Chinese Version 中文版:NEON编码 - 第4部分: 左右移位
This blog has been updated and turned into a more formal guide on Arm Developer. You can find the latest guide here:
This article introduces the shifting operations provided by Neon, and shows how they can be used to convert image data between commonly used color depths.
Previous articles in this series:
A shift on NEON is very similar to shifts you may have used in scalar Arm code. The shift moves the bits in each element of a vector left or right. Bits that fall off the left or right of each element are discarded; they are not shifted to adjacent elements.
The amount to shift can be specified with a literal encoded in the instruction, or with an additional shift vector. When using a shift vector, the shift applied to each element of the input vector depends on the value of the corresponding element in the shift vector. The elements in the shift vector are treated as signed values, so left, right and zero shifts are possible, on a per-element basis.
A right shift operating on a vector of signed elements, indicated by the type attached to the instruction, will sign extend each element. This is the equivalent of an arithmetic shift you may have used in Arm code. Shifts applied to unsigned vectors do not sign extend.
Neon also supports shifts with insertion, providing a way to combine bits from two vectors. For example, shift left and insert (VSLI) shifts each element of the source vector left. The new bits inserted at the right of each element are the corresponding bits from the destination vector.
VSLI
Finally, Neon supports shifting the elements of a vector right, and accumulating the results into another vector. This is useful for situations in which interim calculations are made at a high precision, before the result is combined with a lower precision accumulator.
Each shift instruction can take one or more modifiers. These modifiers do not change the shift operation itself, but the inputs or outputs are adjusted to remove bias or saturate to a range.There are five shift modifiers:
R
N
L
Q
U
Some combinations of these modifiers do not describe useful operations, and so the instruction is not provided by Neon. For example, a saturating shift right (which would be called VQSHR) is unnecessary, as right shifting makes results smaller, and so the value cannot exceed the available range.
VQSHR
All of the shifting instructions provided by Neon are shown in the table below. They are arranged according to the modifiers mentioned earlier. If you are still unsure about what the modifier letters mean, use the table to select the instruction you need.
Converting between color depths is a frequent operation required in graphics processing. Often, input or output data is in an RGB565 16-bit color format, but working with the data is much easier in RGB888 format. This is particularly true on Neon, as there is no native support for data types like RGB565.
However, Neon can still handle RGB565 data efficiently, and the vector shifts introduced above provide a method to do it.
First, we will look at converting RGB565 to RGB888. We assume there are eight 16-bit pixels in register q0, and we would like to separate reds, greens and blues into 8-bit elements across three registers d2 to d4. vshr.u8 q1, q0, #3 @ shift red elements right by three bits, @ discarding the green bits at the bottom of @ the red 8-bit elements. vshrn.i16 d2, q1, #5 @ shift red elements right and narrow, @ discarding the blue and green bits. vshrn.i16 d3, q0, #5 @ shift green elements right and narrow, @ discarding the blue bits and some red bits @ due to narrowing. vshl.i8 d3, d3, #2 @ shift green elements left, discarding the @ remaining red bits, and placing green bits @ in the correct place. vshl.i16 q0, q0, #3 @ shift blue elements left to most-significant @ bits of 8-bit color channel. vmovn.i16 d4, q0 @ remove remaining red and green bits by @ narrowing to 8 bits.The effects of each instruction are described in the comments above, but in summary, the operation performed on each channel is:
q0
d2
d4
vshr.u8 q1, q0, #3 @ shift red elements right by three bits, @ discarding the green bits at the bottom of @ the red 8-bit elements. vshrn.i16 d2, q1, #5 @ shift red elements right and narrow, @ discarding the blue and green bits. vshrn.i16 d3, q0, #5 @ shift green elements right and narrow, @ discarding the blue bits and some red bits @ due to narrowing. vshl.i8 d3, d3, #2 @ shift green elements left, discarding the @ remaining red bits, and placing green bits @ in the correct place. vshl.i16 q0, q0, #3 @ shift blue elements left to most-significant @ bits of 8-bit color channel. vmovn.i16 d4, q0 @ remove remaining red and green bits by @ narrowing to 8 bits.
Note the use of element sizes in this sequence to address 8 and 16 bit elements, in order to achieve some of the masking operations.
You may notice that, if you use the code above to convert to RGB888 format, your whites aren't quite white. This is because, for each channel, the lowest two or three bits are zero, rather than one; a white represented in RGB565 as (0x1F, 0x3F, 0x1F) becomes (0xF8, 0xFC, 0xF8) in RGB888. This can be fixed using shift with insert to place some of the most-significant bits into the lower bits.
Now, we can look at the reverse operation, converting RGB888 to RGB565. Here, we ssume that the RGB888 data is in the format produced by the code above; separated cross three registers d0 to d2, with each register containing eight elements of each color. The result will be stored as eight 16-bit RGB565 elements in q2.
d0
q2
vshll.u8 q2, d0, #8 @ shift red elements left to most-significant @ bits of wider 16-bit elements. vshll.u8 q3, d1, #8 @ shift green elements left to most-significant @ bits of wider 16-bit elements. vsri.16 q2, q3, #5 @ shift green elements right and insert into @ red elements. vshll.u8 q3, d2, #8 @ shift blue elements left to most-significant @ bits of wider 16-bit elements. vsri.16 q2, q3, #11 @ shift blue elements right and insert into @ red and green elements.
Again, the detail is in the comments for each instruction, but in summary, for each channel:
The powerful range of shift instructions provided by Neon allows you to:
In the next article, we will look at some of the other data processing instructions provided by Neon.
[CTAToken URL = "https://community.arm.com/processors/b/blog/posts/coding-for-neon---part-5-rearranging-vectors" target="_blank" text="Read Part 5: Rearranging Vectors" class ="green"]
That's nice but how quickly convert RGB565 to RGBA8888 without separate the color component.I.e. Having 2 32bit pixel into a Dn register.While there is no alpha into a 16 bit pixel, let suppose that alpha value is 0.Thanks