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0899e11d4b
t19x changes necessary for change in core MM code. JIRA NVGPU-30 Change-Id: I62f419450c1a33d0826390d7cbb5ad93569f8c89 Signed-off-by: Alex Waterman <alexw@nvidia.com> Reviewed-on: https://git-master.nvidia.com/r/1577265 Reviewed-by: Automatic_Commit_Validation_User GVS: Gerrit_Virtual_Submit Reviewed-by: David Martinez Nieto <dmartineznie@nvidia.com> Reviewed-by: Terje Bergstrom <tbergstrom@nvidia.com>
331 lines
9.2 KiB
C
331 lines
9.2 KiB
C
/*
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* GV11B MMU
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*
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* Copyright (c) 2016-2017, NVIDIA CORPORATION. All rights reserved.
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*
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* Permission is hereby granted, free of charge, to any person obtaining a
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* copy of this software and associated documentation files (the "Software"),
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* to deal in the Software without restriction, including without limitation
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* the rights to use, copy, modify, merge, publish, distribute, sublicense,
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* and/or sell copies of the Software, and to permit persons to whom the
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* Software is furnished to do so, subject to the following conditions:
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*
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* The above copyright notice and this permission notice shall be included in
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* all copies or substantial portions of the Software.
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*
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* THE SOFTWARE IS PROVIDED "AS IS", WITHOUT WARRANTY OF ANY KIND, EXPRESS OR
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* IMPLIED, INCLUDING BUT NOT LIMITED TO THE WARRANTIES OF MERCHANTABILITY,
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* FITNESS FOR A PARTICULAR PURPOSE AND NONINFRINGEMENT. IN NO EVENT SHALL
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* THE AUTHORS OR COPYRIGHT HOLDERS BE LIABLE FOR ANY CLAIM, DAMAGES OR OTHER
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* LIABILITY, WHETHER IN AN ACTION OF CONTRACT, TORT OR OTHERWISE, ARISING
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* FROM, OUT OF OR IN CONNECTION WITH THE SOFTWARE OR THE USE OR OTHER
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* DEALINGS IN THE SOFTWARE.
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*/
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#include <linux/pm_runtime.h>
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#include <nvgpu/kmem.h>
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#include <nvgpu/dma.h>
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#include <nvgpu/log.h>
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#include <nvgpu/mm.h>
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#include "gk20a/gk20a.h"
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#include "gk20a/mm_gk20a.h"
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#include "gp10b/mm_gp10b.h"
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#include "gp10b/mc_gp10b.h"
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#include "mm_gv11b.h"
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#include "fb_gv11b.h"
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#include <nvgpu/hw/gv11b/hw_fb_gv11b.h>
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#include <nvgpu/hw/gv11b/hw_gmmu_gv11b.h>
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#include <nvgpu/hw/gv11b/hw_bus_gv11b.h>
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#define NVGPU_L3_ALLOC_BIT BIT(36)
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bool gv11b_mm_is_bar1_supported(struct gk20a *g)
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{
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return false;
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}
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void gv11b_init_inst_block(struct nvgpu_mem *inst_block,
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struct vm_gk20a *vm, u32 big_page_size)
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{
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struct gk20a *g = gk20a_from_vm(vm);
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gk20a_dbg_info("inst block phys = 0x%llx, kv = 0x%p",
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nvgpu_inst_block_addr(g, inst_block), inst_block->cpu_va);
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g->ops.mm.init_pdb(g, inst_block, vm);
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if (big_page_size && g->ops.mm.set_big_page_size)
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g->ops.mm.set_big_page_size(g, inst_block, big_page_size);
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}
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bool gv11b_mm_mmu_fault_pending(struct gk20a *g)
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{
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return gv11b_fb_mmu_fault_pending(g);
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}
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void gv11b_mm_fault_info_mem_destroy(struct gk20a *g)
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{
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nvgpu_log_fn(g, " ");
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nvgpu_mutex_acquire(&g->mm.hub_isr_mutex);
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gv11b_fb_disable_hub_intr(g, STALL_REG_INDEX, HUB_INTR_TYPE_OTHER |
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HUB_INTR_TYPE_NONREPLAY | HUB_INTR_TYPE_REPLAY);
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nvgpu_kfree(g, g->mm.fault_info[FAULT_TYPE_OTHER_AND_NONREPLAY]);
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g->mm.fault_info[FAULT_TYPE_OTHER_AND_NONREPLAY] = NULL;
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g->mm.fault_info[FAULT_TYPE_REPLAY] = NULL;
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nvgpu_mutex_release(&g->mm.hub_isr_mutex);
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nvgpu_mutex_destroy(&g->mm.hub_isr_mutex);
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}
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static int gv11b_mm_mmu_fault_info_buf_init(struct gk20a *g,
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u32 *hub_intr_types)
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{
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struct mmu_fault_info *fault_info_mem;
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fault_info_mem = nvgpu_kzalloc(g, sizeof(struct mmu_fault_info) *
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FAULT_TYPE_NUM);
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if (!fault_info_mem) {
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nvgpu_log_info(g, "failed to alloc shadow fault info");
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return -ENOMEM;
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}
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/* shadow buffer for copying mmu fault info */
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g->mm.fault_info[FAULT_TYPE_OTHER_AND_NONREPLAY] =
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&fault_info_mem[FAULT_TYPE_OTHER_AND_NONREPLAY];
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g->mm.fault_info[FAULT_TYPE_REPLAY] =
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&fault_info_mem[FAULT_TYPE_REPLAY];
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*hub_intr_types |= HUB_INTR_TYPE_OTHER;
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return 0;
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}
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static void gv11b_mm_mmu_hw_fault_buf_init(struct gk20a *g,
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u32 *hub_intr_types)
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{
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struct vm_gk20a *vm = g->mm.bar2.vm;
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int err = 0;
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size_t fb_size;
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/* Max entries take care of 1 entry used for full detection */
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fb_size = (g->ops.fifo.get_num_fifos(g) + 1) *
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gmmu_fault_buf_size_v();
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err = nvgpu_dma_alloc_map_sys(vm, fb_size,
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&g->mm.hw_fault_buf[FAULT_TYPE_OTHER_AND_NONREPLAY]);
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if (err) {
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nvgpu_err(g,
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"Error in hw mmu fault buf [0] alloc in bar2 vm ");
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/* Fault will be snapped in pri reg but not in buffer */
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return;
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}
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g->mm.hw_fault_buf_status[NONREPLAY_REG_INDEX] =
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HW_FAULT_BUF_STATUS_ALLOC_TRUE;
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*hub_intr_types |= HUB_INTR_TYPE_NONREPLAY;
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err = nvgpu_dma_alloc_map_sys(vm, fb_size,
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&g->mm.hw_fault_buf[FAULT_TYPE_REPLAY]);
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if (err) {
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nvgpu_err(g,
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"Error in hw mmu fault buf [1] alloc in bar2 vm ");
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/* Fault will be snapped in pri reg but not in buffer */
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return;
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}
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g->mm.hw_fault_buf_status[REPLAY_REG_INDEX] =
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HW_FAULT_BUF_STATUS_ALLOC_TRUE;
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*hub_intr_types |= HUB_INTR_TYPE_REPLAY;
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}
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static void gv11b_mm_mmu_hw_fault_buf_deinit(struct gk20a *g)
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{
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struct vm_gk20a *vm = g->mm.bar2.vm;
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nvgpu_log_fn(g, " ");
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gv11b_fb_disable_hub_intr(g, STALL_REG_INDEX, HUB_INTR_TYPE_NONREPLAY |
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HUB_INTR_TYPE_REPLAY);
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g->mm.hub_intr_types &= (~(HUB_INTR_TYPE_NONREPLAY |
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HUB_INTR_TYPE_REPLAY));
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if ((gv11b_fb_is_fault_buf_enabled(g, NONREPLAY_REG_INDEX))) {
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gv11b_fb_fault_buf_set_state_hw(g, NONREPLAY_REG_INDEX,
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FAULT_BUF_DISABLED);
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}
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if ((gv11b_fb_is_fault_buf_enabled(g, REPLAY_REG_INDEX))) {
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gv11b_fb_fault_buf_set_state_hw(g, REPLAY_REG_INDEX,
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FAULT_BUF_DISABLED);
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}
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if (g->mm.hw_fault_buf_status[NONREPLAY_REG_INDEX] ==
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HW_FAULT_BUF_STATUS_ALLOC_TRUE) {
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nvgpu_dma_unmap_free(vm,
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&g->mm.hw_fault_buf[FAULT_TYPE_OTHER_AND_NONREPLAY]);
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g->mm.hw_fault_buf_status[NONREPLAY_REG_INDEX] =
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HW_FAULT_BUF_STATUS_ALLOC_FALSE;
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}
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if (g->mm.hw_fault_buf_status[REPLAY_REG_INDEX] ==
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HW_FAULT_BUF_STATUS_ALLOC_TRUE) {
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nvgpu_dma_unmap_free(vm,
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&g->mm.hw_fault_buf[FAULT_TYPE_REPLAY]);
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g->mm.hw_fault_buf_status[REPLAY_REG_INDEX] =
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HW_FAULT_BUF_STATUS_ALLOC_FALSE;
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}
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}
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void gv11b_mm_remove_bar2_vm(struct gk20a *g)
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{
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struct mm_gk20a *mm = &g->mm;
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nvgpu_log_fn(g, " ");
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gv11b_mm_mmu_hw_fault_buf_deinit(g);
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nvgpu_free_inst_block(g, &mm->bar2.inst_block);
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nvgpu_vm_put(mm->bar2.vm);
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}
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static void gv11b_mm_mmu_fault_setup_hw(struct gk20a *g)
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{
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if (g->mm.hw_fault_buf_status[NONREPLAY_REG_INDEX] ==
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HW_FAULT_BUF_STATUS_ALLOC_TRUE) {
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gv11b_fb_fault_buf_configure_hw(g, NONREPLAY_REG_INDEX);
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}
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if (g->mm.hw_fault_buf_status[REPLAY_REG_INDEX] ==
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HW_FAULT_BUF_STATUS_ALLOC_TRUE) {
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gv11b_fb_fault_buf_configure_hw(g, REPLAY_REG_INDEX);
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}
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}
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static int gv11b_mm_mmu_fault_setup_sw(struct gk20a *g)
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{
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int err;
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nvgpu_log_fn(g, " ");
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nvgpu_mutex_init(&g->mm.hub_isr_mutex);
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g->mm.hw_fault_buf_status[NONREPLAY_REG_INDEX] =
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HW_FAULT_BUF_STATUS_ALLOC_FALSE;
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g->mm.hw_fault_buf_status[REPLAY_REG_INDEX] =
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HW_FAULT_BUF_STATUS_ALLOC_FALSE;
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g->mm.hub_intr_types = HUB_INTR_TYPE_ECC_UNCORRECTED;
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err = gv11b_mm_mmu_fault_info_buf_init(g, &g->mm.hub_intr_types);
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if (!err)
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gv11b_mm_mmu_hw_fault_buf_init(g, &g->mm.hub_intr_types);
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return err;
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}
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int gv11b_init_mm_setup_hw(struct gk20a *g)
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{
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int err = 0;
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nvgpu_log_fn(g, " ");
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g->ops.fb.set_mmu_page_size(g);
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g->ops.fb.init_hw(g);
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err = g->ops.mm.init_bar2_mm_hw_setup(g);
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if (err)
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return err;
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if (gk20a_mm_fb_flush(g) || gk20a_mm_fb_flush(g))
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return -EBUSY;
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err = gv11b_mm_mmu_fault_setup_sw(g);
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if (!err)
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gv11b_mm_mmu_fault_setup_hw(g);
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nvgpu_log_fn(g, "end");
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return err;
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}
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void gv11b_mm_l2_flush(struct gk20a *g, bool invalidate)
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{
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nvgpu_log(g, gpu_dbg_fn, "gv11b_mm_l2_flush");
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g->ops.mm.fb_flush(g);
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gk20a_mm_l2_flush(g, invalidate);
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g->ops.mm.fb_flush(g);
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}
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/*
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* On Volta the GPU determines whether to do L3 allocation for a mapping by
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* checking bit 36 of the phsyical address. So if a mapping should allocte lines
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* in the L3 this bit must be set.
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*/
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u64 gv11b_gpu_phys_addr(struct gk20a *g,
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struct nvgpu_gmmu_attrs *attrs, u64 phys)
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{
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if (attrs && attrs->t19x_attrs.l3_alloc)
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return phys | NVGPU_L3_ALLOC_BIT;
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return phys;
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}
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int gv11b_init_bar2_mm_hw_setup(struct gk20a *g)
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{
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struct mm_gk20a *mm = &g->mm;
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struct nvgpu_mem *inst_block = &mm->bar2.inst_block;
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u64 inst_pa = nvgpu_inst_block_addr(g, inst_block);
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u32 reg_val;
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struct nvgpu_timeout timeout;
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u32 delay = GR_IDLE_CHECK_DEFAULT;
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nvgpu_log_fn(g, " ");
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g->ops.fb.set_mmu_page_size(g);
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inst_pa = (u32)(inst_pa >> bus_bar2_block_ptr_shift_v());
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nvgpu_log_info(g, "bar2 inst block ptr: 0x%08x", (u32)inst_pa);
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gk20a_writel(g, bus_bar2_block_r(),
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nvgpu_aperture_mask(g, inst_block,
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bus_bar2_block_target_sys_mem_ncoh_f(),
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bus_bar2_block_target_vid_mem_f()) |
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bus_bar2_block_mode_virtual_f() |
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bus_bar2_block_ptr_f(inst_pa));
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/* This is needed as BAR1 support is removed and there is no way
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* to know if gpu successfully accessed memory.
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* To avoid deadlocks and non-deterministic virtual address translation
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* behavior, after writing BAR2_BLOCK to bind BAR2 to a virtual address
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* space, SW must ensure that the bind has completed prior to issuing
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* any further BAR2 requests by polling for both
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* BUS_BIND_STATUS_BAR2_PENDING to return to EMPTY and
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* BUS_BIND_STATUS_BAR2_OUTSTANDING to return to FALSE
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*/
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nvgpu_timeout_init(g, &timeout, gk20a_get_gr_idle_timeout(g),
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NVGPU_TIMER_CPU_TIMER);
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nvgpu_log_info(g, "check bar2 bind status");
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do {
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reg_val = gk20a_readl(g, bus_bind_status_r());
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if (!((reg_val & bus_bind_status_bar2_pending_busy_f()) ||
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(reg_val & bus_bind_status_bar2_outstanding_true_f())))
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return 0;
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nvgpu_usleep_range(delay, delay * 2);
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delay = min_t(u32, delay << 1, GR_IDLE_CHECK_MAX);
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} while (!nvgpu_timeout_expired_msg(&timeout, "bar2 bind timedout"));
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nvgpu_err(g, "bar2 bind failed. gpu unable to access memory");
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return -EBUSY;
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}
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