/*
* GP10B MMU
*
* Copyright (c) 2014-2017, NVIDIA CORPORATION. All rights reserved.
*
* Permission is hereby granted, free of charge, to any person obtaining a
* copy of this software and associated documentation files (the "Software"),
* to deal in the Software without restriction, including without limitation
* the rights to use, copy, modify, merge, publish, distribute, sublicense,
* and/or sell copies of the Software, and to permit persons to whom the
* Software is furnished to do so, subject to the following conditions:
*
* The above copyright notice and this permission notice shall be included in
* all copies or substantial portions of the Software.
*
* THE SOFTWARE IS PROVIDED "AS IS", WITHOUT WARRANTY OF ANY KIND, EXPRESS OR
* IMPLIED, INCLUDING BUT NOT LIMITED TO THE WARRANTIES OF MERCHANTABILITY,
* FITNESS FOR A PARTICULAR PURPOSE AND NONINFRINGEMENT. IN NO EVENT SHALL
* THE AUTHORS OR COPYRIGHT HOLDERS BE LIABLE FOR ANY CLAIM, DAMAGES OR OTHER
* LIABILITY, WHETHER IN AN ACTION OF CONTRACT, TORT OR OTHERWISE, ARISING
* FROM, OUT OF OR IN CONNECTION WITH THE SOFTWARE OR THE USE OR OTHER
* DEALINGS IN THE SOFTWARE.
*/
#include <nvgpu/mm.h>
#include <nvgpu/dma.h>
#include <nvgpu/gmmu.h>
#include <nvgpu/sizes.h>
#include "gk20a/gk20a.h"
#include "gm20b/mm_gm20b.h"
#include "mm_gp10b.h"
#include "rpfb_gp10b.h"
#include <nvgpu/hw/gp10b/hw_fb_gp10b.h>
#include <nvgpu/hw/gp10b/hw_ram_gp10b.h>
#include <nvgpu/hw/gp10b/hw_bus_gp10b.h>
#include <nvgpu/hw/gp10b/hw_gmmu_gp10b.h>
u32 gp10b_mm_get_default_big_page_size(void)
{
return SZ_64K;
}
u32 gp10b_mm_get_iommu_bit(struct gk20a *g)
{
return 36;
}
int gp10b_init_mm_setup_hw(struct gk20a *g)
{
struct mm_gk20a *mm = &g->mm;
struct nvgpu_mem *inst_block = &mm->bar1.inst_block;
int err = 0;
gk20a_dbg_fn("");
g->ops.fb.set_mmu_page_size(g);
gk20a_writel(g, fb_niso_flush_sysmem_addr_r(),
nvgpu_mem_get_addr(g, &g->mm.sysmem_flush) >> 8ULL);
g->ops.bus.bar1_bind(g, inst_block);
if (g->ops.mm.init_bar2_mm_hw_setup) {
err = g->ops.mm.init_bar2_mm_hw_setup(g);
if (err)
return err;
}
if (gk20a_mm_fb_flush(g) || gk20a_mm_fb_flush(g))
return -EBUSY;
err = gp10b_replayable_pagefault_buffer_init(g);
gk20a_dbg_fn("done");
return err;
}
int gp10b_init_bar2_vm(struct gk20a *g)
{
int err;
struct mm_gk20a *mm = &g->mm;
struct nvgpu_mem *inst_block = &mm->bar2.inst_block;
u32 big_page_size = g->ops.mm.get_default_big_page_size();
/* BAR2 aperture size is 32MB */
mm->bar2.aperture_size = 32 << 20;
gk20a_dbg_info("bar2 vm size = 0x%x", mm->bar2.aperture_size);
mm->bar2.vm = nvgpu_vm_init(g, big_page_size, SZ_4K,
mm->bar2.aperture_size - SZ_4K,
mm->bar2.aperture_size, false, false, "bar2");
if (!mm->bar2.vm)
return -ENOMEM;
/* allocate instance mem for bar2 */
err = g->ops.mm.alloc_inst_block(g, inst_block);
if (err)
goto clean_up_va;
g->ops.mm.init_inst_block(inst_block, mm->bar2.vm, big_page_size);
return 0;
clean_up_va:
nvgpu_vm_put(mm->bar2.vm);
return err;
}
int gp10b_init_bar2_mm_hw_setup(struct gk20a *g)
{
struct mm_gk20a *mm = &g->mm;
struct nvgpu_mem *inst_block = &mm->bar2.inst_block;
u64 inst_pa = nvgpu_inst_block_addr(g, inst_block);
gk20a_dbg_fn("");
g->ops.fb.set_mmu_page_size(g);
inst_pa = (u32)(inst_pa >> bus_bar2_block_ptr_shift_v());
gk20a_dbg_info("bar2 inst block ptr: 0x%08x", (u32)inst_pa);
gk20a_writel(g, bus_bar2_block_r(),
nvgpu_aperture_mask(g, inst_block,
bus_bar2_block_target_sys_mem_ncoh_f(),
bus_bar2_block_target_vid_mem_f()) |
bus_bar2_block_mode_virtual_f() |
bus_bar2_block_ptr_f(inst_pa));
gk20a_dbg_fn("done");
return 0;
}
static void update_gmmu_pde3_locked(struct vm_gk20a *vm,
const struct gk20a_mmu_level *l,
struct nvgpu_gmmu_pd *pd,
u32 pd_idx,
u64 virt_addr,
u64 phys_addr,
struct nvgpu_gmmu_attrs *attrs)
{
struct gk20a *g = gk20a_from_vm(vm);
u32 pd_offset = pd_offset_from_index(l, pd_idx);
u32 pde_v[2] = {0, 0};
phys_addr >>= gmmu_new_pde_address_shift_v();
pde_v[0] |= nvgpu_aperture_mask(g, pd->mem,
gmmu_new_pde_aperture_sys_mem_ncoh_f(),
gmmu_new_pde_aperture_video_memory_f());
pde_v[0] |= gmmu_new_pde_address_sys_f(u64_lo32(phys_addr));
pde_v[0] |= gmmu_new_pde_vol_true_f();
pde_v[1] |= phys_addr >> 24;
pd_write(g, pd, pd_offset + 0, pde_v[0]);
pd_write(g, pd, pd_offset + 1, pde_v[1]);
pte_dbg(g, attrs,
"PDE: i=%-4u size=%-2u offs=%-4u pgsz: -- | "
"GPU %#-12llx phys %#-12llx "
"[0x%08x, 0x%08x]",
pd_idx, l->entry_size, pd_offset,
virt_addr, phys_addr,
pde_v[1], pde_v[0]);
}
static void update_gmmu_pde0_locked(struct vm_gk20a *vm,
const struct gk20a_mmu_level *l,
struct nvgpu_gmmu_pd *pd,
u32 pd_idx,
u64 virt_addr,
u64 phys_addr,
struct nvgpu_gmmu_attrs *attrs)
{
struct gk20a *g = gk20a_from_vm(vm);
bool small_valid, big_valid;
u32 small_addr = 0, big_addr = 0;
u32 pd_offset = pd_offset_from_index(l, pd_idx);
u32 pde_v[4] = {0, 0, 0, 0};
small_valid = attrs->pgsz == gmmu_page_size_small;
big_valid = attrs->pgsz == gmmu_page_size_big;
if (small_valid)
small_addr = phys_addr >> gmmu_new_dual_pde_address_shift_v();
if (big_valid)
big_addr = phys_addr >> gmmu_new_dual_pde_address_big_shift_v();
if (small_valid) {
pde_v[2] |=
gmmu_new_dual_pde_address_small_sys_f(small_addr);
pde_v[2] |= nvgpu_aperture_mask(g, pd->mem,
gmmu_new_dual_pde_aperture_small_sys_mem_ncoh_f(),
gmmu_new_dual_pde_aperture_small_video_memory_f());
pde_v[2] |= gmmu_new_dual_pde_vol_small_true_f();
pde_v[3] |= small_addr >> 24;
}
if (big_valid) {
pde_v[0] |= gmmu_new_dual_pde_address_big_sys_f(big_addr);
pde_v[0] |= gmmu_new_dual_pde_vol_big_true_f();
pde_v[0] |= nvgpu_aperture_mask(g, pd->mem,
gmmu_new_dual_pde_aperture_big_sys_mem_ncoh_f(),
gmmu_new_dual_pde_aperture_big_video_memory_f());
pde_v[1] |= big_addr >> 28;
}
pd_write(g, pd, pd_offset + 0, pde_v[0]);
pd_write(g, pd, pd_offset + 1, pde_v[1]);
pd_write(g, pd, pd_offset + 2, pde_v[2]);
pd_write(g, pd, pd_offset + 3, pde_v[3]);
pte_dbg(g, attrs,
"PDE: i=%-4u size=%-2u offs=%-4u pgsz: %c%c | "
"GPU %#-12llx phys %#-12llx "
"[0x%08x, 0x%08x, 0x%08x, 0x%08x]",
pd_idx, l->entry_size, pd_offset,
small_valid ? 'S' : '-',
big_valid ? 'B' : '-',
virt_addr, phys_addr,
pde_v[3], pde_v[2], pde_v[1], pde_v[0]);
}
static void __update_pte(struct vm_gk20a *vm,
u32 *pte_w,
u64 phys_addr,
struct nvgpu_gmmu_attrs *attrs)
{
struct gk20a *g = gk20a_from_vm(vm);
u64 ctag_granularity = g->ops.fb.compression_page_size(g);
u32 page_size = vm->gmmu_page_sizes[attrs->pgsz];
u32 pte_valid = attrs->valid ?
gmmu_new_pte_valid_true_f() :
gmmu_new_pte_valid_false_f();
u32 phys_shifted = phys_addr >> gmmu_new_pte_address_shift_v();
u32 pte_addr = attrs->aperture == APERTURE_SYSMEM ?
gmmu_new_pte_address_sys_f(phys_shifted) :
gmmu_new_pte_address_vid_f(phys_shifted);
u32 pte_tgt = __nvgpu_aperture_mask(g,
attrs->aperture,
attrs->coherent ?
gmmu_new_pte_aperture_sys_mem_coh_f() :
gmmu_new_pte_aperture_sys_mem_ncoh_f(),
gmmu_new_pte_aperture_video_memory_f());
pte_w[0] = pte_valid | pte_addr | pte_tgt;
if (attrs->priv)
pte_w[0] |= gmmu_new_pte_privilege_true_f();
pte_w[1] = phys_addr >> (24 + gmmu_new_pte_address_shift_v()) |
gmmu_new_pte_kind_f(attrs->kind_v) |
gmmu_new_pte_comptagline_f((u32)(attrs->ctag /
ctag_granularity));
if (attrs->rw_flag == gk20a_mem_flag_read_only)
pte_w[0] |= gmmu_new_pte_read_only_true_f();
if (!attrs->valid && !attrs->cacheable)
pte_w[0] |= gmmu_new_pte_read_only_true_f();
else if (!attrs->cacheable)
pte_w[0] |= gmmu_new_pte_vol_true_f();
if (attrs->ctag)
attrs->ctag += page_size;
}
static void __update_pte_sparse(u32 *pte_w)
{
pte_w[0] = gmmu_new_pte_valid_false_f();
pte_w[0] |= gmmu_new_pte_vol_true_f();
}
static void update_gmmu_pte_locked(struct vm_gk20a *vm,
const struct gk20a_mmu_level *l,
struct nvgpu_gmmu_pd *pd,
u32 pd_idx,
u64 virt_addr,
u64 phys_addr,
struct nvgpu_gmmu_attrs *attrs)
{
struct gk20a *g = vm->mm->g;
u32 page_size = vm->gmmu_page_sizes[attrs->pgsz];
u32 pd_offset = pd_offset_from_index(l, pd_idx);
u32 pte_w[2] = {0, 0};
if (phys_addr)
__update_pte(vm, pte_w, phys_addr, attrs);
else if (attrs->sparse)
__update_pte_sparse(pte_w);
pte_dbg(g, attrs,
"vm=%s "
"PTE: i=%-4u size=%-2u | "
"GPU %#-12llx phys %#-12llx "
"pgsz: %3dkb perm=%-2s kind=%#02x APT=%-6s %c%c%c%c%c "
"ctag=0x%08x "
"[0x%08x, 0x%08x]",
vm->name,
pd_idx, l->entry_size,
virt_addr, phys_addr,
page_size >> 10,
nvgpu_gmmu_perm_str(attrs->rw_flag),
attrs->kind_v,
nvgpu_aperture_str(attrs->aperture),
attrs->cacheable ? 'C' : 'v',
attrs->sparse ? 'S' : '-',
attrs->priv ? 'P' : '-',
attrs->coherent ? 'c' : '-',
attrs->valid ? 'V' : '-',
(u32)attrs->ctag / g->ops.fb.compression_page_size(g),
pte_w[1], pte_w[0]);
pd_write(g, pd, pd_offset + 0, pte_w[0]);
pd_write(g, pd, pd_offset + 1, pte_w[1]);
}
#define GP10B_PDE0_ENTRY_SIZE 16
/*
* Calculate the pgsz of the pde level
* Pascal+ implements a 5 level page table structure with only the last
* level having a different number of entries depending on whether it holds
* big pages or small pages.
*/
static enum gmmu_pgsz_gk20a gp10b_get_pde0_pgsz(struct gk20a *g,
const struct gk20a_mmu_level *l,
struct nvgpu_gmmu_pd *pd, u32 pd_idx)
{
u32 pde_base = pd->mem_offs / sizeof(u32);
u32 pde_offset = pde_base + pd_offset_from_index(l, pd_idx);
u32 pde_v[GP10B_PDE0_ENTRY_SIZE >> 2];
u32 i;
enum gmmu_pgsz_gk20a pgsz = gmmu_nr_page_sizes;
if (!pd->mem)
return pgsz;
nvgpu_mem_begin(g, pd->mem);
for (i = 0; i < GP10B_PDE0_ENTRY_SIZE >> 2; i++)
pde_v[i] = nvgpu_mem_rd32(g, pd->mem, pde_offset + i);
nvgpu_mem_end(g, pd->mem);
/*
* Check if the aperture AND address are set
*/
if (pde_v[2] & (gmmu_new_dual_pde_aperture_small_sys_mem_ncoh_f() |
gmmu_new_dual_pde_aperture_small_video_memory_f())) {
u64 addr = (((u64) pde_v[3] << 32) | (u64) (pde_v[2] &
gmmu_new_dual_pde_address_small_sys_f(~0))) <<
gmmu_new_dual_pde_address_shift_v();
if (addr)
pgsz = gmmu_page_size_small;
}
if (pde_v[0] & (gmmu_new_dual_pde_aperture_big_sys_mem_ncoh_f() |
gmmu_new_dual_pde_aperture_big_video_memory_f())) {
u64 addr = (((u64) pde_v[1] << 32) | (u64) (pde_v[0] &
gmmu_new_dual_pde_address_big_sys_f(~0))) <<
gmmu_new_dual_pde_address_big_shift_v();
if (addr) {
/*
* If small is set that means that somehow MM allowed
* both small and big to be set, the PDE is not valid
* and may be corrupted
*/
if (pgsz == gmmu_page_size_small) {
nvgpu_err(g,
"both small and big apertures enabled");
return gmmu_nr_page_sizes;
}
pgsz = gmmu_page_size_big;
}
}
return pgsz;
}
static const struct gk20a_mmu_level gp10b_mm_levels[] = {
{.hi_bit = {48, 48},
.lo_bit = {47, 47},
.update_entry = update_gmmu_pde3_locked,
.entry_size = 8,
.get_pgsz = gk20a_get_pde_pgsz},
{.hi_bit = {46, 46},
.lo_bit = {38, 38},
.update_entry = update_gmmu_pde3_locked,
.entry_size = 8,
.get_pgsz = gk20a_get_pde_pgsz},
{.hi_bit = {37, 37},
.lo_bit = {29, 29},
.update_entry = update_gmmu_pde3_locked,
.entry_size = 8,
.get_pgsz = gk20a_get_pde_pgsz},
{.hi_bit = {28, 28},
.lo_bit = {21, 21},
.update_entry = update_gmmu_pde0_locked,
.entry_size = GP10B_PDE0_ENTRY_SIZE,
.get_pgsz = gp10b_get_pde0_pgsz},
{.hi_bit = {20, 20},
.lo_bit = {12, 16},
.update_entry = update_gmmu_pte_locked,
.entry_size = 8,
.get_pgsz = gk20a_get_pte_pgsz},
{.update_entry = NULL}
};
const struct gk20a_mmu_level *gp10b_mm_get_mmu_levels(struct gk20a *g,
u32 big_page_size)
{
return gp10b_mm_levels;
}
void gp10b_mm_init_pdb(struct gk20a *g, struct nvgpu_mem *inst_block,
struct vm_gk20a *vm)
{
u64 pdb_addr = nvgpu_mem_get_addr(g, vm->pdb.mem);
u32 pdb_addr_lo = u64_lo32(pdb_addr >> ram_in_base_shift_v());
u32 pdb_addr_hi = u64_hi32(pdb_addr);
gk20a_dbg_info("pde pa=0x%llx", pdb_addr);
nvgpu_mem_wr32(g, inst_block, ram_in_page_dir_base_lo_w(),
nvgpu_aperture_mask(g, vm->pdb.mem,
ram_in_page_dir_base_target_sys_mem_ncoh_f(),
ram_in_page_dir_base_target_vid_mem_f()) |
ram_in_page_dir_base_vol_true_f() |
ram_in_big_page_size_64kb_f() |
ram_in_page_dir_base_lo_f(pdb_addr_lo) |
ram_in_use_ver2_pt_format_true_f());
nvgpu_mem_wr32(g, inst_block, ram_in_page_dir_base_hi_w(),
ram_in_page_dir_base_hi_f(pdb_addr_hi));
}
void gp10b_remove_bar2_vm(struct gk20a *g)
{
struct mm_gk20a *mm = &g->mm;
gp10b_replayable_pagefault_buffer_deinit(g);
nvgpu_free_inst_block(g, &mm->bar2.inst_block);
nvgpu_vm_put(mm->bar2.vm);
}