NEC V30MZ: Difference between revisions
(→Registers: add register names) |
m (→Architecture) |
||
Line 20: | Line 20: | ||
** '''DI'''<sup>IY</sup> - the ''destination index'' register, | ** '''DI'''<sup>IY</sup> - the ''destination index'' register, | ||
** '''SP''' - the ''stack pointer''; the stack is always addressed in the stack segment (so as <code>SS:SP</code> far addresses), | ** '''SP''' - the ''stack pointer''; the stack is always addressed in the stack segment (so as <code>SS:SP</code> far addresses), | ||
** '''BP''' - the ''base pointer'. | ** '''BP''' - the ''base pointer''. | ||
* Four segment registers: | * Four segment registers: | ||
** '''CS'''<sup>PS</sup> - code segment, | ** '''CS'''<sup>PS</sup> - the ''code segment'', | ||
** '''DS'''<sup>DS0</sup> - data segment, | ** '''DS'''<sup>DS0</sup> - the ''data segment'', | ||
** '''ES'''<sup>DS1</sup> - additional data segment, | ** '''ES'''<sup>DS1</sup> - the ''extra segment''; an additional data segment, | ||
** '''SS''' - stack segment. | ** '''SS''' - the ''stack segment''. | ||
* '''IP'''<sup>PC</sup> - instruction pointer; instructions are always addressed in the code segment (so as <code>CS:IP</code> far addresses), | * '''IP'''<sup>PC</sup> - the ''instruction pointer''; instructions are always addressed in the code segment (so as <code>CS:IP</code> far addresses), | ||
* '''FLAGS'''<sup>PSW</sup> - 16-bit processor flag register. | * '''FLAGS'''<sup>PSW</sup> - the 16-bit processor flag register. | ||
While the eight registers can be used in a general-purpose manner, some opcodes are constrained to only using certain registers: | While the eight registers can be used in a general-purpose manner, some opcodes are constrained to only using certain registers: |
Revision as of 09:02, 3 August 2024
The NEC V30MZ is the CPU component of the WonderSwan SoC.
Unlike the NEC V20/V30 CPU family, the V30MZ is fully compatible with the Intel 80186's documented behaviour, as well as some of its undocumented behaviour (such as the SALC opcode); it also omits the V20/V30's opcode extensions.
The NEC V30MZ datasheet uses distinct names for opcodes and registers (NEC names); as all homebrew compilers and assemblers for the platform utilize Intel's official naming (Intel names), the latter is what the wiki - and most community tooling - has standardized on.
Architecture
For this section, elements of the architecture which have distinct NEC names are provided in the following format: IntelNEC.
Registers
- Four 16-bit general-purpose registers, with their (low, high) components accessible as individual 8-bit sub-registers:
- AXAW (AL, AH) - the accumulator register,
- BXBW (BL, BH) - the base register,
- CXCW (CL, CH) - the count register,
- DXDW (DL, DH) - the data register,
- Four additional 16-bit registers:
- SIIX - the source index register,
- DIIY - the destination index register,
- SP - the stack pointer; the stack is always addressed in the stack segment (so as
SS:SP
far addresses), - BP - the base pointer.
- Four segment registers:
- CSPS - the code segment,
- DSDS0 - the data segment,
- ESDS1 - the extra segment; an additional data segment,
- SS - the stack segment.
- IPPC - the instruction pointer; instructions are always addressed in the code segment (so as
CS:IP
far addresses), - FLAGSPSW - the 16-bit processor flag register.
While the eight registers can be used in a general-purpose manner, some opcodes are constrained to only using certain registers:
- AX benefits from more compact encoding for certain instructions; it's also used as an output and input register in multiplication/division, port access, BCD conversions, and (as AL) in the XCHG opcode.
- CX is used for loop and repeat instructions as a counter.
- DX can be used used as the address register for port access, it is also used as an output register for word multiplication/division.
- BX, SI, and DI can be used as indices for accessing data in tables in the DS segment (or other segments when overridden).
- SI and DI are, in addition, used as source and destination pointers by string instructions.
- Similarly, BP can be used as an index for accessing stack data; this makes it particularly useful as a frame pointer.
Flags
The V30MZ features the following flags:
15 bit 8 7 bit 0 ---- ---- ---- ---- m111 odit sz0a 0p1c | |||| || | | | | |||| || | | +- Carry (CFCY) | |||| || | +--- Parity (PFP) | |||| || +------ Auxillary Carry (AFAC) | |||| |+-------- Zero (Z) | |||| +--------- Sign (S) | |||+------------ Single StepBreak (TFBRK) | ||+------------- Interrupt Enable (IFIE) | |+-------------- Direction (DFDIR) | +--------------- Overflow (OFV) +-------------------- Mode (MD)
In general, they are set by operations as follows:
- Carry - stores the carry/borrow state of the last arithmetic operation, or the bit shifted to it for shift/rotate operations.
- Parity - set to 1 if, after arithmetic and logical operations, the lower 8 bits of the result are even.
- Auxillary Carry - stores the carry state from the lower 4-bit nibble (bits 0-3) to the higher 4-bit nibble (bits 4-7), or the borrow state from the higher nibble to the lower nibble.
- Zero - set to 1 if, after arithmetic and logical operations, the result is equal to zero.
- Sign - set to 1 if, after arithmetic and logical operations, the highest bit of the result is set.
- Overflow - set to 1 if an overflow occured as part of the arithmetic operation.
There are also programmer-controlled control flags:
- Single Step - if set to 1, after every instruction, a software interrupt (vector 1) is generated.
- Interrupt Enable - if set to 1, enables maskable interrupt handling via the interrupt vector table; cleared to 0 as part of interrupt handling and restored by the IRET opcode.
- Direction - if set to 1, string instructions decrement pointers as part of their operation; if set to 0, the pointers are to be incremented.
- Mode - used for 8080 emulation mode in other V20/V30-family chips, does nothing on V30MZ
Instruction set
Instruction | Opcode (hex) | Opcode (bin) | Bytes | Cycles | Flags | NEC mnemonic | Notes |
---|---|---|---|---|---|---|---|
ADD AL, imm8 | 04 | 00000100 | 2 | 1 | O...SZAPC | ADD AL, imm8 | |
ADD AX, imm16 | 05 | 00000101 | 3 | 1 | O...SZAPC | ADD AW, imm16 | |
ADD mem8, imm8 | 80 rm / 82 rm | 100000.0 oo000mm | 3-5 | 3 | O...SZAPC | ADD mem8, imm8 |