type graphics CHUNKS
data courtesy of Wikipedia
The Resource Interchange File Format (RIFF) is a generic file container format for storing data in tagged chunks.
It was introduced in 1991 by Microsoft and IBM, and was presented by Microsoft as the default format for Windows 3.1 multimedia files. It is based on Electronic Arts’s Interchange File Format, introduced in 1985 on the Amiga 1000, the only difference being that multi-byte integers are in little-endian format, native to the 80×86 processor series used in IBM PCs, rather than the big-endian format native to the 68k processor series used in Amiga and Apple Macintosh computers, where IFF files were heavily used.
(The specification for AIFF, the big-endian analogue of RIFF, was published by Apple Computer in 1988.)
The Microsoft implementation is mostly known through container formats like AVI, ANI and WAV, which use RIFF as their basis.
In 2010 Google introduced the WebP picture format, which uses RIFF as a container.
so where did this go wrong due to the obvious truth that there is a great difficulty in developing atom quantal computers with anything beyond what would be CHUNK computations such as
2 Chunks + 3 Chunks = 5 Chunks
well you could use the packed pixel Chunky frame in relations to pixelations of galaxy Andromeda force which has already made its CHUNK basis a type of observable BUFFER state of relativity with its format engagement or involvement with the following
basically 16 BIT CHUNKS computatability quant=per pixel of the ANDROMEDA FORCE
8 CHUNK bit bytes = quant frame Buffer and romeda galaxy force arrangements Andromeda
as the basis of the common value being 4 bit chunk responses per pixel in the andromeda image
the value multiple of 4 x 4 = 16 pixel amounts as the projective usage of the Andromeda galaxy image as a computer for the multiples of 16 colours and the data on such BIT CHUNK values as 2 BIT values where 8/4 = 2 as the common multiple divisive used in the basics of the full uncertainty of the value projective towards the andromeda by image mapping technology as the basis of the data being in general = x/y as a x multiple state stillness and the usage of the zone surround on the image..
In packed pixel or chunky frame buffer organization, the bits defining each pixel are grouped together. For example, if there are 16 bits per pixel, each pixel is represented in two consecutive (contiguous) 8-bit bytes in the frame buffer (a.k.a. screen buffer). If there are 4 bits per pixel (16 colors), each frame buffer byte defines two pixels, one in each nibble. The latter example is as opposed to storing perhaps half of the bits—2 bits—for each of four pixels in one byte and the other two bits for each of those four pixels in another byte or bytes. It is also as opposed to interleaving the bits of the two pixels within the byte. As this illustrates, packed pixel organization can be directly contrasted with planar organization.
how can this be developed on a already existant basis of the R.I.F.F basis and the andromeda galaxy
remembering that the Andromeda is a force and has similarities when the types of data chunks are spacially isolated and can have applications for the types of computations made as a reference in which the total value of their compisite parts = the general basis of data that does a extra boost into non restricted options for the booster applications to the R:I:F:F programming.
as a basic chunk value in the basis of globular clusters and the basis for a data delay to work out the types of data chunks that are spacial in type and which are the basis for the types of multiple point enter and exit of data so that the compression of the space will =the exchange or interexchanges of the types of referenced data that has basic flow values
the general optional extra developments of the Andromeda running its own print art programme by the types of programme formats for CHUNKS of data which are known as the pdf files and all their types in interactions with the R.I.F.F types of data which would CHUNK the Andromeda galaxy and actually help in defining the parameters of the observational data on the types of parameters that are there and to make printouts of a type telescopic printer of images related to this function..