Unicore

Unicore
Designer	Microprocessor Research and Development Center
Bits	32-bit
Introduced	1999
Design	RISC
Encoding	Fixed
Branching	Condition code
Endianness	Little
Page size	4 KiB
Registers
General purpose	31
Floating point	32

Unicore is the name of a computer instruction set architecture designed by the Microprocessor Research and Development Center (MPRC) of Peking University in the PRC. The computer built on this architecture is called the Unity-863.^[1] The CPU is integrated into a fully functional SoC to make a PC-like system.^[2]

The processor is very similar to the ARM architecture, but uses a different instruction set.^[3]^{[better source needed]}

It is supported by the Linux kernel as of version 2.6.39.^[4] Support will be removed in Linux kernel version 5.9 as nobody seems to maintain it and the code is falling behind the rest of the kernel code and compiler requirements.^[5]

Instruction set

The instructions are almost identical to the standard ARM formats, except that conditional execution has been removed, and the bits reassigned to expand all the register specifiers to 5 bits.^[6]^[7] Likewise, the immediate format is 9 bits rotated by a 5-bit amount (rather than 8 bit rotated by 4), the load/store offset sizes are 14 bits for byte/word and 10 bits for signed byte or half-word. Conditional moves are provided by encoding the condition in the (unused by ARM) second source register field Rn for MOV and MVN instructions.

Unicore32 instruction set overview^[8]
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0	0	0	opcode				S	Rn	Rd	shift	0	Sh		0	Rm	ALU operation, Rd = Rn op Rm shift #shift
0	0	0	opcode				S	Rn	Rd	Rs	0	Sh		1	Rm	ALU operation, Rd = Rn op Rm shift Rs
0	0	1	opcode				S	Rn	Rd	shift	imm9					ALU operation, Rd = Rn op #imm9 ROTL #shift
0	1	0	P	U	B	W	L	Rn	Rd	shift	0	Sh		0	Rm	Load/store Rd to address Rn ± Rm shift #shift
0	1	1	P	U	B	W	L	Rn	Rd	offset14						Load/store Rd to address Rn ± offset14
1	0	0	P	U	S	W	L	Rn	Bitmap high		0	0	H	Bitmap low		Load/store multiple registers
1	0	1	cond				L	offset24								Branch (and link) if condition true
1	1	0														Coprocessor (FPU) instructions
1	1	1	1	1	1	1	1	Trap number								Software interrupt

0	0	0	0	0	0	A	S	Rn	Rd	Rs	1	0	0	1	Rm	Multiply, Rd = Rm * Rs (+ Rn)
0	0	0	1	0	0	0	L	11111	11111	00000	1	0	0	1	Rm	Branch and exchange (BX, BLX)
0	1	0	P	U	0	W	L	Rn	Rd	00000	1	S	H	1	Rm	Load/store Rd to address Rn ± Rm (16-bit)
0	1	0	P	U	1	W	L	Rn	Rd	imm_hi	1	S	H	1	imm_lo	Load/store Rd to address Rn ± #imm10 (16-bit)

The meaning of various flag bits (such as S=1 enables setting the condition codes) is identical to the ARM instruction set. The load/store multiple instruction can only access half of the register set, depending on the H bit. If H=0, the 16 bits indicate R0–R15; if H=1, R16–R31.

References

↑ "Introduction to MPRC". Microprocessor Research and Develop Center, Peking University. http://mprc.pku.cn/eng/intro.html.
↑ Xu Cheng; Xiaoyin Wang; Junlin Lu; Jiangfang Yi; Dong Tong; Xuetao Guan; Feng Liu; Xianhua Liu et al. (March 2010), "Research Progress of UniCore CPUs and PKUnity SoCs", Journal of Computer Science and Technology (JCST) 25 (2): 200–213, doi:10.1007/s11390-010-9317-1, http://mprc.pku.edu.cn/~guanxuetao/publications/2010-JCST-CX.pdf, retrieved 2012-07-11
↑ Bergmann, Arnd (2012-07-09). "Re: [PATCH 00/36] AArch64 Linux kernel port". linux-kernel (Mailing list). Retrieved 2012-07-11. Another interesting example is unicore32, which actually shares more code with arch/arm than the proposed arch/aarch64 does. I think the unicore32 code base would benefit from being merged back into arch/arm as a third instruction set, but the additional maintenance cost for everyone working on ARM makes that unrealistic.
↑ "Merge window closed - 2.6.39-rc1 out". Linus Torvalds. https://lkml.org/lkml/2011/3/29/351.
↑ "remove unicore32 support". Mike Rapoport. https://lkml.org/lkml/2020/8/3/232.
↑ Hsu-Hung Chiang; Huang-Jia Cheng; Yuan-Shin Hwan (2012-02-25), "Doubling the Number of Registers on ARM Processors", 16th Workshop on Interaction between Compilers and Computer Architectures (INTERACT), pp. 1–8, doi:10.1109/INTERACT.2012.6339620, ISBN 978-1-4673-2613-1, http://aces.snu.ac.kr/interact-16/papers/interact-16-paper-1.pdf
↑ Unicore processor simulator source code. Instruction formats are in decode.c, disassembly in interpret.c, and emulation in instEx.c.
↑ QEMU Unicore32 emulator source code

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Original source: https://en.wikipedia.org/wiki/Unicore. Read more

[1] "Introduction to MPRC". Microprocessor Research and Develop Center, Peking University. http://mprc.pku.cn/eng/intro.html.

[2] Xu Cheng; Xiaoyin Wang; Junlin Lu; Jiangfang Yi; Dong Tong; Xuetao Guan; Feng Liu; Xianhua Liu et al. (March 2010), "Research Progress of UniCore CPUs and PKUnity SoCs", Journal of Computer Science and Technology (JCST) 25 (2): 200–213, doi:10.1007/s11390-010-9317-1, http://mprc.pku.edu.cn/~guanxuetao/publications/2010-JCST-CX.pdf, retrieved 2012-07-11

[3] Bergmann, Arnd (2012-07-09). "Re: [PATCH 00/36] AArch64 Linux kernel port". linux-kernel (Mailing list). Retrieved 2012-07-11. Another interesting example is unicore32, which actually shares more code with arch/arm than the proposed arch/aarch64 does. I think the unicore32 code base would benefit from being merged back into arch/arm as a third instruction set, but the additional maintenance cost for everyone working on ARM makes that unrealistic.

[4] "Merge window closed - 2.6.39-rc1 out". Linus Torvalds. https://lkml.org/lkml/2011/3/29/351.

[5] "remove unicore32 support". Mike Rapoport. https://lkml.org/lkml/2020/8/3/232.

[6] Hsu-Hung Chiang; Huang-Jia Cheng; Yuan-Shin Hwan (2012-02-25), "Doubling the Number of Registers on ARM Processors", 16th Workshop on Interaction between Compilers and Computer Architectures (INTERACT), pp. 1–8, doi:10.1109/INTERACT.2012.6339620, ISBN 978-1-4673-2613-1, http://aces.snu.ac.kr/interact-16/papers/interact-16-paper-1.pdf

[7] Unicore processor simulator source code. Instruction formats are in decode.c, disassembly in interpret.c, and emulation in instEx.c.

[8] QEMU Unicore32 emulator source code

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