You can use the flatten to string node to send the image data to your python script but you should note the following things:
The image data will be converted from a U32 2D-array to unsigned bytes (values 0-255). Some of these values are outside the standard ASCII character set, so they will not render correctly (they look like weird symbols or blank spaces). This also means that it is difficult to pass them as arguments but we can write them to stdin.
The flatten to string node (by default) appends the array size as I32s to the beginning of the data (which is useful) and uses the big-endian format (which is not).
The up-shot of this is that we need to override the default behaviour of the flatten to string node to use the little-endian format and strip off the first 8-bytes to convert to the array width and height in python.
LabVIEW stores image pixels in ARGB order but as we have flattened using the little-endian option, we end up with data in BGRA order which is conviently the expected channel order for openCV.
Putting this together and making sure we pass the image data into the standard input
input of the system exec.vi we have the following LabVIEW and python code (Python Version 3.10.4):
import sys
import numpy as np
import cv2
# read std in as byteArray
dataInBuffer = sys.stdin.buffer.read()
# first 8 bytes are two, 4-byte signed integer values image width and height
width = int.from_bytes( dataInBuffer[0:3], "little", signed=True )
height = int.from_bytes( dataInBuffer[4:7], "little", signed=True)
# the rest of the data is 4-channel pixel data in BGRA format
imageBuffer = np.frombuffer(dataInBuffer[8:], dtype=np.uint8)
image = imageBuffer.reshape(width,height,4)
cv2.imshow('sample image',image)
cv2.waitKey(0) # waits until a key is pressed
cv2.destroyAllWindows() # destroys the window showing image
In response to the comment from @Asky
Sending images back to LabVIEW is indeed possible using the sys.stdout.buffer.write
function.
Assuming that we want to use the Unflatten from string node in LabVIEW and we still have 4-channel BGRA data then the code is quite straight forward. We write the output image width and height as 4-byte signed integers first and then the image data. If you no longer have 4-channel data you could pad the data in python with zeros or do the padding in LabVIEW
The python code for these two cases is
import sys
import numpy as np
import cv2
# read std in as byteArray
dataInBuffer = sys.stdin.buffer.read()
# first 8 bytes are two, 4-byte signed integer values image width and height
width = int.from_bytes( dataInBuffer[0:3], "little", signed=True )
height = int.from_bytes( dataInBuffer[4:7], "little", signed=True)
# the rest of the data is 4-channel pixel data in BGRA format
imageBuffer = np.frombuffer(dataInBuffer[8:], dtype=np.uint8)
image = imageBuffer.reshape(width,height,4)
# process image
image = cv2.putText(image, 'Greetings from Python', (20,20), cv2.FONT_HERSHEY_SIMPLEX,
0.5, (255,0,0), 1, cv2.LINE_AA)
outputWidthBytes = width.to_bytes(4,'little',signed=True)
outputHeightBytes = height.to_bytes(4,'little',signed=True)
# write to standard out
sys.stdout.buffer.write(outputWidthBytes)
sys.stdout.buffer.write(outputHeightBytes)
sys.stdout.buffer.write(image)
# write out three channel example
bgrImage = cv2.cvtColor(image, cv2.COLOR_BGRA2BGR)
# write to standard out as 3D array (width x height x channels)
sys.stdout.buffer.write(outputWidthBytes)
sys.stdout.buffer.write(outputHeightBytes)
sys.stdout.buffer.write((3).to_bytes(4,'little',signed=True))
sys.stdout.buffer.write(bgrImage)
# use flush to ensure all bytes are written to stdout before the program exits
sys.stdout.buffer.flush()
And the LabVIEW code extended to process the stdout
data becomes