libliftoff/alloc.c

#include <assert.h>
#include <errno.h>
#include <inttypes.h>
#include <limits.h>
#include <stdlib.h>
#include <string.h>
#include <unistd.h>
#include "log.h"
#include "private.h"

/* Plane allocation algorithm
 *
 * Goal: KMS exposes a set of hardware planes, user submitted a set of layers.
 * We want to map as many layers as possible to planes.
 *
 * However, all layers can't be mapped to any plane. There are constraints,
 * sometimes depending on driver-specific limitations or the configuration of
 * other planes.
 *
 * The only way to discover driver-specific limitations is via an atomic test
 * commit: we submit a plane configuration, and KMS replies whether it's
 * supported or not. Thus we need to incrementally build a valid configuration.
 *
 * Let's take an example with 2 planes and 3 layers. Plane 1 is only compatible
 * with layer 2 and plane 2 is only compatible with layer 3. Our algorithm will
 * discover the solution by building the mapping one plane at a time. It first
 * starts with plane 1: an atomic commit assigning layer 1 to plane 1 is
 * submitted. It fails, because this isn't supported by the driver. Then layer
 * 2 is assigned to plane 1 and the atomic test succeeds. We can go on and
 * repeat the operation with plane 2. After exploring the whole tree, we end up
 * with a valid allocation.
 *
 *
 *                    layer 1                 layer 1
 *                  +---------> failure     +---------> failure
 *                  |                       |
 *                  |                       |
 *                  |                       |
 *     +---------+  |          +---------+  |
 *     |         |  | layer 2  |         |  | layer 3   final allocation:
 *     | plane 1 +------------>+ plane 2 +--+---------> plane 1 → layer 2
 *     |         |  |          |         |              plane 2 → layer 3
 *     +---------+  |          +---------+
 *                  |
 *                  |
 *                  | layer 3
 *                  +---------> failure
 *
 *
 * Note how layer 2 isn't considered for plane 2: it's already mapped to plane
 * 1. Also note that branches are pruned as soon as an atomic test fails.
 *
 * In practice, the primary plane is treated separately. This is where layers
 * that can't be mapped to any plane (e.g. layer 1 in our example) will be
 * composited. The primary plane is the first that will be allocated. Then all
 * other planes will be allocated, from the topmost one to the bottommost one.
 *
 * The "zpos" property (which defines ordering between layers/planes) is handled
 * as a special case. If it's set on layers, it adds additional constraints on
 * their relative ordering. If two layers intersect, their relative zpos needs
 * to be preserved during plane allocation.
 *
 * Implementation-wise, the output_choose_layers function is called at each node
 * of the tree. It iterates over layers, check constraints, performs an atomic
 * test commit and calls itself recursively on the next plane.
 */

/* Global data for the allocation algorithm */
struct alloc_result {
	drmModeAtomicReq *req;
	size_t planes_len;

	struct liftoff_layer **best;
	int best_score;

	/* per-output */
	bool has_composition_layer;
	size_t non_composition_layers_len;
};

/* Transient data, arguments for each step */
struct alloc_step {
	struct liftoff_list *plane_link; /* liftoff_plane.link */
	size_t plane_idx;

	struct liftoff_layer **alloc; /* only items up to plane_idx are valid */
	int score; /* number of allocated layers */
	int last_layer_zpos;

	bool composited; /* per-output */
};

static void plane_step_init_next(struct alloc_step *step,
				 struct alloc_step *prev,
				 struct liftoff_layer *layer)
{
	struct liftoff_plane *plane;
	struct liftoff_layer_property *zpos_prop;

	plane = liftoff_container_of(prev->plane_link, plane, link);

	step->plane_link = prev->plane_link->next;
	step->plane_idx = prev->plane_idx + 1;
	step->alloc = prev->alloc;
	step->alloc[prev->plane_idx] = layer;

	if (layer != NULL && layer == layer->output->composition_layer) {
		assert(!prev->composited);
		step->composited = true;
	} else {
		step->composited = prev->composited;
	}

	if (layer != NULL && layer != layer->output->composition_layer) {
		step->score = prev->score + 1;
	} else {
		step->score = prev->score;
	}

	zpos_prop = NULL;
	if (layer != NULL) {
		zpos_prop = layer_get_property(layer, "zpos");
	}
	if (zpos_prop != NULL && plane->type != DRM_PLANE_TYPE_PRIMARY) {
		step->last_layer_zpos = zpos_prop->value;
	} else {
		step->last_layer_zpos = prev->last_layer_zpos;
	}
}

static bool is_layer_allocated(struct alloc_step *step,
			       struct liftoff_layer *layer)
{
	size_t i;

	/* TODO: speed this up with an array of bools indicating whether a layer
	 * has been allocated */
	for (i = 0; i < step->plane_idx; i++) {
		if (step->alloc[i] == layer) {
			return true;
		}
	}
	return false;
}

static bool has_composited_layer_over(struct liftoff_output *output,
				      struct alloc_step *step,
				      struct liftoff_layer *layer)
{
	struct liftoff_layer *other_layer;
	struct liftoff_layer_property *zpos_prop, *other_zpos_prop;

	zpos_prop = layer_get_property(layer, "zpos");
	if (zpos_prop == NULL) {
		return false;
	}

	liftoff_list_for_each(other_layer, &output->layers, link) {
		if (is_layer_allocated(step, other_layer)) {
			continue;
		}

		other_zpos_prop = layer_get_property(other_layer, "zpos");
		if (other_zpos_prop == NULL) {
			continue;
		}

		if (layer_intersects(layer, other_layer) &&
		    other_zpos_prop->value > zpos_prop->value) {
			return true;
		}
	}

	return false;
}

static bool has_allocated_layer_over(struct liftoff_output *output,
				     struct alloc_step *step,
				     struct liftoff_layer *layer)
{
	ssize_t i;
	struct liftoff_plane *other_plane;
	struct liftoff_layer *other_layer;
	struct liftoff_layer_property *zpos_prop, *other_zpos_prop;

	zpos_prop = layer_get_property(layer, "zpos");
	if (zpos_prop == NULL) {
		return false;
	}

	i = -1;
	liftoff_list_for_each(other_plane, &output->device->planes, link) {
		i++;
		if (i >= (ssize_t)step->plane_idx) {
			break;
		}
		if (other_plane->type == DRM_PLANE_TYPE_PRIMARY) {
			continue;
		}

		other_layer = step->alloc[i];
		if (other_layer == NULL) {
			continue;
		}

		other_zpos_prop = layer_get_property(other_layer, "zpos");
		if (other_zpos_prop == NULL) {
			continue;
		}

		/* Since plane zpos is descending, this means the other layer is
		 * supposed to be under but is mapped to a plane over the
		 * current one. */
		if (zpos_prop->value > other_zpos_prop->value &&
		    layer_intersects(layer, other_layer)) {
			return true;
		}
	}

	return false;
}

static bool has_allocated_plane_under(struct liftoff_output *output,
				      struct alloc_step *step,
				      struct liftoff_layer *layer)
{
	struct liftoff_plane *plane, *other_plane;
	ssize_t i;

	plane = liftoff_container_of(step->plane_link, plane, link);

	i = -1;
	liftoff_list_for_each(other_plane, &output->device->planes, link) {
		i++;
		if (i >= (ssize_t)step->plane_idx) {
			break;
		}
		if (other_plane->type == DRM_PLANE_TYPE_PRIMARY) {
			continue;
		}
		if (step->alloc[i] == NULL) {
			continue;
		}

		if (plane->zpos >= other_plane->zpos &&
		    layer_intersects(layer, step->alloc[i])) {
			return true;
		}
	}

	return false;
}

bool check_layer_plane_compatible(struct alloc_step *step,
				  struct liftoff_layer *layer,
				  struct liftoff_plane *plane)
{
	struct liftoff_output *output;
	struct liftoff_layer_property *zpos_prop;

	output = layer->output;

	/* Skip this layer if already allocated */
	if (is_layer_allocated(step, layer)) {
		return false;
	}

	zpos_prop = layer_get_property(layer, "zpos");
	if (zpos_prop != NULL) {
		if ((int)zpos_prop->value > step->last_layer_zpos &&
		    has_allocated_layer_over(output, step, layer)) {
			/* This layer needs to be on top of the last
			 * allocated one */
			liftoff_log(LIFTOFF_DEBUG,
				    "Layer %p -> plane %"PRIu32": "
				    "layer zpos invalid",
				    (void *)layer, plane->id);
			return false;
		}
		if ((int)zpos_prop->value < step->last_layer_zpos &&
		    has_allocated_plane_under(output, step, layer)) {
			/* This layer needs to be under the last
			 * allocated one, but this plane isn't under the
			 * last one (in practice, since planes are
			 * sorted by zpos it means it has the same zpos,
			 * ie. undefined ordering). */
			liftoff_log(LIFTOFF_DEBUG,
				    "Layer %p -> plane %"PRIu32": "
				    "plane zpos invalid",
				    (void *)layer, plane->id);
			return false;
		}
	}

	if (plane->type != DRM_PLANE_TYPE_PRIMARY &&
	    has_composited_layer_over(output, step, layer)) {
		liftoff_log(LIFTOFF_DEBUG,
			    "Layer %p -> plane %"PRIu32": "
			    "has composited layer on top",
			    (void *)layer, plane->id);
		return false;
	}

	if (plane->type != DRM_PLANE_TYPE_PRIMARY &&
	    layer == layer->output->composition_layer) {
		liftoff_log(LIFTOFF_DEBUG,
			    "Layer %p -> plane %"PRIu32": "
			    "cannot put composition layer on "
			    "non-primary plane",
			    (void *)layer, plane->id);
		return false;
	}

	return true;
}

bool check_alloc_valid(struct alloc_result *result, struct alloc_step *step)
{
	/* If composition isn't used, we need to have allocated all
	 * layers. */
	/* TODO: find a way to fail earlier, e.g. when the number of
	 * layers exceeds the number of planes. */
	if (result->has_composition_layer && !step->composited &&
	    step->score != (int)result->non_composition_layers_len) {
		liftoff_log(LIFTOFF_DEBUG,
			    "Cannot skip composition: some layers "
			    "are missing a plane");
		return false;
	}
	/* On the other hand, if we manage to allocate all layers, we
	 * don't want to use composition. We don't want to use the
	 * composition layer at all. */
	if (step->composited &&
	    step->score == (int)result->non_composition_layers_len) {
		liftoff_log(LIFTOFF_DEBUG,
			    "Refusing to use composition: all layers "
			    "have been put in a plane");
		return false;
	}

	/* TODO: check allocation isn't empty */

	return true;
}

static bool device_test_commit(struct liftoff_device *device,
				drmModeAtomicReq *req, bool *compatible)
{
	int ret;

	ret = drmModeAtomicCommit(device->drm_fd, req,
				  DRM_MODE_ATOMIC_TEST_ONLY, NULL);
	if (ret == 0) {
		*compatible = true;
	} else if (-ret == EINVAL || -ret == ERANGE) {
		*compatible = false;
	} else {
		liftoff_log_errno(LIFTOFF_ERROR, "drmModeAtomicCommit");
		*compatible = false;
		return false;
	}

	return true;
}

bool output_choose_layers(struct liftoff_output *output,
			  struct alloc_result *result, struct alloc_step *step)
{
	struct liftoff_device *device;
	struct liftoff_plane *plane;
	struct liftoff_layer *layer;
	int cursor;
	size_t remaining_planes;
	bool compatible;
	struct alloc_step next_step;

	device = output->device;

	if (step->plane_link == &device->planes) { /* Allocation finished */
		if (step->score > result->best_score &&
		    check_alloc_valid(result, step)) {
			/* We found a better allocation */
			liftoff_log(LIFTOFF_DEBUG,
				    "Found a better allocation with score=%d",
				    step->score);
			result->best_score = step->score;
			memcpy(result->best, step->alloc,
			       result->planes_len * sizeof(struct liftoff_layer *));
		}
		return true;
	}

	plane = liftoff_container_of(step->plane_link, plane, link);

	remaining_planes = result->planes_len - step->plane_idx;
	if (result->best_score >= step->score + (int)remaining_planes) {
		/* Even if we find a layer for all remaining planes, we won't
		 * find a better allocation. Give up. */
		/* TODO: change remaining_planes to only count those whose
		 * possible CRTC match and which aren't allocated */
		return true;
	}

	cursor = drmModeAtomicGetCursor(result->req);

	if (plane->layer != NULL) {
		goto skip;
	}
	if ((plane->possible_crtcs & (1 << output->crtc_index)) == 0) {
		goto skip;
	}

	liftoff_log(LIFTOFF_DEBUG,
		    "Performing allocation for plane %"PRIu32" (%zu/%zu)",
		    plane->id, step->plane_idx + 1, result->planes_len);

	liftoff_list_for_each(layer, &output->layers, link) {
		if (layer->plane != NULL || layer->force_composition) {
			continue;
		}
		if (!layer_has_fb(layer)) {
			continue; /* no FB set, nothing to display */
		}
		if (!check_layer_plane_compatible(step, layer, plane)) {
			continue;
		}

		/* Try to use this layer for the current plane */
		liftoff_log(LIFTOFF_DEBUG, "Layer %p -> plane %"PRIu32": "
			    "applying properties...",
			    (void *)layer, plane->id);
		if (!plane_apply(plane, layer, result->req, &compatible)) {
			return false;
		}
		if (!compatible) {
			liftoff_log(LIFTOFF_DEBUG,
				    "Layer %p -> plane %"PRIu32": "
				    "incompatible properties",
				    (void *)layer, plane->id);
			continue;
		}

		if (!device_test_commit(device, result->req, &compatible)) {
			return false;
		}
		if (compatible) {
			liftoff_log(LIFTOFF_DEBUG,
				    "Layer %p -> plane %"PRIu32": success",
				    (void *)layer, plane->id);
			/* Continue with the next plane */
			plane_step_init_next(&next_step, step, layer);
			if (!output_choose_layers(output, result, &next_step)) {
				return false;
			}
		}

		drmModeAtomicSetCursor(result->req, cursor);
	}

skip:
	/* Try not to use the current plane */
	plane_step_init_next(&next_step, step, NULL);
	if (!output_choose_layers(output, result, &next_step)) {
		return false;
	}
	drmModeAtomicSetCursor(result->req, cursor);

	return true;
}

static bool apply_current(struct liftoff_device *device,
			  drmModeAtomicReq *req)
{
	struct liftoff_plane *plane;
	int cursor;
	bool compatible;

	cursor = drmModeAtomicGetCursor(req);

	liftoff_list_for_each(plane, &device->planes, link) {
		if (!plane_apply(plane, plane->layer, req, &compatible)) {
			drmModeAtomicSetCursor(req, cursor);
			return false;
		}
		assert(compatible);
	}

	return true;
}

static bool layer_needs_realloc(struct liftoff_layer *layer)
{
	size_t i;
	struct liftoff_layer_property *prop;

	for (i = 0; i < layer->props_len; i++) {
		prop = &layer->props[i];
		if (!prop->changed) {
			continue;
		}
		if (strcmp(prop->name, "FB_ID") == 0) {
			if (layer->force_composition) {
				return true;
			}
			/* TODO: check format/modifier is the same. Check
			 * previous/next value isn't zero. */
			continue;
		}

		/* TODO: if CRTC_{X,Y,W,H} changed but intersection with other
		 * layers hasn't changed, don't realloc */
		return true;
	}

	return false;
}

static bool reuse_previous_alloc(struct liftoff_output *output,
				 drmModeAtomicReq *req)
{
	struct liftoff_device *device;
	struct liftoff_layer *layer;
	int cursor;
	bool compatible;

	device = output->device;

	if (output->layers_changed) {
		return false;
	}

	liftoff_list_for_each(layer, &output->layers, link) {
		if (layer_needs_realloc(layer)) {
			return false;
		}
	}

	cursor = drmModeAtomicGetCursor(req);

	if (!apply_current(device, req)) {
		return false;
	}
	if (!device_test_commit(device, req, &compatible) || !compatible) {
		drmModeAtomicSetCursor(req, cursor);
		return false;
	}

	return true;
}

static void mark_layers_clean(struct liftoff_output *output)
{
	struct liftoff_layer *layer;

	output->layers_changed = false;

	liftoff_list_for_each(layer, &output->layers, link) {
		layer_mark_clean(layer);
	}
}

static void update_layers_priority(struct liftoff_device *device)
{
	struct liftoff_output *output;
	struct liftoff_layer *layer;

	device->page_flip_counter++;
	bool period_elapsed =
		device->page_flip_counter >= LIFTOFF_PRIORITY_PERIOD;
	if (period_elapsed) {
		device->page_flip_counter = 0;
	}

	liftoff_list_for_each(output, &device->outputs, link) {
		liftoff_list_for_each(layer, &output->layers, link) {
			layer_update_priority(layer, period_elapsed);
		}
	}
}

bool liftoff_output_apply(struct liftoff_output *output, drmModeAtomicReq *req)
{
	struct liftoff_device *device;
	struct liftoff_plane *plane;
	struct liftoff_layer *layer;
	struct alloc_result result;
	struct alloc_step step;
	size_t i;
	bool compatible;

	device = output->device;

	update_layers_priority(device);

	if (reuse_previous_alloc(output, req)) {
		liftoff_log(LIFTOFF_DEBUG, "Re-using previous plane allocation");
		return true;
	}

	output_log_layers(output);

	/* Unset all existing plane and layer mappings. */
	liftoff_list_for_each(plane, &device->planes, link) {
		if (plane->layer != NULL && plane->layer->output == output) {
			plane->layer->plane = NULL;
			plane->layer = NULL;
		}
	}

	/* Disable all planes. Do it before building mappings to make sure not
	   to hit bandwidth limits because too many planes are enabled. */
	liftoff_list_for_each(plane, &device->planes, link) {
		if (plane->layer == NULL) {
			liftoff_log(LIFTOFF_DEBUG,
				    "Disabling plane %d", plane->id);
			if (!plane_apply(plane, NULL, req, &compatible)) {
				return false;
			}
			assert(compatible);
		}
	}

	result.req = req;
	result.planes_len = liftoff_list_length(&device->planes);

	step.alloc = malloc(result.planes_len * sizeof(*step.alloc));
	result.best = malloc(result.planes_len * sizeof(*result.best));
	if (step.alloc == NULL || result.best == NULL) {
		liftoff_log_errno(LIFTOFF_ERROR, "malloc");
		return false;
	}

	/* For each plane, try to find a layer. Don't do it the other
	 * way around (ie. for each layer, try to find a plane) because
	 * some drivers want user-space to enable the primary plane
	 * before any other plane. */

	result.best_score = -1;
	memset(result.best, 0, result.planes_len * sizeof(*result.best));
	result.has_composition_layer = output->composition_layer != NULL;
	result.non_composition_layers_len =
		liftoff_list_length(&output->layers);
	if (output->composition_layer != NULL) {
		result.non_composition_layers_len--;
	}
	step.plane_link = device->planes.next;
	step.plane_idx = 0;
	step.score = 0;
	step.last_layer_zpos = INT_MAX;
	step.composited = false;
	if (!output_choose_layers(output, &result, &step)) {
		return false;
	}

	liftoff_log(LIFTOFF_DEBUG,
		    "Found plane allocation for output %p with "
		    "score=%d", (void *)output, result.best_score);

	/* Apply the best allocation */
	i = 0;
	liftoff_list_for_each(plane, &device->planes, link) {
		layer = result.best[i];
		i++;
		if (layer == NULL) {
			continue;
		}

		liftoff_log(LIFTOFF_DEBUG,
			    "Assigning layer %p to plane %"PRIu32,
			    (void *)layer, plane->id);

		assert(plane->layer == NULL);
		assert(layer->plane == NULL);
		plane->layer = layer;
		layer->plane = plane;
	}

	if (!apply_current(device, req)) {
		return false;
	}

	free(step.alloc);
	free(result.best);

	mark_layers_clean(output);

	return true;
}