def render(self):
read_game = self.env.read_game
frame = self.env.frame
if not read_game.is_in_game or not keys["KEY_RADAR"]:
return
rx = self.rx = int(read_game.resolution_x / 2 - RADAR_SIZE / 2 + RADAR_CENTER_X)
ry = self.ry = RADAR_OFFSET
rh = rw = self.rh = self.rw = RADAR_SIZE
r = D3DRECT(rx, ry, rx + rw, ry + rh)
frame.device.Clear(1, byref(r), D3DCLEAR.TARGET, MAP_COLOR_BACK, 1, 0)
draw4(frame.line, rx, ry, rx + rw, ry, rx + rw, ry + rh, rx, ry + rh, 2, MAP_COLOR_BORDER)
draw_arrow(frame.line, rx + rw / 2, ry + rh / 2, 0, MAP_COLOR_ME)
# myself
for p in read_game.player:
if p != read_game.my_player and p.type == ET_PLAYER and p.valid and p.alive & ALIVE_FLAG:
cx, cy = self.calcPoint(p.pos, RADAR_RANGE)
draw_arrow(frame.line, cx, cy, -p.yaw + read_game.view_angles.y, p.color_map)
# clibrating is a debug mode
if CALIBRATING:
origin = VECTOR(0, 0, 0)
cx, cy = self.calcPoint(origin, RADAR_RANGE)
draw_spot(frame.line, cx, cy, 0x7FFFFFFF)
def render(self):
read_game = self.env.read_game
frame = self.env.frame
bot = self.env.bot
if not read_game.is_in_game or not keys["KEY_BOT_VISUAL_MOUSE"]: return
rh = rw = VISUAL_MOUSE_SIZE + (VISUAL_MOUSE_SIZE % 2)
rx = read_game.resolution_x - rw - VISUAL_MOUSE_RIGHT_MARGIN
ry = read_game.resolution_y - rh - VISUAL_MOUSE_BOTTOM_MARGIN
r = D3DRECT(rx, ry, rx + rw, ry + rh)
frame.device.Clear(1, byref(r), D3DCLEAR.TARGET, VISUAL_MOUSE_COLOR_BACK, 1, 0)
draw4(frame.line, rx, ry, rx+rw, ry, rx+rw, ry+rh, rx, ry+rh, 2, VISUAL_MOUSE_COLOR_BORDER)
line_x = bot.mouse_move_x
line_y = bot.mouse_move_y
if (line_x < -rw/2): line_x = -rw/2
if (line_x > +rw/2): line_x = +rw/2
if (line_y < -rh/2): line_y = -rh/2
if (line_y > +rh/2): line_y = +rh/2
draw_line(frame.line, rx + rw/2, ry, 0, rh, 1, VISUAL_MOUSE_COLOR_CROSSHAIR)
draw_line(frame.line, rx, ry + rh/2, rw, 0, 1, VISUAL_MOUSE_COLOR_CROSSHAIR)
draw_line(frame.line, rx + rw/2, ry + rh/2, line_x, line_y, VISUAL_MOUSE_LINE_WIDTH, VISUAL_MOUSE_COLOR_LINE)
def render(self):
read_game = self.env.read_game
frame = self.env.frame
textures = self.env.textures
if not read_game.is_in_game or not keys["KEY_RADAR"]: return
rx = self.rx = int(read_game.resolution_x/2 - RADAR_SIZE/2 + RADAR_CENTER_X)
ry = self.ry = RADAR_OFFSET
rh = rw = self.rh = self.rw = RADAR_SIZE
scaling = 0.5 # TODO
pos = read_game.mw2_mypos
map_name = read_game.map_name # name of the current map
p_matrix = textures.matrix[map_name] # transformation matrix (scale + rotation)
transl = textures.translations[map_name] # translation vector to correct with map origin
map_pos = VECTOR() # contains the coord on the map (with applied scaling)
map_pos.x = scaling * (transl[0] + p_matrix[0]*pos.x + p_matrix[1]*pos.y)
map_pos.y = scaling * (transl[1] + p_matrix[2]*pos.x + p_matrix[3]*pos.y)
arrow_angle = textures.angle[map_name] # offset to apply to angles (only in estate)s
arrow_inversion = textures.angle_inversion[map_name]
sprite_center = D3DXVECTOR2(map_pos.x, map_pos.y)
trans = D3DXVECTOR2(rx + rw/2 - map_pos.x, ry + rh/2 - map_pos.y) # global translation
#print "x=%.2f y=%.2f" % (new_pos.x, new_pos.y )
angle = radians(read_game.view_angles.y - arrow_angle)
matrix = D3DMATRIX()
d3dxdll.D3DXMatrixAffineTransformation2D(byref(matrix), #@UndefinedVariable
c_float(scaling), # scaling
byref(sprite_center), # rotation center
c_float(angle), # angle
byref(trans) # translation
)
r = D3DRECT(rx, ry, rx + rw, ry + rh)
frame.device.Clear(1, byref(r), D3DCLEAR.TARGET, MAP_COLOR_BACK, 1, 0)
if keys["KEY_RADAR_MAP"]:
frame.device.SetRenderState(174, True)
save_scissors = None
try:
save_scissors = RECT()
frame.device.GetScissorRect(byref(save_scissors))
scissors = RECT(rx, ry, rx+rw, ry+rh)
frame.device.SetScissorRect(byref(scissors))
except:
pass
frame.sprite.Begin(0)
frame.sprite.SetTransform(matrix)
frame.sprite.Draw(textures.textures[map_name], None, None, None, BIG_RADAR_BLENDING)
frame.sprite.Flush()
frame.sprite.End()
frame.device.SetRenderState(174, False)
if not save_scissors is None:
frame.device.SetScissorRect(byref(save_scissors))
draw4(frame.line, rx, ry, rx+rw, ry, rx+rw, ry+rh, rx, ry+rh, 2, MAP_COLOR_BORDER)
p_pos = VECTOR()
for te in self.env.tracker.get_tracked_entity_list():
p_pos.x = transl[0] + p_matrix[0]*te.pos.x + p_matrix[1]*te.pos.y
p_pos.y = transl[1] + p_matrix[2]*te.pos.x + p_matrix[3]*te.pos.y
cx, cy = self.calcPoint(p_pos, matrix)
if te.type == ET_TURRET:
self.env.sprites.draw_sentry(cx, cy, te.planter.enemy)
if te.type == ET_HELICOPTER:
self.env.sprites.draw_heli(cx, cy, -te.yaw + read_game.view_angles.y + arrow_angle + arrow_inversion, te.planter.enemy, te.weapon_num)
if te.type == ET_PLANE:
self.env.sprites.draw_plane(cx, cy, -te.yaw + read_game.view_angles.y + arrow_angle + arrow_inversion, te.planter.enemy)
if te.type == ET_EXPLOSIVE and te.model_name.find("_AIRDROP_") > 0:
self.env.sprites.draw_flare(cx, cy)
draw_arrow(frame.line, rx + rw/2, ry + rh/2, 0, MAP_COLOR_ME); # myself
for p in read_game.player:
if p != read_game.my_player and p.type == ET_PLAYER and p.valid and p.alive & ALIVE_FLAG:
p_pos.x = transl[0] + p_matrix[0]*p.pos.x + p_matrix[1]*p.pos.y
p_pos.y = transl[1] + p_matrix[2]*p.pos.x + p_matrix[3]*p.pos.y
cx, cy = self.calcPoint(p_pos, matrix)
draw_arrow(frame.line, cx, cy, -p.yaw + read_game.view_angles.y + arrow_angle + arrow_inversion, p.color_map);
