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https://github.com/KrisKennaway/ii-pix.git
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Optimize palette initialization and NTSC image conversion
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parent
f8fbd768a5
commit
4091dd259c
15
palette.py
15
palette.py
@ -41,12 +41,19 @@ class Palette:
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def __init__(self):
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self.RGB = {}
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for k, v in self.SRGB.items():
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# Do a bulk conversion because it's much faster than doing it within the
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# loop
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srgb = np.stack(list(self.SRGB.values()))
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with colour.utilities.suppress_warnings(colour_usage_warnings=True):
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cam = colour.convert(srgb / 255, "sRGB", "CAM16UCS").astype(
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np.float32)
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for i, kv in enumerate(self.SRGB.items()):
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k, v = kv
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self.RGB[k] = (np.clip(image.srgb_to_linear_array(v / 255), 0.0,
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1.0) * 255).astype(np.uint8)
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with colour.utilities.suppress_warnings(colour_usage_warnings=True):
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self.CAM16UCS[k] = colour.convert(
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v / 255, "sRGB", "CAM16UCS").astype(np.float32)
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self.CAM16UCS[k] = cam[i, :]
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@staticmethod
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def _pixel_phase_shifts(phase_3_srgb):
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48
screen.py
48
screen.py
@ -139,10 +139,10 @@ class NTSCScreen:
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x = pos % 12 + self.NTSC_PHASE_SHIFT * 3
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return np.cos(x * 2 * np.pi / 12)
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def _read(self, line, pos):
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def _read(self, lines, pos):
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if pos < 0:
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return 0
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return 1 if line[pos] else 0
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return np.zeros(lines.shape[0], dtype=np.float32)
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return lines[:, pos].astype(np.float32)
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def bitmap_to_image_ntsc(self, bitmap: np.ndarray) -> np.ndarray:
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y_width = 12
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@ -177,26 +177,30 @@ class NTSCScreen:
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out_rgb = np.empty((bitmap.shape[0], bitmap.shape[1] * 3, 3),
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dtype=np.uint8)
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for y in range(bitmap.shape[0]):
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ysum = 0
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usum = 0
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vsum = 0
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line = np.repeat(bitmap[y], 3)
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ysum = np.zeros(bitmap.shape[0], dtype=np.float32)
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usum = np.zeros(bitmap.shape[0], dtype=np.float32)
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vsum = np.zeros(bitmap.shape[0], dtype=np.float32)
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# Repeat each pixel 3 times so we can do sub-pixel colour sampling
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lines = np.repeat(bitmap, 3, axis=1)
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for x in range(bitmap.shape[1] * 3):
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ysum += self._read(lines, x) - self._read(lines, x - y_width)
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usum += self._read(lines, x) * self._sin(x) - self._read(
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lines, x - u_width) * self._sin((x - u_width))
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vsum += self._read(lines, x) * self._cos(x) - self._read(
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lines, x - v_width) * self._cos((x - v_width))
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rgb = np.matmul(
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yuv_to_rgb, np.stack(
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(ysum / y_width, usum / u_width,
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vsum / v_width), axis=1).reshape(
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(bitmap.shape[0], 3, 1))).reshape(
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bitmap.shape[0], 3)
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out_rgb[:, x, 0] = np.minimum(255, np.maximum(0, rgb[:, 0] * 255))
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out_rgb[:, x, 1] = np.minimum(255, np.maximum(0, rgb[:, 1] * 255))
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out_rgb[:, x, 2] = np.minimum(255, np.maximum(0, rgb[:, 2] * 255))
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for x in range(bitmap.shape[1] * 3):
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ysum += self._read(line, x) - self._read(line, x - y_width)
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usum += self._read(line, x) * self._sin(x) - self._read(
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line, x - u_width) * self._sin((x - u_width))
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vsum += self._read(line, x) * self._cos(x) - self._read(
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line, x - v_width) * self._cos((x - v_width))
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rgb = np.matmul(
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yuv_to_rgb, np.array(
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(ysum / y_width, usum / u_width,
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vsum / v_width)).reshape((3, 1))).reshape(3)
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r = min(255, max(0, rgb[0] * 255))
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g = min(255, max(0, rgb[1] * 255))
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b = min(255, max(0, rgb[2] * 255))
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out_rgb[y, x, :] = (r, g, b)
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return out_rgb
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