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https://github.com/dolphin-emu/dolphin.git
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eec7cba0af
git-svn-id: https://dolphin-emu.googlecode.com/svn/trunk@3871 8ced0084-cf51-0410-be5f-012b33b47a6e
359 lines
7.0 KiB
PHP
359 lines
7.0 KiB
PHP
; This is the trojan program we send to the DSP from DSPSpy to figure it out.
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REGS_BASE: equ 0x0f80
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MEM_HI: equ 0x0f7E
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MEM_LO: equ 0x0f7F
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;
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; CODE STARTS HERE.
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; Interrupt vectors 8 vectors, 2 opcodes each
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jmp irq0
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jmp irq1
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jmp irq2
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jmp irq3
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jmp irq4
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jmp irq5
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jmp irq6
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jmp irq7
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; Main code at 0x10
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sbset #0x02
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sbset #0x03
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sbclr #0x04
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sbset #0x05
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sbset #0x06
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s16
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lri $CR, #0x00ff
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; Why do we have a main label here?
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main:
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clr $acc1
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clr $acc0
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; get address of memory dump and copy it to DRAM
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call wait_for_dsp_mbox
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si @DMBH, #0x8888
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si @DMBL, #0xdead
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si @DIRQ, #0x0001
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call wait_for_cpu_mbox
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lrs $ac0.m, @CMBL
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andi $ac1.m, #0x7fff
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sr @MEM_HI, $ac1.m
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sr @MEM_LO, $ac0.m
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lri $ax0.l, #0
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lri $ax1.l, #0 ;(DSP_CR_IMEM | DSP_CR_TO_CPU)
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lri $ax0.h, #0x2000
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lr $ac0.l, @MEM_HI
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lr $ac0.m, @MEM_LO
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call do_dma
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; get address of registers and DMA them to ram
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call wait_for_dsp_mbox
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si @DMBH, #0x8888
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si @DMBL, #0xbeef
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si @DIRQ, #0x0001
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call wait_for_cpu_mbox
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lrs $ac0.m, @CMBL
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andi $ac1.m, #0x7fff
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sr @MEM_HI, $ac1.m
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sr @MEM_LO, $ac0.m
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lri $ax0.l, #REGS_BASE
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lri $ax1.l, #0 ;(DSP_CR_IMEM | DSP_CR_TO_CPU)
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lri $ax0.h, #0x80
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lr $ac0.l, @MEM_HI
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lr $ac0.m, @MEM_LO
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call do_dma
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; Read in all the registers from RAM
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lri $ar0, #REGS_BASE+1
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lrri $ar1, @$ar0
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lrri $ar2, @$ar0
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lrri $ar3, @$ar0
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lrri $ix0, @$ar0
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lrri $ix1, @$ar0
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lrri $ix2, @$ar0
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lrri $ix3, @$ar0
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lrri $wr0, @$ar0
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lrri $wr1, @$ar0
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lrri $wr2, @$ar0
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lrri $wr3, @$ar0
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lrri $st0, @$ar0
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lrri $st1, @$ar0
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lrri $st2, @$ar0
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lrri $st3, @$ar0
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lrri $ac0.h, @$ar0
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lrri $ac1.h, @$ar0
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lrri $cr, @$ar0
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lrri $sr, @$ar0
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lrri $prod.l, @$ar0
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lrri $prod.m1, @$ar0
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lrri $prod.h, @$ar0
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lrri $prod.m2, @$ar0
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lrri $ax0.l, @$ar0
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lrri $ax1.l, @$ar0
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lrri $ax0.h, @$ar0
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lrri $ax1.h, @$ar0
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lrri $ac0.l, @$ar0
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lrri $ac1.l, @$ar0
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lrri $ac0.m, @$ar0
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lrri $ac1.m, @$ar0
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lr $ar0, @REGS_BASE
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jmp start_of_test
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; This is where we jump when we're done testing, see above.
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end_of_test:
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nop
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nop
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nop
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nop
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nop
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nop
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nop
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; We just fall into a loop, playing dead until someone resets the DSP.
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dead_loop:
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jmp dead_loop
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; Utility function to do DMA.
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; ac0.l:ac0.m - external address.
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; ax0.l - address in DSP
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do_dma:
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sr @DSMAH, $ac0.l
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sr @DSMAL, $ac0.m
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sr @DSPA, $ax0.l
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sr @DSCR, $ax1.l
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sr @DSBL, $ax0.h ; This kicks off the DMA.
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; Waits for said DMA to complete by watching a bit in DSCR.
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wait_dma:
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lrs $ac1.m, @DSCR
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andcf $ac1.m, #0x0004
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jlz wait_dma
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ret
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; This waits for a mail to arrive in the DSP in-mailbox.
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wait_for_dsp_mbox:
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lrs $ac1.m, @DMBH
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andcf $ac1.m, #0x8000
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jlz wait_for_dsp_mbox
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ret
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; This waits for the CPU to grab a mail that we just sent from the DSP.
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wait_for_cpu_mbox:
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lrs $ac1.m, @CMBH
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andcf $ac1.m, #0x8000
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jlnz wait_for_cpu_mbox
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ret
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; IRQ handlers. Not entirely sure what good they do currently.
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irq0:
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lri $ac0.m, #0x0000
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jmp irq
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irq1:
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lri $ac0.m, #0x0001
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jmp irq
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irq2:
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lri $ac0.m, #0x0002
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jmp irq
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irq3:
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lri $ac0.m, #0x0003
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jmp irq
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irq4:
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lri $ac0.m, #0x0004
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jmp irq
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irq5:
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; No idea what this code is doing.
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s16
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mrr $st1, $ac0.l
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mrr $st1, $ac0.m
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clr $acc0
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mrr $ac0.m, $st1
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mrr $ac0.l, $st1
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nop ; Or why there's a nop sled here.
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nop
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nop
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nop
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nop
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nop
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rti
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lri $ac0.m, #0x0005
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jmp irq
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irq6:
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lri $ac0.m, #0x0006
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jmp irq
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irq7:
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lri $ac0.m, #0x0007
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jmp irq
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irq:
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lrs $ac1.m, @DMBH
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andcf $ac1.m, #0x8000
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jlz irq
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si @DMBH, #0x8bad
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;sr @DMBL, $wr3 ; ???
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sr @DMBL, $ac0.m ; Exception number
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si @DIRQ, #0x0001
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halt ; Through some magic this allows us to properly ack the exception in dspspy
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;rti ; allow dumping of ucodes which cause exceptions...probably not safe at all
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; DMA:s the current state of the registers back to the PowerPC. To do this,
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; it must write the contents of all regs to DRAM.
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; Unfortunately, this loop uses ar0 so it's best to use AR1 and friends for testing
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; when messing with indexing.
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send_back:
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; make state safe.
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set16
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; store registers to reg table
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sr @REGS_BASE, $ar0
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lri $ar0, #(REGS_BASE + 1)
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srri @$ar0, $ar1
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srri @$ar0, $ar2
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srri @$ar0, $ar3
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srri @$ar0, $ix0
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srri @$ar0, $ix1
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srri @$ar0, $ix2
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srri @$ar0, $ix3
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srri @$ar0, $wr0
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srri @$ar0, $wr1
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srri @$ar0, $wr2
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srri @$ar0, $wr3
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srri @$ar0, $st0
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srri @$ar0, $st1
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srri @$ar0, $st2
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srri @$ar0, $st3
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srri @$ar0, $ac0.h
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srri @$ar0, $ac1.h
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srri @$ar0, $cr
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srri @$ar0, $sr
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srri @$ar0, $prod.l
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srri @$ar0, $prod.m1
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srri @$ar0, $prod.h
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srri @$ar0, $prod.m2
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srri @$ar0, $ax0.l
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srri @$ar0, $ax1.l
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srri @$ar0, $ax0.h
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srri @$ar0, $ax1.h
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srri @$ar0, $ac0.l
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srri @$ar0, $ac1.l
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srri @$ar0, $ac0.m
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srri @$ar0, $ac1.m
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; Regs are stored. Prepare DMA.
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lri $ax0.l, #0x0000
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lri $ax1.l, #1 ;(DSP_CR_IMEM | DSP_CR_TO_CPU)
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lri $ax0.h, #0x200
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lr $ac0.l, @MEM_HI
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lr $ac0.m, @MEM_LO
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lri $ar1, #8+8
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; Now, why are we looping here?
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bloop $ar1, dma_copy
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call do_dma
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addi $ac0.m, #0x200
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mrr $ac1.m, $ax0.l
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addi $ac1.m, #0x100
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mrr $ax0.l, $ac1.m
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nop
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dma_copy:
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nop
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; Wait for the CPU to send us a mail.
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call wait_for_dsp_mbox
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si @DMBH, #0x8888
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si @DMBL, #0xfeeb
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si @DIRQ, #0x0001
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; wait for the CPU to recieve our response before we execute the next op
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call wait_for_cpu_mbox
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lrs $ac0.m, @CMBL
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andi $ac1.m, #0x7fff
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; Restore all regs again so we're ready to execute another op.
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lri $ar0, #REGS_BASE+1
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lrri $ar1, @$ar0
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lrri $ar2, @$ar0
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lrri $ar3, @$ar0
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lrri $ix0, @$ar0
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lrri $ix1, @$ar0
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lrri $ix2, @$ar0
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lrri $ix3, @$ar0
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lrri $wr0, @$ar0
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lrri $wr1, @$ar0
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lrri $wr2, @$ar0
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lrri $wr3, @$ar0
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lrri $st0, @$ar0
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lrri $st1, @$ar0
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lrri $st2, @$ar0
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lrri $st3, @$ar0
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lrri $ac0.h, @$ar0
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lrri $ac1.h, @$ar0
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lrri $cr, @$ar0
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lrri $sr, @$ar0
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lrri $prod.l, @$ar0
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lrri $prod.m1, @$ar0
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lrri $prod.h, @$ar0
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lrri $prod.m2, @$ar0
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lrri $ax0.l, @$ar0
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lrri $ax1.l, @$ar0
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lrri $ax0.h, @$ar0
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lrri $ax1.h, @$ar0
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lrri $ac0.l, @$ar0
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lrri $ac1.l, @$ar0
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lrri $ac0.m, @$ar0
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lrri $ac1.m, @$ar0
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lr $ar0, @REGS_BASE
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ret ; from send_back
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; If you are in set40 mode, use this instead of send_back if you want to stay
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; in set40 mode.
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send_back_40:
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set16
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call send_back
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set40
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ret
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; This one's odd. Doesn't look like it should work since it uses ac0.m but
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; increments acm0... (acc0)
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; -- It's ok as addis adds short immediate to mid accumulator $acD.hm
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dump_memory:
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lri $ar2, #0x0000
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lri $ac0.m, #0x1000
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lri $ar1, #0x1000
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bloop $ar1, _fill_loop2
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mrr $ar3, $ac0.m
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nx'ld : $ax0.h, $ax1.h, @$ar0
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mrr $ac1.m, $ar0
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mrr $ar0, $ar2
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srri @$ar0, $ax1.h
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mrr $ar2, $ar0
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mrr $ar0, $ac1.m
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addis $acc0, #0x1
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_fill_loop2:
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nop
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ret ; from dump_memory
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; Obviously this must be included directly before your test code
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start_of_test:
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