openpilot_comma/selfdrive/modeld/fill_model_msg.py

import capnp
import numpy as np
from typing import Dict
from cereal import log
from openpilot.selfdrive.modeld.constants import ModelConstants, Plan, Meta

ConfidenceClass = log.ModelDataV2.ConfidenceClass

class PublishState:
  def __init__(self):
    self.disengage_buffer = np.zeros(ModelConstants.CONFIDENCE_BUFFER_LEN*ModelConstants.DISENGAGE_WIDTH, dtype=np.float32)
    self.prev_brake_5ms2_probs = np.zeros(ModelConstants.DISENGAGE_WIDTH, dtype=np.float32)
    self.prev_brake_3ms2_probs = np.zeros(ModelConstants.DISENGAGE_WIDTH, dtype=np.float32)

def fill_xyzt(builder, t, x, y, z, x_std=None, y_std=None, z_std=None):
  builder.t = t
  builder.x = x.tolist()
  builder.y = y.tolist()
  builder.z = z.tolist()
  if x_std is not None:
    builder.xStd = x_std.tolist()
  if y_std is not None:
    builder.yStd = y_std.tolist()
  if z_std is not None:
    builder.zStd = z_std.tolist()

def fill_xyvat(builder, t, x, y, v, a, x_std=None, y_std=None, v_std=None, a_std=None):
  builder.t = t
  builder.x = x.tolist()
  builder.y = y.tolist()
  builder.v = v.tolist()
  builder.a = a.tolist()
  if x_std is not None:
    builder.xStd = x_std.tolist()
  if y_std is not None:
    builder.yStd = y_std.tolist()
  if v_std is not None:
    builder.vStd = v_std.tolist()
  if a_std is not None:
    builder.aStd = a_std.tolist()

def fill_model_msg(msg: capnp._DynamicStructBuilder, net_output_data: Dict[str, np.ndarray], publish_state: PublishState,
                   vipc_frame_id: int, vipc_frame_id_extra: int, frame_id: int, frame_drop: float,
                   timestamp_eof: int, timestamp_llk: int, model_execution_time: float,
                   nav_enabled: bool, valid: bool) -> None:
  frame_age = frame_id - vipc_frame_id if frame_id > vipc_frame_id else 0
  msg.valid = valid

  modelV2 = msg.modelV2
  modelV2.frameId = vipc_frame_id
  modelV2.frameIdExtra = vipc_frame_id_extra
  modelV2.frameAge = frame_age
  modelV2.frameDropPerc = frame_drop * 100
  modelV2.timestampEof = timestamp_eof
  modelV2.locationMonoTime = timestamp_llk
  modelV2.modelExecutionTime = model_execution_time
  modelV2.navEnabled = nav_enabled

  # plan
  position = modelV2.position
  fill_xyzt(position, ModelConstants.T_IDXS, *net_output_data['plan'][0,:,Plan.POSITION].T, *net_output_data['plan_stds'][0,:,Plan.POSITION].T)
  velocity = modelV2.velocity
  fill_xyzt(velocity, ModelConstants.T_IDXS, *net_output_data['plan'][0,:,Plan.VELOCITY].T)
  acceleration = modelV2.acceleration
  fill_xyzt(acceleration, ModelConstants.T_IDXS, *net_output_data['plan'][0,:,Plan.ACCELERATION].T)
  orientation = modelV2.orientation
  fill_xyzt(orientation, ModelConstants.T_IDXS, *net_output_data['plan'][0,:,Plan.T_FROM_CURRENT_EULER].T)
  orientation_rate = modelV2.orientationRate
  fill_xyzt(orientation_rate, ModelConstants.T_IDXS, *net_output_data['plan'][0,:,Plan.ORIENTATION_RATE].T)

  # times at X_IDXS according to model plan
  PLAN_T_IDXS = [np.nan] * ModelConstants.IDX_N
  PLAN_T_IDXS[0] = 0.0
  plan_x = net_output_data['plan'][0,:,Plan.POSITION][:,0].tolist()
  for xidx in range(1, ModelConstants.IDX_N):
    tidx = 0
    # increment tidx until we find an element that's further away than the current xidx
    while tidx < ModelConstants.IDX_N - 1 and plan_x[tidx+1] < ModelConstants.X_IDXS[xidx]:
      tidx += 1
    if tidx == ModelConstants.IDX_N - 1:
      # if the Plan doesn't extend far enough, set plan_t to the max value (10s), then break
      PLAN_T_IDXS[xidx] = ModelConstants.T_IDXS[ModelConstants.IDX_N - 1]
      break
    # interpolate to find `t` for the current xidx
    current_x_val = plan_x[tidx]
    next_x_val = plan_x[tidx+1]
    p = (ModelConstants.X_IDXS[xidx] - current_x_val) / (next_x_val - current_x_val)
    PLAN_T_IDXS[xidx] = p * ModelConstants.T_IDXS[tidx+1] + (1 - p) * ModelConstants.T_IDXS[tidx]

  # lane lines
  modelV2.init('laneLines', 4)
  for i in range(4):
    lane_line = modelV2.laneLines[i]
    fill_xyzt(lane_line, PLAN_T_IDXS, np.array(ModelConstants.X_IDXS), net_output_data['lane_lines'][0,i,:,0], net_output_data['lane_lines'][0,i,:,1])
  modelV2.laneLineStds = net_output_data['lane_lines_stds'][0,:,0,0].tolist()
  modelV2.laneLineProbs = net_output_data['lane_lines_prob'][0,1::2].tolist()

  # road edges
  modelV2.init('roadEdges', 2)
  for i in range(2):
    road_edge = modelV2.roadEdges[i]
    fill_xyzt(road_edge, PLAN_T_IDXS, np.array(ModelConstants.X_IDXS), net_output_data['road_edges'][0,i,:,0], net_output_data['road_edges'][0,i,:,1])
  modelV2.roadEdgeStds = net_output_data['road_edges_stds'][0,:,0,0].tolist()

  # leads
  modelV2.init('leadsV3', 3)
  for i in range(3):
    lead = modelV2.leadsV3[i]
    fill_xyvat(lead, ModelConstants.LEAD_T_IDXS, *net_output_data['lead'][0,i].T, *net_output_data['lead_stds'][0,i].T)
    lead.prob = net_output_data['lead_prob'][0,i].tolist()
    lead.probTime = ModelConstants.LEAD_T_OFFSETS[i]

  # meta
  meta = modelV2.meta
  meta.desireState = net_output_data['desire_state'][0].reshape(-1).tolist()
  meta.desirePrediction = net_output_data['desire_pred'][0].reshape(-1).tolist()
  meta.engagedProb = net_output_data['meta'][0,Meta.ENGAGED].item()
  meta.init('disengagePredictions')
  disengage_predictions = meta.disengagePredictions
  disengage_predictions.t = ModelConstants.META_T_IDXS
  disengage_predictions.brakeDisengageProbs = net_output_data['meta'][0,Meta.BRAKE_DISENGAGE].tolist()
  disengage_predictions.gasDisengageProbs = net_output_data['meta'][0,Meta.GAS_DISENGAGE].tolist()
  disengage_predictions.steerOverrideProbs = net_output_data['meta'][0,Meta.STEER_OVERRIDE].tolist()
  disengage_predictions.brake3MetersPerSecondSquaredProbs = net_output_data['meta'][0,Meta.HARD_BRAKE_3].tolist()
  disengage_predictions.brake4MetersPerSecondSquaredProbs = net_output_data['meta'][0,Meta.HARD_BRAKE_4].tolist()
  disengage_predictions.brake5MetersPerSecondSquaredProbs = net_output_data['meta'][0,Meta.HARD_BRAKE_5].tolist()

  publish_state.prev_brake_5ms2_probs[:-1] = publish_state.prev_brake_5ms2_probs[1:]
  publish_state.prev_brake_5ms2_probs[-1] = net_output_data['meta'][0,Meta.HARD_BRAKE_5][0]
  publish_state.prev_brake_3ms2_probs[:-1] = publish_state.prev_brake_3ms2_probs[1:]
  publish_state.prev_brake_3ms2_probs[-1] = net_output_data['meta'][0,Meta.HARD_BRAKE_3][0]
  hard_brake_predicted = (publish_state.prev_brake_5ms2_probs > ModelConstants.FCW_THRESHOLDS_5MS2).all() and \
    (publish_state.prev_brake_3ms2_probs > ModelConstants.FCW_THRESHOLDS_3MS2).all()
  meta.hardBrakePredicted = hard_brake_predicted.item()

  # temporal pose
  temporal_pose = modelV2.temporalPose
  temporal_pose.trans = net_output_data['sim_pose'][0,:3].tolist()
  temporal_pose.transStd = net_output_data['sim_pose_stds'][0,:3].tolist()
  temporal_pose.rot = net_output_data['sim_pose'][0,3:].tolist()
  temporal_pose.rotStd = net_output_data['sim_pose_stds'][0,3:].tolist()

  # confidence
  if vipc_frame_id % (2*ModelConstants.MODEL_FREQ) == 0:
    # any disengage prob
    brake_disengage_probs = net_output_data['meta'][0,Meta.BRAKE_DISENGAGE]
    gas_disengage_probs = net_output_data['meta'][0,Meta.GAS_DISENGAGE]
    steer_override_probs = net_output_data['meta'][0,Meta.STEER_OVERRIDE]
    any_disengage_probs = 1-((1-brake_disengage_probs)*(1-gas_disengage_probs)*(1-steer_override_probs))
    # independent disengage prob for each 2s slice
    ind_disengage_probs = np.r_[any_disengage_probs[0], np.diff(any_disengage_probs) / (1 - any_disengage_probs[:-1])]
    # rolling buf for 2, 4, 6, 8, 10s
    publish_state.disengage_buffer[:-ModelConstants.DISENGAGE_WIDTH] = publish_state.disengage_buffer[ModelConstants.DISENGAGE_WIDTH:]
    publish_state.disengage_buffer[-ModelConstants.DISENGAGE_WIDTH:] = ind_disengage_probs

  score = 0.
  for i in range(ModelConstants.DISENGAGE_WIDTH):
    score += publish_state.disengage_buffer[i*ModelConstants.DISENGAGE_WIDTH+ModelConstants.DISENGAGE_WIDTH-1-i].item() / ModelConstants.DISENGAGE_WIDTH
  if score < ModelConstants.RYG_GREEN:
    modelV2.confidence = ConfidenceClass.green
  elif score < ModelConstants.RYG_YELLOW:
    modelV2.confidence = ConfidenceClass.yellow
  else:
    modelV2.confidence = ConfidenceClass.red

def fill_pose_msg(msg: capnp._DynamicStructBuilder, net_output_data: Dict[str, np.ndarray],
                  vipc_frame_id: int, vipc_dropped_frames: int, timestamp_eof: int, live_calib_seen: bool) -> None:
  msg.valid = live_calib_seen & (vipc_dropped_frames < 1)
  cameraOdometry = msg.cameraOdometry

  cameraOdometry.frameId = vipc_frame_id
  cameraOdometry.timestampEof = timestamp_eof

  cameraOdometry.trans = net_output_data['pose'][0,:3].tolist()
  cameraOdometry.rot = net_output_data['pose'][0,3:].tolist()
  cameraOdometry.wideFromDeviceEuler = net_output_data['wide_from_device_euler'][0,:].tolist()
  cameraOdometry.roadTransformTrans = net_output_data['road_transform'][0,:3].tolist()
  cameraOdometry.transStd = net_output_data['pose_stds'][0,:3].tolist()
  cameraOdometry.rotStd = net_output_data['pose_stds'][0,3:].tolist()
  cameraOdometry.wideFromDeviceEulerStd = net_output_data['wide_from_device_euler_stds'][0,:].tolist()
  cameraOdometry.roadTransformTransStd = net_output_data['road_transform_stds'][0,:3].tolist()
modeld: parsing and publishing in python (#30273) * WIP try modeld all in python * fix plan * add lane lines stds * fix lane lines prob * add lead prob * add meta * simplify plan parsing * add hard brake pred * add confidence * fix desire state and desire pred * check this file for now * rm prints * rm debug * add todos * add plan_t_idxs * same as cpp * removed cython * add wfd width - rm cpp code * add new files rm old files * get metadata at compile time * forgot this file * now uses more CPU * not used * update readme * lint * copy this too * simplify disengage probs * update model replay ref commit * update again * confidence: remove if statemens * use publish_state.enqueue * Revert "use publish_state.enqueue" This reverts commit d8807c8348338a1f773a8de00fd796abb8181404. * confidence: better shape defs * use ModelConstants class * fix confidence * Parser * slightly more power too * no inline ifs :( * confidence: just use if statements 2 years ago			`import capnp`
			`import numpy as np`
			`from typing import Dict`
			`from cereal import log`
			`from openpilot.selfdrive.modeld.constants import ModelConstants, Plan, Meta`

			`ConfidenceClass = log.ModelDataV2.ConfidenceClass`

			`class PublishState:`
			`def __init__(self):`
			`self.disengage_buffer = np.zeros(ModelConstants.CONFIDENCE_BUFFER_LEN*ModelConstants.DISENGAGE_WIDTH, dtype=np.float32)`
			`self.prev_brake_5ms2_probs = np.zeros(ModelConstants.DISENGAGE_WIDTH, dtype=np.float32)`
			`self.prev_brake_3ms2_probs = np.zeros(ModelConstants.DISENGAGE_WIDTH, dtype=np.float32)`

			`def fill_xyzt(builder, t, x, y, z, x_std=None, y_std=None, z_std=None):`
			`builder.t = t`
			`builder.x = x.tolist()`
			`builder.y = y.tolist()`
			`builder.z = z.tolist()`
			`if x_std is not None:`
			`builder.xStd = x_std.tolist()`
			`if y_std is not None:`
			`builder.yStd = y_std.tolist()`
			`if z_std is not None:`
			`builder.zStd = z_std.tolist()`

			`def fill_xyvat(builder, t, x, y, v, a, x_std=None, y_std=None, v_std=None, a_std=None):`
			`builder.t = t`
			`builder.x = x.tolist()`
			`builder.y = y.tolist()`
			`builder.v = v.tolist()`
			`builder.a = a.tolist()`
			`if x_std is not None:`
			`builder.xStd = x_std.tolist()`
			`if y_std is not None:`
			`builder.yStd = y_std.tolist()`
			`if v_std is not None:`
			`builder.vStd = v_std.tolist()`
			`if a_std is not None:`
			`builder.aStd = a_std.tolist()`

			`def fill_model_msg(msg: capnp._DynamicStructBuilder, net_output_data: Dict[str, np.ndarray], publish_state: PublishState,`
			`vipc_frame_id: int, vipc_frame_id_extra: int, frame_id: int, frame_drop: float,`
			`timestamp_eof: int, timestamp_llk: int, model_execution_time: float,`
			`nav_enabled: bool, valid: bool) -> None:`
			`frame_age = frame_id - vipc_frame_id if frame_id > vipc_frame_id else 0`
			`msg.valid = valid`

			`modelV2 = msg.modelV2`
			`modelV2.frameId = vipc_frame_id`
			`modelV2.frameIdExtra = vipc_frame_id_extra`
			`modelV2.frameAge = frame_age`
			`modelV2.frameDropPerc = frame_drop * 100`
			`modelV2.timestampEof = timestamp_eof`
			`modelV2.locationMonoTime = timestamp_llk`
			`modelV2.modelExecutionTime = model_execution_time`
			`modelV2.navEnabled = nav_enabled`

			`# plan`
			`position = modelV2.position`
			`fill_xyzt(position, ModelConstants.T_IDXS, net_output_data['plan'][0,:,Plan.POSITION].T, net_output_data['plan_stds'][0,:,Plan.POSITION].T)`
			`velocity = modelV2.velocity`
			`fill_xyzt(velocity, ModelConstants.T_IDXS, *net_output_data['plan'][0,:,Plan.VELOCITY].T)`
			`acceleration = modelV2.acceleration`
			`fill_xyzt(acceleration, ModelConstants.T_IDXS, *net_output_data['plan'][0,:,Plan.ACCELERATION].T)`
			`orientation = modelV2.orientation`
			`fill_xyzt(orientation, ModelConstants.T_IDXS, *net_output_data['plan'][0,:,Plan.T_FROM_CURRENT_EULER].T)`
			`orientation_rate = modelV2.orientationRate`
			`fill_xyzt(orientation_rate, ModelConstants.T_IDXS, *net_output_data['plan'][0,:,Plan.ORIENTATION_RATE].T)`

			`# times at X_IDXS according to model plan`
			`PLAN_T_IDXS = [np.nan] * ModelConstants.IDX_N`
			`PLAN_T_IDXS[0] = 0.0`
			`plan_x = net_output_data['plan'][0,:,Plan.POSITION][:,0].tolist()`
			`for xidx in range(1, ModelConstants.IDX_N):`
			`tidx = 0`
			`# increment tidx until we find an element that's further away than the current xidx`
			`while tidx < ModelConstants.IDX_N - 1 and plan_x[tidx+1] < ModelConstants.X_IDXS[xidx]:`
			`tidx += 1`
			`if tidx == ModelConstants.IDX_N - 1:`
			`# if the Plan doesn't extend far enough, set plan_t to the max value (10s), then break`
			`PLAN_T_IDXS[xidx] = ModelConstants.T_IDXS[ModelConstants.IDX_N - 1]`
			`break`
			# interpolate to find `t` for the current xidx
			`current_x_val = plan_x[tidx]`
			`next_x_val = plan_x[tidx+1]`
			`p = (ModelConstants.X_IDXS[xidx] - current_x_val) / (next_x_val - current_x_val)`
			`PLAN_T_IDXS[xidx] = p * ModelConstants.T_IDXS[tidx+1] + (1 - p) * ModelConstants.T_IDXS[tidx]`

			`# lane lines`
			`modelV2.init('laneLines', 4)`
			`for i in range(4):`
			`lane_line = modelV2.laneLines[i]`
			`fill_xyzt(lane_line, PLAN_T_IDXS, np.array(ModelConstants.X_IDXS), net_output_data['lane_lines'][0,i,:,0], net_output_data['lane_lines'][0,i,:,1])`
			`modelV2.laneLineStds = net_output_data['lane_lines_stds'][0,:,0,0].tolist()`
			`modelV2.laneLineProbs = net_output_data['lane_lines_prob'][0,1::2].tolist()`

			`# road edges`
			`modelV2.init('roadEdges', 2)`
			`for i in range(2):`
			`road_edge = modelV2.roadEdges[i]`
			`fill_xyzt(road_edge, PLAN_T_IDXS, np.array(ModelConstants.X_IDXS), net_output_data['road_edges'][0,i,:,0], net_output_data['road_edges'][0,i,:,1])`
			`modelV2.roadEdgeStds = net_output_data['road_edges_stds'][0,:,0,0].tolist()`

			`# leads`
			`modelV2.init('leadsV3', 3)`
			`for i in range(3):`
			`lead = modelV2.leadsV3[i]`
			`fill_xyvat(lead, ModelConstants.LEAD_T_IDXS, net_output_data['lead'][0,i].T, net_output_data['lead_stds'][0,i].T)`
			`lead.prob = net_output_data['lead_prob'][0,i].tolist()`
			`lead.probTime = ModelConstants.LEAD_T_OFFSETS[i]`

			`# meta`
			`meta = modelV2.meta`
			`meta.desireState = net_output_data['desire_state'][0].reshape(-1).tolist()`
			`meta.desirePrediction = net_output_data['desire_pred'][0].reshape(-1).tolist()`
			`meta.engagedProb = net_output_data['meta'][0,Meta.ENGAGED].item()`
			`meta.init('disengagePredictions')`
			`disengage_predictions = meta.disengagePredictions`
			`disengage_predictions.t = ModelConstants.META_T_IDXS`
			`disengage_predictions.brakeDisengageProbs = net_output_data['meta'][0,Meta.BRAKE_DISENGAGE].tolist()`
			`disengage_predictions.gasDisengageProbs = net_output_data['meta'][0,Meta.GAS_DISENGAGE].tolist()`
			`disengage_predictions.steerOverrideProbs = net_output_data['meta'][0,Meta.STEER_OVERRIDE].tolist()`
			`disengage_predictions.brake3MetersPerSecondSquaredProbs = net_output_data['meta'][0,Meta.HARD_BRAKE_3].tolist()`
			`disengage_predictions.brake4MetersPerSecondSquaredProbs = net_output_data['meta'][0,Meta.HARD_BRAKE_4].tolist()`
			`disengage_predictions.brake5MetersPerSecondSquaredProbs = net_output_data['meta'][0,Meta.HARD_BRAKE_5].tolist()`

			`publish_state.prev_brake_5ms2_probs[:-1] = publish_state.prev_brake_5ms2_probs[1:]`
			`publish_state.prev_brake_5ms2_probs[-1] = net_output_data['meta'][0,Meta.HARD_BRAKE_5][0]`
			`publish_state.prev_brake_3ms2_probs[:-1] = publish_state.prev_brake_3ms2_probs[1:]`
			`publish_state.prev_brake_3ms2_probs[-1] = net_output_data['meta'][0,Meta.HARD_BRAKE_3][0]`
			`hard_brake_predicted = (publish_state.prev_brake_5ms2_probs > ModelConstants.FCW_THRESHOLDS_5MS2).all() and \`
			`(publish_state.prev_brake_3ms2_probs > ModelConstants.FCW_THRESHOLDS_3MS2).all()`
			`meta.hardBrakePredicted = hard_brake_predicted.item()`

			`# temporal pose`
			`temporal_pose = modelV2.temporalPose`
			`temporal_pose.trans = net_output_data['sim_pose'][0,:3].tolist()`
			`temporal_pose.transStd = net_output_data['sim_pose_stds'][0,:3].tolist()`
			`temporal_pose.rot = net_output_data['sim_pose'][0,3:].tolist()`
			`temporal_pose.rotStd = net_output_data['sim_pose_stds'][0,3:].tolist()`

			`# confidence`
			`if vipc_frame_id % (2*ModelConstants.MODEL_FREQ) == 0:`
			`# any disengage prob`
			`brake_disengage_probs = net_output_data['meta'][0,Meta.BRAKE_DISENGAGE]`
			`gas_disengage_probs = net_output_data['meta'][0,Meta.GAS_DISENGAGE]`
			`steer_override_probs = net_output_data['meta'][0,Meta.STEER_OVERRIDE]`
			`any_disengage_probs = 1-((1-brake_disengage_probs)(1-gas_disengage_probs)(1-steer_override_probs))`
			`# independent disengage prob for each 2s slice`
			`ind_disengage_probs = np.r_[any_disengage_probs[0], np.diff(any_disengage_probs) / (1 - any_disengage_probs[:-1])]`
			`# rolling buf for 2, 4, 6, 8, 10s`
			`publish_state.disengage_buffer[:-ModelConstants.DISENGAGE_WIDTH] = publish_state.disengage_buffer[ModelConstants.DISENGAGE_WIDTH:]`
			`publish_state.disengage_buffer[-ModelConstants.DISENGAGE_WIDTH:] = ind_disengage_probs`

			`score = 0.`
			`for i in range(ModelConstants.DISENGAGE_WIDTH):`
			`score += publish_state.disengage_buffer[i*ModelConstants.DISENGAGE_WIDTH+ModelConstants.DISENGAGE_WIDTH-1-i].item() / ModelConstants.DISENGAGE_WIDTH`
			`if score < ModelConstants.RYG_GREEN:`
			`modelV2.confidence = ConfidenceClass.green`
			`elif score < ModelConstants.RYG_YELLOW:`
			`modelV2.confidence = ConfidenceClass.yellow`
			`else:`
			`modelV2.confidence = ConfidenceClass.red`

			`def fill_pose_msg(msg: capnp._DynamicStructBuilder, net_output_data: Dict[str, np.ndarray],`
			`vipc_frame_id: int, vipc_dropped_frames: int, timestamp_eof: int, live_calib_seen: bool) -> None:`
			`msg.valid = live_calib_seen & (vipc_dropped_frames < 1)`
			`cameraOdometry = msg.cameraOdometry`

			`cameraOdometry.frameId = vipc_frame_id`
			`cameraOdometry.timestampEof = timestamp_eof`

			`cameraOdometry.trans = net_output_data['pose'][0,:3].tolist()`
			`cameraOdometry.rot = net_output_data['pose'][0,3:].tolist()`
			`cameraOdometry.wideFromDeviceEuler = net_output_data['wide_from_device_euler'][0,:].tolist()`
			`cameraOdometry.roadTransformTrans = net_output_data['road_transform'][0,:3].tolist()`
			`cameraOdometry.transStd = net_output_data['pose_stds'][0,:3].tolist()`
			`cameraOdometry.rotStd = net_output_data['pose_stds'][0,3:].tolist()`
			`cameraOdometry.wideFromDeviceEulerStd = net_output_data['wide_from_device_euler_stds'][0,:].tolist()`
			`cameraOdometry.roadTransformTransStd = net_output_data['road_transform_stds'][0,:3].tolist()`