On an element-wise basis, calculates the number of one-bits in the 64-bit two's complement binary representation of the input.
| Usage | Returns | Array.bitCount() | Array |
| Argument | Type | Details | this: input | Array | The input array. |
Examples
Code Editor (JavaScript)
print(ee.Array([], ee.PixelType.int8()).bitCount()); // []
print(ee.Array([0]).bitCount()); // [0]
print(ee.Array([1]).bitCount()); // [1]
print(ee.Array([2]).bitCount()); // [1]
print(ee.Array([3]).bitCount()); // [2]
print(ee.Array([0xFFFF]).bitCount()); // [16]
print(ee.Array([1, 2, 3]).bitCount()); // [1,1,2]
print(ee.Array([[0, 1], [6, 13]]).bitCount()); // [[0,1],[2,3]]
// https://en.wikipedia.org/wiki/Two's_complement signed values.
print(ee.Array([-1]).bitCount()); // [64]
print(ee.Array([-1], ee.PixelType.int8()).bitCount()); // [64]
print(ee.Array([-2]).bitCount()); // [63]
Python setup
See the
Python Environment page for information on the Python API and using
geemap for interactive development.
import ee
import geemap.core as geemap
Colab (Python)
display(ee.Array([], ee.PixelType.int8()).bitCount()) # []
display(ee.Array([0]).bitCount()) # [0]
display(ee.Array([1]).bitCount()) # [1]
display(ee.Array([2]).bitCount()) # [1]
display(ee.Array([3]).bitCount()) # [2]
display(ee.Array([0xFFFF]).bitCount()) # [16]
display(ee.Array([1, 2, 3]).bitCount()) # [1, 1, 2]
display(ee.Array([[0, 1], [6, 13]]).bitCount()) # [[0, 1], [2, 3]]
# https://en.wikipedia.org/wiki/Two's_complement signed values.
display(ee.Array([-1]).bitCount()) # [64]
display(ee.Array([-1], ee.PixelType.int8()).bitCount()) # [64]
display(ee.Array([-2]).bitCount()) # [63]