linux_dsm_epyc7002/drivers/gpu/drm/i915/i915_gem_gtt.h
Ben Widawsky 06fda602db drm/i915: Create page table allocators
As we move toward dynamic page table allocation, it becomes much easier
to manage our data structures if break do things less coarsely by
breaking up all of our actions into individual tasks.  This makes the
code easier to write, read, and verify.

Aside from the dissection of the allocation functions, the patch
statically allocates the page table structures without a page directory.
This remains the same for all platforms,

The patch itself should not have much functional difference. The primary
noticeable difference is the fact that page tables are no longer
allocated, but rather statically declared as part of the page directory.
This has non-zero overhead, but things gain additional complexity as a
result.

This patch exists for a few reasons:
1. Splitting out the functions allows easily combining GEN6 and GEN8
code. Page tables have no difference based on GEN8. As we'll see in a
future patch when we add the DMA mappings to the allocations, it
requires only one small change to make work, and error handling should
just fall into place.

2. Unless we always want to allocate all page tables under a given PDE,
we'll have to eventually break this up into an array of pointers (or
pointer to pointer).

3. Having the discrete functions is easier to review, and understand.
All allocations and frees now take place in just a couple of locations.
Reviewing, and catching leaks should be easy.

4. Less important: the GFP flags are confined to one location, which
makes playing around with such things trivial.

v2: Updated commit message to explain why this patch exists

v3: For lrc, s/pdp.page_directory[i].daddr/pdp.page_directory[i]->daddr/

v4: Renamed free_pt/pd_single functions to unmap_and_free_pt/pd (Daniel)

v5: Added additional safety checks in gen8 clear/free/unmap.

v6: Use WARN_ON and return -EINVAL in alloc_pt_range (Mika).

v7: Make err_out loop symmetrical to the way we allocate in
alloc_pt_range. Also s/page_tables/page_table and correct commit
message (Mika)

Cc: Mika Kuoppala <mika.kuoppala@linux.intel.com>
Signed-off-by: Ben Widawsky <ben@bwidawsk.net>
Signed-off-by: Michel Thierry <michel.thierry@intel.com> (v3+)
Reviewed-by: Mika Kuoppala <mika.kuoppala@intel.com>
Signed-off-by: Daniel Vetter <daniel.vetter@ffwll.ch>
2015-02-25 16:53:43 +01:00

336 lines
11 KiB
C

/*
* Copyright © 2014 Intel Corporation
*
* Permission is hereby granted, free of charge, to any person obtaining a
* copy of this software and associated documentation files (the "Software"),
* to deal in the Software without restriction, including without limitation
* the rights to use, copy, modify, merge, publish, distribute, sublicense,
* and/or sell copies of the Software, and to permit persons to whom the
* Software is furnished to do so, subject to the following conditions:
*
* The above copyright notice and this permission notice (including the next
* paragraph) shall be included in all copies or substantial portions of the
* Software.
*
* THE SOFTWARE IS PROVIDED "AS IS", WITHOUT WARRANTY OF ANY KIND, EXPRESS OR
* IMPLIED, INCLUDING BUT NOT LIMITED TO THE WARRANTIES OF MERCHANTABILITY,
* FITNESS FOR A PARTICULAR PURPOSE AND NONINFRINGEMENT. IN NO EVENT SHALL
* THE AUTHORS OR COPYRIGHT HOLDERS BE LIABLE FOR ANY CLAIM, DAMAGES OR OTHER
* LIABILITY, WHETHER IN AN ACTION OF CONTRACT, TORT OR OTHERWISE, ARISING
* FROM, OUT OF OR IN CONNECTION WITH THE SOFTWARE OR THE USE OR OTHER DEALINGS
* IN THE SOFTWARE.
*
* Please try to maintain the following order within this file unless it makes
* sense to do otherwise. From top to bottom:
* 1. typedefs
* 2. #defines, and macros
* 3. structure definitions
* 4. function prototypes
*
* Within each section, please try to order by generation in ascending order,
* from top to bottom (ie. gen6 on the top, gen8 on the bottom).
*/
#ifndef __I915_GEM_GTT_H__
#define __I915_GEM_GTT_H__
struct drm_i915_file_private;
typedef uint32_t gen6_gtt_pte_t;
typedef uint64_t gen8_gtt_pte_t;
typedef gen8_gtt_pte_t gen8_ppgtt_pde_t;
#define gtt_total_entries(gtt) ((gtt).base.total >> PAGE_SHIFT)
#define I915_PPGTT_PT_ENTRIES (PAGE_SIZE / sizeof(gen6_gtt_pte_t))
/* gen6-hsw has bit 11-4 for physical addr bit 39-32 */
#define GEN6_GTT_ADDR_ENCODE(addr) ((addr) | (((addr) >> 28) & 0xff0))
#define GEN6_PTE_ADDR_ENCODE(addr) GEN6_GTT_ADDR_ENCODE(addr)
#define GEN6_PDE_ADDR_ENCODE(addr) GEN6_GTT_ADDR_ENCODE(addr)
#define GEN6_PTE_CACHE_LLC (2 << 1)
#define GEN6_PTE_UNCACHED (1 << 1)
#define GEN6_PTE_VALID (1 << 0)
#define GEN6_PPGTT_PD_ENTRIES 512
#define GEN6_PD_SIZE (GEN6_PPGTT_PD_ENTRIES * PAGE_SIZE)
#define GEN6_PD_ALIGN (PAGE_SIZE * 16)
#define GEN6_PDE_VALID (1 << 0)
#define GEN7_PTE_CACHE_L3_LLC (3 << 1)
#define BYT_PTE_SNOOPED_BY_CPU_CACHES (1 << 2)
#define BYT_PTE_WRITEABLE (1 << 1)
/* Cacheability Control is a 4-bit value. The low three bits are stored in bits
* 3:1 of the PTE, while the fourth bit is stored in bit 11 of the PTE.
*/
#define HSW_CACHEABILITY_CONTROL(bits) ((((bits) & 0x7) << 1) | \
(((bits) & 0x8) << (11 - 3)))
#define HSW_WB_LLC_AGE3 HSW_CACHEABILITY_CONTROL(0x2)
#define HSW_WB_LLC_AGE0 HSW_CACHEABILITY_CONTROL(0x3)
#define HSW_WB_ELLC_LLC_AGE3 HSW_CACHEABILITY_CONTROL(0x8)
#define HSW_WB_ELLC_LLC_AGE0 HSW_CACHEABILITY_CONTROL(0xb)
#define HSW_WT_ELLC_LLC_AGE3 HSW_CACHEABILITY_CONTROL(0x7)
#define HSW_WT_ELLC_LLC_AGE0 HSW_CACHEABILITY_CONTROL(0x6)
#define HSW_PTE_UNCACHED (0)
#define HSW_GTT_ADDR_ENCODE(addr) ((addr) | (((addr) >> 28) & 0x7f0))
#define HSW_PTE_ADDR_ENCODE(addr) HSW_GTT_ADDR_ENCODE(addr)
/* GEN8 legacy style address is defined as a 3 level page table:
* 31:30 | 29:21 | 20:12 | 11:0
* PDPE | PDE | PTE | offset
* The difference as compared to normal x86 3 level page table is the PDPEs are
* programmed via register.
*/
#define GEN8_PDPE_SHIFT 30
#define GEN8_PDPE_MASK 0x3
#define GEN8_PDE_SHIFT 21
#define GEN8_PDE_MASK 0x1ff
#define GEN8_PTE_SHIFT 12
#define GEN8_PTE_MASK 0x1ff
#define GEN8_LEGACY_PDPES 4
#define GEN8_PTES_PER_PAGE (PAGE_SIZE / sizeof(gen8_gtt_pte_t))
#define GEN8_PDES_PER_PAGE (PAGE_SIZE / sizeof(gen8_ppgtt_pde_t))
#define PPAT_UNCACHED_INDEX (_PAGE_PWT | _PAGE_PCD)
#define PPAT_CACHED_PDE_INDEX 0 /* WB LLC */
#define PPAT_CACHED_INDEX _PAGE_PAT /* WB LLCeLLC */
#define PPAT_DISPLAY_ELLC_INDEX _PAGE_PCD /* WT eLLC */
#define CHV_PPAT_SNOOP (1<<6)
#define GEN8_PPAT_AGE(x) (x<<4)
#define GEN8_PPAT_LLCeLLC (3<<2)
#define GEN8_PPAT_LLCELLC (2<<2)
#define GEN8_PPAT_LLC (1<<2)
#define GEN8_PPAT_WB (3<<0)
#define GEN8_PPAT_WT (2<<0)
#define GEN8_PPAT_WC (1<<0)
#define GEN8_PPAT_UC (0<<0)
#define GEN8_PPAT_ELLC_OVERRIDE (0<<2)
#define GEN8_PPAT(i, x) ((uint64_t) (x) << ((i) * 8))
enum i915_ggtt_view_type {
I915_GGTT_VIEW_NORMAL = 0,
};
struct i915_ggtt_view {
enum i915_ggtt_view_type type;
struct sg_table *pages;
};
extern const struct i915_ggtt_view i915_ggtt_view_normal;
enum i915_cache_level;
/**
* A VMA represents a GEM BO that is bound into an address space. Therefore, a
* VMA's presence cannot be guaranteed before binding, or after unbinding the
* object into/from the address space.
*
* To make things as simple as possible (ie. no refcounting), a VMA's lifetime
* will always be <= an objects lifetime. So object refcounting should cover us.
*/
struct i915_vma {
struct drm_mm_node node;
struct drm_i915_gem_object *obj;
struct i915_address_space *vm;
/** Flags and address space this VMA is bound to */
#define GLOBAL_BIND (1<<0)
#define LOCAL_BIND (1<<1)
#define PTE_READ_ONLY (1<<2)
unsigned int bound : 4;
/**
* Support different GGTT views into the same object.
* This means there can be multiple VMA mappings per object and per VM.
* i915_ggtt_view_type is used to distinguish between those entries.
* The default one of zero (I915_GGTT_VIEW_NORMAL) is default and also
* assumed in GEM functions which take no ggtt view parameter.
*/
struct i915_ggtt_view ggtt_view;
/** This object's place on the active/inactive lists */
struct list_head mm_list;
struct list_head vma_link; /* Link in the object's VMA list */
/** This vma's place in the batchbuffer or on the eviction list */
struct list_head exec_list;
/**
* Used for performing relocations during execbuffer insertion.
*/
struct hlist_node exec_node;
unsigned long exec_handle;
struct drm_i915_gem_exec_object2 *exec_entry;
/**
* How many users have pinned this object in GTT space. The following
* users can each hold at most one reference: pwrite/pread, execbuffer
* (objects are not allowed multiple times for the same batchbuffer),
* and the framebuffer code. When switching/pageflipping, the
* framebuffer code has at most two buffers pinned per crtc.
*
* In the worst case this is 1 + 1 + 1 + 2*2 = 7. That would fit into 3
* bits with absolutely no headroom. So use 4 bits. */
unsigned int pin_count:4;
#define DRM_I915_GEM_OBJECT_MAX_PIN_COUNT 0xf
/** Unmap an object from an address space. This usually consists of
* setting the valid PTE entries to a reserved scratch page. */
void (*unbind_vma)(struct i915_vma *vma);
/* Map an object into an address space with the given cache flags. */
void (*bind_vma)(struct i915_vma *vma,
enum i915_cache_level cache_level,
u32 flags);
};
struct i915_page_table_entry {
struct page *page;
dma_addr_t daddr;
};
struct i915_page_directory_entry {
struct page *page; /* NULL for GEN6-GEN7 */
union {
uint32_t pd_offset;
dma_addr_t daddr;
};
struct i915_page_table_entry *page_table[GEN6_PPGTT_PD_ENTRIES]; /* PDEs */
};
struct i915_page_directory_pointer_entry {
/* struct page *page; */
struct i915_page_directory_entry *page_directory[GEN8_LEGACY_PDPES];
};
struct i915_address_space {
struct drm_mm mm;
struct drm_device *dev;
struct list_head global_link;
unsigned long start; /* Start offset always 0 for dri2 */
size_t total; /* size addr space maps (ex. 2GB for ggtt) */
struct {
dma_addr_t addr;
struct page *page;
} scratch;
/**
* List of objects currently involved in rendering.
*
* Includes buffers having the contents of their GPU caches
* flushed, not necessarily primitives. last_read_req
* represents when the rendering involved will be completed.
*
* A reference is held on the buffer while on this list.
*/
struct list_head active_list;
/**
* LRU list of objects which are not in the ringbuffer and
* are ready to unbind, but are still in the GTT.
*
* last_read_req is NULL while an object is in this list.
*
* A reference is not held on the buffer while on this list,
* as merely being GTT-bound shouldn't prevent its being
* freed, and we'll pull it off the list in the free path.
*/
struct list_head inactive_list;
/* FIXME: Need a more generic return type */
gen6_gtt_pte_t (*pte_encode)(dma_addr_t addr,
enum i915_cache_level level,
bool valid, u32 flags); /* Create a valid PTE */
void (*clear_range)(struct i915_address_space *vm,
uint64_t start,
uint64_t length,
bool use_scratch);
void (*insert_entries)(struct i915_address_space *vm,
struct sg_table *st,
uint64_t start,
enum i915_cache_level cache_level, u32 flags);
void (*cleanup)(struct i915_address_space *vm);
};
/* The Graphics Translation Table is the way in which GEN hardware translates a
* Graphics Virtual Address into a Physical Address. In addition to the normal
* collateral associated with any va->pa translations GEN hardware also has a
* portion of the GTT which can be mapped by the CPU and remain both coherent
* and correct (in cases like swizzling). That region is referred to as GMADR in
* the spec.
*/
struct i915_gtt {
struct i915_address_space base;
size_t stolen_size; /* Total size of stolen memory */
unsigned long mappable_end; /* End offset that we can CPU map */
struct io_mapping *mappable; /* Mapping to our CPU mappable region */
phys_addr_t mappable_base; /* PA of our GMADR */
/** "Graphics Stolen Memory" holds the global PTEs */
void __iomem *gsm;
bool do_idle_maps;
int mtrr;
/* global gtt ops */
int (*gtt_probe)(struct drm_device *dev, size_t *gtt_total,
size_t *stolen, phys_addr_t *mappable_base,
unsigned long *mappable_end);
};
struct i915_hw_ppgtt {
struct i915_address_space base;
struct kref ref;
struct drm_mm_node node;
unsigned num_pd_entries;
unsigned num_pd_pages; /* gen8+ */
union {
struct i915_page_directory_pointer_entry pdp;
struct i915_page_directory_entry pd;
};
struct drm_i915_file_private *file_priv;
int (*enable)(struct i915_hw_ppgtt *ppgtt);
int (*switch_mm)(struct i915_hw_ppgtt *ppgtt,
struct intel_engine_cs *ring);
void (*debug_dump)(struct i915_hw_ppgtt *ppgtt, struct seq_file *m);
};
int i915_gem_gtt_init(struct drm_device *dev);
void i915_gem_init_global_gtt(struct drm_device *dev);
void i915_global_gtt_cleanup(struct drm_device *dev);
int i915_ppgtt_init(struct drm_device *dev, struct i915_hw_ppgtt *ppgtt);
int i915_ppgtt_init_hw(struct drm_device *dev);
void i915_ppgtt_release(struct kref *kref);
struct i915_hw_ppgtt *i915_ppgtt_create(struct drm_device *dev,
struct drm_i915_file_private *fpriv);
static inline void i915_ppgtt_get(struct i915_hw_ppgtt *ppgtt)
{
if (ppgtt)
kref_get(&ppgtt->ref);
}
static inline void i915_ppgtt_put(struct i915_hw_ppgtt *ppgtt)
{
if (ppgtt)
kref_put(&ppgtt->ref, i915_ppgtt_release);
}
void i915_check_and_clear_faults(struct drm_device *dev);
void i915_gem_suspend_gtt_mappings(struct drm_device *dev);
void i915_gem_restore_gtt_mappings(struct drm_device *dev);
int __must_check i915_gem_gtt_prepare_object(struct drm_i915_gem_object *obj);
void i915_gem_gtt_finish_object(struct drm_i915_gem_object *obj);
#endif