/* fuc microcode for gf100 PGRAPH/HUB
*
* Copyright 2011 Red Hat Inc.
*
* Permission is hereby granted, free of charge, to any person obtaining a
* copy of this software and associated documentation files (the "Software"),
* to deal in the Software without restriction, including without limitation
* the rights to use, copy, modify, merge, publish, distribute, sublicense,
* and/or sell copies of the Software, and to permit persons to whom the
* Software is furnished to do so, subject to the following conditions:
*
* The above copyright notice and this permission notice shall be included in
* all copies or substantial portions of the Software.
*
* THE SOFTWARE IS PROVIDED "AS IS", WITHOUT WARRANTY OF ANY KIND, EXPRESS OR
* IMPLIED, INCLUDING BUT NOT LIMITED TO THE WARRANTIES OF MERCHANTABILITY,
* FITNESS FOR A PARTICULAR PURPOSE AND NONINFRINGEMENT. IN NO EVENT SHALL
* THE COPYRIGHT HOLDER(S) OR AUTHOR(S) BE LIABLE FOR ANY CLAIM, DAMAGES OR
* OTHER LIABILITY, WHETHER IN AN ACTION OF CONTRACT, TORT OR OTHERWISE,
* ARISING FROM, OUT OF OR IN CONNECTION WITH THE SOFTWARE OR THE USE OR
* OTHER DEALINGS IN THE SOFTWARE.
*
* Authors: Ben Skeggs
*/
#ifdef INCLUDE_DATA
hub_mmio_list_head: .b32 #hub_mmio_list_base
hub_mmio_list_tail: .b32 #hub_mmio_list_next
gpc_count: .b32 0
rop_count: .b32 0
cmd_queue: queue_init
ctx_current: .b32 0
.align 256
chan_data:
chan_mmio_count: .b32 0
chan_mmio_address: .b32 0
.align 256
xfer_data: .skip 256
hub_mmio_list_base:
.b32 0x0417e91c // 0x17e91c, 2
hub_mmio_list_next:
#endif
#ifdef INCLUDE_CODE
// reports an exception to the host
//
// In: $r15 error code (see os.h)
//
error:
nv_iowr(NV_PGRAPH_FECS_CC_SCRATCH_VAL(5), 0, $r15)
mov $r15 1
nv_iowr(NV_PGRAPH_FECS_INTR_UP_SET, 0, $r15)
ret
// HUB fuc initialisation, executed by triggering ucode start, will
// fall through to main loop after completion.
//
// Output:
// CC_SCRATCH[0]:
// 31:31: set to signal completion
// CC_SCRATCH[1]:
// 31:0: total PGRAPH context size
//
init:
clear b32 $r0
mov $xdbase $r0
// setup stack
nv_iord($r1, NV_PGRAPH_FECS_CAPS, 0)
extr $r1 $r1 9:17
shl b32 $r1 8
mov $sp $r1
// enable fifo access
mov $r2 NV_PGRAPH_FECS_ACCESS_FIFO
nv_iowr(NV_PGRAPH_FECS_ACCESS, 0, $r2)
// setup i0 handler, and route all interrupts to it
mov $r1 #ih
mov $iv0 $r1
clear b32 $r2
nv_iowr(NV_PGRAPH_FECS_INTR_ROUTE, 0, $r2)
// route HUB_CHSW_PULSE to fuc interrupt 8
mov $r2 0x2003 // { HUB_CHSW_PULSE, ZERO } -> intr 8
nv_iowr(NV_PGRAPH_FECS_IROUTE, 0, $r2)
// not sure what these are, route them because NVIDIA does, and
// the IRQ handler will signal the host if we ever get one.. we
// may find out if/why we need to handle these if so..
//
mov $r2 0x2004 // { 0x04, ZERO } -> intr 9
nv_iowr(NV_PGRAPH_FECS_IROUTE, 1, $r2)
mov $r2 0x200b // { HUB_FIRMWARE_MTHD, ZERO } -> intr 10
nv_iowr(NV_PGRAPH_FECS_IROUTE, 2, $r2)
mov $r2 0x200c // { 0x0c, ZERO } -> intr 15
nv_iowr(NV_PGRAPH_FECS_IROUTE, 7, $r2)
// enable all INTR_UP interrupts
sub b32 $r3 $r0 1
nv_iowr(NV_PGRAPH_FECS_INTR_UP_EN, 0, $r3)
// enable fifo, ctxsw, 9, fwmthd, 15 interrupts
imm32($r2, 0x8704)
nv_iowr(NV_PGRAPH_FECS_INTR_EN_SET, 0, $r2)
// fifo level triggered, rest edge
mov $r2 NV_PGRAPH_FECS_INTR_MODE_FIFO_LEVEL
nv_iowr(NV_PGRAPH_FECS_INTR_MODE, 0, $r2)
// enable interrupts
bset $flags ie0
// fetch enabled GPC/ROP counts
nv_rd32($r14, 0x409604)
extr $r1 $r15 16:20
st b32 D[$r0 + #rop_count] $r1
and $r15 0x1f
st b32 D[$r0 + #gpc_count] $r15
// set BAR_REQMASK to GPC mask
mov $r1 1
shl b32 $r1 $r15
sub b32 $r1 1
nv_iowr(NV_PGRAPH_FECS_BAR_MASK0, 0, $r1)
nv_iowr(NV_PGRAPH_FECS_BAR_MASK1, 0, $r1)
// context size calculation, reserve first 256 bytes for use by fuc
mov $r1 256
//
mov $r15 2
call(ctx_4170s)
call(ctx_4170w)
mov $r15 0x10
call(ctx_86c)
// calculate size of mmio context data
ld b32 $r14 D[$r0 + #hub_mmio_list_head]
ld b32 $r15 D[$r0 + #hub_mmio_list_tail]
call(mmctx_size)
// set mmctx base addresses now so we don't have to do it later,
// they don't (currently) ever change
shr b32 $r4 $r1 8
nv_iowr(NV_PGRAPH_FECS_MMCTX_SAVE_SWBASE, 0, $r4)
nv_iowr(NV_PGRAPH_FECS_MMCTX_LOAD_SWBASE, 0, $r4)
add b32 $r3 0x1300
add b32 $r1 $r15
shr b32 $r15 2
nv_iowr(NV_PGRAPH_FECS_MMCTX_LOAD_COUNT, 0, $r15) // wtf??
// strands, base offset needs to be aligned to 256 bytes
shr b32 $r1 8
add b32 $r1 1
shl b32 $r1 8
mov b32 $r15 $r1
call(strand_ctx_init)
add b32 $r1 $r15
// initialise each GPC in sequence by passing in the offset of its
// context data in GPCn_CC_SCRATCH[1], and starting its FUC (which
// has previously been uploaded by the host) running.
//
// the GPC fuc init sequence will set GPCn_CC_SCRATCH[0] bit 31
// when it has completed, and return the size of its context data
// in GPCn_CC_SCRATCH[1]
//
ld b32 $r3 D[$r0 + #gpc_count]
imm32($r4, 0x502000)
init_gpc:
// setup, and start GPC ucode running
add b32 $r14 $r4 0x804
mov b32 $r15 $r1
call(nv_wr32) // CC_SCRATCH[1] = ctx offset
add b32 $r14 $r4 0x10c
clear b32 $r15
call(nv_wr32)
add b32 $r14 $r4 0x104
call(nv_wr32) // ENTRY
add b32 $r14 $r4 0x100
mov $r15 2 // CTRL_START_TRIGGER
call(nv_wr32) // CTRL
// wait for it to complete, and adjust context size
add b32 $r14 $r4 0x800
init_gpc_wait:
call(nv_rd32)
xbit $r15 $r15 31
bra e #init_gpc_wait
add b32 $r14 $r4 0x804
call(nv_rd32)
add b32 $r1 $r15
// next!
add b32 $r4 0x8000
sub b32 $r3 1
bra ne #init_gpc
//
mov $r15 0
call(ctx_86c)
mov $r15 0
call(ctx_4170s)
// save context size, and tell host we're ready
nv_iowr(NV_PGRAPH_FECS_CC_SCRATCH_VAL(1), 0, $r1)
clear b32 $r1
bset $r1 31
nv_iowr(NV_PGRAPH_FECS_CC_SCRATCH_SET(0), 0, $r1)
// Main program loop, very simple, sleeps until woken up by the interrupt
// handler, pulls a command from the queue and executes its handler
//
wait:
// sleep until we have something to do
sleep $p0
bset $flags $p0
main:
mov $r13 #cmd_queue
call(queue_get)
bra $p1 #wait
// context switch, requested by GPU?
cmpu b32 $r14 0x4001
bra ne #main_not_ctx_switch
trace_set(T_AUTO)
nv_iord($r1, NV_PGRAPH_FECS_CHAN_ADDR, 0)
nv_iord($r2, NV_PGRAPH_FECS_CHAN_NEXT, 0)
xbit $r3 $r1 31
bra e #chsw_no_prev
xbit $r3 $r2 31
bra e #chsw_prev_no_next
push $r2
mov b32 $r2 $r1
trace_set(T_SAVE)
bclr $flags $p1
bset $flags $p2
call(ctx_xfer)
trace_clr(T_SAVE);
pop $r2
trace_set(T_LOAD);
bset $flags $p1
call(ctx_xfer)
trace_clr(T_LOAD);
bra #chsw_done
chsw_prev_no_next:
push $r2
mov b32 $r2 $r1
bclr $flags $p1
bclr $flags $p2
call(ctx_xfer)
pop $r2
nv_iowr(NV_PGRAPH_FECS_CHAN_ADDR, 0, $r2)
bra #chsw_done
chsw_no_prev:
xbit $r3 $r2 31
bra e #chsw_done
bset $flags $p1
bclr $flags $p2
call(ctx_xfer)
// ack the context switch request
chsw_done:
mov $r2 NV_PGRAPH_FECS_CHSW_ACK
nv_iowr(NV_PGRAPH_FECS_CHSW, 0, $r2)
trace_clr(T_AUTO)
bra #main
// request to set current channel? (*not* a context switch)
main_not_ctx_switch:
cmpu b32 $r14 0x0001
bra ne #main_not_ctx_chan
mov b32 $r2 $r15
call(ctx_chan)
bra #main_done
// request to store current channel context?
main_not_ctx_chan:
cmpu b32 $r14 0x0002
bra ne #main_not_ctx_save
trace_set(T_SAVE)
bclr $flags $p1
bclr $flags $p2
call(ctx_xfer)
trace_clr(T_SAVE)
bra #main_done
main_not_ctx_save:
shl b32 $r15 $r14 16
or $r15 E_BAD_COMMAND
call(error)
bra #main
main_done:
clear b32 $r2
bset $r2 31
nv_iowr(NV_PGRAPH_FECS_CC_SCRATCH_SET(0), 0, $r2)
bra #main
// interrupt handler
ih:
push $r0
push $r8
mov $r8 $flags
push $r8
push $r9
push $r10
push $r11
push $r13
push $r14
push $r15
clear b32 $r0
// incoming fifo command?
nv_iord($r10, NV_PGRAPH_FECS_INTR, 0)
and $r11 $r10 NV_PGRAPH_FECS_INTR_FIFO
bra e #ih_no_fifo
// queue incoming fifo command for later processing
mov $r13 #cmd_queue
nv_iord($r14, NV_PGRAPH_FECS_FIFO_CMD, 0)
nv_iord($r15, NV_PGRAPH_FECS_FIFO_DATA, 0)
call(queue_put)
add b32 $r11 0x400
mov $r14 1
nv_iowr(NV_PGRAPH_FECS_FIFO_ACK, 0, $r14)
// context switch request?
ih_no_fifo:
and $r11 $r10 NV_PGRAPH_FECS_INTR_CHSW
bra e #ih_no_ctxsw
// enqueue a context switch for later processing
mov $r13 #cmd_queue
mov $r14 0x4001
call(queue_put)
// firmware method?
ih_no_ctxsw:
and $r11 $r10 NV_PGRAPH_FECS_INTR_FWMTHD
bra e #ih_no_fwmthd
// none we handle; report to host and ack
nv_rd32($r15, NV_PGRAPH_TRAPPED_DATA_LO)
nv_iowr(NV_PGRAPH_FECS_CC_SCRATCH_VAL(4), 0, $r15)
nv_rd32($r15, NV_PGRAPH_TRAPPED_ADDR)
nv_iowr(NV_PGRAPH_FECS_CC_SCRATCH_VAL(3), 0, $r15)
extr $r14 $r15 16:18
shl b32 $r14 $r14 2
imm32($r15, NV_PGRAPH_FE_OBJECT_TABLE(0))
add b32 $r14 $r15
call(nv_rd32)
nv_iowr(NV_PGRAPH_FECS_CC_SCRATCH_VAL(2), 0, $r15)
mov $r15 E_BAD_FWMTHD
call(error)
mov $r11 0x100
nv_wr32(0x400144, $r11)
// anything we didn't handle, bring it to the host's attention
ih_no_fwmthd:
mov $r11 0x504 // FIFO | CHSW | FWMTHD
not b32 $r11
and $r11 $r10 $r11
bra e #ih_no_other
nv_iowr(NV_PGRAPH_FECS_INTR_UP_SET, 0, $r11)
// ack, and wake up main()
ih_no_other:
nv_iowr(NV_PGRAPH_FECS_INTR_ACK, 0, $r10)
pop $r15
pop $r14
pop $r13
pop $r11
pop $r10
pop $r9
pop $r8
mov $flags $r8
pop $r8
pop $r0
bclr $flags $p0
iret
#if CHIPSET < GK100
// Not real sure, but, MEM_CMD 7 will hang forever if this isn't done
ctx_4160s:
mov $r15 1
nv_wr32(0x404160, $r15)
ctx_4160s_wait:
nv_rd32($r15, 0x404160)
xbit $r15 $r15 4
bra e #ctx_4160s_wait
ret
// Without clearing again at end of xfer, some things cause PGRAPH
// to hang with STATUS=0x00000007 until it's cleared.. fbcon can
// still function with it set however...
ctx_4160c:
clear b32 $r15
nv_wr32(0x404160, $r15)
ret
#endif
// Again, not real sure
//
// In: $r15 value to set 0x404170 to
//
ctx_4170s:
or $r15 0x10
nv_wr32(0x404170, $r15)
ret
// Waits for a ctx_4170s() call to complete
//
ctx_4170w:
nv_rd32($r15, 0x404170)
and $r15 0x10
bra ne #ctx_4170w
ret
// Disables various things, waits a bit, and re-enables them..
//
// Not sure how exactly this helps, perhaps "ENABLE" is not such a
// good description for the bits we turn off? Anyways, without this,
// funny things happen.
//
ctx_redswitch:
mov $r14 NV_PGRAPH_FECS_RED_SWITCH_ENABLE_GPC
or $r14 NV_PGRAPH_FECS_RED_SWITCH_POWER_ROP
or $r14 NV_PGRAPH_FECS_RED_SWITCH_POWER_GPC
or $r14 NV_PGRAPH_FECS_RED_SWITCH_POWER_MAIN
nv_iowr(NV_PGRAPH_FECS_RED_SWITCH, 0, $r14)
mov $r15 8
ctx_redswitch_delay:
sub b32 $r15 1
bra ne #ctx_redswitch_delay
or $r14 NV_PGRAPH_FECS_RED_SWITCH_ENABLE_ROP
or $r14 NV_PGRAPH_FECS_RED_SWITCH_ENABLE_MAIN
nv_iowr(NV_PGRAPH_FECS_RED_SWITCH, 0, $r14)
ret
// Not a clue what this is for, except that unless the value is 0x10, the
// strand context is saved (and presumably restored) incorrectly..
//
// In: $r15 value to set to (0x00/0x10 are used)
//
ctx_86c:
nv_iowr(NV_PGRAPH_FECS_UNK86C, 0, $r15)
nv_wr32(0x408a14, $r15)
nv_wr32(NV_PGRAPH_GPCX_GPCCS_UNK86C, $r15)
ret
// In: $r15 NV_PGRAPH_FECS_MEM_CMD_*
ctx_mem:
nv_iowr(NV_PGRAPH_FECS_MEM_CMD, 0, $r15)
ctx_mem_wait:
nv_iord($r15, NV_PGRAPH_FECS_MEM_CMD, 0)
or $r15 $r15
bra ne #ctx_mem_wait
ret
// ctx_load - load's a channel's ctxctl data, and selects its vm
//
// In: $r2 channel address
//
ctx_load:
trace_set(T_CHAN)
// switch to channel, somewhat magic in parts..
mov $r10 12 // DONE_UNK12
call(wait_donez)
clear b32 $r15
nv_iowr(0x409a24, 0, $r15)
nv_iowr(NV_PGRAPH_FECS_CHAN_NEXT, 0, $r2)
nv_iowr(NV_PGRAPH_FECS_MEM_CHAN, 0, $r2)
mov $r15 NV_PGRAPH_FECS_MEM_CMD_LOAD_CHAN
call(ctx_mem)
nv_iowr(NV_PGRAPH_FECS_CHAN_ADDR, 0, $r2)
// load channel header, fetch PGRAPH context pointer
mov $xtargets $r0
bclr $r2 31
shl b32 $r2 4
add b32 $r2 2
trace_set(T_LCHAN)
nv_iowr(NV_PGRAPH_FECS_MEM_BASE, 0, $r2)
imm32($r2, NV_PGRAPH_FECS_MEM_TARGET_UNK31)
or $r2 NV_PGRAPH_FECS_MEM_TARGET_AS_VRAM
nv_iowr(NV_PGRAPH_FECS_MEM_TARGET, 0, $r2)
mov $r1 0x10 // chan + 0x0210
mov $r2 #xfer_data
sethi $r2 0x00020000 // 16 bytes
xdld $r1 $r2
xdwait
trace_clr(T_LCHAN)
// update current context
ld b32 $r1 D[$r0 + #xfer_data + 4]
shl b32 $r1 24
ld b32 $r2 D[$r0 + #xfer_data + 0]
shr b32 $r2 8
or $r1 $r2
st b32 D[$r0 + #ctx_current] $r1
// set transfer base to start of context, and fetch context header
trace_set(T_LCTXH)
nv_iowr(NV_PGRAPH_FECS_MEM_BASE, 0, $r1)
mov $r2 NV_PGRAPH_FECS_MEM_TARGET_AS_VM
nv_iowr(NV_PGRAPH_FECS_MEM_TARGET, 0, $r2)
mov $r1 #chan_data
sethi $r1 0x00060000 // 256 bytes
xdld $r0 $r1
xdwait
trace_clr(T_LCTXH)
trace_clr(T_CHAN)
ret
// ctx_chan - handler for HUB_SET_CHAN command, will set a channel as
// the active channel for ctxctl, but not actually transfer
// any context data. intended for use only during initial
// context construction.
//
// In: $r2 channel address
//
ctx_chan:
#if CHIPSET < GK100
call(ctx_4160s)
#endif
call(ctx_load)
mov $r10 12 // DONE_UNK12
call(wait_donez)
mov $r15 5 // MEM_CMD 5 ???
call(ctx_mem)
#if CHIPSET < GK100
call(ctx_4160c)
#endif
ret
// Execute per-context state overrides list
//
// Only executed on the first load of a channel. Might want to look into
// removing this and having the host directly modify the channel's context
// to change this state... The nouveau DRM already builds this list as
// it's definitely needed for NVIDIA's, so we may as well use it for now
//
// Input: $r1 mmio list length
//
ctx_mmio_exec:
// set transfer base to be the mmio list
ld b32 $r3 D[$r0 + #chan_mmio_address]
nv_iowr(NV_PGRAPH_FECS_MEM_BASE, 0, $r3)
clear b32 $r3
ctx_mmio_loop:
// fetch next 256 bytes of mmio list if necessary
and $r4 $r3 0xff
bra ne #ctx_mmio_pull
mov $r5 #xfer_data
sethi $r5 0x00060000 // 256 bytes
xdld $r3 $r5
xdwait
// execute a single list entry
ctx_mmio_pull:
ld b32 $r14 D[$r4 + #xfer_data + 0x00]
ld b32 $r15 D[$r4 + #xfer_data + 0x04]
call(nv_wr32)
// next!
add b32 $r3 8
sub b32 $r1 1
bra ne #ctx_mmio_loop
// set transfer base back to the current context
ctx_mmio_done:
ld b32 $r3 D[$r0 + #ctx_current]
nv_iowr(NV_PGRAPH_FECS_MEM_BASE, 0, $r3)
// disable the mmio list now, we don't need/want to execute it again
st b32 D[$r0 + #chan_mmio_count] $r0
mov $r1 #chan_data
sethi $r1 0x00060000 // 256 bytes
xdst $r0 $r1
xdwait
ret
// Transfer HUB context data between GPU and storage area
//
// In: $r2 channel address
// $p1 clear on save, set on load
// $p2 set if opposite direction done/will be done, so:
// on save it means: "a load will follow this save"
// on load it means: "a save preceeded this load"
//
ctx_xfer:
// according to mwk, some kind of wait for idle
mov $r14 4
nv_iowr(0x409c08, 0, $r14)
ctx_xfer_idle:
nv_iord($r14, 0x409c00, 0)
and $r14 0x2000
bra ne #ctx_xfer_idle
bra not $p1 #ctx_xfer_pre
bra $p2 #ctx_xfer_pre_load
ctx_xfer_pre:
mov $r15 0x10
call(ctx_86c)
#if CHIPSET < GK100
call(ctx_4160s)
#endif
bra not $p1 #ctx_xfer_exec
ctx_xfer_pre_load:
mov $r15 2
call(ctx_4170s)
call(ctx_4170w)
call(ctx_redswitch)
clear b32 $r15
call(ctx_4170s)
call(ctx_load)
// fetch context pointer, and initiate xfer on all GPCs
ctx_xfer_exec:
ld b32 $r1 D[$r0 + #ctx_current]
clear b32 $r2
nv_iowr(NV_PGRAPH_FECS_BAR, 0, $r2)
nv_wr32(0x41a500, $r1) // GPC_BCAST_WRCMD_DATA = ctx pointer
xbit $r15 $flags $p1
xbit $r2 $flags $p2
shl b32 $r2 1
or $r15 $r2
nv_wr32(0x41a504, $r15) // GPC_BCAST_WRCMD_CMD = GPC_XFER(type)
// strands
call(strand_pre)
clear b32 $r2
nv_iowr(NV_PGRAPH_FECS_STRAND_SELECT, 0x3f, $r2)
xbit $r2 $flags $p1 // SAVE/LOAD
add b32 $r2 NV_PGRAPH_FECS_STRAND_CMD_SAVE
nv_iowr(NV_PGRAPH_FECS_STRAND_CMD, 0x3f, $r2)
// mmio context
xbit $r10 $flags $p1 // direction
or $r10 6 // first, last
mov $r11 0 // base = 0
ld b32 $r12 D[$r0 + #hub_mmio_list_head]
ld b32 $r13 D[$r0 + #hub_mmio_list_tail]
mov $r14 0 // not multi
call(mmctx_xfer)
// wait for GPCs to all complete
mov $r10 8 // DONE_BAR
call(wait_doneo)
// wait for strand xfer to complete
call(strand_wait)
// post-op
bra $p1 #ctx_xfer_post
mov $r10 12 // DONE_UNK12
call(wait_donez)
mov $r15 5 // MEM_CMD 5 ???
call(ctx_mem)
bra $p2 #ctx_xfer_done
ctx_xfer_post:
mov $r15 2
call(ctx_4170s)
clear b32 $r15
call(ctx_86c)
call(strand_post)
call(ctx_4170w)
clear b32 $r15
call(ctx_4170s)
bra not $p1 #ctx_xfer_no_post_mmio
ld b32 $r1 D[$r0 + #chan_mmio_count]
or $r1 $r1
bra e #ctx_xfer_no_post_mmio
call(ctx_mmio_exec)
ctx_xfer_no_post_mmio:
#if CHIPSET < GK100
call(ctx_4160c)
#endif
ctx_xfer_done:
ret
#endif