dolphin/Source/DSPSpy/dsp_code.ds

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; This is the trojan program we send to the DSP from DSPSpy to figure it out.
; A lot of constant definitions.
DSCR: equ 0xffc9 ; DSP DMA Control Reg
DSBL: equ 0xffcb ; DSP DMA Block Length
DSPA: equ 0xffcd ; DSP DMA DMEM Address
DSMAH: equ 0xffce ; DSP DMA Mem Address H
DSMAL: equ 0xffcf ; DSP DMA Mem Address L
ACSAH: equ 0xffd4
ACSAL: equ 0xffd5
ACEAH: equ 0xffd6
ACEAL: equ 0xffd7
ACCAH: equ 0xffd8
ACCAL: equ 0xffd9
AMDM: equ 0xffef ; ARAM DMA Request Mask
DIRQ: equ 0xfffb ; DSP Irq Request
DMBH: equ 0xfffc ; DSP Mailbox H
DMBL: equ 0xfffd ; DSP Mailbox L
CMBH: equ 0xfffe ; CPU Mailbox H
CMBL: equ 0xffff ; CPU Mailbox L
R00: equ 0x00
R01: equ 0x01
R02: equ 0x02
R03: equ 0x03
R04: equ 0x04
R05: equ 0x05
R06: equ 0x06
R07: equ 0x07
R08: equ 0x08
R09: equ 0x09
R0A: equ 0x0a
R0B: equ 0x0b
R0C: equ 0x0c
R0D: equ 0x0d
R0E: equ 0x0e
R0F: equ 0x0f
R10: equ 0x10
R11: equ 0x11
R12: equ 0x12
R13: equ 0x13
R14: equ 0x14
R15: equ 0x15
R16: equ 0x16
R17: equ 0x17
R18: equ 0x18
R19: equ 0x19
R1A: equ 0x1a
R1B: equ 0x1b
R1C: equ 0x1c
R1D: equ 0x1d
R1E: equ 0x1e
R1F: equ 0x1f
ACH0: equ 0x10
ACH1: equ 0x11
ACL0: equ 0x1e
ACL1: equ 0x1f
DSP_CR_IMEM: equ 2
DSP_CR_TO_CPU: equ 1
REGS_BASE: equ 0x0f80
MEM_HI: equ 0x0f7E
MEM_LO: equ 0x0f7F
; CODE STARTS HERE.
; Interrupt vectors 8 vectors, 2 opcodes each
jmp irq0
jmp irq1
jmp irq2
jmp irq3
jmp irq4
jmp irq5
jmp irq6
jmp irq7
; Main code at 0x10
sbset #0x02
sbset #0x03
sbclr #0x04
sbset #0x05
sbset #0x06
s40
lri $CR, #0x00ff
; Why do we have a main label here?
main:
clr $ACC1
clr $ACC0
; get address of memory dump and copy it to DRAM
call wait_for_dsp_mbox
si @DMBH, #0x8888
si @DMBL, #0xdead
si @DIRQ, #0x0001
call wait_for_cpu_mbox
lrs $ACL0, @CMBL
andi $acl1, #0x7fff
sr @MEM_HI, $ACL1
sr @MEM_LO, $ACL0
lri $r18, #0
lri $r19, #0 ;(DSP_CR_IMEM | DSP_CR_TO_CPU)
lri $r1a, #0x2000
lr $r1c, @MEM_HI
lr $r1e, @MEM_LO
call do_dma
; get address of registers and DMA them to ram
call wait_for_dsp_mbox
si @DMBH, #0x8888
si @DMBL, #0xbeef
si @DIRQ, #0x0001
call wait_for_cpu_mbox
lrs $ACL0, @CMBL
andi $acl1, #0x7fff
sr @MEM_HI, $ACL1
sr @MEM_LO, $ACL0
lri $r18, #REGS_BASE
lri $r19, #0 ;(DSP_CR_IMEM | DSP_CR_TO_CPU)
lri $r1a, #0x80
lr $r1c, @MEM_HI
lr $r1e, @MEM_LO
call do_dma
; Read in all the registers from RAM
lri $r00, #REGS_BASE+1
lrri $r01, @$r00
lrri $r02, @$r00
lrri $r03, @$r00
lrri $r04, @$r00
lrri $r05, @$r00
lrri $r06, @$r00
lrri $r07, @$r00
lrri $r08, @$r00
lrri $r09, @$r00
lrri $r0a, @$r00
lrri $r0b, @$r00
lrri $r0c, @$r00
lrri $r0d, @$r00
lrri $r0e, @$r00
lrri $r0f, @$r00
lrri $r10, @$r00
lrri $r11, @$r00
lrri $r12, @$r00
lrri $r13, @$r00
lrri $r14, @$r00
lrri $r15, @$r00
lrri $r16, @$r00
lrri $r17, @$r00
lrri $r18, @$r00
lrri $r19, @$r00
lrri $r1a, @$r00
lrri $r1b, @$r00
lrri $r1c, @$r00
lrri $r1d, @$r00
lrri $r1e, @$r00
lrri $r1f, @$r00
lr $r00, @REGS_BASE
; Right here we are at a specific predetermined state.
; Ideal environment to try instructions.
; We can call send_back at any time to send data back to the PowerPC.
; Calling set16 here seemed to crash the dsp tester in strange ways
; until I added set40 in send_back. Seems clear that it affects something important.
nop
nop
lris $AC0.M, #0xcc
lris $AC1.M, #0xcc
nop
mrr $r00, $r13
call send_back
s16
nop
lris $AC0.M, #0xcc
lris $AC1.M, #0xcc
nop
nop
mrr $r00, $r13
call send_back
cw 0xa100
call send_back
cw 0xa900
call send_back
s16
cw 0xa100
call send_back
s16
cw 0xa900
call send_back
; We're done - currently we only test one opcode, in this case 0x8600.
; It's possible to test many more in one go - just call send_back after each one.
jmp ende
; Below here is tons of random leftover test code from whoever last experimented with this.
; call dump_memory
; call send_back
cw 0x00de
cw 0x03f1
call send_back
cw 0x0200
cw 0x0a60
call send_back
cw 0x1c7e
call send_back
cw 0x8100
call send_back
cw 0x8900
call send_back
cw 0x009f
cw 0x00a0
call send_back
cw 0x00de
cw 0x03f1
call send_back
cw 0x5d00
call send_back
cw 0x0e50
call send_back
cw 0x0750
call send_back
cw 0x0270
call send_back
cw 0x5d00
call send_back
cw 0x00da
cw 0x03f2
call send_back
cw 0x8600
call send_back
JNS g_0c4d
; cw 0x0290
; cw 0x0c4d
; call send_back JX0
cw 0x00de
cw 0x03f3
call send_back
cw 0x5c00
call send_back
JLE g_0c38
; cw 0x0293
; cw 0x0c38 JX3
; call send_back
JMP g_0c52
; cw 0x029f
; cw 0x0c52
; call send_back
g_0c38:
cw 0x00db
cw 0x03f7
call send_back
cw 0x009e
cw 0x8000
call send_back
cw 0x4600
call send_back
JMP g_0c44
; cw 0x029f
; cw 0x0c44
; call send_back
g_0c3f:
cw 0x00db
cw 0x03f7
call send_back
cw 0x009e
cw 0x8000
call send_back
cw 0x5600
call send_back
g_0c44:
cw 0x00fe
cw 0x03f5
call send_back
cw 0x1fda
call send_back
cw 0x7c00
call send_back
cw 0x1f5e
call send_back
cw 0x00fe
cw 0x03f2
call send_back
JMP g_0c52
; cw 0x029f
; cw 0x0c52
; call send_back
g_0c4d:
cw 0x00de
cw 0x03f4
call send_back
cw 0x5d00
call send_back
JLE g_0c3f
; cw 0x0293
; cw 0x0c3f
; call send_back
g_0c52:
cw 0x8900
call send_back
cw 0x00dd
cw 0x03f5
call send_back
cw 0x1501
call send_back
cw 0x8100
call send_back
cw 0x00dc
cw 0x03f6
call send_back
cw 0x008b
cw 0x009f
call send_back
cw 0x0080
cw 0x0a00
call send_back
cw 0x0900
call send_back
BLOOPI #0x50, g_0c65
; cw 0x1150
; cw 0x0c65
; call send_back
cw 0x1878
call send_back
cw 0x4c00
call send_back
cw 0x1cfe
call send_back
cw 0x001f
call send_back
cw 0x1fd9
call send_back
g_0c65:
cw 0x1b18
call send_back
cw 0x009f
cw 0x0a60
call send_back
cw 0x1fc3
call send_back
cw 0x5c00
call send_back
cw 0x00fe
cw 0x03f1
call send_back
cw 0x00fc
cw 0x03f6
call send_back
cw 0x008b
cw 0xffff
call send_back
; This is where we jump when we're done testing, see above.
ende:
nop
nop
nop
nop
nop
nop
nop
; We just fall into a loop, playing dead until someone resets the DSP.
dead_loop:
jmp dead_loop
; Utility function to do DMA.
; r1c:r1e - external address.
; r18 - address in DSP
do_dma:
sr @DSMAH, $r1c
sr @DSMAL, $r1e
sr @DSPA, $r18
sr @DSCR, $r19
sr @DSBL, $r1a ; This kicks off the DMA.
; Waits for said DMA to complete by watching a bit in DSCR.
wait_dma:
LRS $ACL1, @DSCR
andcf $acl1, #0x0004
JLZ wait_dma
RET
; This waits for a mail to arrive in the DSP in-mailbox.
wait_for_dsp_mbox:
lrs $ACL1, @DMBH
andcf $acl1, #0x8000
jlz wait_for_dsp_mbox
ret
; This waits for the CPU to grab a mail that we just sent from the DSP.
wait_for_cpu_mbox:
lrs $ACL1, @cmbh
andcf $acl1, #0x8000
jlnz wait_for_cpu_mbox
ret
; IRQ handlers. Not entirely sure what good they do currently.
irq0:
lri $acl0, #0x0000
jmp irq
irq1:
lri $acl0, #0x0001
jmp irq
irq2:
lri $acl0, #0x0002
jmp irq
irq3:
lri $acl0, #0x0003
jmp irq
irq4:
lri $acl0, #0x0004
jmp irq
irq5:
; No idea what this code is doing.
s40
mrr $r0d, $r1c
mrr $r0d, $r1e
clr $acc0
mrr $r1e, $r0d
mrr $r1c, $r0d
nop ; Or why there's a nop sled here.
nop
nop
nop
nop
nop
rti
lri $acl0, #0x0005
jmp irq
irq6:
lri $acl0, #0x0006
jmp irq
irq7:
lri $acl0, #0x0007
jmp irq
irq:
lrs $ACL1, @DMBH
andcf $acl1, #0x8000
jlz irq
si @DMBH, #0x8BAD
sr @DMBL, $r0b
;sr @DMBL, $acl0
si @DIRQ, #0x0001
halt
; DMA:s the current state of the registers back to the PowerPC. To do this,
; it must write the contents of all regs to DRAM.
send_back:
; make state safe.
set40
; store registers to reg table
sr @REGS_BASE, $r00
lri $r00, #(REGS_BASE + 1)
srri @$r00, $r01
srri @$r00, $r02
srri @$r00, $r03
srri @$r00, $r04
srri @$r00, $r05
srri @$r00, $r06
srri @$r00, $r07
srri @$r00, $r08
srri @$r00, $r09
srri @$r00, $r0a
srri @$r00, $r0b
srri @$r00, $r0c
srri @$r00, $r0d
srri @$r00, $r0e
srri @$r00, $r0f
srri @$r00, $r10
srri @$r00, $r11
srri @$r00, $r12
srri @$r00, $r13
srri @$r00, $r14
srri @$r00, $r15
srri @$r00, $r16
srri @$r00, $r17
srri @$r00, $r18
srri @$r00, $r19
srri @$r00, $r1a
srri @$r00, $r1b
srri @$r00, $r1c
srri @$r00, $r1d
srri @$r00, $r1e
srri @$r00, $r1f
; Regs are stored. Prepare DMA.
lri $r18, #0x0000
lri $r19, #1 ;(DSP_CR_IMEM | DSP_CR_TO_CPU)
lri $r1a, #0x200
lr $r1c, @MEM_HI
lr $r1e, @MEM_LO
lri $r01, #8+8
; Now, why are we looping here?
bloop $r01, dma_copy
call do_dma
addi $r1e, #0x200
mrr $r1f, $r18
addi $r1f, #0x100
mrr $r18, $r1f
nop
dma_copy:
nop
; Wait for the CPU to send us a mail.
call wait_for_dsp_mbox
si @DMBH, #0x8888
si @DMBL, #0xfeeb
si @DIRQ, #0x0001
; wait for the CPU to recieve our response before we execute the next op
call wait_for_cpu_mbox
lrs $ACL0, @CMBL
andi $acl1, #0x7fff
; Restore all regs again so we're ready to execute another op.
lri $r00, #REGS_BASE+1
lrri $r01, @$r00
lrri $r02, @$r00
lrri $r03, @$r00
lrri $r04, @$r00
lrri $r05, @$r00
lrri $r06, @$r00
lrri $r07, @$r00
lrri $r08, @$r00
lrri $r09, @$r00
lrri $r0a, @$r00
lrri $r0b, @$r00
lrri $r0c, @$r00
lrri $r0d, @$r00
lrri $r0e, @$r00
lrri $r0f, @$r00
lrri $r10, @$r00
lrri $r11, @$r00
lrri $r12, @$r00
lrri $r13, @$r00
lrri $r14, @$r00
lrri $r15, @$r00
lrri $r16, @$r00
lrri $r17, @$r00
lrri $r18, @$r00
lrri $r19, @$r00
lrri $r1a, @$r00
lrri $r1b, @$r00
lrri $r1c, @$r00
lrri $r1d, @$r00
lrri $r1e, @$r00
lrri $r1f, @$r00
lr $r00, @REGS_BASE
ret ; from send_back
; If you are in s16 mode, use this instead of send_back if you want to stay
; in s16 mode.
send_back_16:
set40
call send_back
set16
ret
; This one's odd. Doesn't look like it should work since it uses acl0 but
; increments acm0... (acc0)
dump_memory:
lri $r02, #0x0000
lri $acl0, #0x1000
lri $r01, #0x1000
bloop $r01, _fill_loop2
mrr $r03, $acl0
nx'ld : $AX0.H, $AX1.H, @$AR0
mrr $r1f, $r00
mrr $r00, $r02
srri @$r00, $r1b
mrr $r02, $r00
mrr $r00, $r1f
addis $acc0, #0x1
_fill_loop2:
nop
ret ; from dump_memory