1
linux/arch/powerpc/platforms/cell/spufs/switch.c
Masato Noguchi 9476141c18 [POWERPC] spufs: don't set reserved bits in spu interrupt status
This changes the spu context switch code to not write to reserved bits
of spu interrupt status register.
The architecture book says the reserved fields should be set to zero.

Signed-off-by: Masato Noguchi <Masato.Noguchi@jp.sony.com>
Signed-off-by: Jeremy Kerr <jk@ozlabs.org>
Signed-off-by: Paul Mackerras <paulus@samba.org>
2007-12-21 19:46:20 +11:00

2190 lines
62 KiB
C

/*
* spu_switch.c
*
* (C) Copyright IBM Corp. 2005
*
* Author: Mark Nutter <mnutter@us.ibm.com>
*
* Host-side part of SPU context switch sequence outlined in
* Synergistic Processor Element, Book IV.
*
* A fully premptive switch of an SPE is very expensive in terms
* of time and system resources. SPE Book IV indicates that SPE
* allocation should follow a "serially reusable device" model,
* in which the SPE is assigned a task until it completes. When
* this is not possible, this sequence may be used to premptively
* save, and then later (optionally) restore the context of a
* program executing on an SPE.
*
*
* This program is free software; you can redistribute it and/or modify
* it under the terms of the GNU General Public License as published by
* the Free Software Foundation; either version 2, or (at your option)
* any later version.
*
* This program is distributed in the hope that it will be useful,
* but WITHOUT ANY WARRANTY; without even the implied warranty of
* MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the
* GNU General Public License for more details.
*
* You should have received a copy of the GNU General Public License
* along with this program; if not, write to the Free Software
* Foundation, Inc., 675 Mass Ave, Cambridge, MA 02139, USA.
*/
#include <linux/module.h>
#include <linux/errno.h>
#include <linux/sched.h>
#include <linux/kernel.h>
#include <linux/mm.h>
#include <linux/vmalloc.h>
#include <linux/smp.h>
#include <linux/stddef.h>
#include <linux/unistd.h>
#include <asm/io.h>
#include <asm/spu.h>
#include <asm/spu_priv1.h>
#include <asm/spu_csa.h>
#include <asm/mmu_context.h>
#include "spufs.h"
#include "spu_save_dump.h"
#include "spu_restore_dump.h"
#if 0
#define POLL_WHILE_TRUE(_c) { \
do { \
} while (_c); \
}
#else
#define RELAX_SPIN_COUNT 1000
#define POLL_WHILE_TRUE(_c) { \
do { \
int _i; \
for (_i=0; _i<RELAX_SPIN_COUNT && (_c); _i++) { \
cpu_relax(); \
} \
if (unlikely(_c)) yield(); \
else break; \
} while (_c); \
}
#endif /* debug */
#define POLL_WHILE_FALSE(_c) POLL_WHILE_TRUE(!(_c))
static inline void acquire_spu_lock(struct spu *spu)
{
/* Save, Step 1:
* Restore, Step 1:
* Acquire SPU-specific mutual exclusion lock.
* TBD.
*/
}
static inline void release_spu_lock(struct spu *spu)
{
/* Restore, Step 76:
* Release SPU-specific mutual exclusion lock.
* TBD.
*/
}
static inline int check_spu_isolate(struct spu_state *csa, struct spu *spu)
{
struct spu_problem __iomem *prob = spu->problem;
u32 isolate_state;
/* Save, Step 2:
* Save, Step 6:
* If SPU_Status[E,L,IS] any field is '1', this
* SPU is in isolate state and cannot be context
* saved at this time.
*/
isolate_state = SPU_STATUS_ISOLATED_STATE |
SPU_STATUS_ISOLATED_LOAD_STATUS | SPU_STATUS_ISOLATED_EXIT_STATUS;
return (in_be32(&prob->spu_status_R) & isolate_state) ? 1 : 0;
}
static inline void disable_interrupts(struct spu_state *csa, struct spu *spu)
{
/* Save, Step 3:
* Restore, Step 2:
* Save INT_Mask_class0 in CSA.
* Write INT_MASK_class0 with value of 0.
* Save INT_Mask_class1 in CSA.
* Write INT_MASK_class1 with value of 0.
* Save INT_Mask_class2 in CSA.
* Write INT_MASK_class2 with value of 0.
*/
spin_lock_irq(&spu->register_lock);
if (csa) {
csa->priv1.int_mask_class0_RW = spu_int_mask_get(spu, 0);
csa->priv1.int_mask_class1_RW = spu_int_mask_get(spu, 1);
csa->priv1.int_mask_class2_RW = spu_int_mask_get(spu, 2);
}
spu_int_mask_set(spu, 0, 0ul);
spu_int_mask_set(spu, 1, 0ul);
spu_int_mask_set(spu, 2, 0ul);
eieio();
spin_unlock_irq(&spu->register_lock);
}
static inline void set_watchdog_timer(struct spu_state *csa, struct spu *spu)
{
/* Save, Step 4:
* Restore, Step 25.
* Set a software watchdog timer, which specifies the
* maximum allowable time for a context save sequence.
*
* For present, this implementation will not set a global
* watchdog timer, as virtualization & variable system load
* may cause unpredictable execution times.
*/
}
static inline void inhibit_user_access(struct spu_state *csa, struct spu *spu)
{
/* Save, Step 5:
* Restore, Step 3:
* Inhibit user-space access (if provided) to this
* SPU by unmapping the virtual pages assigned to
* the SPU memory-mapped I/O (MMIO) for problem
* state. TBD.
*/
}
static inline void set_switch_pending(struct spu_state *csa, struct spu *spu)
{
/* Save, Step 7:
* Restore, Step 5:
* Set a software context switch pending flag.
*/
set_bit(SPU_CONTEXT_SWITCH_PENDING, &spu->flags);
mb();
}
static inline void save_mfc_cntl(struct spu_state *csa, struct spu *spu)
{
struct spu_priv2 __iomem *priv2 = spu->priv2;
/* Save, Step 8:
* Suspend DMA and save MFC_CNTL.
*/
switch (in_be64(&priv2->mfc_control_RW) &
MFC_CNTL_SUSPEND_DMA_STATUS_MASK) {
case MFC_CNTL_SUSPEND_IN_PROGRESS:
POLL_WHILE_FALSE((in_be64(&priv2->mfc_control_RW) &
MFC_CNTL_SUSPEND_DMA_STATUS_MASK) ==
MFC_CNTL_SUSPEND_COMPLETE);
/* fall through */
case MFC_CNTL_SUSPEND_COMPLETE:
if (csa) {
csa->priv2.mfc_control_RW =
MFC_CNTL_SUSPEND_MASK |
MFC_CNTL_SUSPEND_DMA_QUEUE;
}
break;
case MFC_CNTL_NORMAL_DMA_QUEUE_OPERATION:
out_be64(&priv2->mfc_control_RW, MFC_CNTL_SUSPEND_DMA_QUEUE);
POLL_WHILE_FALSE((in_be64(&priv2->mfc_control_RW) &
MFC_CNTL_SUSPEND_DMA_STATUS_MASK) ==
MFC_CNTL_SUSPEND_COMPLETE);
if (csa) {
csa->priv2.mfc_control_RW = 0;
}
break;
}
}
static inline void save_spu_runcntl(struct spu_state *csa, struct spu *spu)
{
struct spu_problem __iomem *prob = spu->problem;
/* Save, Step 9:
* Save SPU_Runcntl in the CSA. This value contains
* the "Application Desired State".
*/
csa->prob.spu_runcntl_RW = in_be32(&prob->spu_runcntl_RW);
}
static inline void save_mfc_sr1(struct spu_state *csa, struct spu *spu)
{
/* Save, Step 10:
* Save MFC_SR1 in the CSA.
*/
csa->priv1.mfc_sr1_RW = spu_mfc_sr1_get(spu);
}
static inline void save_spu_status(struct spu_state *csa, struct spu *spu)
{
struct spu_problem __iomem *prob = spu->problem;
/* Save, Step 11:
* Read SPU_Status[R], and save to CSA.
*/
if ((in_be32(&prob->spu_status_R) & SPU_STATUS_RUNNING) == 0) {
csa->prob.spu_status_R = in_be32(&prob->spu_status_R);
} else {
u32 stopped;
out_be32(&prob->spu_runcntl_RW, SPU_RUNCNTL_STOP);
eieio();
POLL_WHILE_TRUE(in_be32(&prob->spu_status_R) &
SPU_STATUS_RUNNING);
stopped =
SPU_STATUS_INVALID_INSTR | SPU_STATUS_SINGLE_STEP |
SPU_STATUS_STOPPED_BY_HALT | SPU_STATUS_STOPPED_BY_STOP;
if ((in_be32(&prob->spu_status_R) & stopped) == 0)
csa->prob.spu_status_R = SPU_STATUS_RUNNING;
else
csa->prob.spu_status_R = in_be32(&prob->spu_status_R);
}
}
static inline void save_mfc_decr(struct spu_state *csa, struct spu *spu)
{
struct spu_priv2 __iomem *priv2 = spu->priv2;
/* Save, Step 12:
* Read MFC_CNTL[Ds]. Update saved copy of
* CSA.MFC_CNTL[Ds].
*/
csa->priv2.mfc_control_RW |=
in_be64(&priv2->mfc_control_RW) & MFC_CNTL_DECREMENTER_RUNNING;
}
static inline void halt_mfc_decr(struct spu_state *csa, struct spu *spu)
{
struct spu_priv2 __iomem *priv2 = spu->priv2;
/* Save, Step 13:
* Write MFC_CNTL[Dh] set to a '1' to halt
* the decrementer.
*/
out_be64(&priv2->mfc_control_RW,
MFC_CNTL_DECREMENTER_HALTED | MFC_CNTL_SUSPEND_MASK);
eieio();
}
static inline void save_timebase(struct spu_state *csa, struct spu *spu)
{
/* Save, Step 14:
* Read PPE Timebase High and Timebase low registers
* and save in CSA. TBD.
*/
csa->suspend_time = get_cycles();
}
static inline void remove_other_spu_access(struct spu_state *csa,
struct spu *spu)
{
/* Save, Step 15:
* Remove other SPU access to this SPU by unmapping
* this SPU's pages from their address space. TBD.
*/
}
static inline void do_mfc_mssync(struct spu_state *csa, struct spu *spu)
{
struct spu_problem __iomem *prob = spu->problem;
/* Save, Step 16:
* Restore, Step 11.
* Write SPU_MSSync register. Poll SPU_MSSync[P]
* for a value of 0.
*/
out_be64(&prob->spc_mssync_RW, 1UL);
POLL_WHILE_TRUE(in_be64(&prob->spc_mssync_RW) & MS_SYNC_PENDING);
}
static inline void issue_mfc_tlbie(struct spu_state *csa, struct spu *spu)
{
/* Save, Step 17:
* Restore, Step 12.
* Restore, Step 48.
* Write TLB_Invalidate_Entry[IS,VPN,L,Lp]=0 register.
* Then issue a PPE sync instruction.
*/
spu_tlb_invalidate(spu);
mb();
}
static inline void handle_pending_interrupts(struct spu_state *csa,
struct spu *spu)
{
/* Save, Step 18:
* Handle any pending interrupts from this SPU
* here. This is OS or hypervisor specific. One
* option is to re-enable interrupts to handle any
* pending interrupts, with the interrupt handlers
* recognizing the software Context Switch Pending
* flag, to ensure the SPU execution or MFC command
* queue is not restarted. TBD.
*/
}
static inline void save_mfc_queues(struct spu_state *csa, struct spu *spu)
{
struct spu_priv2 __iomem *priv2 = spu->priv2;
int i;
/* Save, Step 19:
* If MFC_Cntl[Se]=0 then save
* MFC command queues.
*/
if ((in_be64(&priv2->mfc_control_RW) & MFC_CNTL_DMA_QUEUES_EMPTY) == 0) {
for (i = 0; i < 8; i++) {
csa->priv2.puq[i].mfc_cq_data0_RW =
in_be64(&priv2->puq[i].mfc_cq_data0_RW);
csa->priv2.puq[i].mfc_cq_data1_RW =
in_be64(&priv2->puq[i].mfc_cq_data1_RW);
csa->priv2.puq[i].mfc_cq_data2_RW =
in_be64(&priv2->puq[i].mfc_cq_data2_RW);
csa->priv2.puq[i].mfc_cq_data3_RW =
in_be64(&priv2->puq[i].mfc_cq_data3_RW);
}
for (i = 0; i < 16; i++) {
csa->priv2.spuq[i].mfc_cq_data0_RW =
in_be64(&priv2->spuq[i].mfc_cq_data0_RW);
csa->priv2.spuq[i].mfc_cq_data1_RW =
in_be64(&priv2->spuq[i].mfc_cq_data1_RW);
csa->priv2.spuq[i].mfc_cq_data2_RW =
in_be64(&priv2->spuq[i].mfc_cq_data2_RW);
csa->priv2.spuq[i].mfc_cq_data3_RW =
in_be64(&priv2->spuq[i].mfc_cq_data3_RW);
}
}
}
static inline void save_ppu_querymask(struct spu_state *csa, struct spu *spu)
{
struct spu_problem __iomem *prob = spu->problem;
/* Save, Step 20:
* Save the PPU_QueryMask register
* in the CSA.
*/
csa->prob.dma_querymask_RW = in_be32(&prob->dma_querymask_RW);
}
static inline void save_ppu_querytype(struct spu_state *csa, struct spu *spu)
{
struct spu_problem __iomem *prob = spu->problem;
/* Save, Step 21:
* Save the PPU_QueryType register
* in the CSA.
*/
csa->prob.dma_querytype_RW = in_be32(&prob->dma_querytype_RW);
}
static inline void save_ppu_tagstatus(struct spu_state *csa, struct spu *spu)
{
struct spu_problem __iomem *prob = spu->problem;
/* Save the Prxy_TagStatus register in the CSA.
*
* It is unnecessary to restore dma_tagstatus_R, however,
* dma_tagstatus_R in the CSA is accessed via backing_ops, so
* we must save it.
*/
csa->prob.dma_tagstatus_R = in_be32(&prob->dma_tagstatus_R);
}
static inline void save_mfc_csr_tsq(struct spu_state *csa, struct spu *spu)
{
struct spu_priv2 __iomem *priv2 = spu->priv2;
/* Save, Step 22:
* Save the MFC_CSR_TSQ register
* in the LSCSA.
*/
csa->priv2.spu_tag_status_query_RW =
in_be64(&priv2->spu_tag_status_query_RW);
}
static inline void save_mfc_csr_cmd(struct spu_state *csa, struct spu *spu)
{
struct spu_priv2 __iomem *priv2 = spu->priv2;
/* Save, Step 23:
* Save the MFC_CSR_CMD1 and MFC_CSR_CMD2
* registers in the CSA.
*/
csa->priv2.spu_cmd_buf1_RW = in_be64(&priv2->spu_cmd_buf1_RW);
csa->priv2.spu_cmd_buf2_RW = in_be64(&priv2->spu_cmd_buf2_RW);
}
static inline void save_mfc_csr_ato(struct spu_state *csa, struct spu *spu)
{
struct spu_priv2 __iomem *priv2 = spu->priv2;
/* Save, Step 24:
* Save the MFC_CSR_ATO register in
* the CSA.
*/
csa->priv2.spu_atomic_status_RW = in_be64(&priv2->spu_atomic_status_RW);
}
static inline void save_mfc_tclass_id(struct spu_state *csa, struct spu *spu)
{
/* Save, Step 25:
* Save the MFC_TCLASS_ID register in
* the CSA.
*/
csa->priv1.mfc_tclass_id_RW = spu_mfc_tclass_id_get(spu);
}
static inline void set_mfc_tclass_id(struct spu_state *csa, struct spu *spu)
{
/* Save, Step 26:
* Restore, Step 23.
* Write the MFC_TCLASS_ID register with
* the value 0x10000000.
*/
spu_mfc_tclass_id_set(spu, 0x10000000);
eieio();
}
static inline void purge_mfc_queue(struct spu_state *csa, struct spu *spu)
{
struct spu_priv2 __iomem *priv2 = spu->priv2;
/* Save, Step 27:
* Restore, Step 14.
* Write MFC_CNTL[Pc]=1 (purge queue).
*/
out_be64(&priv2->mfc_control_RW, MFC_CNTL_PURGE_DMA_REQUEST);
eieio();
}
static inline void wait_purge_complete(struct spu_state *csa, struct spu *spu)
{
struct spu_priv2 __iomem *priv2 = spu->priv2;
/* Save, Step 28:
* Poll MFC_CNTL[Ps] until value '11' is read
* (purge complete).
*/
POLL_WHILE_FALSE((in_be64(&priv2->mfc_control_RW) &
MFC_CNTL_PURGE_DMA_STATUS_MASK) ==
MFC_CNTL_PURGE_DMA_COMPLETE);
}
static inline void setup_mfc_sr1(struct spu_state *csa, struct spu *spu)
{
/* Save, Step 30:
* Restore, Step 18:
* Write MFC_SR1 with MFC_SR1[D=0,S=1] and
* MFC_SR1[TL,R,Pr,T] set correctly for the
* OS specific environment.
*
* Implementation note: The SPU-side code
* for save/restore is privileged, so the
* MFC_SR1[Pr] bit is not set.
*
*/
spu_mfc_sr1_set(spu, (MFC_STATE1_MASTER_RUN_CONTROL_MASK |
MFC_STATE1_RELOCATE_MASK |
MFC_STATE1_BUS_TLBIE_MASK));
}
static inline void save_spu_npc(struct spu_state *csa, struct spu *spu)
{
struct spu_problem __iomem *prob = spu->problem;
/* Save, Step 31:
* Save SPU_NPC in the CSA.
*/
csa->prob.spu_npc_RW = in_be32(&prob->spu_npc_RW);
}
static inline void save_spu_privcntl(struct spu_state *csa, struct spu *spu)
{
struct spu_priv2 __iomem *priv2 = spu->priv2;
/* Save, Step 32:
* Save SPU_PrivCntl in the CSA.
*/
csa->priv2.spu_privcntl_RW = in_be64(&priv2->spu_privcntl_RW);
}
static inline void reset_spu_privcntl(struct spu_state *csa, struct spu *spu)
{
struct spu_priv2 __iomem *priv2 = spu->priv2;
/* Save, Step 33:
* Restore, Step 16:
* Write SPU_PrivCntl[S,Le,A] fields reset to 0.
*/
out_be64(&priv2->spu_privcntl_RW, 0UL);
eieio();
}
static inline void save_spu_lslr(struct spu_state *csa, struct spu *spu)
{
struct spu_priv2 __iomem *priv2 = spu->priv2;
/* Save, Step 34:
* Save SPU_LSLR in the CSA.
*/
csa->priv2.spu_lslr_RW = in_be64(&priv2->spu_lslr_RW);
}
static inline void reset_spu_lslr(struct spu_state *csa, struct spu *spu)
{
struct spu_priv2 __iomem *priv2 = spu->priv2;
/* Save, Step 35:
* Restore, Step 17.
* Reset SPU_LSLR.
*/
out_be64(&priv2->spu_lslr_RW, LS_ADDR_MASK);
eieio();
}
static inline void save_spu_cfg(struct spu_state *csa, struct spu *spu)
{
struct spu_priv2 __iomem *priv2 = spu->priv2;
/* Save, Step 36:
* Save SPU_Cfg in the CSA.
*/
csa->priv2.spu_cfg_RW = in_be64(&priv2->spu_cfg_RW);
}
static inline void save_pm_trace(struct spu_state *csa, struct spu *spu)
{
/* Save, Step 37:
* Save PM_Trace_Tag_Wait_Mask in the CSA.
* Not performed by this implementation.
*/
}
static inline void save_mfc_rag(struct spu_state *csa, struct spu *spu)
{
/* Save, Step 38:
* Save RA_GROUP_ID register and the
* RA_ENABLE reigster in the CSA.
*/
csa->priv1.resource_allocation_groupID_RW =
spu_resource_allocation_groupID_get(spu);
csa->priv1.resource_allocation_enable_RW =
spu_resource_allocation_enable_get(spu);
}
static inline void save_ppu_mb_stat(struct spu_state *csa, struct spu *spu)
{
struct spu_problem __iomem *prob = spu->problem;
/* Save, Step 39:
* Save MB_Stat register in the CSA.
*/
csa->prob.mb_stat_R = in_be32(&prob->mb_stat_R);
}
static inline void save_ppu_mb(struct spu_state *csa, struct spu *spu)
{
struct spu_problem __iomem *prob = spu->problem;
/* Save, Step 40:
* Save the PPU_MB register in the CSA.
*/
csa->prob.pu_mb_R = in_be32(&prob->pu_mb_R);
}
static inline void save_ppuint_mb(struct spu_state *csa, struct spu *spu)
{
struct spu_priv2 __iomem *priv2 = spu->priv2;
/* Save, Step 41:
* Save the PPUINT_MB register in the CSA.
*/
csa->priv2.puint_mb_R = in_be64(&priv2->puint_mb_R);
}
static inline void save_ch_part1(struct spu_state *csa, struct spu *spu)
{
struct spu_priv2 __iomem *priv2 = spu->priv2;
u64 idx, ch_indices[] = { 0UL, 3UL, 4UL, 24UL, 25UL, 27UL };
int i;
/* Save, Step 42:
*/
/* Save CH 1, without channel count */
out_be64(&priv2->spu_chnlcntptr_RW, 1);
csa->spu_chnldata_RW[1] = in_be64(&priv2->spu_chnldata_RW);
/* Save the following CH: [0,3,4,24,25,27] */
for (i = 0; i < ARRAY_SIZE(ch_indices); i++) {
idx = ch_indices[i];
out_be64(&priv2->spu_chnlcntptr_RW, idx);
eieio();
csa->spu_chnldata_RW[idx] = in_be64(&priv2->spu_chnldata_RW);
csa->spu_chnlcnt_RW[idx] = in_be64(&priv2->spu_chnlcnt_RW);
out_be64(&priv2->spu_chnldata_RW, 0UL);
out_be64(&priv2->spu_chnlcnt_RW, 0UL);
eieio();
}
}
static inline void save_spu_mb(struct spu_state *csa, struct spu *spu)
{
struct spu_priv2 __iomem *priv2 = spu->priv2;
int i;
/* Save, Step 43:
* Save SPU Read Mailbox Channel.
*/
out_be64(&priv2->spu_chnlcntptr_RW, 29UL);
eieio();
csa->spu_chnlcnt_RW[29] = in_be64(&priv2->spu_chnlcnt_RW);
for (i = 0; i < 4; i++) {
csa->spu_mailbox_data[i] = in_be64(&priv2->spu_chnldata_RW);
}
out_be64(&priv2->spu_chnlcnt_RW, 0UL);
eieio();
}
static inline void save_mfc_cmd(struct spu_state *csa, struct spu *spu)
{
struct spu_priv2 __iomem *priv2 = spu->priv2;
/* Save, Step 44:
* Save MFC_CMD Channel.
*/
out_be64(&priv2->spu_chnlcntptr_RW, 21UL);
eieio();
csa->spu_chnlcnt_RW[21] = in_be64(&priv2->spu_chnlcnt_RW);
eieio();
}
static inline void reset_ch(struct spu_state *csa, struct spu *spu)
{
struct spu_priv2 __iomem *priv2 = spu->priv2;
u64 ch_indices[4] = { 21UL, 23UL, 28UL, 30UL };
u64 ch_counts[4] = { 16UL, 1UL, 1UL, 1UL };
u64 idx;
int i;
/* Save, Step 45:
* Reset the following CH: [21, 23, 28, 30]
*/
for (i = 0; i < 4; i++) {
idx = ch_indices[i];
out_be64(&priv2->spu_chnlcntptr_RW, idx);
eieio();
out_be64(&priv2->spu_chnlcnt_RW, ch_counts[i]);
eieio();
}
}
static inline void resume_mfc_queue(struct spu_state *csa, struct spu *spu)
{
struct spu_priv2 __iomem *priv2 = spu->priv2;
/* Save, Step 46:
* Restore, Step 25.
* Write MFC_CNTL[Sc]=0 (resume queue processing).
*/
out_be64(&priv2->mfc_control_RW, MFC_CNTL_RESUME_DMA_QUEUE);
}
static inline void setup_mfc_slbs(struct spu_state *csa, struct spu *spu,
unsigned int *code, int code_size)
{
/* Save, Step 47:
* Restore, Step 30.
* If MFC_SR1[R]=1, write 0 to SLB_Invalidate_All
* register, then initialize SLB_VSID and SLB_ESID
* to provide access to SPU context save code and
* LSCSA.
*
* This implementation places both the context
* switch code and LSCSA in kernel address space.
*
* Further this implementation assumes that the
* MFC_SR1[R]=1 (in other words, assume that
* translation is desired by OS environment).
*/
spu_invalidate_slbs(spu);
spu_setup_kernel_slbs(spu, csa->lscsa, code, code_size);
}
static inline void set_switch_active(struct spu_state *csa, struct spu *spu)
{
/* Save, Step 48:
* Restore, Step 23.
* Change the software context switch pending flag
* to context switch active.
*/
set_bit(SPU_CONTEXT_SWITCH_ACTIVE, &spu->flags);
clear_bit(SPU_CONTEXT_SWITCH_PENDING, &spu->flags);
mb();
}
static inline void enable_interrupts(struct spu_state *csa, struct spu *spu)
{
unsigned long class1_mask = CLASS1_ENABLE_SEGMENT_FAULT_INTR |
CLASS1_ENABLE_STORAGE_FAULT_INTR;
/* Save, Step 49:
* Restore, Step 22:
* Reset and then enable interrupts, as
* needed by OS.
*
* This implementation enables only class1
* (translation) interrupts.
*/
spin_lock_irq(&spu->register_lock);
spu_int_stat_clear(spu, 0, CLASS0_INTR_MASK);
spu_int_stat_clear(spu, 1, CLASS1_INTR_MASK);
spu_int_stat_clear(spu, 2, CLASS2_INTR_MASK);
spu_int_mask_set(spu, 0, 0ul);
spu_int_mask_set(spu, 1, class1_mask);
spu_int_mask_set(spu, 2, 0ul);
spin_unlock_irq(&spu->register_lock);
}
static inline int send_mfc_dma(struct spu *spu, unsigned long ea,
unsigned int ls_offset, unsigned int size,
unsigned int tag, unsigned int rclass,
unsigned int cmd)
{
struct spu_problem __iomem *prob = spu->problem;
union mfc_tag_size_class_cmd command;
unsigned int transfer_size;
volatile unsigned int status = 0x0;
while (size > 0) {
transfer_size =
(size > MFC_MAX_DMA_SIZE) ? MFC_MAX_DMA_SIZE : size;
command.u.mfc_size = transfer_size;
command.u.mfc_tag = tag;
command.u.mfc_rclassid = rclass;
command.u.mfc_cmd = cmd;
do {
out_be32(&prob->mfc_lsa_W, ls_offset);
out_be64(&prob->mfc_ea_W, ea);
out_be64(&prob->mfc_union_W.all64, command.all64);
status =
in_be32(&prob->mfc_union_W.by32.mfc_class_cmd32);
if (unlikely(status & 0x2)) {
cpu_relax();
}
} while (status & 0x3);
size -= transfer_size;
ea += transfer_size;
ls_offset += transfer_size;
}
return 0;
}
static inline void save_ls_16kb(struct spu_state *csa, struct spu *spu)
{
unsigned long addr = (unsigned long)&csa->lscsa->ls[0];
unsigned int ls_offset = 0x0;
unsigned int size = 16384;
unsigned int tag = 0;
unsigned int rclass = 0;
unsigned int cmd = MFC_PUT_CMD;
/* Save, Step 50:
* Issue a DMA command to copy the first 16K bytes
* of local storage to the CSA.
*/
send_mfc_dma(spu, addr, ls_offset, size, tag, rclass, cmd);
}
static inline void set_spu_npc(struct spu_state *csa, struct spu *spu)
{
struct spu_problem __iomem *prob = spu->problem;
/* Save, Step 51:
* Restore, Step 31.
* Write SPU_NPC[IE]=0 and SPU_NPC[LSA] to entry
* point address of context save code in local
* storage.
*
* This implementation uses SPU-side save/restore
* programs with entry points at LSA of 0.
*/
out_be32(&prob->spu_npc_RW, 0);
eieio();
}
static inline void set_signot1(struct spu_state *csa, struct spu *spu)
{
struct spu_problem __iomem *prob = spu->problem;
union {
u64 ull;
u32 ui[2];
} addr64;
/* Save, Step 52:
* Restore, Step 32:
* Write SPU_Sig_Notify_1 register with upper 32-bits
* of the CSA.LSCSA effective address.
*/
addr64.ull = (u64) csa->lscsa;
out_be32(&prob->signal_notify1, addr64.ui[0]);
eieio();
}
static inline void set_signot2(struct spu_state *csa, struct spu *spu)
{
struct spu_problem __iomem *prob = spu->problem;
union {
u64 ull;
u32 ui[2];
} addr64;
/* Save, Step 53:
* Restore, Step 33:
* Write SPU_Sig_Notify_2 register with lower 32-bits
* of the CSA.LSCSA effective address.
*/
addr64.ull = (u64) csa->lscsa;
out_be32(&prob->signal_notify2, addr64.ui[1]);
eieio();
}
static inline void send_save_code(struct spu_state *csa, struct spu *spu)
{
unsigned long addr = (unsigned long)&spu_save_code[0];
unsigned int ls_offset = 0x0;
unsigned int size = sizeof(spu_save_code);
unsigned int tag = 0;
unsigned int rclass = 0;
unsigned int cmd = MFC_GETFS_CMD;
/* Save, Step 54:
* Issue a DMA command to copy context save code
* to local storage and start SPU.
*/
send_mfc_dma(spu, addr, ls_offset, size, tag, rclass, cmd);
}
static inline void set_ppu_querymask(struct spu_state *csa, struct spu *spu)
{
struct spu_problem __iomem *prob = spu->problem;
/* Save, Step 55:
* Restore, Step 38.
* Write PPU_QueryMask=1 (enable Tag Group 0)
* and issue eieio instruction.
*/
out_be32(&prob->dma_querymask_RW, MFC_TAGID_TO_TAGMASK(0));
eieio();
}
static inline void wait_tag_complete(struct spu_state *csa, struct spu *spu)
{
struct spu_problem __iomem *prob = spu->problem;
u32 mask = MFC_TAGID_TO_TAGMASK(0);
unsigned long flags;
/* Save, Step 56:
* Restore, Step 39.
* Restore, Step 39.
* Restore, Step 46.
* Poll PPU_TagStatus[gn] until 01 (Tag group 0 complete)
* or write PPU_QueryType[TS]=01 and wait for Tag Group
* Complete Interrupt. Write INT_Stat_Class0 or
* INT_Stat_Class2 with value of 'handled'.
*/
POLL_WHILE_FALSE(in_be32(&prob->dma_tagstatus_R) & mask);
local_irq_save(flags);
spu_int_stat_clear(spu, 0, CLASS0_INTR_MASK);
spu_int_stat_clear(spu, 2, CLASS2_INTR_MASK);
local_irq_restore(flags);
}
static inline void wait_spu_stopped(struct spu_state *csa, struct spu *spu)
{
struct spu_problem __iomem *prob = spu->problem;
unsigned long flags;
/* Save, Step 57:
* Restore, Step 40.
* Poll until SPU_Status[R]=0 or wait for SPU Class 0
* or SPU Class 2 interrupt. Write INT_Stat_class0
* or INT_Stat_class2 with value of handled.
*/
POLL_WHILE_TRUE(in_be32(&prob->spu_status_R) & SPU_STATUS_RUNNING);
local_irq_save(flags);
spu_int_stat_clear(spu, 0, CLASS0_INTR_MASK);
spu_int_stat_clear(spu, 2, CLASS2_INTR_MASK);
local_irq_restore(flags);
}
static inline int check_save_status(struct spu_state *csa, struct spu *spu)
{
struct spu_problem __iomem *prob = spu->problem;
u32 complete;
/* Save, Step 54:
* If SPU_Status[P]=1 and SPU_Status[SC] = "success",
* context save succeeded, otherwise context save
* failed.
*/
complete = ((SPU_SAVE_COMPLETE << SPU_STOP_STATUS_SHIFT) |
SPU_STATUS_STOPPED_BY_STOP);
return (in_be32(&prob->spu_status_R) != complete) ? 1 : 0;
}
static inline void terminate_spu_app(struct spu_state *csa, struct spu *spu)
{
/* Restore, Step 4:
* If required, notify the "using application" that
* the SPU task has been terminated. TBD.
*/
}
static inline void suspend_mfc_and_halt_decr(struct spu_state *csa,
struct spu *spu)
{
struct spu_priv2 __iomem *priv2 = spu->priv2;
/* Restore, Step 7:
* Write MFC_Cntl[Dh,Sc,Sm]='1','1','0' to suspend
* the queue and halt the decrementer.
*/
out_be64(&priv2->mfc_control_RW, MFC_CNTL_SUSPEND_DMA_QUEUE |
MFC_CNTL_DECREMENTER_HALTED);
eieio();
}
static inline void wait_suspend_mfc_complete(struct spu_state *csa,
struct spu *spu)
{
struct spu_priv2 __iomem *priv2 = spu->priv2;
/* Restore, Step 8:
* Restore, Step 47.
* Poll MFC_CNTL[Ss] until 11 is returned.
*/
POLL_WHILE_FALSE((in_be64(&priv2->mfc_control_RW) &
MFC_CNTL_SUSPEND_DMA_STATUS_MASK) ==
MFC_CNTL_SUSPEND_COMPLETE);
}
static inline int suspend_spe(struct spu_state *csa, struct spu *spu)
{
struct spu_problem __iomem *prob = spu->problem;
/* Restore, Step 9:
* If SPU_Status[R]=1, stop SPU execution
* and wait for stop to complete.
*
* Returns 1 if SPU_Status[R]=1 on entry.
* 0 otherwise
*/
if (in_be32(&prob->spu_status_R) & SPU_STATUS_RUNNING) {
if (in_be32(&prob->spu_status_R) &
SPU_STATUS_ISOLATED_EXIT_STATUS) {
POLL_WHILE_TRUE(in_be32(&prob->spu_status_R) &
SPU_STATUS_RUNNING);
}
if ((in_be32(&prob->spu_status_R) &
SPU_STATUS_ISOLATED_LOAD_STATUS)
|| (in_be32(&prob->spu_status_R) &
SPU_STATUS_ISOLATED_STATE)) {
out_be32(&prob->spu_runcntl_RW, SPU_RUNCNTL_STOP);
eieio();
POLL_WHILE_TRUE(in_be32(&prob->spu_status_R) &
SPU_STATUS_RUNNING);
out_be32(&prob->spu_runcntl_RW, 0x2);
eieio();
POLL_WHILE_TRUE(in_be32(&prob->spu_status_R) &
SPU_STATUS_RUNNING);
}
if (in_be32(&prob->spu_status_R) &
SPU_STATUS_WAITING_FOR_CHANNEL) {
out_be32(&prob->spu_runcntl_RW, SPU_RUNCNTL_STOP);
eieio();
POLL_WHILE_TRUE(in_be32(&prob->spu_status_R) &
SPU_STATUS_RUNNING);
}
return 1;
}
return 0;
}
static inline void clear_spu_status(struct spu_state *csa, struct spu *spu)
{
struct spu_problem __iomem *prob = spu->problem;
/* Restore, Step 10:
* If SPU_Status[R]=0 and SPU_Status[E,L,IS]=1,
* release SPU from isolate state.
*/
if (!(in_be32(&prob->spu_status_R) & SPU_STATUS_RUNNING)) {
if (in_be32(&prob->spu_status_R) &
SPU_STATUS_ISOLATED_EXIT_STATUS) {
spu_mfc_sr1_set(spu,
MFC_STATE1_MASTER_RUN_CONTROL_MASK);
eieio();
out_be32(&prob->spu_runcntl_RW, SPU_RUNCNTL_RUNNABLE);
eieio();
POLL_WHILE_TRUE(in_be32(&prob->spu_status_R) &
SPU_STATUS_RUNNING);
}
if ((in_be32(&prob->spu_status_R) &
SPU_STATUS_ISOLATED_LOAD_STATUS)
|| (in_be32(&prob->spu_status_R) &
SPU_STATUS_ISOLATED_STATE)) {
spu_mfc_sr1_set(spu,
MFC_STATE1_MASTER_RUN_CONTROL_MASK);
eieio();
out_be32(&prob->spu_runcntl_RW, 0x2);
eieio();
POLL_WHILE_TRUE(in_be32(&prob->spu_status_R) &
SPU_STATUS_RUNNING);
}
}
}
static inline void reset_ch_part1(struct spu_state *csa, struct spu *spu)
{
struct spu_priv2 __iomem *priv2 = spu->priv2;
u64 ch_indices[] = { 0UL, 3UL, 4UL, 24UL, 25UL, 27UL };
u64 idx;
int i;
/* Restore, Step 20:
*/
/* Reset CH 1 */
out_be64(&priv2->spu_chnlcntptr_RW, 1);
out_be64(&priv2->spu_chnldata_RW, 0UL);
/* Reset the following CH: [0,3,4,24,25,27] */
for (i = 0; i < ARRAY_SIZE(ch_indices); i++) {
idx = ch_indices[i];
out_be64(&priv2->spu_chnlcntptr_RW, idx);
eieio();
out_be64(&priv2->spu_chnldata_RW, 0UL);
out_be64(&priv2->spu_chnlcnt_RW, 0UL);
eieio();
}
}
static inline void reset_ch_part2(struct spu_state *csa, struct spu *spu)
{
struct spu_priv2 __iomem *priv2 = spu->priv2;
u64 ch_indices[5] = { 21UL, 23UL, 28UL, 29UL, 30UL };
u64 ch_counts[5] = { 16UL, 1UL, 1UL, 0UL, 1UL };
u64 idx;
int i;
/* Restore, Step 21:
* Reset the following CH: [21, 23, 28, 29, 30]
*/
for (i = 0; i < 5; i++) {
idx = ch_indices[i];
out_be64(&priv2->spu_chnlcntptr_RW, idx);
eieio();
out_be64(&priv2->spu_chnlcnt_RW, ch_counts[i]);
eieio();
}
}
static inline void setup_spu_status_part1(struct spu_state *csa,
struct spu *spu)
{
u32 status_P = SPU_STATUS_STOPPED_BY_STOP;
u32 status_I = SPU_STATUS_INVALID_INSTR;
u32 status_H = SPU_STATUS_STOPPED_BY_HALT;
u32 status_S = SPU_STATUS_SINGLE_STEP;
u32 status_S_I = SPU_STATUS_SINGLE_STEP | SPU_STATUS_INVALID_INSTR;
u32 status_S_P = SPU_STATUS_SINGLE_STEP | SPU_STATUS_STOPPED_BY_STOP;
u32 status_P_H = SPU_STATUS_STOPPED_BY_HALT |SPU_STATUS_STOPPED_BY_STOP;
u32 status_P_I = SPU_STATUS_STOPPED_BY_STOP |SPU_STATUS_INVALID_INSTR;
u32 status_code;
/* Restore, Step 27:
* If the CSA.SPU_Status[I,S,H,P]=1 then add the correct
* instruction sequence to the end of the SPU based restore
* code (after the "context restored" stop and signal) to
* restore the correct SPU status.
*
* NOTE: Rather than modifying the SPU executable, we
* instead add a new 'stopped_status' field to the
* LSCSA. The SPU-side restore reads this field and
* takes the appropriate action when exiting.
*/
status_code =
(csa->prob.spu_status_R >> SPU_STOP_STATUS_SHIFT) & 0xFFFF;
if ((csa->prob.spu_status_R & status_P_I) == status_P_I) {
/* SPU_Status[P,I]=1 - Illegal Instruction followed
* by Stop and Signal instruction, followed by 'br -4'.
*
*/
csa->lscsa->stopped_status.slot[0] = SPU_STOPPED_STATUS_P_I;
csa->lscsa->stopped_status.slot[1] = status_code;
} else if ((csa->prob.spu_status_R & status_P_H) == status_P_H) {
/* SPU_Status[P,H]=1 - Halt Conditional, followed
* by Stop and Signal instruction, followed by
* 'br -4'.
*/
csa->lscsa->stopped_status.slot[0] = SPU_STOPPED_STATUS_P_H;
csa->lscsa->stopped_status.slot[1] = status_code;
} else if ((csa->prob.spu_status_R & status_S_P) == status_S_P) {
/* SPU_Status[S,P]=1 - Stop and Signal instruction
* followed by 'br -4'.
*/
csa->lscsa->stopped_status.slot[0] = SPU_STOPPED_STATUS_S_P;
csa->lscsa->stopped_status.slot[1] = status_code;
} else if ((csa->prob.spu_status_R & status_S_I) == status_S_I) {
/* SPU_Status[S,I]=1 - Illegal instruction followed
* by 'br -4'.
*/
csa->lscsa->stopped_status.slot[0] = SPU_STOPPED_STATUS_S_I;
csa->lscsa->stopped_status.slot[1] = status_code;
} else if ((csa->prob.spu_status_R & status_P) == status_P) {
/* SPU_Status[P]=1 - Stop and Signal instruction
* followed by 'br -4'.
*/
csa->lscsa->stopped_status.slot[0] = SPU_STOPPED_STATUS_P;
csa->lscsa->stopped_status.slot[1] = status_code;
} else if ((csa->prob.spu_status_R & status_H) == status_H) {
/* SPU_Status[H]=1 - Halt Conditional, followed
* by 'br -4'.
*/
csa->lscsa->stopped_status.slot[0] = SPU_STOPPED_STATUS_H;
} else if ((csa->prob.spu_status_R & status_S) == status_S) {
/* SPU_Status[S]=1 - Two nop instructions.
*/
csa->lscsa->stopped_status.slot[0] = SPU_STOPPED_STATUS_S;
} else if ((csa->prob.spu_status_R & status_I) == status_I) {
/* SPU_Status[I]=1 - Illegal instruction followed
* by 'br -4'.
*/
csa->lscsa->stopped_status.slot[0] = SPU_STOPPED_STATUS_I;
}
}
static inline void setup_spu_status_part2(struct spu_state *csa,
struct spu *spu)
{
u32 mask;
/* Restore, Step 28:
* If the CSA.SPU_Status[I,S,H,P,R]=0 then
* add a 'br *' instruction to the end of
* the SPU based restore code.
*
* NOTE: Rather than modifying the SPU executable, we
* instead add a new 'stopped_status' field to the
* LSCSA. The SPU-side restore reads this field and
* takes the appropriate action when exiting.
*/
mask = SPU_STATUS_INVALID_INSTR |
SPU_STATUS_SINGLE_STEP |
SPU_STATUS_STOPPED_BY_HALT |
SPU_STATUS_STOPPED_BY_STOP | SPU_STATUS_RUNNING;
if (!(csa->prob.spu_status_R & mask)) {
csa->lscsa->stopped_status.slot[0] = SPU_STOPPED_STATUS_R;
}
}
static inline void restore_mfc_rag(struct spu_state *csa, struct spu *spu)
{
/* Restore, Step 29:
* Restore RA_GROUP_ID register and the
* RA_ENABLE reigster from the CSA.
*/
spu_resource_allocation_groupID_set(spu,
csa->priv1.resource_allocation_groupID_RW);
spu_resource_allocation_enable_set(spu,
csa->priv1.resource_allocation_enable_RW);
}
static inline void send_restore_code(struct spu_state *csa, struct spu *spu)
{
unsigned long addr = (unsigned long)&spu_restore_code[0];
unsigned int ls_offset = 0x0;
unsigned int size = sizeof(spu_restore_code);
unsigned int tag = 0;
unsigned int rclass = 0;
unsigned int cmd = MFC_GETFS_CMD;
/* Restore, Step 37:
* Issue MFC DMA command to copy context
* restore code to local storage.
*/
send_mfc_dma(spu, addr, ls_offset, size, tag, rclass, cmd);
}
static inline void setup_decr(struct spu_state *csa, struct spu *spu)
{
/* Restore, Step 34:
* If CSA.MFC_CNTL[Ds]=1 (decrementer was
* running) then adjust decrementer, set
* decrementer running status in LSCSA,
* and set decrementer "wrapped" status
* in LSCSA.
*/
if (csa->priv2.mfc_control_RW & MFC_CNTL_DECREMENTER_RUNNING) {
cycles_t resume_time = get_cycles();
cycles_t delta_time = resume_time - csa->suspend_time;
csa->lscsa->decr_status.slot[0] = SPU_DECR_STATUS_RUNNING;
if (csa->lscsa->decr.slot[0] < delta_time) {
csa->lscsa->decr_status.slot[0] |=
SPU_DECR_STATUS_WRAPPED;
}
csa->lscsa->decr.slot[0] -= delta_time;
} else {
csa->lscsa->decr_status.slot[0] = 0;
}
}
static inline void setup_ppu_mb(struct spu_state *csa, struct spu *spu)
{
/* Restore, Step 35:
* Copy the CSA.PU_MB data into the LSCSA.
*/
csa->lscsa->ppu_mb.slot[0] = csa->prob.pu_mb_R;
}
static inline void setup_ppuint_mb(struct spu_state *csa, struct spu *spu)
{
/* Restore, Step 36:
* Copy the CSA.PUINT_MB data into the LSCSA.
*/
csa->lscsa->ppuint_mb.slot[0] = csa->priv2.puint_mb_R;
}
static inline int check_restore_status(struct spu_state *csa, struct spu *spu)
{
struct spu_problem __iomem *prob = spu->problem;
u32 complete;
/* Restore, Step 40:
* If SPU_Status[P]=1 and SPU_Status[SC] = "success",
* context restore succeeded, otherwise context restore
* failed.
*/
complete = ((SPU_RESTORE_COMPLETE << SPU_STOP_STATUS_SHIFT) |
SPU_STATUS_STOPPED_BY_STOP);
return (in_be32(&prob->spu_status_R) != complete) ? 1 : 0;
}
static inline void restore_spu_privcntl(struct spu_state *csa, struct spu *spu)
{
struct spu_priv2 __iomem *priv2 = spu->priv2;
/* Restore, Step 41:
* Restore SPU_PrivCntl from the CSA.
*/
out_be64(&priv2->spu_privcntl_RW, csa->priv2.spu_privcntl_RW);
eieio();
}
static inline void restore_status_part1(struct spu_state *csa, struct spu *spu)
{
struct spu_problem __iomem *prob = spu->problem;
u32 mask;
/* Restore, Step 42:
* If any CSA.SPU_Status[I,S,H,P]=1, then
* restore the error or single step state.
*/
mask = SPU_STATUS_INVALID_INSTR |
SPU_STATUS_SINGLE_STEP |
SPU_STATUS_STOPPED_BY_HALT | SPU_STATUS_STOPPED_BY_STOP;
if (csa->prob.spu_status_R & mask) {
out_be32(&prob->spu_runcntl_RW, SPU_RUNCNTL_RUNNABLE);
eieio();
POLL_WHILE_TRUE(in_be32(&prob->spu_status_R) &
SPU_STATUS_RUNNING);
}
}
static inline void restore_status_part2(struct spu_state *csa, struct spu *spu)
{
struct spu_problem __iomem *prob = spu->problem;
u32 mask;
/* Restore, Step 43:
* If all CSA.SPU_Status[I,S,H,P,R]=0 then write
* SPU_RunCntl[R0R1]='01', wait for SPU_Status[R]=1,
* then write '00' to SPU_RunCntl[R0R1] and wait
* for SPU_Status[R]=0.
*/
mask = SPU_STATUS_INVALID_INSTR |
SPU_STATUS_SINGLE_STEP |
SPU_STATUS_STOPPED_BY_HALT |
SPU_STATUS_STOPPED_BY_STOP | SPU_STATUS_RUNNING;
if (!(csa->prob.spu_status_R & mask)) {
out_be32(&prob->spu_runcntl_RW, SPU_RUNCNTL_RUNNABLE);
eieio();
POLL_WHILE_FALSE(in_be32(&prob->spu_status_R) &
SPU_STATUS_RUNNING);
out_be32(&prob->spu_runcntl_RW, SPU_RUNCNTL_STOP);
eieio();
POLL_WHILE_TRUE(in_be32(&prob->spu_status_R) &
SPU_STATUS_RUNNING);
}
}
static inline void restore_ls_16kb(struct spu_state *csa, struct spu *spu)
{
unsigned long addr = (unsigned long)&csa->lscsa->ls[0];
unsigned int ls_offset = 0x0;
unsigned int size = 16384;
unsigned int tag = 0;
unsigned int rclass = 0;
unsigned int cmd = MFC_GET_CMD;
/* Restore, Step 44:
* Issue a DMA command to restore the first
* 16kb of local storage from CSA.
*/
send_mfc_dma(spu, addr, ls_offset, size, tag, rclass, cmd);
}
static inline void suspend_mfc(struct spu_state *csa, struct spu *spu)
{
struct spu_priv2 __iomem *priv2 = spu->priv2;
/* Restore, Step 47.
* Write MFC_Cntl[Sc,Sm]='1','0' to suspend
* the queue.
*/
out_be64(&priv2->mfc_control_RW, MFC_CNTL_SUSPEND_DMA_QUEUE);
eieio();
}
static inline void clear_interrupts(struct spu_state *csa, struct spu *spu)
{
/* Restore, Step 49:
* Write INT_MASK_class0 with value of 0.
* Write INT_MASK_class1 with value of 0.
* Write INT_MASK_class2 with value of 0.
* Write INT_STAT_class0 with value of -1.
* Write INT_STAT_class1 with value of -1.
* Write INT_STAT_class2 with value of -1.
*/
spin_lock_irq(&spu->register_lock);
spu_int_mask_set(spu, 0, 0ul);
spu_int_mask_set(spu, 1, 0ul);
spu_int_mask_set(spu, 2, 0ul);
spu_int_stat_clear(spu, 0, CLASS0_INTR_MASK);
spu_int_stat_clear(spu, 1, CLASS1_INTR_MASK);
spu_int_stat_clear(spu, 2, CLASS2_INTR_MASK);
spin_unlock_irq(&spu->register_lock);
}
static inline void restore_mfc_queues(struct spu_state *csa, struct spu *spu)
{
struct spu_priv2 __iomem *priv2 = spu->priv2;
int i;
/* Restore, Step 50:
* If MFC_Cntl[Se]!=0 then restore
* MFC command queues.
*/
if ((csa->priv2.mfc_control_RW & MFC_CNTL_DMA_QUEUES_EMPTY_MASK) == 0) {
for (i = 0; i < 8; i++) {
out_be64(&priv2->puq[i].mfc_cq_data0_RW,
csa->priv2.puq[i].mfc_cq_data0_RW);
out_be64(&priv2->puq[i].mfc_cq_data1_RW,
csa->priv2.puq[i].mfc_cq_data1_RW);
out_be64(&priv2->puq[i].mfc_cq_data2_RW,
csa->priv2.puq[i].mfc_cq_data2_RW);
out_be64(&priv2->puq[i].mfc_cq_data3_RW,
csa->priv2.puq[i].mfc_cq_data3_RW);
}
for (i = 0; i < 16; i++) {
out_be64(&priv2->spuq[i].mfc_cq_data0_RW,
csa->priv2.spuq[i].mfc_cq_data0_RW);
out_be64(&priv2->spuq[i].mfc_cq_data1_RW,
csa->priv2.spuq[i].mfc_cq_data1_RW);
out_be64(&priv2->spuq[i].mfc_cq_data2_RW,
csa->priv2.spuq[i].mfc_cq_data2_RW);
out_be64(&priv2->spuq[i].mfc_cq_data3_RW,
csa->priv2.spuq[i].mfc_cq_data3_RW);
}
}
eieio();
}
static inline void restore_ppu_querymask(struct spu_state *csa, struct spu *spu)
{
struct spu_problem __iomem *prob = spu->problem;
/* Restore, Step 51:
* Restore the PPU_QueryMask register from CSA.
*/
out_be32(&prob->dma_querymask_RW, csa->prob.dma_querymask_RW);
eieio();
}
static inline void restore_ppu_querytype(struct spu_state *csa, struct spu *spu)
{
struct spu_problem __iomem *prob = spu->problem;
/* Restore, Step 52:
* Restore the PPU_QueryType register from CSA.
*/
out_be32(&prob->dma_querytype_RW, csa->prob.dma_querytype_RW);
eieio();
}
static inline void restore_mfc_csr_tsq(struct spu_state *csa, struct spu *spu)
{
struct spu_priv2 __iomem *priv2 = spu->priv2;
/* Restore, Step 53:
* Restore the MFC_CSR_TSQ register from CSA.
*/
out_be64(&priv2->spu_tag_status_query_RW,
csa->priv2.spu_tag_status_query_RW);
eieio();
}
static inline void restore_mfc_csr_cmd(struct spu_state *csa, struct spu *spu)
{
struct spu_priv2 __iomem *priv2 = spu->priv2;
/* Restore, Step 54:
* Restore the MFC_CSR_CMD1 and MFC_CSR_CMD2
* registers from CSA.
*/
out_be64(&priv2->spu_cmd_buf1_RW, csa->priv2.spu_cmd_buf1_RW);
out_be64(&priv2->spu_cmd_buf2_RW, csa->priv2.spu_cmd_buf2_RW);
eieio();
}
static inline void restore_mfc_csr_ato(struct spu_state *csa, struct spu *spu)
{
struct spu_priv2 __iomem *priv2 = spu->priv2;
/* Restore, Step 55:
* Restore the MFC_CSR_ATO register from CSA.
*/
out_be64(&priv2->spu_atomic_status_RW, csa->priv2.spu_atomic_status_RW);
}
static inline void restore_mfc_tclass_id(struct spu_state *csa, struct spu *spu)
{
/* Restore, Step 56:
* Restore the MFC_TCLASS_ID register from CSA.
*/
spu_mfc_tclass_id_set(spu, csa->priv1.mfc_tclass_id_RW);
eieio();
}
static inline void set_llr_event(struct spu_state *csa, struct spu *spu)
{
u64 ch0_cnt, ch0_data;
u64 ch1_data;
/* Restore, Step 57:
* Set the Lock Line Reservation Lost Event by:
* 1. OR CSA.SPU_Event_Status with bit 21 (Lr) set to 1.
* 2. If CSA.SPU_Channel_0_Count=0 and
* CSA.SPU_Wr_Event_Mask[Lr]=1 and
* CSA.SPU_Event_Status[Lr]=0 then set
* CSA.SPU_Event_Status_Count=1.
*/
ch0_cnt = csa->spu_chnlcnt_RW[0];
ch0_data = csa->spu_chnldata_RW[0];
ch1_data = csa->spu_chnldata_RW[1];
csa->spu_chnldata_RW[0] |= MFC_LLR_LOST_EVENT;
if ((ch0_cnt == 0) && !(ch0_data & MFC_LLR_LOST_EVENT) &&
(ch1_data & MFC_LLR_LOST_EVENT)) {
csa->spu_chnlcnt_RW[0] = 1;
}
}
static inline void restore_decr_wrapped(struct spu_state *csa, struct spu *spu)
{
/* Restore, Step 58:
* If the status of the CSA software decrementer
* "wrapped" flag is set, OR in a '1' to
* CSA.SPU_Event_Status[Tm].
*/
if (!(csa->lscsa->decr_status.slot[0] & SPU_DECR_STATUS_WRAPPED))
return;
if ((csa->spu_chnlcnt_RW[0] == 0) &&
(csa->spu_chnldata_RW[1] & 0x20) &&
!(csa->spu_chnldata_RW[0] & 0x20))
csa->spu_chnlcnt_RW[0] = 1;
csa->spu_chnldata_RW[0] |= 0x20;
}
static inline void restore_ch_part1(struct spu_state *csa, struct spu *spu)
{
struct spu_priv2 __iomem *priv2 = spu->priv2;
u64 idx, ch_indices[] = { 0UL, 3UL, 4UL, 24UL, 25UL, 27UL };
int i;
/* Restore, Step 59:
* Restore the following CH: [0,3,4,24,25,27]
*/
for (i = 0; i < ARRAY_SIZE(ch_indices); i++) {
idx = ch_indices[i];
out_be64(&priv2->spu_chnlcntptr_RW, idx);
eieio();
out_be64(&priv2->spu_chnldata_RW, csa->spu_chnldata_RW[idx]);
out_be64(&priv2->spu_chnlcnt_RW, csa->spu_chnlcnt_RW[idx]);
eieio();
}
}
static inline void restore_ch_part2(struct spu_state *csa, struct spu *spu)
{
struct spu_priv2 __iomem *priv2 = spu->priv2;
u64 ch_indices[3] = { 9UL, 21UL, 23UL };
u64 ch_counts[3] = { 1UL, 16UL, 1UL };
u64 idx;
int i;
/* Restore, Step 60:
* Restore the following CH: [9,21,23].
*/
ch_counts[0] = 1UL;
ch_counts[1] = csa->spu_chnlcnt_RW[21];
ch_counts[2] = 1UL;
for (i = 0; i < 3; i++) {
idx = ch_indices[i];
out_be64(&priv2->spu_chnlcntptr_RW, idx);
eieio();
out_be64(&priv2->spu_chnlcnt_RW, ch_counts[i]);
eieio();
}
}
static inline void restore_spu_lslr(struct spu_state *csa, struct spu *spu)
{
struct spu_priv2 __iomem *priv2 = spu->priv2;
/* Restore, Step 61:
* Restore the SPU_LSLR register from CSA.
*/
out_be64(&priv2->spu_lslr_RW, csa->priv2.spu_lslr_RW);
eieio();
}
static inline void restore_spu_cfg(struct spu_state *csa, struct spu *spu)
{
struct spu_priv2 __iomem *priv2 = spu->priv2;
/* Restore, Step 62:
* Restore the SPU_Cfg register from CSA.
*/
out_be64(&priv2->spu_cfg_RW, csa->priv2.spu_cfg_RW);
eieio();
}
static inline void restore_pm_trace(struct spu_state *csa, struct spu *spu)
{
/* Restore, Step 63:
* Restore PM_Trace_Tag_Wait_Mask from CSA.
* Not performed by this implementation.
*/
}
static inline void restore_spu_npc(struct spu_state *csa, struct spu *spu)
{
struct spu_problem __iomem *prob = spu->problem;
/* Restore, Step 64:
* Restore SPU_NPC from CSA.
*/
out_be32(&prob->spu_npc_RW, csa->prob.spu_npc_RW);
eieio();
}
static inline void restore_spu_mb(struct spu_state *csa, struct spu *spu)
{
struct spu_priv2 __iomem *priv2 = spu->priv2;
int i;
/* Restore, Step 65:
* Restore MFC_RdSPU_MB from CSA.
*/
out_be64(&priv2->spu_chnlcntptr_RW, 29UL);
eieio();
out_be64(&priv2->spu_chnlcnt_RW, csa->spu_chnlcnt_RW[29]);
for (i = 0; i < 4; i++) {
out_be64(&priv2->spu_chnldata_RW, csa->spu_mailbox_data[i]);
}
eieio();
}
static inline void check_ppu_mb_stat(struct spu_state *csa, struct spu *spu)
{
struct spu_problem __iomem *prob = spu->problem;
u32 dummy = 0;
/* Restore, Step 66:
* If CSA.MB_Stat[P]=0 (mailbox empty) then
* read from the PPU_MB register.
*/
if ((csa->prob.mb_stat_R & 0xFF) == 0) {
dummy = in_be32(&prob->pu_mb_R);
eieio();
}
}
static inline void check_ppuint_mb_stat(struct spu_state *csa, struct spu *spu)
{
struct spu_priv2 __iomem *priv2 = spu->priv2;
u64 dummy = 0UL;
/* Restore, Step 66:
* If CSA.MB_Stat[I]=0 (mailbox empty) then
* read from the PPUINT_MB register.
*/
if ((csa->prob.mb_stat_R & 0xFF0000) == 0) {
dummy = in_be64(&priv2->puint_mb_R);
eieio();
spu_int_stat_clear(spu, 2, CLASS2_ENABLE_MAILBOX_INTR);
eieio();
}
}
static inline void restore_mfc_sr1(struct spu_state *csa, struct spu *spu)
{
/* Restore, Step 69:
* Restore the MFC_SR1 register from CSA.
*/
spu_mfc_sr1_set(spu, csa->priv1.mfc_sr1_RW);
eieio();
}
static inline void restore_other_spu_access(struct spu_state *csa,
struct spu *spu)
{
/* Restore, Step 70:
* Restore other SPU mappings to this SPU. TBD.
*/
}
static inline void restore_spu_runcntl(struct spu_state *csa, struct spu *spu)
{
struct spu_problem __iomem *prob = spu->problem;
/* Restore, Step 71:
* If CSA.SPU_Status[R]=1 then write
* SPU_RunCntl[R0R1]='01'.
*/
if (csa->prob.spu_status_R & SPU_STATUS_RUNNING) {
out_be32(&prob->spu_runcntl_RW, SPU_RUNCNTL_RUNNABLE);
eieio();
}
}
static inline void restore_mfc_cntl(struct spu_state *csa, struct spu *spu)
{
struct spu_priv2 __iomem *priv2 = spu->priv2;
/* Restore, Step 72:
* Restore the MFC_CNTL register for the CSA.
*/
out_be64(&priv2->mfc_control_RW, csa->priv2.mfc_control_RW);
eieio();
/*
* FIXME: this is to restart a DMA that we were processing
* before the save. better remember the fault information
* in the csa instead.
*/
if ((csa->priv2.mfc_control_RW & MFC_CNTL_SUSPEND_DMA_QUEUE_MASK)) {
out_be64(&priv2->mfc_control_RW, MFC_CNTL_RESTART_DMA_COMMAND);
eieio();
}
}
static inline void enable_user_access(struct spu_state *csa, struct spu *spu)
{
/* Restore, Step 73:
* Enable user-space access (if provided) to this
* SPU by mapping the virtual pages assigned to
* the SPU memory-mapped I/O (MMIO) for problem
* state. TBD.
*/
}
static inline void reset_switch_active(struct spu_state *csa, struct spu *spu)
{
/* Restore, Step 74:
* Reset the "context switch active" flag.
*/
clear_bit(SPU_CONTEXT_SWITCH_ACTIVE, &spu->flags);
mb();
}
static inline void reenable_interrupts(struct spu_state *csa, struct spu *spu)
{
/* Restore, Step 75:
* Re-enable SPU interrupts.
*/
spin_lock_irq(&spu->register_lock);
spu_int_mask_set(spu, 0, csa->priv1.int_mask_class0_RW);
spu_int_mask_set(spu, 1, csa->priv1.int_mask_class1_RW);
spu_int_mask_set(spu, 2, csa->priv1.int_mask_class2_RW);
spin_unlock_irq(&spu->register_lock);
}
static int quiece_spu(struct spu_state *prev, struct spu *spu)
{
/*
* Combined steps 2-18 of SPU context save sequence, which
* quiesce the SPU state (disable SPU execution, MFC command
* queues, decrementer, SPU interrupts, etc.).
*
* Returns 0 on success.
* 2 if failed step 2.
* 6 if failed step 6.
*/
if (check_spu_isolate(prev, spu)) { /* Step 2. */
return 2;
}
disable_interrupts(prev, spu); /* Step 3. */
set_watchdog_timer(prev, spu); /* Step 4. */
inhibit_user_access(prev, spu); /* Step 5. */
if (check_spu_isolate(prev, spu)) { /* Step 6. */
return 6;
}
set_switch_pending(prev, spu); /* Step 7. */
save_mfc_cntl(prev, spu); /* Step 8. */
save_spu_runcntl(prev, spu); /* Step 9. */
save_mfc_sr1(prev, spu); /* Step 10. */
save_spu_status(prev, spu); /* Step 11. */
save_mfc_decr(prev, spu); /* Step 12. */
halt_mfc_decr(prev, spu); /* Step 13. */
save_timebase(prev, spu); /* Step 14. */
remove_other_spu_access(prev, spu); /* Step 15. */
do_mfc_mssync(prev, spu); /* Step 16. */
issue_mfc_tlbie(prev, spu); /* Step 17. */
handle_pending_interrupts(prev, spu); /* Step 18. */
return 0;
}
static void save_csa(struct spu_state *prev, struct spu *spu)
{
/*
* Combine steps 19-44 of SPU context save sequence, which
* save regions of the privileged & problem state areas.
*/
save_mfc_queues(prev, spu); /* Step 19. */
save_ppu_querymask(prev, spu); /* Step 20. */
save_ppu_querytype(prev, spu); /* Step 21. */
save_ppu_tagstatus(prev, spu); /* NEW. */
save_mfc_csr_tsq(prev, spu); /* Step 22. */
save_mfc_csr_cmd(prev, spu); /* Step 23. */
save_mfc_csr_ato(prev, spu); /* Step 24. */
save_mfc_tclass_id(prev, spu); /* Step 25. */
set_mfc_tclass_id(prev, spu); /* Step 26. */
purge_mfc_queue(prev, spu); /* Step 27. */
wait_purge_complete(prev, spu); /* Step 28. */
setup_mfc_sr1(prev, spu); /* Step 30. */
save_spu_npc(prev, spu); /* Step 31. */
save_spu_privcntl(prev, spu); /* Step 32. */
reset_spu_privcntl(prev, spu); /* Step 33. */
save_spu_lslr(prev, spu); /* Step 34. */
reset_spu_lslr(prev, spu); /* Step 35. */
save_spu_cfg(prev, spu); /* Step 36. */
save_pm_trace(prev, spu); /* Step 37. */
save_mfc_rag(prev, spu); /* Step 38. */
save_ppu_mb_stat(prev, spu); /* Step 39. */
save_ppu_mb(prev, spu); /* Step 40. */
save_ppuint_mb(prev, spu); /* Step 41. */
save_ch_part1(prev, spu); /* Step 42. */
save_spu_mb(prev, spu); /* Step 43. */
save_mfc_cmd(prev, spu); /* Step 44. */
reset_ch(prev, spu); /* Step 45. */
}
static void save_lscsa(struct spu_state *prev, struct spu *spu)
{
/*
* Perform steps 46-57 of SPU context save sequence,
* which save regions of the local store and register
* file.
*/
resume_mfc_queue(prev, spu); /* Step 46. */
/* Step 47. */
setup_mfc_slbs(prev, spu, spu_save_code, sizeof(spu_save_code));
set_switch_active(prev, spu); /* Step 48. */
enable_interrupts(prev, spu); /* Step 49. */
save_ls_16kb(prev, spu); /* Step 50. */
set_spu_npc(prev, spu); /* Step 51. */
set_signot1(prev, spu); /* Step 52. */
set_signot2(prev, spu); /* Step 53. */
send_save_code(prev, spu); /* Step 54. */
set_ppu_querymask(prev, spu); /* Step 55. */
wait_tag_complete(prev, spu); /* Step 56. */
wait_spu_stopped(prev, spu); /* Step 57. */
}
static void force_spu_isolate_exit(struct spu *spu)
{
struct spu_problem __iomem *prob = spu->problem;
struct spu_priv2 __iomem *priv2 = spu->priv2;
/* Stop SPE execution and wait for completion. */
out_be32(&prob->spu_runcntl_RW, SPU_RUNCNTL_STOP);
iobarrier_rw();
POLL_WHILE_TRUE(in_be32(&prob->spu_status_R) & SPU_STATUS_RUNNING);
/* Restart SPE master runcntl. */
spu_mfc_sr1_set(spu, MFC_STATE1_MASTER_RUN_CONTROL_MASK);
iobarrier_w();
/* Initiate isolate exit request and wait for completion. */
out_be64(&priv2->spu_privcntl_RW, 4LL);
iobarrier_w();
out_be32(&prob->spu_runcntl_RW, 2);
iobarrier_rw();
POLL_WHILE_FALSE((in_be32(&prob->spu_status_R)
& SPU_STATUS_STOPPED_BY_STOP));
/* Reset load request to normal. */
out_be64(&priv2->spu_privcntl_RW, SPU_PRIVCNT_LOAD_REQUEST_NORMAL);
iobarrier_w();
}
/**
* stop_spu_isolate
* Check SPU run-control state and force isolated
* exit function as necessary.
*/
static void stop_spu_isolate(struct spu *spu)
{
struct spu_problem __iomem *prob = spu->problem;
if (in_be32(&prob->spu_status_R) & SPU_STATUS_ISOLATED_STATE) {
/* The SPU is in isolated state; the only way
* to get it out is to perform an isolated
* exit (clean) operation.
*/
force_spu_isolate_exit(spu);
}
}
static void harvest(struct spu_state *prev, struct spu *spu)
{
/*
* Perform steps 2-25 of SPU context restore sequence,
* which resets an SPU either after a failed save, or
* when using SPU for first time.
*/
disable_interrupts(prev, spu); /* Step 2. */
inhibit_user_access(prev, spu); /* Step 3. */
terminate_spu_app(prev, spu); /* Step 4. */
set_switch_pending(prev, spu); /* Step 5. */
stop_spu_isolate(spu); /* NEW. */
remove_other_spu_access(prev, spu); /* Step 6. */
suspend_mfc_and_halt_decr(prev, spu); /* Step 7. */
wait_suspend_mfc_complete(prev, spu); /* Step 8. */
if (!suspend_spe(prev, spu)) /* Step 9. */
clear_spu_status(prev, spu); /* Step 10. */
do_mfc_mssync(prev, spu); /* Step 11. */
issue_mfc_tlbie(prev, spu); /* Step 12. */
handle_pending_interrupts(prev, spu); /* Step 13. */
purge_mfc_queue(prev, spu); /* Step 14. */
wait_purge_complete(prev, spu); /* Step 15. */
reset_spu_privcntl(prev, spu); /* Step 16. */
reset_spu_lslr(prev, spu); /* Step 17. */
setup_mfc_sr1(prev, spu); /* Step 18. */
spu_invalidate_slbs(spu); /* Step 19. */
reset_ch_part1(prev, spu); /* Step 20. */
reset_ch_part2(prev, spu); /* Step 21. */
enable_interrupts(prev, spu); /* Step 22. */
set_switch_active(prev, spu); /* Step 23. */
set_mfc_tclass_id(prev, spu); /* Step 24. */
resume_mfc_queue(prev, spu); /* Step 25. */
}
static void restore_lscsa(struct spu_state *next, struct spu *spu)
{
/*
* Perform steps 26-40 of SPU context restore sequence,
* which restores regions of the local store and register
* file.
*/
set_watchdog_timer(next, spu); /* Step 26. */
setup_spu_status_part1(next, spu); /* Step 27. */
setup_spu_status_part2(next, spu); /* Step 28. */
restore_mfc_rag(next, spu); /* Step 29. */
/* Step 30. */
setup_mfc_slbs(next, spu, spu_restore_code, sizeof(spu_restore_code));
set_spu_npc(next, spu); /* Step 31. */
set_signot1(next, spu); /* Step 32. */
set_signot2(next, spu); /* Step 33. */
setup_decr(next, spu); /* Step 34. */
setup_ppu_mb(next, spu); /* Step 35. */
setup_ppuint_mb(next, spu); /* Step 36. */
send_restore_code(next, spu); /* Step 37. */
set_ppu_querymask(next, spu); /* Step 38. */
wait_tag_complete(next, spu); /* Step 39. */
wait_spu_stopped(next, spu); /* Step 40. */
}
static void restore_csa(struct spu_state *next, struct spu *spu)
{
/*
* Combine steps 41-76 of SPU context restore sequence, which
* restore regions of the privileged & problem state areas.
*/
restore_spu_privcntl(next, spu); /* Step 41. */
restore_status_part1(next, spu); /* Step 42. */
restore_status_part2(next, spu); /* Step 43. */
restore_ls_16kb(next, spu); /* Step 44. */
wait_tag_complete(next, spu); /* Step 45. */
suspend_mfc(next, spu); /* Step 46. */
wait_suspend_mfc_complete(next, spu); /* Step 47. */
issue_mfc_tlbie(next, spu); /* Step 48. */
clear_interrupts(next, spu); /* Step 49. */
restore_mfc_queues(next, spu); /* Step 50. */
restore_ppu_querymask(next, spu); /* Step 51. */
restore_ppu_querytype(next, spu); /* Step 52. */
restore_mfc_csr_tsq(next, spu); /* Step 53. */
restore_mfc_csr_cmd(next, spu); /* Step 54. */
restore_mfc_csr_ato(next, spu); /* Step 55. */
restore_mfc_tclass_id(next, spu); /* Step 56. */
set_llr_event(next, spu); /* Step 57. */
restore_decr_wrapped(next, spu); /* Step 58. */
restore_ch_part1(next, spu); /* Step 59. */
restore_ch_part2(next, spu); /* Step 60. */
restore_spu_lslr(next, spu); /* Step 61. */
restore_spu_cfg(next, spu); /* Step 62. */
restore_pm_trace(next, spu); /* Step 63. */
restore_spu_npc(next, spu); /* Step 64. */
restore_spu_mb(next, spu); /* Step 65. */
check_ppu_mb_stat(next, spu); /* Step 66. */
check_ppuint_mb_stat(next, spu); /* Step 67. */
spu_invalidate_slbs(spu); /* Modified Step 68. */
restore_mfc_sr1(next, spu); /* Step 69. */
restore_other_spu_access(next, spu); /* Step 70. */
restore_spu_runcntl(next, spu); /* Step 71. */
restore_mfc_cntl(next, spu); /* Step 72. */
enable_user_access(next, spu); /* Step 73. */
reset_switch_active(next, spu); /* Step 74. */
reenable_interrupts(next, spu); /* Step 75. */
}
static int __do_spu_save(struct spu_state *prev, struct spu *spu)
{
int rc;
/*
* SPU context save can be broken into three phases:
*
* (a) quiesce [steps 2-16].
* (b) save of CSA, performed by PPE [steps 17-42]
* (c) save of LSCSA, mostly performed by SPU [steps 43-52].
*
* Returns 0 on success.
* 2,6 if failed to quiece SPU
* 53 if SPU-side of save failed.
*/
rc = quiece_spu(prev, spu); /* Steps 2-16. */
switch (rc) {
default:
case 2:
case 6:
harvest(prev, spu);
return rc;
break;
case 0:
break;
}
save_csa(prev, spu); /* Steps 17-43. */
save_lscsa(prev, spu); /* Steps 44-53. */
return check_save_status(prev, spu); /* Step 54. */
}
static int __do_spu_restore(struct spu_state *next, struct spu *spu)
{
int rc;
/*
* SPU context restore can be broken into three phases:
*
* (a) harvest (or reset) SPU [steps 2-24].
* (b) restore LSCSA [steps 25-40], mostly performed by SPU.
* (c) restore CSA [steps 41-76], performed by PPE.
*
* The 'harvest' step is not performed here, but rather
* as needed below.
*/
restore_lscsa(next, spu); /* Steps 24-39. */
rc = check_restore_status(next, spu); /* Step 40. */
switch (rc) {
default:
/* Failed. Return now. */
return rc;
break;
case 0:
/* Fall through to next step. */
break;
}
restore_csa(next, spu);
return 0;
}
/**
* spu_save - SPU context save, with locking.
* @prev: pointer to SPU context save area, to be saved.
* @spu: pointer to SPU iomem structure.
*
* Acquire locks, perform the save operation then return.
*/
int spu_save(struct spu_state *prev, struct spu *spu)
{
int rc;
acquire_spu_lock(spu); /* Step 1. */
rc = __do_spu_save(prev, spu); /* Steps 2-53. */
release_spu_lock(spu);
if (rc != 0 && rc != 2 && rc != 6) {
panic("%s failed on SPU[%d], rc=%d.\n",
__func__, spu->number, rc);
}
return 0;
}
EXPORT_SYMBOL_GPL(spu_save);
/**
* spu_restore - SPU context restore, with harvest and locking.
* @new: pointer to SPU context save area, to be restored.
* @spu: pointer to SPU iomem structure.
*
* Perform harvest + restore, as we may not be coming
* from a previous successful save operation, and the
* hardware state is unknown.
*/
int spu_restore(struct spu_state *new, struct spu *spu)
{
int rc;
acquire_spu_lock(spu);
harvest(NULL, spu);
spu->slb_replace = 0;
rc = __do_spu_restore(new, spu);
release_spu_lock(spu);
if (rc) {
panic("%s failed on SPU[%d] rc=%d.\n",
__func__, spu->number, rc);
}
return rc;
}
EXPORT_SYMBOL_GPL(spu_restore);
static void init_prob(struct spu_state *csa)
{
csa->spu_chnlcnt_RW[9] = 1;
csa->spu_chnlcnt_RW[21] = 16;
csa->spu_chnlcnt_RW[23] = 1;
csa->spu_chnlcnt_RW[28] = 1;
csa->spu_chnlcnt_RW[30] = 1;
csa->prob.spu_runcntl_RW = SPU_RUNCNTL_STOP;
csa->prob.mb_stat_R = 0x000400;
}
static void init_priv1(struct spu_state *csa)
{
/* Enable decode, relocate, tlbie response, master runcntl. */
csa->priv1.mfc_sr1_RW = MFC_STATE1_LOCAL_STORAGE_DECODE_MASK |
MFC_STATE1_MASTER_RUN_CONTROL_MASK |
MFC_STATE1_PROBLEM_STATE_MASK |
MFC_STATE1_RELOCATE_MASK | MFC_STATE1_BUS_TLBIE_MASK;
/* Enable OS-specific set of interrupts. */
csa->priv1.int_mask_class0_RW = CLASS0_ENABLE_DMA_ALIGNMENT_INTR |
CLASS0_ENABLE_INVALID_DMA_COMMAND_INTR |
CLASS0_ENABLE_SPU_ERROR_INTR;
csa->priv1.int_mask_class1_RW = CLASS1_ENABLE_SEGMENT_FAULT_INTR |
CLASS1_ENABLE_STORAGE_FAULT_INTR;
csa->priv1.int_mask_class2_RW = CLASS2_ENABLE_SPU_STOP_INTR |
CLASS2_ENABLE_SPU_HALT_INTR |
CLASS2_ENABLE_SPU_DMA_TAG_GROUP_COMPLETE_INTR;
}
static void init_priv2(struct spu_state *csa)
{
csa->priv2.spu_lslr_RW = LS_ADDR_MASK;
csa->priv2.mfc_control_RW = MFC_CNTL_RESUME_DMA_QUEUE |
MFC_CNTL_NORMAL_DMA_QUEUE_OPERATION |
MFC_CNTL_DMA_QUEUES_EMPTY_MASK;
}
/**
* spu_alloc_csa - allocate and initialize an SPU context save area.
*
* Allocate and initialize the contents of an SPU context save area.
* This includes enabling address translation, interrupt masks, etc.,
* as appropriate for the given OS environment.
*
* Note that storage for the 'lscsa' is allocated separately,
* as it is by far the largest of the context save regions,
* and may need to be pinned or otherwise specially aligned.
*/
int spu_init_csa(struct spu_state *csa)
{
int rc;
if (!csa)
return -EINVAL;
memset(csa, 0, sizeof(struct spu_state));
rc = spu_alloc_lscsa(csa);
if (rc)
return rc;
spin_lock_init(&csa->register_lock);
init_prob(csa);
init_priv1(csa);
init_priv2(csa);
return 0;
}
void spu_fini_csa(struct spu_state *csa)
{
spu_free_lscsa(csa);
}