
      offset = other_coords_expr + '[' + str(other_widget_coord_index) + ']'
  
      return offset, is_left == is_align
  
  
  def get_offset_x(widget):
      return get_offset_helper(widget, 0, 'left')
  
  
  def get_offset_y(widget):
      return get_offset_helper(widget, 1, 'top')
  
  
  def get_bounding_box_coords(offset, width, offset_is_left, is_left_aligned):
      # See comment in generate_widget_init_helper.  This function is implementing the following:
      #
      # -  offset_is_left &&  is_left_aligned: [offset, offset + width]
      # -  offset_is_left && !is_left_aligned: [offset, std::min(offset + width, -1)]
      # - !offset_is_left &&  is_left_aligned: [std::max(1, offset - width), offset]
      # - !offset_is_left && !is_left_aligned: [offset - width, offset]
  
      coord_left = offset if offset_is_left else (offset + ' - ' + width)
      coord_right = (offset + ' + ' + width) if offset_is_left else offset
  
      if offset_is_left and not is_left_aligned:
          coord_right = 'std::min(' + coord_right + ', -1)'
      if not offset_is_left and is_left_aligned:
          coord_left = 'std::max(' + coord_left + ', 1)'
  
      return coord_left, coord_right
  
  
  def generate_widget_init_helper(widget, is_graph_description=False):
      font_size = '0'
  
      # Common attributes
      color = [channel / 255.0 for channel in widget.color]
      offset_x, offset_x_is_left = get_offset_x(widget)
      offset_y, offset_y_is_top = get_offset_y(widget)
  
      if is_text_type(widget.type):
          # Attributes deriven from text properties
          font_size = widget.font
          width = str(widget.length) + ' * (kFontGlyphWidth >> fontSize)'
          height = '(kFontGlyphHeight >> fontSize)'
      else:
          # Attributes deriven from graph properties
          width = str(widget.bar_width) + ' * static_cast<uint32_t>(widget->runningValues.size())'
          height = widget.height
  
      is_left_aligned = not widget.negative_alignment[0]
      is_top_aligned = not widget.negative_alignment[1]
  
      # We have offset_x, offset_y, width and height which together determine the bounding box.  If
      # offset_x_is_left, the bounding box X would be in [offset_x, offset_x + width], otherwise it
      # would be in [offset_x - width, offset_x].  Similarly for y.  Since we use negative values to
      # mean aligned to the right side of the screen, we need to make sure that:
      #
      # - if left aligned: offset_x - width is at minimum 1
      # - if right aligned: offset_x + width is at maximum -1
      #
      # We therefore have the following combinations for the X axis:
      #
      # -  offset_x_is_left &&  is_left_aligned: [offset_x, offset_x + width]
      # -  offset_x_is_left && !is_left_aligned: [offset_x, std::min(offset_x + width, -1)]
      # - !offset_x_is_left &&  is_left_aligned: [std::max(1, offset_x - width), offset_x]
      # - !offset_x_is_left && !is_left_aligned: [offset_x - width, offset_x]
      #
      # Similarly for y.
      coord0, coord2 = get_bounding_box_coords('offsetX', 'width', offset_x_is_left, is_left_aligned)
      coord1, coord3 = get_bounding_box_coords('offsetY', 'height', offset_y_is_top, is_top_aligned)
  
      match_to = 'nullptr' if widget.match_to is None else \
                 'mState.mOverlayWidgets[WidgetId::' + widget.match_to + '].get()'
  
      return WIDGET_INIT_TEMPLATE.format(
          subwidget='description.' if is_graph_description else '',
          offset_x=offset_x,
          offset_y=offset_y,
          width=width,
          height=height,
          type=widget.type,
          font_size=font_size,
          coord0=coord0,
          coord1=coord1,
          coord2=coord2,
          coord3=coord3,
          color_r=color[0],
          color_g=color[1],
          color_b=color[2],
          color_a=color[3],
          match_to=match_to)
  
  
  def generate_widget_init(widget):
      widget_init = '{\n' + widget.type + ' *widget = new ' + widget.constructor + ';\n'
  
      widget_init += generate_widget_init_helper(widget)
      widget_init += 'mState.mOverlayWidgets[WidgetId::' + widget.name + '].reset(widget);\n'
  
      if is_graph_type(widget.type):
          widget_init += generate_widget_init_helper(widget.description, True)
  
      widget_init += '}\n'
  
      return widget_init
  
  
  def main():
      if len(sys.argv) == 2 and sys.argv[1] == 'inputs':
          print(IN_JSON_FILE_NAME)
          return
      if len(sys.argv) == 2 and sys.argv[1] == 'outputs':
          outputs = [
              OUT_SOURCE_FILE_NAME,
              OUT_HEADER_FILE_NAME,
          ]
          print(','.join(outputs))
          return
  
      with open(IN_JSON_FILE_NAME) as fin:
          layout = json.loads(fin.read())
  
      widgets = layout['widgets']
  
      # Read the layouts from the json file and determine alignment of widgets (as they can refer to
      # other widgets.
      overlay_widgets = {}
      for widget_properties in widgets:
          widget = OverlayWidget(widget_properties)
          overlay_widgets[widget.name] = widget
          set_alignment_flags(widget, overlay_widgets)
  
      # Go over the widgets again and generate initialization code.  Note that we need to iterate over
      # the widgets in order, so we can't use the overlay_widgets dictionary for iteration.
      init_widgets = []
      for widget_properties in widgets:
          init_widgets.append(generate_widget_init(overlay_widgets[widget_properties['name']]))
  
      with open(OUT_SOURCE_FILE_NAME, 'w') as outfile:
          outfile.write(
              OUT_SOURCE_FILE_TEMPLATE.format(
                  script_name=os.path.basename(__file__),
                  input_file_name=IN_JSON_FILE_NAME,
                  out_file_name=OUT_SOURCE_FILE_NAME,
                  init_widgets='\n'.join(init_widgets)))
          outfile.close()
  
      with open(OUT_HEADER_FILE_NAME, 'w') as outfile:
          widget_ids = [WIDGET_ID_TEMPLATE.format(**widget) for widget in widgets]
          widget_x_defs = ["PROC(" + widget['name'] + ")" for widget in widgets]
  
          outfile.write(
              OUT_HEADER_FILE_TEMPLATE.format(
                  script_name=os.path.basename(__file__),
                  input_file_name=IN_JSON_FILE_NAME,
                  out_file_name=OUT_SOURCE_FILE_NAME,
                  widget_ids=''.join(widget_ids),
                  widget_x_defs=' \\\n'.join(widget_x_defs)))
          outfile.close()
  
  
  if __name__ == '__main__':
      sys.exit(main())
  

Download