linux-zen-desktop/drivers/accel/ivpu/ivpu_mmu.c

874 lines
25 KiB
C

// SPDX-License-Identifier: GPL-2.0-only
/*
* Copyright (C) 2020-2023 Intel Corporation
*/
#include <linux/circ_buf.h>
#include <linux/highmem.h>
#include "ivpu_drv.h"
#include "ivpu_hw_mtl_reg.h"
#include "ivpu_hw_reg_io.h"
#include "ivpu_mmu.h"
#include "ivpu_mmu_context.h"
#include "ivpu_pm.h"
#define IVPU_MMU_IDR0_REF 0x080f3e0f
#define IVPU_MMU_IDR0_REF_SIMICS 0x080f3e1f
#define IVPU_MMU_IDR1_REF 0x0e739d18
#define IVPU_MMU_IDR3_REF 0x0000003c
#define IVPU_MMU_IDR5_REF 0x00040070
#define IVPU_MMU_IDR5_REF_SIMICS 0x00000075
#define IVPU_MMU_IDR5_REF_FPGA 0x00800075
#define IVPU_MMU_CDTAB_ENT_SIZE 64
#define IVPU_MMU_CDTAB_ENT_COUNT_LOG2 8 /* 256 entries */
#define IVPU_MMU_CDTAB_ENT_COUNT ((u32)1 << IVPU_MMU_CDTAB_ENT_COUNT_LOG2)
#define IVPU_MMU_STREAM_ID0 0
#define IVPU_MMU_STREAM_ID3 3
#define IVPU_MMU_STRTAB_ENT_SIZE 64
#define IVPU_MMU_STRTAB_ENT_COUNT 4
#define IVPU_MMU_STRTAB_CFG_LOG2SIZE 2
#define IVPU_MMU_STRTAB_CFG IVPU_MMU_STRTAB_CFG_LOG2SIZE
#define IVPU_MMU_Q_COUNT_LOG2 4 /* 16 entries */
#define IVPU_MMU_Q_COUNT ((u32)1 << IVPU_MMU_Q_COUNT_LOG2)
#define IVPU_MMU_Q_WRAP_BIT (IVPU_MMU_Q_COUNT << 1)
#define IVPU_MMU_Q_WRAP_MASK (IVPU_MMU_Q_WRAP_BIT - 1)
#define IVPU_MMU_Q_IDX_MASK (IVPU_MMU_Q_COUNT - 1)
#define IVPU_MMU_Q_IDX(val) ((val) & IVPU_MMU_Q_IDX_MASK)
#define IVPU_MMU_CMDQ_CMD_SIZE 16
#define IVPU_MMU_CMDQ_SIZE (IVPU_MMU_Q_COUNT * IVPU_MMU_CMDQ_CMD_SIZE)
#define IVPU_MMU_EVTQ_CMD_SIZE 32
#define IVPU_MMU_EVTQ_SIZE (IVPU_MMU_Q_COUNT * IVPU_MMU_EVTQ_CMD_SIZE)
#define IVPU_MMU_CMD_OPCODE GENMASK(7, 0)
#define IVPU_MMU_CMD_SYNC_0_CS GENMASK(13, 12)
#define IVPU_MMU_CMD_SYNC_0_MSH GENMASK(23, 22)
#define IVPU_MMU_CMD_SYNC_0_MSI_ATTR GENMASK(27, 24)
#define IVPU_MMU_CMD_SYNC_0_MSI_ATTR GENMASK(27, 24)
#define IVPU_MMU_CMD_SYNC_0_MSI_DATA GENMASK(63, 32)
#define IVPU_MMU_CMD_CFGI_0_SSEC BIT(10)
#define IVPU_MMU_CMD_CFGI_0_SSV BIT(11)
#define IVPU_MMU_CMD_CFGI_0_SSID GENMASK(31, 12)
#define IVPU_MMU_CMD_CFGI_0_SID GENMASK(63, 32)
#define IVPU_MMU_CMD_CFGI_1_RANGE GENMASK(4, 0)
#define IVPU_MMU_CMD_TLBI_0_ASID GENMASK(63, 48)
#define IVPU_MMU_CMD_TLBI_0_VMID GENMASK(47, 32)
#define CMD_PREFETCH_CFG 0x1
#define CMD_CFGI_STE 0x3
#define CMD_CFGI_ALL 0x4
#define CMD_CFGI_CD 0x5
#define CMD_CFGI_CD_ALL 0x6
#define CMD_TLBI_NH_ASID 0x11
#define CMD_TLBI_EL2_ALL 0x20
#define CMD_TLBI_NSNH_ALL 0x30
#define CMD_SYNC 0x46
#define IVPU_MMU_EVT_F_UUT 0x01
#define IVPU_MMU_EVT_C_BAD_STREAMID 0x02
#define IVPU_MMU_EVT_F_STE_FETCH 0x03
#define IVPU_MMU_EVT_C_BAD_STE 0x04
#define IVPU_MMU_EVT_F_BAD_ATS_TREQ 0x05
#define IVPU_MMU_EVT_F_STREAM_DISABLED 0x06
#define IVPU_MMU_EVT_F_TRANSL_FORBIDDEN 0x07
#define IVPU_MMU_EVT_C_BAD_SUBSTREAMID 0x08
#define IVPU_MMU_EVT_F_CD_FETCH 0x09
#define IVPU_MMU_EVT_C_BAD_CD 0x0a
#define IVPU_MMU_EVT_F_WALK_EABT 0x0b
#define IVPU_MMU_EVT_F_TRANSLATION 0x10
#define IVPU_MMU_EVT_F_ADDR_SIZE 0x11
#define IVPU_MMU_EVT_F_ACCESS 0x12
#define IVPU_MMU_EVT_F_PERMISSION 0x13
#define IVPU_MMU_EVT_F_TLB_CONFLICT 0x20
#define IVPU_MMU_EVT_F_CFG_CONFLICT 0x21
#define IVPU_MMU_EVT_E_PAGE_REQUEST 0x24
#define IVPU_MMU_EVT_F_VMS_FETCH 0x25
#define IVPU_MMU_EVT_OP_MASK GENMASK_ULL(7, 0)
#define IVPU_MMU_EVT_SSID_MASK GENMASK_ULL(31, 12)
#define IVPU_MMU_Q_BASE_RWA BIT(62)
#define IVPU_MMU_Q_BASE_ADDR_MASK GENMASK_ULL(51, 5)
#define IVPU_MMU_STRTAB_BASE_RA BIT(62)
#define IVPU_MMU_STRTAB_BASE_ADDR_MASK GENMASK_ULL(51, 6)
#define IVPU_MMU_IRQ_EVTQ_EN BIT(2)
#define IVPU_MMU_IRQ_GERROR_EN BIT(0)
#define IVPU_MMU_CR0_ATSCHK BIT(4)
#define IVPU_MMU_CR0_CMDQEN BIT(3)
#define IVPU_MMU_CR0_EVTQEN BIT(2)
#define IVPU_MMU_CR0_PRIQEN BIT(1)
#define IVPU_MMU_CR0_SMMUEN BIT(0)
#define IVPU_MMU_CR1_TABLE_SH GENMASK(11, 10)
#define IVPU_MMU_CR1_TABLE_OC GENMASK(9, 8)
#define IVPU_MMU_CR1_TABLE_IC GENMASK(7, 6)
#define IVPU_MMU_CR1_QUEUE_SH GENMASK(5, 4)
#define IVPU_MMU_CR1_QUEUE_OC GENMASK(3, 2)
#define IVPU_MMU_CR1_QUEUE_IC GENMASK(1, 0)
#define IVPU_MMU_CACHE_NC 0
#define IVPU_MMU_CACHE_WB 1
#define IVPU_MMU_CACHE_WT 2
#define IVPU_MMU_SH_NSH 0
#define IVPU_MMU_SH_OSH 2
#define IVPU_MMU_SH_ISH 3
#define IVPU_MMU_CMDQ_OP GENMASK_ULL(7, 0)
#define IVPU_MMU_CD_0_TCR_T0SZ GENMASK_ULL(5, 0)
#define IVPU_MMU_CD_0_TCR_TG0 GENMASK_ULL(7, 6)
#define IVPU_MMU_CD_0_TCR_IRGN0 GENMASK_ULL(9, 8)
#define IVPU_MMU_CD_0_TCR_ORGN0 GENMASK_ULL(11, 10)
#define IVPU_MMU_CD_0_TCR_SH0 GENMASK_ULL(13, 12)
#define IVPU_MMU_CD_0_TCR_EPD0 BIT_ULL(14)
#define IVPU_MMU_CD_0_TCR_EPD1 BIT_ULL(30)
#define IVPU_MMU_CD_0_ENDI BIT(15)
#define IVPU_MMU_CD_0_V BIT(31)
#define IVPU_MMU_CD_0_TCR_IPS GENMASK_ULL(34, 32)
#define IVPU_MMU_CD_0_TCR_TBI0 BIT_ULL(38)
#define IVPU_MMU_CD_0_AA64 BIT(41)
#define IVPU_MMU_CD_0_S BIT(44)
#define IVPU_MMU_CD_0_R BIT(45)
#define IVPU_MMU_CD_0_A BIT(46)
#define IVPU_MMU_CD_0_ASET BIT(47)
#define IVPU_MMU_CD_0_ASID GENMASK_ULL(63, 48)
#define IVPU_MMU_CD_1_TTB0_MASK GENMASK_ULL(51, 4)
#define IVPU_MMU_STE_0_S1CDMAX GENMASK_ULL(63, 59)
#define IVPU_MMU_STE_0_S1FMT GENMASK_ULL(5, 4)
#define IVPU_MMU_STE_0_S1FMT_LINEAR 0
#define IVPU_MMU_STE_DWORDS 8
#define IVPU_MMU_STE_0_CFG_S1_TRANS 5
#define IVPU_MMU_STE_0_CFG GENMASK_ULL(3, 1)
#define IVPU_MMU_STE_0_S1CTXPTR_MASK GENMASK_ULL(51, 6)
#define IVPU_MMU_STE_0_V BIT(0)
#define IVPU_MMU_STE_1_STRW_NSEL1 0ul
#define IVPU_MMU_STE_1_CONT GENMASK_ULL(16, 13)
#define IVPU_MMU_STE_1_STRW GENMASK_ULL(31, 30)
#define IVPU_MMU_STE_1_PRIVCFG GENMASK_ULL(49, 48)
#define IVPU_MMU_STE_1_PRIVCFG_UNPRIV 2ul
#define IVPU_MMU_STE_1_INSTCFG GENMASK_ULL(51, 50)
#define IVPU_MMU_STE_1_INSTCFG_DATA 2ul
#define IVPU_MMU_STE_1_MEV BIT(19)
#define IVPU_MMU_STE_1_S1STALLD BIT(27)
#define IVPU_MMU_STE_1_S1C_CACHE_NC 0ul
#define IVPU_MMU_STE_1_S1C_CACHE_WBRA 1ul
#define IVPU_MMU_STE_1_S1C_CACHE_WT 2ul
#define IVPU_MMU_STE_1_S1C_CACHE_WB 3ul
#define IVPU_MMU_STE_1_S1CIR GENMASK_ULL(3, 2)
#define IVPU_MMU_STE_1_S1COR GENMASK_ULL(5, 4)
#define IVPU_MMU_STE_1_S1CSH GENMASK_ULL(7, 6)
#define IVPU_MMU_STE_1_S1DSS GENMASK_ULL(1, 0)
#define IVPU_MMU_STE_1_S1DSS_TERMINATE 0x0
#define IVPU_MMU_REG_TIMEOUT_US (10 * USEC_PER_MSEC)
#define IVPU_MMU_QUEUE_TIMEOUT_US (100 * USEC_PER_MSEC)
#define IVPU_MMU_GERROR_ERR_MASK ((REG_FLD(MTL_VPU_HOST_MMU_GERROR, CMDQ)) | \
(REG_FLD(MTL_VPU_HOST_MMU_GERROR, EVTQ_ABT)) | \
(REG_FLD(MTL_VPU_HOST_MMU_GERROR, PRIQ_ABT)) | \
(REG_FLD(MTL_VPU_HOST_MMU_GERROR, MSI_CMDQ_ABT)) | \
(REG_FLD(MTL_VPU_HOST_MMU_GERROR, MSI_EVTQ_ABT)) | \
(REG_FLD(MTL_VPU_HOST_MMU_GERROR, MSI_PRIQ_ABT)) | \
(REG_FLD(MTL_VPU_HOST_MMU_GERROR, MSI_ABT)))
static char *ivpu_mmu_event_to_str(u32 cmd)
{
switch (cmd) {
case IVPU_MMU_EVT_F_UUT:
return "Unsupported Upstream Transaction";
case IVPU_MMU_EVT_C_BAD_STREAMID:
return "Transaction StreamID out of range";
case IVPU_MMU_EVT_F_STE_FETCH:
return "Fetch of STE caused external abort";
case IVPU_MMU_EVT_C_BAD_STE:
return "Used STE invalid";
case IVPU_MMU_EVT_F_BAD_ATS_TREQ:
return "Address Request disallowed for a StreamID";
case IVPU_MMU_EVT_F_STREAM_DISABLED:
return "Transaction marks non-substream disabled";
case IVPU_MMU_EVT_F_TRANSL_FORBIDDEN:
return "MMU bypass is disallowed for this StreamID";
case IVPU_MMU_EVT_C_BAD_SUBSTREAMID:
return "Invalid StreamID";
case IVPU_MMU_EVT_F_CD_FETCH:
return "Fetch of CD caused external abort";
case IVPU_MMU_EVT_C_BAD_CD:
return "Fetched CD invalid";
case IVPU_MMU_EVT_F_WALK_EABT:
return " An external abort occurred fetching a TLB";
case IVPU_MMU_EVT_F_TRANSLATION:
return "Translation fault";
case IVPU_MMU_EVT_F_ADDR_SIZE:
return " Output address caused address size fault";
case IVPU_MMU_EVT_F_ACCESS:
return "Access flag fault";
case IVPU_MMU_EVT_F_PERMISSION:
return "Permission fault occurred on page access";
case IVPU_MMU_EVT_F_TLB_CONFLICT:
return "A TLB conflict";
case IVPU_MMU_EVT_F_CFG_CONFLICT:
return "A configuration cache conflict";
case IVPU_MMU_EVT_E_PAGE_REQUEST:
return "Page request hint from a client device";
case IVPU_MMU_EVT_F_VMS_FETCH:
return "Fetch of VMS caused external abort";
default:
return "Unknown CMDQ command";
}
}
static void ivpu_mmu_config_check(struct ivpu_device *vdev)
{
u32 val_ref;
u32 val;
if (ivpu_is_simics(vdev))
val_ref = IVPU_MMU_IDR0_REF_SIMICS;
else
val_ref = IVPU_MMU_IDR0_REF;
val = REGV_RD32(MTL_VPU_HOST_MMU_IDR0);
if (val != val_ref)
ivpu_dbg(vdev, MMU, "IDR0 0x%x != IDR0_REF 0x%x\n", val, val_ref);
val = REGV_RD32(MTL_VPU_HOST_MMU_IDR1);
if (val != IVPU_MMU_IDR1_REF)
ivpu_dbg(vdev, MMU, "IDR1 0x%x != IDR1_REF 0x%x\n", val, IVPU_MMU_IDR1_REF);
val = REGV_RD32(MTL_VPU_HOST_MMU_IDR3);
if (val != IVPU_MMU_IDR3_REF)
ivpu_dbg(vdev, MMU, "IDR3 0x%x != IDR3_REF 0x%x\n", val, IVPU_MMU_IDR3_REF);
if (ivpu_is_simics(vdev))
val_ref = IVPU_MMU_IDR5_REF_SIMICS;
else if (ivpu_is_fpga(vdev))
val_ref = IVPU_MMU_IDR5_REF_FPGA;
else
val_ref = IVPU_MMU_IDR5_REF;
val = REGV_RD32(MTL_VPU_HOST_MMU_IDR5);
if (val != val_ref)
ivpu_dbg(vdev, MMU, "IDR5 0x%x != IDR5_REF 0x%x\n", val, val_ref);
}
static int ivpu_mmu_cdtab_alloc(struct ivpu_device *vdev)
{
struct ivpu_mmu_info *mmu = vdev->mmu;
struct ivpu_mmu_cdtab *cdtab = &mmu->cdtab;
size_t size = IVPU_MMU_CDTAB_ENT_COUNT * IVPU_MMU_CDTAB_ENT_SIZE;
cdtab->base = dmam_alloc_coherent(vdev->drm.dev, size, &cdtab->dma, GFP_KERNEL);
if (!cdtab->base)
return -ENOMEM;
ivpu_dbg(vdev, MMU, "CDTAB alloc: dma=%pad size=%zu\n", &cdtab->dma, size);
return 0;
}
static int ivpu_mmu_strtab_alloc(struct ivpu_device *vdev)
{
struct ivpu_mmu_info *mmu = vdev->mmu;
struct ivpu_mmu_strtab *strtab = &mmu->strtab;
size_t size = IVPU_MMU_STRTAB_ENT_COUNT * IVPU_MMU_STRTAB_ENT_SIZE;
strtab->base = dmam_alloc_coherent(vdev->drm.dev, size, &strtab->dma, GFP_KERNEL);
if (!strtab->base)
return -ENOMEM;
strtab->base_cfg = IVPU_MMU_STRTAB_CFG;
strtab->dma_q = IVPU_MMU_STRTAB_BASE_RA;
strtab->dma_q |= strtab->dma & IVPU_MMU_STRTAB_BASE_ADDR_MASK;
ivpu_dbg(vdev, MMU, "STRTAB alloc: dma=%pad dma_q=%pad size=%zu\n",
&strtab->dma, &strtab->dma_q, size);
return 0;
}
static int ivpu_mmu_cmdq_alloc(struct ivpu_device *vdev)
{
struct ivpu_mmu_info *mmu = vdev->mmu;
struct ivpu_mmu_queue *q = &mmu->cmdq;
q->base = dmam_alloc_coherent(vdev->drm.dev, IVPU_MMU_CMDQ_SIZE, &q->dma, GFP_KERNEL);
if (!q->base)
return -ENOMEM;
q->dma_q = IVPU_MMU_Q_BASE_RWA;
q->dma_q |= q->dma & IVPU_MMU_Q_BASE_ADDR_MASK;
q->dma_q |= IVPU_MMU_Q_COUNT_LOG2;
ivpu_dbg(vdev, MMU, "CMDQ alloc: dma=%pad dma_q=%pad size=%u\n",
&q->dma, &q->dma_q, IVPU_MMU_CMDQ_SIZE);
return 0;
}
static int ivpu_mmu_evtq_alloc(struct ivpu_device *vdev)
{
struct ivpu_mmu_info *mmu = vdev->mmu;
struct ivpu_mmu_queue *q = &mmu->evtq;
q->base = dmam_alloc_coherent(vdev->drm.dev, IVPU_MMU_EVTQ_SIZE, &q->dma, GFP_KERNEL);
if (!q->base)
return -ENOMEM;
q->dma_q = IVPU_MMU_Q_BASE_RWA;
q->dma_q |= q->dma & IVPU_MMU_Q_BASE_ADDR_MASK;
q->dma_q |= IVPU_MMU_Q_COUNT_LOG2;
ivpu_dbg(vdev, MMU, "EVTQ alloc: dma=%pad dma_q=%pad size=%u\n",
&q->dma, &q->dma_q, IVPU_MMU_EVTQ_SIZE);
return 0;
}
static int ivpu_mmu_structs_alloc(struct ivpu_device *vdev)
{
int ret;
ret = ivpu_mmu_cdtab_alloc(vdev);
if (ret) {
ivpu_err(vdev, "Failed to allocate cdtab: %d\n", ret);
return ret;
}
ret = ivpu_mmu_strtab_alloc(vdev);
if (ret) {
ivpu_err(vdev, "Failed to allocate strtab: %d\n", ret);
return ret;
}
ret = ivpu_mmu_cmdq_alloc(vdev);
if (ret) {
ivpu_err(vdev, "Failed to allocate cmdq: %d\n", ret);
return ret;
}
ret = ivpu_mmu_evtq_alloc(vdev);
if (ret)
ivpu_err(vdev, "Failed to allocate evtq: %d\n", ret);
return ret;
}
static int ivpu_mmu_reg_write(struct ivpu_device *vdev, u32 reg, u32 val)
{
u32 reg_ack = reg + 4; /* ACK register is 4B after base register */
u32 val_ack;
int ret;
REGV_WR32(reg, val);
ret = REGV_POLL(reg_ack, val_ack, (val == val_ack), IVPU_MMU_REG_TIMEOUT_US);
if (ret)
ivpu_err(vdev, "Failed to write register 0x%x\n", reg);
return ret;
}
static int ivpu_mmu_irqs_setup(struct ivpu_device *vdev)
{
u32 irq_ctrl = IVPU_MMU_IRQ_EVTQ_EN | IVPU_MMU_IRQ_GERROR_EN;
int ret;
ret = ivpu_mmu_reg_write(vdev, MTL_VPU_HOST_MMU_IRQ_CTRL, 0);
if (ret)
return ret;
return ivpu_mmu_reg_write(vdev, MTL_VPU_HOST_MMU_IRQ_CTRL, irq_ctrl);
}
static int ivpu_mmu_cmdq_wait_for_cons(struct ivpu_device *vdev)
{
struct ivpu_mmu_queue *cmdq = &vdev->mmu->cmdq;
return REGV_POLL(MTL_VPU_HOST_MMU_CMDQ_CONS, cmdq->cons, (cmdq->prod == cmdq->cons),
IVPU_MMU_QUEUE_TIMEOUT_US);
}
static int ivpu_mmu_cmdq_cmd_write(struct ivpu_device *vdev, const char *name, u64 data0, u64 data1)
{
struct ivpu_mmu_queue *q = &vdev->mmu->cmdq;
u64 *queue_buffer = q->base;
int idx = IVPU_MMU_Q_IDX(q->prod) * (IVPU_MMU_CMDQ_CMD_SIZE / sizeof(*queue_buffer));
if (!CIRC_SPACE(IVPU_MMU_Q_IDX(q->prod), IVPU_MMU_Q_IDX(q->cons), IVPU_MMU_Q_COUNT)) {
ivpu_err(vdev, "Failed to write MMU CMD %s\n", name);
return -EBUSY;
}
queue_buffer[idx] = data0;
queue_buffer[idx + 1] = data1;
q->prod = (q->prod + 1) & IVPU_MMU_Q_WRAP_MASK;
ivpu_dbg(vdev, MMU, "CMD write: %s data: 0x%llx 0x%llx\n", name, data0, data1);
return 0;
}
static int ivpu_mmu_cmdq_sync(struct ivpu_device *vdev)
{
struct ivpu_mmu_queue *q = &vdev->mmu->cmdq;
u64 val;
int ret;
val = FIELD_PREP(IVPU_MMU_CMD_OPCODE, CMD_SYNC) |
FIELD_PREP(IVPU_MMU_CMD_SYNC_0_CS, 0x2) |
FIELD_PREP(IVPU_MMU_CMD_SYNC_0_MSH, 0x3) |
FIELD_PREP(IVPU_MMU_CMD_SYNC_0_MSI_ATTR, 0xf);
ret = ivpu_mmu_cmdq_cmd_write(vdev, "SYNC", val, 0);
if (ret)
return ret;
clflush_cache_range(q->base, IVPU_MMU_CMDQ_SIZE);
REGV_WR32(MTL_VPU_HOST_MMU_CMDQ_PROD, q->prod);
ret = ivpu_mmu_cmdq_wait_for_cons(vdev);
if (ret)
ivpu_err(vdev, "Timed out waiting for consumer: %d\n", ret);
return ret;
}
static int ivpu_mmu_cmdq_write_cfgi_all(struct ivpu_device *vdev)
{
u64 data0 = FIELD_PREP(IVPU_MMU_CMD_OPCODE, CMD_CFGI_ALL);
u64 data1 = FIELD_PREP(IVPU_MMU_CMD_CFGI_1_RANGE, 0x1f);
return ivpu_mmu_cmdq_cmd_write(vdev, "CFGI_ALL", data0, data1);
}
static int ivpu_mmu_cmdq_write_tlbi_nh_asid(struct ivpu_device *vdev, u16 ssid)
{
u64 val = FIELD_PREP(IVPU_MMU_CMD_OPCODE, CMD_TLBI_NH_ASID) |
FIELD_PREP(IVPU_MMU_CMD_TLBI_0_ASID, ssid);
return ivpu_mmu_cmdq_cmd_write(vdev, "TLBI_NH_ASID", val, 0);
}
static int ivpu_mmu_cmdq_write_tlbi_nsnh_all(struct ivpu_device *vdev)
{
u64 val = FIELD_PREP(IVPU_MMU_CMD_OPCODE, CMD_TLBI_NSNH_ALL);
return ivpu_mmu_cmdq_cmd_write(vdev, "TLBI_NSNH_ALL", val, 0);
}
static int ivpu_mmu_reset(struct ivpu_device *vdev)
{
struct ivpu_mmu_info *mmu = vdev->mmu;
u32 val;
int ret;
memset(mmu->cmdq.base, 0, IVPU_MMU_CMDQ_SIZE);
clflush_cache_range(mmu->cmdq.base, IVPU_MMU_CMDQ_SIZE);
mmu->cmdq.prod = 0;
mmu->cmdq.cons = 0;
memset(mmu->evtq.base, 0, IVPU_MMU_EVTQ_SIZE);
clflush_cache_range(mmu->evtq.base, IVPU_MMU_EVTQ_SIZE);
mmu->evtq.prod = 0;
mmu->evtq.cons = 0;
ret = ivpu_mmu_reg_write(vdev, MTL_VPU_HOST_MMU_CR0, 0);
if (ret)
return ret;
val = FIELD_PREP(IVPU_MMU_CR1_TABLE_SH, IVPU_MMU_SH_ISH) |
FIELD_PREP(IVPU_MMU_CR1_TABLE_OC, IVPU_MMU_CACHE_WB) |
FIELD_PREP(IVPU_MMU_CR1_TABLE_IC, IVPU_MMU_CACHE_WB) |
FIELD_PREP(IVPU_MMU_CR1_QUEUE_SH, IVPU_MMU_SH_ISH) |
FIELD_PREP(IVPU_MMU_CR1_QUEUE_OC, IVPU_MMU_CACHE_WB) |
FIELD_PREP(IVPU_MMU_CR1_QUEUE_IC, IVPU_MMU_CACHE_WB);
REGV_WR32(MTL_VPU_HOST_MMU_CR1, val);
REGV_WR64(MTL_VPU_HOST_MMU_STRTAB_BASE, mmu->strtab.dma_q);
REGV_WR32(MTL_VPU_HOST_MMU_STRTAB_BASE_CFG, mmu->strtab.base_cfg);
REGV_WR64(MTL_VPU_HOST_MMU_CMDQ_BASE, mmu->cmdq.dma_q);
REGV_WR32(MTL_VPU_HOST_MMU_CMDQ_PROD, 0);
REGV_WR32(MTL_VPU_HOST_MMU_CMDQ_CONS, 0);
val = IVPU_MMU_CR0_CMDQEN;
ret = ivpu_mmu_reg_write(vdev, MTL_VPU_HOST_MMU_CR0, val);
if (ret)
return ret;
ret = ivpu_mmu_cmdq_write_cfgi_all(vdev);
if (ret)
return ret;
ret = ivpu_mmu_cmdq_write_tlbi_nsnh_all(vdev);
if (ret)
return ret;
ret = ivpu_mmu_cmdq_sync(vdev);
if (ret)
return ret;
REGV_WR64(MTL_VPU_HOST_MMU_EVTQ_BASE, mmu->evtq.dma_q);
REGV_WR32(MTL_VPU_HOST_MMU_EVTQ_PROD_SEC, 0);
REGV_WR32(MTL_VPU_HOST_MMU_EVTQ_CONS_SEC, 0);
val |= IVPU_MMU_CR0_EVTQEN;
ret = ivpu_mmu_reg_write(vdev, MTL_VPU_HOST_MMU_CR0, val);
if (ret)
return ret;
val |= IVPU_MMU_CR0_ATSCHK;
ret = ivpu_mmu_reg_write(vdev, MTL_VPU_HOST_MMU_CR0, val);
if (ret)
return ret;
ret = ivpu_mmu_irqs_setup(vdev);
if (ret)
return ret;
val |= IVPU_MMU_CR0_SMMUEN;
return ivpu_mmu_reg_write(vdev, MTL_VPU_HOST_MMU_CR0, val);
}
static void ivpu_mmu_strtab_link_cd(struct ivpu_device *vdev, u32 sid)
{
struct ivpu_mmu_info *mmu = vdev->mmu;
struct ivpu_mmu_strtab *strtab = &mmu->strtab;
struct ivpu_mmu_cdtab *cdtab = &mmu->cdtab;
u64 *entry = strtab->base + (sid * IVPU_MMU_STRTAB_ENT_SIZE);
u64 str[2];
str[0] = FIELD_PREP(IVPU_MMU_STE_0_CFG, IVPU_MMU_STE_0_CFG_S1_TRANS) |
FIELD_PREP(IVPU_MMU_STE_0_S1CDMAX, IVPU_MMU_CDTAB_ENT_COUNT_LOG2) |
FIELD_PREP(IVPU_MMU_STE_0_S1FMT, IVPU_MMU_STE_0_S1FMT_LINEAR) |
IVPU_MMU_STE_0_V |
(cdtab->dma & IVPU_MMU_STE_0_S1CTXPTR_MASK);
str[1] = FIELD_PREP(IVPU_MMU_STE_1_S1DSS, IVPU_MMU_STE_1_S1DSS_TERMINATE) |
FIELD_PREP(IVPU_MMU_STE_1_S1CIR, IVPU_MMU_STE_1_S1C_CACHE_NC) |
FIELD_PREP(IVPU_MMU_STE_1_S1COR, IVPU_MMU_STE_1_S1C_CACHE_NC) |
FIELD_PREP(IVPU_MMU_STE_1_S1CSH, IVPU_MMU_SH_NSH) |
FIELD_PREP(IVPU_MMU_STE_1_PRIVCFG, IVPU_MMU_STE_1_PRIVCFG_UNPRIV) |
FIELD_PREP(IVPU_MMU_STE_1_INSTCFG, IVPU_MMU_STE_1_INSTCFG_DATA) |
FIELD_PREP(IVPU_MMU_STE_1_STRW, IVPU_MMU_STE_1_STRW_NSEL1) |
FIELD_PREP(IVPU_MMU_STE_1_CONT, IVPU_MMU_STRTAB_CFG_LOG2SIZE) |
IVPU_MMU_STE_1_MEV |
IVPU_MMU_STE_1_S1STALLD;
WRITE_ONCE(entry[1], str[1]);
WRITE_ONCE(entry[0], str[0]);
clflush_cache_range(entry, IVPU_MMU_STRTAB_ENT_SIZE);
ivpu_dbg(vdev, MMU, "STRTAB write entry (SSID=%u): 0x%llx, 0x%llx\n", sid, str[0], str[1]);
}
static int ivpu_mmu_strtab_init(struct ivpu_device *vdev)
{
ivpu_mmu_strtab_link_cd(vdev, IVPU_MMU_STREAM_ID0);
ivpu_mmu_strtab_link_cd(vdev, IVPU_MMU_STREAM_ID3);
return 0;
}
int ivpu_mmu_invalidate_tlb(struct ivpu_device *vdev, u16 ssid)
{
struct ivpu_mmu_info *mmu = vdev->mmu;
int ret = 0;
mutex_lock(&mmu->lock);
if (!mmu->on)
goto unlock;
ret = ivpu_mmu_cmdq_write_tlbi_nh_asid(vdev, ssid);
if (ret)
goto unlock;
ret = ivpu_mmu_cmdq_sync(vdev);
unlock:
mutex_unlock(&mmu->lock);
return ret;
}
static int ivpu_mmu_cd_add(struct ivpu_device *vdev, u32 ssid, u64 cd_dma)
{
struct ivpu_mmu_info *mmu = vdev->mmu;
struct ivpu_mmu_cdtab *cdtab = &mmu->cdtab;
u64 *entry;
u64 cd[4];
int ret = 0;
if (ssid > IVPU_MMU_CDTAB_ENT_COUNT)
return -EINVAL;
entry = cdtab->base + (ssid * IVPU_MMU_CDTAB_ENT_SIZE);
if (cd_dma != 0) {
cd[0] = FIELD_PREP(IVPU_MMU_CD_0_TCR_T0SZ, 26) |
FIELD_PREP(IVPU_MMU_CD_0_TCR_TG0, 0) |
FIELD_PREP(IVPU_MMU_CD_0_TCR_IRGN0, 0) |
FIELD_PREP(IVPU_MMU_CD_0_TCR_ORGN0, 0) |
FIELD_PREP(IVPU_MMU_CD_0_TCR_SH0, 0) |
FIELD_PREP(IVPU_MMU_CD_0_TCR_IPS, 3) |
FIELD_PREP(IVPU_MMU_CD_0_ASID, ssid) |
IVPU_MMU_CD_0_TCR_EPD1 |
IVPU_MMU_CD_0_AA64 |
IVPU_MMU_CD_0_R |
IVPU_MMU_CD_0_ASET |
IVPU_MMU_CD_0_V;
cd[1] = cd_dma & IVPU_MMU_CD_1_TTB0_MASK;
cd[2] = 0;
cd[3] = 0x0000000000007444;
/* For global context generate memory fault on VPU */
if (ssid == IVPU_GLOBAL_CONTEXT_MMU_SSID)
cd[0] |= IVPU_MMU_CD_0_A;
} else {
memset(cd, 0, sizeof(cd));
}
WRITE_ONCE(entry[1], cd[1]);
WRITE_ONCE(entry[2], cd[2]);
WRITE_ONCE(entry[3], cd[3]);
WRITE_ONCE(entry[0], cd[0]);
clflush_cache_range(entry, IVPU_MMU_CDTAB_ENT_SIZE);
ivpu_dbg(vdev, MMU, "CDTAB %s entry (SSID=%u, dma=%pad): 0x%llx, 0x%llx, 0x%llx, 0x%llx\n",
cd_dma ? "write" : "clear", ssid, &cd_dma, cd[0], cd[1], cd[2], cd[3]);
mutex_lock(&mmu->lock);
if (!mmu->on)
goto unlock;
ret = ivpu_mmu_cmdq_write_cfgi_all(vdev);
if (ret)
goto unlock;
ret = ivpu_mmu_cmdq_sync(vdev);
unlock:
mutex_unlock(&mmu->lock);
return ret;
}
static int ivpu_mmu_cd_add_gbl(struct ivpu_device *vdev)
{
int ret;
ret = ivpu_mmu_cd_add(vdev, 0, vdev->gctx.pgtable.pgd_dma);
if (ret)
ivpu_err(vdev, "Failed to add global CD entry: %d\n", ret);
return ret;
}
static int ivpu_mmu_cd_add_user(struct ivpu_device *vdev, u32 ssid, dma_addr_t cd_dma)
{
int ret;
if (ssid == 0) {
ivpu_err(vdev, "Invalid SSID: %u\n", ssid);
return -EINVAL;
}
ret = ivpu_mmu_cd_add(vdev, ssid, cd_dma);
if (ret)
ivpu_err(vdev, "Failed to add CD entry SSID=%u: %d\n", ssid, ret);
return ret;
}
int ivpu_mmu_init(struct ivpu_device *vdev)
{
struct ivpu_mmu_info *mmu = vdev->mmu;
int ret;
ivpu_dbg(vdev, MMU, "Init..\n");
drmm_mutex_init(&vdev->drm, &mmu->lock);
ivpu_mmu_config_check(vdev);
ret = ivpu_mmu_structs_alloc(vdev);
if (ret)
return ret;
ret = ivpu_mmu_strtab_init(vdev);
if (ret) {
ivpu_err(vdev, "Failed to initialize strtab: %d\n", ret);
return ret;
}
ret = ivpu_mmu_cd_add_gbl(vdev);
if (ret) {
ivpu_err(vdev, "Failed to initialize strtab: %d\n", ret);
return ret;
}
ret = ivpu_mmu_enable(vdev);
if (ret) {
ivpu_err(vdev, "Failed to resume MMU: %d\n", ret);
return ret;
}
ivpu_dbg(vdev, MMU, "Init done\n");
return 0;
}
int ivpu_mmu_enable(struct ivpu_device *vdev)
{
struct ivpu_mmu_info *mmu = vdev->mmu;
int ret;
mutex_lock(&mmu->lock);
mmu->on = true;
ret = ivpu_mmu_reset(vdev);
if (ret) {
ivpu_err(vdev, "Failed to reset MMU: %d\n", ret);
goto err;
}
ret = ivpu_mmu_cmdq_write_cfgi_all(vdev);
if (ret)
goto err;
ret = ivpu_mmu_cmdq_write_tlbi_nsnh_all(vdev);
if (ret)
goto err;
ret = ivpu_mmu_cmdq_sync(vdev);
if (ret)
goto err;
mutex_unlock(&mmu->lock);
return 0;
err:
mmu->on = false;
mutex_unlock(&mmu->lock);
return ret;
}
void ivpu_mmu_disable(struct ivpu_device *vdev)
{
struct ivpu_mmu_info *mmu = vdev->mmu;
mutex_lock(&mmu->lock);
mmu->on = false;
mutex_unlock(&mmu->lock);
}
static void ivpu_mmu_dump_event(struct ivpu_device *vdev, u32 *event)
{
u32 ssid = FIELD_GET(IVPU_MMU_EVT_SSID_MASK, event[0]);
u32 op = FIELD_GET(IVPU_MMU_EVT_OP_MASK, event[0]);
u64 fetch_addr = ((u64)event[7]) << 32 | event[6];
u64 in_addr = ((u64)event[5]) << 32 | event[4];
u32 sid = event[1];
ivpu_err(vdev, "MMU EVTQ: 0x%x (%s) SSID: %d SID: %d, e[2] %08x, e[3] %08x, in addr: 0x%llx, fetch addr: 0x%llx\n",
op, ivpu_mmu_event_to_str(op), ssid, sid, event[2], event[3], in_addr, fetch_addr);
}
static u32 *ivpu_mmu_get_event(struct ivpu_device *vdev)
{
struct ivpu_mmu_queue *evtq = &vdev->mmu->evtq;
u32 idx = IVPU_MMU_Q_IDX(evtq->cons);
u32 *evt = evtq->base + (idx * IVPU_MMU_EVTQ_CMD_SIZE);
evtq->prod = REGV_RD32(MTL_VPU_HOST_MMU_EVTQ_PROD_SEC);
if (!CIRC_CNT(IVPU_MMU_Q_IDX(evtq->prod), IVPU_MMU_Q_IDX(evtq->cons), IVPU_MMU_Q_COUNT))
return NULL;
clflush_cache_range(evt, IVPU_MMU_EVTQ_CMD_SIZE);
evtq->cons = (evtq->cons + 1) & IVPU_MMU_Q_WRAP_MASK;
REGV_WR32(MTL_VPU_HOST_MMU_EVTQ_CONS_SEC, evtq->cons);
return evt;
}
void ivpu_mmu_irq_evtq_handler(struct ivpu_device *vdev)
{
bool schedule_recovery = false;
u32 *event;
u32 ssid;
ivpu_dbg(vdev, IRQ, "MMU event queue\n");
while ((event = ivpu_mmu_get_event(vdev)) != NULL) {
ivpu_mmu_dump_event(vdev, event);
ssid = FIELD_GET(IVPU_MMU_EVT_SSID_MASK, event[0]);
if (ssid == IVPU_GLOBAL_CONTEXT_MMU_SSID)
schedule_recovery = true;
else
ivpu_mmu_user_context_mark_invalid(vdev, ssid);
}
if (schedule_recovery)
ivpu_pm_schedule_recovery(vdev);
}
void ivpu_mmu_irq_gerr_handler(struct ivpu_device *vdev)
{
u32 gerror_val, gerrorn_val, active;
ivpu_dbg(vdev, IRQ, "MMU error\n");
gerror_val = REGV_RD32(MTL_VPU_HOST_MMU_GERROR);
gerrorn_val = REGV_RD32(MTL_VPU_HOST_MMU_GERRORN);
active = gerror_val ^ gerrorn_val;
if (!(active & IVPU_MMU_GERROR_ERR_MASK))
return;
if (REG_TEST_FLD(MTL_VPU_HOST_MMU_GERROR, MSI_ABT, active))
ivpu_warn_ratelimited(vdev, "MMU MSI ABT write aborted\n");
if (REG_TEST_FLD(MTL_VPU_HOST_MMU_GERROR, MSI_PRIQ_ABT, active))
ivpu_warn_ratelimited(vdev, "MMU PRIQ MSI ABT write aborted\n");
if (REG_TEST_FLD(MTL_VPU_HOST_MMU_GERROR, MSI_EVTQ_ABT, active))
ivpu_warn_ratelimited(vdev, "MMU EVTQ MSI ABT write aborted\n");
if (REG_TEST_FLD(MTL_VPU_HOST_MMU_GERROR, MSI_CMDQ_ABT, active))
ivpu_warn_ratelimited(vdev, "MMU CMDQ MSI ABT write aborted\n");
if (REG_TEST_FLD(MTL_VPU_HOST_MMU_GERROR, PRIQ_ABT, active))
ivpu_err_ratelimited(vdev, "MMU PRIQ write aborted\n");
if (REG_TEST_FLD(MTL_VPU_HOST_MMU_GERROR, EVTQ_ABT, active))
ivpu_err_ratelimited(vdev, "MMU EVTQ write aborted\n");
if (REG_TEST_FLD(MTL_VPU_HOST_MMU_GERROR, CMDQ, active))
ivpu_err_ratelimited(vdev, "MMU CMDQ write aborted\n");
REGV_WR32(MTL_VPU_HOST_MMU_GERRORN, gerror_val);
}
int ivpu_mmu_set_pgtable(struct ivpu_device *vdev, int ssid, struct ivpu_mmu_pgtable *pgtable)
{
return ivpu_mmu_cd_add_user(vdev, ssid, pgtable->pgd_dma);
}
void ivpu_mmu_clear_pgtable(struct ivpu_device *vdev, int ssid)
{
ivpu_mmu_cd_add_user(vdev, ssid, 0); /* 0 will clear CD entry */
}