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525 lines
24 KiB
Plaintext
525 lines
24 KiB
Plaintext
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notaz's SVP doc
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$Id: svpdoc.txt 349 2008-02-04 23:13:59Z notaz $
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Copyright 2008, Grazvydas Ignotas (notaz)
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-------------------------------------------------------------------------------
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If you use this, please credit me in your work or it's documentation.
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Tasco Deluxe should also be credited for his pioneering work on the subject.
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Thanks.
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Use monospace font and disable word wrap when reading this document.
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-------------------------------------------------------------------------------
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Table of Contents
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-------------------------------------------------------------------------------
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0. Introduction
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1. Overview
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2. The SSP160x DSP
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2.1. General registers
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2.2. External registers
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2.3. Pointer registers
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2.4. The instruction set
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3. Memory map
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4. Other notes
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-------------------------------------------------------------------------------
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0. Introduction
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-------------------------------------------------------------------------------
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This document is an attempt to provide technical information needed to
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emulate Sega's SVP chip. It is based on reverse engineering Virtua Racing
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game and on various internet sources. None of information provided here
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was verified on the real hardware, so some things are likely to be
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inaccurate.
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The following information sources were used while writing this document
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and emulator implementation:
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[1] SVP Reference Guide (annotated) and SVP Register Guide (annotated)
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by Tasco Deluxe < tasco.deluxe @ gmail.com >
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http://www.sharemation.com/TascoDLX/SVP%20Reference%20Guide%202007.02.11.txt
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http://www.sharemation.com/TascoDLX/SVP%20Register%20Guide%202007.02.11.txt
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[2] SSP1610 disassembler
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written by Pierpaolo Prazzoli, MAME source code.
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http://mamedev.org/
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[3] SSP1601 DSP datasheet
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http://notaz.gp2x.de/docs/SSP1601.pdf
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[4] DSP page (with code samples) in Samsung Semiconductor website from 1997
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retrieved from Internet Archive: The Wayback Machine
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http://web.archive.org/web/19970607052826/www.sec.samsung.com/Products/dsp/dspcore.htm
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[5] Sega's SVP Chip: The Road not Taken?
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Ken Horowitz, Sega-16
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http://sega-16.com/feature_page.php?id=37&title=Sega's%20SVP%20Chip:%20The%20Road%20not%20Taken?
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-------------------------------------------------------------------------------
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1. Overview
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-------------------------------------------------------------------------------
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The only game released with SVP chip was Virtua Racing. There are at least 4
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versions of the game: USA, Jap and 2 different Eur revisions. Three of them
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share identical SSP160x code, one of the Eur revisions has some differences.
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From the software developer's point of view, the game cartridge contains
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at least:
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* Samsung SSP160x 16-bit DSP core, which includes [3]:
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* Two independent high-speed RAM banks, accessed in single clock cycle,
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256 words each.
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* 16 x 16 bit multiply unit.
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* 32-bit ALU, status register.
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* Hardware stack of 6 levels.
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* 128KB of DRAM.
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* 2KB of IRAM (instruction RAM).
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* Memory controller with address mapping capability.
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* 2MB of game ROM.
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[5] claims there is also "2 Channels PWM" in the cartridge, but it's either
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not used or not there at all.
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Various sources claim that SSP160x is SSP1601 which is likely to be true,
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because the code doesn't seem to use any SSP1605+ features.
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-------------------------------------------------------------------------------
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2. The SSP160x DSP
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-------------------------------------------------------------------------------
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SSP160x is 16-bit DSP, capable of performing multiplication + addition in
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single clock cycle [3]. It has 8 general, 8 external and 8 pointer registers.
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There is a status register which has operation control bits and condition
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flags. Condition flags are set/cleared during ALU (arithmetic, logic)
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operations. It also has 6-level hardware stack and 2 internal RAM banks
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RAM0 and RAM1, 256 words each.
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The device is only capable of addressing 16-bit words, so all addresses refer
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to words (16bit value in ROM, accessed by 68k through address 0x84 would be
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accessed by SSP160x using address 0x42).
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[3] mentions interrupt pins, but interrupts don't seem to be used by SVP code
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(actually there are functions which look like interrupt handler routines, but
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they don't seem to do anything important).
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2.1. General registers
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----------------------
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There are 8 general registers: -, X, Y, A, ST, STACK, PC and P ([2] [4]).
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Size is given in bits.
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2.1.1. "-"
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Constant register with all bits set (0xffff). Also used for programming
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external registers (blind reads/writes, see 2.2).
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size: 16
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2.1.2. "X"
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Generic register. Also acts as a multiplier 1 for P register.
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size: 16
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2.1.3. "Y"
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Generic register. Also acts as a multiplier 2 for P register.
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size: 16
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2.1.4. "A"
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Accumulator. Stores the result of all ALU (but not multiply) operations,
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status register is updated according to this. When directly accessed,
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only upper word is read/written. Low word can be accessed by using AL
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(see 2.2.8).
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size: 32
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2.1.5. "ST"
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STatus register. Bits 0-9 are CONTROL, other are FLAG [2]. Only some of
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them are actually used by SVP.
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Bits: fedc ba98 7654 3210
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210 - RPL "Loop size". If non-zero, makes (rX+) and (rX-) respectively
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modulo-increment and modulo-decrement (see 2.3). The value
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shows which power of 2 to use, i.e. 4 means modulo by 16.
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43 - RB Unknown. Not used by SVP code.
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5 - ST5 Affects behavior of external registers. See 2.2.
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6 - ST6 Affects behavior of external registers. See 2.2.
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According to [3] (5,6) bits correspond to hardware pins.
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7 - IE Interrupt enable? Not used by SVP code.
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8 - OP Saturated value? Not used by SVP code.
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9 - MACS MAC shift? Not used by SVP code.
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a - GPI_0 Interrupt 0 enable/status? Not used by SVP code.
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b - GPI_1 Interrupt 1 enable/status? Not used by SVP code.
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c - L L flag. Similar to carry? Not used by SVP code.
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d - Z Zero flag. Set after ALU operations, when all 32 accumulator
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bits become zero.
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e - OV Overflow flag. Not used by SVP code.
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f - N Negative flag. Set after ALU operations, when bit31 in
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accumulator is 1.
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size: 16
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2.1.6. "STACK"
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Hardware stack of 6 levels [3]. Values are "pushed" by directly writing to
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it, or by "call" instruction. "Pop" is performed by directly reading the
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register or by "ret" instruction.
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size: 16
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2.1.7. "PC"
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Program Counter. Can be written directly to perform a jump. It is not clear
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if it is possible to read it (SVP code never does).
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size: 16
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2.1.8. "P"
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multiply Product - multiplication result register.
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Always contains 32-bit multiplication result of X, Y and 2 (P = X * Y * 2).
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X and Y are sign-extended before performing the multiplication.
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size: 32
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2.2. External registers
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-----------------------
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The external registers, as the name says, are external to SSP160x, they are
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hooked to memory controller in SVP, so by accessing them we actually program
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the memory controller. They act as programmable memory access registers or
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external status registers [1]. Some of them can act as both, depending on how
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ST5 ans ST6 bits are set in status register. After a register is programmed,
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accessing it causes reads/writes from/to external memory (see section 3 for
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the memory map). The access may also cause some additional effects, like
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incremental of address, associated with accessed register.
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In this document and my emu, instead of using names EXT0-EXT7
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from [4] I used different names for these registers. Those names are from
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Tasco Deluxe's [1] doc.
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All these registers can be blind-accessed (as said in [1]) by performing
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(ld -, PMx) or (ld PMx, -). This programs them to access memory (except PMC,
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where the effect is different).
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All registers are 16-bit.
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2.2.1. "PM0"
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If ST5 or ST6 is set, acts as Programmable Memory access register
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(see 2.2.7). Else it acts as status of XST (2.2.4). It is also mapped
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to a15004 on 68k side:
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???????? ??????10
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0: set, when SSP160x has written something to XST
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(cleared when 015004 is read by 68k)
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1: set, when 68k has written something to a15000 or a15002
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(cleared on PM0 read by SSP160x)
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Note that this is likely to be incorrect, but such behavior is OK for
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emulation to work.
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2.2.2. "PM1"
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Programmable Memory access register. Only accessed with ST bits set by
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SVP code.
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2.2.3. "PM2"
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Same as PM1.
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2.2.4. "XST"
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If ST5 or ST6 is set, acts as Programmable Memory access register
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(only used by memory test code). Else it acts as eXternal STatus
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register, which is also mapped to a15000 and a15002 on 68k side.
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Affects PM0 when written to.
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2.2.5. "PM4"
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Programmable Memory access register. Not affected by ST5 and ST6 bits,
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always stays in PMAR mode.
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2.2.6. "EXT5"
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Not used by SVP, so not covered by this document.
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2.2.7. "PMC"
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Programmable Memory access Control. It is set using 2 16bit writes, first
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address, then mode word. After setting PMAC, PMx should be blind accessed
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using (ld -, PMx) or (ld PMx, -) to program it for reading or writing
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external memory respectively. Every PMx register can be programmed to
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access it's own memory location with it's own mode. Registers are programmed
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separately for reading and writing.
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Reading PMC register also shifts it's state (from "waiting for address" to
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"waiting for mode" and back). Reads always return address word related to
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last PMx register accessed, or last address word written to PMC (whichever
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event happened last before PMC read).
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The address word contains bits 0-15 of the memory word-address.
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The mode word format is as follows:
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dsnnnv?? ???aaaaa
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a: bits 16-20 of memory word-address.
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n: auto-increment value. If set, after every access of PMx, word-address
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value related to it will be incremented by (words):
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1 - 1 5 - 16
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2 - 2 6 - 32
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3 - 4 7 - 128
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4 - 8
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d: make auto-increment negative - decrement by count listed above.
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s: special-increment mode. If current address is even (when accessing
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programmed PMx), increment it by 1. Else, increment by 32. It is not
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clear what happens if d and n bits are also set (never done by SVP).
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v: over-write mode when writing, unknown when reading (not used).
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Over-write mode splits the word being written into 4 half-bytes and
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only writes those half-bytes, which are not zero.
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When auto-increment is performed, it affects all 21 address bits.
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2.2.8. "AL"
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This register acts more like a general register.
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If this register is blind-accessed, it is "dummy programmed", i.e. nothing
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happens and PMC is reset to "waiting for address" state.
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In all other cases, it is Accumulator Low, 16 least significant bits of
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accumulator. Normally reading acc (ld X, A) you get 16 most significant
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bits, so this allows you access the low word of 32bit accumulator.
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2.3. Pointer registers
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----------------------
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There are 8 8-bit pointer registers rX, which are internal to SSP160x and are
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used to access internal RAM banks RAM0 and RAM1, or program memory indirectly.
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r0-r3 (ri) point to RAM0, r4-r7 (rj) point to RAM1. Each bank has 256 words of
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RAM, so 8bit registers can fully address them. The registers can be accessed
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directly, or 2 indirection levels can be used [ (rX), ((rX)) ]. They work
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similar to * and ** operators in C, only they use different types of memory
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and ((rX)) also performs post-increment. First indirection level (rX) accesses
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a word in RAMx, second accesses program memory at address read from (rX), and
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increments value in (rX).
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Only r0,r1,r2,r4,r5,r6 can be directly modified (ldi r0, 5), or by using
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modifiers. 3 modifiers can be applied when using first indirection level
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(optional):
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+ : post-increment (ld a, (r0+) ). Increment register value after operation.
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Can be made modulo-increment by setting RPL bits in status register
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(see 2.1.5).
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- : post-decrement. Also can be made modulo-decrement by using RPL bits in ST.
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+!: post-increment, unaffected by RPL (probably).
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These are only used on 1st indirection level, so things like ( ld a, ((r0+)) )
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and (ld X, r6-) are probably invalid.
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r3 and r7 are special and can not be changed (at least Samsung samples [4] and
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SVP code never do). They are fixed to the start of their RAM banks. (They are
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probably changeable for ssp1605+, Samsung's old DSP page claims that).
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1 of these 4 modifiers must be used on these registers (short form direct
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addressing? [2]):
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|00: RAMx[0] The very first word in the RAM bank.
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|01: RAMx[1] Second word
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|10: RAMx[2] ...
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|11: RAMx[3]
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2.4. The instruction set
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------------------------
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The Samsung SSP16 series assembler uses right-to-left notation ([2] [4]):
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ld X, Y
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means value from Y should be copied to X.
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Size of every instruction is word, some have extension words for immediate
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values. When writing an interpreter, 7 most significant bits are usually
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enough to determine which opcode it is.
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encoding bits are marked as:
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rrrr - general or external register, in order specified in 2.1 and 2.2
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(0 is '-', 1 'X', ..., 8 is 'PM0', ..., 0xf is 'AL')
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dddd - same as above, as destination operand
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ssss - same as above, as source operand
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jpp - pointer register index, 0-7
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j - specifies RAM bank, i.e. RAM0 or RAM1
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i* - immediate value bits
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a* - offset in internal RAM bank
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mm - modifier for pointer register, depending on register:
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r0-r2,r4-r6 r3,r7 examples
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0: (none) |00 ld a, (r0) cmp a, (r7|00)
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1: +! |01 ld (r0+!), a ld (r7|01), a
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2: - |10 add a, (r0-)
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3: + |11
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cccc - encodes condition, only 3 used by SVP, see check_cond() below
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ooo - operation to perform
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Operation is written in C-style pseudo-code, where:
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program_memory[X] - access program memory at address X
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RAMj[X] - access internal RAM bank j=0,1 (RAM0 or RAM1), word
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offset X
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RIJ[X] - pointer register rX, X=0-7
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pr_modif_read(m,X) - read pointer register rX, applying modifier m:
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if register is r3 or r7, return value m
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else switch on value m:
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0: return rX;
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1: tmp = rX; rX++; return tmp; // rX+!
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2: tmp = rX; modulo_decrement(rX); return tmp; // rX-
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3: tmp = rX; modulo_increment(rX); return tmp; // rX+
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the modulo value used (if used at all) depends on ST
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RPL bits (see 2.1.5)
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check_cond(c,f) - checks if a flag matches f bit:
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switch (c) {
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case 0: return true;
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case 5: return (Z == f) ? true : false; // check Z flag
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case 7: return (N == f) ? true : false; // check N flag
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} // other conditions are possible, but they are not used
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update_flags() - update ST flags according to last ALU operation.
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sign_extend(X) - sign extend 16bit value X to 32bits.
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next_op_address() - address of instruction after current instruction.
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2.4.1. ALU instructions
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All of these instructions update flags, which are set according to full 32bit
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accumulator. The SVP code only checks N and Z flags, so it is not known when
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exactly OV and L flags are set. Operations are performed on full A, so
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(andi A, 0) would clear all 32 bits of A.
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They share the same addressing modes. The exact arithmetic operation is
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determined by 3 most significant (ooo) bits:
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001 - sub - subtract (OP -=)
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011 - cmp - compare (OP -, flags are updated according to result)
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100 - add - add (OP +=)
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101 - and - binary AND (OP &=)
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110 - or - binary OR (OP |=)
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111 - eor - exclusive OR (OP ^=)
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syntax encoding operation
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OP A, s ooo0 0000 0000 rrrr A OP r << 16;
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OP A, (ri) ooo0 001j 0000 mmpp A OP RAMj[pr_modif_read(m,jpp)] << 16;
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OP A, adr ooo0 011j aaaa aaaa A OP RAMj[a] << 16;
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OPi A, imm ooo0 1000 0000 0000 A OP i << 16;
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iiii iiii iiii iiii
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op A, ((ri)) ooo0 101j 0000 mmpp tmp = pr_modif_read(m,jpp);
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A OP program_memory[RAMj[tmp]] << 16;
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RAMj[tmp]++;
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|
op A, ri ooo1 001j 0000 00pp A OP RIJ[jpp] << 16;
|
||
|
OPi simm ooo1 1000 iiii iiii A OP i << 16;
|
||
|
|
||
|
There is also "perform operation on accumulator" instruction:
|
||
|
|
||
|
syntax encoding operation
|
||
|
mod cond, op 1001 000f cccc 0ooo if (check_cond(c,f)) switch(o) {
|
||
|
case 2: A >>= 1; break; // arithmetic shift
|
||
|
case 3: A <<= 1; break;
|
||
|
case 6: A = -A; break; // negate A
|
||
|
case 7: A = abs(A); break; // absolute val.
|
||
|
} // other operations are possible, but
|
||
|
// they are not used by SVP.
|
||
|
|
||
|
2.4.2. Load (move) instructions
|
||
|
|
||
|
These instructions never affect flags (even ld A).
|
||
|
If destination is A, and source is 16bit, only upper word is transfered (same
|
||
|
thing happens on opposite). If dest. is A, and source is P, whole 32bit value
|
||
|
is transfered. It is not clear if P can be destination operand (probably not,
|
||
|
no code ever does this).
|
||
|
Writing to STACK pushes a value there, reading pops. It is not known what
|
||
|
happens on overflow/underflow (never happens in SVP code).
|
||
|
ld -, - is used as a nop.
|
||
|
|
||
|
syntax encoding operation
|
||
|
ld d, s 0000 0000 dddd ssss d = s;
|
||
|
ld d, (ri) 0000 001j dddd mmpp d = RAMj[pr_modif_read(m,jpp)];
|
||
|
ld (ri), s 0000 010j ssss mmpp RAMj[pr_modif_read(m,jpp)] = s;
|
||
|
ldi d, imm 0000 1000 dddd 0000 d = i;
|
||
|
iiii iiii iiii iiii
|
||
|
ld d, ((ri)) 0000 101j dddd mmpp tmp = pr_modif_read(m,jpp);
|
||
|
d = program_memory[RAMj[tmp]];
|
||
|
RAMj[tmp]++;
|
||
|
ldi (ri), imm 0000 110l 0000 mmpp RAMj[pr_modif_read(m,jpp)] = i;
|
||
|
iiii iiii iiii iiii
|
||
|
ld adr, a 0000 111j aaaa aaaa RAMj[a] = A;
|
||
|
ld d, ri 0001 001j dddd 00pp d = RIJ[jpp];
|
||
|
ld ri, s 0001 010j ssss 00pp RIJ[jpp] = s;
|
||
|
ldi ri, simm 0001 1jpp iiii iiii RIJ[jpp] = i;
|
||
|
ld d, (a) 0100 1010 dddd 0000 d = program_memory[A[31:16]];
|
||
|
// read a word from program memory. Offset
|
||
|
// is the upper word in A.
|
||
|
|
||
|
2.4.3. Program control instructions
|
||
|
|
||
|
Only 3 instructions: call, ret (alias of ld PC, STACK) and branch. Indirect
|
||
|
jumps can be performed by simply writing to PC.
|
||
|
|
||
|
syntax encoding operation
|
||
|
call cond, addr 0100 100f cccc 0000 if (check_cond(c,f)) {
|
||
|
aaaa aaaa aaaa aaaa STACK = next_op_address(); PC = a;
|
||
|
}
|
||
|
bra cond, addr 0100 110f cccc 0000 if (check_cond(c,f)) PC = a;
|
||
|
aaaa aaaa aaaa aaaa
|
||
|
ret 0000 0000 0110 0101 PC = STACK; // same as ld PC, STACK
|
||
|
|
||
|
2.4.4. Multiply-accumulate instructions
|
||
|
|
||
|
Not sure if (ri) and (rj) really get loaded into X and Y, but multiplication
|
||
|
result surely is loaded into P. There is probably optional 3rd operand (1, 0;
|
||
|
encoded by bit16, default 1), but it's not used by SVP code.
|
||
|
|
||
|
syntax encoding operation
|
||
|
mld (rj), (ri) 1011 0111 nnjj mmii A = 0; update_flags();
|
||
|
X = RAM0[pr_modif_read(m,0ii)];
|
||
|
Y = RAM1[pr_modif_read(m,1jj)];
|
||
|
P = sign_extend(X) * sign_extend(Y) * 2
|
||
|
mpya (rj), (ri) 1001 0111 nnjj mmii A += P; update_flags();
|
||
|
X = RAM0[pr_modif_read(m,0ii)];
|
||
|
Y = RAM1[pr_modif_read(m,1jj)];
|
||
|
P = sign_extend(X) * sign_extend(Y) * 2
|
||
|
mpys (rj), (ri) 0011 0111 nnjj mmii A -= P; update_flags();
|
||
|
X = RAM0[pr_modif_read(m,0ii)];
|
||
|
Y = RAM1[pr_modif_read(m,1jj)];
|
||
|
P = sign_extend(X) * sign_extend(Y) * 2
|
||
|
|
||
|
-------------------------------------------------------------------------------
|
||
|
3. Memory map
|
||
|
-------------------------------------------------------------------------------
|
||
|
|
||
|
The SSp160x can access it's own program memory, and external memory through EXT
|
||
|
registers (see 2.2). Program memory is read-execute-only, the size of this
|
||
|
space is 64K words (this is how much 16bit PC can address):
|
||
|
|
||
|
byte address word address name
|
||
|
0- 7ff 0- 3ff IRAM
|
||
|
800-1ffff 400-ffff ROM
|
||
|
|
||
|
There were reports that SVP has internal ROM, but fortunately they were wrong.
|
||
|
The location 800-1ffff is mapped from the same location in the 2MB game ROM.
|
||
|
The IRAM is read-only (as SSP160x doesn't have any means of writing to it's
|
||
|
program memory), but it can be changed through external memory space, as it's
|
||
|
also mapped there.
|
||
|
|
||
|
The external memory space seems to match the one visible by 68k, with some
|
||
|
differences:
|
||
|
|
||
|
68k space SVP space word address name
|
||
|
0-1fffff 0-1fffff 0- fffff game ROM
|
||
|
300000-31ffff 300000-31ffff 180000-18ffff DRAM
|
||
|
? 390000-3907ff 1c8000-1c83ff IRAM
|
||
|
390000-39ffff ? ? "cell arrange" 1
|
||
|
3a0000-3affff ? ? "cell arrange" 2
|
||
|
a15000-a15009 n/a n/a Status/control registers
|
||
|
|
||
|
The external memory can be read/written by SSP160x (except game ROM, which can
|
||
|
only be read).
|
||
|
|
||
|
"cell arrange" 1 and 2 are similar to the one used in SegaCD, they map
|
||
|
300000-30ffff location to 390000-39ffff and 3a0000-3affff, where linear image
|
||
|
written to 300000 can be read as VDP patterns at 390000. Virtua Racing doesn't
|
||
|
seem to use this feature, it is only used by memory test code.
|
||
|
|
||
|
Here is the list of status/control registers (16bit size):
|
||
|
a15000 - w/r command/result register. Visible as XST for SSP160x (2.2.4).
|
||
|
a15002 - mirror of the above.
|
||
|
a15004 - status of command/result register (see 2.2.1).
|
||
|
a15006 - possibly halts the SVP. Before doing DMA from DRAM, 68k code writes
|
||
|
0xa, and after it's finished, writes 0. This is probably done to
|
||
|
prevent SVP accessing DRAM and avoid bus clashes.
|
||
|
a15008 - possibly causes an interrupt. There is (unused?) code which writes
|
||
|
0, 1, and again 0 in sequence.
|
||
|
|
||
|
|
||
|
-------------------------------------------------------------------------------
|
||
|
4. Other notes
|
||
|
-------------------------------------------------------------------------------
|
||
|
|
||
|
The game has arcade-style memory self-check mode, which can be accessed by
|
||
|
pressing _all_ buttons (including directions) on 3-button controller. There was
|
||
|
probably some loopback plug for this.
|
||
|
|
||
|
SVP seems to have DMA latency issue similar to one in Sega CD, as the code
|
||
|
always sets DMA source address value larger by 2, then intended for copy.
|
||
|
This is even true for DMAs from ROM, as it's probably hooked through SVP's
|
||
|
memory controller.
|
||
|
|
||
|
The entry point for the code seems to be at address 0x800 (word 0x400) in ROM,
|
||
|
but it is not clear where the address is fetched from when the system powers
|
||
|
up. The memory test code also sets up "ld PC, .." opcodes at 0x7f4, 0x7f8 and
|
||
|
0x7fc, which jump to some routines, possibly interrupt handlers. This means
|
||
|
that mentioned addresses might be built-in interrupt vectors.
|
||
|
|
||
|
The SVP code doesn't seem to be timing sensitive, so it can be emulated without
|
||
|
knowing timing of the instructions or even how fast the chip is clocked.
|
||
|
Overclocking doesn't have any effect, underclocking causes slowdowns. Running
|
||
|
10-12M instructions/sec (or possibly less) is sufficient.
|
||
|
|