linux/drivers/gpu/drm/i915/intel_uncore.c

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/*
* Copyright © 2013 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.
*/
#include "i915_drv.h"
#include "intel_drv.h"
#define FORCEWAKE_ACK_TIMEOUT_MS 2
#define __raw_i915_read8(dev_priv__, reg__) readb((dev_priv__)->regs + (reg__))
#define __raw_i915_write8(dev_priv__, reg__, val__) writeb(val__, (dev_priv__)->regs + (reg__))
#define __raw_i915_read16(dev_priv__, reg__) readw((dev_priv__)->regs + (reg__))
#define __raw_i915_write16(dev_priv__, reg__, val__) writew(val__, (dev_priv__)->regs + (reg__))
#define __raw_i915_read32(dev_priv__, reg__) readl((dev_priv__)->regs + (reg__))
#define __raw_i915_write32(dev_priv__, reg__, val__) writel(val__, (dev_priv__)->regs + (reg__))
#define __raw_i915_read64(dev_priv__, reg__) readq((dev_priv__)->regs + (reg__))
#define __raw_i915_write64(dev_priv__, reg__, val__) writeq(val__, (dev_priv__)->regs + (reg__))
#define __raw_posting_read(dev_priv__, reg__) (void)__raw_i915_read32(dev_priv__, reg__)
static void
assert_device_not_suspended(struct drm_i915_private *dev_priv)
{
WARN(HAS_RUNTIME_PM(dev_priv->dev) && dev_priv->pm.suspended,
"Device suspended\n");
}
static void __gen6_gt_wait_for_thread_c0(struct drm_i915_private *dev_priv)
{
u32 gt_thread_status_mask;
if (IS_HASWELL(dev_priv->dev))
gt_thread_status_mask = GEN6_GT_THREAD_STATUS_CORE_MASK_HSW;
else
gt_thread_status_mask = GEN6_GT_THREAD_STATUS_CORE_MASK;
/* w/a for a sporadic read returning 0 by waiting for the GT
* thread to wake up.
*/
if (wait_for_atomic_us((__raw_i915_read32(dev_priv, GEN6_GT_THREAD_STATUS_REG) & gt_thread_status_mask) == 0, 500))
DRM_ERROR("GT thread status wait timed out\n");
}
static void __gen6_gt_force_wake_reset(struct drm_i915_private *dev_priv)
{
__raw_i915_write32(dev_priv, FORCEWAKE, 0);
/* something from same cacheline, but !FORCEWAKE */
__raw_posting_read(dev_priv, ECOBUS);
}
static void __gen6_gt_force_wake_get(struct drm_i915_private *dev_priv,
int fw_engine)
{
if (wait_for_atomic((__raw_i915_read32(dev_priv, FORCEWAKE_ACK) & 1) == 0,
FORCEWAKE_ACK_TIMEOUT_MS))
DRM_ERROR("Timed out waiting for forcewake old ack to clear.\n");
__raw_i915_write32(dev_priv, FORCEWAKE, 1);
/* something from same cacheline, but !FORCEWAKE */
__raw_posting_read(dev_priv, ECOBUS);
if (wait_for_atomic((__raw_i915_read32(dev_priv, FORCEWAKE_ACK) & 1),
FORCEWAKE_ACK_TIMEOUT_MS))
DRM_ERROR("Timed out waiting for forcewake to ack request.\n");
/* WaRsForcewakeWaitTC0:snb */
__gen6_gt_wait_for_thread_c0(dev_priv);
}
static void __gen6_gt_force_wake_mt_reset(struct drm_i915_private *dev_priv)
{
__raw_i915_write32(dev_priv, FORCEWAKE_MT, _MASKED_BIT_DISABLE(0xffff));
/* something from same cacheline, but !FORCEWAKE_MT */
__raw_posting_read(dev_priv, ECOBUS);
}
static void __gen6_gt_force_wake_mt_get(struct drm_i915_private *dev_priv,
int fw_engine)
{
u32 forcewake_ack;
drm/i915/bdw: Handle forcewake for writes on gen8 GEN8 removes the GT FIFO which we've all come to know and love. Instead it offers a wider range of optimized registers which always keep a shadowed copy, and are fed to the GPU when it wakes. How this is implemented in hardware is still somewhat of a mystery. As far as I can tell, the basic design is as follows: If the register is not optimized, you must use the old forcewake mechanism to bring the GT out of sleep. [1] If register is in the optimized list the write will signal that the GT should begin to come out of whatever sleep state it is in. While the GT is coming out of sleep, the requested write will be stored in an intermediate shadow register. Do to the fact that the implementation details are not clear, I see several risks: 1. Order is not preserved as it is with GT FIFO. If we issue multiple writes to optimized registers, where order matters, we may need to serialize it with forcewake. 2. The optimized registers have only 1 shadowed slot, meaning if we issue multiple writes to the same register, and those values need to reach the GPU in order, forcewake will be required. [1] We could implement a SW queue the way the GT FIFO used to work if desired. NOTE: Compile tested only until we get real silicon. v2: - Use a default case to make future platforms also work. - Get rid of IS_BROADWELL since that's not yet defined, but we want to MMIO as soon as possible. v3: Apply suggestions from Mika's review: - s/optimized/shadowed/ - invert the logic of the helper so that it does what it says (the code itself was correct, just confusing to read). v4: - Squash in lost break. Signed-off-by: Ben Widawsky <ben@bwidawsk.net> (v1) Reviewed-by: Mika Kuoppala <mika.kuoppala@intel.com> Signed-off-by: Daniel Vetter <daniel.vetter@ffwll.ch>
2013-11-03 04:07:00 +00:00
if (IS_HASWELL(dev_priv->dev) || IS_GEN8(dev_priv->dev))
forcewake_ack = FORCEWAKE_ACK_HSW;
else
forcewake_ack = FORCEWAKE_MT_ACK;
if (wait_for_atomic((__raw_i915_read32(dev_priv, forcewake_ack) & FORCEWAKE_KERNEL) == 0,
FORCEWAKE_ACK_TIMEOUT_MS))
DRM_ERROR("Timed out waiting for forcewake old ack to clear.\n");
__raw_i915_write32(dev_priv, FORCEWAKE_MT,
_MASKED_BIT_ENABLE(FORCEWAKE_KERNEL));
/* something from same cacheline, but !FORCEWAKE_MT */
__raw_posting_read(dev_priv, ECOBUS);
if (wait_for_atomic((__raw_i915_read32(dev_priv, forcewake_ack) & FORCEWAKE_KERNEL),
FORCEWAKE_ACK_TIMEOUT_MS))
DRM_ERROR("Timed out waiting for forcewake to ack request.\n");
/* WaRsForcewakeWaitTC0:ivb,hsw */
if (INTEL_INFO(dev_priv->dev)->gen < 8)
__gen6_gt_wait_for_thread_c0(dev_priv);
}
static void gen6_gt_check_fifodbg(struct drm_i915_private *dev_priv)
{
u32 gtfifodbg;
gtfifodbg = __raw_i915_read32(dev_priv, GTFIFODBG);
if (WARN(gtfifodbg, "GT wake FIFO error 0x%x\n", gtfifodbg))
__raw_i915_write32(dev_priv, GTFIFODBG, gtfifodbg);
}
static void __gen6_gt_force_wake_put(struct drm_i915_private *dev_priv,
int fw_engine)
{
__raw_i915_write32(dev_priv, FORCEWAKE, 0);
/* something from same cacheline, but !FORCEWAKE */
__raw_posting_read(dev_priv, ECOBUS);
gen6_gt_check_fifodbg(dev_priv);
}
static void __gen6_gt_force_wake_mt_put(struct drm_i915_private *dev_priv,
int fw_engine)
{
__raw_i915_write32(dev_priv, FORCEWAKE_MT,
_MASKED_BIT_DISABLE(FORCEWAKE_KERNEL));
/* something from same cacheline, but !FORCEWAKE_MT */
__raw_posting_read(dev_priv, ECOBUS);
gen6_gt_check_fifodbg(dev_priv);
}
static int __gen6_gt_wait_for_fifo(struct drm_i915_private *dev_priv)
{
int ret = 0;
/* On VLV, FIFO will be shared by both SW and HW.
* So, we need to read the FREE_ENTRIES everytime */
if (IS_VALLEYVIEW(dev_priv->dev))
dev_priv->uncore.fifo_count =
__raw_i915_read32(dev_priv, GTFIFOCTL) &
GT_FIFO_FREE_ENTRIES_MASK;
if (dev_priv->uncore.fifo_count < GT_FIFO_NUM_RESERVED_ENTRIES) {
int loop = 500;
u32 fifo = __raw_i915_read32(dev_priv, GTFIFOCTL) & GT_FIFO_FREE_ENTRIES_MASK;
while (fifo <= GT_FIFO_NUM_RESERVED_ENTRIES && loop--) {
udelay(10);
fifo = __raw_i915_read32(dev_priv, GTFIFOCTL) & GT_FIFO_FREE_ENTRIES_MASK;
}
if (WARN_ON(loop < 0 && fifo <= GT_FIFO_NUM_RESERVED_ENTRIES))
++ret;
dev_priv->uncore.fifo_count = fifo;
}
dev_priv->uncore.fifo_count--;
return ret;
}
static void vlv_force_wake_reset(struct drm_i915_private *dev_priv)
{
__raw_i915_write32(dev_priv, FORCEWAKE_VLV,
_MASKED_BIT_DISABLE(0xffff));
/* something from same cacheline, but !FORCEWAKE_VLV */
__raw_posting_read(dev_priv, FORCEWAKE_ACK_VLV);
}
static void __vlv_force_wake_get(struct drm_i915_private *dev_priv,
int fw_engine)
{
/* Check for Render Engine */
if (FORCEWAKE_RENDER & fw_engine) {
if (wait_for_atomic((__raw_i915_read32(dev_priv,
FORCEWAKE_ACK_VLV) &
FORCEWAKE_KERNEL) == 0,
FORCEWAKE_ACK_TIMEOUT_MS))
DRM_ERROR("Timed out: Render forcewake old ack to clear.\n");
__raw_i915_write32(dev_priv, FORCEWAKE_VLV,
_MASKED_BIT_ENABLE(FORCEWAKE_KERNEL));
if (wait_for_atomic((__raw_i915_read32(dev_priv,
FORCEWAKE_ACK_VLV) &
FORCEWAKE_KERNEL),
FORCEWAKE_ACK_TIMEOUT_MS))
DRM_ERROR("Timed out: waiting for Render to ack.\n");
}
/* Check for Media Engine */
if (FORCEWAKE_MEDIA & fw_engine) {
if (wait_for_atomic((__raw_i915_read32(dev_priv,
FORCEWAKE_ACK_MEDIA_VLV) &
FORCEWAKE_KERNEL) == 0,
FORCEWAKE_ACK_TIMEOUT_MS))
DRM_ERROR("Timed out: Media forcewake old ack to clear.\n");
__raw_i915_write32(dev_priv, FORCEWAKE_MEDIA_VLV,
_MASKED_BIT_ENABLE(FORCEWAKE_KERNEL));
if (wait_for_atomic((__raw_i915_read32(dev_priv,
FORCEWAKE_ACK_MEDIA_VLV) &
FORCEWAKE_KERNEL),
FORCEWAKE_ACK_TIMEOUT_MS))
DRM_ERROR("Timed out: waiting for media to ack.\n");
}
/* WaRsForcewakeWaitTC0:vlv */
__gen6_gt_wait_for_thread_c0(dev_priv);
}
static void __vlv_force_wake_put(struct drm_i915_private *dev_priv,
int fw_engine)
{
/* Check for Render Engine */
if (FORCEWAKE_RENDER & fw_engine)
__raw_i915_write32(dev_priv, FORCEWAKE_VLV,
_MASKED_BIT_DISABLE(FORCEWAKE_KERNEL));
/* Check for Media Engine */
if (FORCEWAKE_MEDIA & fw_engine)
__raw_i915_write32(dev_priv, FORCEWAKE_MEDIA_VLV,
_MASKED_BIT_DISABLE(FORCEWAKE_KERNEL));
/* The below doubles as a POSTING_READ */
gen6_gt_check_fifodbg(dev_priv);
}
void vlv_force_wake_get(struct drm_i915_private *dev_priv,
int fw_engine)
{
unsigned long irqflags;
spin_lock_irqsave(&dev_priv->uncore.lock, irqflags);
if (FORCEWAKE_RENDER & fw_engine) {
if (dev_priv->uncore.fw_rendercount++ == 0)
dev_priv->uncore.funcs.force_wake_get(dev_priv,
FORCEWAKE_RENDER);
}
if (FORCEWAKE_MEDIA & fw_engine) {
if (dev_priv->uncore.fw_mediacount++ == 0)
dev_priv->uncore.funcs.force_wake_get(dev_priv,
FORCEWAKE_MEDIA);
}
spin_unlock_irqrestore(&dev_priv->uncore.lock, irqflags);
}
void vlv_force_wake_put(struct drm_i915_private *dev_priv,
int fw_engine)
{
unsigned long irqflags;
spin_lock_irqsave(&dev_priv->uncore.lock, irqflags);
if (FORCEWAKE_RENDER & fw_engine) {
WARN_ON(dev_priv->uncore.fw_rendercount == 0);
if (--dev_priv->uncore.fw_rendercount == 0)
dev_priv->uncore.funcs.force_wake_put(dev_priv,
FORCEWAKE_RENDER);
}
if (FORCEWAKE_MEDIA & fw_engine) {
WARN_ON(dev_priv->uncore.fw_mediacount == 0);
if (--dev_priv->uncore.fw_mediacount == 0)
dev_priv->uncore.funcs.force_wake_put(dev_priv,
FORCEWAKE_MEDIA);
}
spin_unlock_irqrestore(&dev_priv->uncore.lock, irqflags);
}
static void gen6_force_wake_timer(unsigned long arg)
{
struct drm_i915_private *dev_priv = (void *)arg;
unsigned long irqflags;
assert_device_not_suspended(dev_priv);
spin_lock_irqsave(&dev_priv->uncore.lock, irqflags);
if (--dev_priv->uncore.forcewake_count == 0)
dev_priv->uncore.funcs.force_wake_put(dev_priv, FORCEWAKE_ALL);
spin_unlock_irqrestore(&dev_priv->uncore.lock, irqflags);
intel_runtime_pm_put(dev_priv);
}
static void intel_uncore_forcewake_reset(struct drm_device *dev)
{
struct drm_i915_private *dev_priv = dev->dev_private;
if (IS_VALLEYVIEW(dev)) {
vlv_force_wake_reset(dev_priv);
} else if (INTEL_INFO(dev)->gen >= 6) {
__gen6_gt_force_wake_reset(dev_priv);
if (IS_IVYBRIDGE(dev) || IS_HASWELL(dev))
__gen6_gt_force_wake_mt_reset(dev_priv);
}
}
void intel_uncore_early_sanitize(struct drm_device *dev)
{
struct drm_i915_private *dev_priv = dev->dev_private;
if (HAS_FPGA_DBG_UNCLAIMED(dev))
__raw_i915_write32(dev_priv, FPGA_DBG, FPGA_DBG_RM_NOCLAIM);
if (IS_HASWELL(dev) &&
(__raw_i915_read32(dev_priv, HSW_EDRAM_PRESENT) == 1)) {
/* The docs do not explain exactly how the calculation can be
* made. It is somewhat guessable, but for now, it's always
* 128MB.
* NB: We can't write IDICR yet because we do not have gt funcs
* set up */
dev_priv->ellc_size = 128;
DRM_INFO("Found %zuMB of eLLC\n", dev_priv->ellc_size);
}
/* clear out old GT FIFO errors */
if (IS_GEN6(dev) || IS_GEN7(dev))
__raw_i915_write32(dev_priv, GTFIFODBG,
__raw_i915_read32(dev_priv, GTFIFODBG));
intel_uncore_forcewake_reset(dev);
}
void intel_uncore_sanitize(struct drm_device *dev)
{
struct drm_i915_private *dev_priv = dev->dev_private;
u32 reg_val;
/* BIOS often leaves RC6 enabled, but disable it for hw init */
intel_disable_gt_powersave(dev);
/* Turn off power gate, require especially for the BIOS less system */
if (IS_VALLEYVIEW(dev)) {
mutex_lock(&dev_priv->rps.hw_lock);
reg_val = vlv_punit_read(dev_priv, PUNIT_REG_PWRGT_STATUS);
if (reg_val & (RENDER_PWRGT | MEDIA_PWRGT | DISP2D_PWRGT))
vlv_punit_write(dev_priv, PUNIT_REG_PWRGT_CTRL, 0x0);
mutex_unlock(&dev_priv->rps.hw_lock);
}
}
/*
* Generally this is called implicitly by the register read function. However,
* if some sequence requires the GT to not power down then this function should
* be called at the beginning of the sequence followed by a call to
* gen6_gt_force_wake_put() at the end of the sequence.
*/
void gen6_gt_force_wake_get(struct drm_i915_private *dev_priv, int fw_engine)
{
unsigned long irqflags;
if (!dev_priv->uncore.funcs.force_wake_get)
return;
intel_runtime_pm_get(dev_priv);
/* Redirect to VLV specific routine */
if (IS_VALLEYVIEW(dev_priv->dev))
return vlv_force_wake_get(dev_priv, fw_engine);
spin_lock_irqsave(&dev_priv->uncore.lock, irqflags);
if (dev_priv->uncore.forcewake_count++ == 0)
dev_priv->uncore.funcs.force_wake_get(dev_priv, FORCEWAKE_ALL);
spin_unlock_irqrestore(&dev_priv->uncore.lock, irqflags);
}
/*
* see gen6_gt_force_wake_get()
*/
void gen6_gt_force_wake_put(struct drm_i915_private *dev_priv, int fw_engine)
{
unsigned long irqflags;
bool delayed = false;
if (!dev_priv->uncore.funcs.force_wake_put)
return;
/* Redirect to VLV specific routine */
if (IS_VALLEYVIEW(dev_priv->dev)) {
vlv_force_wake_put(dev_priv, fw_engine);
goto out;
}
spin_lock_irqsave(&dev_priv->uncore.lock, irqflags);
if (--dev_priv->uncore.forcewake_count == 0) {
dev_priv->uncore.forcewake_count++;
delayed = true;
mod_timer_pinned(&dev_priv->uncore.force_wake_timer,
jiffies + 1);
}
spin_unlock_irqrestore(&dev_priv->uncore.lock, irqflags);
out:
if (!delayed)
intel_runtime_pm_put(dev_priv);
}
void assert_force_wake_inactive(struct drm_i915_private *dev_priv)
{
if (!dev_priv->uncore.funcs.force_wake_get)
return;
WARN_ON(dev_priv->uncore.forcewake_count > 0);
}
/* We give fast paths for the really cool registers */
#define NEEDS_FORCE_WAKE(dev_priv, reg) \
((reg) < 0x40000 && (reg) != FORCEWAKE)
static void
ilk_dummy_write(struct drm_i915_private *dev_priv)
{
/* WaIssueDummyWriteToWakeupFromRC6:ilk Issue a dummy write to wake up
* the chip from rc6 before touching it for real. MI_MODE is masked,
* hence harmless to write 0 into. */
__raw_i915_write32(dev_priv, MI_MODE, 0);
}
static void
hsw_unclaimed_reg_clear(struct drm_i915_private *dev_priv, u32 reg)
{
if (__raw_i915_read32(dev_priv, FPGA_DBG) & FPGA_DBG_RM_NOCLAIM) {
DRM_ERROR("Unknown unclaimed register before writing to %x\n",
reg);
__raw_i915_write32(dev_priv, FPGA_DBG, FPGA_DBG_RM_NOCLAIM);
}
}
static void
hsw_unclaimed_reg_check(struct drm_i915_private *dev_priv, u32 reg)
{
if (__raw_i915_read32(dev_priv, FPGA_DBG) & FPGA_DBG_RM_NOCLAIM) {
DRM_ERROR("Unclaimed write to %x\n", reg);
__raw_i915_write32(dev_priv, FPGA_DBG, FPGA_DBG_RM_NOCLAIM);
}
}
#define REG_READ_HEADER(x) \
unsigned long irqflags; \
u##x val = 0; \
assert_device_not_suspended(dev_priv); \
spin_lock_irqsave(&dev_priv->uncore.lock, irqflags)
#define REG_READ_FOOTER \
spin_unlock_irqrestore(&dev_priv->uncore.lock, irqflags); \
trace_i915_reg_rw(false, reg, val, sizeof(val), trace); \
return val
#define __gen4_read(x) \
static u##x \
gen4_read##x(struct drm_i915_private *dev_priv, off_t reg, bool trace) { \
REG_READ_HEADER(x); \
val = __raw_i915_read##x(dev_priv, reg); \
REG_READ_FOOTER; \
}
#define __gen5_read(x) \
static u##x \
gen5_read##x(struct drm_i915_private *dev_priv, off_t reg, bool trace) { \
REG_READ_HEADER(x); \
ilk_dummy_write(dev_priv); \
val = __raw_i915_read##x(dev_priv, reg); \
REG_READ_FOOTER; \
}
#define __gen6_read(x) \
static u##x \
gen6_read##x(struct drm_i915_private *dev_priv, off_t reg, bool trace) { \
REG_READ_HEADER(x); \
if (dev_priv->uncore.forcewake_count == 0 && \
NEEDS_FORCE_WAKE((dev_priv), (reg))) { \
dev_priv->uncore.funcs.force_wake_get(dev_priv, \
FORCEWAKE_ALL); \
dev_priv->uncore.forcewake_count++; \
mod_timer_pinned(&dev_priv->uncore.force_wake_timer, \
jiffies + 1); \
} \
val = __raw_i915_read##x(dev_priv, reg); \
REG_READ_FOOTER; \
}
#define __vlv_read(x) \
static u##x \
vlv_read##x(struct drm_i915_private *dev_priv, off_t reg, bool trace) { \
unsigned fwengine = 0; \
unsigned *fwcount; \
REG_READ_HEADER(x); \
if (FORCEWAKE_VLV_RENDER_RANGE_OFFSET(reg)) { \
fwengine = FORCEWAKE_RENDER; \
fwcount = &dev_priv->uncore.fw_rendercount; \
} \
else if (FORCEWAKE_VLV_MEDIA_RANGE_OFFSET(reg)) { \
fwengine = FORCEWAKE_MEDIA; \
fwcount = &dev_priv->uncore.fw_mediacount; \
} \
if (fwengine != 0) { \
if ((*fwcount)++ == 0) \
(dev_priv)->uncore.funcs.force_wake_get(dev_priv, \
fwengine); \
val = __raw_i915_read##x(dev_priv, reg); \
if (--(*fwcount) == 0) \
(dev_priv)->uncore.funcs.force_wake_put(dev_priv, \
fwengine); \
} else { \
val = __raw_i915_read##x(dev_priv, reg); \
} \
REG_READ_FOOTER; \
}
__vlv_read(8)
__vlv_read(16)
__vlv_read(32)
__vlv_read(64)
__gen6_read(8)
__gen6_read(16)
__gen6_read(32)
__gen6_read(64)
__gen5_read(8)
__gen5_read(16)
__gen5_read(32)
__gen5_read(64)
__gen4_read(8)
__gen4_read(16)
__gen4_read(32)
__gen4_read(64)
#undef __vlv_read
#undef __gen6_read
#undef __gen5_read
#undef __gen4_read
#undef REG_READ_FOOTER
#undef REG_READ_HEADER
#define REG_WRITE_HEADER \
unsigned long irqflags; \
trace_i915_reg_rw(true, reg, val, sizeof(val), trace); \
assert_device_not_suspended(dev_priv); \
spin_lock_irqsave(&dev_priv->uncore.lock, irqflags)
#define REG_WRITE_FOOTER \
spin_unlock_irqrestore(&dev_priv->uncore.lock, irqflags)
#define __gen4_write(x) \
static void \
gen4_write##x(struct drm_i915_private *dev_priv, off_t reg, u##x val, bool trace) { \
REG_WRITE_HEADER; \
__raw_i915_write##x(dev_priv, reg, val); \
REG_WRITE_FOOTER; \
}
#define __gen5_write(x) \
static void \
gen5_write##x(struct drm_i915_private *dev_priv, off_t reg, u##x val, bool trace) { \
REG_WRITE_HEADER; \
ilk_dummy_write(dev_priv); \
__raw_i915_write##x(dev_priv, reg, val); \
REG_WRITE_FOOTER; \
}
#define __gen6_write(x) \
static void \
gen6_write##x(struct drm_i915_private *dev_priv, off_t reg, u##x val, bool trace) { \
u32 __fifo_ret = 0; \
REG_WRITE_HEADER; \
if (NEEDS_FORCE_WAKE((dev_priv), (reg))) { \
__fifo_ret = __gen6_gt_wait_for_fifo(dev_priv); \
} \
__raw_i915_write##x(dev_priv, reg, val); \
if (unlikely(__fifo_ret)) { \
gen6_gt_check_fifodbg(dev_priv); \
} \
REG_WRITE_FOOTER; \
}
#define __hsw_write(x) \
static void \
hsw_write##x(struct drm_i915_private *dev_priv, off_t reg, u##x val, bool trace) { \
u32 __fifo_ret = 0; \
REG_WRITE_HEADER; \
if (NEEDS_FORCE_WAKE((dev_priv), (reg))) { \
__fifo_ret = __gen6_gt_wait_for_fifo(dev_priv); \
} \
hsw_unclaimed_reg_clear(dev_priv, reg); \
__raw_i915_write##x(dev_priv, reg, val); \
if (unlikely(__fifo_ret)) { \
gen6_gt_check_fifodbg(dev_priv); \
} \
hsw_unclaimed_reg_check(dev_priv, reg); \
REG_WRITE_FOOTER; \
}
drm/i915/bdw: Handle forcewake for writes on gen8 GEN8 removes the GT FIFO which we've all come to know and love. Instead it offers a wider range of optimized registers which always keep a shadowed copy, and are fed to the GPU when it wakes. How this is implemented in hardware is still somewhat of a mystery. As far as I can tell, the basic design is as follows: If the register is not optimized, you must use the old forcewake mechanism to bring the GT out of sleep. [1] If register is in the optimized list the write will signal that the GT should begin to come out of whatever sleep state it is in. While the GT is coming out of sleep, the requested write will be stored in an intermediate shadow register. Do to the fact that the implementation details are not clear, I see several risks: 1. Order is not preserved as it is with GT FIFO. If we issue multiple writes to optimized registers, where order matters, we may need to serialize it with forcewake. 2. The optimized registers have only 1 shadowed slot, meaning if we issue multiple writes to the same register, and those values need to reach the GPU in order, forcewake will be required. [1] We could implement a SW queue the way the GT FIFO used to work if desired. NOTE: Compile tested only until we get real silicon. v2: - Use a default case to make future platforms also work. - Get rid of IS_BROADWELL since that's not yet defined, but we want to MMIO as soon as possible. v3: Apply suggestions from Mika's review: - s/optimized/shadowed/ - invert the logic of the helper so that it does what it says (the code itself was correct, just confusing to read). v4: - Squash in lost break. Signed-off-by: Ben Widawsky <ben@bwidawsk.net> (v1) Reviewed-by: Mika Kuoppala <mika.kuoppala@intel.com> Signed-off-by: Daniel Vetter <daniel.vetter@ffwll.ch>
2013-11-03 04:07:00 +00:00
static const u32 gen8_shadowed_regs[] = {
FORCEWAKE_MT,
GEN6_RPNSWREQ,
GEN6_RC_VIDEO_FREQ,
RING_TAIL(RENDER_RING_BASE),
RING_TAIL(GEN6_BSD_RING_BASE),
RING_TAIL(VEBOX_RING_BASE),
RING_TAIL(BLT_RING_BASE),
/* TODO: Other registers are not yet used */
};
static bool is_gen8_shadowed(struct drm_i915_private *dev_priv, u32 reg)
{
int i;
for (i = 0; i < ARRAY_SIZE(gen8_shadowed_regs); i++)
if (reg == gen8_shadowed_regs[i])
return true;
return false;
}
#define __gen8_write(x) \
static void \
gen8_write##x(struct drm_i915_private *dev_priv, off_t reg, u##x val, bool trace) { \
REG_WRITE_HEADER; \
if (reg < 0x40000 && !is_gen8_shadowed(dev_priv, reg)) { \
if (dev_priv->uncore.forcewake_count == 0) \
dev_priv->uncore.funcs.force_wake_get(dev_priv, \
FORCEWAKE_ALL); \
__raw_i915_write##x(dev_priv, reg, val); \
if (dev_priv->uncore.forcewake_count == 0) \
dev_priv->uncore.funcs.force_wake_put(dev_priv, \
FORCEWAKE_ALL); \
} else { \
__raw_i915_write##x(dev_priv, reg, val); \
drm/i915/bdw: Handle forcewake for writes on gen8 GEN8 removes the GT FIFO which we've all come to know and love. Instead it offers a wider range of optimized registers which always keep a shadowed copy, and are fed to the GPU when it wakes. How this is implemented in hardware is still somewhat of a mystery. As far as I can tell, the basic design is as follows: If the register is not optimized, you must use the old forcewake mechanism to bring the GT out of sleep. [1] If register is in the optimized list the write will signal that the GT should begin to come out of whatever sleep state it is in. While the GT is coming out of sleep, the requested write will be stored in an intermediate shadow register. Do to the fact that the implementation details are not clear, I see several risks: 1. Order is not preserved as it is with GT FIFO. If we issue multiple writes to optimized registers, where order matters, we may need to serialize it with forcewake. 2. The optimized registers have only 1 shadowed slot, meaning if we issue multiple writes to the same register, and those values need to reach the GPU in order, forcewake will be required. [1] We could implement a SW queue the way the GT FIFO used to work if desired. NOTE: Compile tested only until we get real silicon. v2: - Use a default case to make future platforms also work. - Get rid of IS_BROADWELL since that's not yet defined, but we want to MMIO as soon as possible. v3: Apply suggestions from Mika's review: - s/optimized/shadowed/ - invert the logic of the helper so that it does what it says (the code itself was correct, just confusing to read). v4: - Squash in lost break. Signed-off-by: Ben Widawsky <ben@bwidawsk.net> (v1) Reviewed-by: Mika Kuoppala <mika.kuoppala@intel.com> Signed-off-by: Daniel Vetter <daniel.vetter@ffwll.ch>
2013-11-03 04:07:00 +00:00
} \
REG_WRITE_FOOTER; \
drm/i915/bdw: Handle forcewake for writes on gen8 GEN8 removes the GT FIFO which we've all come to know and love. Instead it offers a wider range of optimized registers which always keep a shadowed copy, and are fed to the GPU when it wakes. How this is implemented in hardware is still somewhat of a mystery. As far as I can tell, the basic design is as follows: If the register is not optimized, you must use the old forcewake mechanism to bring the GT out of sleep. [1] If register is in the optimized list the write will signal that the GT should begin to come out of whatever sleep state it is in. While the GT is coming out of sleep, the requested write will be stored in an intermediate shadow register. Do to the fact that the implementation details are not clear, I see several risks: 1. Order is not preserved as it is with GT FIFO. If we issue multiple writes to optimized registers, where order matters, we may need to serialize it with forcewake. 2. The optimized registers have only 1 shadowed slot, meaning if we issue multiple writes to the same register, and those values need to reach the GPU in order, forcewake will be required. [1] We could implement a SW queue the way the GT FIFO used to work if desired. NOTE: Compile tested only until we get real silicon. v2: - Use a default case to make future platforms also work. - Get rid of IS_BROADWELL since that's not yet defined, but we want to MMIO as soon as possible. v3: Apply suggestions from Mika's review: - s/optimized/shadowed/ - invert the logic of the helper so that it does what it says (the code itself was correct, just confusing to read). v4: - Squash in lost break. Signed-off-by: Ben Widawsky <ben@bwidawsk.net> (v1) Reviewed-by: Mika Kuoppala <mika.kuoppala@intel.com> Signed-off-by: Daniel Vetter <daniel.vetter@ffwll.ch>
2013-11-03 04:07:00 +00:00
}
__gen8_write(8)
__gen8_write(16)
__gen8_write(32)
__gen8_write(64)
__hsw_write(8)
__hsw_write(16)
__hsw_write(32)
__hsw_write(64)
__gen6_write(8)
__gen6_write(16)
__gen6_write(32)
__gen6_write(64)
__gen5_write(8)
__gen5_write(16)
__gen5_write(32)
__gen5_write(64)
__gen4_write(8)
__gen4_write(16)
__gen4_write(32)
__gen4_write(64)
drm/i915/bdw: Handle forcewake for writes on gen8 GEN8 removes the GT FIFO which we've all come to know and love. Instead it offers a wider range of optimized registers which always keep a shadowed copy, and are fed to the GPU when it wakes. How this is implemented in hardware is still somewhat of a mystery. As far as I can tell, the basic design is as follows: If the register is not optimized, you must use the old forcewake mechanism to bring the GT out of sleep. [1] If register is in the optimized list the write will signal that the GT should begin to come out of whatever sleep state it is in. While the GT is coming out of sleep, the requested write will be stored in an intermediate shadow register. Do to the fact that the implementation details are not clear, I see several risks: 1. Order is not preserved as it is with GT FIFO. If we issue multiple writes to optimized registers, where order matters, we may need to serialize it with forcewake. 2. The optimized registers have only 1 shadowed slot, meaning if we issue multiple writes to the same register, and those values need to reach the GPU in order, forcewake will be required. [1] We could implement a SW queue the way the GT FIFO used to work if desired. NOTE: Compile tested only until we get real silicon. v2: - Use a default case to make future platforms also work. - Get rid of IS_BROADWELL since that's not yet defined, but we want to MMIO as soon as possible. v3: Apply suggestions from Mika's review: - s/optimized/shadowed/ - invert the logic of the helper so that it does what it says (the code itself was correct, just confusing to read). v4: - Squash in lost break. Signed-off-by: Ben Widawsky <ben@bwidawsk.net> (v1) Reviewed-by: Mika Kuoppala <mika.kuoppala@intel.com> Signed-off-by: Daniel Vetter <daniel.vetter@ffwll.ch>
2013-11-03 04:07:00 +00:00
#undef __gen8_write
#undef __hsw_write
#undef __gen6_write
#undef __gen5_write
#undef __gen4_write
#undef REG_WRITE_FOOTER
#undef REG_WRITE_HEADER
void intel_uncore_init(struct drm_device *dev)
{
struct drm_i915_private *dev_priv = dev->dev_private;
setup_timer(&dev_priv->uncore.force_wake_timer,
gen6_force_wake_timer, (unsigned long)dev_priv);
if (IS_VALLEYVIEW(dev)) {
dev_priv->uncore.funcs.force_wake_get = __vlv_force_wake_get;
dev_priv->uncore.funcs.force_wake_put = __vlv_force_wake_put;
} else if (IS_HASWELL(dev) || IS_GEN8(dev)) {
dev_priv->uncore.funcs.force_wake_get = __gen6_gt_force_wake_mt_get;
dev_priv->uncore.funcs.force_wake_put = __gen6_gt_force_wake_mt_put;
} else if (IS_IVYBRIDGE(dev)) {
u32 ecobus;
/* IVB configs may use multi-threaded forcewake */
/* A small trick here - if the bios hasn't configured
* MT forcewake, and if the device is in RC6, then
* force_wake_mt_get will not wake the device and the
* ECOBUS read will return zero. Which will be
* (correctly) interpreted by the test below as MT
* forcewake being disabled.
*/
mutex_lock(&dev->struct_mutex);
__gen6_gt_force_wake_mt_get(dev_priv, FORCEWAKE_ALL);
ecobus = __raw_i915_read32(dev_priv, ECOBUS);
__gen6_gt_force_wake_mt_put(dev_priv, FORCEWAKE_ALL);
mutex_unlock(&dev->struct_mutex);
if (ecobus & FORCEWAKE_MT_ENABLE) {
dev_priv->uncore.funcs.force_wake_get =
__gen6_gt_force_wake_mt_get;
dev_priv->uncore.funcs.force_wake_put =
__gen6_gt_force_wake_mt_put;
} else {
DRM_INFO("No MT forcewake available on Ivybridge, this can result in issues\n");
DRM_INFO("when using vblank-synced partial screen updates.\n");
dev_priv->uncore.funcs.force_wake_get =
__gen6_gt_force_wake_get;
dev_priv->uncore.funcs.force_wake_put =
__gen6_gt_force_wake_put;
}
} else if (IS_GEN6(dev)) {
dev_priv->uncore.funcs.force_wake_get =
__gen6_gt_force_wake_get;
dev_priv->uncore.funcs.force_wake_put =
__gen6_gt_force_wake_put;
}
switch (INTEL_INFO(dev)->gen) {
drm/i915/bdw: Handle forcewake for writes on gen8 GEN8 removes the GT FIFO which we've all come to know and love. Instead it offers a wider range of optimized registers which always keep a shadowed copy, and are fed to the GPU when it wakes. How this is implemented in hardware is still somewhat of a mystery. As far as I can tell, the basic design is as follows: If the register is not optimized, you must use the old forcewake mechanism to bring the GT out of sleep. [1] If register is in the optimized list the write will signal that the GT should begin to come out of whatever sleep state it is in. While the GT is coming out of sleep, the requested write will be stored in an intermediate shadow register. Do to the fact that the implementation details are not clear, I see several risks: 1. Order is not preserved as it is with GT FIFO. If we issue multiple writes to optimized registers, where order matters, we may need to serialize it with forcewake. 2. The optimized registers have only 1 shadowed slot, meaning if we issue multiple writes to the same register, and those values need to reach the GPU in order, forcewake will be required. [1] We could implement a SW queue the way the GT FIFO used to work if desired. NOTE: Compile tested only until we get real silicon. v2: - Use a default case to make future platforms also work. - Get rid of IS_BROADWELL since that's not yet defined, but we want to MMIO as soon as possible. v3: Apply suggestions from Mika's review: - s/optimized/shadowed/ - invert the logic of the helper so that it does what it says (the code itself was correct, just confusing to read). v4: - Squash in lost break. Signed-off-by: Ben Widawsky <ben@bwidawsk.net> (v1) Reviewed-by: Mika Kuoppala <mika.kuoppala@intel.com> Signed-off-by: Daniel Vetter <daniel.vetter@ffwll.ch>
2013-11-03 04:07:00 +00:00
default:
dev_priv->uncore.funcs.mmio_writeb = gen8_write8;
dev_priv->uncore.funcs.mmio_writew = gen8_write16;
dev_priv->uncore.funcs.mmio_writel = gen8_write32;
dev_priv->uncore.funcs.mmio_writeq = gen8_write64;
dev_priv->uncore.funcs.mmio_readb = gen6_read8;
dev_priv->uncore.funcs.mmio_readw = gen6_read16;
dev_priv->uncore.funcs.mmio_readl = gen6_read32;
dev_priv->uncore.funcs.mmio_readq = gen6_read64;
break;
case 7:
case 6:
if (IS_HASWELL(dev)) {
dev_priv->uncore.funcs.mmio_writeb = hsw_write8;
dev_priv->uncore.funcs.mmio_writew = hsw_write16;
dev_priv->uncore.funcs.mmio_writel = hsw_write32;
dev_priv->uncore.funcs.mmio_writeq = hsw_write64;
} else {
dev_priv->uncore.funcs.mmio_writeb = gen6_write8;
dev_priv->uncore.funcs.mmio_writew = gen6_write16;
dev_priv->uncore.funcs.mmio_writel = gen6_write32;
dev_priv->uncore.funcs.mmio_writeq = gen6_write64;
}
if (IS_VALLEYVIEW(dev)) {
dev_priv->uncore.funcs.mmio_readb = vlv_read8;
dev_priv->uncore.funcs.mmio_readw = vlv_read16;
dev_priv->uncore.funcs.mmio_readl = vlv_read32;
dev_priv->uncore.funcs.mmio_readq = vlv_read64;
} else {
dev_priv->uncore.funcs.mmio_readb = gen6_read8;
dev_priv->uncore.funcs.mmio_readw = gen6_read16;
dev_priv->uncore.funcs.mmio_readl = gen6_read32;
dev_priv->uncore.funcs.mmio_readq = gen6_read64;
}
break;
case 5:
dev_priv->uncore.funcs.mmio_writeb = gen5_write8;
dev_priv->uncore.funcs.mmio_writew = gen5_write16;
dev_priv->uncore.funcs.mmio_writel = gen5_write32;
dev_priv->uncore.funcs.mmio_writeq = gen5_write64;
dev_priv->uncore.funcs.mmio_readb = gen5_read8;
dev_priv->uncore.funcs.mmio_readw = gen5_read16;
dev_priv->uncore.funcs.mmio_readl = gen5_read32;
dev_priv->uncore.funcs.mmio_readq = gen5_read64;
break;
case 4:
case 3:
case 2:
dev_priv->uncore.funcs.mmio_writeb = gen4_write8;
dev_priv->uncore.funcs.mmio_writew = gen4_write16;
dev_priv->uncore.funcs.mmio_writel = gen4_write32;
dev_priv->uncore.funcs.mmio_writeq = gen4_write64;
dev_priv->uncore.funcs.mmio_readb = gen4_read8;
dev_priv->uncore.funcs.mmio_readw = gen4_read16;
dev_priv->uncore.funcs.mmio_readl = gen4_read32;
dev_priv->uncore.funcs.mmio_readq = gen4_read64;
break;
}
}
void intel_uncore_fini(struct drm_device *dev)
{
struct drm_i915_private *dev_priv = dev->dev_private;
del_timer_sync(&dev_priv->uncore.force_wake_timer);
/* Paranoia: make sure we have disabled everything before we exit. */
intel_uncore_sanitize(dev);
intel_uncore_forcewake_reset(dev);
}
static const struct register_whitelist {
uint64_t offset;
uint32_t size;
uint32_t gen_bitmask; /* support gens, 0x10 for 4, 0x30 for 4 and 5, etc. */
} whitelist[] = {
{ RING_TIMESTAMP(RENDER_RING_BASE), 8, 0x1F0 },
};
int i915_reg_read_ioctl(struct drm_device *dev,
void *data, struct drm_file *file)
{
struct drm_i915_private *dev_priv = dev->dev_private;
struct drm_i915_reg_read *reg = data;
struct register_whitelist const *entry = whitelist;
int i;
for (i = 0; i < ARRAY_SIZE(whitelist); i++, entry++) {
if (entry->offset == reg->offset &&
(1 << INTEL_INFO(dev)->gen & entry->gen_bitmask))
break;
}
if (i == ARRAY_SIZE(whitelist))
return -EINVAL;
switch (entry->size) {
case 8:
reg->val = I915_READ64(reg->offset);
break;
case 4:
reg->val = I915_READ(reg->offset);
break;
case 2:
reg->val = I915_READ16(reg->offset);
break;
case 1:
reg->val = I915_READ8(reg->offset);
break;
default:
WARN_ON(1);
return -EINVAL;
}
return 0;
}
int i915_get_reset_stats_ioctl(struct drm_device *dev,
void *data, struct drm_file *file)
{
struct drm_i915_private *dev_priv = dev->dev_private;
struct drm_i915_reset_stats *args = data;
struct i915_ctx_hang_stats *hs;
drm/i915: Get context early in execbuf We need to have the address space when reserving space for the objects. Since the address space and context are tied together, and reserve occurs before context switch (for good reason), we must lookup our context earlier in the process. This leaves some room for optimizations where we no longer need to use ctx_id in certain places. This will be addressed in a subsequent patch. Important tricky bit: Because slow relocations during execbuffer drop struct_mutex Perhaps it would be best to acquire the reference when we get the context, but I'll save that for another day (note I have written the patch before, and I found the changes required to be uglier than this). Note that since we currently access everything via context id, and not the data structure this is fine, though not desirable. The next change attempts to get the context only once via the context ID idr lookup, and as such, the following can happen: CTX-A is created, refcount = 1 CTX-A execbuf, mutex dropped close IOCTL called on CTX-A, refcount = 0 CTX-A resumes in execbuf. v2: Rebased on top of commit b6359918b885da7c7b58c050674278dbd06020ab Author: Mika Kuoppala <mika.kuoppala@linux.intel.com> Date: Wed Oct 30 15:44:16 2013 +0200 drm/i915: add i915_get_reset_stats_ioctl v3: Rebased on top of commit 25b3dfc87bff80317d67ddd2cd4cfb91e6fe7d79 Author: Mika Westerberg <mika.westerberg@linux.intel.com> Date: Tue Nov 12 11:57:30 2013 +0200 Author: Mika Kuoppala <mika.kuoppala@linux.intel.com> Date: Tue Nov 26 16:14:33 2013 +0200 drm/i915: check context reset stats before relocations Signed-off-by: Ben Widawsky <ben@bwidawsk.net> Signed-off-by: Daniel Vetter <daniel.vetter@ffwll.ch>
2013-12-06 22:11:21 +00:00
struct i915_hw_context *ctx;
int ret;
if (args->flags || args->pad)
return -EINVAL;
if (args->ctx_id == DEFAULT_CONTEXT_ID && !capable(CAP_SYS_ADMIN))
return -EPERM;
ret = mutex_lock_interruptible(&dev->struct_mutex);
if (ret)
return ret;
drm/i915: Get context early in execbuf We need to have the address space when reserving space for the objects. Since the address space and context are tied together, and reserve occurs before context switch (for good reason), we must lookup our context earlier in the process. This leaves some room for optimizations where we no longer need to use ctx_id in certain places. This will be addressed in a subsequent patch. Important tricky bit: Because slow relocations during execbuffer drop struct_mutex Perhaps it would be best to acquire the reference when we get the context, but I'll save that for another day (note I have written the patch before, and I found the changes required to be uglier than this). Note that since we currently access everything via context id, and not the data structure this is fine, though not desirable. The next change attempts to get the context only once via the context ID idr lookup, and as such, the following can happen: CTX-A is created, refcount = 1 CTX-A execbuf, mutex dropped close IOCTL called on CTX-A, refcount = 0 CTX-A resumes in execbuf. v2: Rebased on top of commit b6359918b885da7c7b58c050674278dbd06020ab Author: Mika Kuoppala <mika.kuoppala@linux.intel.com> Date: Wed Oct 30 15:44:16 2013 +0200 drm/i915: add i915_get_reset_stats_ioctl v3: Rebased on top of commit 25b3dfc87bff80317d67ddd2cd4cfb91e6fe7d79 Author: Mika Westerberg <mika.westerberg@linux.intel.com> Date: Tue Nov 12 11:57:30 2013 +0200 Author: Mika Kuoppala <mika.kuoppala@linux.intel.com> Date: Tue Nov 26 16:14:33 2013 +0200 drm/i915: check context reset stats before relocations Signed-off-by: Ben Widawsky <ben@bwidawsk.net> Signed-off-by: Daniel Vetter <daniel.vetter@ffwll.ch>
2013-12-06 22:11:21 +00:00
ctx = i915_gem_context_get(file->driver_priv, args->ctx_id);
if (IS_ERR(ctx)) {
mutex_unlock(&dev->struct_mutex);
drm/i915: Get context early in execbuf We need to have the address space when reserving space for the objects. Since the address space and context are tied together, and reserve occurs before context switch (for good reason), we must lookup our context earlier in the process. This leaves some room for optimizations where we no longer need to use ctx_id in certain places. This will be addressed in a subsequent patch. Important tricky bit: Because slow relocations during execbuffer drop struct_mutex Perhaps it would be best to acquire the reference when we get the context, but I'll save that for another day (note I have written the patch before, and I found the changes required to be uglier than this). Note that since we currently access everything via context id, and not the data structure this is fine, though not desirable. The next change attempts to get the context only once via the context ID idr lookup, and as such, the following can happen: CTX-A is created, refcount = 1 CTX-A execbuf, mutex dropped close IOCTL called on CTX-A, refcount = 0 CTX-A resumes in execbuf. v2: Rebased on top of commit b6359918b885da7c7b58c050674278dbd06020ab Author: Mika Kuoppala <mika.kuoppala@linux.intel.com> Date: Wed Oct 30 15:44:16 2013 +0200 drm/i915: add i915_get_reset_stats_ioctl v3: Rebased on top of commit 25b3dfc87bff80317d67ddd2cd4cfb91e6fe7d79 Author: Mika Westerberg <mika.westerberg@linux.intel.com> Date: Tue Nov 12 11:57:30 2013 +0200 Author: Mika Kuoppala <mika.kuoppala@linux.intel.com> Date: Tue Nov 26 16:14:33 2013 +0200 drm/i915: check context reset stats before relocations Signed-off-by: Ben Widawsky <ben@bwidawsk.net> Signed-off-by: Daniel Vetter <daniel.vetter@ffwll.ch>
2013-12-06 22:11:21 +00:00
return PTR_ERR(ctx);
}
drm/i915: Get context early in execbuf We need to have the address space when reserving space for the objects. Since the address space and context are tied together, and reserve occurs before context switch (for good reason), we must lookup our context earlier in the process. This leaves some room for optimizations where we no longer need to use ctx_id in certain places. This will be addressed in a subsequent patch. Important tricky bit: Because slow relocations during execbuffer drop struct_mutex Perhaps it would be best to acquire the reference when we get the context, but I'll save that for another day (note I have written the patch before, and I found the changes required to be uglier than this). Note that since we currently access everything via context id, and not the data structure this is fine, though not desirable. The next change attempts to get the context only once via the context ID idr lookup, and as such, the following can happen: CTX-A is created, refcount = 1 CTX-A execbuf, mutex dropped close IOCTL called on CTX-A, refcount = 0 CTX-A resumes in execbuf. v2: Rebased on top of commit b6359918b885da7c7b58c050674278dbd06020ab Author: Mika Kuoppala <mika.kuoppala@linux.intel.com> Date: Wed Oct 30 15:44:16 2013 +0200 drm/i915: add i915_get_reset_stats_ioctl v3: Rebased on top of commit 25b3dfc87bff80317d67ddd2cd4cfb91e6fe7d79 Author: Mika Westerberg <mika.westerberg@linux.intel.com> Date: Tue Nov 12 11:57:30 2013 +0200 Author: Mika Kuoppala <mika.kuoppala@linux.intel.com> Date: Tue Nov 26 16:14:33 2013 +0200 drm/i915: check context reset stats before relocations Signed-off-by: Ben Widawsky <ben@bwidawsk.net> Signed-off-by: Daniel Vetter <daniel.vetter@ffwll.ch>
2013-12-06 22:11:21 +00:00
hs = &ctx->hang_stats;
if (capable(CAP_SYS_ADMIN))
args->reset_count = i915_reset_count(&dev_priv->gpu_error);
else
args->reset_count = 0;
args->batch_active = hs->batch_active;
args->batch_pending = hs->batch_pending;
mutex_unlock(&dev->struct_mutex);
return 0;
}
static int i965_reset_complete(struct drm_device *dev)
{
u8 gdrst;
pci_read_config_byte(dev->pdev, I965_GDRST, &gdrst);
return (gdrst & GRDOM_RESET_ENABLE) == 0;
}
static int i965_do_reset(struct drm_device *dev)
{
int ret;
/*
* Set the domains we want to reset (GRDOM/bits 2 and 3) as
* well as the reset bit (GR/bit 0). Setting the GR bit
* triggers the reset; when done, the hardware will clear it.
*/
pci_write_config_byte(dev->pdev, I965_GDRST,
GRDOM_RENDER | GRDOM_RESET_ENABLE);
ret = wait_for(i965_reset_complete(dev), 500);
if (ret)
return ret;
/* We can't reset render&media without also resetting display ... */
pci_write_config_byte(dev->pdev, I965_GDRST,
GRDOM_MEDIA | GRDOM_RESET_ENABLE);
ret = wait_for(i965_reset_complete(dev), 500);
if (ret)
return ret;
pci_write_config_byte(dev->pdev, I965_GDRST, 0);
return 0;
}
static int ironlake_do_reset(struct drm_device *dev)
{
struct drm_i915_private *dev_priv = dev->dev_private;
u32 gdrst;
int ret;
gdrst = I915_READ(MCHBAR_MIRROR_BASE + ILK_GDSR);
gdrst &= ~GRDOM_MASK;
I915_WRITE(MCHBAR_MIRROR_BASE + ILK_GDSR,
gdrst | GRDOM_RENDER | GRDOM_RESET_ENABLE);
ret = wait_for(I915_READ(MCHBAR_MIRROR_BASE + ILK_GDSR) & 0x1, 500);
if (ret)
return ret;
/* We can't reset render&media without also resetting display ... */
gdrst = I915_READ(MCHBAR_MIRROR_BASE + ILK_GDSR);
gdrst &= ~GRDOM_MASK;
I915_WRITE(MCHBAR_MIRROR_BASE + ILK_GDSR,
gdrst | GRDOM_MEDIA | GRDOM_RESET_ENABLE);
return wait_for(I915_READ(MCHBAR_MIRROR_BASE + ILK_GDSR) & 0x1, 500);
}
static int gen6_do_reset(struct drm_device *dev)
{
struct drm_i915_private *dev_priv = dev->dev_private;
int ret;
unsigned long irqflags;
/* Hold uncore.lock across reset to prevent any register access
* with forcewake not set correctly
*/
spin_lock_irqsave(&dev_priv->uncore.lock, irqflags);
/* Reset the chip */
/* GEN6_GDRST is not in the gt power well, no need to check
* for fifo space for the write or forcewake the chip for
* the read
*/
__raw_i915_write32(dev_priv, GEN6_GDRST, GEN6_GRDOM_FULL);
/* Spin waiting for the device to ack the reset request */
ret = wait_for((__raw_i915_read32(dev_priv, GEN6_GDRST) & GEN6_GRDOM_FULL) == 0, 500);
intel_uncore_forcewake_reset(dev);
/* If reset with a user forcewake, try to restore, otherwise turn it off */
if (dev_priv->uncore.forcewake_count)
dev_priv->uncore.funcs.force_wake_get(dev_priv, FORCEWAKE_ALL);
else
dev_priv->uncore.funcs.force_wake_put(dev_priv, FORCEWAKE_ALL);
/* Restore fifo count */
dev_priv->uncore.fifo_count = __raw_i915_read32(dev_priv, GTFIFOCTL) & GT_FIFO_FREE_ENTRIES_MASK;
spin_unlock_irqrestore(&dev_priv->uncore.lock, irqflags);
return ret;
}
int intel_gpu_reset(struct drm_device *dev)
{
switch (INTEL_INFO(dev)->gen) {
case 8:
case 7:
case 6: return gen6_do_reset(dev);
case 5: return ironlake_do_reset(dev);
case 4: return i965_do_reset(dev);
default: return -ENODEV;
}
}
void intel_uncore_check_errors(struct drm_device *dev)
{
struct drm_i915_private *dev_priv = dev->dev_private;
if (HAS_FPGA_DBG_UNCLAIMED(dev) &&
(__raw_i915_read32(dev_priv, FPGA_DBG) & FPGA_DBG_RM_NOCLAIM)) {
DRM_ERROR("Unclaimed register before interrupt\n");
__raw_i915_write32(dev_priv, FPGA_DBG, FPGA_DBG_RM_NOCLAIM);
}
}