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I am working on Arm cortex M3 controller which has the Thumb-2 instruction set.

Thumb mode is used to compress the instruction to 16 bit size. So size of code is reduced. But with normal Thumb mode why it is said that performance is reduced?

In case of Thumb-2, it is said performance is improved as per these two links:

Improve performance in cases where a single 16-bit instruction restricts functions available to the compiler.

A stated aim for Thumb-2 was to achieve code density similar to Thumb with performance similar to the ARM instruction set on 32-bit memory.

What exactly is this performance. Can someone give few example related to it?

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Performance is always relative. There are many cases where thumb code runs better than arm. Mainly if the memory bus is a bottle neck. Generally the thumb doesn't have as many registers, so even though the instruction set is more compact, with some algorithms, it will have to access memory more often to spill registers. –  artless noise Apr 6 '13 at 4:01
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If I have a delivery truck A and a delivery truck B that is half the size of A. If the amount of stuff being delivered fits in truck A but is two big for truck B it will take truck B twice as many trips to do the same job. Thumb is not half as efficient as ARM, it is more like 10-15% more instructions to do the same thing as ARM. –  dwelch Apr 6 '13 at 4:08
    
See also: Stackoverflow's Gcc -mthumb vs -marm, and Arizona paper on Thumb and ARM guided compiles. –  artless noise Apr 6 '13 at 4:11

2 Answers 2

Thumb-2 introduced variable length instructions to the original Thumb; now instructions can be a mixture of 16-bit and 32-bit. That means you retain the size advantage of the original Thumb in everyday code, but now have access to almost the full ARM feature-set in more complex code, but without the ARM-interworking overhead previously incurred by Thumb.

Aside from the aforementioned access to the full register set from all register operations, Thumb-2 added back branchless conditional execution in the form of the IF-THEN (IT) block. The original Thumb removed the trademark ARM feature of conditional execution on nearly all instructions; this is now achieved in Thumb-2 by prepending the IT instruction with conditions for up to four succeeding instructions.

In addition, the instruction set itself has been vastly expanded; for example, the Cortex-M4F implements the DSP extension as well as the FPv4-SP floating point extension. In fact, I believe even NEON can be encoded in Thumb2.

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When compared against the ARM 32 bit instruction set, the thumb 16 bit instruction set (not talking about thumb2 extensions yet) takes less space because the instructions are half the size, but there is a performance drop, in general, because it takes more instructions to do the same thing as on arm. There are less features to the instruction set, and most instructions only operate on registers r0-r7. Apples to Apples comparison more instructions to do the same thing is slower.

Now thumb2 extensions take formerly undefined thumb instructions and create 32 bit thumb instructions. Understand that there is more than one set of thumb2 extensions. ARMv6m adds a couple dozen perhaps. ARMv7m adds something like 150 instructions to the thumb instruction set, I dont know what ARMv8 or the future hold. So assuming ARMv7m, they have bridged the gap between what you can do in thumb and what you can do in ARM. So thumb2 is a reduced ARM instruction set as thumb is, but not as reduced. So it might still take more instructions to do the same thing in thumb2 (assume plus thumb) compared to ARM doing the same thing.

This gives a taste of the issue, a single instruction in arm and its equivalent in thumb.

ARM

and r8,r9,r10

THUMB

push {r0,r1}
mov r0,r8
mov r1,r9
and r0,r1
mov r1,r10
and r0,r1
mov r8,r0
pop {r0,r1}

Now a compiler wouldnt do that, the compiler would know it is targeting thumb and do things differently by choosing other registers. You still have fewer registers and fewer features per instruction:

mov r0,r1
and r0,r2

Still takes two instructions/execution cycles to and two registers together, without modifying the operands, and put the result in a third register. Thumb2 has a three register and so you are back to a single instruction using the thumb2 extensions. And that thumb2 instruction allows for r0-r15 on any of those three registers where thumb is limited to r0-r7.

Look at the ARMv5 Architectural Reference Manual, under each thumb instruction it shows you the equivalent ARM instruction. Then go to that ARM instruction and compare what you can do with that arm instruction that you cant do with the thumb instruction. It is a one way path the thumb instructions (not thumb2) have a one to one relationship with an ARM instruction. all thumb instructions have an equivalent arm instruction. but not all arm instructions have an equivalent thumb instruction. You should be able to see from this exercise the limitation on the compilers when using the thumb instruction set. Then get the ARMv7m Architectural Reference Manual and look at the instruction set, and compare the "all thumb variants" encodings (the ones that include ARMv4T) and the ones that are limited to ARMv6 and/or v7 and see the expansion of features between thumb and thumb2 as well as the thumb2 only instructions that have no thumb counterpart. This should clarify what the compilers have to work with between thumb and thumb2. You can then go so far as to compare thumb+thumb2 with the full blown ARM instructions (ARMv7 AR is that what it is called?). And see that thumb2 gets a lot closer to ARM, but you lose for example conditionals on every instruction, so conditional execution in thumb becomes comparisons with branching over code, where in ARM you can sometimes have an if-then-else without branching...

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also be very careful, cortex-m3 and cortex-m4 are ARMv7m, the cortex-m0 and -m1 are ARMv6m, a lot of difference between the thumb2 extensions on those instruction sets,also the compilers lept forward with the cortex-m3 and added a bunch of thumb2 stuff, and you couldnt use thumb2 on the cortex-m0 when it came out. Not sure if the compilers (gcc/clang) have caught up yet completely. Likewise the cortex-m4 has (can have) floating point which is a reduced flavor of the Cortex-A,and the compilers were struggling with floating point on the cortex-m4 when it came out. not sure if they have caught up –  dwelch Apr 6 '13 at 4:05
    
if thumb can access only register R0-R7 ... then how in your example you are using mov instruction on register r8, r9 & r10 ... please suggest ? –  Katoch Apr 6 '13 at 7:21
    
MOST thumb instructions a few can in particular a specific move high to/from low –  dwelch Apr 6 '13 at 11:22
    
Just read the manual the answers are there... –  dwelch Apr 6 '13 at 11:22
    
I wish the assembler had defined a suffix which meant "use the form that affects flags if more convenient than the one that doesn't" and a suffix which meant "don't use the form that affects flags; refuse assembly if the only available form does affect flags", since in Thumb some instructions must affect flags, others can't, and some grant a choice; worse, some instructions behave differently depending upon the registers used. –  supercat Jan 21 at 17:42

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