/*
* GK20A memory management
*
* Copyright (c) 2011-2016, NVIDIA CORPORATION. All rights reserved.
*
* This program is free software; you can redistribute it and/or modify it
* under the terms and conditions of the GNU General Public License,
* version 2, as published by the Free Software Foundation.
*
* This program is distributed in the hope 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, see <http://www.gnu.org/licenses/>.
*/
#include <linux/delay.h>
#include <linux/highmem.h>
#include <linux/log2.h>
#include <linux/nvhost.h>
#include <linux/pm_runtime.h>
#include <linux/scatterlist.h>
#include <linux/nvmap.h>
#include <linux/tegra-soc.h>
#include <linux/vmalloc.h>
#include <linux/dma-buf.h>
#include <linux/lcm.h>
#include <linux/fdtable.h>
#include <uapi/linux/nvgpu.h>
#include <trace/events/gk20a.h>
#include <gk20a/page_allocator_priv.h>
#include <nvgpu/timers.h>
#include "gk20a.h"
#include "mm_gk20a.h"
#include "fence_gk20a.h"
#include "hw_gmmu_gk20a.h"
#include "hw_fb_gk20a.h"
#include "hw_bus_gk20a.h"
#include "hw_ram_gk20a.h"
#include "hw_pram_gk20a.h"
#include "hw_mc_gk20a.h"
#include "hw_flush_gk20a.h"
#include "hw_ltc_gk20a.h"
#include "kind_gk20a.h"
#include "semaphore_gk20a.h"
/*
* Flip this to force all gk20a_mem* accesses via PRAMIN from the start of the
* boot, even for buffers that would work via cpu_va. In runtime, the flag is
* in debugfs, called "force_pramin".
*/
#define GK20A_FORCE_PRAMIN_DEFAULT false
#if defined(CONFIG_GK20A_VIDMEM)
static void gk20a_vidmem_clear_mem_worker(struct work_struct *work);
#endif
static inline void
set_vidmem_page_alloc(struct scatterlist *sgl, u64 addr)
{
/* set bit 0 to indicate vidmem allocation */
sg_dma_address(sgl) = (addr | 1ULL);
}
static inline bool
is_vidmem_page_alloc(u64 addr)
{
return !!(addr & 1ULL);
}
static inline struct gk20a_page_alloc *
get_vidmem_page_alloc(struct scatterlist *sgl)
{
u64 addr;
addr = sg_dma_address(sgl);
if (is_vidmem_page_alloc(addr))
addr = addr & ~1ULL;
else
WARN_ON(1);
return (struct gk20a_page_alloc *)(uintptr_t)addr;
}
int gk20a_mem_begin(struct gk20a *g, struct mem_desc *mem)
{
void *cpu_va;
if (mem->aperture != APERTURE_SYSMEM || g->mm.force_pramin)
return 0;
if (WARN_ON(mem->cpu_va)) {
gk20a_warn(dev_from_gk20a(g), "nested %s", __func__);
return -EBUSY;
}
cpu_va = vmap(mem->pages,
PAGE_ALIGN(mem->size) >> PAGE_SHIFT,
0, pgprot_writecombine(PAGE_KERNEL));
if (WARN_ON(!cpu_va))
return -ENOMEM;
mem->cpu_va = cpu_va;
return 0;
}
void gk20a_mem_end(struct gk20a *g, struct mem_desc *mem)
{
if (mem->aperture != APERTURE_SYSMEM || g->mm.force_pramin)
return;
vunmap(mem->cpu_va);
mem->cpu_va = NULL;
}
/* WARNING: returns pramin_window_lock taken, complement with pramin_exit() */
static u32 gk20a_pramin_enter(struct gk20a *g, struct mem_desc *mem,
struct page_alloc_chunk *chunk, u32 w)
{
u64 bufbase = chunk->base;
u64 addr = bufbase + w * sizeof(u32);
u32 hi = (u32)((addr & ~(u64)0xfffff)
>> bus_bar0_window_target_bar0_window_base_shift_v());
u32 lo = (u32)(addr & 0xfffff);
u32 win = gk20a_aperture_mask(g, mem,
bus_bar0_window_target_sys_mem_noncoherent_f(),
bus_bar0_window_target_vid_mem_f()) |
bus_bar0_window_base_f(hi);
gk20a_dbg(gpu_dbg_mem,
"0x%08x:%08x begin for %p,%p at [%llx,%llx] (sz %llx)",
hi, lo, mem, chunk, bufbase,
bufbase + chunk->length, chunk->length);
WARN_ON(!bufbase);
spin_lock(&g->mm.pramin_window_lock);
if (g->mm.pramin_window != win) {
gk20a_writel(g, bus_bar0_window_r(), win);
gk20a_readl(g, bus_bar0_window_r());
g->mm.pramin_window = win;
}
return lo;
}
static void gk20a_pramin_exit(struct gk20a *g, struct mem_desc *mem,
struct page_alloc_chunk *chunk)
{
gk20a_dbg(gpu_dbg_mem, "end for %p,%p", mem, chunk);
spin_unlock(&g->mm.pramin_window_lock);
}
/*
* Batch innerloop for the function below once per each PRAMIN range (some
* 4B..1MB at a time). "start" reg goes as-is to gk20a_{readl,writel}.
*/
typedef void (*pramin_access_batch_fn)(struct gk20a *g, u32 start, u32 words,
u32 **arg);
/*
* The PRAMIN range is 1 MB, must change base addr if a buffer crosses that.
* This same loop is used for read/write/memset. Offset and size in bytes.
* One call to "loop" is done per range, with "arg" supplied.
*/
static inline void pramin_access_batched(struct gk20a *g, struct mem_desc *mem,
u32 offset, u32 size, pramin_access_batch_fn loop, u32 **arg)
{
struct gk20a_page_alloc *alloc = NULL;
struct page_alloc_chunk *chunk = NULL;
u32 byteoff, start_reg, until_end, n;
alloc = get_vidmem_page_alloc(mem->sgt->sgl);
list_for_each_entry(chunk, &alloc->alloc_chunks, list_entry) {
if (offset >= chunk->length)
offset -= chunk->length;
else
break;
}
offset /= sizeof(u32);
while (size) {
byteoff = gk20a_pramin_enter(g, mem, chunk, offset);
start_reg = pram_data032_r(byteoff / sizeof(u32));
until_end = SZ_1M - (byteoff & (SZ_1M - 1));
n = min3(size, until_end, (u32)(chunk->length - offset));
loop(g, start_reg, n / sizeof(u32), arg);
/* read back to synchronize accesses */
gk20a_readl(g, start_reg);
gk20a_pramin_exit(g, mem, chunk);
size -= n;
if (n == (chunk->length - offset)) {
chunk = list_next_entry(chunk, list_entry);
offset = 0;
} else {
offset += n / sizeof(u32);
}
}
}
static inline void pramin_access_batch_rd_n(struct gk20a *g, u32 start,
u32 words, u32 **arg)
{
u32 r = start, *dest_u32 = *arg;
while (words--) {
*dest_u32++ = gk20a_readl(g, r);
r += sizeof(u32);
}
*arg = dest_u32;
}
static inline void pramin_access_batch_wr_n(struct gk20a *g, u32 start,
u32 words, u32 **arg)
{
u32 r = start, *src_u32 = *arg;
while (words--) {
writel_relaxed(*src_u32++, g->regs + r);
r += sizeof(u32);
}
*arg = src_u32;
}
static inline void pramin_access_batch_set(struct gk20a *g, u32 start,
u32 words, u32 **arg)
{
u32 r = start, repeat = **arg;
while (words--) {
writel_relaxed(repeat, g->regs + r);
r += sizeof(u32);
}
}
u32 gk20a_mem_rd32(struct gk20a *g, struct mem_desc *mem, u32 w)
{
u32 data = 0;
if (mem->aperture == APERTURE_SYSMEM && !g->mm.force_pramin) {
u32 *ptr = mem->cpu_va;
WARN_ON(!ptr);
data = ptr[w];
#ifdef CONFIG_TEGRA_SIMULATION_PLATFORM
gk20a_dbg(gpu_dbg_mem, " %p = 0x%x", ptr + w, data);
#endif
} else if (mem->aperture == APERTURE_VIDMEM || g->mm.force_pramin) {
u32 value;
u32 *p = &value;
pramin_access_batched(g, mem, w * sizeof(u32), sizeof(u32),
pramin_access_batch_rd_n, &p);
data = value;
} else {
WARN_ON("Accessing unallocated mem_desc");
}
return data;
}
u32 gk20a_mem_rd(struct gk20a *g, struct mem_desc *mem, u32 offset)
{
WARN_ON(offset & 3);
return gk20a_mem_rd32(g, mem, offset / sizeof(u32));
}
void gk20a_mem_rd_n(struct gk20a *g, struct mem_desc *mem,
u32 offset, void *dest, u32 size)
{
WARN_ON(offset & 3);
WARN_ON(size & 3);
if (mem->aperture == APERTURE_SYSMEM && !g->mm.force_pramin) {
u8 *src = (u8 *)mem->cpu_va + offset;
WARN_ON(!mem->cpu_va);
memcpy(dest, src, size);
#ifdef CONFIG_TEGRA_SIMULATION_PLATFORM
if (size)
gk20a_dbg(gpu_dbg_mem, " %p = 0x%x ... [%d bytes]",
src, *dest, size);
#endif
} else if (mem->aperture == APERTURE_VIDMEM || g->mm.force_pramin) {
u32 *dest_u32 = dest;
pramin_access_batched(g, mem, offset, size,
pramin_access_batch_rd_n, &dest_u32);
} else {
WARN_ON("Accessing unallocated mem_desc");
}
}
void gk20a_mem_wr32(struct gk20a *g, struct mem_desc *mem, u32 w, u32 data)
{
if (mem->aperture == APERTURE_SYSMEM && !g->mm.force_pramin) {
u32 *ptr = mem->cpu_va;
WARN_ON(!ptr);
#ifdef CONFIG_TEGRA_SIMULATION_PLATFORM
gk20a_dbg(gpu_dbg_mem, " %p = 0x%x", ptr + w, data);
#endif
ptr[w] = data;
} else if (mem->aperture == APERTURE_VIDMEM || g->mm.force_pramin) {
u32 value = data;
u32 *p = &value;
pramin_access_batched(g, mem, w * sizeof(u32), sizeof(u32),
pramin_access_batch_wr_n, &p);
if (!mem->skip_wmb)
wmb();
} else {
WARN_ON("Accessing unallocated mem_desc");
}
}
void gk20a_mem_wr(struct gk20a *g, struct mem_desc *mem, u32 offset, u32 data)
{
WARN_ON(offset & 3);
gk20a_mem_wr32(g, mem, offset / sizeof(u32), data);
}
void gk20a_mem_wr_n(struct gk20a *g, struct mem_desc *mem, u32 offset,
void *src, u32 size)
{
WARN_ON(offset & 3);
WARN_ON(size & 3);
if (mem->aperture == APERTURE_SYSMEM && !g->mm.force_pramin) {
u8 *dest = (u8 *)mem->cpu_va + offset;
WARN_ON(!mem->cpu_va);
#ifdef CONFIG_TEGRA_SIMULATION_PLATFORM
if (size)
gk20a_dbg(gpu_dbg_mem, " %p = 0x%x ... [%d bytes]",
dest, *src, size);
#endif
memcpy(dest, src, size);
} else if (mem->aperture == APERTURE_VIDMEM || g->mm.force_pramin) {
u32 *src_u32 = src;
pramin_access_batched(g, mem, offset, size,
pramin_access_batch_wr_n, &src_u32);
if (!mem->skip_wmb)
wmb();
} else {
WARN_ON("Accessing unallocated mem_desc");
}
}
void gk20a_memset(struct gk20a *g, struct mem_desc *mem, u32 offset,
u32 c, u32 size)
{
WARN_ON(offset & 3);
WARN_ON(size & 3);
WARN_ON(c & ~0xff);
c &= 0xff;
if (mem->aperture == APERTURE_SYSMEM && !g->mm.force_pramin) {
u8 *dest = (u8 *)mem->cpu_va + offset;
WARN_ON(!mem->cpu_va);
#ifdef CONFIG_TEGRA_SIMULATION_PLATFORM
if (size)
gk20a_dbg(gpu_dbg_mem, " %p = 0x%x [times %d]",
dest, c, size);
#endif
memset(dest, c, size);
} else if (mem->aperture == APERTURE_VIDMEM || g->mm.force_pramin) {
u32 repeat_value = c | (c << 8) | (c << 16) | (c << 24);
u32 *p = &repeat_value;
pramin_access_batched(g, mem, offset, size,
pramin_access_batch_set, &p);
if (!mem->skip_wmb)
wmb();
} else {
WARN_ON("Accessing unallocated mem_desc");
}
}
/*
* GPU mapping life cycle
* ======================
*
* Kernel mappings
* ---------------
*
* Kernel mappings are created through vm.map(..., false):
*
* - Mappings to the same allocations are reused and refcounted.
* - This path does not support deferred unmapping (i.e. kernel must wait for
* all hw operations on the buffer to complete before unmapping).
* - References to dmabuf are owned and managed by the (kernel) clients of
* the gk20a_vm layer.
*
*
* User space mappings
* -------------------
*
* User space mappings are created through as.map_buffer -> vm.map(..., true):
*
* - Mappings to the same allocations are reused and refcounted.
* - This path supports deferred unmapping (i.e. we delay the actual unmapping
* until all hw operations have completed).
* - References to dmabuf are owned and managed by the vm_gk20a
* layer itself. vm.map acquires these refs, and sets
* mapped_buffer->own_mem_ref to record that we must release the refs when we
* actually unmap.
*
*/
static inline int vm_aspace_id(struct vm_gk20a *vm)
{
/* -1 is bar1 or pmu, etc. */
return vm->as_share ? vm->as_share->id : -1;
}
static inline u32 hi32(u64 f)
{
return (u32)(f >> 32);
}
static inline u32 lo32(u64 f)
{
return (u32)(f & 0xffffffff);
}
static struct mapped_buffer_node *find_mapped_buffer_locked(
struct rb_root *root, u64 addr);
static struct mapped_buffer_node *find_mapped_buffer_reverse_locked(
struct rb_root *root, struct dma_buf *dmabuf,
u32 kind);
static int update_gmmu_ptes_locked(struct vm_gk20a *vm,
enum gmmu_pgsz_gk20a pgsz_idx,
struct sg_table *sgt, u64 buffer_offset,
u64 first_vaddr, u64 last_vaddr,
u8 kind_v, u32 ctag_offset, bool cacheable,
bool umapped_pte, int rw_flag,
bool sparse,
bool priv,
enum gk20a_aperture aperture);
static int __must_check gk20a_init_system_vm(struct mm_gk20a *mm);
static int __must_check gk20a_init_bar1_vm(struct mm_gk20a *mm);
static int __must_check gk20a_init_hwpm(struct mm_gk20a *mm);
static int __must_check gk20a_init_cde_vm(struct mm_gk20a *mm);
static int __must_check gk20a_init_ce_vm(struct mm_gk20a *mm);
static struct gk20a *gk20a_vidmem_buf_owner(struct dma_buf *dmabuf);
struct gk20a_dmabuf_priv {
struct mutex lock;
struct gk20a_comptag_allocator *comptag_allocator;
struct gk20a_comptags comptags;
struct dma_buf_attachment *attach;
struct sg_table *sgt;
int pin_count;
struct list_head states;
u64 buffer_id;
};
struct gk20a_vidmem_buf {
struct gk20a *g;
struct mem_desc *mem;
struct dma_buf *dmabuf;
void *dmabuf_priv;
void (*dmabuf_priv_delete)(void *);
};
static void gk20a_vm_remove_support_nofree(struct vm_gk20a *vm);
static int gk20a_comptaglines_alloc(struct gk20a_comptag_allocator *allocator,
u32 *offset, u32 len)
{
unsigned long addr;
int err = 0;
mutex_lock(&allocator->lock);
addr = bitmap_find_next_zero_area(allocator->bitmap, allocator->size,
0, len, 0);
if (addr < allocator->size) {
/* number zero is reserved; bitmap base is 1 */
*offset = 1 + addr;
bitmap_set(allocator->bitmap, addr, len);
} else {
err = -ENOMEM;
}
mutex_unlock(&allocator->lock);
return err;
}
static void gk20a_comptaglines_free(struct gk20a_comptag_allocator *allocator,
u32 offset, u32 len)
{
/* number zero is reserved; bitmap base is 1 */
u32 addr = offset - 1;
WARN_ON(offset == 0);
WARN_ON(addr > allocator->size);
WARN_ON(addr + len > allocator->size);
mutex_lock(&allocator->lock);
bitmap_clear(allocator->bitmap, addr, len);
mutex_unlock(&allocator->lock);
}
static void gk20a_mm_delete_priv(void *_priv)
{
struct gk20a_buffer_state *s, *s_tmp;
struct gk20a_dmabuf_priv *priv = _priv;
if (!priv)
return;
if (priv->comptags.lines) {
BUG_ON(!priv->comptag_allocator);
gk20a_comptaglines_free(priv->comptag_allocator,
priv->comptags.offset,
priv->comptags.allocated_lines);
}
/* Free buffer states */
list_for_each_entry_safe(s, s_tmp, &priv->states, list) {
gk20a_fence_put(s->fence);
list_del(&s->list);
kfree(s);
}
kfree(priv);
}
struct sg_table *gk20a_mm_pin(struct device *dev, struct dma_buf *dmabuf)
{
struct gk20a_dmabuf_priv *priv;
priv = dma_buf_get_drvdata(dmabuf, dev);
if (WARN_ON(!priv))
return ERR_PTR(-EINVAL);
mutex_lock(&priv->lock);
if (priv->pin_count == 0) {
priv->attach = dma_buf_attach(dmabuf, dev);
if (IS_ERR(priv->attach)) {
mutex_unlock(&priv->lock);
return (struct sg_table *)priv->attach;
}
priv->sgt = dma_buf_map_attachment(priv->attach,
DMA_BIDIRECTIONAL);
if (IS_ERR(priv->sgt)) {
dma_buf_detach(dmabuf, priv->attach);
mutex_unlock(&priv->lock);
return priv->sgt;
}
}
priv->pin_count++;
mutex_unlock(&priv->lock);
return priv->sgt;
}
void gk20a_mm_unpin(struct device *dev, struct dma_buf *dmabuf,
struct sg_table *sgt)
{
struct gk20a_dmabuf_priv *priv = dma_buf_get_drvdata(dmabuf, dev);
dma_addr_t dma_addr;
if (IS_ERR(priv) || !priv)
return;
mutex_lock(&priv->lock);
WARN_ON(priv->sgt != sgt);
priv->pin_count--;
WARN_ON(priv->pin_count < 0);
dma_addr = sg_dma_address(priv->sgt->sgl);
if (priv->pin_count == 0) {
dma_buf_unmap_attachment(priv->attach, priv->sgt,
DMA_BIDIRECTIONAL);
dma_buf_detach(dmabuf, priv->attach);
}
mutex_unlock(&priv->lock);
}
void gk20a_get_comptags(struct device *dev, struct dma_buf *dmabuf,
struct gk20a_comptags *comptags)
{
struct gk20a_dmabuf_priv *priv = dma_buf_get_drvdata(dmabuf, dev);
if (!comptags)
return;
if (!priv) {
memset(comptags, 0, sizeof(*comptags));
return;
}
*comptags = priv->comptags;
}
static int gk20a_alloc_comptags(struct gk20a *g,
struct device *dev,
struct dma_buf *dmabuf,
struct gk20a_comptag_allocator *allocator,
u32 lines, bool user_mappable,
u64 *ctag_map_win_size,
u32 *ctag_map_win_ctagline)
{
struct gk20a_dmabuf_priv *priv = dma_buf_get_drvdata(dmabuf, dev);
u32 ctaglines_allocsize;
u32 ctagline_align;
u32 offset;
u32 alignment_lines;
const u32 aggregate_cacheline_sz =
g->gr.cacheline_size * g->gr.slices_per_ltc *
g->ltc_count;
const u32 small_pgsz = 4096;
int err;
if (!priv)
return -ENOSYS;
if (!lines)
return -EINVAL;
if (!user_mappable) {
ctaglines_allocsize = lines;
ctagline_align = 1;
} else {
/*
* For security, align the allocation on a page, and reserve
* whole pages. Unfortunately, we cannot ask the allocator to
* align here, since compbits per cacheline is not always a
* power of two. So, we just have to allocate enough extra that
* we're guaranteed to find a ctagline inside the allocation so
* that: 1) it is the first ctagline in a cacheline that starts
* at a page boundary, and 2) we can add enough overallocation
* that the ctaglines of the succeeding allocation are on
* different page than ours.
*/
ctagline_align =
(lcm(aggregate_cacheline_sz, small_pgsz) /
aggregate_cacheline_sz) *
g->gr.comptags_per_cacheline;
ctaglines_allocsize =
/* for alignment */
ctagline_align +
/* lines rounded up to cachelines */
DIV_ROUND_UP(lines, g->gr.comptags_per_cacheline) *
g->gr.comptags_per_cacheline +
/* trail-padding */
DIV_ROUND_UP(aggregate_cacheline_sz, small_pgsz) *
g->gr.comptags_per_cacheline;
if (ctaglines_allocsize < lines)
return -EINVAL; /* integer overflow */
}
/* store the allocator so we can use it when we free the ctags */
priv->comptag_allocator = allocator;
err = gk20a_comptaglines_alloc(allocator, &offset,
ctaglines_allocsize);
if (err)
return err;
/*
* offset needs to be at the start of a page/cacheline boundary;
* prune the preceding ctaglines that were allocated for alignment.
*/
alignment_lines =
DIV_ROUND_UP(offset, ctagline_align) * ctagline_align - offset;
if (alignment_lines) {
gk20a_comptaglines_free(allocator, offset, alignment_lines);
offset += alignment_lines;
ctaglines_allocsize -= alignment_lines;
}
/*
* check if we can prune the trailing, too; we just need to reserve
* whole pages and ctagcachelines.
*/
if (user_mappable) {
u32 needed_cachelines =
DIV_ROUND_UP(lines, g->gr.comptags_per_cacheline);
u32 needed_bytes = round_up(needed_cachelines *
aggregate_cacheline_sz,
small_pgsz);
u32 first_unneeded_cacheline =
DIV_ROUND_UP(needed_bytes, aggregate_cacheline_sz);
u32 needed_ctaglines = first_unneeded_cacheline *
g->gr.comptags_per_cacheline;
u64 win_size;
if (needed_ctaglines < ctaglines_allocsize) {
gk20a_comptaglines_free(allocator,
offset + needed_ctaglines,
ctaglines_allocsize - needed_ctaglines);
ctaglines_allocsize = needed_ctaglines;
}
*ctag_map_win_ctagline = offset;
win_size =
DIV_ROUND_UP(lines, g->gr.comptags_per_cacheline) *
aggregate_cacheline_sz;
*ctag_map_win_size = round_up(win_size, small_pgsz);
}
priv->comptags.offset = offset;
priv->comptags.lines = lines;
priv->comptags.allocated_lines = ctaglines_allocsize;
priv->comptags.user_mappable = user_mappable;
return 0;
}
static int gk20a_init_mm_reset_enable_hw(struct gk20a *g)
{
gk20a_dbg_fn("");
if (g->ops.fb.reset)
g->ops.fb.reset(g);
if (g->ops.clock_gating.slcg_fb_load_gating_prod)
g->ops.clock_gating.slcg_fb_load_gating_prod(g,
g->slcg_enabled);
if (g->ops.clock_gating.slcg_ltc_load_gating_prod)
g->ops.clock_gating.slcg_ltc_load_gating_prod(g,
g->slcg_enabled);
if (g->ops.clock_gating.blcg_fb_load_gating_prod)
g->ops.clock_gating.blcg_fb_load_gating_prod(g,
g->blcg_enabled);
if (g->ops.clock_gating.blcg_ltc_load_gating_prod)
g->ops.clock_gating.blcg_ltc_load_gating_prod(g,
g->blcg_enabled);
if (g->ops.fb.init_fs_state)
g->ops.fb.init_fs_state(g);
return 0;
}
void gk20a_remove_vm(struct vm_gk20a *vm, struct mem_desc *inst_block)
{
struct gk20a *g = vm->mm->g;
gk20a_dbg_fn("");
gk20a_free_inst_block(g, inst_block);
gk20a_vm_remove_support_nofree(vm);
}
static void gk20a_vidmem_destroy(struct gk20a *g)
{
#if defined(CONFIG_GK20A_VIDMEM)
if (gk20a_alloc_initialized(&g->mm.vidmem.allocator))
gk20a_alloc_destroy(&g->mm.vidmem.allocator);
#endif
}
static void gk20a_remove_mm_ce_support(struct mm_gk20a *mm)
{
struct gk20a *g = gk20a_from_mm(mm);
struct gk20a_platform *platform = gk20a_get_platform(g->dev);
if (mm->vidmem.ce_ctx_id != (u32)~0)
gk20a_ce_delete_context(g->dev, mm->vidmem.ce_ctx_id);
mm->vidmem.ce_ctx_id = (u32)~0;
if (platform->has_ce)
gk20a_vm_remove_support_nofree(&mm->ce.vm);
}
static void gk20a_remove_mm_support(struct mm_gk20a *mm)
{
struct gk20a *g = gk20a_from_mm(mm);
if (g->ops.mm.remove_bar2_vm)
g->ops.mm.remove_bar2_vm(g);
if (g->ops.mm.is_bar1_supported(g))
gk20a_remove_vm(&mm->bar1.vm, &mm->bar1.inst_block);
gk20a_remove_vm(&mm->pmu.vm, &mm->pmu.inst_block);
gk20a_free_inst_block(gk20a_from_mm(mm), &mm->hwpm.inst_block);
gk20a_vm_remove_support_nofree(&mm->cde.vm);
gk20a_vidmem_destroy(g);
}
static int gk20a_alloc_sysmem_flush(struct gk20a *g)
{
return gk20a_gmmu_alloc_sys(g, SZ_4K, &g->mm.sysmem_flush);
}
static void gk20a_init_pramin(struct mm_gk20a *mm)
{
mm->pramin_window = 0;
spin_lock_init(&mm->pramin_window_lock);
mm->force_pramin = GK20A_FORCE_PRAMIN_DEFAULT;
}
#if defined(CONFIG_GK20A_VIDMEM)
static int gk20a_vidmem_clear_all(struct gk20a *g)
{
struct mm_gk20a *mm = &g->mm;
struct gk20a_fence *gk20a_fence_out = NULL;
u64 region2_base = 0;
int err = 0;
if (mm->vidmem.ce_ctx_id == (u32)~0)
return -EINVAL;
err = gk20a_ce_execute_ops(g->dev,
mm->vidmem.ce_ctx_id,
0,
mm->vidmem.base,
mm->vidmem.bootstrap_base - mm->vidmem.base,
0x00000000,
NVGPU_CE_DST_LOCATION_LOCAL_FB,
NVGPU_CE_MEMSET,
NULL,
0,
NULL);
if (err) {
gk20a_err(g->dev,
"Failed to clear vidmem region 1 : %d", err);
return err;
}
region2_base = mm->vidmem.bootstrap_base + mm->vidmem.bootstrap_size;
err = gk20a_ce_execute_ops(g->dev,
mm->vidmem.ce_ctx_id,
0,
region2_base,
mm->vidmem.size - region2_base,
0x00000000,
NVGPU_CE_DST_LOCATION_LOCAL_FB,
NVGPU_CE_MEMSET,
NULL,
0,
&gk20a_fence_out);
if (err) {
gk20a_err(g->dev,
"Failed to clear vidmem region 2 : %d", err);
return err;
}
if (gk20a_fence_out) {
unsigned long end_jiffies = jiffies +
msecs_to_jiffies(gk20a_get_gr_idle_timeout(g));
do {
unsigned int timeout = jiffies_to_msecs(end_jiffies - jiffies);
err = gk20a_fence_wait(gk20a_fence_out,
timeout);
} while ((err == -ERESTARTSYS) && time_before(jiffies, end_jiffies));
gk20a_fence_put(gk20a_fence_out);
if (err) {
gk20a_err(g->dev,
"fence wait failed for CE execute ops");
return err;
}
}
mm->vidmem.cleared = true;
return 0;
}
#endif
static int gk20a_init_vidmem(struct mm_gk20a *mm)
{
#if defined(CONFIG_GK20A_VIDMEM)
struct gk20a *g = mm->g;
struct device *d = dev_from_gk20a(g);
size_t size = g->ops.mm.get_vidmem_size ?
g->ops.mm.get_vidmem_size(g) : 0;
u64 bootstrap_base, bootstrap_size, base;
u64 default_page_size = SZ_64K;
int err;
static struct gk20a_alloc_carveout wpr_co =
GK20A_CARVEOUT("wpr-region", 0, SZ_16M);
if (!size)
return 0;
wpr_co.base = size - SZ_256M;
bootstrap_base = wpr_co.base;
bootstrap_size = SZ_16M;
base = default_page_size;
/*
* Bootstrap allocator for use before the CE is initialized (CE
* initialization requires vidmem but we want to use the CE to zero
* out vidmem before allocating it...
*/
err = gk20a_page_allocator_init(g, &g->mm.vidmem.bootstrap_allocator,
"vidmem-bootstrap",
bootstrap_base, bootstrap_size,
SZ_4K, 0);
err = gk20a_page_allocator_init(g, &g->mm.vidmem.allocator,
"vidmem",
base, size - base,
default_page_size,
GPU_ALLOC_4K_VIDMEM_PAGES);
if (err) {
gk20a_err(d, "Failed to register vidmem for size %zu: %d",
size, err);
return err;
}
/* Reserve bootstrap region in vidmem allocator */
gk20a_alloc_reserve_carveout(&g->mm.vidmem.allocator, &wpr_co);
mm->vidmem.base = base;
mm->vidmem.size = size - base;
mm->vidmem.bootstrap_base = bootstrap_base;
mm->vidmem.bootstrap_size = bootstrap_size;
mutex_init(&mm->vidmem.first_clear_mutex);
INIT_WORK(&mm->vidmem.clear_mem_worker, gk20a_vidmem_clear_mem_worker);
atomic64_set(&mm->vidmem.bytes_pending, 0);
INIT_LIST_HEAD(&mm->vidmem.clear_list_head);
mutex_init(&mm->vidmem.clear_list_mutex);
gk20a_dbg_info("registered vidmem: %zu MB", size / SZ_1M);
#endif
return 0;
}
int gk20a_init_mm_setup_sw(struct gk20a *g)
{
struct mm_gk20a *mm = &g->mm;
int err;
struct gk20a_platform *platform = gk20a_get_platform(g->dev);
gk20a_dbg_fn("");
if (mm->sw_ready) {
gk20a_dbg_fn("skip init");
return 0;
}
mm->g = g;
mutex_init(&mm->l2_op_lock);
/*TBD: make channel vm size configurable */
mm->channel.user_size = NV_MM_DEFAULT_USER_SIZE;
mm->channel.kernel_size = NV_MM_DEFAULT_KERNEL_SIZE;
gk20a_dbg_info("channel vm size: user %dMB kernel %dMB",
(int)(mm->channel.user_size >> 20),
(int)(mm->channel.kernel_size >> 20));
gk20a_init_pramin(mm);
mm->vidmem.ce_ctx_id = (u32)~0;
err = gk20a_init_vidmem(mm);
if (err)
return err;
/*
* this requires fixed allocations in vidmem which must be
* allocated before all other buffers
*/
if (g->ops.pmu.alloc_blob_space && g->mm.vidmem_is_vidmem) {
err = g->ops.pmu.alloc_blob_space(g, 0, &g->acr.ucode_blob);
if (err)
return err;
}
err = gk20a_alloc_sysmem_flush(g);
if (err)
return err;
if (g->ops.mm.is_bar1_supported(g)) {
err = gk20a_init_bar1_vm(mm);
if (err)
return err;
}
if (g->ops.mm.init_bar2_vm) {
err = g->ops.mm.init_bar2_vm(g);
if (err)
return err;
}
err = gk20a_init_system_vm(mm);
if (err)
return err;
err = gk20a_init_hwpm(mm);
if (err)
return err;
err = gk20a_init_cde_vm(mm);
if (err)
return err;
if (platform->has_ce) {
err = gk20a_init_ce_vm(mm);
if (err)
return err;
}
/* set vm_alloc_share op here as gk20a_as_alloc_share needs it */
g->ops.mm.vm_alloc_share = gk20a_vm_alloc_share;
mm->remove_support = gk20a_remove_mm_support;
mm->remove_ce_support = gk20a_remove_mm_ce_support;
mm->sw_ready = true;
gk20a_dbg_fn("done");
return 0;
}
/* make sure gk20a_init_mm_support is called before */
int gk20a_init_mm_setup_hw(struct gk20a *g)
{
struct mm_gk20a *mm = &g->mm;
int err;
gk20a_dbg_fn("");
g->ops.fb.set_mmu_page_size(g);
if (g->ops.fb.set_use_full_comp_tag_line)
mm->use_full_comp_tag_line =
g->ops.fb.set_use_full_comp_tag_line(g);
gk20a_writel(g, fb_niso_flush_sysmem_addr_r(),
g->ops.mm.get_iova_addr(g, g->mm.sysmem_flush.sgt->sgl, 0)
>> 8);
if (g->ops.mm.bar1_bind)
g->ops.mm.bar1_bind(g, &mm->bar1.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;
gk20a_dbg_fn("done");
return 0;
}
static int gk20a_mm_bar1_bind(struct gk20a *g, struct mem_desc *bar1_inst)
{
u64 iova = gk20a_mm_inst_block_addr(g, bar1_inst);
u32 ptr_v = (u32)(iova >> bar1_instance_block_shift_gk20a());
gk20a_dbg_info("bar1 inst block ptr: 0x%08x", ptr_v);
gk20a_writel(g, bus_bar1_block_r(),
gk20a_aperture_mask(g, bar1_inst,
bus_bar1_block_target_sys_mem_ncoh_f(),
bus_bar1_block_target_vid_mem_f()) |
bus_bar1_block_mode_virtual_f() |
bus_bar1_block_ptr_f(ptr_v));
return 0;
}
int gk20a_init_mm_support(struct gk20a *g)
{
u32 err;
err = gk20a_init_mm_reset_enable_hw(g);
if (err)
return err;
err = gk20a_init_mm_setup_sw(g);
if (err)
return err;
if (g->ops.mm.init_mm_setup_hw)
err = g->ops.mm.init_mm_setup_hw(g);
return err;
}
void gk20a_init_mm_ce_context(struct gk20a *g)
{
#if defined(CONFIG_GK20A_VIDMEM)
if (g->mm.vidmem.size && (g->mm.vidmem.ce_ctx_id == (u32)~0)) {
g->mm.vidmem.ce_ctx_id =
gk20a_ce_create_context_with_cb(g->dev,
gk20a_fifo_get_fast_ce_runlist_id(g),
-1,
-1,
-1,
NULL);
if (g->mm.vidmem.ce_ctx_id == (u32)~0)
gk20a_err(g->dev,
"Failed to allocate CE context for vidmem page clearing support");
}
#endif
}
static int alloc_gmmu_phys_pages(struct vm_gk20a *vm, u32 order,
struct gk20a_mm_entry *entry)
{
u32 num_pages = 1 << order;
u32 len = num_pages * PAGE_SIZE;
int err;
struct page *pages;
gk20a_dbg_fn("");
/* note: mem_desc slightly abused (wrt. alloc_gmmu_pages) */
pages = alloc_pages(GFP_KERNEL, order);
if (!pages) {
gk20a_dbg(gpu_dbg_pte, "alloc_pages failed");
goto err_out;
}
entry->mem.sgt = kzalloc(sizeof(*entry->mem.sgt), GFP_KERNEL);
if (!entry->mem.sgt) {
gk20a_dbg(gpu_dbg_pte, "cannot allocate sg table");
goto err_alloced;
}
err = sg_alloc_table(entry->mem.sgt, 1, GFP_KERNEL);
if (err) {
gk20a_dbg(gpu_dbg_pte, "sg_alloc_table failed");
goto err_sg_table;
}
sg_set_page(entry->mem.sgt->sgl, pages, len, 0);
entry->mem.cpu_va = page_address(pages);
memset(entry->mem.cpu_va, 0, len);
entry->mem.size = len;
entry->mem.aperture = APERTURE_SYSMEM;
FLUSH_CPU_DCACHE(entry->mem.cpu_va, sg_phys(entry->mem.sgt->sgl), len);
return 0;
err_sg_table:
kfree(entry->mem.sgt);
err_alloced:
__free_pages(pages, order);
err_out:
return -ENOMEM;
}
static void free_gmmu_phys_pages(struct vm_gk20a *vm,
struct gk20a_mm_entry *entry)
{
gk20a_dbg_fn("");
/* note: mem_desc slightly abused (wrt. free_gmmu_pages) */
free_pages((unsigned long)entry->mem.cpu_va, get_order(entry->mem.size));
entry->mem.cpu_va = NULL;
sg_free_table(entry->mem.sgt);
kfree(entry->mem.sgt);
entry->mem.sgt = NULL;
entry->mem.size = 0;
entry->mem.aperture = APERTURE_INVALID;
}
static int map_gmmu_phys_pages(struct gk20a_mm_entry *entry)
{
FLUSH_CPU_DCACHE(entry->mem.cpu_va,
sg_phys(entry->mem.sgt->sgl),
entry->mem.sgt->sgl->length);
return 0;
}
static void unmap_gmmu_phys_pages(struct gk20a_mm_entry *entry)
{
FLUSH_CPU_DCACHE(entry->mem.cpu_va,
sg_phys(entry->mem.sgt->sgl),
entry->mem.sgt->sgl->length);
}
static int alloc_gmmu_pages(struct vm_gk20a *vm, u32 order,
struct gk20a_mm_entry *entry)
{
struct device *d = dev_from_vm(vm);
struct gk20a *g = gk20a_from_vm(vm);
u32 num_pages = 1 << order;
u32 len = num_pages * PAGE_SIZE;
int err;
struct gk20a_platform *platform = dev_get_drvdata(g->dev);
gk20a_dbg_fn("");
if (platform->is_fmodel)
return alloc_gmmu_phys_pages(vm, order, entry);
/*
* On arm32 we're limited by vmalloc space, so we do not map pages by
* default.
*/
if (IS_ENABLED(CONFIG_ARM64))
err = gk20a_gmmu_alloc(g, len, &entry->mem);
else
err = gk20a_gmmu_alloc_attr(g, DMA_ATTR_NO_KERNEL_MAPPING,
len, &entry->mem);
if (err) {
gk20a_err(d, "memory allocation failed");
return -ENOMEM;
}
return 0;
}
void free_gmmu_pages(struct vm_gk20a *vm,
struct gk20a_mm_entry *entry)
{
struct gk20a *g = gk20a_from_vm(vm);
struct gk20a_platform *platform = dev_get_drvdata(g->dev);
gk20a_dbg_fn("");
if (!entry->mem.size)
return;
if (entry->woffset) /* fake shadow mem */
return;
if (platform->is_fmodel) {
free_gmmu_phys_pages(vm, entry);
return;
}
/*
* On arm32 we're limited by vmalloc space, so we do not map pages by
* default.
*/
if (IS_ENABLED(CONFIG_ARM64))
gk20a_gmmu_free(g, &entry->mem);
else
gk20a_gmmu_free_attr(g, DMA_ATTR_NO_KERNEL_MAPPING,
&entry->mem);
}
int map_gmmu_pages(struct gk20a *g, struct gk20a_mm_entry *entry)
{
struct gk20a_platform *platform = dev_get_drvdata(g->dev);
gk20a_dbg_fn("");
if (platform->is_fmodel)
return map_gmmu_phys_pages(entry);
if (IS_ENABLED(CONFIG_ARM64)) {
if (entry->mem.aperture == APERTURE_VIDMEM)
return 0;
FLUSH_CPU_DCACHE(entry->mem.cpu_va,
sg_phys(entry->mem.sgt->sgl),
entry->mem.size);
} else {
int err = gk20a_mem_begin(g, &entry->mem);
if (err)
return err;
}
return 0;
}
void unmap_gmmu_pages(struct gk20a *g, struct gk20a_mm_entry *entry)
{
struct gk20a_platform *platform = dev_get_drvdata(g->dev);
gk20a_dbg_fn("");
if (platform->is_fmodel) {
unmap_gmmu_phys_pages(entry);
return;
}
if (IS_ENABLED(CONFIG_ARM64)) {
if (entry->mem.aperture == APERTURE_VIDMEM)
return;
FLUSH_CPU_DCACHE(entry->mem.cpu_va,
sg_phys(entry->mem.sgt->sgl),
entry->mem.size);
} else {
gk20a_mem_end(g, &entry->mem);
}
}
/*
* Allocate a phys contig region big enough for a full
* sized gmmu page table for the given gmmu_page_size.
* the whole range is zeroed so it's "invalid"/will fault.
*
* If a previous entry is supplied, its memory will be used for
* suballocation for this next entry too, if there is space.
*/
static int gk20a_zalloc_gmmu_page_table(struct vm_gk20a *vm,
enum gmmu_pgsz_gk20a pgsz_idx,
const struct gk20a_mmu_level *l,
struct gk20a_mm_entry *entry,
struct gk20a_mm_entry *prev_entry)
{
int err = -ENOMEM;
int order;
struct gk20a *g = gk20a_from_vm(vm);
u32 bytes;
gk20a_dbg_fn("");
/* allocate enough pages for the table */
order = l->hi_bit[pgsz_idx] - l->lo_bit[pgsz_idx] + 1;
order += ilog2(l->entry_size);
bytes = 1 << order;
order -= PAGE_SHIFT;
if (order < 0 && prev_entry) {
/* try to suballocate from previous chunk */
u32 capacity = prev_entry->mem.size / bytes;
u32 prev = prev_entry->woffset * sizeof(u32) / bytes;
u32 free = capacity - prev - 1;
gk20a_dbg(gpu_dbg_pte, "cap %d prev %d free %d bytes %d",
capacity, prev, free, bytes);
if (free) {
memcpy(&entry->mem, &prev_entry->mem,
sizeof(entry->mem));
entry->woffset = prev_entry->woffset
+ bytes / sizeof(u32);
err = 0;
}
}
if (err) {
/* no suballoc space */
order = max(0, order);
err = alloc_gmmu_pages(vm, order, entry);
entry->woffset = 0;
}
gk20a_dbg(gpu_dbg_pte, "entry = 0x%p, addr=%08llx, size %d, woff %x",
entry,
(entry->mem.sgt && entry->mem.aperture == APERTURE_SYSMEM) ?
g->ops.mm.get_iova_addr(g, entry->mem.sgt->sgl, 0)
: 0,
order, entry->woffset);
if (err)
return err;
entry->pgsz = pgsz_idx;
entry->mem.skip_wmb = true;
return err;
}
int gk20a_mm_pde_coverage_bit_count(struct vm_gk20a *vm)
{
return vm->mmu_levels[0].lo_bit[0];
}
/* given address range (inclusive) determine the pdes crossed */
void pde_range_from_vaddr_range(struct vm_gk20a *vm,
u64 addr_lo, u64 addr_hi,
u32 *pde_lo, u32 *pde_hi)
{
int pde_shift = gk20a_mm_pde_coverage_bit_count(vm);
*pde_lo = (u32)(addr_lo >> pde_shift);
*pde_hi = (u32)(addr_hi >> pde_shift);
gk20a_dbg(gpu_dbg_pte, "addr_lo=0x%llx addr_hi=0x%llx pde_ss=%d",
addr_lo, addr_hi, pde_shift);
gk20a_dbg(gpu_dbg_pte, "pde_lo=%d pde_hi=%d",
*pde_lo, *pde_hi);
}
static u32 pde_from_index(u32 i)
{
return i * gmmu_pde__size_v() / sizeof(u32);
}
static u32 pte_from_index(u32 i)
{
return i * gmmu_pte__size_v() / sizeof(u32);
}
u32 pte_index_from_vaddr(struct vm_gk20a *vm,
u64 addr, enum gmmu_pgsz_gk20a pgsz_idx)
{
u32 ret;
/* mask off pde part */
addr = addr & ((1ULL << gk20a_mm_pde_coverage_bit_count(vm)) - 1ULL);
/* shift over to get pte index. note assumption that pte index
* doesn't leak over into the high 32b */
ret = (u32)(addr >> ilog2(vm->gmmu_page_sizes[pgsz_idx]));
gk20a_dbg(gpu_dbg_pte, "addr=0x%llx pte_i=0x%x", addr, ret);
return ret;
}
static struct vm_reserved_va_node *addr_to_reservation(struct vm_gk20a *vm,
u64 addr)
{
struct vm_reserved_va_node *va_node;
list_for_each_entry(va_node, &vm->reserved_va_list, reserved_va_list)
if (addr >= va_node->vaddr_start &&
addr < (u64)va_node->vaddr_start + (u64)va_node->size)
return va_node;
return NULL;
}
int gk20a_vm_get_buffers(struct vm_gk20a *vm,
struct mapped_buffer_node ***mapped_buffers,
int *num_buffers)
{
struct mapped_buffer_node *mapped_buffer;
struct mapped_buffer_node **buffer_list;
struct rb_node *node;
int i = 0;
if (vm->userspace_managed) {
*mapped_buffers = NULL;
*num_buffers = 0;
return 0;
}
mutex_lock(&vm->update_gmmu_lock);
buffer_list = nvgpu_alloc(sizeof(*buffer_list) *
vm->num_user_mapped_buffers, true);
if (!buffer_list) {
mutex_unlock(&vm->update_gmmu_lock);
return -ENOMEM;
}
node = rb_first(&vm->mapped_buffers);
while (node) {
mapped_buffer =
container_of(node, struct mapped_buffer_node, node);
if (mapped_buffer->user_mapped) {
buffer_list[i] = mapped_buffer;
kref_get(&mapped_buffer->ref);
i++;
}
node = rb_next(&mapped_buffer->node);
}
BUG_ON(i != vm->num_user_mapped_buffers);
*num_buffers = vm->num_user_mapped_buffers;
*mapped_buffers = buffer_list;
mutex_unlock(&vm->update_gmmu_lock);
return 0;
}
static void gk20a_vm_unmap_locked_kref(struct kref *ref)
{
struct mapped_buffer_node *mapped_buffer =
container_of(ref, struct mapped_buffer_node, ref);
gk20a_vm_unmap_locked(mapped_buffer, mapped_buffer->vm->kref_put_batch);
}
void gk20a_vm_mapping_batch_start(struct vm_gk20a_mapping_batch *mapping_batch)
{
memset(mapping_batch, 0, sizeof(*mapping_batch));
mapping_batch->gpu_l2_flushed = false;
mapping_batch->need_tlb_invalidate = false;
}
void gk20a_vm_mapping_batch_finish_locked(
struct vm_gk20a *vm, struct vm_gk20a_mapping_batch *mapping_batch)
{
/* hanging kref_put batch pointer? */
WARN_ON(vm->kref_put_batch == mapping_batch);
if (mapping_batch->need_tlb_invalidate) {
struct gk20a *g = gk20a_from_vm(vm);
g->ops.mm.tlb_invalidate(vm);
}
}
void gk20a_vm_mapping_batch_finish(struct vm_gk20a *vm,
struct vm_gk20a_mapping_batch *mapping_batch)
{
mutex_lock(&vm->update_gmmu_lock);
gk20a_vm_mapping_batch_finish_locked(vm, mapping_batch);
mutex_unlock(&vm->update_gmmu_lock);
}
void gk20a_vm_put_buffers(struct vm_gk20a *vm,
struct mapped_buffer_node **mapped_buffers,
int num_buffers)
{
int i;
struct vm_gk20a_mapping_batch batch;
if (num_buffers == 0)
return;
mutex_lock(&vm->update_gmmu_lock);
gk20a_vm_mapping_batch_start(&batch);
vm->kref_put_batch = &batch;
for (i = 0; i < num_buffers; ++i)
kref_put(&mapped_buffers[i]->ref,
gk20a_vm_unmap_locked_kref);
vm->kref_put_batch = NULL;
gk20a_vm_mapping_batch_finish_locked(vm, &batch);
mutex_unlock(&vm->update_gmmu_lock);
nvgpu_free(mapped_buffers);
}
static void gk20a_vm_unmap_user(struct vm_gk20a *vm, u64 offset,
struct vm_gk20a_mapping_batch *batch)
{
struct device *d = dev_from_vm(vm);
int retries = 10000; /* 50 ms */
struct mapped_buffer_node *mapped_buffer;
mutex_lock(&vm->update_gmmu_lock);
mapped_buffer = find_mapped_buffer_locked(&vm->mapped_buffers, offset);
if (!mapped_buffer) {
mutex_unlock(&vm->update_gmmu_lock);
gk20a_err(d, "invalid addr to unmap 0x%llx", offset);
return;
}
if (mapped_buffer->flags & NVGPU_AS_MAP_BUFFER_FLAGS_FIXED_OFFSET) {
mutex_unlock(&vm->update_gmmu_lock);
while (retries >= 0 || !tegra_platform_is_silicon()) {
if (atomic_read(&mapped_buffer->ref.refcount) == 1)
break;
retries--;
udelay(5);
}
if (retries < 0 && tegra_platform_is_silicon())
gk20a_err(d, "sync-unmap failed on 0x%llx",
offset);
mutex_lock(&vm->update_gmmu_lock);
}
if (mapped_buffer->user_mapped == 0) {
mutex_unlock(&vm->update_gmmu_lock);
gk20a_err(d, "addr already unmapped from user 0x%llx", offset);
return;
}
mapped_buffer->user_mapped--;
if (mapped_buffer->user_mapped == 0)
vm->num_user_mapped_buffers--;
vm->kref_put_batch = batch;
kref_put(&mapped_buffer->ref, gk20a_vm_unmap_locked_kref);
vm->kref_put_batch = NULL;
mutex_unlock(&vm->update_gmmu_lock);
}
u64 gk20a_vm_alloc_va(struct vm_gk20a *vm,
u64 size,
enum gmmu_pgsz_gk20a gmmu_pgsz_idx)
{
struct gk20a_allocator *vma = &vm->vma[gmmu_pgsz_idx];
u64 offset;
u64 gmmu_page_size = vm->gmmu_page_sizes[gmmu_pgsz_idx];
if (gmmu_pgsz_idx >= gmmu_nr_page_sizes) {
dev_warn(dev_from_vm(vm),
"invalid page size requested in gk20a vm alloc");
return 0;
}
if ((gmmu_pgsz_idx == gmmu_page_size_big) && !vm->big_pages) {
dev_warn(dev_from_vm(vm),
"unsupportd page size requested");
return 0;
}
/* Be certain we round up to gmmu_page_size if needed */
size = (size + ((u64)gmmu_page_size - 1)) & ~((u64)gmmu_page_size - 1);
gk20a_dbg_info("size=0x%llx @ pgsz=%dKB", size,
vm->gmmu_page_sizes[gmmu_pgsz_idx]>>10);
offset = gk20a_alloc(vma, size);
if (!offset) {
gk20a_err(dev_from_vm(vm),
"%s oom: sz=0x%llx", vma->name, size);
return 0;
}
gk20a_dbg_fn("%s found addr: 0x%llx", vma->name, offset);
return offset;
}
int gk20a_vm_free_va(struct vm_gk20a *vm,
u64 offset, u64 size,
enum gmmu_pgsz_gk20a pgsz_idx)
{
struct gk20a_allocator *vma = &vm->vma[pgsz_idx];
gk20a_dbg_info("%s free addr=0x%llx, size=0x%llx",
vma->name, offset, size);
gk20a_free(vma, offset);
return 0;
}
static int insert_mapped_buffer(struct rb_root *root,
struct mapped_buffer_node *mapped_buffer)
{
struct rb_node **new_node = &(root->rb_node), *parent = NULL;
/* Figure out where to put new node */
while (*new_node) {
struct mapped_buffer_node *cmp_with =
container_of(*new_node, struct mapped_buffer_node,
node);
parent = *new_node;
if (cmp_with->addr > mapped_buffer->addr) /* u64 cmp */
new_node = &((*new_node)->rb_left);
else if (cmp_with->addr != mapped_buffer->addr) /* u64 cmp */
new_node = &((*new_node)->rb_right);
else
return -EINVAL; /* no fair dup'ing */
}
/* Add new node and rebalance tree. */
rb_link_node(&mapped_buffer->node, parent, new_node);
rb_insert_color(&mapped_buffer->node, root);
return 0;
}
static struct mapped_buffer_node *find_mapped_buffer_reverse_locked(
struct rb_root *root, struct dma_buf *dmabuf,
u32 kind)
{
struct rb_node *node = rb_first(root);
while (node) {
struct mapped_buffer_node *mapped_buffer =
container_of(node, struct mapped_buffer_node, node);
if (mapped_buffer->dmabuf == dmabuf &&
kind == mapped_buffer->kind)
return mapped_buffer;
node = rb_next(&mapped_buffer->node);
}
return NULL;
}
static struct mapped_buffer_node *find_mapped_buffer_locked(
struct rb_root *root, u64 addr)
{
struct rb_node *node = root->rb_node;
while (node) {
struct mapped_buffer_node *mapped_buffer =
container_of(node, struct mapped_buffer_node, node);
if (mapped_buffer->addr > addr) /* u64 cmp */
node = node->rb_left;
else if (mapped_buffer->addr != addr) /* u64 cmp */
node = node->rb_right;
else
return mapped_buffer;
}
return NULL;
}
static struct mapped_buffer_node *find_mapped_buffer_range_locked(
struct rb_root *root, u64 addr)
{
struct rb_node *node = root->rb_node;
while (node) {
struct mapped_buffer_node *m =
container_of(node, struct mapped_buffer_node, node);
if (m->addr <= addr && m->addr + m->size > addr)
return m;
else if (m->addr > addr) /* u64 cmp */
node = node->rb_left;
else
node = node->rb_right;
}
return NULL;
}
/* find the first mapped buffer with GPU VA less than addr */
static struct mapped_buffer_node *find_mapped_buffer_less_than_locked(
struct rb_root *root, u64 addr)
{
struct rb_node *node = root->rb_node;
struct mapped_buffer_node *ret = NULL;
while (node) {
struct mapped_buffer_node *mapped_buffer =
container_of(node, struct mapped_buffer_node, node);
if (mapped_buffer->addr >= addr)
node = node->rb_left;
else {
ret = mapped_buffer;
node = node->rb_right;
}
}
return ret;
}
#define BFR_ATTRS (sizeof(nvmap_bfr_param)/sizeof(nvmap_bfr_param[0]))
struct buffer_attrs {
struct sg_table *sgt;
u64 size;
u64 align;
u32 ctag_offset;
u32 ctag_lines;
u32 ctag_allocated_lines;
int pgsz_idx;
u8 kind_v;
u8 uc_kind_v;
bool ctag_user_mappable;
};
static void gmmu_select_page_size(struct vm_gk20a *vm,
struct buffer_attrs *bfr)
{
int i;
/* choose the biggest first (top->bottom) */
for (i = gmmu_page_size_kernel - 1; i >= 0; i--)
if (!((vm->gmmu_page_sizes[i] - 1) & bfr->align)) {
bfr->pgsz_idx = i;
break;
}
}
static int setup_buffer_kind_and_compression(struct vm_gk20a *vm,
u32 flags,
struct buffer_attrs *bfr,
enum gmmu_pgsz_gk20a pgsz_idx)
{
bool kind_compressible;
struct gk20a *g = gk20a_from_vm(vm);
struct device *d = dev_from_gk20a(g);
int ctag_granularity = g->ops.fb.compression_page_size(g);
if (unlikely(bfr->kind_v == gmmu_pte_kind_invalid_v()))
bfr->kind_v = gmmu_pte_kind_pitch_v();
if (unlikely(!gk20a_kind_is_supported(bfr->kind_v))) {
gk20a_err(d, "kind 0x%x not supported", bfr->kind_v);
return -EINVAL;
}
bfr->uc_kind_v = gmmu_pte_kind_invalid_v();
/* find a suitable uncompressed kind if it becomes necessary later */
kind_compressible = gk20a_kind_is_compressible(bfr->kind_v);
if (kind_compressible) {
bfr->uc_kind_v = gk20a_get_uncompressed_kind(bfr->kind_v);
if (unlikely(bfr->uc_kind_v == gmmu_pte_kind_invalid_v())) {
/* shouldn't happen, but it is worth cross-checking */
gk20a_err(d, "comptag kind 0x%x can't be"
" downgraded to uncompressed kind",
bfr->kind_v);
return -EINVAL;
}
}
/* comptags only supported for suitable kinds, 128KB pagesize */
if (kind_compressible &&
vm->gmmu_page_sizes[pgsz_idx] < g->ops.fb.compressible_page_size(g)) {
/*
gk20a_warn(d, "comptags specified"
" but pagesize being used doesn't support it");*/
/* it is safe to fall back to uncompressed as
functionality is not harmed */
bfr->kind_v = bfr->uc_kind_v;
kind_compressible = false;
}
if (kind_compressible)
bfr->ctag_lines = DIV_ROUND_UP_ULL(bfr->size, ctag_granularity);
else
bfr->ctag_lines = 0;
return 0;
}
static int validate_fixed_buffer(struct vm_gk20a *vm,
struct buffer_attrs *bfr,
u64 map_offset, u64 map_size,
struct vm_reserved_va_node **pva_node)
{
struct device *dev = dev_from_vm(vm);
struct vm_reserved_va_node *va_node;
struct mapped_buffer_node *buffer;
u64 map_end = map_offset + map_size;
/* can wrap around with insane map_size; zero is disallowed too */
if (map_end <= map_offset) {
gk20a_warn(dev, "fixed offset mapping with invalid map_size");
return -EINVAL;
}
if (map_offset & (vm->gmmu_page_sizes[bfr->pgsz_idx] - 1)) {
gk20a_err(dev, "map offset must be buffer page size aligned 0x%llx",
map_offset);
return -EINVAL;
}
/* Find the space reservation, but it's ok to have none for
* userspace-managed address spaces */
va_node = addr_to_reservation(vm, map_offset);
if (!va_node && !vm->userspace_managed) {
gk20a_warn(dev, "fixed offset mapping without space allocation");
return -EINVAL;
}
/* Mapped area should fit inside va, if there's one */
if (va_node && map_end > va_node->vaddr_start + va_node->size) {
gk20a_warn(dev, "fixed offset mapping size overflows va node");
return -EINVAL;
}
/* check that this mapping does not collide with existing
* mappings by checking the buffer with the highest GPU VA
* that is less than our buffer end */
buffer = find_mapped_buffer_less_than_locked(
&vm->mapped_buffers, map_offset + map_size);
if (buffer && buffer->addr + buffer->size > map_offset) {
gk20a_warn(dev, "overlapping buffer map requested");
return -EINVAL;
}
*pva_node = va_node;
return 0;
}
u64 gk20a_locked_gmmu_map(struct vm_gk20a *vm,
u64 map_offset,
struct sg_table *sgt,
u64 buffer_offset,
u64 size,
int pgsz_idx,
u8 kind_v,
u32 ctag_offset,
u32 flags,
int rw_flag,
bool clear_ctags,
bool sparse,
bool priv,
struct vm_gk20a_mapping_batch *batch,
enum gk20a_aperture aperture)
{
int err = 0;
bool allocated = false;
struct device *d = dev_from_vm(vm);
struct gk20a *g = gk20a_from_vm(vm);
int ctag_granularity = g->ops.fb.compression_page_size(g);
u32 ctag_lines = DIV_ROUND_UP_ULL(size, ctag_granularity);
/* Allocate (or validate when map_offset != 0) the virtual address. */
if (!map_offset) {
map_offset = gk20a_vm_alloc_va(vm, size,
pgsz_idx);
if (!map_offset) {
gk20a_err(d, "failed to allocate va space");
err = -ENOMEM;
goto fail_alloc;
}
allocated = true;
}
gk20a_dbg(gpu_dbg_map,
"gv: 0x%04x_%08x + 0x%-7llx "
"[dma: 0x%02x_%08x, pa: 0x%02x_%08x] "
"pgsz=%-3dKb as=%-2d ctags=%d start=%d "
"kind=0x%x flags=0x%x apt=%s",
hi32(map_offset), lo32(map_offset), size,
sgt ? hi32((u64)sg_dma_address(sgt->sgl)) : 0,
sgt ? lo32((u64)sg_dma_address(sgt->sgl)) : 0,
sgt ? hi32((u64)sg_phys(sgt->sgl)) : 0,
sgt ? lo32((u64)sg_phys(sgt->sgl)) : 0,
vm->gmmu_page_sizes[pgsz_idx] >> 10, vm_aspace_id(vm),
ctag_lines, ctag_offset,
kind_v, flags, gk20a_aperture_str(aperture));
err = update_gmmu_ptes_locked(vm, pgsz_idx,
sgt,
buffer_offset,
map_offset, map_offset + size,
kind_v,
ctag_offset,
flags &
NVGPU_MAP_BUFFER_FLAGS_CACHEABLE_TRUE,
flags &
NVGPU_AS_MAP_BUFFER_FLAGS_UNMAPPED_PTE,
rw_flag,
sparse,
priv,
aperture);
if (err) {
gk20a_err(d, "failed to update ptes on map");
goto fail_validate;
}
if (!batch)
g->ops.mm.tlb_invalidate(vm);
else
batch->need_tlb_invalidate = true;
return map_offset;
fail_validate:
if (allocated)
gk20a_vm_free_va(vm, map_offset, size, pgsz_idx);
fail_alloc:
gk20a_err(d, "%s: failed with err=%d\n", __func__, err);
return 0;
}
void gk20a_locked_gmmu_unmap(struct vm_gk20a *vm,
u64 vaddr,
u64 size,
int pgsz_idx,
bool va_allocated,
int rw_flag,
bool sparse,
struct vm_gk20a_mapping_batch *batch)
{
int err = 0;
struct gk20a *g = gk20a_from_vm(vm);
if (va_allocated) {
err = gk20a_vm_free_va(vm, vaddr, size, pgsz_idx);
if (err) {
dev_err(dev_from_vm(vm),
"failed to free va");
return;
}
}
/* unmap here needs to know the page size we assigned at mapping */
err = update_gmmu_ptes_locked(vm,
pgsz_idx,
NULL, /* n/a for unmap */
0,
vaddr,
vaddr + size,
0, 0, false /* n/a for unmap */,
false, rw_flag,
sparse, 0,
APERTURE_INVALID); /* don't care for unmap */
if (err)
dev_err(dev_from_vm(vm),
"failed to update gmmu ptes on unmap");
/* flush l2 so any dirty lines are written out *now*.
* also as we could potentially be switching this buffer
* from nonvolatile (l2 cacheable) to volatile (l2 non-cacheable) at
* some point in the future we need to invalidate l2. e.g. switching
* from a render buffer unmap (here) to later using the same memory
* for gmmu ptes. note the positioning of this relative to any smmu
* unmapping (below). */
if (!batch) {
gk20a_mm_l2_flush(g, true);
g->ops.mm.tlb_invalidate(vm);
} else {
if (!batch->gpu_l2_flushed) {
gk20a_mm_l2_flush(g, true);
batch->gpu_l2_flushed = true;
}
batch->need_tlb_invalidate = true;
}
}
static enum gk20a_aperture gk20a_dmabuf_aperture(struct gk20a *g,
struct dma_buf *dmabuf)
{
struct gk20a *buf_owner = gk20a_vidmem_buf_owner(dmabuf);
if (buf_owner == NULL) {
/* Not nvgpu-allocated, assume system memory */
return APERTURE_SYSMEM;
} else if (WARN_ON(buf_owner == g && !g->mm.vidmem_is_vidmem)) {
/* Looks like our video memory, but this gpu doesn't support
* it. Warn about a bug and bail out */
gk20a_warn(dev_from_gk20a(g),
"dmabuf is our vidmem but we don't have local vidmem");
return APERTURE_INVALID;
} else if (buf_owner != g) {
/* Someone else's vidmem */
return APERTURE_INVALID;
} else {
/* Yay, buf_owner == g */
return APERTURE_VIDMEM;
}
}
static u64 gk20a_vm_map_duplicate_locked(struct vm_gk20a *vm,
struct dma_buf *dmabuf,
u64 offset_align,
u32 flags,
int kind,
struct sg_table **sgt,
bool user_mapped,
int rw_flag)
{
struct gk20a *g = gk20a_from_vm(vm);
struct mapped_buffer_node *mapped_buffer = NULL;
mapped_buffer =
find_mapped_buffer_reverse_locked(&vm->mapped_buffers,
dmabuf, kind);
if (!mapped_buffer)
return 0;
if (mapped_buffer->flags != flags)
return 0;
if (flags & NVGPU_AS_MAP_BUFFER_FLAGS_FIXED_OFFSET &&
mapped_buffer->addr != offset_align)
return 0;
BUG_ON(mapped_buffer->vm != vm);
/* mark the buffer as used */
if (user_mapped) {
if (mapped_buffer->user_mapped == 0)
vm->num_user_mapped_buffers++;
mapped_buffer->user_mapped++;
/* If the mapping comes from user space, we own
* the handle ref. Since we reuse an
* existing mapping here, we need to give back those
* refs once in order not to leak.
*/
if (mapped_buffer->own_mem_ref)
dma_buf_put(mapped_buffer->dmabuf);
else
mapped_buffer->own_mem_ref = true;
}
kref_get(&mapped_buffer->ref);
gk20a_dbg(gpu_dbg_map,
"gv: 0x%04x_%08x + 0x%-7zu "
"[dma: 0x%02x_%08x, pa: 0x%02x_%08x] "
"pgsz=%-3dKb as=%-2d ctags=%d start=%d "
"flags=0x%x apt=%s (reused)",
hi32(mapped_buffer->addr), lo32(mapped_buffer->addr),
dmabuf->size,
hi32((u64)sg_dma_address(mapped_buffer->sgt->sgl)),
lo32((u64)sg_dma_address(mapped_buffer->sgt->sgl)),
hi32((u64)sg_phys(mapped_buffer->sgt->sgl)),
lo32((u64)sg_phys(mapped_buffer->sgt->sgl)),
vm->gmmu_page_sizes[mapped_buffer->pgsz_idx] >> 10,
vm_aspace_id(vm),
mapped_buffer->ctag_lines, mapped_buffer->ctag_offset,
mapped_buffer->flags,
gk20a_aperture_str(gk20a_dmabuf_aperture(g, dmabuf)));
if (sgt)
*sgt = mapped_buffer->sgt;
return mapped_buffer->addr;
}
#if defined(CONFIG_GK20A_VIDMEM)
static struct sg_table *gk20a_vidbuf_map_dma_buf(
struct dma_buf_attachment *attach, enum dma_data_direction dir)
{
struct gk20a_vidmem_buf *buf = attach->dmabuf->priv;
return buf->mem->sgt;
}
static void gk20a_vidbuf_unmap_dma_buf(struct dma_buf_attachment *attach,
struct sg_table *sgt,
enum dma_data_direction dir)
{
}
static void gk20a_vidbuf_release(struct dma_buf *dmabuf)
{
struct gk20a_vidmem_buf *buf = dmabuf->priv;
gk20a_dbg_fn("");
if (buf->dmabuf_priv)
buf->dmabuf_priv_delete(buf->dmabuf_priv);
gk20a_gmmu_free(buf->g, buf->mem);
kfree(buf);
}
static void *gk20a_vidbuf_kmap(struct dma_buf *dmabuf, unsigned long page_num)
{
WARN_ON("Not supported");
return NULL;
}
static void *gk20a_vidbuf_kmap_atomic(struct dma_buf *dmabuf,
unsigned long page_num)
{
WARN_ON("Not supported");
return NULL;
}
static int gk20a_vidbuf_mmap(struct dma_buf *dmabuf, struct vm_area_struct *vma)
{
return -EINVAL;
}
static int gk20a_vidbuf_set_private(struct dma_buf *dmabuf,
struct device *dev, void *priv, void (*delete)(void *priv))
{
struct gk20a_vidmem_buf *buf = dmabuf->priv;
buf->dmabuf_priv = priv;
buf->dmabuf_priv_delete = delete;
return 0;
}
static void *gk20a_vidbuf_get_private(struct dma_buf *dmabuf,
struct device *dev)
{
struct gk20a_vidmem_buf *buf = dmabuf->priv;
return buf->dmabuf_priv;
}
static const struct dma_buf_ops gk20a_vidbuf_ops = {
.map_dma_buf = gk20a_vidbuf_map_dma_buf,
.unmap_dma_buf = gk20a_vidbuf_unmap_dma_buf,
.release = gk20a_vidbuf_release,
.kmap_atomic = gk20a_vidbuf_kmap_atomic,
.kmap = gk20a_vidbuf_kmap,
.mmap = gk20a_vidbuf_mmap,
.set_drvdata = gk20a_vidbuf_set_private,
.get_drvdata = gk20a_vidbuf_get_private,
};
static struct dma_buf *gk20a_vidbuf_export(struct gk20a_vidmem_buf *buf)
{
#if LINUX_VERSION_CODE >= KERNEL_VERSION(4, 4, 0)
DEFINE_DMA_BUF_EXPORT_INFO(exp_info);
exp_info.priv = buf;
exp_info.ops = &gk20a_vidbuf_ops;
exp_info.size = buf->mem->size;
exp_info.flags = O_RDWR;
return dma_buf_export(&exp_info);
#else
return dma_buf_export(buf, &gk20a_vidbuf_ops, buf->mem->size,
O_RDWR, NULL);
#endif
}
#endif
static struct gk20a *gk20a_vidmem_buf_owner(struct dma_buf *dmabuf)
{
#if defined(CONFIG_GK20A_VIDMEM)
struct gk20a_vidmem_buf *buf = dmabuf->priv;
if (dmabuf->ops != &gk20a_vidbuf_ops)
return NULL;
return buf->g;
#else
return NULL;
#endif
}
int gk20a_vidmem_buf_alloc(struct gk20a *g, size_t bytes)
{
#if defined(CONFIG_GK20A_VIDMEM)
struct gk20a_vidmem_buf *buf;
int err = 0, fd;
gk20a_dbg_fn("");
buf = kzalloc(sizeof(*buf), GFP_KERNEL);
if (!buf)
return -ENOMEM;
buf->g = g;
if (!g->mm.vidmem.cleared) {
mutex_lock(&g->mm.vidmem.first_clear_mutex);
if (!g->mm.vidmem.cleared) {
err = gk20a_vidmem_clear_all(g);
if (err) {
gk20a_err(g->dev,
"failed to clear whole vidmem");
goto err_kfree;
}
}
mutex_unlock(&g->mm.vidmem.first_clear_mutex);
}
buf->mem = kzalloc(sizeof(struct mem_desc), GFP_KERNEL);
if (!buf->mem)
goto err_kfree;
buf->mem->user_mem = true;
err = gk20a_gmmu_alloc_vid(g, bytes, buf->mem);
if (err)
goto err_memfree;
buf->dmabuf = gk20a_vidbuf_export(buf);
if (IS_ERR(buf->dmabuf)) {
err = PTR_ERR(buf->dmabuf);
goto err_bfree;
}
fd = __alloc_fd(current->files, 1024, sysctl_nr_open, O_RDWR);
if (fd < 0) {
/* ->release frees what we have done */
dma_buf_put(buf->dmabuf);
return fd;
}
/* fclose() on this drops one ref, freeing the dma buf */
fd_install(fd, buf->dmabuf->file);
return fd;
err_bfree:
gk20a_gmmu_free(g, buf->mem);
err_memfree:
kfree(buf->mem);
err_kfree:
kfree(buf);
return err;
#else
return -ENOSYS;
#endif
}
int gk20a_vidmem_get_space(struct gk20a *g, u64 *space)
{
#if defined(CONFIG_GK20A_VIDMEM)
struct gk20a_allocator *allocator = &g->mm.vidmem.allocator;
gk20a_dbg_fn("");
if (!gk20a_alloc_initialized(allocator))
return -ENOSYS;
mutex_lock(&g->mm.vidmem.clear_list_mutex);
*space = gk20a_alloc_space(allocator) +
atomic64_read(&g->mm.vidmem.bytes_pending);
mutex_unlock(&g->mm.vidmem.clear_list_mutex);
return 0;
#else
return -ENOSYS;
#endif
}
int gk20a_vidbuf_access_memory(struct gk20a *g, struct dma_buf *dmabuf,
void *buffer, u64 offset, u64 size, u32 cmd)
{
#if defined(CONFIG_GK20A_VIDMEM)
struct gk20a_vidmem_buf *vidmem_buf;
struct mem_desc *mem;
int err = 0;
if (gk20a_dmabuf_aperture(g, dmabuf) != APERTURE_VIDMEM)
return -EINVAL;
vidmem_buf = dmabuf->priv;
mem = vidmem_buf->mem;
switch (cmd) {
case NVGPU_DBG_GPU_IOCTL_ACCESS_FB_MEMORY_CMD_READ:
gk20a_mem_rd_n(g, mem, offset, buffer, size);
break;
case NVGPU_DBG_GPU_IOCTL_ACCESS_FB_MEMORY_CMD_WRITE:
gk20a_mem_wr_n(g, mem, offset, buffer, size);
break;
default:
err = -EINVAL;
}
return err;
#else
return -ENOSYS;
#endif
}
static u64 gk20a_mm_get_align(struct gk20a *g, struct scatterlist *sgl,
enum gk20a_aperture aperture)
{
u64 align = 0, chunk_align = 0;
u64 buf_addr;
if (aperture == APERTURE_VIDMEM) {
struct gk20a_page_alloc *alloc = get_vidmem_page_alloc(sgl);
struct page_alloc_chunk *chunk = NULL;
list_for_each_entry(chunk, &alloc->alloc_chunks, list_entry) {
chunk_align = 1ULL << __ffs(chunk->base | chunk->length);
if (align)
align = min(align, chunk_align);
else
align = chunk_align;
}
return align;
}
buf_addr = (u64)sg_dma_address(sgl);
if (g->mm.bypass_smmu || buf_addr == DMA_ERROR_CODE || !buf_addr) {
while (sgl) {
buf_addr = (u64)sg_phys(sgl);
chunk_align = 1ULL << __ffs(buf_addr | (u64)sgl->length);
if (align)
align = min(align, chunk_align);
else
align = chunk_align;
sgl = sg_next(sgl);
}
return align;
}
align = 1ULL << __ffs(buf_addr);
return align;
}
u64 gk20a_vm_map(struct vm_gk20a *vm,
struct dma_buf *dmabuf,
u64 offset_align,
u32 flags /*NVGPU_AS_MAP_BUFFER_FLAGS_*/,
int kind,
struct sg_table **sgt,
bool user_mapped,
int rw_flag,
u64 buffer_offset,
u64 mapping_size,
struct vm_gk20a_mapping_batch *batch)
{
struct gk20a *g = gk20a_from_vm(vm);
struct gk20a_comptag_allocator *ctag_allocator = &g->gr.comp_tags;
struct device *d = dev_from_vm(vm);
struct mapped_buffer_node *mapped_buffer = NULL;
bool inserted = false, va_allocated = false;
u32 gmmu_page_size = 0;
u64 map_offset = 0;
int err = 0;
struct buffer_attrs bfr = {NULL};
struct gk20a_comptags comptags;
bool clear_ctags = false;
struct scatterlist *sgl;
u64 ctag_map_win_size = 0;
u32 ctag_map_win_ctagline = 0;
struct vm_reserved_va_node *va_node = NULL;
u32 ctag_offset;
enum gk20a_aperture aperture;
if (user_mapped && vm->userspace_managed &&
!(flags & NVGPU_AS_MAP_BUFFER_FLAGS_FIXED_OFFSET)) {
gk20a_err(d,
"%s: non-fixed-offset mapping not available on userspace managed address spaces",
__func__);
return -EFAULT;
}
mutex_lock(&vm->update_gmmu_lock);
/* check if this buffer is already mapped */
if (!vm->userspace_managed) {
map_offset = gk20a_vm_map_duplicate_locked(
vm, dmabuf, offset_align,
flags, kind, sgt,
user_mapped, rw_flag);
if (map_offset) {
mutex_unlock(&vm->update_gmmu_lock);
return map_offset;
}
}
/* pin buffer to get phys/iovmm addr */
bfr.sgt = gk20a_mm_pin(d, dmabuf);
if (IS_ERR(bfr.sgt)) {
/* Falling back to physical is actually possible
* here in many cases if we use 4K phys pages in the
* gmmu. However we have some regions which require
* contig regions to work properly (either phys-contig
* or contig through smmu io_vaspace). Until we can
* track the difference between those two cases we have
* to fail the mapping when we run out of SMMU space.
*/
gk20a_warn(d, "oom allocating tracking buffer");
goto clean_up;
}
if (sgt)
*sgt = bfr.sgt;
bfr.kind_v = kind;
bfr.size = dmabuf->size;
sgl = bfr.sgt->sgl;
aperture = gk20a_dmabuf_aperture(g, dmabuf);
if (aperture == APERTURE_INVALID) {
err = -EINVAL;
goto clean_up;
}
bfr.align = gk20a_mm_get_align(g, sgl, aperture);
bfr.pgsz_idx = -1;
mapping_size = mapping_size ? mapping_size : bfr.size;
if (vm->big_pages)
gmmu_select_page_size(vm, &bfr);
else
bfr.pgsz_idx = gmmu_page_size_small;
/* If FIX_OFFSET is set, pgsz is determined at address allocation
* time. The alignment at address alloc time must be the same as
* the alignment determined by gmmu_select_page_size().
*/
if (flags & NVGPU_AS_MAP_BUFFER_FLAGS_FIXED_OFFSET) {
int pgsz_idx =
__nv_gmmu_va_is_big_page_region(vm, offset_align) ?
gmmu_page_size_big : gmmu_page_size_small;
if (pgsz_idx > bfr.pgsz_idx) {
gk20a_err(d, "%llx buffer pgsz %d, VA pgsz %d",
offset_align, bfr.pgsz_idx, pgsz_idx);
err = -EINVAL;
goto clean_up;
}
bfr.pgsz_idx = min(bfr.pgsz_idx, pgsz_idx);
}
/* validate/adjust bfr attributes */
if (unlikely(bfr.pgsz_idx == -1)) {
gk20a_err(d, "unsupported page size detected");
goto clean_up;
}
if (unlikely(bfr.pgsz_idx < gmmu_page_size_small ||
bfr.pgsz_idx > gmmu_page_size_big)) {
BUG_ON(1);
err = -EINVAL;
goto clean_up;
}
gmmu_page_size = vm->gmmu_page_sizes[bfr.pgsz_idx];
/* Check if we should use a fixed offset for mapping this buffer */
if (flags & NVGPU_AS_MAP_BUFFER_FLAGS_FIXED_OFFSET) {
err = validate_fixed_buffer(vm, &bfr,
offset_align, mapping_size,
&va_node);
if (err)
goto clean_up;
map_offset = offset_align;
va_allocated = false;
} else
va_allocated = true;
if (sgt)
*sgt = bfr.sgt;
err = setup_buffer_kind_and_compression(vm, flags, &bfr, bfr.pgsz_idx);
if (unlikely(err)) {
gk20a_err(d, "failure setting up kind and compression");
goto clean_up;
}
/* bar1 and pmu vm don't need ctag */
if (!vm->enable_ctag)
bfr.ctag_lines = 0;
gk20a_get_comptags(d, dmabuf, &comptags);
/* ensure alignment to compression page size if compression enabled */
if (bfr.ctag_offset)
mapping_size = ALIGN(mapping_size,
g->ops.fb.compression_page_size(g));
if (bfr.ctag_lines && !comptags.lines) {
const bool user_mappable =
!!(flags & NVGPU_AS_MAP_BUFFER_FLAGS_MAPPABLE_COMPBITS);
/* allocate compression resources if needed */
err = gk20a_alloc_comptags(g, d, dmabuf, ctag_allocator,
bfr.ctag_lines, user_mappable,
&ctag_map_win_size,
&ctag_map_win_ctagline);
if (err) {
/* ok to fall back here if we ran out */
/* TBD: we can partially alloc ctags as well... */
bfr.kind_v = bfr.uc_kind_v;
} else {
gk20a_get_comptags(d, dmabuf, &comptags);
if (g->ops.ltc.cbc_ctrl)
g->ops.ltc.cbc_ctrl(g, gk20a_cbc_op_clear,
comptags.offset,
comptags.offset +
comptags.allocated_lines - 1);
else
clear_ctags = true;
}
}
/* store the comptag info */
bfr.ctag_offset = comptags.offset;
bfr.ctag_lines = comptags.lines;
bfr.ctag_allocated_lines = comptags.allocated_lines;
bfr.ctag_user_mappable = comptags.user_mappable;
/*
* Calculate comptag index for this mapping. Differs in
* case of partial mapping.
*/
ctag_offset = comptags.offset;
if (ctag_offset)
ctag_offset += buffer_offset >>
ilog2(g->ops.fb.compression_page_size(g));
/* update gmmu ptes */
map_offset = g->ops.mm.gmmu_map(vm, map_offset,
bfr.sgt,
buffer_offset, /* sg offset */
mapping_size,
bfr.pgsz_idx,
bfr.kind_v,
ctag_offset,
flags, rw_flag,
clear_ctags,
false,
false,
batch,
aperture);
if (!map_offset)
goto clean_up;
#if defined(NVHOST_DEBUG)
{
int i;
struct scatterlist *sg = NULL;
gk20a_dbg(gpu_dbg_pte, "for_each_sg(bfr.sgt->sgl, sg, bfr.sgt->nents, i)");
for_each_sg(bfr.sgt->sgl, sg, bfr.sgt->nents, i ) {
u64 da = sg_dma_address(sg);
u64 pa = sg_phys(sg);
u64 len = sg->length;
gk20a_dbg(gpu_dbg_pte, "i=%d pa=0x%x,%08x da=0x%x,%08x len=0x%x,%08x",
i, hi32(pa), lo32(pa), hi32(da), lo32(da),
hi32(len), lo32(len));
}
}
#endif
/* keep track of the buffer for unmapping */
/* TBD: check for multiple mapping of same buffer */
mapped_buffer = kzalloc(sizeof(*mapped_buffer), GFP_KERNEL);
if (!mapped_buffer) {
gk20a_warn(d, "oom allocating tracking buffer");
goto clean_up;
}
mapped_buffer->dmabuf = dmabuf;
mapped_buffer->sgt = bfr.sgt;
mapped_buffer->addr = map_offset;
mapped_buffer->size = mapping_size;
mapped_buffer->pgsz_idx = bfr.pgsz_idx;
mapped_buffer->ctag_offset = bfr.ctag_offset;
mapped_buffer->ctag_lines = bfr.ctag_lines;
mapped_buffer->ctag_allocated_lines = bfr.ctag_allocated_lines;
mapped_buffer->ctags_mappable = bfr.ctag_user_mappable;
mapped_buffer->ctag_map_win_size = ctag_map_win_size;
mapped_buffer->ctag_map_win_ctagline = ctag_map_win_ctagline;
mapped_buffer->vm = vm;
mapped_buffer->flags = flags;
mapped_buffer->kind = kind;
mapped_buffer->va_allocated = va_allocated;
mapped_buffer->user_mapped = user_mapped ? 1 : 0;
mapped_buffer->own_mem_ref = user_mapped;
INIT_LIST_HEAD(&mapped_buffer->unmap_list);
INIT_LIST_HEAD(&mapped_buffer->va_buffers_list);
kref_init(&mapped_buffer->ref);
err = insert_mapped_buffer(&vm->mapped_buffers, mapped_buffer);
if (err) {
gk20a_err(d, "failed to insert into mapped buffer tree");
goto clean_up;
}
inserted = true;
if (user_mapped)
vm->num_user_mapped_buffers++;
gk20a_dbg_info("allocated va @ 0x%llx", map_offset);
if (va_node) {
list_add_tail(&mapped_buffer->va_buffers_list,
&va_node->va_buffers_list);
mapped_buffer->va_node = va_node;
}
mutex_unlock(&vm->update_gmmu_lock);
return map_offset;
clean_up:
if (inserted) {
rb_erase(&mapped_buffer->node, &vm->mapped_buffers);
if (user_mapped)
vm->num_user_mapped_buffers--;
}
kfree(mapped_buffer);
if (va_allocated)
gk20a_vm_free_va(vm, map_offset, bfr.size, bfr.pgsz_idx);
if (!IS_ERR(bfr.sgt))
gk20a_mm_unpin(d, dmabuf, bfr.sgt);
mutex_unlock(&vm->update_gmmu_lock);
gk20a_dbg_info("err=%d\n", err);
return 0;
}
int gk20a_vm_get_compbits_info(struct vm_gk20a *vm,
u64 mapping_gva,
u64 *compbits_win_size,
u32 *compbits_win_ctagline,
u32 *mapping_ctagline,
u32 *flags)
{
struct mapped_buffer_node *mapped_buffer;
struct device *d = dev_from_vm(vm);
mutex_lock(&vm->update_gmmu_lock);
mapped_buffer = find_mapped_buffer_locked(&vm->mapped_buffers, mapping_gva);
if (!mapped_buffer || !mapped_buffer->user_mapped)
{
mutex_unlock(&vm->update_gmmu_lock);
gk20a_err(d, "%s: bad offset 0x%llx", __func__, mapping_gva);
return -EFAULT;
}
*compbits_win_size = 0;
*compbits_win_ctagline = 0;
*mapping_ctagline = 0;
*flags = 0;
if (mapped_buffer->ctag_offset)
*flags |= NVGPU_AS_GET_BUFFER_COMPBITS_INFO_FLAGS_HAS_COMPBITS;
if (mapped_buffer->ctags_mappable)
{
*flags |= NVGPU_AS_GET_BUFFER_COMPBITS_INFO_FLAGS_MAPPABLE;
*compbits_win_size = mapped_buffer->ctag_map_win_size;
*compbits_win_ctagline = mapped_buffer->ctag_map_win_ctagline;
*mapping_ctagline = mapped_buffer->ctag_offset;
}
mutex_unlock(&vm->update_gmmu_lock);
return 0;
}
int gk20a_vm_map_compbits(struct vm_gk20a *vm,
u64 mapping_gva,
u64 *compbits_win_gva,
u64 *mapping_iova,
u32 flags)
{
struct mapped_buffer_node *mapped_buffer;
struct gk20a *g = gk20a_from_vm(vm);
struct device *d = dev_from_vm(vm);
const bool fixed_mapping =
(flags & NVGPU_AS_MAP_BUFFER_COMPBITS_FLAGS_FIXED_OFFSET) != 0;
if (vm->userspace_managed && !fixed_mapping) {
gk20a_err(d,
"%s: non-fixed-offset mapping is not available on userspace managed address spaces",
__func__);
return -EFAULT;
}
if (fixed_mapping && !vm->userspace_managed) {
gk20a_err(d,
"%s: fixed-offset mapping is available only on userspace managed address spaces",
__func__);
return -EFAULT;
}
mutex_lock(&vm->update_gmmu_lock);
mapped_buffer =
find_mapped_buffer_locked(&vm->mapped_buffers, mapping_gva);
if (!mapped_buffer || !mapped_buffer->user_mapped) {
mutex_unlock(&vm->update_gmmu_lock);
gk20a_err(d, "%s: bad offset 0x%llx", __func__, mapping_gva);
return -EFAULT;
}
if (!mapped_buffer->ctags_mappable) {
mutex_unlock(&vm->update_gmmu_lock);
gk20a_err(d, "%s: comptags not mappable, offset 0x%llx",
__func__, mapping_gva);
return -EFAULT;
}
if (!mapped_buffer->ctag_map_win_addr) {
const u32 small_pgsz_index = 0; /* small pages, 4K */
const u32 aggregate_cacheline_sz =
g->gr.cacheline_size * g->gr.slices_per_ltc *
g->ltc_count;
/* first aggregate cacheline to map */
u32 cacheline_start; /* inclusive */
/* offset of the start cacheline (will be page aligned) */
u64 cacheline_offset_start;
if (!mapped_buffer->ctag_map_win_size) {
mutex_unlock(&vm->update_gmmu_lock);
gk20a_err(d,
"%s: mapping 0x%llx does not have "
"mappable comptags",
__func__, mapping_gva);
return -EFAULT;
}
cacheline_start = mapped_buffer->ctag_offset /
g->gr.comptags_per_cacheline;
cacheline_offset_start =
(u64)cacheline_start * aggregate_cacheline_sz;
if (fixed_mapping) {
struct buffer_attrs bfr;
int err;
struct vm_reserved_va_node *va_node = NULL;
memset(&bfr, 0, sizeof(bfr));
bfr.pgsz_idx = small_pgsz_index;
err = validate_fixed_buffer(
vm, &bfr, *compbits_win_gva,
mapped_buffer->ctag_map_win_size, &va_node);
if (err) {
mutex_unlock(&vm->update_gmmu_lock);
return err;
}
if (va_node) {
/* this would create a dangling GPU VA
* pointer if the space is freed
* before before the buffer is
* unmapped */
mutex_unlock(&vm->update_gmmu_lock);
gk20a_err(d,
"%s: comptags cannot be mapped into allocated space",
__func__);
return -EINVAL;
}
}
mapped_buffer->ctag_map_win_addr =
g->ops.mm.gmmu_map(
vm,
!fixed_mapping ? 0 : *compbits_win_gva, /* va */
g->gr.compbit_store.mem.sgt,
cacheline_offset_start, /* sg offset */
mapped_buffer->ctag_map_win_size, /* size */
small_pgsz_index,
0, /* kind */
0, /* ctag_offset */
NVGPU_MAP_BUFFER_FLAGS_CACHEABLE_TRUE,
gk20a_mem_flag_read_only,
false, /* clear_ctags */
false, /* sparse */
false, /* priv */
NULL, /* mapping_batch handle */
g->gr.compbit_store.mem.aperture);
if (!mapped_buffer->ctag_map_win_addr) {
mutex_unlock(&vm->update_gmmu_lock);
gk20a_err(d,
"%s: failed to map comptags for mapping 0x%llx",
__func__, mapping_gva);
return -ENOMEM;
}
} else if (fixed_mapping && *compbits_win_gva &&
mapped_buffer->ctag_map_win_addr != *compbits_win_gva) {
mutex_unlock(&vm->update_gmmu_lock);
gk20a_err(d,
"%s: re-requesting comptags map into mismatching address. buffer offset 0x"
"%llx, existing comptag map at 0x%llx, requested remap 0x%llx",
__func__, mapping_gva,
mapped_buffer->ctag_map_win_addr, *compbits_win_gva);
return -EINVAL;
}
*mapping_iova = gk20a_mm_iova_addr(g, mapped_buffer->sgt->sgl, 0);
*compbits_win_gva = mapped_buffer->ctag_map_win_addr;
mutex_unlock(&vm->update_gmmu_lock);
return 0;
}
/*
* Core GMMU map function for the kernel to use. If @addr is 0 then the GPU
* VA will be allocated for you. If addr is non-zero then the buffer will be
* mapped at @addr.
*/
static u64 __gk20a_gmmu_map(struct vm_gk20a *vm,
struct sg_table **sgt,
u64 addr,
u64 size,
u32 flags,
int rw_flag,
bool priv,
enum gk20a_aperture aperture)
{
struct gk20a *g = gk20a_from_vm(vm);
u64 vaddr;
mutex_lock(&vm->update_gmmu_lock);
vaddr = g->ops.mm.gmmu_map(vm, addr,
*sgt, /* sg table */
0, /* sg offset */
size,
gmmu_page_size_kernel,
0, /* kind */
0, /* ctag_offset */
flags, rw_flag,
false, /* clear_ctags */
false, /* sparse */
priv, /* priv */
NULL, /* mapping_batch handle */
aperture);
mutex_unlock(&vm->update_gmmu_lock);
if (!vaddr) {
gk20a_err(dev_from_vm(vm), "failed to allocate va space");
return 0;
}
return vaddr;
}
u64 gk20a_gmmu_map(struct vm_gk20a *vm,
struct sg_table **sgt,
u64 size,
u32 flags,
int rw_flag,
bool priv,
enum gk20a_aperture aperture)
{
return __gk20a_gmmu_map(vm, sgt, 0, size, flags, rw_flag, priv,
aperture);
}
/*
* Like gk20a_gmmu_map() except it works on a fixed address instead.
*/
u64 gk20a_gmmu_fixed_map(struct vm_gk20a *vm,
struct sg_table **sgt,
u64 addr,
u64 size,
u32 flags,
int rw_flag,
bool priv,
enum gk20a_aperture aperture)
{
return __gk20a_gmmu_map(vm, sgt, addr, size, flags, rw_flag, priv,
aperture);
}
int gk20a_gmmu_alloc(struct gk20a *g, size_t size, struct mem_desc *mem)
{
return gk20a_gmmu_alloc_attr(g, 0, size, mem);
}
int gk20a_gmmu_alloc_attr(struct gk20a *g, enum dma_attr attr, size_t size,
struct mem_desc *mem)
{
if (g->mm.vidmem_is_vidmem) {
int err = gk20a_gmmu_alloc_attr_vid(g, attr, size, mem);
if (!err)
return 0;
/*
* Fall back to sysmem (which may then also fail) in case
* vidmem is exhausted.
*/
}
return gk20a_gmmu_alloc_attr_sys(g, attr, size, mem);
}
int gk20a_gmmu_alloc_sys(struct gk20a *g, size_t size, struct mem_desc *mem)
{
return gk20a_gmmu_alloc_attr_sys(g, 0, size, mem);
}
int gk20a_gmmu_alloc_attr_sys(struct gk20a *g, enum dma_attr attr,
size_t size, struct mem_desc *mem)
{
struct device *d = dev_from_gk20a(g);
int err;
dma_addr_t iova;
gk20a_dbg_fn("");
if (attr) {
DEFINE_DMA_ATTRS(attrs);
dma_set_attr(attr, &attrs);
if (attr == DMA_ATTR_NO_KERNEL_MAPPING) {
mem->pages = dma_alloc_attrs(d,
size, &iova, GFP_KERNEL, &attrs);
if (!mem->pages)
return -ENOMEM;
} else {
mem->cpu_va = dma_alloc_attrs(d,
size, &iova, GFP_KERNEL, &attrs);
if (!mem->cpu_va)
return -ENOMEM;
}
} else {
mem->cpu_va = dma_alloc_coherent(d, size, &iova, GFP_KERNEL);
if (!mem->cpu_va)
return -ENOMEM;
}
if (attr == DMA_ATTR_NO_KERNEL_MAPPING)
err = gk20a_get_sgtable_from_pages(d, &mem->sgt, mem->pages,
iova, size);
else {
err = gk20a_get_sgtable(d, &mem->sgt, mem->cpu_va, iova, size);
memset(mem->cpu_va, 0, size);
}
if (err)
goto fail_free;
mem->size = size;
mem->aperture = APERTURE_SYSMEM;
gk20a_dbg_fn("done");
return 0;
fail_free:
dma_free_coherent(d, size, mem->cpu_va, iova);
mem->cpu_va = NULL;
mem->sgt = NULL;
return err;
}
static void gk20a_gmmu_free_attr_sys(struct gk20a *g, enum dma_attr attr,
struct mem_desc *mem)
{
struct device *d = dev_from_gk20a(g);
if (mem->cpu_va || mem->pages) {
if (attr) {
DEFINE_DMA_ATTRS(attrs);
dma_set_attr(attr, &attrs);
if (attr == DMA_ATTR_NO_KERNEL_MAPPING) {
if (mem->pages)
dma_free_attrs(d, mem->size, mem->pages,
sg_dma_address(mem->sgt->sgl),
&attrs);
} else {
if (mem->cpu_va)
dma_free_attrs(d, mem->size,
mem->cpu_va,
sg_dma_address(mem->sgt->sgl),
&attrs);
}
} else {
if (mem->cpu_va)
dma_free_coherent(d, mem->size, mem->cpu_va,
sg_dma_address(mem->sgt->sgl));
}
mem->cpu_va = NULL;
mem->pages = NULL;
}
if (mem->sgt)
gk20a_free_sgtable(&mem->sgt);
mem->size = 0;
mem->aperture = APERTURE_INVALID;
}
#if defined(CONFIG_GK20A_VIDMEM)
static int gk20a_gmmu_clear_vidmem_mem(struct gk20a *g, struct mem_desc *mem)
{
struct gk20a_fence *gk20a_fence_out = NULL;
struct gk20a_fence *gk20a_last_fence = NULL;
struct gk20a_page_alloc *alloc = NULL;
struct page_alloc_chunk *chunk = NULL;
int err = 0;
if (g->mm.vidmem.ce_ctx_id == (u32)~0)
return -EINVAL;
alloc = get_vidmem_page_alloc(mem->sgt->sgl);
list_for_each_entry(chunk, &alloc->alloc_chunks, list_entry) {
if (gk20a_last_fence)
gk20a_fence_put(gk20a_last_fence);
err = gk20a_ce_execute_ops(g->dev,
g->mm.vidmem.ce_ctx_id,
0,
chunk->base,
chunk->length,
0x00000000,
NVGPU_CE_DST_LOCATION_LOCAL_FB,
NVGPU_CE_MEMSET,
NULL,
0,
&gk20a_fence_out);
if (err) {
gk20a_err(g->dev,
"Failed gk20a_ce_execute_ops[%d]", err);
return err;
}
gk20a_last_fence = gk20a_fence_out;
}
if (gk20a_last_fence) {
unsigned long end_jiffies = jiffies +
msecs_to_jiffies(gk20a_get_gr_idle_timeout(g));
do {
unsigned int timeout = jiffies_to_msecs(end_jiffies - jiffies);
err = gk20a_fence_wait(gk20a_last_fence,
timeout);
} while ((err == -ERESTARTSYS) && time_before(jiffies, end_jiffies));
gk20a_fence_put(gk20a_last_fence);
if (err)
gk20a_err(g->dev,
"fence wait failed for CE execute ops");
}
return err;
}
#endif
int gk20a_gmmu_alloc_vid(struct gk20a *g, size_t size, struct mem_desc *mem)
{
return gk20a_gmmu_alloc_attr_vid(g, 0, size, mem);
}
int gk20a_gmmu_alloc_attr_vid(struct gk20a *g, enum dma_attr attr,
size_t size, struct mem_desc *mem)
{
return gk20a_gmmu_alloc_attr_vid_at(g, attr, size, mem, 0);
}
#if defined(CONFIG_GK20A_VIDMEM)
static u64 __gk20a_gmmu_alloc(struct gk20a_allocator *allocator, dma_addr_t at,
size_t size)
{
u64 addr = 0;
if (at)
addr = gk20a_alloc_fixed(allocator, at, size);
else
addr = gk20a_alloc(allocator, size);
return addr;
}
#endif
int gk20a_gmmu_alloc_attr_vid_at(struct gk20a *g, enum dma_attr attr,
size_t size, struct mem_desc *mem, dma_addr_t at)
{
#if defined(CONFIG_GK20A_VIDMEM)
u64 addr;
int err;
struct gk20a_allocator *vidmem_alloc = g->mm.vidmem.cleared ?
&g->mm.vidmem.allocator :
&g->mm.vidmem.bootstrap_allocator;
int before_pending;
gk20a_dbg_fn("");
if (!gk20a_alloc_initialized(&g->mm.vidmem.allocator))
return -ENOSYS;
/* we don't support dma attributes here, except that kernel mappings
* are not done anyway */
WARN_ON(attr != 0 && attr != DMA_ATTR_NO_KERNEL_MAPPING);
mutex_lock(&g->mm.vidmem.clear_list_mutex);
before_pending = atomic64_read(&g->mm.vidmem.bytes_pending);
addr = __gk20a_gmmu_alloc(vidmem_alloc, at, size);
mutex_unlock(&g->mm.vidmem.clear_list_mutex);
if (!addr) {
/*
* If memory is known to be freed soon, let the user know that
* it may be available after a while.
*/
if (before_pending)
return -EAGAIN;
else
return -ENOMEM;
}
if (at)
mem->fixed = true;
else
mem->fixed = false;
mem->sgt = kzalloc(sizeof(struct sg_table), GFP_KERNEL);
if (!mem->sgt) {
err = -ENOMEM;
goto fail_physfree;
}
err = sg_alloc_table(mem->sgt, 1, GFP_KERNEL);
if (err)
goto fail_kfree;
set_vidmem_page_alloc(mem->sgt->sgl, addr);
sg_set_page(mem->sgt->sgl, NULL, size, 0);
mem->size = size;
mem->aperture = APERTURE_VIDMEM;
mem->allocator = vidmem_alloc;
INIT_LIST_HEAD(&mem->clear_list_entry);
gk20a_dbg_fn("done at 0x%llx size %zu", addr, size);
return 0;
fail_kfree:
kfree(mem->sgt);
fail_physfree:
gk20a_free(&g->mm.vidmem.allocator, addr);
return err;
#else
return -ENOSYS;
#endif
}
static void gk20a_gmmu_free_attr_vid(struct gk20a *g, enum dma_attr attr,
struct mem_desc *mem)
{
#if defined(CONFIG_GK20A_VIDMEM)
bool was_empty;
if (mem->user_mem) {
mutex_lock(&g->mm.vidmem.clear_list_mutex);
was_empty = list_empty(&g->mm.vidmem.clear_list_head);
list_add_tail(&mem->clear_list_entry,
&g->mm.vidmem.clear_list_head);
atomic64_add(mem->size, &g->mm.vidmem.bytes_pending);
mutex_unlock(&g->mm.vidmem.clear_list_mutex);
if (was_empty) {
cancel_work_sync(&g->mm.vidmem.clear_mem_worker);
schedule_work(&g->mm.vidmem.clear_mem_worker);
}
} else {
gk20a_memset(g, mem, 0, 0, mem->size);
gk20a_free(mem->allocator,
(u64)get_vidmem_page_alloc(mem->sgt->sgl));
gk20a_free_sgtable(&mem->sgt);
mem->size = 0;
mem->aperture = APERTURE_INVALID;
}
#endif
}
void gk20a_gmmu_free_attr(struct gk20a *g, enum dma_attr attr,
struct mem_desc *mem)
{
switch (mem->aperture) {
case APERTURE_SYSMEM:
return gk20a_gmmu_free_attr_sys(g, attr, mem);
case APERTURE_VIDMEM:
return gk20a_gmmu_free_attr_vid(g, attr, mem);
default:
break; /* like free() on "null" memory */
}
}
void gk20a_gmmu_free(struct gk20a *g, struct mem_desc *mem)
{
return gk20a_gmmu_free_attr(g, 0, mem);
}
/*
* If mem is in VIDMEM, return base address in vidmem
* else return IOVA address for SYSMEM
*/
u64 gk20a_mem_get_base_addr(struct gk20a *g, struct mem_desc *mem,
u32 flags)
{
struct gk20a_page_alloc *alloc;
u64 addr;
if (mem->aperture == APERTURE_VIDMEM) {
alloc = get_vidmem_page_alloc(mem->sgt->sgl);
/* This API should not be used with > 1 chunks */
WARN_ON(alloc->nr_chunks != 1);
addr = alloc->base;
} else {
addr = g->ops.mm.get_iova_addr(g, mem->sgt->sgl, flags);
}
return addr;
}
#if defined(CONFIG_GK20A_VIDMEM)
static struct mem_desc *get_pending_mem_desc(struct mm_gk20a *mm)
{
struct mem_desc *mem = NULL;
mutex_lock(&mm->vidmem.clear_list_mutex);
mem = list_first_entry_or_null(&mm->vidmem.clear_list_head,
struct mem_desc, clear_list_entry);
if (mem)
list_del_init(&mem->clear_list_entry);
mutex_unlock(&mm->vidmem.clear_list_mutex);
return mem;
}
static void gk20a_vidmem_clear_mem_worker(struct work_struct *work)
{
struct mm_gk20a *mm = container_of(work, struct mm_gk20a,
vidmem.clear_mem_worker);
struct gk20a *g = mm->g;
struct mem_desc *mem;
while ((mem = get_pending_mem_desc(mm)) != NULL) {
gk20a_gmmu_clear_vidmem_mem(g, mem);
gk20a_free(mem->allocator,
(u64)get_vidmem_page_alloc(mem->sgt->sgl));
gk20a_free_sgtable(&mem->sgt);
WARN_ON(atomic64_sub_return(mem->size,
&g->mm.vidmem.bytes_pending) < 0);
mem->size = 0;
mem->aperture = APERTURE_INVALID;
kfree(mem);
}
}
#endif
u32 __gk20a_aperture_mask(struct gk20a *g, enum gk20a_aperture aperture,
u32 sysmem_mask, u32 vidmem_mask)
{
switch (aperture) {
case APERTURE_SYSMEM:
/* sysmem for dgpus; some igpus consider system memory vidmem */
return g->mm.vidmem_is_vidmem ? sysmem_mask : vidmem_mask;
case APERTURE_VIDMEM:
/* for dgpus only */
return vidmem_mask;
case APERTURE_INVALID:
WARN_ON("Bad aperture");
}
return 0;
}
u32 gk20a_aperture_mask(struct gk20a *g, struct mem_desc *mem,
u32 sysmem_mask, u32 vidmem_mask)
{
return __gk20a_aperture_mask(g, mem->aperture,
sysmem_mask, vidmem_mask);
}
int gk20a_gmmu_alloc_map(struct vm_gk20a *vm, size_t size,
struct mem_desc *mem)
{
return gk20a_gmmu_alloc_map_attr(vm, 0, size, mem);
}
int gk20a_gmmu_alloc_map_attr(struct vm_gk20a *vm,
enum dma_attr attr, size_t size, struct mem_desc *mem)
{
if (vm->mm->vidmem_is_vidmem) {
int err = gk20a_gmmu_alloc_map_attr_vid(vm, 0, size, mem);
if (!err)
return 0;
/*
* Fall back to sysmem (which may then also fail) in case
* vidmem is exhausted.
*/
}
return gk20a_gmmu_alloc_map_attr_sys(vm, 0, size, mem);
}
int gk20a_gmmu_alloc_map_sys(struct vm_gk20a *vm, size_t size,
struct mem_desc *mem)
{
return gk20a_gmmu_alloc_map_attr_sys(vm, 0, size, mem);
}
int gk20a_gmmu_alloc_map_attr_sys(struct vm_gk20a *vm,
enum dma_attr attr, size_t size, struct mem_desc *mem)
{
int err = gk20a_gmmu_alloc_attr_sys(vm->mm->g, attr, size, mem);
if (err)
return err;
mem->gpu_va = gk20a_gmmu_map(vm, &mem->sgt, size, 0,
gk20a_mem_flag_none, false,
mem->aperture);
if (!mem->gpu_va) {
err = -ENOMEM;
goto fail_free;
}
return 0;
fail_free:
gk20a_gmmu_free(vm->mm->g, mem);
return err;
}
int gk20a_gmmu_alloc_map_vid(struct vm_gk20a *vm, size_t size, struct mem_desc *mem)
{
return gk20a_gmmu_alloc_map_attr_vid(vm, 0, size, mem);
}
int gk20a_gmmu_alloc_map_attr_vid(struct vm_gk20a *vm,
enum dma_attr attr, size_t size, struct mem_desc *mem)
{
int err = gk20a_gmmu_alloc_attr_vid(vm->mm->g, attr, size, mem);
if (err)
return err;
mem->gpu_va = gk20a_gmmu_map(vm, &mem->sgt, size, 0,
gk20a_mem_flag_none, false,
mem->aperture);
if (!mem->gpu_va) {
err = -ENOMEM;
goto fail_free;
}
return 0;
fail_free:
gk20a_gmmu_free(vm->mm->g, mem);
return err;
}
void gk20a_gmmu_unmap_free(struct vm_gk20a *vm, struct mem_desc *mem)
{
if (mem->gpu_va)
gk20a_gmmu_unmap(vm, mem->gpu_va, mem->size, gk20a_mem_flag_none);
mem->gpu_va = 0;
gk20a_gmmu_free(vm->mm->g, mem);
}
dma_addr_t gk20a_mm_gpuva_to_iova_base(struct vm_gk20a *vm, u64 gpu_vaddr)
{
struct mapped_buffer_node *buffer;
dma_addr_t addr = 0;
struct gk20a *g = gk20a_from_vm(vm);
mutex_lock(&vm->update_gmmu_lock);
buffer = find_mapped_buffer_locked(&vm->mapped_buffers, gpu_vaddr);
if (buffer)
addr = g->ops.mm.get_iova_addr(g, buffer->sgt->sgl,
buffer->flags);
mutex_unlock(&vm->update_gmmu_lock);
return addr;
}
void gk20a_gmmu_unmap(struct vm_gk20a *vm,
u64 vaddr,
u64 size,
int rw_flag)
{
struct gk20a *g = gk20a_from_vm(vm);
mutex_lock(&vm->update_gmmu_lock);
g->ops.mm.gmmu_unmap(vm,
vaddr,
size,
gmmu_page_size_kernel,
true, /*va_allocated */
rw_flag,
false,
NULL);
mutex_unlock(&vm->update_gmmu_lock);
}
phys_addr_t gk20a_get_phys_from_iova(struct device *d,
u64 dma_addr)
{
phys_addr_t phys;
u64 iova;
struct dma_iommu_mapping *mapping = to_dma_iommu_mapping(d);
if (!mapping)
return dma_addr;
iova = dma_addr & PAGE_MASK;
phys = iommu_iova_to_phys(mapping->domain, iova);
return phys;
}
/* get sg_table from already allocated buffer */
int gk20a_get_sgtable(struct device *d, struct sg_table **sgt,
void *cpuva, u64 iova,
size_t size)
{
int err = 0;
*sgt = kzalloc(sizeof(struct sg_table), GFP_KERNEL);
if (!(*sgt)) {
dev_err(d, "failed to allocate memory\n");
err = -ENOMEM;
goto fail;
}
err = dma_get_sgtable(d, *sgt,
cpuva, iova,
size);
if (err) {
dev_err(d, "failed to create sg table\n");
goto fail;
}
sg_dma_address((*sgt)->sgl) = iova;
return 0;
fail:
if (*sgt) {
kfree(*sgt);
*sgt = NULL;
}
return err;
}
int gk20a_get_sgtable_from_pages(struct device *d, struct sg_table **sgt,
struct page **pages, u64 iova,
size_t size)
{
int err = 0;
*sgt = kzalloc(sizeof(struct sg_table), GFP_KERNEL);
if (!(*sgt)) {
dev_err(d, "failed to allocate memory\n");
err = -ENOMEM;
goto fail;
}
err = sg_alloc_table_from_pages(*sgt, pages,
DIV_ROUND_UP(size, PAGE_SIZE), 0, size, GFP_KERNEL);
if (err) {
dev_err(d, "failed to allocate sg_table\n");
goto fail;
}
sg_dma_address((*sgt)->sgl) = iova;
return 0;
fail:
if (*sgt) {
kfree(*sgt);
*sgt = NULL;
}
return err;
}
void gk20a_free_sgtable(struct sg_table **sgt)
{
sg_free_table(*sgt);
kfree(*sgt);
*sgt = NULL;
}
u64 gk20a_mm_smmu_vaddr_translate(struct gk20a *g, dma_addr_t iova)
{
/* ensure it is not vidmem allocation */
WARN_ON(is_vidmem_page_alloc((u64)iova));
if (device_is_iommuable(dev_from_gk20a(g)) &&
g->ops.mm.get_physical_addr_bits)
return iova | 1ULL << g->ops.mm.get_physical_addr_bits(g);
return iova;
}
u64 gk20a_mm_iova_addr(struct gk20a *g, struct scatterlist *sgl,
u32 flags)
{
if (!device_is_iommuable(dev_from_gk20a(g)))
return sg_phys(sgl);
if (sg_dma_address(sgl) == 0)
return sg_phys(sgl);
if (sg_dma_address(sgl) == DMA_ERROR_CODE)
return 0;
return gk20a_mm_smmu_vaddr_translate(g, sg_dma_address(sgl));
}
void gk20a_pde_wr32(struct gk20a *g, struct gk20a_mm_entry *entry,
size_t w, size_t data)
{
gk20a_mem_wr32(g, &entry->mem, entry->woffset + w, data);
}
u64 gk20a_pde_addr(struct gk20a *g, struct gk20a_mm_entry *entry)
{
u64 base;
if (g->mm.has_physical_mode)
base = sg_phys(entry->mem.sgt->sgl);
else
base = gk20a_mem_get_base_addr(g, &entry->mem, 0);
return base + entry->woffset * sizeof(u32);
}
/* for gk20a the "video memory" apertures here are misnomers. */
static inline u32 big_valid_pde0_bits(struct gk20a *g,
struct gk20a_mm_entry *entry)
{
u64 pte_addr = gk20a_pde_addr(g, entry);
u32 pde0_bits =
gk20a_aperture_mask(g, &entry->mem,
gmmu_pde_aperture_big_sys_mem_ncoh_f(),
gmmu_pde_aperture_big_video_memory_f()) |
gmmu_pde_address_big_sys_f(
(u32)(pte_addr >> gmmu_pde_address_shift_v()));
return pde0_bits;
}
static inline u32 small_valid_pde1_bits(struct gk20a *g,
struct gk20a_mm_entry *entry)
{
u64 pte_addr = gk20a_pde_addr(g, entry);
u32 pde1_bits =
gk20a_aperture_mask(g, &entry->mem,
gmmu_pde_aperture_small_sys_mem_ncoh_f(),
gmmu_pde_aperture_small_video_memory_f()) |
gmmu_pde_vol_small_true_f() | /* tbd: why? */
gmmu_pde_address_small_sys_f(
(u32)(pte_addr >> gmmu_pde_address_shift_v()));
return pde1_bits;
}
/* Given the current state of the ptes associated with a pde,
determine value and write it out. There's no checking
here to determine whether or not a change was actually
made. So, superfluous updates will cause unnecessary
pde invalidations.
*/
static int update_gmmu_pde_locked(struct vm_gk20a *vm,
struct gk20a_mm_entry *pte,
u32 i, u32 gmmu_pgsz_idx,
struct scatterlist **sgl,
u64 *offset,
u64 *iova,
u32 kind_v, u64 *ctag,
bool cacheable, bool unammped_pte,
int rw_flag, bool sparse, bool priv,
enum gk20a_aperture aperture)
{
struct gk20a *g = gk20a_from_vm(vm);
bool small_valid, big_valid;
struct gk20a_mm_entry *entry = vm->pdb.entries + i;
u32 pde_v[2] = {0, 0};
u32 pde;
gk20a_dbg_fn("");
small_valid = entry->mem.size && entry->pgsz == gmmu_page_size_small;
big_valid = entry->mem.size && entry->pgsz == gmmu_page_size_big;
pde_v[0] = gmmu_pde_size_full_f();
pde_v[0] |= big_valid ?
big_valid_pde0_bits(g, entry) :
gmmu_pde_aperture_big_invalid_f();
pde_v[1] |= (small_valid ?
small_valid_pde1_bits(g, entry) :
(gmmu_pde_aperture_small_invalid_f() |
gmmu_pde_vol_small_false_f()))
|
(big_valid ? (gmmu_pde_vol_big_true_f()) :
gmmu_pde_vol_big_false_f());
pde = pde_from_index(i);
gk20a_pde_wr32(g, &vm->pdb, pde + 0, pde_v[0]);
gk20a_pde_wr32(g, &vm->pdb, pde + 1, pde_v[1]);
gk20a_dbg(gpu_dbg_pte, "pde:%d,sz=%d = 0x%x,0x%08x",
i, gmmu_pgsz_idx, pde_v[1], pde_v[0]);
return 0;
}
static int update_gmmu_pte_locked(struct vm_gk20a *vm,
struct gk20a_mm_entry *pte,
u32 i, u32 gmmu_pgsz_idx,
struct scatterlist **sgl,
u64 *offset,
u64 *iova,
u32 kind_v, u64 *ctag,
bool cacheable, bool unmapped_pte,
int rw_flag, bool sparse, bool priv,
enum gk20a_aperture aperture)
{
struct gk20a *g = gk20a_from_vm(vm);
int ctag_shift = ilog2(g->ops.fb.compression_page_size(g));
u32 page_size = vm->gmmu_page_sizes[gmmu_pgsz_idx];
u32 pte_w[2] = {0, 0}; /* invalid pte */
if (*iova) {
u32 pte_valid = unmapped_pte ?
gmmu_pte_valid_false_f() :
gmmu_pte_valid_true_f();
u32 iova_v = *iova >> gmmu_pte_address_shift_v();
u32 pte_addr = aperture == APERTURE_SYSMEM ?
gmmu_pte_address_sys_f(iova_v) :
gmmu_pte_address_vid_f(iova_v);
pte_w[0] = pte_valid | pte_addr;
if (priv)
pte_w[0] |= gmmu_pte_privilege_true_f();
pte_w[1] = __gk20a_aperture_mask(g, aperture,
gmmu_pte_aperture_sys_mem_ncoh_f(),
gmmu_pte_aperture_video_memory_f()) |
gmmu_pte_kind_f(kind_v) |
gmmu_pte_comptagline_f((u32)(*ctag >> ctag_shift));
if (*ctag && vm->mm->use_full_comp_tag_line && *iova & 0x10000)
pte_w[1] |= gmmu_pte_comptagline_f(
1 << (gmmu_pte_comptagline_s() - 1));
if (rw_flag == gk20a_mem_flag_read_only) {
pte_w[0] |= gmmu_pte_read_only_true_f();
pte_w[1] |=
gmmu_pte_write_disable_true_f();
} else if (rw_flag ==
gk20a_mem_flag_write_only) {
pte_w[1] |=
gmmu_pte_read_disable_true_f();
}
if (!unmapped_pte) {
if (!cacheable)
pte_w[1] |=
gmmu_pte_vol_true_f();
} else {
/* Store cacheable value behind
* gmmu_pte_write_disable_true_f */
if (!cacheable)
pte_w[1] |=
gmmu_pte_write_disable_true_f();
}
gk20a_dbg(gpu_dbg_pte,
"pte=%d iova=0x%llx kind=%d ctag=%d vol=%d [0x%08x, 0x%08x]",
i, *iova,
kind_v, (u32)(*ctag >> ctag_shift), !cacheable,
pte_w[1], pte_w[0]);
if (*ctag)
*ctag += page_size;
} else if (sparse) {
pte_w[0] = gmmu_pte_valid_false_f();
pte_w[1] |= gmmu_pte_vol_true_f();
} else {
gk20a_dbg(gpu_dbg_pte, "pte_cur=%d [0x0,0x0]", i);
}
gk20a_pde_wr32(g, pte, pte_from_index(i) + 0, pte_w[0]);
gk20a_pde_wr32(g, pte, pte_from_index(i) + 1, pte_w[1]);
if (*iova) {
*iova += page_size;
*offset += page_size;
if (*sgl && *offset + page_size > (*sgl)->length) {
u64 new_iova;
*sgl = sg_next(*sgl);
if (*sgl) {
new_iova = sg_phys(*sgl);
gk20a_dbg(gpu_dbg_pte, "chunk address %llx, size %d",
new_iova, (*sgl)->length);
if (new_iova) {
*offset = 0;
*iova = new_iova;
}
}
}
}
return 0;
}
static int update_gmmu_level_locked(struct vm_gk20a *vm,
struct gk20a_mm_entry *pte,
enum gmmu_pgsz_gk20a pgsz_idx,
struct scatterlist **sgl,
u64 *offset,
u64 *iova,
u64 gpu_va, u64 gpu_end,
u8 kind_v, u64 *ctag,
bool cacheable, bool unmapped_pte,
int rw_flag,
bool sparse,
int lvl,
bool priv,
enum gk20a_aperture aperture)
{
struct gk20a *g = gk20a_from_vm(vm);
const struct gk20a_mmu_level *l = &vm->mmu_levels[lvl];
const struct gk20a_mmu_level *next_l = &vm->mmu_levels[lvl+1];
int err = 0;
u32 pde_i;
u64 pde_size = 1ULL << (u64)l->lo_bit[pgsz_idx];
struct gk20a_mm_entry *next_pte = NULL, *prev_pte = NULL;
gk20a_dbg_fn("");
pde_i = (gpu_va & ((1ULL << ((u64)l->hi_bit[pgsz_idx]+1)) - 1ULL))
>> (u64)l->lo_bit[pgsz_idx];
gk20a_dbg(gpu_dbg_pte, "size_idx=%d, l: %d, [%llx,%llx], iova=%llx",
pgsz_idx, lvl, gpu_va, gpu_end-1, *iova);
while (gpu_va < gpu_end) {
u64 next = min((gpu_va + pde_size) & ~(pde_size-1), gpu_end);
/* Allocate next level */
if (next_l->update_entry) {
if (!pte->entries) {
int num_entries =
1 <<
(l->hi_bit[pgsz_idx]
- l->lo_bit[pgsz_idx] + 1);
pte->entries =
vzalloc(sizeof(struct gk20a_mm_entry) *
num_entries);
if (!pte->entries)
return -ENOMEM;
pte->pgsz = pgsz_idx;
pte->num_entries = num_entries;
}
prev_pte = next_pte;
next_pte = pte->entries + pde_i;
if (!next_pte->mem.size) {
err = gk20a_zalloc_gmmu_page_table(vm,
pgsz_idx, next_l, next_pte, prev_pte);
if (err)
return err;
}
}
err = l->update_entry(vm, pte, pde_i, pgsz_idx,
sgl, offset, iova,
kind_v, ctag, cacheable, unmapped_pte,
rw_flag, sparse, priv, aperture);
if (err)
return err;
if (next_l->update_entry) {
/* get cpu access to the ptes */
err = map_gmmu_pages(g, next_pte);
if (err) {
gk20a_err(dev_from_vm(vm),
"couldn't map ptes for update as=%d",
vm_aspace_id(vm));
return err;
}
err = update_gmmu_level_locked(vm, next_pte,
pgsz_idx,
sgl,
offset,
iova,
gpu_va,
next,
kind_v, ctag, cacheable, unmapped_pte,
rw_flag, sparse, lvl+1, priv, aperture);
unmap_gmmu_pages(g, next_pte);
if (err)
return err;
}
pde_i++;
gpu_va = next;
}
gk20a_dbg_fn("done");
return 0;
}
static int update_gmmu_ptes_locked(struct vm_gk20a *vm,
enum gmmu_pgsz_gk20a pgsz_idx,
struct sg_table *sgt,
u64 buffer_offset,
u64 gpu_va, u64 gpu_end,
u8 kind_v, u32 ctag_offset,
bool cacheable, bool unmapped_pte,
int rw_flag,
bool sparse,
bool priv,
enum gk20a_aperture aperture)
{
struct gk20a *g = gk20a_from_vm(vm);
int ctag_granularity = g->ops.fb.compression_page_size(g);
u64 ctag = (u64)ctag_offset * (u64)ctag_granularity;
u64 iova = 0;
u64 space_to_skip = buffer_offset;
u64 map_size = gpu_end - gpu_va;
u32 page_size = vm->gmmu_page_sizes[pgsz_idx];
int err;
struct scatterlist *sgl = NULL;
struct gk20a_page_alloc *alloc = NULL;
struct page_alloc_chunk *chunk = NULL;
u64 length;
/* note: here we need to map kernel to small, since the
* low-level mmu code assumes 0 is small and 1 is big pages */
if (pgsz_idx == gmmu_page_size_kernel)
pgsz_idx = gmmu_page_size_small;
if (space_to_skip & (page_size - 1))
return -EINVAL;
err = map_gmmu_pages(g, &vm->pdb);
if (err) {
gk20a_err(dev_from_vm(vm),
"couldn't map ptes for update as=%d",
vm_aspace_id(vm));
return err;
}
if (aperture == APERTURE_VIDMEM) {
gk20a_dbg(gpu_dbg_map_v, "vidmem map size_idx=%d, gpu_va=[%llx,%llx], alloc=%llx",
pgsz_idx, gpu_va, gpu_end-1, iova);
if (sgt) {
alloc = get_vidmem_page_alloc(sgt->sgl);
list_for_each_entry(chunk, &alloc->alloc_chunks,
list_entry) {
if (space_to_skip &&
space_to_skip > chunk->length) {
space_to_skip -= chunk->length;
} else {
iova = chunk->base + space_to_skip;
length = chunk->length - space_to_skip;
length = min(length, map_size);
space_to_skip = 0;
err = update_gmmu_level_locked(vm,
&vm->pdb, pgsz_idx,
&sgl,
&space_to_skip,
&iova,
gpu_va, gpu_va + length,
kind_v, &ctag,
cacheable, unmapped_pte,
rw_flag, sparse, 0, priv,
aperture);
if (err)
break;
/* need to set explicit zero here */
space_to_skip = 0;
gpu_va += length;
map_size -= length;
if (!map_size)
break;
}
}
} else {
err = update_gmmu_level_locked(vm, &vm->pdb, pgsz_idx,
&sgl,
&space_to_skip,
&iova,
gpu_va, gpu_end,
kind_v, &ctag,
cacheable, unmapped_pte, rw_flag,
sparse, 0, priv,
aperture);
}
} else {
gk20a_dbg(gpu_dbg_pte, "size_idx=%d, iova=%llx, buffer offset %lld, nents %d",
pgsz_idx,
sgt ? g->ops.mm.get_iova_addr(vm->mm->g, sgt->sgl, 0)
: 0ULL,
buffer_offset,
sgt ? sgt->nents : 0);
gk20a_dbg(gpu_dbg_map_v, "size_idx=%d, gpu_va=[%llx,%llx], iova=%llx",
pgsz_idx, gpu_va, gpu_end-1, iova);
if (sgt) {
iova = g->ops.mm.get_iova_addr(vm->mm->g, sgt->sgl, 0);
if (!vm->mm->bypass_smmu && iova) {
iova += space_to_skip;
} else {
sgl = sgt->sgl;
gk20a_dbg(gpu_dbg_pte, "chunk address %llx, size %d",
(u64)sg_phys(sgl),
sgl->length);
while (space_to_skip && sgl &&
space_to_skip + page_size > sgl->length) {
space_to_skip -= sgl->length;
sgl = sg_next(sgl);
gk20a_dbg(gpu_dbg_pte, "chunk address %llx, size %d",
(u64)sg_phys(sgl),
sgl->length);
}
iova = sg_phys(sgl) + space_to_skip;
}
}
err = update_gmmu_level_locked(vm, &vm->pdb, pgsz_idx,
&sgl,
&space_to_skip,
&iova,
gpu_va, gpu_end,
kind_v, &ctag,
cacheable, unmapped_pte, rw_flag,
sparse, 0, priv,
aperture);
}
unmap_gmmu_pages(g, &vm->pdb);
smp_mb();
gk20a_dbg_fn("done");
return err;
}
/* NOTE! mapped_buffers lock must be held */
void gk20a_vm_unmap_locked(struct mapped_buffer_node *mapped_buffer,
struct vm_gk20a_mapping_batch *batch)
{
struct vm_gk20a *vm = mapped_buffer->vm;
struct gk20a *g = vm->mm->g;
if (mapped_buffer->ctag_map_win_addr) {
/* unmap compbits */
g->ops.mm.gmmu_unmap(vm,
mapped_buffer->ctag_map_win_addr,
mapped_buffer->ctag_map_win_size,
0, /* page size 4k */
true, /* va allocated */
gk20a_mem_flag_none,
false, /* not sparse */
batch); /* batch handle */
}
g->ops.mm.gmmu_unmap(vm,
mapped_buffer->addr,
mapped_buffer->size,
mapped_buffer->pgsz_idx,
mapped_buffer->va_allocated,
gk20a_mem_flag_none,
mapped_buffer->va_node ?
mapped_buffer->va_node->sparse : false,
batch);
gk20a_dbg(gpu_dbg_map,
"gv: 0x%04x_%08x pgsz=%-3dKb as=%-2d own_mem_ref=%d",
hi32(mapped_buffer->addr), lo32(mapped_buffer->addr),
vm->gmmu_page_sizes[mapped_buffer->pgsz_idx] >> 10,
vm_aspace_id(vm),
mapped_buffer->own_mem_ref);
gk20a_mm_unpin(dev_from_vm(vm), mapped_buffer->dmabuf,
mapped_buffer->sgt);
/* remove from mapped buffer tree and remove list, free */
rb_erase(&mapped_buffer->node, &vm->mapped_buffers);
if (!list_empty(&mapped_buffer->va_buffers_list))
list_del(&mapped_buffer->va_buffers_list);
/* keep track of mapped buffers */
if (mapped_buffer->user_mapped)
vm->num_user_mapped_buffers--;
if (mapped_buffer->own_mem_ref)
dma_buf_put(mapped_buffer->dmabuf);
kfree(mapped_buffer);
return;
}
void gk20a_vm_unmap(struct vm_gk20a *vm, u64 offset)
{
struct device *d = dev_from_vm(vm);
struct mapped_buffer_node *mapped_buffer;
mutex_lock(&vm->update_gmmu_lock);
mapped_buffer = find_mapped_buffer_locked(&vm->mapped_buffers, offset);
if (!mapped_buffer) {
mutex_unlock(&vm->update_gmmu_lock);
gk20a_err(d, "invalid addr to unmap 0x%llx", offset);
return;
}
kref_put(&mapped_buffer->ref, gk20a_vm_unmap_locked_kref);
mutex_unlock(&vm->update_gmmu_lock);
}
static void gk20a_vm_free_entries(struct vm_gk20a *vm,
struct gk20a_mm_entry *parent,
int level)
{
int i;
if (parent->entries)
for (i = 0; i < parent->num_entries; i++)
gk20a_vm_free_entries(vm, &parent->entries[i], level+1);
if (parent->mem.size)
free_gmmu_pages(vm, parent);
vfree(parent->entries);
parent->entries = NULL;
}
static void gk20a_vm_remove_support_nofree(struct vm_gk20a *vm)
{
struct mapped_buffer_node *mapped_buffer;
struct vm_reserved_va_node *va_node, *va_node_tmp;
struct rb_node *node;
gk20a_dbg_fn("");
/*
* Do this outside of the update_gmmu_lock since unmapping the semaphore
* pool involves unmapping a GMMU mapping which means aquiring the
* update_gmmu_lock.
*/
if (!gk20a_platform_has_syncpoints(gk20a_from_vm(vm)->dev)) {
if (vm->sema_pool) {
gk20a_semaphore_pool_unmap(vm->sema_pool, vm);
gk20a_semaphore_pool_put(vm->sema_pool);
}
}
mutex_lock(&vm->update_gmmu_lock);
/* TBD: add a flag here for the unmap code to recognize teardown
* and short-circuit any otherwise expensive operations. */
node = rb_first(&vm->mapped_buffers);
while (node) {
mapped_buffer =
container_of(node, struct mapped_buffer_node, node);
gk20a_vm_unmap_locked(mapped_buffer, NULL);
node = rb_first(&vm->mapped_buffers);
}
/* destroy remaining reserved memory areas */
list_for_each_entry_safe(va_node, va_node_tmp, &vm->reserved_va_list,
reserved_va_list) {
list_del(&va_node->reserved_va_list);
kfree(va_node);
}
gk20a_deinit_vm(vm);
mutex_unlock(&vm->update_gmmu_lock);
}
void gk20a_vm_remove_support(struct vm_gk20a *vm)
{
gk20a_vm_remove_support_nofree(vm);
/* vm is not used anymore. release it. */
kfree(vm);
}
static void gk20a_vm_remove_support_kref(struct kref *ref)
{
struct vm_gk20a *vm = container_of(ref, struct vm_gk20a, ref);
struct gk20a *g = gk20a_from_vm(vm);
g->ops.mm.vm_remove(vm);
}
void gk20a_vm_get(struct vm_gk20a *vm)
{
kref_get(&vm->ref);
}
void gk20a_vm_put(struct vm_gk20a *vm)
{
kref_put(&vm->ref, gk20a_vm_remove_support_kref);
}
const struct gk20a_mmu_level gk20a_mm_levels_64k[] = {
{.hi_bit = {NV_GMMU_VA_RANGE-1, NV_GMMU_VA_RANGE-1},
.lo_bit = {26, 26},
.update_entry = update_gmmu_pde_locked,
.entry_size = 8},
{.hi_bit = {25, 25},
.lo_bit = {12, 16},
.update_entry = update_gmmu_pte_locked,
.entry_size = 8},
{.update_entry = NULL}
};
const struct gk20a_mmu_level gk20a_mm_levels_128k[] = {
{.hi_bit = {NV_GMMU_VA_RANGE-1, NV_GMMU_VA_RANGE-1},
.lo_bit = {27, 27},
.update_entry = update_gmmu_pde_locked,
.entry_size = 8},
{.hi_bit = {26, 26},
.lo_bit = {12, 17},
.update_entry = update_gmmu_pte_locked,
.entry_size = 8},
{.update_entry = NULL}
};
/*
* Initialize a semaphore pool. Just return successfully if we do not need
* semaphores (i.e when sync-pts are active).
*/
static int gk20a_init_sema_pool(struct vm_gk20a *vm)
{
struct gk20a_semaphore_sea *sema_sea;
struct mm_gk20a *mm = vm->mm;
struct gk20a *g = mm->g;
int err;
/*
* Don't waste the memory on semaphores if we don't need them.
*/
if (gk20a_platform_has_syncpoints(g->dev))
return 0;
if (vm->sema_pool)
return 0;
sema_sea = gk20a_semaphore_sea_create(g);
if (!sema_sea)
return -ENOMEM;
vm->sema_pool = gk20a_semaphore_pool_alloc(sema_sea);
if (!vm->sema_pool) {
gk20a_vm_put(vm);
return -ENOMEM;
}
/*
* Allocate a chunk of GPU VA space for mapping the semaphores. We will
* do a fixed alloc in the kernel VM so that all channels have the same
* RO address range for the semaphores.
*
* !!! TODO: cleanup.
*/
sema_sea->gpu_va = gk20a_alloc_fixed(&vm->vma[gmmu_page_size_kernel],
vm->va_limit -
mm->channel.kernel_size,
512 * PAGE_SIZE);
if (!sema_sea->gpu_va) {
gk20a_free(&vm->vma[gmmu_page_size_small], sema_sea->gpu_va);
gk20a_vm_put(vm);
return -ENOMEM;
}
err = gk20a_semaphore_pool_map(vm->sema_pool, vm);
if (err) {
gk20a_semaphore_pool_unmap(vm->sema_pool, vm);
gk20a_free(&vm->vma[gmmu_page_size_small],
vm->sema_pool->gpu_va);
gk20a_vm_put(vm);
}
return 0;
}
int gk20a_init_vm(struct mm_gk20a *mm,
struct vm_gk20a *vm,
u32 big_page_size,
u64 low_hole,
u64 kernel_reserved,
u64 aperture_size,
bool big_pages,
bool userspace_managed,
char *name)
{
int err, i;
char alloc_name[32];
u64 small_vma_start, small_vma_limit, large_vma_start, large_vma_limit,
kernel_vma_start, kernel_vma_limit;
u32 pde_lo, pde_hi;
struct gk20a *g = mm->g;
/* note: this must match gmmu_pgsz_gk20a enum */
u32 gmmu_page_sizes[gmmu_nr_page_sizes] = { SZ_4K, big_page_size, SZ_4K };
WARN_ON(kernel_reserved + low_hole > aperture_size);
if (kernel_reserved > aperture_size)
return -ENOMEM;
vm->mm = mm;
vm->va_start = low_hole;
vm->va_limit = aperture_size;
vm->big_pages = big_pages;
vm->big_page_size = gmmu_page_sizes[gmmu_page_size_big];
vm->userspace_managed = userspace_managed;
vm->mmu_levels = vm->mm->g->ops.mm.get_mmu_levels(vm->mm->g,
vm->big_page_size);
for (i = 0; i < gmmu_nr_page_sizes; i++)
vm->gmmu_page_sizes[i] = gmmu_page_sizes[i];
gk20a_dbg_info("small page-size (%dKB)",
vm->gmmu_page_sizes[gmmu_page_size_small] >> 10);
gk20a_dbg_info("big page-size (%dKB)",
vm->gmmu_page_sizes[gmmu_page_size_big] >> 10);
gk20a_dbg_info("kernel page-size (%dKB)",
vm->gmmu_page_sizes[gmmu_page_size_kernel] >> 10);
pde_range_from_vaddr_range(vm,
0, vm->va_limit-1,
&pde_lo, &pde_hi);
vm->pdb.entries = vzalloc(sizeof(struct gk20a_mm_entry) *
(pde_hi + 1));
vm->pdb.num_entries = pde_hi + 1;
if (!vm->pdb.entries)
return -ENOMEM;
gk20a_dbg_info("init space for %s va_limit=0x%llx num_pdes=%d",
name, vm->va_limit, pde_hi + 1);
/* allocate the page table directory */
err = gk20a_zalloc_gmmu_page_table(vm, 0, &vm->mmu_levels[0],
&vm->pdb, NULL);
if (err)
goto clean_up_pdes;
/* setup vma limits */
small_vma_start = low_hole;
if (big_pages) {
/* First 16GB of the address space goes towards small
* pages. What ever remains is allocated to large
* pages. */
small_vma_limit = __nv_gmmu_va_small_page_limit();
large_vma_start = small_vma_limit;
large_vma_limit = vm->va_limit - kernel_reserved;
} else {
small_vma_limit = vm->va_limit - kernel_reserved;
large_vma_start = 0;
large_vma_limit = 0;
}
kernel_vma_start = vm->va_limit - kernel_reserved;
kernel_vma_limit = vm->va_limit;
gk20a_dbg_info(
"small_vma=[0x%llx,0x%llx) large_vma=[0x%llx,0x%llx) kernel_vma=[0x%llx,0x%llx)\n",
small_vma_start, small_vma_limit,
large_vma_start, large_vma_limit,
kernel_vma_start, kernel_vma_limit);
/* check that starts do not exceed limits */
WARN_ON(small_vma_start > small_vma_limit);
WARN_ON(large_vma_start > large_vma_limit);
/* kernel_vma must also be non-zero */
WARN_ON(kernel_vma_start >= kernel_vma_limit);
if (small_vma_start > small_vma_limit ||
large_vma_start > large_vma_limit ||
kernel_vma_start >= kernel_vma_limit) {
err = -EINVAL;
goto clean_up_pdes;
}
/*
* Attempt to make a separate VM for fixed allocations.
*/
if (g->separate_fixed_allocs &&
small_vma_start < small_vma_limit) {
if (g->separate_fixed_allocs >= small_vma_limit)
goto clean_up_pdes;
snprintf(alloc_name, sizeof(alloc_name),
"gk20a_%s-fixed", name);
err = __gk20a_buddy_allocator_init(g, &vm->fixed,
vm, alloc_name,
small_vma_start,
g->separate_fixed_allocs,
SZ_4K,
GPU_BALLOC_MAX_ORDER,
GPU_ALLOC_GVA_SPACE);
if (err)
goto clean_up_ptes;
/* Make sure to update the user vma size. */
small_vma_start = g->separate_fixed_allocs;
}
if (small_vma_start < small_vma_limit) {
snprintf(alloc_name, sizeof(alloc_name), "gk20a_%s-%dKB", name,
vm->gmmu_page_sizes[gmmu_page_size_small] >> 10);
err = __gk20a_buddy_allocator_init(
g,
&vm->vma[gmmu_page_size_small],
vm, alloc_name,
small_vma_start,
small_vma_limit - small_vma_start,
SZ_4K,
GPU_BALLOC_MAX_ORDER,
GPU_ALLOC_GVA_SPACE);
if (err)
goto clean_up_ptes;
}
if (large_vma_start < large_vma_limit) {
snprintf(alloc_name, sizeof(alloc_name), "gk20a_%s-%dKB",
name, vm->gmmu_page_sizes[gmmu_page_size_big] >> 10);
err = __gk20a_buddy_allocator_init(
g,
&vm->vma[gmmu_page_size_big],
vm, alloc_name,
large_vma_start,
large_vma_limit - large_vma_start,
big_page_size,
GPU_BALLOC_MAX_ORDER,
GPU_ALLOC_GVA_SPACE);
if (err)
goto clean_up_small_allocator;
}
snprintf(alloc_name, sizeof(alloc_name), "gk20a_%s-%dKB-sys",
name, vm->gmmu_page_sizes[gmmu_page_size_kernel] >> 10);
/*
* kernel reserved VMA is at the end of the aperture
*/
err = __gk20a_buddy_allocator_init(g, &vm->vma[gmmu_page_size_kernel],
vm, alloc_name,
kernel_vma_start,
kernel_vma_limit - kernel_vma_start,
SZ_4K,
GPU_BALLOC_MAX_ORDER,
GPU_ALLOC_GVA_SPACE);
if (err)
goto clean_up_big_allocator;
vm->mapped_buffers = RB_ROOT;
mutex_init(&vm->update_gmmu_lock);
kref_init(&vm->ref);
INIT_LIST_HEAD(&vm->reserved_va_list);
/*
* This is only necessary for channel address spaces. The best way to
* distinguish channel address spaces from other address spaces is by
* size - if the address space is 4GB or less, it's not a channel.
*/
if (vm->va_limit > SZ_4G) {
err = gk20a_init_sema_pool(vm);
if (err)
goto clean_up_big_allocator;
}
return 0;
clean_up_big_allocator:
if (large_vma_start < large_vma_limit)
gk20a_alloc_destroy(&vm->vma[gmmu_page_size_big]);
clean_up_small_allocator:
if (small_vma_start < small_vma_limit)
gk20a_alloc_destroy(&vm->vma[gmmu_page_size_small]);
clean_up_ptes:
free_gmmu_pages(vm, &vm->pdb);
clean_up_pdes:
vfree(vm->pdb.entries);
return err;
}
/* address space interfaces for the gk20a module */
int gk20a_vm_alloc_share(struct gk20a_as_share *as_share, u32 big_page_size,
u32 flags)
{
struct gk20a_as *as = as_share->as;
struct gk20a *g = gk20a_from_as(as);
struct mm_gk20a *mm = &g->mm;
struct vm_gk20a *vm;
char name[32];
int err;
const bool userspace_managed =
(flags & NVGPU_GPU_IOCTL_ALLOC_AS_FLAGS_USERSPACE_MANAGED) != 0;
gk20a_dbg_fn("");
if (big_page_size == 0) {
big_page_size =
gk20a_get_platform(g->dev)->default_big_page_size;
} else {
if (!is_power_of_2(big_page_size))
return -EINVAL;
if (!(big_page_size & g->gpu_characteristics.available_big_page_sizes))
return -EINVAL;
}
vm = kzalloc(sizeof(*vm), GFP_KERNEL);
if (!vm)
return -ENOMEM;
as_share->vm = vm;
vm->as_share = as_share;
vm->enable_ctag = true;
snprintf(name, sizeof(name), "gk20a_as_%d", as_share->id);
err = gk20a_init_vm(mm, vm, big_page_size, big_page_size << 10,
mm->channel.kernel_size,
mm->channel.user_size + mm->channel.kernel_size,
!mm->disable_bigpage, userspace_managed, name);
return err;
}
int gk20a_vm_release_share(struct gk20a_as_share *as_share)
{
struct vm_gk20a *vm = as_share->vm;
gk20a_dbg_fn("");
vm->as_share = NULL;
/* put as reference to vm */
gk20a_vm_put(vm);
as_share->vm = NULL;
return 0;
}
int gk20a_vm_alloc_space(struct gk20a_as_share *as_share,
struct nvgpu_as_alloc_space_args *args)
{
int err = -ENOMEM;
int pgsz_idx = gmmu_page_size_small;
struct gk20a_allocator *vma;
struct vm_gk20a *vm = as_share->vm;
struct gk20a *g = vm->mm->g;
struct vm_reserved_va_node *va_node;
u64 vaddr_start = 0;
int page_sizes = gmmu_nr_page_sizes;
gk20a_dbg_fn("flags=0x%x pgsz=0x%x nr_pages=0x%x o/a=0x%llx",
args->flags, args->page_size, args->pages,
args->o_a.offset);
if (!vm->big_pages)
page_sizes--;
for (; pgsz_idx < page_sizes; pgsz_idx++) {
if (vm->gmmu_page_sizes[pgsz_idx] == args->page_size)
break;
}
if (pgsz_idx >= page_sizes) {
err = -EINVAL;
goto clean_up;
}
va_node = kzalloc(sizeof(*va_node), GFP_KERNEL);
if (!va_node) {
err = -ENOMEM;
goto clean_up;
}
vma = &vm->vma[pgsz_idx];
if (args->flags & NVGPU_AS_ALLOC_SPACE_FLAGS_FIXED_OFFSET) {
if (gk20a_alloc_initialized(&vm->fixed))
vma = &vm->fixed;
vaddr_start = gk20a_alloc_fixed(vma, args->o_a.offset,
(u64)args->pages *
(u64)args->page_size);
} else {
vaddr_start = gk20a_alloc(vma,
(u64)args->pages *
(u64)args->page_size);
}
if (!vaddr_start) {
kfree(va_node);
goto clean_up;
}
va_node->vaddr_start = vaddr_start;
va_node->size = (u64)args->page_size * (u64)args->pages;
va_node->pgsz_idx = pgsz_idx;
INIT_LIST_HEAD(&va_node->va_buffers_list);
INIT_LIST_HEAD(&va_node->reserved_va_list);
mutex_lock(&vm->update_gmmu_lock);
/* mark that we need to use sparse mappings here */
if (args->flags & NVGPU_AS_ALLOC_SPACE_FLAGS_SPARSE) {
u64 map_offset = g->ops.mm.gmmu_map(vm, vaddr_start,
NULL,
0,
va_node->size,
pgsz_idx,
0,
0,
args->flags,
gk20a_mem_flag_none,
false,
true,
false,
NULL,
APERTURE_INVALID);
if (!map_offset) {
mutex_unlock(&vm->update_gmmu_lock);
gk20a_free(vma, vaddr_start);
kfree(va_node);
goto clean_up;
}
va_node->sparse = true;
}
list_add_tail(&va_node->reserved_va_list, &vm->reserved_va_list);
mutex_unlock(&vm->update_gmmu_lock);
args->o_a.offset = vaddr_start;
err = 0;
clean_up:
return err;
}
int gk20a_vm_free_space(struct gk20a_as_share *as_share,
struct nvgpu_as_free_space_args *args)
{
int err = -ENOMEM;
int pgsz_idx;
struct gk20a_allocator *vma;
struct vm_gk20a *vm = as_share->vm;
struct vm_reserved_va_node *va_node;
struct gk20a *g = gk20a_from_vm(vm);
gk20a_dbg_fn("pgsz=0x%x nr_pages=0x%x o/a=0x%llx", args->page_size,
args->pages, args->offset);
/* determine pagesz idx */
pgsz_idx = __nv_gmmu_va_is_big_page_region(vm, args->offset) ?
gmmu_page_size_big : gmmu_page_size_small;
if (gk20a_alloc_initialized(&vm->fixed))
vma = &vm->fixed;
else
vma = &vm->vma[pgsz_idx];
gk20a_free(vma, args->offset);
mutex_lock(&vm->update_gmmu_lock);
va_node = addr_to_reservation(vm, args->offset);
if (va_node) {
struct mapped_buffer_node *buffer, *n;
/* Decrement the ref count on all buffers in this va_node. This
* allows userspace to let the kernel free mappings that are
* only used by this va_node. */
list_for_each_entry_safe(buffer, n,
&va_node->va_buffers_list, va_buffers_list) {
list_del_init(&buffer->va_buffers_list);
kref_put(&buffer->ref, gk20a_vm_unmap_locked_kref);
}
list_del(&va_node->reserved_va_list);
/* if this was a sparse mapping, free the va */
if (va_node->sparse)
g->ops.mm.gmmu_unmap(vm,
va_node->vaddr_start,
va_node->size,
va_node->pgsz_idx,
true,
gk20a_mem_flag_none,
true,
NULL);
kfree(va_node);
}
mutex_unlock(&vm->update_gmmu_lock);
err = 0;
return err;
}
int gk20a_vm_bind_channel(struct gk20a_as_share *as_share,
struct channel_gk20a *ch)
{
int err = 0;
struct vm_gk20a *vm = as_share->vm;
gk20a_dbg_fn("");
ch->vm = vm;
err = channel_gk20a_commit_va(ch);
if (err)
ch->vm = NULL;
return err;
}
int gk20a_dmabuf_alloc_drvdata(struct dma_buf *dmabuf, struct device *dev)
{
struct gk20a_dmabuf_priv *priv;
static DEFINE_MUTEX(priv_lock);
static u64 priv_count = 0;
priv = dma_buf_get_drvdata(dmabuf, dev);
if (likely(priv))
return 0;
mutex_lock(&priv_lock);
priv = dma_buf_get_drvdata(dmabuf, dev);
if (priv)
goto priv_exist_or_err;
priv = kzalloc(sizeof(*priv), GFP_KERNEL);
if (!priv) {
priv = ERR_PTR(-ENOMEM);
goto priv_exist_or_err;
}
mutex_init(&priv->lock);
INIT_LIST_HEAD(&priv->states);
priv->buffer_id = ++priv_count;
dma_buf_set_drvdata(dmabuf, dev, priv, gk20a_mm_delete_priv);
priv_exist_or_err:
mutex_unlock(&priv_lock);
if (IS_ERR(priv))
return -ENOMEM;
return 0;
}
int gk20a_dmabuf_get_state(struct dma_buf *dmabuf, struct device *dev,
u64 offset, struct gk20a_buffer_state **state)
{
int err = 0;
struct gk20a_dmabuf_priv *priv;
struct gk20a_buffer_state *s;
if (WARN_ON(offset >= (u64)dmabuf->size))
return -EINVAL;
err = gk20a_dmabuf_alloc_drvdata(dmabuf, dev);
if (err)
return err;
priv = dma_buf_get_drvdata(dmabuf, dev);
if (WARN_ON(!priv))
return -ENOSYS;
mutex_lock(&priv->lock);
list_for_each_entry(s, &priv->states, list)
if (s->offset == offset)
goto out;
/* State not found, create state. */
s = kzalloc(sizeof(*s), GFP_KERNEL);
if (!s) {
err = -ENOMEM;
goto out;
}
s->offset = offset;
INIT_LIST_HEAD(&s->list);
mutex_init(&s->lock);
list_add_tail(&s->list, &priv->states);
out:
mutex_unlock(&priv->lock);
if (!err)
*state = s;
return err;
}
int gk20a_vm_map_buffer(struct vm_gk20a *vm,
int dmabuf_fd,
u64 *offset_align,
u32 flags, /*NVGPU_AS_MAP_BUFFER_FLAGS_*/
int kind,
u64 buffer_offset,
u64 mapping_size,
struct vm_gk20a_mapping_batch *batch)
{
int err = 0;
struct dma_buf *dmabuf;
u64 ret_va;
gk20a_dbg_fn("");
/* get ref to the mem handle (released on unmap_locked) */
dmabuf = dma_buf_get(dmabuf_fd);
if (IS_ERR(dmabuf)) {
dev_warn(dev_from_vm(vm), "%s: fd %d is not a dmabuf",
__func__, dmabuf_fd);
return PTR_ERR(dmabuf);
}
err = gk20a_dmabuf_alloc_drvdata(dmabuf, dev_from_vm(vm));
if (err) {
dma_buf_put(dmabuf);
return err;
}
ret_va = gk20a_vm_map(vm, dmabuf, *offset_align,
flags, kind, NULL, true,
gk20a_mem_flag_none,
buffer_offset,
mapping_size,
batch);
*offset_align = ret_va;
if (!ret_va) {
dma_buf_put(dmabuf);
err = -EINVAL;
}
return err;
}
int gk20a_vm_unmap_buffer(struct vm_gk20a *vm, u64 offset,
struct vm_gk20a_mapping_batch *batch)
{
gk20a_dbg_fn("");
gk20a_vm_unmap_user(vm, offset, batch);
return 0;
}
void gk20a_deinit_vm(struct vm_gk20a *vm)
{
gk20a_alloc_destroy(&vm->vma[gmmu_page_size_kernel]);
if (gk20a_alloc_initialized(&vm->vma[gmmu_page_size_big]))
gk20a_alloc_destroy(&vm->vma[gmmu_page_size_big]);
if (gk20a_alloc_initialized(&vm->vma[gmmu_page_size_small]))
gk20a_alloc_destroy(&vm->vma[gmmu_page_size_small]);
if (gk20a_alloc_initialized(&vm->fixed))
gk20a_alloc_destroy(&vm->fixed);
gk20a_vm_free_entries(vm, &vm->pdb, 0);
}
int gk20a_alloc_inst_block(struct gk20a *g, struct mem_desc *inst_block)
{
struct device *dev = dev_from_gk20a(g);
int err;
gk20a_dbg_fn("");
err = gk20a_gmmu_alloc(g, ram_in_alloc_size_v(), inst_block);
if (err) {
gk20a_err(dev, "%s: memory allocation failed\n", __func__);
return err;
}
gk20a_dbg_fn("done");
return 0;
}
void gk20a_free_inst_block(struct gk20a *g, struct mem_desc *inst_block)
{
if (inst_block->size)
gk20a_gmmu_free(g, inst_block);
}
u64 gk20a_mm_inst_block_addr(struct gk20a *g, struct mem_desc *inst_block)
{
u64 addr;
if (g->mm.has_physical_mode)
addr = gk20a_mem_phys(inst_block);
else
addr = gk20a_mem_get_base_addr(g, inst_block, 0);
return addr;
}
static int gk20a_init_bar1_vm(struct mm_gk20a *mm)
{
int err;
struct vm_gk20a *vm = &mm->bar1.vm;
struct gk20a *g = gk20a_from_mm(mm);
struct mem_desc *inst_block = &mm->bar1.inst_block;
u32 big_page_size = gk20a_get_platform(g->dev)->default_big_page_size;
mm->bar1.aperture_size = bar1_aperture_size_mb_gk20a() << 20;
gk20a_dbg_info("bar1 vm size = 0x%x", mm->bar1.aperture_size);
gk20a_init_vm(mm, vm, big_page_size, SZ_4K,
mm->bar1.aperture_size - SZ_4K,
mm->bar1.aperture_size, false, false, "bar1");
err = gk20a_alloc_inst_block(g, inst_block);
if (err)
goto clean_up_va;
g->ops.mm.init_inst_block(inst_block, vm, big_page_size);
return 0;
clean_up_va:
gk20a_deinit_vm(vm);
return err;
}
/* pmu vm, share channel_vm interfaces */
static int gk20a_init_system_vm(struct mm_gk20a *mm)
{
int err;
struct vm_gk20a *vm = &mm->pmu.vm;
struct gk20a *g = gk20a_from_mm(mm);
struct mem_desc *inst_block = &mm->pmu.inst_block;
u32 big_page_size = gk20a_get_platform(g->dev)->default_big_page_size;
mm->pmu.aperture_size = GK20A_PMU_VA_SIZE;
gk20a_dbg_info("pmu vm size = 0x%x", mm->pmu.aperture_size);
gk20a_init_vm(mm, vm, big_page_size,
SZ_4K * 16, GK20A_PMU_VA_SIZE,
GK20A_PMU_VA_SIZE * 2, false, false,
"system");
err = gk20a_alloc_inst_block(g, inst_block);
if (err)
goto clean_up_va;
g->ops.mm.init_inst_block(inst_block, vm, big_page_size);
return 0;
clean_up_va:
gk20a_deinit_vm(vm);
return err;
}
static int gk20a_init_hwpm(struct mm_gk20a *mm)
{
int err;
struct vm_gk20a *vm = &mm->pmu.vm;
struct gk20a *g = gk20a_from_mm(mm);
struct mem_desc *inst_block = &mm->hwpm.inst_block;
err = gk20a_alloc_inst_block(g, inst_block);
if (err)
return err;
g->ops.mm.init_inst_block(inst_block, vm, 0);
return 0;
}
static int gk20a_init_cde_vm(struct mm_gk20a *mm)
{
struct vm_gk20a *vm = &mm->cde.vm;
struct gk20a *g = gk20a_from_mm(mm);
u32 big_page_size = gk20a_get_platform(g->dev)->default_big_page_size;
return gk20a_init_vm(mm, vm, big_page_size,
SZ_4K * 16,
NV_MM_DEFAULT_KERNEL_SIZE,
NV_MM_DEFAULT_KERNEL_SIZE + NV_MM_DEFAULT_USER_SIZE,
false, false, "cde");
}
static int gk20a_init_ce_vm(struct mm_gk20a *mm)
{
struct vm_gk20a *vm = &mm->ce.vm;
struct gk20a *g = gk20a_from_mm(mm);
u32 big_page_size = gk20a_get_platform(g->dev)->default_big_page_size;
return gk20a_init_vm(mm, vm, big_page_size,
SZ_4K * 16,
NV_MM_DEFAULT_KERNEL_SIZE,
NV_MM_DEFAULT_KERNEL_SIZE + NV_MM_DEFAULT_USER_SIZE,
false, false, "ce");
}
void gk20a_mm_init_pdb(struct gk20a *g, struct mem_desc *inst_block,
struct vm_gk20a *vm)
{
u64 pdb_addr = gk20a_mem_get_base_addr(g, &vm->pdb.mem, 0);
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);
gk20a_mem_wr32(g, inst_block, ram_in_page_dir_base_lo_w(),
gk20a_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_page_dir_base_lo_f(pdb_addr_lo));
gk20a_mem_wr32(g, inst_block, ram_in_page_dir_base_hi_w(),
ram_in_page_dir_base_hi_f(pdb_addr_hi));
}
void gk20a_init_inst_block(struct mem_desc *inst_block, struct vm_gk20a *vm,
u32 big_page_size)
{
struct gk20a *g = gk20a_from_vm(vm);
gk20a_dbg_info("inst block phys = 0x%llx, kv = 0x%p",
gk20a_mm_inst_block_addr(g, inst_block), inst_block->cpu_va);
g->ops.mm.init_pdb(g, inst_block, vm);
gk20a_mem_wr32(g, inst_block, ram_in_adr_limit_lo_w(),
u64_lo32(vm->va_limit - 1) & ~0xfff);
gk20a_mem_wr32(g, inst_block, ram_in_adr_limit_hi_w(),
ram_in_adr_limit_hi_f(u64_hi32(vm->va_limit - 1)));
if (big_page_size && g->ops.mm.set_big_page_size)
g->ops.mm.set_big_page_size(g, inst_block, big_page_size);
}
int gk20a_mm_fb_flush(struct gk20a *g)
{
struct mm_gk20a *mm = &g->mm;
u32 data;
int ret = 0;
struct nvgpu_timeout timeout;
gk20a_dbg_fn("");
gk20a_busy_noresume(g->dev);
if (!g->power_on) {
pm_runtime_put_noidle(g->dev);
return 0;
}
nvgpu_timeout_init(g, &timeout, 100, NVGPU_TIMER_RETRY_TIMER);
mutex_lock(&mm->l2_op_lock);
/* Make sure all previous writes are committed to the L2. There's no
guarantee that writes are to DRAM. This will be a sysmembar internal
to the L2. */
trace_gk20a_mm_fb_flush(dev_name(g->dev));
gk20a_writel(g, flush_fb_flush_r(),
flush_fb_flush_pending_busy_f());
do {
data = gk20a_readl(g, flush_fb_flush_r());
if (flush_fb_flush_outstanding_v(data) ==
flush_fb_flush_outstanding_true_v() ||
flush_fb_flush_pending_v(data) ==
flush_fb_flush_pending_busy_v()) {
gk20a_dbg_info("fb_flush 0x%x", data);
udelay(5);
} else
break;
} while (!nvgpu_timeout_expired(&timeout));
if (nvgpu_timeout_peek_expired(&timeout)) {
if (g->ops.fb.dump_vpr_wpr_info)
g->ops.fb.dump_vpr_wpr_info(g);
ret = -EBUSY;
}
trace_gk20a_mm_fb_flush_done(dev_name(g->dev));
mutex_unlock(&mm->l2_op_lock);
pm_runtime_put_noidle(g->dev);
return ret;
}
static void gk20a_mm_l2_invalidate_locked(struct gk20a *g)
{
u32 data;
struct nvgpu_timeout timeout;
trace_gk20a_mm_l2_invalidate(dev_name(g->dev));
nvgpu_timeout_init(g, &timeout, 200, NVGPU_TIMER_RETRY_TIMER);
/* Invalidate any clean lines from the L2 so subsequent reads go to
DRAM. Dirty lines are not affected by this operation. */
gk20a_writel(g, flush_l2_system_invalidate_r(),
flush_l2_system_invalidate_pending_busy_f());
do {
data = gk20a_readl(g, flush_l2_system_invalidate_r());
if (flush_l2_system_invalidate_outstanding_v(data) ==
flush_l2_system_invalidate_outstanding_true_v() ||
flush_l2_system_invalidate_pending_v(data) ==
flush_l2_system_invalidate_pending_busy_v()) {
gk20a_dbg_info("l2_system_invalidate 0x%x",
data);
udelay(5);
} else
break;
} while (!nvgpu_timeout_expired(&timeout));
if (nvgpu_timeout_peek_expired(&timeout))
gk20a_warn(dev_from_gk20a(g),
"l2_system_invalidate too many retries");
trace_gk20a_mm_l2_invalidate_done(dev_name(g->dev));
}
void gk20a_mm_l2_invalidate(struct gk20a *g)
{
struct mm_gk20a *mm = &g->mm;
gk20a_busy_noresume(g->dev);
if (g->power_on) {
mutex_lock(&mm->l2_op_lock);
gk20a_mm_l2_invalidate_locked(g);
mutex_unlock(&mm->l2_op_lock);
}
pm_runtime_put_noidle(g->dev);
}
void gk20a_mm_l2_flush(struct gk20a *g, bool invalidate)
{
struct mm_gk20a *mm = &g->mm;
u32 data;
struct nvgpu_timeout timeout;
gk20a_dbg_fn("");
gk20a_busy_noresume(g->dev);
if (!g->power_on)
goto hw_was_off;
nvgpu_timeout_init(g, &timeout, 2000, NVGPU_TIMER_RETRY_TIMER);
mutex_lock(&mm->l2_op_lock);
trace_gk20a_mm_l2_flush(dev_name(g->dev));
/* Flush all dirty lines from the L2 to DRAM. Lines are left in the L2
as clean, so subsequent reads might hit in the L2. */
gk20a_writel(g, flush_l2_flush_dirty_r(),
flush_l2_flush_dirty_pending_busy_f());
do {
data = gk20a_readl(g, flush_l2_flush_dirty_r());
if (flush_l2_flush_dirty_outstanding_v(data) ==
flush_l2_flush_dirty_outstanding_true_v() ||
flush_l2_flush_dirty_pending_v(data) ==
flush_l2_flush_dirty_pending_busy_v()) {
gk20a_dbg_info("l2_flush_dirty 0x%x", data);
udelay(5);
} else
break;
} while (!nvgpu_timeout_expired_msg(&timeout,
"l2_flush_dirty too many retries"));
trace_gk20a_mm_l2_flush_done(dev_name(g->dev));
if (invalidate)
gk20a_mm_l2_invalidate_locked(g);
mutex_unlock(&mm->l2_op_lock);
hw_was_off:
pm_runtime_put_noidle(g->dev);
}
void gk20a_mm_cbc_clean(struct gk20a *g)
{
struct mm_gk20a *mm = &g->mm;
u32 data;
struct nvgpu_timeout timeout;
gk20a_dbg_fn("");
gk20a_busy_noresume(g->dev);
if (!g->power_on)
goto hw_was_off;
nvgpu_timeout_init(g, &timeout, 200, NVGPU_TIMER_RETRY_TIMER);
mutex_lock(&mm->l2_op_lock);
/* Flush all dirty lines from the CBC to L2 */
gk20a_writel(g, flush_l2_clean_comptags_r(),
flush_l2_clean_comptags_pending_busy_f());
do {
data = gk20a_readl(g, flush_l2_clean_comptags_r());
if (flush_l2_clean_comptags_outstanding_v(data) ==
flush_l2_clean_comptags_outstanding_true_v() ||
flush_l2_clean_comptags_pending_v(data) ==
flush_l2_clean_comptags_pending_busy_v()) {
gk20a_dbg_info("l2_clean_comptags 0x%x", data);
udelay(5);
} else
break;
} while (!nvgpu_timeout_expired_msg(&timeout,
"l2_clean_comptags too many retries"));
mutex_unlock(&mm->l2_op_lock);
hw_was_off:
pm_runtime_put_noidle(g->dev);
}
int gk20a_vm_find_buffer(struct vm_gk20a *vm, u64 gpu_va,
struct dma_buf **dmabuf,
u64 *offset)
{
struct mapped_buffer_node *mapped_buffer;
gk20a_dbg_fn("gpu_va=0x%llx", gpu_va);
mutex_lock(&vm->update_gmmu_lock);
mapped_buffer = find_mapped_buffer_range_locked(&vm->mapped_buffers,
gpu_va);
if (!mapped_buffer) {
mutex_unlock(&vm->update_gmmu_lock);
return -EINVAL;
}
*dmabuf = mapped_buffer->dmabuf;
*offset = gpu_va - mapped_buffer->addr;
mutex_unlock(&vm->update_gmmu_lock);
return 0;
}
void gk20a_mm_tlb_invalidate(struct vm_gk20a *vm)
{
struct gk20a *g = gk20a_from_vm(vm);
struct nvgpu_timeout timeout;
u32 addr_lo;
u32 data;
static DEFINE_MUTEX(tlb_lock);
gk20a_dbg_fn("");
/* pagetables are considered sw states which are preserved after
prepare_poweroff. When gk20a deinit releases those pagetables,
common code in vm unmap path calls tlb invalidate that touches
hw. Use the power_on flag to skip tlb invalidation when gpu
power is turned off */
if (!g->power_on)
return;
addr_lo = u64_lo32(gk20a_mem_get_base_addr(g, &vm->pdb.mem, 0) >> 12);
mutex_lock(&tlb_lock);
trace_gk20a_mm_tlb_invalidate(dev_name(g->dev));
nvgpu_timeout_init(g, &timeout, 1000, NVGPU_TIMER_RETRY_TIMER);
do {
data = gk20a_readl(g, fb_mmu_ctrl_r());
if (fb_mmu_ctrl_pri_fifo_space_v(data) != 0)
break;
udelay(2);
} while (!nvgpu_timeout_expired_msg(&timeout,
"wait mmu fifo space"));
if (nvgpu_timeout_peek_expired(&timeout))
goto out;
nvgpu_timeout_init(g, &timeout, 1000, NVGPU_TIMER_RETRY_TIMER);
gk20a_writel(g, fb_mmu_invalidate_pdb_r(),
fb_mmu_invalidate_pdb_addr_f(addr_lo) |
gk20a_aperture_mask(g, &vm->pdb.mem,
fb_mmu_invalidate_pdb_aperture_sys_mem_f(),
fb_mmu_invalidate_pdb_aperture_vid_mem_f()));
gk20a_writel(g, fb_mmu_invalidate_r(),
fb_mmu_invalidate_all_va_true_f() |
fb_mmu_invalidate_trigger_true_f());
do {
data = gk20a_readl(g, fb_mmu_ctrl_r());
if (fb_mmu_ctrl_pri_fifo_empty_v(data) !=
fb_mmu_ctrl_pri_fifo_empty_false_f())
break;
udelay(2);
} while (!nvgpu_timeout_expired_msg(&timeout,
"wait mmu invalidate"));
trace_gk20a_mm_tlb_invalidate_done(dev_name(g->dev));
out:
mutex_unlock(&tlb_lock);
}
int gk20a_mm_suspend(struct gk20a *g)
{
gk20a_dbg_fn("");
cancel_work_sync(&g->mm.vidmem.clear_mem_worker);
g->ops.mm.cbc_clean(g);
g->ops.mm.l2_flush(g, false);
gk20a_dbg_fn("done");
return 0;
}
bool gk20a_mm_mmu_debug_mode_enabled(struct gk20a *g)
{
u32 debug_ctrl = gk20a_readl(g, fb_mmu_debug_ctrl_r());
return fb_mmu_debug_ctrl_debug_v(debug_ctrl) ==
fb_mmu_debug_ctrl_debug_enabled_v();
}
static void gk20a_mm_mmu_set_debug_mode(struct gk20a *g, bool enable)
{
u32 reg_val, debug_ctrl;
reg_val = gk20a_readl(g, fb_mmu_debug_ctrl_r());
if (enable) {
debug_ctrl = fb_mmu_debug_ctrl_debug_enabled_f();
g->mmu_debug_ctrl = true;
} else {
debug_ctrl = fb_mmu_debug_ctrl_debug_disabled_f();
g->mmu_debug_ctrl = false;
}
reg_val = set_field(reg_val,
fb_mmu_debug_ctrl_debug_m(), debug_ctrl);
gk20a_writel(g, fb_mmu_debug_ctrl_r(), reg_val);
}
u32 gk20a_mm_get_physical_addr_bits(struct gk20a *g)
{
return 34;
}
const struct gk20a_mmu_level *gk20a_mm_get_mmu_levels(struct gk20a *g,
u32 big_page_size)
{
return (big_page_size == SZ_64K) ?
gk20a_mm_levels_64k : gk20a_mm_levels_128k;
}
int gk20a_mm_get_buffer_info(struct device *dev, int dmabuf_fd,
u64 *buffer_id, u64 *buffer_len)
{
struct dma_buf *dmabuf;
struct gk20a_dmabuf_priv *priv;
int err = 0;
dmabuf = dma_buf_get(dmabuf_fd);
if (IS_ERR(dmabuf)) {
dev_warn(dev, "%s: fd %d is not a dmabuf", __func__, dmabuf_fd);
return PTR_ERR(dmabuf);
}
err = gk20a_dmabuf_alloc_drvdata(dmabuf, dev);
if (err) {
dev_warn(dev, "Failed to allocate dmabuf drvdata (err = %d)",
err);
goto clean_up;
}
priv = dma_buf_get_drvdata(dmabuf, dev);
if (likely(priv)) {
*buffer_id = priv->buffer_id;
*buffer_len = dmabuf->size;
}
clean_up:
dma_buf_put(dmabuf);
return err;
}
static bool gk20a_mm_is_bar1_supported(struct gk20a *g)
{
return true;
}
#ifdef CONFIG_DEBUG_FS
void gk20a_mm_debugfs_init(struct device *dev)
{
struct gk20a_platform *platform = dev_get_drvdata(dev);
struct dentry *gpu_root = platform->debugfs;
struct gk20a *g = gk20a_get_platform(dev)->g;
debugfs_create_x64("separate_fixed_allocs", 0664, gpu_root,
&g->separate_fixed_allocs);
debugfs_create_bool("force_pramin", 0664, gpu_root,
&g->mm.force_pramin);
}
#endif
void gk20a_init_mm(struct gpu_ops *gops)
{
gops->mm.is_debug_mode_enabled = gk20a_mm_mmu_debug_mode_enabled;
gops->mm.set_debug_mode = gk20a_mm_mmu_set_debug_mode;
gops->mm.gmmu_map = gk20a_locked_gmmu_map;
gops->mm.gmmu_unmap = gk20a_locked_gmmu_unmap;
gops->mm.vm_remove = gk20a_vm_remove_support;
gops->mm.vm_alloc_share = gk20a_vm_alloc_share;
gops->mm.vm_bind_channel = gk20a_vm_bind_channel;
gops->mm.fb_flush = gk20a_mm_fb_flush;
gops->mm.l2_invalidate = gk20a_mm_l2_invalidate;
gops->mm.l2_flush = gk20a_mm_l2_flush;
gops->mm.cbc_clean = gk20a_mm_cbc_clean;
gops->mm.tlb_invalidate = gk20a_mm_tlb_invalidate;
gops->mm.get_iova_addr = gk20a_mm_iova_addr;
gops->mm.get_physical_addr_bits = gk20a_mm_get_physical_addr_bits;
gops->mm.get_mmu_levels = gk20a_mm_get_mmu_levels;
gops->mm.init_pdb = gk20a_mm_init_pdb;
gops->mm.init_mm_setup_hw = gk20a_init_mm_setup_hw;
gops->mm.bar1_bind = gk20a_mm_bar1_bind;
gops->mm.init_inst_block = gk20a_init_inst_block;
gops->mm.is_bar1_supported = gk20a_mm_is_bar1_supported;
}