blob: 6ebda3d65086482fd394979e9afb195c41cf5571 [file] [log] [blame]
// SPDX-License-Identifier: MIT
/*
* Copyright © 2008-2015 Intel Corporation
*/
#include <linux/highmem.h>
#include "i915_drv.h"
#include "i915_reg.h"
#include "i915_scatterlist.h"
#include "i915_pvinfo.h"
#include "i915_vgpu.h"
#include "intel_gt_regs.h"
#include "intel_mchbar_regs.h"
/**
* DOC: fence register handling
*
* Important to avoid confusions: "fences" in the i915 driver are not execution
* fences used to track command completion but hardware detiler objects which
* wrap a given range of the global GTT. Each platform has only a fairly limited
* set of these objects.
*
* Fences are used to detile GTT memory mappings. They're also connected to the
* hardware frontbuffer render tracking and hence interact with frontbuffer
* compression. Furthermore on older platforms fences are required for tiled
* objects used by the display engine. They can also be used by the render
* engine - they're required for blitter commands and are optional for render
* commands. But on gen4+ both display (with the exception of fbc) and rendering
* have their own tiling state bits and don't need fences.
*
* Also note that fences only support X and Y tiling and hence can't be used for
* the fancier new tiling formats like W, Ys and Yf.
*
* Finally note that because fences are such a restricted resource they're
* dynamically associated with objects. Furthermore fence state is committed to
* the hardware lazily to avoid unnecessary stalls on gen2/3. Therefore code must
* explicitly call i915_gem_object_get_fence() to synchronize fencing status
* for cpu access. Also note that some code wants an unfenced view, for those
* cases the fence can be removed forcefully with i915_gem_object_put_fence().
*
* Internally these functions will synchronize with userspace access by removing
* CPU ptes into GTT mmaps (not the GTT ptes themselves) as needed.
*/
#define pipelined 0
static struct drm_i915_private *fence_to_i915(struct i915_fence_reg *fence)
{
return fence->ggtt->vm.i915;
}
static struct intel_uncore *fence_to_uncore(struct i915_fence_reg *fence)
{
return fence->ggtt->vm.gt->uncore;
}
static void i965_write_fence_reg(struct i915_fence_reg *fence)
{
i915_reg_t fence_reg_lo, fence_reg_hi;
int fence_pitch_shift;
u64 val;
if (GRAPHICS_VER(fence_to_i915(fence)) >= 6) {
fence_reg_lo = FENCE_REG_GEN6_LO(fence->id);
fence_reg_hi = FENCE_REG_GEN6_HI(fence->id);
fence_pitch_shift = GEN6_FENCE_PITCH_SHIFT;
} else {
fence_reg_lo = FENCE_REG_965_LO(fence->id);
fence_reg_hi = FENCE_REG_965_HI(fence->id);
fence_pitch_shift = I965_FENCE_PITCH_SHIFT;
}
val = 0;
if (fence->tiling) {
unsigned int stride = fence->stride;
GEM_BUG_ON(!IS_ALIGNED(stride, 128));
val = fence->start + fence->size - I965_FENCE_PAGE;
val <<= 32;
val |= fence->start;
val |= (u64)((stride / 128) - 1) << fence_pitch_shift;
if (fence->tiling == I915_TILING_Y)
val |= BIT(I965_FENCE_TILING_Y_SHIFT);
val |= I965_FENCE_REG_VALID;
}
if (!pipelined) {
struct intel_uncore *uncore = fence_to_uncore(fence);
/*
* To w/a incoherency with non-atomic 64-bit register updates,
* we split the 64-bit update into two 32-bit writes. In order
* for a partial fence not to be evaluated between writes, we
* precede the update with write to turn off the fence register,
* and only enable the fence as the last step.
*
* For extra levels of paranoia, we make sure each step lands
* before applying the next step.
*/
intel_uncore_write_fw(uncore, fence_reg_lo, 0);
intel_uncore_posting_read_fw(uncore, fence_reg_lo);
intel_uncore_write_fw(uncore, fence_reg_hi, upper_32_bits(val));
intel_uncore_write_fw(uncore, fence_reg_lo, lower_32_bits(val));
intel_uncore_posting_read_fw(uncore, fence_reg_lo);
}
}
static void i915_write_fence_reg(struct i915_fence_reg *fence)
{
u32 val;
val = 0;
if (fence->tiling) {
unsigned int stride = fence->stride;
unsigned int tiling = fence->tiling;
bool is_y_tiled = tiling == I915_TILING_Y;
if (is_y_tiled && HAS_128_BYTE_Y_TILING(fence_to_i915(fence)))
stride /= 128;
else
stride /= 512;
GEM_BUG_ON(!is_power_of_2(stride));
val = fence->start;
if (is_y_tiled)
val |= BIT(I830_FENCE_TILING_Y_SHIFT);
val |= I915_FENCE_SIZE_BITS(fence->size);
val |= ilog2(stride) << I830_FENCE_PITCH_SHIFT;
val |= I830_FENCE_REG_VALID;
}
if (!pipelined) {
struct intel_uncore *uncore = fence_to_uncore(fence);
i915_reg_t reg = FENCE_REG(fence->id);
intel_uncore_write_fw(uncore, reg, val);
intel_uncore_posting_read_fw(uncore, reg);
}
}
static void i830_write_fence_reg(struct i915_fence_reg *fence)
{
u32 val;
val = 0;
if (fence->tiling) {
unsigned int stride = fence->stride;
val = fence->start;
if (fence->tiling == I915_TILING_Y)
val |= BIT(I830_FENCE_TILING_Y_SHIFT);
val |= I830_FENCE_SIZE_BITS(fence->size);
val |= ilog2(stride / 128) << I830_FENCE_PITCH_SHIFT;
val |= I830_FENCE_REG_VALID;
}
if (!pipelined) {
struct intel_uncore *uncore = fence_to_uncore(fence);
i915_reg_t reg = FENCE_REG(fence->id);
intel_uncore_write_fw(uncore, reg, val);
intel_uncore_posting_read_fw(uncore, reg);
}
}
static void fence_write(struct i915_fence_reg *fence)
{
struct drm_i915_private *i915 = fence_to_i915(fence);
/*
* Previous access through the fence register is marshalled by
* the mb() inside the fault handlers (i915_gem_release_mmaps)
* and explicitly managed for internal users.
*/
if (GRAPHICS_VER(i915) == 2)
i830_write_fence_reg(fence);
else if (GRAPHICS_VER(i915) == 3)
i915_write_fence_reg(fence);
else
i965_write_fence_reg(fence);
/*
* Access through the fenced region afterwards is
* ordered by the posting reads whilst writing the registers.
*/
}
static bool gpu_uses_fence_registers(struct i915_fence_reg *fence)
{
return GRAPHICS_VER(fence_to_i915(fence)) < 4;
}
static int fence_update(struct i915_fence_reg *fence,
struct i915_vma *vma)
{
struct i915_ggtt *ggtt = fence->ggtt;
struct intel_uncore *uncore = fence_to_uncore(fence);
intel_wakeref_t wakeref;
struct i915_vma *old;
int ret;
fence->tiling = 0;
if (vma) {
GEM_BUG_ON(!i915_gem_object_get_stride(vma->obj) ||
!i915_gem_object_get_tiling(vma->obj));
if (!i915_vma_is_map_and_fenceable(vma))
return -EINVAL;
if (gpu_uses_fence_registers(fence)) {
/* implicit 'unfenced' GPU blits */
ret = i915_vma_sync(vma);
if (ret)
return ret;
}
fence->start = vma->node.start;
fence->size = vma->fence_size;
fence->stride = i915_gem_object_get_stride(vma->obj);
fence->tiling = i915_gem_object_get_tiling(vma->obj);
}
WRITE_ONCE(fence->dirty, false);
old = xchg(&fence->vma, NULL);
if (old) {
/* XXX Ideally we would move the waiting to outside the mutex */
ret = i915_active_wait(&fence->active);
if (ret) {
fence->vma = old;
return ret;
}
i915_vma_flush_writes(old);
/*
* Ensure that all userspace CPU access is completed before
* stealing the fence.
*/
if (old != vma) {
GEM_BUG_ON(old->fence != fence);
i915_vma_revoke_mmap(old);
old->fence = NULL;
}
list_move(&fence->link, &ggtt->fence_list);
}
/*
* We only need to update the register itself if the device is awake.
* If the device is currently powered down, we will defer the write
* to the runtime resume, see intel_ggtt_restore_fences().
*
* This only works for removing the fence register, on acquisition
* the caller must hold the rpm wakeref. The fence register must
* be cleared before we can use any other fences to ensure that
* the new fences do not overlap the elided clears, confusing HW.
*/
wakeref = intel_runtime_pm_get_if_in_use(uncore->rpm);
if (!wakeref) {
GEM_BUG_ON(vma);
return 0;
}
WRITE_ONCE(fence->vma, vma);
fence_write(fence);
if (vma) {
vma->fence = fence;
list_move_tail(&fence->link, &ggtt->fence_list);
}
intel_runtime_pm_put(uncore->rpm, wakeref);
return 0;
}
/**
* i915_vma_revoke_fence - force-remove fence for a VMA
* @vma: vma to map linearly (not through a fence reg)
*
* This function force-removes any fence from the given object, which is useful
* if the kernel wants to do untiled GTT access.
*/
void i915_vma_revoke_fence(struct i915_vma *vma)
{
struct i915_fence_reg *fence = vma->fence;
intel_wakeref_t wakeref;
lockdep_assert_held(&vma->vm->mutex);
if (!fence)
return;
GEM_BUG_ON(fence->vma != vma);
GEM_BUG_ON(!i915_active_is_idle(&fence->active));
GEM_BUG_ON(atomic_read(&fence->pin_count));
fence->tiling = 0;
WRITE_ONCE(fence->vma, NULL);
vma->fence = NULL;
/*
* Skip the write to HW if and only if the device is currently
* suspended.
*
* If the driver does not currently hold a wakeref (if_in_use == 0),
* the device may currently be runtime suspended, or it may be woken
* up before the suspend takes place. If the device is not suspended
* (powered down) and we skip clearing the fence register, the HW is
* left in an undefined state where we may end up with multiple
* registers overlapping.
*/
with_intel_runtime_pm_if_active(fence_to_uncore(fence)->rpm, wakeref)
fence_write(fence);
}
static bool fence_is_active(const struct i915_fence_reg *fence)
{
return fence->vma && i915_vma_is_active(fence->vma);
}
static struct i915_fence_reg *fence_find(struct i915_ggtt *ggtt)
{
struct i915_fence_reg *active = NULL;
struct i915_fence_reg *fence, *fn;
list_for_each_entry_safe(fence, fn, &ggtt->fence_list, link) {
GEM_BUG_ON(fence->vma && fence->vma->fence != fence);
if (fence == active) /* now seen this fence twice */
active = ERR_PTR(-EAGAIN);
/* Prefer idle fences so we do not have to wait on the GPU */
if (active != ERR_PTR(-EAGAIN) && fence_is_active(fence)) {
if (!active)
active = fence;
list_move_tail(&fence->link, &ggtt->fence_list);
continue;
}
if (atomic_read(&fence->pin_count))
continue;
return fence;
}
/* Wait for completion of pending flips which consume fences */
if (intel_has_pending_fb_unpin(ggtt->vm.i915))
return ERR_PTR(-EAGAIN);
return ERR_PTR(-ENOBUFS);
}
int __i915_vma_pin_fence(struct i915_vma *vma)
{
struct i915_ggtt *ggtt = i915_vm_to_ggtt(vma->vm);
struct i915_fence_reg *fence;
struct i915_vma *set = i915_gem_object_is_tiled(vma->obj) ? vma : NULL;
int err;
lockdep_assert_held(&vma->vm->mutex);
/* Just update our place in the LRU if our fence is getting reused. */
if (vma->fence) {
fence = vma->fence;
GEM_BUG_ON(fence->vma != vma);
atomic_inc(&fence->pin_count);
if (!fence->dirty) {
list_move_tail(&fence->link, &ggtt->fence_list);
return 0;
}
} else if (set) {
fence = fence_find(ggtt);
if (IS_ERR(fence))
return PTR_ERR(fence);
GEM_BUG_ON(atomic_read(&fence->pin_count));
atomic_inc(&fence->pin_count);
} else {
return 0;
}
err = fence_update(fence, set);
if (err)
goto out_unpin;
GEM_BUG_ON(fence->vma != set);
GEM_BUG_ON(vma->fence != (set ? fence : NULL));
if (set)
return 0;
out_unpin:
atomic_dec(&fence->pin_count);
return err;
}
/**
* i915_vma_pin_fence - set up fencing for a vma
* @vma: vma to map through a fence reg
*
* When mapping objects through the GTT, userspace wants to be able to write
* to them without having to worry about swizzling if the object is tiled.
* This function walks the fence regs looking for a free one for @obj,
* stealing one if it can't find any.
*
* It then sets up the reg based on the object's properties: address, pitch
* and tiling format.
*
* For an untiled surface, this removes any existing fence.
*
* Returns:
*
* 0 on success, negative error code on failure.
*/
int i915_vma_pin_fence(struct i915_vma *vma)
{
int err;
if (!vma->fence && !i915_gem_object_is_tiled(vma->obj))
return 0;
/*
* Note that we revoke fences on runtime suspend. Therefore the user
* must keep the device awake whilst using the fence.
*/
assert_rpm_wakelock_held(vma->vm->gt->uncore->rpm);
GEM_BUG_ON(!i915_vma_is_ggtt(vma));
err = mutex_lock_interruptible(&vma->vm->mutex);
if (err)
return err;
err = __i915_vma_pin_fence(vma);
mutex_unlock(&vma->vm->mutex);
return err;
}
/**
* i915_reserve_fence - Reserve a fence for vGPU
* @ggtt: Global GTT
*
* This function walks the fence regs looking for a free one and remove
* it from the fence_list. It is used to reserve fence for vGPU to use.
*/
struct i915_fence_reg *i915_reserve_fence(struct i915_ggtt *ggtt)
{
struct i915_fence_reg *fence;
int count;
int ret;
lockdep_assert_held(&ggtt->vm.mutex);
/* Keep at least one fence available for the display engine. */
count = 0;
list_for_each_entry(fence, &ggtt->fence_list, link)
count += !atomic_read(&fence->pin_count);
if (count <= 1)
return ERR_PTR(-ENOSPC);
fence = fence_find(ggtt);
if (IS_ERR(fence))
return fence;
if (fence->vma) {
/* Force-remove fence from VMA */
ret = fence_update(fence, NULL);
if (ret)
return ERR_PTR(ret);
}
list_del(&fence->link);
return fence;
}
/**
* i915_unreserve_fence - Reclaim a reserved fence
* @fence: the fence reg
*
* This function add a reserved fence register from vGPU to the fence_list.
*/
void i915_unreserve_fence(struct i915_fence_reg *fence)
{
struct i915_ggtt *ggtt = fence->ggtt;
lockdep_assert_held(&ggtt->vm.mutex);
list_add(&fence->link, &ggtt->fence_list);
}
/**
* intel_ggtt_restore_fences - restore fence state
* @ggtt: Global GTT
*
* Restore the hw fence state to match the software tracking again, to be called
* after a gpu reset and on resume. Note that on runtime suspend we only cancel
* the fences, to be reacquired by the user later.
*/
void intel_ggtt_restore_fences(struct i915_ggtt *ggtt)
{
int i;
for (i = 0; i < ggtt->num_fences; i++)
fence_write(&ggtt->fence_regs[i]);
}
/**
* DOC: tiling swizzling details
*
* The idea behind tiling is to increase cache hit rates by rearranging
* pixel data so that a group of pixel accesses are in the same cacheline.
* Performance improvement from doing this on the back/depth buffer are on
* the order of 30%.
*
* Intel architectures make this somewhat more complicated, though, by
* adjustments made to addressing of data when the memory is in interleaved
* mode (matched pairs of DIMMS) to improve memory bandwidth.
* For interleaved memory, the CPU sends every sequential 64 bytes
* to an alternate memory channel so it can get the bandwidth from both.
*
* The GPU also rearranges its accesses for increased bandwidth to interleaved
* memory, and it matches what the CPU does for non-tiled. However, when tiled
* it does it a little differently, since one walks addresses not just in the
* X direction but also Y. So, along with alternating channels when bit
* 6 of the address flips, it also alternates when other bits flip -- Bits 9
* (every 512 bytes, an X tile scanline) and 10 (every two X tile scanlines)
* are common to both the 915 and 965-class hardware.
*
* The CPU also sometimes XORs in higher bits as well, to improve
* bandwidth doing strided access like we do so frequently in graphics. This
* is called "Channel XOR Randomization" in the MCH documentation. The result
* is that the CPU is XORing in either bit 11 or bit 17 to bit 6 of its address
* decode.
*
* All of this bit 6 XORing has an effect on our memory management,
* as we need to make sure that the 3d driver can correctly address object
* contents.
*
* If we don't have interleaved memory, all tiling is safe and no swizzling is
* required.
*
* When bit 17 is XORed in, we simply refuse to tile at all. Bit
* 17 is not just a page offset, so as we page an object out and back in,
* individual pages in it will have different bit 17 addresses, resulting in
* each 64 bytes being swapped with its neighbor!
*
* Otherwise, if interleaved, we have to tell the 3d driver what the address
* swizzling it needs to do is, since it's writing with the CPU to the pages
* (bit 6 and potentially bit 11 XORed in), and the GPU is reading from the
* pages (bit 6, 9, and 10 XORed in), resulting in a cumulative bit swizzling
* required by the CPU of XORing in bit 6, 9, 10, and potentially 11, in order
* to match what the GPU expects.
*/
/**
* detect_bit_6_swizzle - detect bit 6 swizzling pattern
* @ggtt: Global GGTT
*
* Detects bit 6 swizzling of address lookup between IGD access and CPU
* access through main memory.
*/
static void detect_bit_6_swizzle(struct i915_ggtt *ggtt)
{
struct intel_uncore *uncore = ggtt->vm.gt->uncore;
struct drm_i915_private *i915 = ggtt->vm.i915;
u32 swizzle_x = I915_BIT_6_SWIZZLE_UNKNOWN;
u32 swizzle_y = I915_BIT_6_SWIZZLE_UNKNOWN;
if (GRAPHICS_VER(i915) >= 8 || IS_VALLEYVIEW(i915)) {
/*
* On BDW+, swizzling is not used. We leave the CPU memory
* controller in charge of optimizing memory accesses without
* the extra address manipulation GPU side.
*
* VLV and CHV don't have GPU swizzling.
*/
swizzle_x = I915_BIT_6_SWIZZLE_NONE;
swizzle_y = I915_BIT_6_SWIZZLE_NONE;
} else if (GRAPHICS_VER(i915) >= 6) {
if (i915->preserve_bios_swizzle) {
if (intel_uncore_read(uncore, DISP_ARB_CTL) &
DISP_TILE_SURFACE_SWIZZLING) {
swizzle_x = I915_BIT_6_SWIZZLE_9_10;
swizzle_y = I915_BIT_6_SWIZZLE_9;
} else {
swizzle_x = I915_BIT_6_SWIZZLE_NONE;
swizzle_y = I915_BIT_6_SWIZZLE_NONE;
}
} else {
u32 dimm_c0, dimm_c1;
dimm_c0 = intel_uncore_read(uncore, MAD_DIMM_C0);
dimm_c1 = intel_uncore_read(uncore, MAD_DIMM_C1);
dimm_c0 &= MAD_DIMM_A_SIZE_MASK | MAD_DIMM_B_SIZE_MASK;
dimm_c1 &= MAD_DIMM_A_SIZE_MASK | MAD_DIMM_B_SIZE_MASK;
/*
* Enable swizzling when the channels are populated
* with identically sized dimms. We don't need to check
* the 3rd channel because no cpu with gpu attached
* ships in that configuration. Also, swizzling only
* makes sense for 2 channels anyway.
*/
if (dimm_c0 == dimm_c1) {
swizzle_x = I915_BIT_6_SWIZZLE_9_10;
swizzle_y = I915_BIT_6_SWIZZLE_9;
} else {
swizzle_x = I915_BIT_6_SWIZZLE_NONE;
swizzle_y = I915_BIT_6_SWIZZLE_NONE;
}
}
} else if (GRAPHICS_VER(i915) == 5) {
/*
* On Ironlake whatever DRAM config, GPU always do
* same swizzling setup.
*/
swizzle_x = I915_BIT_6_SWIZZLE_9_10;
swizzle_y = I915_BIT_6_SWIZZLE_9;
} else if (GRAPHICS_VER(i915) == 2) {
/*
* As far as we know, the 865 doesn't have these bit 6
* swizzling issues.
*/
swizzle_x = I915_BIT_6_SWIZZLE_NONE;
swizzle_y = I915_BIT_6_SWIZZLE_NONE;
} else if (IS_G45(i915) || IS_I965G(i915) || IS_G33(i915)) {
/*
* The 965, G33, and newer, have a very flexible memory
* configuration. It will enable dual-channel mode
* (interleaving) on as much memory as it can, and the GPU
* will additionally sometimes enable different bit 6
* swizzling for tiled objects from the CPU.
*
* Here's what I found on the G965:
* slot fill memory size swizzling
* 0A 0B 1A 1B 1-ch 2-ch
* 512 0 0 0 512 0 O
* 512 0 512 0 16 1008 X
* 512 0 0 512 16 1008 X
* 0 512 0 512 16 1008 X
* 1024 1024 1024 0 2048 1024 O
*
* We could probably detect this based on either the DRB
* matching, which was the case for the swizzling required in
* the table above, or from the 1-ch value being less than
* the minimum size of a rank.
*
* Reports indicate that the swizzling actually
* varies depending upon page placement inside the
* channels, i.e. we see swizzled pages where the
* banks of memory are paired and unswizzled on the
* uneven portion, so leave that as unknown.
*/
if (intel_uncore_read16(uncore, C0DRB3_BW) ==
intel_uncore_read16(uncore, C1DRB3_BW)) {
swizzle_x = I915_BIT_6_SWIZZLE_9_10;
swizzle_y = I915_BIT_6_SWIZZLE_9;
}
} else {
u32 dcc = intel_uncore_read(uncore, DCC);
/*
* On 9xx chipsets, channel interleave by the CPU is
* determined by DCC. For single-channel, neither the CPU
* nor the GPU do swizzling. For dual channel interleaved,
* the GPU's interleave is bit 9 and 10 for X tiled, and bit
* 9 for Y tiled. The CPU's interleave is independent, and
* can be based on either bit 11 (haven't seen this yet) or
* bit 17 (common).
*/
switch (dcc & DCC_ADDRESSING_MODE_MASK) {
case DCC_ADDRESSING_MODE_SINGLE_CHANNEL:
case DCC_ADDRESSING_MODE_DUAL_CHANNEL_ASYMMETRIC:
swizzle_x = I915_BIT_6_SWIZZLE_NONE;
swizzle_y = I915_BIT_6_SWIZZLE_NONE;
break;
case DCC_ADDRESSING_MODE_DUAL_CHANNEL_INTERLEAVED:
if (dcc & DCC_CHANNEL_XOR_DISABLE) {
/*
* This is the base swizzling by the GPU for
* tiled buffers.
*/
swizzle_x = I915_BIT_6_SWIZZLE_9_10;
swizzle_y = I915_BIT_6_SWIZZLE_9;
} else if ((dcc & DCC_CHANNEL_XOR_BIT_17) == 0) {
/* Bit 11 swizzling by the CPU in addition. */
swizzle_x = I915_BIT_6_SWIZZLE_9_10_11;
swizzle_y = I915_BIT_6_SWIZZLE_9_11;
} else {
/* Bit 17 swizzling by the CPU in addition. */
swizzle_x = I915_BIT_6_SWIZZLE_9_10_17;
swizzle_y = I915_BIT_6_SWIZZLE_9_17;
}
break;
}
/* check for L-shaped memory aka modified enhanced addressing */
if (GRAPHICS_VER(i915) == 4 &&
!(intel_uncore_read(uncore, DCC2) & DCC2_MODIFIED_ENHANCED_DISABLE)) {
swizzle_x = I915_BIT_6_SWIZZLE_UNKNOWN;
swizzle_y = I915_BIT_6_SWIZZLE_UNKNOWN;
}
if (dcc == 0xffffffff) {
drm_err(&i915->drm, "Couldn't read from MCHBAR. "
"Disabling tiling.\n");
swizzle_x = I915_BIT_6_SWIZZLE_UNKNOWN;
swizzle_y = I915_BIT_6_SWIZZLE_UNKNOWN;
}
}
if (swizzle_x == I915_BIT_6_SWIZZLE_UNKNOWN ||
swizzle_y == I915_BIT_6_SWIZZLE_UNKNOWN) {
/*
* Userspace likes to explode if it sees unknown swizzling,
* so lie. We will finish the lie when reporting through
* the get-tiling-ioctl by reporting the physical swizzle
* mode as unknown instead.
*
* As we don't strictly know what the swizzling is, it may be
* bit17 dependent, and so we need to also prevent the pages
* from being moved.
*/
i915->quirks |= QUIRK_PIN_SWIZZLED_PAGES;
swizzle_x = I915_BIT_6_SWIZZLE_NONE;
swizzle_y = I915_BIT_6_SWIZZLE_NONE;
}
to_gt(i915)->ggtt->bit_6_swizzle_x = swizzle_x;
to_gt(i915)->ggtt->bit_6_swizzle_y = swizzle_y;
}
/*
* Swap every 64 bytes of this page around, to account for it having a new
* bit 17 of its physical address and therefore being interpreted differently
* by the GPU.
*/
static void swizzle_page(struct page *page)
{
char temp[64];
char *vaddr;
int i;
vaddr = kmap(page);
for (i = 0; i < PAGE_SIZE; i += 128) {
memcpy(temp, &vaddr[i], 64);
memcpy(&vaddr[i], &vaddr[i + 64], 64);
memcpy(&vaddr[i + 64], temp, 64);
}
kunmap(page);
}
/**
* i915_gem_object_do_bit_17_swizzle - fixup bit 17 swizzling
* @obj: i915 GEM buffer object
* @pages: the scattergather list of physical pages
*
* This function fixes up the swizzling in case any page frame number for this
* object has changed in bit 17 since that state has been saved with
* i915_gem_object_save_bit_17_swizzle().
*
* This is called when pinning backing storage again, since the kernel is free
* to move unpinned backing storage around (either by directly moving pages or
* by swapping them out and back in again).
*/
void
i915_gem_object_do_bit_17_swizzle(struct drm_i915_gem_object *obj,
struct sg_table *pages)
{
struct sgt_iter sgt_iter;
struct page *page;
int i;
if (obj->bit_17 == NULL)
return;
i = 0;
for_each_sgt_page(page, sgt_iter, pages) {
char new_bit_17 = page_to_phys(page) >> 17;
if ((new_bit_17 & 0x1) != (test_bit(i, obj->bit_17) != 0)) {
swizzle_page(page);
set_page_dirty(page);
}
i++;
}
}
/**
* i915_gem_object_save_bit_17_swizzle - save bit 17 swizzling
* @obj: i915 GEM buffer object
* @pages: the scattergather list of physical pages
*
* This function saves the bit 17 of each page frame number so that swizzling
* can be fixed up later on with i915_gem_object_do_bit_17_swizzle(). This must
* be called before the backing storage can be unpinned.
*/
void
i915_gem_object_save_bit_17_swizzle(struct drm_i915_gem_object *obj,
struct sg_table *pages)
{
const unsigned int page_count = obj->base.size >> PAGE_SHIFT;
struct sgt_iter sgt_iter;
struct page *page;
int i;
if (obj->bit_17 == NULL) {
obj->bit_17 = bitmap_zalloc(page_count, GFP_KERNEL);
if (obj->bit_17 == NULL) {
DRM_ERROR("Failed to allocate memory for bit 17 "
"record\n");
return;
}
}
i = 0;
for_each_sgt_page(page, sgt_iter, pages) {
if (page_to_phys(page) & (1 << 17))
__set_bit(i, obj->bit_17);
else
__clear_bit(i, obj->bit_17);
i++;
}
}
void intel_ggtt_init_fences(struct i915_ggtt *ggtt)
{
struct drm_i915_private *i915 = ggtt->vm.i915;
struct intel_uncore *uncore = ggtt->vm.gt->uncore;
int num_fences;
int i;
INIT_LIST_HEAD(&ggtt->fence_list);
INIT_LIST_HEAD(&ggtt->userfault_list);
intel_wakeref_auto_init(&ggtt->userfault_wakeref, uncore->rpm);
detect_bit_6_swizzle(ggtt);
if (!i915_ggtt_has_aperture(ggtt))
num_fences = 0;
else if (GRAPHICS_VER(i915) >= 7 &&
!(IS_VALLEYVIEW(i915) || IS_CHERRYVIEW(i915)))
num_fences = 32;
else if (GRAPHICS_VER(i915) >= 4 ||
IS_I945G(i915) || IS_I945GM(i915) ||
IS_G33(i915) || IS_PINEVIEW(i915))
num_fences = 16;
else
num_fences = 8;
if (intel_vgpu_active(i915))
num_fences = intel_uncore_read(uncore,
vgtif_reg(avail_rs.fence_num));
ggtt->fence_regs = kcalloc(num_fences,
sizeof(*ggtt->fence_regs),
GFP_KERNEL);
if (!ggtt->fence_regs)
num_fences = 0;
/* Initialize fence registers to zero */
for (i = 0; i < num_fences; i++) {
struct i915_fence_reg *fence = &ggtt->fence_regs[i];
i915_active_init(&fence->active, NULL, NULL, 0);
fence->ggtt = ggtt;
fence->id = i;
list_add_tail(&fence->link, &ggtt->fence_list);
}
ggtt->num_fences = num_fences;
intel_ggtt_restore_fences(ggtt);
}
void intel_ggtt_fini_fences(struct i915_ggtt *ggtt)
{
int i;
for (i = 0; i < ggtt->num_fences; i++) {
struct i915_fence_reg *fence = &ggtt->fence_regs[i];
i915_active_fini(&fence->active);
}
kfree(ggtt->fence_regs);
}
void intel_gt_init_swizzling(struct intel_gt *gt)
{
struct drm_i915_private *i915 = gt->i915;
struct intel_uncore *uncore = gt->uncore;
if (GRAPHICS_VER(i915) < 5 ||
to_gt(i915)->ggtt->bit_6_swizzle_x == I915_BIT_6_SWIZZLE_NONE)
return;
intel_uncore_rmw(uncore, DISP_ARB_CTL, 0, DISP_TILE_SURFACE_SWIZZLING);
if (GRAPHICS_VER(i915) == 5)
return;
intel_uncore_rmw(uncore, TILECTL, 0, TILECTL_SWZCTL);
if (GRAPHICS_VER(i915) == 6)
intel_uncore_write(uncore,
ARB_MODE,
_MASKED_BIT_ENABLE(ARB_MODE_SWIZZLE_SNB));
else if (GRAPHICS_VER(i915) == 7)
intel_uncore_write(uncore,
ARB_MODE,
_MASKED_BIT_ENABLE(ARB_MODE_SWIZZLE_IVB));
else if (GRAPHICS_VER(i915) == 8)
intel_uncore_write(uncore,
GAMTARBMODE,
_MASKED_BIT_ENABLE(ARB_MODE_SWIZZLE_BDW));
else
MISSING_CASE(GRAPHICS_VER(i915));
}