1 files changed, 303 insertions, 0 deletions
diff --git a/driver/product/kernel/drivers/gpu/arm/midgard/backend/gpu/mali_kbase_js_affinity.c b/driver/product/kernel/drivers/gpu/arm/midgard/backend/gpu/mali_kbase_js_affinity.c
new file mode 100755
index 0000000..54d8ddd
--- /dev/null
+++ b/driver/product/kernel/drivers/gpu/arm/midgard/backend/gpu/mali_kbase_js_affinity.c
@@ -0,0 +1,303 @@
+/*
+ *
+ * (C) COPYRIGHT 2010-2016 ARM Limited. All rights reserved.
+ *
+ * This program is free software and is provided to you under the terms of the
+ * GNU General Public License version 2 as published by the Free Software
+ * Foundation, and any use by you of this program is subject to the terms
+ * of such GNU licence.
+ *
+ * A copy of the licence is included with the program, and can also be obtained
+ * from Free Software Foundation, Inc., 51 Franklin Street, Fifth Floor,
+ * Boston, MA  02110-1301, USA.
+ *
+ */
+
+
+
+
+
+/*
+ * Base kernel affinity manager APIs
+ */
+
+#include <mali_kbase.h>
+#include "mali_kbase_js_affinity.h"
+#include "mali_kbase_hw.h"
+
+#include <backend/gpu/mali_kbase_pm_internal.h>
+
+
+bool kbase_js_can_run_job_on_slot_no_lock(struct kbase_device *kbdev,
+									int js)
+{
+	/*
+	 * Here are the reasons for using job slot 2:
+	 * - BASE_HW_ISSUE_8987 (which is entirely used for that purpose)
+	 * - In absence of the above, then:
+	 *  - Atoms with BASE_JD_REQ_COHERENT_GROUP
+	 *  - But, only when there aren't contexts with
+	 *  KBASEP_JS_CTX_ATTR_COMPUTE_ALL_CORES, because the atoms that run on
+	 *  all cores on slot 1 could be blocked by those using a coherent group
+	 *  on slot 2
+	 *  - And, only when you actually have 2 or more coregroups - if you
+	 *  only have 1 coregroup, then having jobs for slot 2 implies they'd
+	 *  also be for slot 1, meaning you'll get interference from them. Jobs
+	 *  able to run on slot 2 could also block jobs that can only run on
+	 *  slot 1 (tiler jobs)
+	 */
+	if (kbase_hw_has_issue(kbdev, BASE_HW_ISSUE_8987))
+		return true;
+
+	if (js != 2)
+		return true;
+
+	/* Only deal with js==2 now: */
+	if (kbdev->gpu_props.num_core_groups > 1) {
+		/* Only use slot 2 in the 2+ coregroup case */
+		if (kbasep_js_ctx_attr_is_attr_on_runpool(kbdev,
+					KBASEP_JS_CTX_ATTR_COMPUTE_ALL_CORES) ==
+								false) {
+			/* ...But only when we *don't* have atoms that run on
+			 * all cores */
+
+			/* No specific check for BASE_JD_REQ_COHERENT_GROUP
+			 * atoms - the policy will sort that out */
+			return true;
+		}
+	}
+
+	/* Above checks failed mean we shouldn't use slot 2 */
+	return false;
+}
+
+/*
+ * As long as it has been decided to have a deeper modification of
+ * what job scheduler, power manager and affinity manager will
+ * implement, this function is just an intermediate step that
+ * assumes:
+ * - all working cores will be powered on when this is called.
+ * - largest current configuration is 2 core groups.
+ * - It has been decided not to have hardcoded values so the low
+ *   and high cores in a core split will be evently distributed.
+ * - Odd combinations of core requirements have been filtered out
+ *   and do not get to this function (e.g. CS+T+NSS is not
+ *   supported here).
+ * - This function is frequently called and can be optimized,
+ *   (see notes in loops), but as the functionallity will likely
+ *   be modified, optimization has not been addressed.
+*/
+bool kbase_js_choose_affinity(u64 * const affinity,
+					struct kbase_device *kbdev,
+					struct kbase_jd_atom *katom, int js)
+{
+	base_jd_core_req core_req = katom->core_req;
+	unsigned int num_core_groups = kbdev->gpu_props.num_core_groups;
+	u64 core_availability_mask;
+
+	lockdep_assert_held(&kbdev->hwaccess_lock);
+
+	core_availability_mask = kbase_pm_ca_get_core_mask(kbdev);
+
+	/*
+	 * If no cores are currently available (core availability policy is
+	 * transitioning) then fail.
+	 */
+	if (0 == core_availability_mask) {
+		*affinity = 0;
+		return false;
+	}
+
+	KBASE_DEBUG_ASSERT(js >= 0);
+
+	if ((core_req & (BASE_JD_REQ_FS | BASE_JD_REQ_CS | BASE_JD_REQ_T)) ==
+								BASE_JD_REQ_T) {
+		 /* If the hardware supports XAFFINITY then we'll only enable
+		  * the tiler (which is the default so this is a no-op),
+		  * otherwise enable shader core 0. */
+		if (!kbase_hw_has_feature(kbdev, BASE_HW_FEATURE_XAFFINITY))
+			*affinity = 1;
+		else
+			*affinity = 0;
+
+		return true;
+	}
+
+	if (1 == kbdev->gpu_props.num_cores) {
+		/* trivial case only one core, nothing to do */
+		*affinity = core_availability_mask &
+				kbdev->pm.debug_core_mask[js];
+	} else {
+		if ((core_req & (BASE_JD_REQ_COHERENT_GROUP |
+					BASE_JD_REQ_SPECIFIC_COHERENT_GROUP))) {
+			if (js == 0 || num_core_groups == 1) {
+				/* js[0] and single-core-group systems just get
+				 * the first core group */
+				*affinity =
+				kbdev->gpu_props.props.coherency_info.group[0].core_mask
+						& core_availability_mask &
+						kbdev->pm.debug_core_mask[js];
+			} else {
+				/* js[1], js[2] use core groups 0, 1 for
+				 * dual-core-group systems */
+				u32 core_group_idx = ((u32) js) - 1;
+
+				KBASE_DEBUG_ASSERT(core_group_idx <
+							num_core_groups);
+				*affinity =
+				kbdev->gpu_props.props.coherency_info.group[core_group_idx].core_mask
+						& core_availability_mask &
+						kbdev->pm.debug_core_mask[js];
+
+				/* If the job is specifically targeting core
+				 * group 1 and the core availability policy is
+				 * keeping that core group off, then fail */
+				if (*affinity == 0 && core_group_idx == 1 &&
+						kbdev->pm.backend.cg1_disabled
+								== true)
+					katom->event_code =
+							BASE_JD_EVENT_PM_EVENT;
+			}
+		} else {
+			/* All cores are available when no core split is
+			 * required */
+			*affinity = core_availability_mask &
+					kbdev->pm.debug_core_mask[js];
+		}
+	}
+
+	/*
+	 * If no cores are currently available in the desired core group(s)
+	 * (core availability policy is transitioning) then fail.
+	 */
+	if (*affinity == 0)
+		return false;
+
+	/* Enable core 0 if tiler required for hardware without XAFFINITY
+	 * support (notes above) */
+	if (core_req & BASE_JD_REQ_T) {
+		if (!kbase_hw_has_feature(kbdev, BASE_HW_FEATURE_XAFFINITY))
+			*affinity = *affinity | 1;
+	}
+
+	return true;
+}
+
+static inline bool kbase_js_affinity_is_violating(
+						struct kbase_device *kbdev,
+								u64 *affinities)
+{
+	/* This implementation checks whether the two slots involved in Generic
+	 * thread creation have intersecting affinity. This is due to micro-
+	 * architectural issues where a job in slot A targetting cores used by
+	 * slot B could prevent the job in slot B from making progress until the
+	 * job in slot A has completed.
+	 */
+	u64 affinity_set_left;
+	u64 affinity_set_right;
+	u64 intersection;
+
+	KBASE_DEBUG_ASSERT(affinities != NULL);
+
+	affinity_set_left = affinities[1];
+
+	affinity_set_right = affinities[2];
+
+	/* A violation occurs when any bit in the left_set is also in the
+	 * right_set */
+	intersection = affinity_set_left & affinity_set_right;
+
+	return (bool) (intersection != (u64) 0u);
+}
+
+bool kbase_js_affinity_would_violate(struct kbase_device *kbdev, int js,
+								u64 affinity)
+{
+	struct kbasep_js_device_data *js_devdata;
+	u64 new_affinities[BASE_JM_MAX_NR_SLOTS];
+
+	KBASE_DEBUG_ASSERT(kbdev != NULL);
+	KBASE_DEBUG_ASSERT(js < BASE_JM_MAX_NR_SLOTS);
+	js_devdata = &kbdev->js_data;
+
+	memcpy(new_affinities, js_devdata->runpool_irq.slot_affinities,
+			sizeof(js_devdata->runpool_irq.slot_affinities));
+
+	new_affinities[js] |= affinity;
+
+	return kbase_js_affinity_is_violating(kbdev, new_affinities);
+}
+
+void kbase_js_affinity_retain_slot_cores(struct kbase_device *kbdev, int js,
+								u64 affinity)
+{
+	struct kbasep_js_device_data *js_devdata;
+	u64 cores;
+
+	KBASE_DEBUG_ASSERT(kbdev != NULL);
+	KBASE_DEBUG_ASSERT(js < BASE_JM_MAX_NR_SLOTS);
+	js_devdata = &kbdev->js_data;
+
+	KBASE_DEBUG_ASSERT(kbase_js_affinity_would_violate(kbdev, js, affinity)
+								== false);
+
+	cores = affinity;
+	while (cores) {
+		int bitnum = fls64(cores) - 1;
+		u64 bit = 1ULL << bitnum;
+		s8 cnt;
+
+		cnt =
+		++(js_devdata->runpool_irq.slot_affinity_refcount[js][bitnum]);
+
+		if (cnt == 1)
+			js_devdata->runpool_irq.slot_affinities[js] |= bit;
+
+		cores &= ~bit;
+	}
+}
+
+void kbase_js_affinity_release_slot_cores(struct kbase_device *kbdev, int js,
+								u64 affinity)
+{
+	struct kbasep_js_device_data *js_devdata;
+	u64 cores;
+
+	KBASE_DEBUG_ASSERT(kbdev != NULL);
+	KBASE_DEBUG_ASSERT(js < BASE_JM_MAX_NR_SLOTS);
+	js_devdata = &kbdev->js_data;
+
+	cores = affinity;
+	while (cores) {
+		int bitnum = fls64(cores) - 1;
+		u64 bit = 1ULL << bitnum;
+		s8 cnt;
+
+		KBASE_DEBUG_ASSERT(
+		js_devdata->runpool_irq.slot_affinity_refcount[js][bitnum] > 0);
+
+		cnt =
+		--(js_devdata->runpool_irq.slot_affinity_refcount[js][bitnum]);
+
+		if (0 == cnt)
+			js_devdata->runpool_irq.slot_affinities[js] &= ~bit;
+
+		cores &= ~bit;
+	}
+}
+
+#if KBASE_TRACE_ENABLE
+void kbase_js_debug_log_current_affinities(struct kbase_device *kbdev)
+{
+	struct kbasep_js_device_data *js_devdata;
+	int slot_nr;
+
+	KBASE_DEBUG_ASSERT(kbdev != NULL);
+	js_devdata = &kbdev->js_data;
+
+	for (slot_nr = 0; slot_nr < 3; ++slot_nr)
+		KBASE_TRACE_ADD_SLOT_INFO(kbdev, JS_AFFINITY_CURRENT, NULL,
+							NULL, 0u, slot_nr,
+			(u32) js_devdata->runpool_irq.slot_affinities[slot_nr]);
+}
+#endif				/* KBASE_TRACE_ENABLE  */