Files
StarPilot/selfdrive/modeld/compile_warp.py
T
Adeeb Shihadeh 667f3bb32f Revert "revert tg calib and opencl cleanup (#37113)" (#37115)
* Revert "revert tg calib and opencl cleanup (#37113)"

This reverts commit 51312afd3d.

* power draw is a lil higher

* just don't miss a cycle

* fix warp targets

* fix tinygrad dep
2026-02-07 21:36:44 -08:00

207 lines
8.0 KiB
Python
Executable File

#!/usr/bin/env python3
import time
import pickle
import numpy as np
from pathlib import Path
from tinygrad.tensor import Tensor
from tinygrad.helpers import Context
from tinygrad.device import Device
from tinygrad.engine.jit import TinyJit
from openpilot.system.camerad.cameras.nv12_info import get_nv12_info
from openpilot.common.transformations.model import MEDMODEL_INPUT_SIZE, DM_INPUT_SIZE
from openpilot.common.transformations.camera import _ar_ox_fisheye, _os_fisheye
MODELS_DIR = Path(__file__).parent / 'models'
CAMERA_CONFIGS = [
(_ar_ox_fisheye.width, _ar_ox_fisheye.height), # tici: 1928x1208
(_os_fisheye.width, _os_fisheye.height), # mici: 1344x760
]
UV_SCALE_MATRIX = np.array([[0.5, 0, 0], [0, 0.5, 0], [0, 0, 1]], dtype=np.float32)
UV_SCALE_MATRIX_INV = np.linalg.inv(UV_SCALE_MATRIX)
IMG_BUFFER_SHAPE = (30, MEDMODEL_INPUT_SIZE[1] // 2, MEDMODEL_INPUT_SIZE[0] // 2)
def warp_pkl_path(w, h):
return MODELS_DIR / f'warp_{w}x{h}_tinygrad.pkl'
def dm_warp_pkl_path(w, h):
return MODELS_DIR / f'dm_warp_{w}x{h}_tinygrad.pkl'
def warp_perspective_tinygrad(src_flat, M_inv, dst_shape, src_shape, stride_pad, ratio):
w_dst, h_dst = dst_shape
h_src, w_src = src_shape
x = Tensor.arange(w_dst).reshape(1, w_dst).expand(h_dst, w_dst)
y = Tensor.arange(h_dst).reshape(h_dst, 1).expand(h_dst, w_dst)
ones = Tensor.ones_like(x)
dst_coords = x.reshape(1, -1).cat(y.reshape(1, -1)).cat(ones.reshape(1, -1))
src_coords = M_inv @ dst_coords
src_coords = src_coords / src_coords[2:3, :]
x_nn_clipped = Tensor.round(src_coords[0]).clip(0, w_src - 1).cast('int')
y_nn_clipped = Tensor.round(src_coords[1]).clip(0, h_src - 1).cast('int')
idx = y_nn_clipped * w_src + (y_nn_clipped * ratio).cast('int') * stride_pad + x_nn_clipped
sampled = src_flat[idx]
return sampled
def frames_to_tensor(frames, model_w, model_h):
H = (frames.shape[0] * 2) // 3
W = frames.shape[1]
in_img1 = Tensor.cat(frames[0:H:2, 0::2],
frames[1:H:2, 0::2],
frames[0:H:2, 1::2],
frames[1:H:2, 1::2],
frames[H:H+H//4].reshape((H//2, W//2)),
frames[H+H//4:H+H//2].reshape((H//2, W//2)), dim=0).reshape((6, H//2, W//2))
return in_img1
def make_frame_prepare(cam_w, cam_h, model_w, model_h):
stride, y_height, _, _ = get_nv12_info(cam_w, cam_h)
uv_offset = stride * y_height
stride_pad = stride - cam_w
def frame_prepare_tinygrad(input_frame, M_inv):
tg_scale = Tensor(UV_SCALE_MATRIX)
M_inv_uv = tg_scale @ M_inv @ Tensor(UV_SCALE_MATRIX_INV)
with Context(SPLIT_REDUCEOP=0):
y = warp_perspective_tinygrad(input_frame[:cam_h*stride],
M_inv, (model_w, model_h),
(cam_h, cam_w), stride_pad, 1).realize()
u = warp_perspective_tinygrad(input_frame[uv_offset:uv_offset + (cam_h//4)*stride],
M_inv_uv, (model_w//2, model_h//2),
(cam_h//2, cam_w//2), stride_pad, 0.5).realize()
v = warp_perspective_tinygrad(input_frame[uv_offset + (cam_h//4)*stride:uv_offset + (cam_h//2)*stride],
M_inv_uv, (model_w//2, model_h//2),
(cam_h//2, cam_w//2), stride_pad, 0.5).realize()
yuv = y.cat(u).cat(v).reshape((model_h * 3 // 2, model_w))
tensor = frames_to_tensor(yuv, model_w, model_h)
return tensor
return frame_prepare_tinygrad
def make_update_img_input(frame_prepare, model_w, model_h):
def update_img_input_tinygrad(tensor, frame, M_inv):
M_inv = M_inv.to(Device.DEFAULT)
new_img = frame_prepare(frame, M_inv)
full_buffer = tensor[6:].cat(new_img, dim=0).contiguous()
return full_buffer, Tensor.cat(full_buffer[:6], full_buffer[-6:], dim=0).contiguous().reshape(1, 12, model_h//2, model_w//2)
return update_img_input_tinygrad
def make_update_both_imgs(frame_prepare, model_w, model_h):
update_img = make_update_img_input(frame_prepare, model_w, model_h)
def update_both_imgs_tinygrad(calib_img_buffer, new_img, M_inv,
calib_big_img_buffer, new_big_img, M_inv_big):
calib_img_buffer, calib_img_pair = update_img(calib_img_buffer, new_img, M_inv)
calib_big_img_buffer, calib_big_img_pair = update_img(calib_big_img_buffer, new_big_img, M_inv_big)
return calib_img_buffer, calib_img_pair, calib_big_img_buffer, calib_big_img_pair
return update_both_imgs_tinygrad
def make_warp_dm(cam_w, cam_h, dm_w, dm_h):
stride, y_height, _, _ = get_nv12_info(cam_w, cam_h)
stride_pad = stride - cam_w
def warp_dm(input_frame, M_inv):
M_inv = M_inv.to(Device.DEFAULT)
with Context(SPLIT_REDUCEOP=0):
result = warp_perspective_tinygrad(input_frame[:cam_h*stride], M_inv, (dm_w, dm_h), (cam_h, cam_w), stride_pad, 1).reshape(-1, dm_h * dm_w)
return result
return warp_dm
def compile_modeld_warp(cam_w, cam_h):
model_w, model_h = MEDMODEL_INPUT_SIZE
_, _, _, yuv_size = get_nv12_info(cam_w, cam_h)
print(f"Compiling modeld warp for {cam_w}x{cam_h}...")
frame_prepare = make_frame_prepare(cam_w, cam_h, model_w, model_h)
update_both_imgs = make_update_both_imgs(frame_prepare, model_w, model_h)
update_img_jit = TinyJit(update_both_imgs, prune=True)
full_buffer = Tensor.zeros(IMG_BUFFER_SHAPE, dtype='uint8').contiguous().realize()
big_full_buffer = Tensor.zeros(IMG_BUFFER_SHAPE, dtype='uint8').contiguous().realize()
full_buffer_np = np.zeros(IMG_BUFFER_SHAPE, dtype=np.uint8)
big_full_buffer_np = np.zeros(IMG_BUFFER_SHAPE, dtype=np.uint8)
for i in range(10):
new_frame_np = (32 * np.random.randn(yuv_size).astype(np.float32) + 128).clip(0, 255).astype(np.uint8)
img_inputs = [full_buffer,
Tensor.from_blob(new_frame_np.ctypes.data, (yuv_size,), dtype='uint8').realize(),
Tensor(Tensor.randn(3, 3).mul(8).realize().numpy(), device='NPY')]
new_big_frame_np = (32 * np.random.randn(yuv_size).astype(np.float32) + 128).clip(0, 255).astype(np.uint8)
big_img_inputs = [big_full_buffer,
Tensor.from_blob(new_big_frame_np.ctypes.data, (yuv_size,), dtype='uint8').realize(),
Tensor(Tensor.randn(3, 3).mul(8).realize().numpy(), device='NPY')]
inputs = img_inputs + big_img_inputs
Device.default.synchronize()
inputs_np = [x.numpy() for x in inputs]
inputs_np[0] = full_buffer_np
inputs_np[3] = big_full_buffer_np
st = time.perf_counter()
out = update_img_jit(*inputs)
full_buffer = out[0].contiguous().realize().clone()
big_full_buffer = out[2].contiguous().realize().clone()
mt = time.perf_counter()
Device.default.synchronize()
et = time.perf_counter()
print(f" [{i+1}/10] enqueue {(mt-st)*1e3:6.2f} ms -- total {(et-st)*1e3:6.2f} ms")
pkl_path = warp_pkl_path(cam_w, cam_h)
with open(pkl_path, "wb") as f:
pickle.dump(update_img_jit, f)
print(f" Saved to {pkl_path}")
jit = pickle.load(open(pkl_path, "rb"))
jit(*inputs)
def compile_dm_warp(cam_w, cam_h):
dm_w, dm_h = DM_INPUT_SIZE
_, _, _, yuv_size = get_nv12_info(cam_w, cam_h)
print(f"Compiling DM warp for {cam_w}x{cam_h}...")
warp_dm = make_warp_dm(cam_w, cam_h, dm_w, dm_h)
warp_dm_jit = TinyJit(warp_dm, prune=True)
for i in range(10):
inputs = [Tensor.from_blob((32 * Tensor.randn(yuv_size,) + 128).cast(dtype='uint8').realize().numpy().ctypes.data, (yuv_size,), dtype='uint8'),
Tensor(Tensor.randn(3, 3).mul(8).realize().numpy(), device='NPY')]
Device.default.synchronize()
st = time.perf_counter()
warp_dm_jit(*inputs)
mt = time.perf_counter()
Device.default.synchronize()
et = time.perf_counter()
print(f" [{i+1}/10] enqueue {(mt-st)*1e3:6.2f} ms -- total {(et-st)*1e3:6.2f} ms")
pkl_path = dm_warp_pkl_path(cam_w, cam_h)
with open(pkl_path, "wb") as f:
pickle.dump(warp_dm_jit, f)
print(f" Saved to {pkl_path}")
def run_and_save_pickle():
for cam_w, cam_h in CAMERA_CONFIGS:
compile_modeld_warp(cam_w, cam_h)
compile_dm_warp(cam_w, cam_h)
if __name__ == "__main__":
run_and_save_pickle()