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#define _POSIX_C_SOURCE 200809L
#include <errno.h>
#include <limits.h>
#include <stdbool.h>
#include <stdlib.h>
#include <string.h>
#include <time.h>
#include <wlr/types/wlr_buffer.h>
#include "sway/config.h"
#include "sway/debug.h"
#include "sway/desktop.h"
#include "sway/desktop/idle_inhibit_v1.h"
#include "sway/desktop/transaction.h"
#include "sway/output.h"
#include "sway/tree/container.h"
#include "sway/tree/node.h"
#include "sway/tree/view.h"
#include "sway/tree/workspace.h"
#include "list.h"
#include "log.h"
struct sway_transaction {
struct wl_event_source *timer;
list_t *instructions; // struct sway_transaction_instruction *
size_t num_waiting;
size_t num_configures;
struct timespec commit_time;
};
struct sway_transaction_instruction {
struct sway_transaction *transaction;
struct sway_node *node;
union {
struct sway_output_state *output_state;
struct sway_workspace_state *workspace_state;
struct sway_container_state *container_state;
};
uint32_t serial;
};
static struct sway_transaction *transaction_create() {
struct sway_transaction *transaction =
calloc(1, sizeof(struct sway_transaction));
if (!sway_assert(transaction, "Unable to allocate transaction")) {
return NULL;
}
transaction->instructions = create_list();
return transaction;
}
static void transaction_destroy(struct sway_transaction *transaction) {
// Free instructions
for (int i = 0; i < transaction->instructions->length; ++i) {
struct sway_transaction_instruction *instruction =
transaction->instructions->items[i];
struct sway_node *node = instruction->node;
node->ntxnrefs--;
if (node->instruction == instruction) {
node->instruction = NULL;
}
if (node->destroying && node->ntxnrefs == 0) {
switch (node->type) {
case N_ROOT:
sway_assert(false, "Never reached");
break;
case N_OUTPUT:
output_destroy(node->sway_output);
break;
case N_WORKSPACE:
workspace_destroy(node->sway_workspace);
break;
case N_CONTAINER:
container_destroy(node->sway_container);
break;
}
}
free(instruction);
}
list_free(transaction->instructions);
if (transaction->timer) {
wl_event_source_remove(transaction->timer);
}
free(transaction);
}
static void copy_output_state(struct sway_output *output,
struct sway_transaction_instruction *instruction) {
struct sway_output_state *state =
calloc(1, sizeof(struct sway_output_state));
if (!state) {
wlr_log(WLR_ERROR, "Could not allocate output state");
return;
}
instruction->output_state = state;
state->workspaces = create_list();
list_cat(state->workspaces, output->workspaces);
state->active_workspace = output_get_active_workspace(output);
}
static void copy_workspace_state(struct sway_workspace *ws,
struct sway_transaction_instruction *instruction) {
struct sway_workspace_state *state =
calloc(1, sizeof(struct sway_workspace_state));
if (!state) {
wlr_log(WLR_ERROR, "Could not allocate workspace state");
return;
}
instruction->workspace_state = state;
state->fullscreen = ws->fullscreen;
state->x = ws->x;
state->y = ws->y;
state->width = ws->width;
state->height = ws->height;
state->layout = ws->layout;
state->output = ws->output;
state->floating = create_list();
state->tiling = create_list();
list_cat(state->floating, ws->floating);
list_cat(state->tiling, ws->tiling);
struct sway_seat *seat = input_manager_current_seat(input_manager);
state->focused = seat_get_focus(seat) == &ws->node;
// Set focused_inactive_child to the direct tiling child
struct sway_container *focus = seat_get_focus_inactive_tiling(seat, ws);
if (focus) {
while (focus->parent) {
focus = focus->parent;
}
}
state->focused_inactive_child = focus;
}
static void copy_container_state(struct sway_container *container,
struct sway_transaction_instruction *instruction) {
struct sway_container_state *state =
calloc(1, sizeof(struct sway_container_state));
if (!state) {
wlr_log(WLR_ERROR, "Could not allocate container state");
return;
}
instruction->container_state = state;
state->layout = container->layout;
state->con_x = container->x;
state->con_y = container->y;
state->con_width = container->width;
state->con_height = container->height;
state->is_fullscreen = container->is_fullscreen;
state->parent = container->parent;
state->workspace = container->workspace;
if (container->view) {
struct sway_view *view = container->view;
state->view_x = view->x;
state->view_y = view->y;
state->view_width = view->width;
state->view_height = view->height;
state->border = view->border;
state->border_thickness = view->border_thickness;
state->border_top = view->border_top;
state->border_left = view->border_left;
state->border_right = view->border_right;
state->border_bottom = view->border_bottom;
} else {
state->children = create_list();
list_cat(state->children, container->children);
}
struct sway_seat *seat = input_manager_current_seat(input_manager);
state->focused = seat_get_focus(seat) == &container->node;
if (!container->view) {
struct sway_node *focus =
seat_get_active_tiling_child(seat, &container->node);
state->focused_inactive_child = focus ? focus->sway_container : NULL;
}
}
static void transaction_add_node(struct sway_transaction *transaction,
struct sway_node *node) {
struct sway_transaction_instruction *instruction =
calloc(1, sizeof(struct sway_transaction_instruction));
if (!sway_assert(instruction, "Unable to allocate instruction")) {
return;
}
instruction->transaction = transaction;
instruction->node = node;
switch (node->type) {
case N_ROOT:
break;
case N_OUTPUT:
copy_output_state(node->sway_output, instruction);
break;
case N_WORKSPACE:
copy_workspace_state(node->sway_workspace, instruction);
break;
case N_CONTAINER:
copy_container_state(node->sway_container, instruction);
break;
}
list_add(transaction->instructions, instruction);
node->ntxnrefs++;
}
static void apply_output_state(struct sway_output *output,
struct sway_output_state *state) {
output_damage_whole(output);
list_free(output->current.workspaces);
memcpy(&output->current, state, sizeof(struct sway_output_state));
output_damage_whole(output);
}
static void apply_workspace_state(struct sway_workspace *ws,
struct sway_workspace_state *state) {
output_damage_whole(ws->current.output);
list_free(ws->current.floating);
list_free(ws->current.tiling);
memcpy(&ws->current, state, sizeof(struct sway_workspace_state));
output_damage_whole(ws->current.output);
}
static void apply_container_state(struct sway_container *container,
struct sway_container_state *state) {
struct sway_view *view = container->view;
// Damage the old location
desktop_damage_whole_container(container);
if (view && view->saved_buffer) {
struct wlr_box box = {
.x = container->current.view_x - view->saved_geometry.x,
.y = container->current.view_y - view->saved_geometry.y,
.width = view->saved_buffer_width,
.height = view->saved_buffer_height,
};
desktop_damage_box(&box);
}
// There are separate children lists for each instruction state, the
// container's current state and the container's pending state
// (ie. con->children). The list itself needs to be freed here.
// Any child containers which are being deleted will be cleaned up in
// transaction_destroy().
list_free(container->current.children);
memcpy(&container->current, state, sizeof(struct sway_container_state));
if (view && view->saved_buffer) {
if (!container->node.destroying || container->node.ntxnrefs == 1) {
view_remove_saved_buffer(view);
}
}
// Damage the new location
desktop_damage_whole_container(container);
if (view && view->surface) {
struct wlr_surface *surface = view->surface;
struct wlr_box box = {
.x = container->current.view_x - view->geometry.x,
.y = container->current.view_y - view->geometry.y,
.width = surface->current.width,
.height = surface->current.height,
};
desktop_damage_box(&box);
}
if (!container->node.destroying) {
container_discover_outputs(container);
}
}
/**
* Apply a transaction to the "current" state of the tree.
*/
static void transaction_apply(struct sway_transaction *transaction) {
wlr_log(WLR_DEBUG, "Applying transaction %p", transaction);
if (debug.txn_timings) {
struct timespec now;
clock_gettime(CLOCK_MONOTONIC, &now);
struct timespec *commit = &transaction->commit_time;
float ms = (now.tv_sec - commit->tv_sec) * 1000 +
(now.tv_nsec - commit->tv_nsec) / 1000000.0;
wlr_log(WLR_DEBUG, "Transaction %p: %.1fms waiting "
"(%.1f frames if 60Hz)", transaction, ms, ms / (1000.0f / 60));
}
// Apply the instruction state to the node's current state
for (int i = 0; i < transaction->instructions->length; ++i) {
struct sway_transaction_instruction *instruction =
transaction->instructions->items[i];
struct sway_node *node = instruction->node;
switch (node->type) {
case N_ROOT:
break;
case N_OUTPUT:
apply_output_state(node->sway_output, instruction->output_state);
break;
case N_WORKSPACE:
apply_workspace_state(node->sway_workspace,
instruction->workspace_state);
break;
case N_CONTAINER:
apply_container_state(node->sway_container,
instruction->container_state);
break;
}
node->instruction = NULL;
}
}
static void transaction_commit(struct sway_transaction *transaction);
// Return true if both transactions operate on the same nodes
static bool transaction_same_nodes(struct sway_transaction *a,
struct sway_transaction *b) {
if (a->instructions->length != b->instructions->length) {
return false;
}
for (int i = 0; i < a->instructions->length; ++i) {
struct sway_transaction_instruction *a_inst = a->instructions->items[i];
struct sway_transaction_instruction *b_inst = b->instructions->items[i];
if (a_inst->node != b_inst->node) {
return false;
}
}
return true;
}
static void transaction_progress_queue() {
if (!server.transactions->length) {
return;
}
// There's only ever one committed transaction,
// and it's the first one in the queue.
struct sway_transaction *transaction = server.transactions->items[0];
if (transaction->num_waiting) {
return;
}
transaction_apply(transaction);
transaction_destroy(transaction);
list_del(server.transactions, 0);
if (!server.transactions->length) {
idle_inhibit_v1_check_active(server.idle_inhibit_manager_v1);
return;
}
// If there's a bunch of consecutive transactions which all apply to the
// same views, skip all except the last one.
while (server.transactions->length >= 2) {
struct sway_transaction *a = server.transactions->items[0];
struct sway_transaction *b = server.transactions->items[1];
if (transaction_same_nodes(a, b)) {
list_del(server.transactions, 0);
transaction_destroy(a);
} else {
break;
}
}
transaction = server.transactions->items[0];
transaction_commit(transaction);
transaction_progress_queue();
}
static int handle_timeout(void *data) {
struct sway_transaction *transaction = data;
wlr_log(WLR_DEBUG, "Transaction %p timed out (%li waiting)",
transaction, transaction->num_waiting);
transaction->num_waiting = 0;
transaction_progress_queue();
return 0;
}
static bool should_configure(struct sway_node *node,
struct sway_transaction_instruction *instruction) {
if (!node_is_view(node)) {
return false;
}
if (node->destroying) {
return false;
}
struct sway_container_state *cstate = &node->sway_container->current;
struct sway_container_state *istate = instruction->container_state;
#ifdef HAVE_XWAYLAND
// Xwayland views are position-aware and need to be reconfigured
// when their position changes.
if (node->sway_container->view->type == SWAY_VIEW_XWAYLAND) {
if (cstate->view_x != istate->view_x ||
cstate->view_y != istate->view_y) {
return true;
}
}
#endif
if (cstate->view_width == istate->view_width &&
cstate->view_height == istate->view_height) {
return false;
}
return true;
}
static void transaction_commit(struct sway_transaction *transaction) {
wlr_log(WLR_DEBUG, "Transaction %p committing with %i instructions",
transaction, transaction->instructions->length);
transaction->num_waiting = 0;
for (int i = 0; i < transaction->instructions->length; ++i) {
struct sway_transaction_instruction *instruction =
transaction->instructions->items[i];
struct sway_node *node = instruction->node;
if (should_configure(node, instruction)) {
instruction->serial = view_configure(node->sway_container->view,
instruction->container_state->view_x,
instruction->container_state->view_y,
instruction->container_state->view_width,
instruction->container_state->view_height);
++transaction->num_waiting;
// From here on we are rendering a saved buffer of the view, which
// means we can send a frame done event to make the client redraw it
// as soon as possible. Additionally, this is required if a view is
// mapping and its default geometry doesn't intersect an output.
struct timespec when;
wlr_surface_send_frame_done(
node->sway_container->view->surface, &when);
}
if (node_is_view(node) && !node->sway_container->view->saved_buffer) {
view_save_buffer(node->sway_container->view);
memcpy(&node->sway_container->view->saved_geometry,
&node->sway_container->view->geometry,
sizeof(struct wlr_box));
}
node->instruction = instruction;
}
transaction->num_configures = transaction->num_waiting;
if (debug.txn_timings) {
clock_gettime(CLOCK_MONOTONIC, &transaction->commit_time);
}
if (debug.noatomic) {
transaction->num_waiting = 0;
} else if (debug.txn_wait) {
// Force the transaction to time out even if all views are ready.
// We do this by inflating the waiting counter.
transaction->num_waiting += 1000000;
}
if (transaction->num_waiting) {
// Set up a timer which the views must respond within
transaction->timer = wl_event_loop_add_timer(server.wl_event_loop,
handle_timeout, transaction);
if (transaction->timer) {
wl_event_source_timer_update(transaction->timer,
server.txn_timeout_ms);
} else {
wlr_log(WLR_ERROR, "Unable to create transaction timer (%s). "
"Some imperfect frames might be rendered.",
strerror(errno));
transaction->num_waiting = 0;
}
}
// The debug tree shows the pending/live tree. Here is a good place to
// update it, because we make a transaction every time we change the pending
// tree.
update_debug_tree();
}
static void set_instruction_ready(
struct sway_transaction_instruction *instruction) {
struct sway_transaction *transaction = instruction->transaction;
if (debug.txn_timings) {
struct timespec now;
clock_gettime(CLOCK_MONOTONIC, &now);
struct timespec *start = &transaction->commit_time;
float ms = (now.tv_sec - start->tv_sec) * 1000 +
(now.tv_nsec - start->tv_nsec) / 1000000.0;
wlr_log(WLR_DEBUG, "Transaction %p: %li/%li ready in %.1fms (%s)",
transaction,
transaction->num_configures - transaction->num_waiting + 1,
transaction->num_configures, ms,
instruction->node->sway_container->title);
}
// If the transaction has timed out then its num_waiting will be 0 already.
if (transaction->num_waiting > 0 && --transaction->num_waiting == 0) {
wlr_log(WLR_DEBUG, "Transaction %p is ready", transaction);
wl_event_source_timer_update(transaction->timer, 0);
}
instruction->node->instruction = NULL;
transaction_progress_queue();
}
void transaction_notify_view_ready_by_serial(struct sway_view *view,
uint32_t serial) {
struct sway_transaction_instruction *instruction =
view->container->node.instruction;
if (instruction->serial == serial) {
set_instruction_ready(instruction);
}
}
void transaction_notify_view_ready_by_size(struct sway_view *view,
int width, int height) {
struct sway_transaction_instruction *instruction =
view->container->node.instruction;
if (instruction->container_state->view_width == width &&
instruction->container_state->view_height == height) {
set_instruction_ready(instruction);
}
}
void transaction_commit_dirty(void) {
if (!server.dirty_nodes->length) {
return;
}
struct sway_transaction *transaction = transaction_create();
if (!transaction) {
return;
}
for (int i = 0; i < server.dirty_nodes->length; ++i) {
struct sway_node *node = server.dirty_nodes->items[i];
transaction_add_node(transaction, node);
node->dirty = false;
}
server.dirty_nodes->length = 0;
list_add(server.transactions, transaction);
// There's only ever one committed transaction,
// and it's the first one in the queue.
if (server.transactions->length == 1) {
transaction_commit(transaction);
// Attempting to progress the queue here is useful
// if the transaction has nothing to wait for.
transaction_progress_queue();
}
}