/* -*- Mode: C; c-basic-offset: 4; indent-tabs-mode: nil -*- */
/*
Copyright (C) 2009 Red Hat, Inc.
This library is free software; you can redistribute it and/or
modify it under the terms of the GNU Lesser General Public
License as published by the Free Software Foundation; either
version 2.1 of the License, or (at your option) any later version.
This library is distributed in the hope that it will be useful,
but WITHOUT ANY WARRANTY; without even the implied warranty of
MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the GNU
Lesser General Public License for more details.
You should have received a copy of the GNU Lesser General Public
License along with this library; if not, see .
*/
#ifdef HAVE_CONFIG_H
#include
#endif
#define SPICE_LOG_DOMAIN "SpiceWorker"
/* Common variable abberiviations:
*
* rcc - RedChannelClient
* ccc - CursorChannelClient (not to be confused with common_cc)
* common_cc - CommonChannelClient
* dcc - DisplayChannelClient
* cursor_red_channel - downcast of CursorChannel to RedChannel
* display_red_channel - downcast of DisplayChannel to RedChannel
*/
#include
#include
#include
#include
#include
#include
#include
#include
#include
#include
#include
#include
#include
#include
#include
#include
#include
#include "common/lz.h"
#include "common/marshaller.h"
#include "common/quic.h"
#include "common/rect.h"
#include "common/region.h"
#include "common/ring.h"
#include "common/generated_server_marshallers.h"
#ifdef USE_OPENGL
#include "common/ogl_ctx.h"
#include "reds_gl_canvas.h"
#endif /* USE_OPENGL */
#include "spice.h"
#include "red_worker.h"
#include "reds_sw_canvas.h"
#include "glz_encoder_dictionary.h"
#include "glz_encoder.h"
#include "stat.h"
#include "reds.h"
#include "mjpeg_encoder.h"
#include "red_memslots.h"
#include "red_parse_qxl.h"
#include "jpeg_encoder.h"
#include "demarshallers.h"
#include "zlib_encoder.h"
#include "red_channel.h"
#include "red_dispatcher.h"
#include "dispatcher.h"
#include "main_channel.h"
#include "migration_protocol.h"
#include "spice_timer_queue.h"
#include "main_dispatcher.h"
//#define COMPRESS_STAT
//#define DUMP_BITMAP
//#define PIPE_DEBUG
//#define RED_WORKER_STAT
//#define DRAW_ALL
//#define COMPRESS_DEBUG
//#define ACYCLIC_SURFACE_DEBUG
//#define DEBUG_CURSORS
//#define UPDATE_AREA_BY_TREE
#define CMD_RING_POLL_TIMEOUT 10 //milli
#define CMD_RING_POLL_RETRIES 200
#define DETACH_TIMEOUT 15000000000ULL //nano
#define DETACH_SLEEP_DURATION 10000 //micro
#define CHANNEL_PUSH_TIMEOUT 30000000000ULL //nano
#define CHANNEL_PUSH_SLEEP_DURATION 10000 //micro
#define DISPLAY_CLIENT_TIMEOUT 15000000000ULL //nano
#define DISPLAY_CLIENT_MIGRATE_DATA_TIMEOUT 10000000000ULL //nano, 10 sec
#define DISPLAY_CLIENT_RETRY_INTERVAL 10000 //micro
#define DISPLAY_FREE_LIST_DEFAULT_SIZE 128
#define RED_STREAM_DETACTION_MAX_DELTA ((1000 * 1000 * 1000) / 5) // 1/5 sec
#define RED_STREAM_CONTINUS_MAX_DELTA (1000 * 1000 * 1000)
#define RED_STREAM_TIMOUT (1000 * 1000 * 1000)
#define RED_STREAM_FRAMES_START_CONDITION 20
#define RED_STREAM_GRADUAL_FRAMES_START_CONDITION 0.2
#define RED_STREAM_FRAMES_RESET_CONDITION 100
#define RED_STREAM_MIN_SIZE (96 * 96)
#define RED_STREAM_INPUT_FPS_TIMEOUT (5 * 1000) // 5 sec
#define RED_STREAM_CHANNEL_CAPACITY 0.8
/* the client's stream report frequency is the minimum of the 2 values below */
#define RED_STREAM_CLIENT_REPORT_WINDOW 5 // #frames
#define RED_STREAM_CLIENT_REPORT_TIMEOUT 1000 // milliseconds
#define RED_STREAM_DEFAULT_HIGH_START_BIT_RATE (10 * 1024 * 1024) // 10Mbps
#define RED_STREAM_DEFAULT_LOW_START_BIT_RATE (2.5 * 1024 * 1024) // 2.5Mbps
#define FPS_TEST_INTERVAL 1
#define MAX_FPS 30
#define RED_COMPRESS_BUF_SIZE (1024 * 64)
#define ZLIB_DEFAULT_COMPRESSION_LEVEL 3
#define MIN_GLZ_SIZE_FOR_ZLIB 100
typedef int64_t red_time_t;
#define VALIDATE_SURFACE_RET(worker, surface_id) \
if (!validate_surface(worker, surface_id)) { \
rendering_incorrect(__func__); \
return; \
}
#define VALIDATE_SURFACE_RETVAL(worker, surface_id, ret) \
if (!validate_surface(worker, surface_id)) { \
rendering_incorrect(__func__); \
return ret; \
}
#define VALIDATE_SURFACE_BREAK(worker, surface_id) \
if (!validate_surface(worker, surface_id)) { \
rendering_incorrect(__func__); \
break; \
}
static void rendering_incorrect(const char *msg)
{
spice_warning("rendering incorrect from now on: %s", msg);
}
static inline red_time_t timespec_to_red_time(struct timespec *time)
{
return time->tv_sec * (1000 * 1000 * 1000) + time->tv_nsec;
}
#if defined(RED_WORKER_STAT) || defined(COMPRESS_STAT)
static clockid_t clock_id;
typedef unsigned long stat_time_t;
static stat_time_t stat_now(void)
{
struct timespec ts;
clock_gettime(clock_id, &ts);
return ts.tv_nsec + ts.tv_sec * 1000 * 1000 * 1000;
}
double stat_cpu_time_to_sec(stat_time_t time)
{
return (double)time / (1000 * 1000 * 1000);
}
typedef struct stat_info_s {
const char *name;
uint32_t count;
stat_time_t max;
stat_time_t min;
stat_time_t total;
#ifdef COMPRESS_STAT
uint64_t orig_size;
uint64_t comp_size;
#endif
} stat_info_t;
static inline void stat_reset(stat_info_t *info)
{
info->count = info->max = info->total = 0;
info->min = ~(stat_time_t)0;
#ifdef COMPRESS_STAT
info->orig_size = info->comp_size = 0;
#endif
}
#endif
#ifdef RED_WORKER_STAT
static const char *add_stat_name = "add";
static const char *exclude_stat_name = "exclude";
static const char *__exclude_stat_name = "__exclude";
static inline void stat_init(stat_info_t *info, const char *name)
{
info->name = name;
stat_reset(info);
}
static inline void stat_add(stat_info_t *info, stat_time_t start)
{
stat_time_t time;
++info->count;
time = stat_now() - start;
info->total += time;
info->max = MAX(info->max, time);
info->min = MIN(info->min, time);
}
#else
#define stat_add(a, b)
#define stat_init(a, b)
#endif
#ifdef COMPRESS_STAT
static const char *lz_stat_name = "lz";
static const char *glz_stat_name = "glz";
static const char *quic_stat_name = "quic";
static const char *jpeg_stat_name = "jpeg";
static const char *zlib_stat_name = "zlib_glz";
static const char *jpeg_alpha_stat_name = "jpeg_alpha";
static inline void stat_compress_init(stat_info_t *info, const char *name)
{
info->name = name;
stat_reset(info);
}
static inline void stat_compress_add(stat_info_t *info, stat_time_t start, int orig_size,
int comp_size)
{
stat_time_t time;
++info->count;
time = stat_now() - start;
info->total += time;
info->max = MAX(info->max, time);
info->min = MIN(info->min, time);
info->orig_size += orig_size;
info->comp_size += comp_size;
}
double inline stat_byte_to_mega(uint64_t size)
{
return (double)size / (1000 * 1000);
}
#else
#define stat_compress_init(a, b)
#define stat_compress_add(a, b, c, d)
#endif
#define MAX_EVENT_SOURCES 20
#define INF_EVENT_WAIT ~0
struct SpiceWatch {
struct RedWorker *worker;
SpiceWatchFunc watch_func;
void *watch_func_opaque;
};
enum {
BUF_TYPE_RAW = 1,
};
enum {
PIPE_ITEM_TYPE_DRAW = PIPE_ITEM_TYPE_CHANNEL_BASE,
PIPE_ITEM_TYPE_INVAL_ONE,
PIPE_ITEM_TYPE_CURSOR,
PIPE_ITEM_TYPE_CURSOR_INIT,
PIPE_ITEM_TYPE_IMAGE,
PIPE_ITEM_TYPE_STREAM_CREATE,
PIPE_ITEM_TYPE_STREAM_CLIP,
PIPE_ITEM_TYPE_STREAM_DESTROY,
PIPE_ITEM_TYPE_UPGRADE,
PIPE_ITEM_TYPE_VERB,
PIPE_ITEM_TYPE_MIGRATE_DATA,
PIPE_ITEM_TYPE_PIXMAP_SYNC,
PIPE_ITEM_TYPE_PIXMAP_RESET,
PIPE_ITEM_TYPE_INVAL_CURSOR_CACHE,
PIPE_ITEM_TYPE_INVAL_PALLET_CACHE,
PIPE_ITEM_TYPE_CREATE_SURFACE,
PIPE_ITEM_TYPE_DESTROY_SURFACE,
PIPE_ITEM_TYPE_MONITORS_CONFIG,
PIPE_ITEM_TYPE_STREAM_ACTIVATE_REPORT,
};
typedef struct VerbItem {
PipeItem base;
uint16_t verb;
} VerbItem;
#define MAX_CACHE_CLIENTS 4
#define MAX_LZ_ENCODERS MAX_CACHE_CLIENTS
typedef struct NewCacheItem NewCacheItem;
struct NewCacheItem {
RingItem lru_link;
NewCacheItem *next;
uint64_t id;
uint64_t sync[MAX_CACHE_CLIENTS];
size_t size;
int lossy;
};
typedef struct CacheItem CacheItem;
struct CacheItem {
union {
PipeItem pipe_data;
struct {
RingItem lru_link;
CacheItem *next;
} cache_data;
} u;
uint64_t id;
size_t size;
uint32_t inval_type;
};
typedef struct SurfaceCreateItem {
SpiceMsgSurfaceCreate surface_create;
PipeItem pipe_item;
} SurfaceCreateItem;
typedef struct SurfaceDestroyItem {
SpiceMsgSurfaceDestroy surface_destroy;
PipeItem pipe_item;
} SurfaceDestroyItem;
typedef struct MonitorsConfig {
int refs;
struct RedWorker *worker;
int count;
int max_allowed;
QXLHead heads[0];
} MonitorsConfig;
typedef struct MonitorsConfigItem {
PipeItem pipe_item;
MonitorsConfig *monitors_config;
} MonitorsConfigItem;
typedef struct StreamActivateReportItem {
PipeItem pipe_item;
uint32_t stream_id;
} StreamActivateReportItem;
typedef struct CursorItem {
uint32_t group_id;
int refs;
RedCursorCmd *red_cursor;
} CursorItem;
typedef struct CursorPipeItem {
PipeItem base;
CursorItem *cursor_item;
int refs;
} CursorPipeItem;
typedef struct LocalCursor {
CursorItem base;
SpicePoint16 position;
uint32_t data_size;
SpiceCursor red_cursor;
} LocalCursor;
#define MAX_PIPE_SIZE 50
#define RECIVE_BUF_SIZE 1024
#define WIDE_CLIENT_ACK_WINDOW 40
#define NARROW_CLIENT_ACK_WINDOW 20
#define BITS_CACHE_HASH_SHIFT 10
#define BITS_CACHE_HASH_SIZE (1 << BITS_CACHE_HASH_SHIFT)
#define BITS_CACHE_HASH_MASK (BITS_CACHE_HASH_SIZE - 1)
#define BITS_CACHE_HASH_KEY(id) ((id) & BITS_CACHE_HASH_MASK)
#define CLIENT_CURSOR_CACHE_SIZE 256
#define CURSOR_CACHE_HASH_SHIFT 8
#define CURSOR_CACHE_HASH_SIZE (1 << CURSOR_CACHE_HASH_SHIFT)
#define CURSOR_CACHE_HASH_MASK (CURSOR_CACHE_HASH_SIZE - 1)
#define CURSOR_CACHE_HASH_KEY(id) ((id) & CURSOR_CACHE_HASH_MASK)
#define CLIENT_PALETTE_CACHE_SIZE 128
#define PALETTE_CACHE_HASH_SHIFT 8
#define PALETTE_CACHE_HASH_SIZE (1 << PALETTE_CACHE_HASH_SHIFT)
#define PALETTE_CACHE_HASH_MASK (PALETTE_CACHE_HASH_SIZE - 1)
#define PALETTE_CACHE_HASH_KEY(id) ((id) & PALETTE_CACHE_HASH_MASK)
typedef struct ImageItem {
PipeItem link;
int refs;
SpicePoint pos;
int width;
int height;
int stride;
int top_down;
int surface_id;
int image_format;
uint32_t image_flags;
int can_lossy;
uint8_t data[0];
} ImageItem;
typedef struct Drawable Drawable;
typedef struct DisplayChannel DisplayChannel;
typedef struct DisplayChannelClient DisplayChannelClient;
enum {
STREAM_FRAME_NONE,
STREAM_FRAME_NATIVE,
STREAM_FRAME_CONTAINER,
};
typedef struct Stream Stream;
struct Stream {
uint8_t refs;
Drawable *current;
red_time_t last_time;
int width;
int height;
SpiceRect dest_area;
int top_down;
Stream *next;
RingItem link;
SpiceTimer *input_fps_timer;
uint32_t num_input_frames;
uint64_t input_fps_timer_start;
uint32_t input_fps;
};
#define STREAM_STATS
#ifdef STREAM_STATS
typedef struct StreamStats {
uint64_t num_drops_pipe;
uint64_t num_drops_fps;
uint64_t num_frames_sent;
uint64_t num_input_frames;
uint64_t size_sent;
uint64_t start;
uint64_t end;
} StreamStats;
#endif
typedef struct StreamAgent {
QRegion vis_region; /* the part of the surface area that is currently occupied by video
fragments */
QRegion clip; /* the current video clipping. It can be different from vis_region:
for example, let c1 be the clip area at time t1, and c2
be the clip area at time t2, where t1 < t2. If c1 contains c2, and
at least part of c1/c2, hasn't been covered by a non-video images,
vis_region will contain c2 and also the part of c1/c2 that still
displays fragments of the video */
PipeItem create_item;
PipeItem destroy_item;
Stream *stream;
uint64_t last_send_time;
MJpegEncoder *mjpeg_encoder;
DisplayChannelClient *dcc;
int frames;
int drops;
int fps;
uint32_t report_id;
uint32_t client_required_latency;
#ifdef STREAM_STATS
StreamStats stats;
#endif
} StreamAgent;
typedef struct StreamClipItem {
PipeItem base;
int refs;
StreamAgent *stream_agent;
int clip_type;
SpiceClipRects *rects;
} StreamClipItem;
typedef struct RedCompressBuf RedCompressBuf;
struct RedCompressBuf {
uint32_t buf[RED_COMPRESS_BUF_SIZE / 4];
RedCompressBuf *next;
RedCompressBuf *send_next;
};
static const int BITMAP_FMT_IS_PLT[] = {0, 1, 1, 1, 1, 1, 0, 0, 0, 0, 0};
static const int BITMAP_FMP_BYTES_PER_PIXEL[] = {0, 0, 0, 0, 0, 1, 2, 3, 4, 4, 1};
#define BITMAP_FMT_HAS_GRADUALITY(f) \
(bitmap_fmt_is_rgb(f) && \
((f) != SPICE_BITMAP_FMT_8BIT_A))
pthread_mutex_t cache_lock = PTHREAD_MUTEX_INITIALIZER;
Ring pixmap_cache_list = {&pixmap_cache_list, &pixmap_cache_list};
typedef struct PixmapCache PixmapCache;
struct PixmapCache {
RingItem base;
pthread_mutex_t lock;
uint8_t id;
uint32_t refs;
NewCacheItem *hash_table[BITS_CACHE_HASH_SIZE];
Ring lru;
int64_t available;
int64_t size;
int32_t items;
int freezed;
RingItem *freezed_head;
RingItem *freezed_tail;
uint32_t generation;
struct {
uint8_t client;
uint64_t message;
} generation_initiator;
uint64_t sync[MAX_CACHE_CLIENTS]; // here CLIENTS refer to different channel
// clients of the same client
RedClient *client;
};
#define NUM_STREAMS 50
typedef struct WaitForChannels {
SpiceMsgWaitForChannels header;
SpiceWaitForChannel buf[MAX_CACHE_CLIENTS];
} WaitForChannels;
typedef struct FreeList {
int res_size;
SpiceResourceList *res;
uint64_t sync[MAX_CACHE_CLIENTS];
WaitForChannels wait;
} FreeList;
typedef struct {
DisplayChannelClient *dcc;
RedCompressBuf *bufs_head;
RedCompressBuf *bufs_tail;
jmp_buf jmp_env;
union {
struct {
SpiceChunks *chunks;
int next;
int stride;
int reverse;
} lines_data;
struct {
RedCompressBuf* next;
int size_left;
} compressed_data; // for encoding data that was already compressed by another method
} u;
char message_buf[512];
} EncoderData;
typedef struct {
QuicUsrContext usr;
EncoderData data;
} QuicData;
typedef struct {
LzUsrContext usr;
EncoderData data;
} LzData;
typedef struct {
GlzEncoderUsrContext usr;
EncoderData data;
} GlzData;
typedef struct {
JpegEncoderUsrContext usr;
EncoderData data;
} JpegData;
typedef struct {
ZlibEncoderUsrContext usr;
EncoderData data;
} ZlibData;
/**********************************/
/* LZ dictionary related entities */
/**********************************/
#define MAX_GLZ_DRAWABLE_INSTANCES 2
typedef struct RedGlzDrawable RedGlzDrawable;
/* for each qxl drawable, there may be several instances of lz drawables */
/* TODO - reuse this stuff for the top level. I just added a second level of multiplicity
* at the Drawable by keeping a ring, so:
* Drawable -> (ring of) RedGlzDrawable -> (up to 2) GlzDrawableInstanceItem
* and it should probably (but need to be sure...) be
* Drawable -> ring of GlzDrawableInstanceItem.
*/
typedef struct GlzDrawableInstanceItem {
RingItem glz_link;
RingItem free_link;
GlzEncDictImageContext *glz_instance;
RedGlzDrawable *red_glz_drawable;
} GlzDrawableInstanceItem;
struct RedGlzDrawable {
RingItem link; // ordered by the time it was encoded
RingItem drawable_link;
RedDrawable *red_drawable;
Drawable *drawable;
uint32_t group_id;
GlzDrawableInstanceItem instances_pool[MAX_GLZ_DRAWABLE_INSTANCES];
Ring instances;
uint8_t instances_count;
DisplayChannelClient *dcc;
};
pthread_mutex_t glz_dictionary_list_lock = PTHREAD_MUTEX_INITIALIZER;
Ring glz_dictionary_list = {&glz_dictionary_list, &glz_dictionary_list};
typedef struct GlzSharedDictionary {
RingItem base;
GlzEncDictContext *dict;
uint32_t refs;
uint8_t id;
pthread_rwlock_t encode_lock;
int migrate_freeze;
RedClient *client; // channel clients of the same client share the dict
} GlzSharedDictionary;
#define NUM_SURFACES 10000
typedef struct CommonChannel {
RedChannel base; // Must be the first thing
struct RedWorker *worker;
uint8_t recv_buf[RECIVE_BUF_SIZE];
uint32_t id_alloc; // bitfield. TODO - use this instead of shift scheme.
int during_target_migrate; /* TRUE when the client that is associated with the channel
is during migration. Turned off when the vm is started.
The flag is used to avoid sending messages that are artifacts
of the transition from stopped vm to loaded vm (e.g., recreation
of the primary surface) */
} CommonChannel;
typedef struct CommonChannelClient {
RedChannelClient base;
uint32_t id;
struct RedWorker *worker;
int is_low_bandwidth;
} CommonChannelClient;
/* Each drawable can refer to at most 3 images: src, brush and mask */
#define MAX_DRAWABLE_PIXMAP_CACHE_ITEMS 3
struct DisplayChannelClient {
CommonChannelClient common;
int expect_init;
PixmapCache *pixmap_cache;
uint32_t pixmap_cache_generation;
int pending_pixmaps_sync;
CacheItem *palette_cache[PALETTE_CACHE_HASH_SIZE];
Ring palette_cache_lru;
long palette_cache_available;
uint32_t palette_cache_items;
struct {
uint32_t stream_outbuf_size;
uint8_t *stream_outbuf; // caution stream buffer is also used as compress bufs!!!
RedCompressBuf *used_compress_bufs;
FreeList free_list;
uint64_t pixmap_cache_items[MAX_DRAWABLE_PIXMAP_CACHE_ITEMS];
int num_pixmap_cache_items;
} send_data;
/* global lz encoding entities */
GlzSharedDictionary *glz_dict;
GlzEncoderContext *glz;
GlzData glz_data;
Ring glz_drawables; // all the living lz drawable, ordered by encoding time
Ring glz_drawables_inst_to_free; // list of instances to be freed
pthread_mutex_t glz_drawables_inst_to_free_lock;
uint8_t surface_client_created[NUM_SURFACES];
QRegion surface_client_lossy_region[NUM_SURFACES];
StreamAgent stream_agents[NUM_STREAMS];
int use_mjpeg_encoder_rate_control;
uint32_t streams_max_latency;
uint64_t streams_max_bit_rate;
};
struct DisplayChannel {
CommonChannel common; // Must be the first thing
int enable_jpeg;
int jpeg_quality;
int enable_zlib_glz_wrap;
int zlib_level;
RedCompressBuf *free_compress_bufs;
#ifdef RED_STATISTICS
StatNodeRef stat;
uint64_t *cache_hits_counter;
uint64_t *add_to_cache_counter;
uint64_t *non_cache_counter;
#endif
#ifdef COMPRESS_STAT
stat_info_t lz_stat;
stat_info_t glz_stat;
stat_info_t quic_stat;
stat_info_t jpeg_stat;
stat_info_t zlib_glz_stat;
stat_info_t jpeg_alpha_stat;
#endif
};
typedef struct CursorChannelClient {
CommonChannelClient common;
CacheItem *cursor_cache[CURSOR_CACHE_HASH_SIZE];
Ring cursor_cache_lru;
long cursor_cache_available;
uint32_t cursor_cache_items;
} CursorChannelClient;
typedef struct CursorChannel {
CommonChannel common; // Must be the first thing
#ifdef RED_STATISTICS
StatNodeRef stat;
#endif
} CursorChannel;
typedef struct ImageCacheItem {
RingItem lru_link;
uint64_t id;
#ifdef IMAGE_CACHE_AGE
uint32_t age;
#endif
struct ImageCacheItem *next;
pixman_image_t *image;
} ImageCacheItem;
#define IMAGE_CACHE_HASH_SIZE 1024
typedef struct ImageCache {
SpiceImageCache base;
ImageCacheItem *hash_table[IMAGE_CACHE_HASH_SIZE];
Ring lru;
#ifdef IMAGE_CACHE_AGE
uint32_t age;
#else
uint32_t num_items;
#endif
} ImageCache;
enum {
TREE_ITEM_TYPE_DRAWABLE,
TREE_ITEM_TYPE_CONTAINER,
TREE_ITEM_TYPE_SHADOW,
};
typedef struct TreeItem {
RingItem siblings_link;
uint32_t type;
struct Container *container;
QRegion rgn;
#ifdef PIPE_DEBUG
uint32_t id;
#endif
} TreeItem;
#define IS_DRAW_ITEM(item) ((item)->type == TREE_ITEM_TYPE_DRAWABLE)
typedef struct Shadow {
TreeItem base;
QRegion on_hold;
struct DrawItem* owner;
} Shadow;
typedef struct Container {
TreeItem base;
Ring items;
} Container;
typedef struct DrawItem {
TreeItem base;
uint8_t effect;
uint8_t container_root;
Shadow *shadow;
} DrawItem;
typedef enum {
BITMAP_GRADUAL_INVALID,
BITMAP_GRADUAL_NOT_AVAIL,
BITMAP_GRADUAL_LOW,
BITMAP_GRADUAL_MEDIUM,
BITMAP_GRADUAL_HIGH,
} BitmapGradualType;
typedef struct DependItem {
Drawable *drawable;
RingItem ring_item;
} DependItem;
typedef struct DrawablePipeItem {
RingItem base; /* link for a list of pipe items held by Drawable */
PipeItem dpi_pipe_item; /* link for the client's pipe itself */
Drawable *drawable;
DisplayChannelClient *dcc;
uint8_t refs;
} DrawablePipeItem;
struct Drawable {
uint8_t refs;
RingItem surface_list_link;
RingItem list_link;
DrawItem tree_item;
Ring pipes;
PipeItem *pipe_item_rest;
uint32_t size_pipe_item_rest;
#ifdef UPDATE_AREA_BY_TREE
RingItem collect_link;
#endif
RedDrawable *red_drawable;
Ring glz_ring;
red_time_t creation_time;
int frames_count;
int gradual_frames_count;
int last_gradual_frame;
Stream *stream;
Stream *sized_stream;
int streamable;
BitmapGradualType copy_bitmap_graduality;
uint32_t group_id;
DependItem depend_items[3];
uint8_t *backed_surface_data;
DependItem pipe_depend_items[3];
int surface_id;
int surfaces_dest[3];
uint32_t process_commands_generation;
};
typedef struct _Drawable _Drawable;
struct _Drawable {
union {
Drawable drawable;
_Drawable *next;
} u;
};
typedef struct _CursorItem _CursorItem;
struct _CursorItem {
union {
CursorItem cursor_item;
_CursorItem *next;
} u;
};
typedef struct UpgradeItem {
PipeItem base;
int refs;
Drawable *drawable;
SpiceClipRects *rects;
} UpgradeItem;
typedef struct DrawContext {
SpiceCanvas *canvas;
int canvas_draws_on_surface;
int top_down;
uint32_t width;
uint32_t height;
int32_t stride;
uint32_t format;
void *line_0;
} DrawContext;
typedef struct RedSurface {
uint32_t refs;
Ring current;
Ring current_list;
#ifdef ACYCLIC_SURFACE_DEBUG
int current_gn;
#endif
DrawContext context;
Ring depend_on_me;
QRegion draw_dirty_region;
//fix me - better handling here
QXLReleaseInfoExt create, destroy;
} RedSurface;
typedef struct ItemTrace {
red_time_t time;
int frames_count;
int gradual_frames_count;
int last_gradual_frame;
int width;
int height;
SpiceRect dest_area;
} ItemTrace;
#define TRACE_ITEMS_SHIFT 3
#define NUM_TRACE_ITEMS (1 << TRACE_ITEMS_SHIFT)
#define ITEMS_TRACE_MASK (NUM_TRACE_ITEMS - 1)
#define NUM_DRAWABLES 1000
#define NUM_CURSORS 100
typedef struct RedWorker {
DisplayChannel *display_channel;
CursorChannel *cursor_channel;
QXLInstance *qxl;
RedDispatcher *red_dispatcher;
int channel;
int id;
int running;
uint32_t *pending;
struct pollfd poll_fds[MAX_EVENT_SOURCES];
struct SpiceWatch watches[MAX_EVENT_SOURCES];
unsigned int event_timeout;
uint32_t repoll_cmd_ring;
uint32_t repoll_cursor_ring;
uint32_t num_renderers;
uint32_t renderers[RED_MAX_RENDERERS];
uint32_t renderer;
RedSurface surfaces[NUM_SURFACES];
uint32_t n_surfaces;
SpiceImageSurfaces image_surfaces;
MonitorsConfig *monitors_config;
Ring current_list;
uint32_t current_size;
uint32_t drawable_count;
uint32_t red_drawable_count;
uint32_t glz_drawable_count;
uint32_t transparent_count;
uint32_t shadows_count;
uint32_t containers_count;
uint32_t stream_count;
uint32_t bits_unique;
CursorItem *cursor;
int cursor_visible;
SpicePoint16 cursor_position;
uint16_t cursor_trail_length;
uint16_t cursor_trail_frequency;
_Drawable drawables[NUM_DRAWABLES];
_Drawable *free_drawables;
_CursorItem cursor_items[NUM_CURSORS];
_CursorItem *free_cursor_items;
RedMemSlotInfo mem_slots;
uint32_t preload_group_id;
ImageCache image_cache;
spice_image_compression_t image_compression;
spice_wan_compression_t jpeg_state;
spice_wan_compression_t zlib_glz_state;
uint32_t mouse_mode;
uint32_t streaming_video;
Stream streams_buf[NUM_STREAMS];
Stream *free_streams;
Ring streams;
ItemTrace items_trace[NUM_TRACE_ITEMS];
uint32_t next_item_trace;
uint64_t streams_size_total;
QuicData quic_data;
QuicContext *quic;
LzData lz_data;
LzContext *lz;
JpegData jpeg_data;
JpegEncoderContext *jpeg;
ZlibData zlib_data;
ZlibEncoder *zlib;
uint32_t process_commands_generation;
#ifdef PIPE_DEBUG
uint32_t last_id;
#endif
#ifdef RED_WORKER_STAT
stat_info_t add_stat;
stat_info_t exclude_stat;
stat_info_t __exclude_stat;
uint32_t add_count;
uint32_t add_with_shadow_count;
#endif
#ifdef RED_STATISTICS
StatNodeRef stat;
uint64_t *wakeup_counter;
uint64_t *command_counter;
#endif
int driver_cap_monitors_config;
int set_client_capabilities_pending;
} RedWorker;
typedef enum {
BITMAP_DATA_TYPE_INVALID,
BITMAP_DATA_TYPE_CACHE,
BITMAP_DATA_TYPE_SURFACE,
BITMAP_DATA_TYPE_BITMAP,
BITMAP_DATA_TYPE_BITMAP_TO_CACHE,
} BitmapDataType;
typedef struct BitmapData {
BitmapDataType type;
uint64_t id; // surface id or cache item id
SpiceRect lossy_rect;
} BitmapData;
static void red_draw_qxl_drawable(RedWorker *worker, Drawable *drawable);
static void red_current_flush(RedWorker *worker, int surface_id);
#ifdef DRAW_ALL
#define red_update_area(worker, rect, surface_id)
#define red_draw_drawable(worker, item)
#else
static void red_draw_drawable(RedWorker *worker, Drawable *item);
static void red_update_area(RedWorker *worker, const SpiceRect *area, int surface_id);
static void red_update_area_till(RedWorker *worker, const SpiceRect *area, int surface_id,
Drawable *last);
#endif
static void red_release_cursor(RedWorker *worker, CursorItem *cursor);
static inline void release_drawable(RedWorker *worker, Drawable *item);
static void red_display_release_stream(RedWorker *worker, StreamAgent *agent);
static inline void red_detach_stream(RedWorker *worker, Stream *stream, int detach_sized);
static void red_stop_stream(RedWorker *worker, Stream *stream);
static inline void red_stream_maintenance(RedWorker *worker, Drawable *candidate, Drawable *sect);
static inline void display_begin_send_message(RedChannelClient *rcc);
static void red_release_pixmap_cache(DisplayChannelClient *dcc);
static void red_release_glz(DisplayChannelClient *dcc);
static void red_freeze_glz(DisplayChannelClient *dcc);
static void display_channel_push_release(DisplayChannelClient *dcc, uint8_t type, uint64_t id,
uint64_t* sync_data);
static void red_display_release_stream_clip(RedWorker *worker, StreamClipItem *item);
static int red_display_free_some_independent_glz_drawables(DisplayChannelClient *dcc);
static void red_display_free_glz_drawable(DisplayChannelClient *dcc, RedGlzDrawable *drawable);
static ImageItem *red_add_surface_area_image(DisplayChannelClient *dcc, int surface_id,
SpiceRect *area, PipeItem *pos, int can_lossy);
static BitmapGradualType _get_bitmap_graduality_level(RedWorker *worker, SpiceBitmap *bitmap,
uint32_t group_id);
static inline int _stride_is_extra(SpiceBitmap *bitmap);
static void red_disconnect_cursor(RedChannel *channel);
static void display_channel_client_release_item_before_push(DisplayChannelClient *dcc,
PipeItem *item);
static void display_channel_client_release_item_after_push(DisplayChannelClient *dcc,
PipeItem *item);
static void cursor_channel_client_release_item_before_push(CursorChannelClient *ccc,
PipeItem *item);
static void cursor_channel_client_release_item_after_push(CursorChannelClient *ccc,
PipeItem *item);
static void red_wait_pipe_item_sent(RedChannelClient *rcc, PipeItem *item);
#ifdef DUMP_BITMAP
static void dump_bitmap(RedWorker *worker, SpiceBitmap *bitmap, uint32_t group_id);
#endif
static void red_push_monitors_config(DisplayChannelClient *dcc);
static inline uint64_t red_now(void);
/*
* Macros to make iterating over stuff easier
* The two collections we iterate over:
* given a channel, iterate over it's clients
*/
/* a generic safe for loop macro */
#define SAFE_FOREACH(link, next, cond, ring, data, get_data) \
for ((((link) = ((cond) ? ring_get_head(ring) : NULL)), \
((next) = ((link) ? ring_next((ring), (link)) : NULL)), \
((data) = ((link)? (get_data) : NULL))); \
(link); \
(((link) = (next)), \
((next) = ((link) ? ring_next((ring), (link)) : NULL)), \
((data) = ((link)? (get_data) : NULL))))
#define LINK_TO_RCC(ptr) SPICE_CONTAINEROF(ptr, RedChannelClient, channel_link)
#define RCC_FOREACH_SAFE(link, next, rcc, channel) \
SAFE_FOREACH(link, next, channel, &(channel)->clients, rcc, LINK_TO_RCC(link))
#define LINK_TO_DCC(ptr) SPICE_CONTAINEROF(ptr, DisplayChannelClient, \
common.base.channel_link)
#define DCC_FOREACH_SAFE(link, next, dcc, channel) \
SAFE_FOREACH(link, next, channel, &(channel)->clients, dcc, LINK_TO_DCC(link))
#define WORKER_FOREACH_DCC_SAFE(worker, link, next, dcc) \
DCC_FOREACH_SAFE(link, next, dcc, \
((((worker) && (worker)->display_channel))? \
(&(worker)->display_channel->common.base) : NULL))
#define LINK_TO_DPI(ptr) SPICE_CONTAINEROF((ptr), DrawablePipeItem, base)
#define DRAWABLE_FOREACH_DPI_SAFE(drawable, link, next, dpi) \
SAFE_FOREACH(link, next, drawable, &(drawable)->pipes, dpi, LINK_TO_DPI(link))
#define LINK_TO_GLZ(ptr) SPICE_CONTAINEROF((ptr), RedGlzDrawable, \
drawable_link)
#define DRAWABLE_FOREACH_GLZ_SAFE(drawable, link, next, glz) \
SAFE_FOREACH(link, next, drawable, &(drawable)->glz_ring, glz, LINK_TO_GLZ(link))
#define DCC_TO_WORKER(dcc) \
(SPICE_CONTAINEROF((dcc)->common.base.channel, CommonChannel, base)->worker)
// TODO: replace with DCC_FOREACH when it is introduced
#define WORKER_TO_DCC(worker) \
(worker->display_channel ? SPICE_CONTAINEROF(worker->display_channel->common.base.rcc,\
DisplayChannelClient, common.base) : NULL)
#define DCC_TO_DC(dcc) SPICE_CONTAINEROF((dcc)->common.base.channel,\
DisplayChannel, common.base)
#define RCC_TO_DCC(rcc) SPICE_CONTAINEROF((rcc), DisplayChannelClient, common.base)
#define RCC_TO_CCC(rcc) SPICE_CONTAINEROF((rcc), CursorChannelClient, common.base)
#ifdef COMPRESS_STAT
static void print_compress_stats(DisplayChannel *display_channel)
{
uint64_t glz_enc_size;
if (!display_channel) {
return;
}
glz_enc_size = display_channel->enable_zlib_glz_wrap ?
display_channel->zlib_glz_stat.comp_size :
display_channel->glz_stat.comp_size;
spice_info("==> Compression stats for display %u", display_channel->common.id);
spice_info("Method \t count \torig_size(MB)\tenc_size(MB)\tenc_time(s)");
spice_info("QUIC \t%8d\t%13.2f\t%12.2f\t%12.2f",
display_channel->quic_stat.count,
stat_byte_to_mega(display_channel->quic_stat.orig_size),
stat_byte_to_mega(display_channel->quic_stat.comp_size),
stat_cpu_time_to_sec(display_channel->quic_stat.total)
);
spice_info("GLZ \t%8d\t%13.2f\t%12.2f\t%12.2f",
display_channel->glz_stat.count,
stat_byte_to_mega(display_channel->glz_stat.orig_size),
stat_byte_to_mega(display_channel->glz_stat.comp_size),
stat_cpu_time_to_sec(display_channel->glz_stat.total)
);
spice_info("ZLIB GLZ \t%8d\t%13.2f\t%12.2f\t%12.2f",
display_channel->zlib_glz_stat.count,
stat_byte_to_mega(display_channel->zlib_glz_stat.orig_size),
stat_byte_to_mega(display_channel->zlib_glz_stat.comp_size),
stat_cpu_time_to_sec(display_channel->zlib_glz_stat.total)
);
spice_info("LZ \t%8d\t%13.2f\t%12.2f\t%12.2f",
display_channel->lz_stat.count,
stat_byte_to_mega(display_channel->lz_stat.orig_size),
stat_byte_to_mega(display_channel->lz_stat.comp_size),
stat_cpu_time_to_sec(display_channel->lz_stat.total)
);
spice_info("JPEG \t%8d\t%13.2f\t%12.2f\t%12.2f",
display_channel->jpeg_stat.count,
stat_byte_to_mega(display_channel->jpeg_stat.orig_size),
stat_byte_to_mega(display_channel->jpeg_stat.comp_size),
stat_cpu_time_to_sec(display_channel->jpeg_stat.total)
);
spice_info("JPEG-RGBA\t%8d\t%13.2f\t%12.2f\t%12.2f",
display_channel->jpeg_alpha_stat.count,
stat_byte_to_mega(display_channel->jpeg_alpha_stat.orig_size),
stat_byte_to_mega(display_channel->jpeg_alpha_stat.comp_size),
stat_cpu_time_to_sec(display_channel->jpeg_alpha_stat.total)
);
spice_info("-------------------------------------------------------------------");
spice_info("Total \t%8d\t%13.2f\t%12.2f\t%12.2f",
display_channel->lz_stat.count + display_channel->glz_stat.count +
display_channel->quic_stat.count +
display_channel->jpeg_stat.count +
display_channel->jpeg_alpha_stat.count,
stat_byte_to_mega(display_channel->lz_stat.orig_size +
display_channel->glz_stat.orig_size +
display_channel->quic_stat.orig_size +
display_channel->jpeg_stat.orig_size +
display_channel->jpeg_alpha_stat.orig_size),
stat_byte_to_mega(display_channel->lz_stat.comp_size +
glz_enc_size +
display_channel->quic_stat.comp_size +
display_channel->jpeg_stat.comp_size +
display_channel->jpeg_alpha_stat.comp_size),
stat_cpu_time_to_sec(display_channel->lz_stat.total +
display_channel->glz_stat.total +
display_channel->zlib_glz_stat.total +
display_channel->quic_stat.total +
display_channel->jpeg_stat.total +
display_channel->jpeg_alpha_stat.total)
);
}
#endif
static MonitorsConfig *monitors_config_getref(MonitorsConfig *monitors_config)
{
monitors_config->refs++;
return monitors_config;
}
static void monitors_config_decref(MonitorsConfig *monitors_config)
{
if (!monitors_config) {
return;
}
if (--monitors_config->refs > 0) {
return;
}
spice_debug("freeing monitors config");
free(monitors_config);
}
static inline int is_primary_surface(RedWorker *worker, uint32_t surface_id)
{
if (surface_id == 0) {
return TRUE;
}
return FALSE;
}
static inline void __validate_surface(RedWorker *worker, uint32_t surface_id)
{
spice_warn_if(surface_id >= worker->n_surfaces);
}
static inline int validate_surface(RedWorker *worker, uint32_t surface_id)
{
spice_warn_if(surface_id >= worker->n_surfaces);
if (!worker->surfaces[surface_id].context.canvas) {
spice_warning("canvas address is %p for %d (and is NULL)\n",
&(worker->surfaces[surface_id].context.canvas), surface_id);
spice_warning("failed on %d", surface_id);
spice_warn_if(!worker->surfaces[surface_id].context.canvas);
return 0;
}
return 1;
}
static const char *draw_type_to_str(uint8_t type)
{
switch (type) {
case QXL_DRAW_FILL:
return "QXL_DRAW_FILL";
case QXL_DRAW_OPAQUE:
return "QXL_DRAW_OPAQUE";
case QXL_DRAW_COPY:
return "QXL_DRAW_COPY";
case QXL_DRAW_TRANSPARENT:
return "QXL_DRAW_TRANSPARENT";
case QXL_DRAW_ALPHA_BLEND:
return "QXL_DRAW_ALPHA_BLEND";
case QXL_COPY_BITS:
return "QXL_COPY_BITS";
case QXL_DRAW_BLEND:
return "QXL_DRAW_BLEND";
case QXL_DRAW_BLACKNESS:
return "QXL_DRAW_BLACKNESS";
case QXL_DRAW_WHITENESS:
return "QXL_DRAW_WHITENESS";
case QXL_DRAW_INVERS:
return "QXL_DRAW_INVERS";
case QXL_DRAW_ROP3:
return "QXL_DRAW_ROP3";
case QXL_DRAW_COMPOSITE:
return "QXL_DRAW_COMPOSITE";
case QXL_DRAW_STROKE:
return "QXL_DRAW_STROKE";
case QXL_DRAW_TEXT:
return "QXL_DRAW_TEXT";
default:
return "?";
}
}
static void show_red_drawable(RedWorker *worker, RedDrawable *drawable, const char *prefix)
{
if (prefix) {
printf("%s: ", prefix);
}
printf("%s effect %d bbox(%d %d %d %d)",
draw_type_to_str(drawable->type),
drawable->effect,
drawable->bbox.top,
drawable->bbox.left,
drawable->bbox.bottom,
drawable->bbox.right);
switch (drawable->type) {
case QXL_DRAW_FILL:
case QXL_DRAW_OPAQUE:
case QXL_DRAW_COPY:
case QXL_DRAW_TRANSPARENT:
case QXL_DRAW_ALPHA_BLEND:
case QXL_COPY_BITS:
case QXL_DRAW_BLEND:
case QXL_DRAW_BLACKNESS:
case QXL_DRAW_WHITENESS:
case QXL_DRAW_INVERS:
case QXL_DRAW_ROP3:
case QXL_DRAW_COMPOSITE:
case QXL_DRAW_STROKE:
case QXL_DRAW_TEXT:
break;
default:
spice_error("bad drawable type");
}
printf("\n");
}
static void show_draw_item(RedWorker *worker, DrawItem *draw_item, const char *prefix)
{
if (prefix) {
printf("%s: ", prefix);
}
printf("effect %d bbox(%d %d %d %d)\n",
draw_item->effect,
draw_item->base.rgn.extents.x1,
draw_item->base.rgn.extents.y1,
draw_item->base.rgn.extents.x2,
draw_item->base.rgn.extents.y2);
}
static inline int pipe_item_is_linked(PipeItem *item)
{
return ring_item_is_linked(&item->link);
}
static inline void pipe_item_remove(PipeItem *item)
{
ring_remove(&item->link);
}
static void red_pipe_add_verb(RedChannelClient* rcc, uint16_t verb)
{
VerbItem *item = spice_new(VerbItem, 1);
red_channel_pipe_item_init(rcc->channel, &item->base, PIPE_ITEM_TYPE_VERB);
item->verb = verb;
red_channel_client_pipe_add(rcc, &item->base);
}
static inline void red_create_surface_item(DisplayChannelClient *dcc, int surface_id);
static void red_push_surface_image(DisplayChannelClient *dcc, int surface_id);
static void red_pipes_add_verb(RedChannel *channel, uint16_t verb)
{
RedChannelClient *rcc;
RingItem *link, *next;
RCC_FOREACH_SAFE(link, next, rcc, channel) {
red_pipe_add_verb(rcc, verb);
}
}
static inline void red_handle_drawable_surfaces_client_synced(
DisplayChannelClient *dcc, Drawable *drawable)
{
RedWorker *worker = DCC_TO_WORKER(dcc);
int x;
for (x = 0; x < 3; ++x) {
int surface_id;
surface_id = drawable->surfaces_dest[x];
if (surface_id != -1) {
if (dcc->surface_client_created[surface_id] == TRUE) {
continue;
}
red_create_surface_item(dcc, surface_id);
red_current_flush(worker, surface_id);
red_push_surface_image(dcc, surface_id);
}
}
if (dcc->surface_client_created[drawable->surface_id] == TRUE) {
return;
}
red_create_surface_item(dcc, drawable->surface_id);
red_current_flush(worker, drawable->surface_id);
red_push_surface_image(dcc, drawable->surface_id);
}
static int display_is_connected(RedWorker *worker)
{
return (worker->display_channel && red_channel_is_connected(
&worker->display_channel->common.base));
}
static int cursor_is_connected(RedWorker *worker)
{
return (worker->cursor_channel && red_channel_is_connected(
&worker->cursor_channel->common.base));
}
static void put_drawable_pipe_item(DrawablePipeItem *dpi)
{
RedWorker *worker = DCC_TO_WORKER(dpi->dcc);
if (--dpi->refs) {
return;
}
spice_assert(!ring_item_is_linked(&dpi->dpi_pipe_item.link));
spice_assert(!ring_item_is_linked(&dpi->base));
release_drawable(worker, dpi->drawable);
free(dpi);
}
static inline DrawablePipeItem *get_drawable_pipe_item(DisplayChannelClient *dcc,
Drawable *drawable)
{
DrawablePipeItem *dpi;
dpi = spice_malloc0(sizeof(*dpi));
dpi->drawable = drawable;
dpi->dcc = dcc;
ring_item_init(&dpi->base);
ring_add(&drawable->pipes, &dpi->base);
red_channel_pipe_item_init(dcc->common.base.channel, &dpi->dpi_pipe_item, PIPE_ITEM_TYPE_DRAW);
dpi->refs++;
drawable->refs++;
return dpi;
}
static inline DrawablePipeItem *ref_drawable_pipe_item(DrawablePipeItem *dpi)
{
spice_assert(dpi->drawable);
dpi->refs++;
return dpi;
}
static inline void red_pipe_add_drawable(DisplayChannelClient *dcc, Drawable *drawable)
{
DrawablePipeItem *dpi;
red_handle_drawable_surfaces_client_synced(dcc, drawable);
dpi = get_drawable_pipe_item(dcc, drawable);
red_channel_client_pipe_add(&dcc->common.base, &dpi->dpi_pipe_item);
}
static inline void red_pipes_add_drawable(RedWorker *worker, Drawable *drawable)
{
DisplayChannelClient *dcc;
RingItem *dcc_ring_item, *next;
spice_warn_if(!ring_is_empty(&drawable->pipes));
WORKER_FOREACH_DCC_SAFE(worker, dcc_ring_item, next, dcc) {
red_pipe_add_drawable(dcc, drawable);
}
}
static inline void red_pipe_add_drawable_to_tail(DisplayChannelClient *dcc, Drawable *drawable)
{
DrawablePipeItem *dpi;
if (!dcc) {
return;
}
red_handle_drawable_surfaces_client_synced(dcc, drawable);
dpi = get_drawable_pipe_item(dcc, drawable);
red_channel_client_pipe_add_tail(&dcc->common.base, &dpi->dpi_pipe_item);
}
static inline void red_pipes_add_drawable_after(RedWorker *worker,
Drawable *drawable, Drawable *pos_after)
{
DrawablePipeItem *dpi, *dpi_pos_after;
RingItem *dpi_link, *dpi_next;
DisplayChannelClient *dcc;
int num_other_linked = 0;
DRAWABLE_FOREACH_DPI_SAFE(pos_after, dpi_link, dpi_next, dpi_pos_after) {
num_other_linked++;
dcc = dpi_pos_after->dcc;
red_handle_drawable_surfaces_client_synced(dcc, drawable);
dpi = get_drawable_pipe_item(dcc, drawable);
red_channel_client_pipe_add_after(&dcc->common.base, &dpi->dpi_pipe_item,
&dpi_pos_after->dpi_pipe_item);
}
if (num_other_linked == 0) {
red_pipes_add_drawable(worker, drawable);
return;
}
if (num_other_linked != worker->display_channel->common.base.clients_num) {
RingItem *worker_item, *next;
spice_debug("TODO: not O(n^2)");
WORKER_FOREACH_DCC_SAFE(worker, worker_item, next, dcc) {
int sent = 0;
DRAWABLE_FOREACH_DPI_SAFE(pos_after, dpi_link, dpi_next, dpi_pos_after) {
if (dpi_pos_after->dcc == dcc) {
sent = 1;
break;
}
}
if (!sent) {
red_pipe_add_drawable(dcc, drawable);
}
}
}
}
static inline PipeItem *red_pipe_get_tail(DisplayChannelClient *dcc)
{
if (!dcc) {
return NULL;
}
return (PipeItem*)ring_get_tail(&dcc->common.base.pipe);
}
static inline void red_destroy_surface(RedWorker *worker, uint32_t surface_id);
static inline void red_pipes_remove_drawable(Drawable *drawable)
{
DrawablePipeItem *dpi;
RingItem *item, *next;
RING_FOREACH_SAFE(item, next, &drawable->pipes) {
dpi = SPICE_CONTAINEROF(item, DrawablePipeItem, base);
if (pipe_item_is_linked(&dpi->dpi_pipe_item)) {
red_channel_client_pipe_remove_and_release(&dpi->dcc->common.base,
&dpi->dpi_pipe_item);
}
}
}
static inline void red_pipe_add_image_item(DisplayChannelClient *dcc, ImageItem *item)
{
if (!dcc) {
return;
}
item->refs++;
red_channel_client_pipe_add(&dcc->common.base, &item->link);
}
static inline void red_pipe_add_image_item_after(DisplayChannelClient *dcc, ImageItem *item,
PipeItem *pos)
{
if (!dcc) {
return;
}
item->refs++;
red_channel_client_pipe_add_after(&dcc->common.base, &item->link, pos);
}
static void release_image_item(ImageItem *item)
{
if (!--item->refs) {
free(item);
}
}
static void release_upgrade_item(RedWorker* worker, UpgradeItem *item)
{
if (!--item->refs) {
release_drawable(worker, item->drawable);
free(item->rects);
free(item);
}
}
static uint8_t *common_alloc_recv_buf(RedChannelClient *rcc, uint16_t type, uint32_t size)
{
CommonChannel *common = SPICE_CONTAINEROF(rcc->channel, CommonChannel, base);
/* SPICE_MSGC_MIGRATE_DATA is the only client message whose size is dynamic */
if (type == SPICE_MSGC_MIGRATE_DATA) {
return spice_malloc(size);
}
if (size > RECIVE_BUF_SIZE) {
spice_critical("unexpected message size %u (max is %d)", size, RECIVE_BUF_SIZE);
return NULL;
}
return common->recv_buf;
}
static void common_release_recv_buf(RedChannelClient *rcc, uint16_t type, uint32_t size,
uint8_t* msg)
{
if (type == SPICE_MSGC_MIGRATE_DATA) {
free(msg);
}
}
#define CLIENT_PIXMAPS_CACHE
#include "red_client_shared_cache.h"
#undef CLIENT_PIXMAPS_CACHE
#define CLIENT_CURSOR_CACHE
#include "red_client_cache.h"
#undef CLIENT_CURSOR_CACHE
#define CLIENT_PALETTE_CACHE
#include "red_client_cache.h"
#undef CLIENT_PALETTE_CACHE
static void red_reset_palette_cache(DisplayChannelClient *dcc)
{
red_palette_cache_reset(dcc, CLIENT_PALETTE_CACHE_SIZE);
}
static void red_reset_cursor_cache(RedChannelClient *rcc)
{
red_cursor_cache_reset(RCC_TO_CCC(rcc), CLIENT_CURSOR_CACHE_SIZE);
}
static inline Drawable *alloc_drawable(RedWorker *worker)
{
Drawable *drawable;
if (!worker->free_drawables) {
return NULL;
}
drawable = &worker->free_drawables->u.drawable;
worker->free_drawables = worker->free_drawables->u.next;
return drawable;
}
static inline void free_drawable(RedWorker *worker, Drawable *item)
{
((_Drawable *)item)->u.next = worker->free_drawables;
worker->free_drawables = (_Drawable *)item;
}
static void drawables_init(RedWorker *worker)
{
int i;
worker->free_drawables = NULL;
for (i = 0; i < NUM_DRAWABLES; i++) {
free_drawable(worker, &worker->drawables[i].u.drawable);
}
}
static void red_reset_stream_trace(RedWorker *worker);
static SurfaceDestroyItem *get_surface_destroy_item(RedChannel *channel,
uint32_t surface_id)
{
SurfaceDestroyItem *destroy;
destroy = (SurfaceDestroyItem *)malloc(sizeof(SurfaceDestroyItem));
spice_warn_if(!destroy);
destroy->surface_destroy.surface_id = surface_id;
red_channel_pipe_item_init(channel,
&destroy->pipe_item, PIPE_ITEM_TYPE_DESTROY_SURFACE);
return destroy;
}
static inline void red_destroy_surface_item(RedWorker *worker,
DisplayChannelClient *dcc, uint32_t surface_id)
{
SurfaceDestroyItem *destroy;
RedChannel *channel;
if (!dcc || worker->display_channel->common.during_target_migrate ||
!dcc->surface_client_created[surface_id]) {
return;
}
dcc->surface_client_created[surface_id] = FALSE;
channel = &worker->display_channel->common.base;
destroy = get_surface_destroy_item(channel, surface_id);
red_channel_client_pipe_add(&dcc->common.base, &destroy->pipe_item);
}
static inline void red_destroy_surface(RedWorker *worker, uint32_t surface_id)
{
RedSurface *surface = &worker->surfaces[surface_id];
DisplayChannelClient *dcc;
RingItem *link, *next;
if (!--surface->refs) {
// only primary surface streams are supported
if (is_primary_surface(worker, surface_id)) {
red_reset_stream_trace(worker);
}
spice_assert(surface->context.canvas);
surface->context.canvas->ops->destroy(surface->context.canvas);
if (surface->create.info) {
worker->qxl->st->qif->release_resource(worker->qxl, surface->create);
}
if (surface->destroy.info) {
worker->qxl->st->qif->release_resource(worker->qxl, surface->destroy);
}
region_destroy(&surface->draw_dirty_region);
surface->context.canvas = NULL;
WORKER_FOREACH_DCC_SAFE(worker, link, next, dcc) {
red_destroy_surface_item(worker, dcc, surface_id);
}
spice_warn_if(!ring_is_empty(&surface->depend_on_me));
}
}
static inline void set_surface_release_info(RedWorker *worker, uint32_t surface_id, int is_create,
QXLReleaseInfo *release_info, uint32_t group_id)
{
RedSurface *surface;
surface = &worker->surfaces[surface_id];
if (is_create) {
surface->create.info = release_info;
surface->create.group_id = group_id;
} else {
surface->destroy.info = release_info;
surface->destroy.group_id = group_id;
}
}
static RedDrawable *ref_red_drawable(RedDrawable *drawable)
{
drawable->refs++;
return drawable;
}
static inline void put_red_drawable(RedWorker *worker, RedDrawable *red_drawable,
uint32_t group_id)
{
QXLReleaseInfoExt release_info_ext;
if (--red_drawable->refs) {
return;
}
worker->red_drawable_count--;
release_info_ext.group_id = group_id;
release_info_ext.info = red_drawable->release_info;
worker->qxl->st->qif->release_resource(worker->qxl, release_info_ext);
red_put_drawable(red_drawable);
free(red_drawable);
}
static void remove_depended_item(DependItem *item)
{
spice_assert(item->drawable);
spice_assert(ring_item_is_linked(&item->ring_item));
item->drawable = NULL;
ring_remove(&item->ring_item);
}
static inline void red_dec_surfaces_drawable_dependencies(RedWorker *worker, Drawable *drawable)
{
int x;
int surface_id;
for (x = 0; x < 3; ++x) {
surface_id = drawable->surfaces_dest[x];
if (surface_id == -1) {
continue;
}
red_destroy_surface(worker, surface_id);
}
}
static void remove_drawable_dependencies(RedWorker *worker, Drawable *drawable)
{
int x;
int surface_id;
for (x = 0; x < 3; ++x) {
surface_id = drawable->surfaces_dest[x];
if (surface_id != -1 && drawable->depend_items[x].drawable) {
remove_depended_item(&drawable->depend_items[x]);
}
}
}
static inline void release_drawable(RedWorker *worker, Drawable *drawable)
{
RingItem *item, *next;
if (!--drawable->refs) {
spice_assert(!drawable->tree_item.shadow);
spice_assert(ring_is_empty(&drawable->pipes));
if (drawable->stream) {
red_detach_stream(worker, drawable->stream, TRUE);
}
region_destroy(&drawable->tree_item.base.rgn);
remove_drawable_dependencies(worker, drawable);
red_dec_surfaces_drawable_dependencies(worker, drawable);
red_destroy_surface(worker, drawable->surface_id);
RING_FOREACH_SAFE(item, next, &drawable->glz_ring) {
SPICE_CONTAINEROF(item, RedGlzDrawable, drawable_link)->drawable = NULL;
ring_remove(item);
}
put_red_drawable(worker, drawable->red_drawable, drawable->group_id);
free_drawable(worker, drawable);
worker->drawable_count--;
}
}
static inline void remove_shadow(RedWorker *worker, DrawItem *item)
{
Shadow *shadow;
if (!item->shadow) {
return;
}
shadow = item->shadow;
item->shadow = NULL;
ring_remove(&shadow->base.siblings_link);
region_destroy(&shadow->base.rgn);
region_destroy(&shadow->on_hold);
free(shadow);
worker->shadows_count--;
}
static inline void current_remove_container(RedWorker *worker, Container *container)
{
spice_assert(ring_is_empty(&container->items));
worker->containers_count--;
ring_remove(&container->base.siblings_link);
region_destroy(&container->base.rgn);
free(container);
}
static inline void container_cleanup(RedWorker *worker, Container *container)
{
while (container && container->items.next == container->items.prev) {
Container *next = container->base.container;
if (container->items.next != &container->items) {
TreeItem *item = (TreeItem *)ring_get_head(&container->items);
spice_assert(item);
ring_remove(&item->siblings_link);
ring_add_after(&item->siblings_link, &container->base.siblings_link);
item->container = container->base.container;
}
current_remove_container(worker, container);
container = next;
}
}
static inline void red_add_item_trace(RedWorker *worker, Drawable *item)
{
ItemTrace *trace;
if (!item->streamable) {
return;
}
trace = &worker->items_trace[worker->next_item_trace++ & ITEMS_TRACE_MASK];
trace->time = item->creation_time;
trace->frames_count = item->frames_count;
trace->gradual_frames_count = item->gradual_frames_count;
trace->last_gradual_frame = item->last_gradual_frame;
SpiceRect* src_area = &item->red_drawable->u.copy.src_area;
trace->width = src_area->right - src_area->left;
trace->height = src_area->bottom - src_area->top;
trace->dest_area = item->red_drawable->bbox;
}
static void surface_flush(RedWorker *worker, int surface_id, SpiceRect *rect)
{
red_update_area(worker, rect, surface_id);
}
static void red_flush_source_surfaces(RedWorker *worker, Drawable *drawable)
{
int x;
int surface_id;
for (x = 0; x < 3; ++x) {
surface_id = drawable->surfaces_dest[x];
if (surface_id != -1 && drawable->depend_items[x].drawable) {
remove_depended_item(&drawable->depend_items[x]);
surface_flush(worker, surface_id, &drawable->red_drawable->surfaces_rects[x]);
}
}
}
static inline void current_remove_drawable(RedWorker *worker, Drawable *item)
{
if (item->tree_item.effect != QXL_EFFECT_OPAQUE) {
worker->transparent_count--;
}
if (!item->stream) {
red_add_item_trace(worker, item);
}
remove_shadow(worker, &item->tree_item);
ring_remove(&item->tree_item.base.siblings_link);
ring_remove(&item->list_link);
ring_remove(&item->surface_list_link);
release_drawable(worker, item);
worker->current_size--;
}
static void remove_drawable(RedWorker *worker, Drawable *drawable)
{
red_pipes_remove_drawable(drawable);
current_remove_drawable(worker, drawable);
}
static inline void current_remove(RedWorker *worker, TreeItem *item)
{
TreeItem *now = item;
for (;;) {
Container *container = now->container;
RingItem *ring_item;
if (now->type == TREE_ITEM_TYPE_DRAWABLE) {
ring_item = now->siblings_link.prev;
remove_drawable(worker, SPICE_CONTAINEROF(now, Drawable, tree_item));
} else {
Container *container = (Container *)now;
spice_assert(now->type == TREE_ITEM_TYPE_CONTAINER);
if ((ring_item = ring_get_head(&container->items))) {
now = SPICE_CONTAINEROF(ring_item, TreeItem, siblings_link);
continue;
}
ring_item = now->siblings_link.prev;
current_remove_container(worker, container);
}
if (now == item) {
return;
}
if ((ring_item = ring_next(&container->items, ring_item))) {
now = SPICE_CONTAINEROF(ring_item, TreeItem, siblings_link);
} else {
now = (TreeItem *)container;
}
}
}
static void current_tree_for_each(Ring *ring, void (*f)(TreeItem *, void *), void * data)
{
RingItem *ring_item;
Ring *top_ring;
if (!(ring_item = ring_get_head(ring))) {
return;
}
top_ring = ring;
for (;;) {
TreeItem *now = SPICE_CONTAINEROF(ring_item, TreeItem, siblings_link);
f(now, data);
if (now->type == TREE_ITEM_TYPE_CONTAINER) {
Container *container = (Container *)now;
if ((ring_item = ring_get_head(&container->items))) {
ring = &container->items;
continue;
}
}
for (;;) {
ring_item = ring_next(ring, &now->siblings_link);
if (ring_item) {
break;
}
if (ring == top_ring) {
return;
}
now = (TreeItem *)now->container;
ring = (now->container) ? &now->container->items : top_ring;
}
}
}
static void red_current_clear(RedWorker *worker, int surface_id)
{
RingItem *ring_item;
while ((ring_item = ring_get_head(&worker->surfaces[surface_id].current))) {
TreeItem *now = SPICE_CONTAINEROF(ring_item, TreeItem, siblings_link);
current_remove(worker, now);
}
}
static void red_clear_surface_drawables_from_pipe(DisplayChannelClient *dcc, int surface_id,
int force)
{
Ring *ring;
PipeItem *item;
int x;
RedChannelClient *rcc;
if (!dcc) {
return;
}
/* removing the newest drawables that their destination is surface_id and
no other drawable depends on them */
rcc = &dcc->common.base;
ring = &dcc->common.base.pipe;
item = (PipeItem *) ring;
while ((item = (PipeItem *)ring_next(ring, (RingItem *)item))) {
Drawable *drawable;
DrawablePipeItem *dpi = NULL;
int depend_found = FALSE;
if (item->type == PIPE_ITEM_TYPE_DRAW) {
dpi = SPICE_CONTAINEROF(item, DrawablePipeItem, dpi_pipe_item);
drawable = dpi->drawable;
} else if (item->type == PIPE_ITEM_TYPE_UPGRADE) {
drawable = ((UpgradeItem *)item)->drawable;
} else {
continue;
}
if (drawable->surface_id == surface_id) {
PipeItem *tmp_item = item;
item = (PipeItem *)ring_prev(ring, (RingItem *)item);
red_channel_client_pipe_remove_and_release(rcc, tmp_item);
if (!item) {
item = (PipeItem *)ring;
}
continue;
}
for (x = 0; x < 3; ++x) {
if (drawable->surfaces_dest[x] == surface_id) {
depend_found = TRUE;
break;
}
}
if (depend_found) {
spice_debug("surface %d dependent item found %p, %p", surface_id, drawable, item);
if (force) {
break;
} else {
return;
}
}
}
if (item) {
red_wait_pipe_item_sent(&dcc->common.base, item);
}
}
static void red_wait_outgoing_item(RedChannelClient *rcc);
static void red_clear_surface_drawables_from_pipes(RedWorker *worker, int surface_id,
int force, int wait_for_outgoing_item)
{
RingItem *item, *next;
DisplayChannelClient *dcc;
WORKER_FOREACH_DCC_SAFE(worker, item, next, dcc) {
red_clear_surface_drawables_from_pipe(dcc, surface_id, force);
if (wait_for_outgoing_item) {
// in case that the pipe didn't contain any item that is dependent on the surface, but
// there is one during sending.
red_wait_outgoing_item(&dcc->common.base);
}
}
}
#ifdef PIPE_DEBUG
static void print_rgn(const char* prefix, const QRegion* rgn)
{
int i;
printf("TEST: %s: RGN: bbox %u %u %u %u\n",
prefix,
rgn->bbox.top,
rgn->bbox.left,
rgn->bbox.bottom,
rgn->bbox.right);
for (i = 0; i < rgn->num_rects; i++) {
printf("TEST: %s: RECT %u %u %u %u\n",
prefix,
rgn->rects[i].top,
rgn->rects[i].left,
rgn->rects[i].bottom,
rgn->rects[i].right);
}
}
static void print_draw_item(const char* prefix, const DrawItem *draw_item)
{
const TreeItem *base = &draw_item->base;
const Drawable *drawable = SPICE_CONTAINEROF(draw_item, Drawable, tree_item);
printf("TEST: %s: draw id %u container %u effect %u",
prefix,
base->id, base->container ? base->container->base.id : 0,
draw_item->effect);
if (draw_item->shadow) {
printf(" shadow %u\n", draw_item->shadow->base.id);
} else {
printf("\n");
}
print_rgn(prefix, &base->rgn);
}
static void print_shadow_item(const char* prefix, const Shadow *item)
{
printf("TEST: %s: shadow %p id %d\n", prefix, item, item->base.id);
print_rgn(prefix, &item->base.rgn);
}
static void print_container_item(const char* prefix, const Container *item)
{
printf("TEST: %s: container %p id %d\n", prefix, item, item->base.id);
print_rgn(prefix, &item->base.rgn);
}
static void print_base_item(const char* prefix, const TreeItem *base)
{
switch (base->type) {
case TREE_ITEM_TYPE_DRAWABLE:
print_draw_item(prefix, (const DrawItem *)base);
break;
case TREE_ITEM_TYPE_SHADOW:
print_shadow_item(prefix, (const Shadow *)base);
break;
case TREE_ITEM_TYPE_CONTAINER:
print_container_item(prefix, (const Container *)base);
break;
default:
spice_error("invalid type %u", base->type);
}
}
void __show_current(TreeItem *item, void *data)
{
print_base_item("TREE", item);
}
static void show_current(RedWorker *worker, Ring *ring)
{
if (ring_is_empty(ring)) {
spice_info("TEST: TREE: EMPTY");
return;
}
current_tree_for_each(ring, __show_current, NULL);
}
#else
#define print_rgn(a, b)
#define print_draw_private(a, b)
#define show_current(a, r)
#define print_shadow_item(a, b)
#define print_base_item(a, b)
#endif
static inline Shadow *__find_shadow(TreeItem *item)
{
while (item->type == TREE_ITEM_TYPE_CONTAINER) {
if (!(item = (TreeItem *)ring_get_tail(&((Container *)item)->items))) {
return NULL;
}
}
if (item->type != TREE_ITEM_TYPE_DRAWABLE) {
return NULL;
}
return ((DrawItem *)item)->shadow;
}
static inline Ring *ring_of(RedWorker *worker, Ring *ring, TreeItem *item)
{
return (item->container) ? &item->container->items : ring;
}
static inline int __contained_by(RedWorker *worker, TreeItem *item, Ring *ring)
{
spice_assert(item && ring);
do {
Ring *now = ring_of(worker, ring, item);
if (now == ring) {
return TRUE;
}
} while ((item = (TreeItem *)item->container));
return FALSE;
}
static inline void __exclude_region(RedWorker *worker, Ring *ring, TreeItem *item, QRegion *rgn,
Ring **top_ring, Drawable *frame_candidate)
{
QRegion and_rgn;
#ifdef RED_WORKER_STAT
stat_time_t start_time = stat_now();
#endif
region_clone(&and_rgn, rgn);
region_and(&and_rgn, &item->rgn);
if (!region_is_empty(&and_rgn)) {
if (IS_DRAW_ITEM(item)) {
DrawItem *draw = (DrawItem *)item;
if (draw->effect == QXL_EFFECT_OPAQUE) {
region_exclude(rgn, &and_rgn);
}
if (draw->shadow) {
Shadow *shadow;
int32_t x = item->rgn.extents.x1;
int32_t y = item->rgn.extents.y1;
region_exclude(&draw->base.rgn, &and_rgn);
shadow = draw->shadow;
region_offset(&and_rgn, shadow->base.rgn.extents.x1 - x,
shadow->base.rgn.extents.y1 - y);
region_exclude(&shadow->base.rgn, &and_rgn);
region_and(&and_rgn, &shadow->on_hold);
if (!region_is_empty(&and_rgn)) {
region_exclude(&shadow->on_hold, &and_rgn);
region_or(rgn, &and_rgn);
// in flat representation of current, shadow is always his owner next
if (!__contained_by(worker, (TreeItem*)shadow, *top_ring)) {
*top_ring = ring_of(worker, ring, (TreeItem*)shadow);
}
}
} else {
if (frame_candidate) {
Drawable *drawable = SPICE_CONTAINEROF(draw, Drawable, tree_item);
red_stream_maintenance(worker, frame_candidate, drawable);
}
region_exclude(&draw->base.rgn, &and_rgn);
}
} else if (item->type == TREE_ITEM_TYPE_CONTAINER) {
region_exclude(&item->rgn, &and_rgn);
if (region_is_empty(&item->rgn)) { //assume container removal will follow
Shadow *shadow;
region_exclude(rgn, &and_rgn);
if ((shadow = __find_shadow(item))) {
region_or(rgn, &shadow->on_hold);
if (!__contained_by(worker, (TreeItem*)shadow, *top_ring)) {
*top_ring = ring_of(worker, ring, (TreeItem*)shadow);
}
}
}
} else {
Shadow *shadow;
spice_assert(item->type == TREE_ITEM_TYPE_SHADOW);
shadow = (Shadow *)item;
region_exclude(rgn, &and_rgn);
region_or(&shadow->on_hold, &and_rgn);
}
}
region_destroy(&and_rgn);
stat_add(&worker->__exclude_stat, start_time);
}
static void exclude_region(RedWorker *worker, Ring *ring, RingItem *ring_item, QRegion *rgn,
TreeItem **last, Drawable *frame_candidate)
{
#ifdef RED_WORKER_STAT
stat_time_t start_time = stat_now();
#endif
Ring *top_ring;
if (!ring_item) {
return;
}
top_ring = ring;
for (;;) {
TreeItem *now = SPICE_CONTAINEROF(ring_item, TreeItem, siblings_link);
Container *container = now->container;
spice_assert(!region_is_empty(&now->rgn));
if (region_intersects(rgn, &now->rgn)) {
print_base_item("EXCLUDE2", now);
__exclude_region(worker, ring, now, rgn, &top_ring, frame_candidate);
print_base_item("EXCLUDE3", now);
if (region_is_empty(&now->rgn)) {
spice_assert(now->type != TREE_ITEM_TYPE_SHADOW);
ring_item = now->siblings_link.prev;
print_base_item("EXCLUDE_REMOVE", now);
current_remove(worker, now);
if (last && *last == now) {
*last = (TreeItem *)ring_next(ring, ring_item);
}
} else if (now->type == TREE_ITEM_TYPE_CONTAINER) {
Container *container = (Container *)now;
if ((ring_item = ring_get_head(&container->items))) {
ring = &container->items;
spice_assert(((TreeItem *)ring_item)->container);
continue;
}
ring_item = &now->siblings_link;
}
if (region_is_empty(rgn)) {
stat_add(&worker->exclude_stat, start_time);
return;
}
}
while ((last && *last == (TreeItem *)ring_item) ||
!(ring_item = ring_next(ring, ring_item))) {
if (ring == top_ring) {
stat_add(&worker->exclude_stat, start_time);
return;
}
ring_item = &container->base.siblings_link;
container = container->base.container;
ring = (container) ? &container->items : top_ring;
}
}
}
static inline Container *__new_container(RedWorker *worker, DrawItem *item)
{
Container *container = spice_new(Container, 1);
worker->containers_count++;
#ifdef PIPE_DEBUG
container->base.id = ++worker->last_id;
#endif
container->base.type = TREE_ITEM_TYPE_CONTAINER;
container->base.container = item->base.container;
item->base.container = container;
item->container_root = TRUE;
region_clone(&container->base.rgn, &item->base.rgn);
ring_item_init(&container->base.siblings_link);
ring_add_after(&container->base.siblings_link, &item->base.siblings_link);
ring_remove(&item->base.siblings_link);
ring_init(&container->items);
ring_add(&container->items, &item->base.siblings_link);
return container;
}
static inline int is_opaque_item(TreeItem *item)
{
return item->type == TREE_ITEM_TYPE_CONTAINER ||
(IS_DRAW_ITEM(item) && ((DrawItem *)item)->effect == QXL_EFFECT_OPAQUE);
}
static inline void __current_add_drawable(RedWorker *worker, Drawable *drawable, RingItem *pos)
{
RedSurface *surface;
uint32_t surface_id = drawable->surface_id;
surface = &worker->surfaces[surface_id];
ring_add_after(&drawable->tree_item.base.siblings_link, pos);
ring_add(&worker->current_list, &drawable->list_link);
ring_add(&surface->current_list, &drawable->surface_list_link);
worker->current_size++;
drawable->refs++;
}
static int is_equal_path(RedWorker *worker, SpicePath *path1, SpicePath *path2)
{
SpicePathSeg *seg1, *seg2;
int i, j;
if (path1->num_segments != path2->num_segments)
return FALSE;
for (i = 0; i < path1->num_segments; i++) {
seg1 = path1->segments[i];
seg2 = path2->segments[i];
if (seg1->flags != seg2->flags ||
seg1->count != seg2->count) {
return FALSE;
}
for (j = 0; j < seg1->count; j++) {
if (seg1->points[j].x != seg2->points[j].x ||
seg1->points[j].y != seg2->points[j].y) {
return FALSE;
}
}
}
return TRUE;
}
// partial imp
static int is_equal_brush(SpiceBrush *b1, SpiceBrush *b2)
{
return b1->type == b2->type &&
b1->type == SPICE_BRUSH_TYPE_SOLID &&
b1->u.color == b2->u.color;
}
// partial imp
static int is_equal_line_attr(SpiceLineAttr *a1, SpiceLineAttr *a2)
{
return a1->flags == a2->flags &&
a1->style_nseg == a2->style_nseg &&
a1->style_nseg == 0;
}
// partial imp
static int is_same_geometry(RedWorker *worker, Drawable *d1, Drawable *d2)
{
if (d1->red_drawable->type != d2->red_drawable->type) {
return FALSE;
}
switch (d1->red_drawable->type) {
case QXL_DRAW_STROKE:
return is_equal_line_attr(&d1->red_drawable->u.stroke.attr,
&d2->red_drawable->u.stroke.attr) &&
is_equal_path(worker, d1->red_drawable->u.stroke.path,
d2->red_drawable->u.stroke.path);
case QXL_DRAW_FILL:
return rect_is_equal(&d1->red_drawable->bbox, &d2->red_drawable->bbox);
default:
return FALSE;
}
}
static int is_same_drawable(RedWorker *worker, Drawable *d1, Drawable *d2)
{
if (!is_same_geometry(worker, d1, d2)) {
return FALSE;
}
switch (d1->red_drawable->type) {
case QXL_DRAW_STROKE:
return is_equal_brush(&d1->red_drawable->u.stroke.brush,
&d2->red_drawable->u.stroke.brush);
case QXL_DRAW_FILL:
return is_equal_brush(&d1->red_drawable->u.fill.brush,
&d2->red_drawable->u.fill.brush);
default:
return FALSE;
}
}
static inline void red_free_stream(RedWorker *worker, Stream *stream)
{
if (stream->input_fps_timer) {
spice_timer_remove(stream->input_fps_timer);
}
stream->next = worker->free_streams;
worker->free_streams = stream;
}
static void red_release_stream(RedWorker *worker, Stream *stream)
{
if (!--stream->refs) {
spice_assert(!ring_item_is_linked(&stream->link));
red_free_stream(worker, stream);
worker->stream_count--;
}
}
static inline void red_detach_stream(RedWorker *worker, Stream *stream, int detach_sized)
{
spice_assert(stream->current && stream->current->stream);
spice_assert(stream->current->stream == stream);
stream->current->stream = NULL;
if (detach_sized) {
stream->current->sized_stream = NULL;
}
stream->current = NULL;
}
static StreamClipItem *__new_stream_clip(DisplayChannelClient* dcc, StreamAgent *agent)
{
StreamClipItem *item = spice_new(StreamClipItem, 1);
red_channel_pipe_item_init(dcc->common.base.channel,
(PipeItem *)item, PIPE_ITEM_TYPE_STREAM_CLIP);
item->stream_agent = agent;
agent->stream->refs++;
item->refs = 1;
return item;
}
static void push_stream_clip(DisplayChannelClient* dcc, StreamAgent *agent)
{
StreamClipItem *item = __new_stream_clip(dcc, agent);
int n_rects;
if (!item) {
spice_critical("alloc failed");
}
item->clip_type = SPICE_CLIP_TYPE_RECTS;
n_rects = pixman_region32_n_rects(&agent->clip);
item->rects = spice_malloc_n_m(n_rects, sizeof(SpiceRect), sizeof(SpiceClipRects));
item->rects->num_rects = n_rects;
region_ret_rects(&agent->clip, item->rects->rects, n_rects);
red_channel_client_pipe_add(&dcc->common.base, (PipeItem *)item);
}
static void red_display_release_stream_clip(RedWorker *worker, StreamClipItem *item)
{
if (!--item->refs) {
red_display_release_stream(worker, item->stream_agent);
free(item->rects);
free(item);
}
}
static inline int get_stream_id(RedWorker *worker, Stream *stream)
{
return (int)(stream - worker->streams_buf);
}
static void red_attach_stream(RedWorker *worker, Drawable *drawable, Stream *stream)
{
DisplayChannelClient *dcc;
RingItem *item, *next;
spice_assert(!drawable->stream && !stream->current);
spice_assert(drawable && stream);
stream->current = drawable;
drawable->stream = stream;
stream->last_time = drawable->creation_time;
stream->num_input_frames++;
WORKER_FOREACH_DCC_SAFE(worker, item, next, dcc) {
StreamAgent *agent;
QRegion clip_in_draw_dest;
agent = &dcc->stream_agents[get_stream_id(worker, stream)];
region_or(&agent->vis_region, &drawable->tree_item.base.rgn);
region_init(&clip_in_draw_dest);
region_add(&clip_in_draw_dest, &drawable->red_drawable->bbox);
region_and(&clip_in_draw_dest, &agent->clip);
if (!region_is_equal(&clip_in_draw_dest, &drawable->tree_item.base.rgn)) {
region_remove(&agent->clip, &drawable->red_drawable->bbox);
region_or(&agent->clip, &drawable->tree_item.base.rgn);
push_stream_clip(dcc, agent);
}
#ifdef STREAM_STATS
agent->stats.num_input_frames++;
#endif
}
}
static void red_print_stream_stats(DisplayChannelClient *dcc, StreamAgent *agent)
{
#ifdef STREAM_STATS
StreamStats *stats = &agent->stats;
double passed_mm_time = (stats->end - stats->start) / 1000.0;
MJpegEncoderStats encoder_stats = {0};
if (agent->mjpeg_encoder) {
mjpeg_encoder_get_stats(agent->mjpeg_encoder, &encoder_stats);
}
spice_debug("stream=%ld dim=(%dx%d) #in-frames=%lu #in-avg-fps=%.2f #out-frames=%lu "
"out/in=%.2f #drops=%lu (#pipe=%lu #fps=%lu) out-avg-fps=%.2f "
"passed-mm-time(sec)=%.2f size-total(MB)=%.2f size-per-sec(Mbps)=%.2f "
"size-per-frame(KBpf)=%.2f avg-quality=%.2f "
"start-bit-rate(Mbps)=%.2f end-bit-rate(Mbps)=%.2f",
agent - dcc->stream_agents, agent->stream->width, agent->stream->height,
stats->num_input_frames,
stats->num_input_frames / passed_mm_time,
stats->num_frames_sent,
(stats->num_frames_sent + 0.0) / stats->num_input_frames,
stats->num_drops_pipe +
stats->num_drops_fps,
stats->num_drops_pipe,
stats->num_drops_fps,
stats->num_frames_sent / passed_mm_time,
passed_mm_time,
stats->size_sent / 1024.0 / 1024.0,
((stats->size_sent * 8.0) / (1024.0 * 1024)) / passed_mm_time,
stats->size_sent / 1000.0 / stats->num_frames_sent,
encoder_stats.avg_quality,
encoder_stats.starting_bit_rate / (1024.0 * 1024),
encoder_stats.cur_bit_rate / (1024.0 * 1024));
#endif
}
static void red_stop_stream(RedWorker *worker, Stream *stream)
{
DisplayChannelClient *dcc;
RingItem *item, *next;
spice_assert(ring_item_is_linked(&stream->link));
spice_assert(!stream->current);
spice_debug("stream %d", get_stream_id(worker, stream));
WORKER_FOREACH_DCC_SAFE(worker, item, next, dcc) {
StreamAgent *stream_agent;
stream_agent = &dcc->stream_agents[get_stream_id(worker, stream)];
region_clear(&stream_agent->vis_region);
region_clear(&stream_agent->clip);
spice_assert(!pipe_item_is_linked(&stream_agent->destroy_item));
if (stream_agent->mjpeg_encoder && dcc->use_mjpeg_encoder_rate_control) {
uint64_t stream_bit_rate = mjpeg_encoder_get_bit_rate(stream_agent->mjpeg_encoder);
if (stream_bit_rate > dcc->streams_max_bit_rate) {
spice_debug("old max-bit-rate=%.2f new=%.2f",
dcc->streams_max_bit_rate / 8.0 / 1024.0 / 1024.0,
stream_bit_rate / 8.0 / 1024.0 / 1024.0);
dcc->streams_max_bit_rate = stream_bit_rate;
}
}
stream->refs++;
red_channel_client_pipe_add(&dcc->common.base, &stream_agent->destroy_item);
red_print_stream_stats(dcc, stream_agent);
}
worker->streams_size_total -= stream->width * stream->height;
ring_remove(&stream->link);
red_release_stream(worker, stream);
}
static int red_display_drawable_is_in_pipe(DisplayChannelClient *dcc, Drawable *drawable)
{
DrawablePipeItem *dpi;
RingItem *dpi_link, *dpi_next;
DRAWABLE_FOREACH_DPI_SAFE(drawable, dpi_link, dpi_next, dpi) {
if (dpi->dcc == dcc) {
return TRUE;
}
}
return FALSE;
}
/*
* after red_display_detach_stream_gracefully is called for all the display channel clients,
* red_detach_stream should be called. See comment (1).
*/
static inline void red_display_detach_stream_gracefully(DisplayChannelClient *dcc,
Stream *stream,
Drawable *update_area_limit)
{
int stream_id = get_stream_id(dcc->common.worker, stream);
StreamAgent *agent = &dcc->stream_agents[stream_id];
/* stopping the client from playing older frames at once*/
region_clear(&agent->clip);
push_stream_clip(dcc, agent);
if (region_is_empty(&agent->vis_region)) {
spice_debug("stream %d: vis region empty", stream_id);
return;
}
if (stream->current &&
region_contains(&stream->current->tree_item.base.rgn, &agent->vis_region)) {
RedChannel *channel;
RedChannelClient *rcc;
UpgradeItem *upgrade_item;
int n_rects;
/* (1) The caller should detach the drawable from the stream. This will
* lead to sending the drawable losslessly, as an ordinary drawable. */
if (red_display_drawable_is_in_pipe(dcc, stream->current)) {
spice_debug("stream %d: upgrade by linked drawable. sized %d, box ==>",
stream_id, stream->current->sized_stream != NULL);
rect_debug(&stream->current->red_drawable->bbox);
goto clear_vis_region;
}
spice_debug("stream %d: upgrade by drawable. sized %d, box ==>",
stream_id, stream->current->sized_stream != NULL);
rect_debug(&stream->current->red_drawable->bbox);
rcc = &dcc->common.base;
channel = rcc->channel;
upgrade_item = spice_new(UpgradeItem, 1);
upgrade_item->refs = 1;
red_channel_pipe_item_init(channel,
&upgrade_item->base, PIPE_ITEM_TYPE_UPGRADE);
upgrade_item->drawable = stream->current;
upgrade_item->drawable->refs++;
n_rects = pixman_region32_n_rects(&upgrade_item->drawable->tree_item.base.rgn);
upgrade_item->rects = spice_malloc_n_m(n_rects, sizeof(SpiceRect), sizeof(SpiceClipRects));
upgrade_item->rects->num_rects = n_rects;
region_ret_rects(&upgrade_item->drawable->tree_item.base.rgn,
upgrade_item->rects->rects, n_rects);
red_channel_client_pipe_add(rcc, &upgrade_item->base);
} else {
SpiceRect upgrade_area;
region_extents(&agent->vis_region, &upgrade_area);
spice_debug("stream %d: upgrade by screenshot. has current %d. box ==>",
stream_id, stream->current != NULL);
rect_debug(&upgrade_area);
if (update_area_limit) {
red_update_area_till(dcc->common.worker, &upgrade_area, 0, update_area_limit);
} else {
red_update_area(dcc->common.worker, &upgrade_area, 0);
}
red_add_surface_area_image(dcc, 0, &upgrade_area, NULL, FALSE);
}
clear_vis_region:
region_clear(&agent->vis_region);
}
static inline void red_detach_stream_gracefully(RedWorker *worker, Stream *stream,
Drawable *update_area_limit)
{
RingItem *item, *next;
DisplayChannelClient *dcc;
WORKER_FOREACH_DCC_SAFE(worker, item, next, dcc) {
red_display_detach_stream_gracefully(dcc, stream, update_area_limit);
}
if (stream->current) {
red_detach_stream(worker, stream, TRUE);
}
}
/*
* region : a primary surface region. Streams that intersects with the given
* region will be detached.
* drawable: If detaching the stream is triggered by the addition of a new drawable
* that is dependent on the given region, and the drawable is already a part
* of the "current tree", the drawable parameter should be set with
* this drawable, otherwise, it should be NULL. Then, if detaching the stream
* involves sending an upgrade image to the client, this drawable won't be rendered
* (see red_display_detach_stream_gracefully).
*/
static void red_detach_streams_behind(RedWorker *worker, QRegion *region, Drawable *drawable)
{
Ring *ring = &worker->streams;
RingItem *item = ring_get_head(ring);
RingItem *dcc_ring_item, *next;
DisplayChannelClient *dcc;
int has_clients = display_is_connected(worker);
while (item) {
Stream *stream = SPICE_CONTAINEROF(item, Stream, link);
int detach_stream = 0;
item = ring_next(ring, item);
WORKER_FOREACH_DCC_SAFE(worker, dcc_ring_item, next, dcc) {
StreamAgent *agent = &dcc->stream_agents[get_stream_id(worker, stream)];
if (region_intersects(&agent->vis_region, region)) {
red_display_detach_stream_gracefully(dcc, stream, drawable);
detach_stream = 1;
spice_debug("stream %d", get_stream_id(worker, stream));
}
}
if (detach_stream && stream->current) {
red_detach_stream(worker, stream, TRUE);
} else if (!has_clients) {
if (stream->current &&
region_intersects(&stream->current->tree_item.base.rgn, region)) {
red_detach_stream(worker, stream, TRUE);
}
}
}
}
static void red_streams_update_visible_region(RedWorker *worker, Drawable *drawable)
{
Ring *ring;
RingItem *item;
RingItem *dcc_ring_item, *next;
DisplayChannelClient *dcc;
if (!display_is_connected(worker)) {
return;
}
if (!is_primary_surface(worker, drawable->surface_id)) {
return;
}
ring = &worker->streams;
item = ring_get_head(ring);
while (item) {
Stream *stream = SPICE_CONTAINEROF(item, Stream, link);
StreamAgent *agent;
item = ring_next(ring, item);
if (stream->current == drawable) {
continue;
}
WORKER_FOREACH_DCC_SAFE(worker, dcc_ring_item, next, dcc) {
agent = &dcc->stream_agents[get_stream_id(worker, stream)];
if (region_intersects(&agent->vis_region, &drawable->tree_item.base.rgn)) {
region_exclude(&agent->vis_region, &drawable->tree_item.base.rgn);
region_exclude(&agent->clip, &drawable->tree_item.base.rgn);
push_stream_clip(dcc, agent);
}
}
}
}
static inline unsigned int red_get_streams_timout(RedWorker *worker)
{
unsigned int timout = -1;
Ring *ring = &worker->streams;
RingItem *item = ring;
struct timespec time;
clock_gettime(CLOCK_MONOTONIC, &time);
red_time_t now = timespec_to_red_time(&time);
while ((item = ring_next(ring, item))) {
Stream *stream;
stream = SPICE_CONTAINEROF(item, Stream, link);
red_time_t delta = (stream->last_time + RED_STREAM_TIMOUT) - now;
if (delta < 1000 * 1000) {
return 0;
}
timout = MIN(timout, (unsigned int)(delta / (1000 * 1000)));
}
return timout;
}
static inline void red_handle_streams_timout(RedWorker *worker)
{
Ring *ring = &worker->streams;
struct timespec time;
RingItem *item;
clock_gettime(CLOCK_MONOTONIC, &time);
red_time_t now = timespec_to_red_time(&time);
item = ring_get_head(ring);
while (item) {
Stream *stream = SPICE_CONTAINEROF(item, Stream, link);
item = ring_next(ring, item);
if (now >= (stream->last_time + RED_STREAM_TIMOUT)) {
red_detach_stream_gracefully(worker, stream, NULL);
red_stop_stream(worker, stream);
}
}
}
static void red_display_release_stream(RedWorker *worker, StreamAgent *agent)
{
spice_assert(agent->stream);
red_release_stream(worker, agent->stream);
}
static inline Stream *red_alloc_stream(RedWorker *worker)
{
Stream *stream;
if (!worker->free_streams) {
return NULL;
}
stream = worker->free_streams;
worker->free_streams = worker->free_streams->next;
return stream;
}
static uint64_t red_stream_get_initial_bit_rate(DisplayChannelClient *dcc,
Stream *stream)
{
char *env_bit_rate_str;
uint64_t bit_rate = 0;
env_bit_rate_str = getenv("SPICE_BIT_RATE");
if (env_bit_rate_str != NULL) {
double env_bit_rate;
errno = 0;
env_bit_rate = strtod(env_bit_rate_str, NULL);
if (errno == 0) {
bit_rate = env_bit_rate * 1024 * 1024;
} else {
spice_warning("error parsing SPICE_BIT_RATE: %s", strerror(errno));
}
}
if (!bit_rate) {
MainChannelClient *mcc;
uint64_t net_test_bit_rate;
mcc = red_client_get_main(dcc->common.base.client);
net_test_bit_rate = main_channel_client_is_network_info_initialized(mcc) ?
main_channel_client_get_bitrate_per_sec(mcc) :
0;
bit_rate = MAX(dcc->streams_max_bit_rate, net_test_bit_rate);
if (bit_rate == 0) {
/*
* In case we are after a spice session migration,
* the low_bandwidth flag is retrieved from migration data.
* If the network info is not initialized due to another reason,
* the low_bandwidth flag is FALSE.
*/
bit_rate = dcc->common.is_low_bandwidth ?
RED_STREAM_DEFAULT_LOW_START_BIT_RATE :
RED_STREAM_DEFAULT_HIGH_START_BIT_RATE;
}
}
spice_debug("base-bit-rate %.2f (Mbps)", bit_rate / 1024.0 / 1024.0);
/* dividing the available bandwidth among the active streams, and saving
* (1-RED_STREAM_CHANNEL_CAPACITY) of it for other messages */
return (RED_STREAM_CHANNEL_CAPACITY * bit_rate *
stream->width * stream->height) / dcc->common.worker->streams_size_total;
}
static uint32_t red_stream_mjpeg_encoder_get_roundtrip(void *opaque)
{
StreamAgent *agent = opaque;
int roundtrip;
spice_assert(agent);
roundtrip = red_channel_client_get_roundtrip_ms(&agent->dcc->common.base);
if (roundtrip < 0) {
MainChannelClient *mcc = red_client_get_main(agent->dcc->common.base.client);
/*
* the main channel client roundtrip might not have been
* calculated (e.g., after migration). In such case,
* main_channel_client_get_roundtrip_ms returns 0.
*/
roundtrip = main_channel_client_get_roundtrip_ms(mcc);
}
return roundtrip;
}
static uint32_t red_stream_mjpeg_encoder_get_source_fps(void *opaque)
{
StreamAgent *agent = opaque;
spice_assert(agent);
return agent->stream->input_fps;
}
static void red_display_update_streams_max_latency(DisplayChannelClient *dcc, StreamAgent *remove_agent)
{
uint32_t new_max_latency = 0;
int i;
if (dcc->streams_max_latency != remove_agent->client_required_latency) {
return;
}
dcc->streams_max_latency = 0;
if (dcc->common.worker->stream_count == 1) {
return;
}
for (i = 0; i < NUM_STREAMS; i++) {
StreamAgent *other_agent = &dcc->stream_agents[i];
if (other_agent == remove_agent || !other_agent->mjpeg_encoder) {
continue;
}
if (other_agent->client_required_latency > new_max_latency) {
new_max_latency = other_agent->client_required_latency;
}
}
dcc->streams_max_latency = new_max_latency;
}
static void red_display_stream_agent_stop(DisplayChannelClient *dcc, StreamAgent *agent)
{
red_display_update_streams_max_latency(dcc, agent);
if (agent->mjpeg_encoder) {
mjpeg_encoder_destroy(agent->mjpeg_encoder);
agent->mjpeg_encoder = NULL;
}
}
static void red_stream_update_client_playback_latency(void *opaque, uint32_t delay_ms)
{
StreamAgent *agent = opaque;
DisplayChannelClient *dcc = agent->dcc;
red_display_update_streams_max_latency(dcc, agent);
agent->client_required_latency = delay_ms;
if (delay_ms > agent->dcc->streams_max_latency) {
agent->dcc->streams_max_latency = delay_ms;
}
spice_debug("reseting client latency: %u", agent->dcc->streams_max_latency);
main_dispatcher_set_mm_time_latency(agent->dcc->common.base.client, agent->dcc->streams_max_latency);
}
static void red_display_create_stream(DisplayChannelClient *dcc, Stream *stream)
{
StreamAgent *agent = &dcc->stream_agents[get_stream_id(dcc->common.worker, stream)];
stream->refs++;
spice_assert(region_is_empty(&agent->vis_region));
if (stream->current) {
agent->frames = 1;
region_clone(&agent->vis_region, &stream->current->tree_item.base.rgn);
region_clone(&agent->clip, &agent->vis_region);
} else {
agent->frames = 0;
}
agent->drops = 0;
agent->fps = MAX_FPS;
agent->dcc = dcc;
if (dcc->use_mjpeg_encoder_rate_control) {
MJpegEncoderRateControlCbs mjpeg_cbs;
uint64_t initial_bit_rate;
mjpeg_cbs.get_roundtrip_ms = red_stream_mjpeg_encoder_get_roundtrip;
mjpeg_cbs.get_source_fps = red_stream_mjpeg_encoder_get_source_fps;
mjpeg_cbs.update_client_playback_delay = red_stream_update_client_playback_latency;
initial_bit_rate = red_stream_get_initial_bit_rate(dcc, stream);
agent->mjpeg_encoder = mjpeg_encoder_new(TRUE, initial_bit_rate, &mjpeg_cbs, agent);
} else {
agent->mjpeg_encoder = mjpeg_encoder_new(FALSE, 0, NULL, NULL);
}
red_channel_client_pipe_add(&dcc->common.base, &agent->create_item);
if (red_channel_client_test_remote_cap(&dcc->common.base, SPICE_DISPLAY_CAP_STREAM_REPORT)) {
StreamActivateReportItem *report_pipe_item = spice_malloc0(sizeof(*report_pipe_item));
agent->report_id = rand();
red_channel_pipe_item_init(dcc->common.base.channel, &report_pipe_item->pipe_item,
PIPE_ITEM_TYPE_STREAM_ACTIVATE_REPORT);
report_pipe_item->stream_id = get_stream_id(dcc->common.worker, stream);
red_channel_client_pipe_add(&dcc->common.base, &report_pipe_item->pipe_item);
}
#ifdef STREAM_STATS
memset(&agent->stats, 0, sizeof(StreamStats));
if (stream->current) {
agent->stats.start = stream->current->red_drawable->mm_time;
}
#endif
}
static void red_stream_input_fps_timer_cb(void *opaque)
{
Stream *stream = opaque;
uint64_t now = red_now();
double duration_sec;
spice_assert(opaque);
if (now == stream->input_fps_timer_start) {
spice_warning("timer start and expiry time are equal");
return;
}
duration_sec = (now - stream->input_fps_timer_start)/(1000.0*1000*1000);
stream->input_fps = stream->num_input_frames / duration_sec;
spice_debug("input-fps=%u", stream->input_fps);
stream->num_input_frames = 0;
stream->input_fps_timer_start = now;
}
static void red_create_stream(RedWorker *worker, Drawable *drawable)
{
DisplayChannelClient *dcc;
RingItem *dcc_ring_item, *next;
Stream *stream;
SpiceRect* src_rect;
spice_assert(!drawable->stream);
if (!(stream = red_alloc_stream(worker))) {
return;
}
spice_assert(drawable->red_drawable->type == QXL_DRAW_COPY);
src_rect = &drawable->red_drawable->u.copy.src_area;
ring_add(&worker->streams, &stream->link);
stream->current = drawable;
stream->last_time = drawable->creation_time;
stream->width = src_rect->right - src_rect->left;
stream->height = src_rect->bottom - src_rect->top;
stream->dest_area = drawable->red_drawable->bbox;
stream->refs = 1;
SpiceBitmap *bitmap = &drawable->red_drawable->u.copy.src_bitmap->u.bitmap;
stream->top_down = !!(bitmap->flags & SPICE_BITMAP_FLAGS_TOP_DOWN);
drawable->stream = stream;
stream->input_fps_timer = spice_timer_queue_add(red_stream_input_fps_timer_cb, stream);
spice_assert(stream->input_fps_timer);
spice_timer_set(stream->input_fps_timer, RED_STREAM_INPUT_FPS_TIMEOUT);
stream->num_input_frames = 0;
stream->input_fps_timer_start = red_now();
stream->input_fps = MAX_FPS;
worker->streams_size_total += stream->width * stream->height;
worker->stream_count++;
WORKER_FOREACH_DCC_SAFE(worker, dcc_ring_item, next, dcc) {
red_display_create_stream(dcc, stream);
}
spice_debug("stream %d %dx%d (%d, %d) (%d, %d)", (int)(stream - worker->streams_buf), stream->width,
stream->height, stream->dest_area.left, stream->dest_area.top,
stream->dest_area.right, stream->dest_area.bottom);
return;
}
static void red_disply_start_streams(DisplayChannelClient *dcc)
{
Ring *ring = &dcc->common.worker->streams;
RingItem *item = ring;
while ((item = ring_next(ring, item))) {
Stream *stream = SPICE_CONTAINEROF(item, Stream, link);
red_display_create_stream(dcc, stream);
}
}
static void red_display_client_init_streams(DisplayChannelClient *dcc)
{
int i;
RedWorker *worker = dcc->common.worker;
RedChannel *channel = dcc->common.base.channel;
for (i = 0; i < NUM_STREAMS; i++) {
StreamAgent *agent = &dcc->stream_agents[i];
agent->stream = &worker->streams_buf[i];
region_init(&agent->vis_region);
region_init(&agent->clip);
red_channel_pipe_item_init(channel, &agent->create_item, PIPE_ITEM_TYPE_STREAM_CREATE);
red_channel_pipe_item_init(channel, &agent->destroy_item, PIPE_ITEM_TYPE_STREAM_DESTROY);
}
dcc->use_mjpeg_encoder_rate_control =
red_channel_client_test_remote_cap(&dcc->common.base, SPICE_DISPLAY_CAP_STREAM_REPORT);
}
static void red_display_destroy_streams_agents(DisplayChannelClient *dcc)
{
int i;
for (i = 0; i < NUM_STREAMS; i++) {
StreamAgent *agent = &dcc->stream_agents[i];
region_destroy(&agent->vis_region);
region_destroy(&agent->clip);
if (agent->mjpeg_encoder) {
mjpeg_encoder_destroy(agent->mjpeg_encoder);
agent->mjpeg_encoder = NULL;
}
}
}
static void red_init_streams(RedWorker *worker)
{
int i;
ring_init(&worker->streams);
worker->free_streams = NULL;
for (i = 0; i < NUM_STREAMS; i++) {
Stream *stream = &worker->streams_buf[i];
ring_item_init(&stream->link);
red_free_stream(worker, stream);
}
}
static inline int __red_is_next_stream_frame(RedWorker *worker,
const Drawable *candidate,
const int other_src_width,
const int other_src_height,
const SpiceRect *other_dest,
const red_time_t other_time,
const Stream *stream,
int container_candidate_allowed)
{
RedDrawable *red_drawable;
int is_frame_container = FALSE;
if (!candidate->streamable) {
return STREAM_FRAME_NONE;
}
if (candidate->creation_time - other_time >
(stream ? RED_STREAM_CONTINUS_MAX_DELTA : RED_STREAM_DETACTION_MAX_DELTA)) {
return STREAM_FRAME_NONE;
}
red_drawable = candidate->red_drawable;
if (!container_candidate_allowed) {
SpiceRect* candidate_src;
if (!rect_is_equal(&red_drawable->bbox, other_dest)) {
return STREAM_FRAME_NONE;
}
candidate_src = &red_drawable->u.copy.src_area;
if (candidate_src->right - candidate_src->left != other_src_width ||
candidate_src->bottom - candidate_src->top != other_src_height) {
return STREAM_FRAME_NONE;
}
} else {
if (rect_contains(&red_drawable->bbox, other_dest)) {
int candidate_area = rect_get_area(&red_drawable->bbox);
int other_area = rect_get_area(other_dest);
/* do not stream drawables that are significantly
* bigger than the original frame */
if (candidate_area > 2 * other_area) {
spice_debug("too big candidate:");
spice_debug("prev box ==>");
rect_debug(other_dest);
spice_debug("new box ==>");
rect_debug(&red_drawable->bbox);
return STREAM_FRAME_NONE;
}
if (candidate_area > other_area) {
is_frame_container = TRUE;
}
} else {
return STREAM_FRAME_NONE;
}
}
if (stream) {
SpiceBitmap *bitmap = &red_drawable->u.copy.src_bitmap->u.bitmap;
if (stream->top_down != !!(bitmap->flags & SPICE_BITMAP_FLAGS_TOP_DOWN)) {
return STREAM_FRAME_NONE;
}
}
if (is_frame_container) {
return STREAM_FRAME_CONTAINER;
} else {
return STREAM_FRAME_NATIVE;
}
}
static inline int red_is_next_stream_frame(RedWorker *worker, const Drawable *candidate,
const Drawable *prev)
{
if (!candidate->streamable) {
return FALSE;
}
SpiceRect* prev_src = &prev->red_drawable->u.copy.src_area;
return __red_is_next_stream_frame(worker, candidate, prev_src->right - prev_src->left,
prev_src->bottom - prev_src->top,
&prev->red_drawable->bbox, prev->creation_time,
prev->stream,
FALSE);
}
static inline void pre_stream_item_swap(RedWorker *worker, Stream *stream, Drawable *new_frame)
{
DrawablePipeItem *dpi;
DisplayChannelClient *dcc;
int index;
StreamAgent *agent;
RingItem *ring_item, *next;
spice_assert(stream->current);
if (!display_is_connected(worker)) {
return;
}
if (new_frame->process_commands_generation == stream->current->process_commands_generation) {
spice_debug("ignoring drop, same process_commands_generation as previous frame");
return;
}
index = get_stream_id(worker, stream);
DRAWABLE_FOREACH_DPI_SAFE(stream->current, ring_item, next, dpi) {
dcc = dpi->dcc;
agent = &dcc->stream_agents[index];
if (!dcc->use_mjpeg_encoder_rate_control &&
!dcc->common.is_low_bandwidth) {
continue;
}
if (pipe_item_is_linked(&dpi->dpi_pipe_item)) {
#ifdef STREAM_STATS
agent->stats.num_drops_pipe++;
#endif
if (dcc->use_mjpeg_encoder_rate_control) {
mjpeg_encoder_notify_server_frame_drop(agent->mjpeg_encoder);
} else {
++agent->drops;
}
}
}
WORKER_FOREACH_DCC_SAFE(worker, ring_item, next, dcc) {
double drop_factor;
agent = &dcc->stream_agents[index];
if (dcc->use_mjpeg_encoder_rate_control) {
continue;
}
if (agent->frames / agent->fps < FPS_TEST_INTERVAL) {
agent->frames++;
continue;
}
drop_factor = ((double)agent->frames - (double)agent->drops) /
(double)agent->frames;
spice_debug("stream %d: #frames %u #drops %u", index, agent->frames, agent->drops);
if (drop_factor == 1) {
if (agent->fps < MAX_FPS) {
agent->fps++;
spice_debug("stream %d: fps++ %u", index, agent->fps);
}
} else if (drop_factor < 0.9) {
if (agent->fps > 1) {
agent->fps--;
spice_debug("stream %d: fps--%u", index, agent->fps);
}
}
agent->frames = 1;
agent->drops = 0;
}
}
static inline void red_update_copy_graduality(RedWorker* worker, Drawable *drawable)
{
SpiceBitmap *bitmap;
spice_assert(drawable->red_drawable->type == QXL_DRAW_COPY);
if (worker->streaming_video != STREAM_VIDEO_FILTER) {
drawable->copy_bitmap_graduality = BITMAP_GRADUAL_INVALID;
return;
}
if (drawable->copy_bitmap_graduality != BITMAP_GRADUAL_INVALID) {
return; // already set
}
bitmap = &drawable->red_drawable->u.copy.src_bitmap->u.bitmap;
if (!BITMAP_FMT_HAS_GRADUALITY(bitmap->format) || _stride_is_extra(bitmap) ||
(bitmap->data->flags & SPICE_CHUNKS_FLAGS_UNSTABLE)) {
drawable->copy_bitmap_graduality = BITMAP_GRADUAL_NOT_AVAIL;
} else {
drawable->copy_bitmap_graduality =
_get_bitmap_graduality_level(worker, bitmap,drawable->group_id);
}
}
static inline int red_is_stream_start(Drawable *drawable)
{
return ((drawable->frames_count >= RED_STREAM_FRAMES_START_CONDITION) &&
(drawable->gradual_frames_count >=
(RED_STREAM_GRADUAL_FRAMES_START_CONDITION * drawable->frames_count)));
}
// returns whether a stream was created
static int red_stream_add_frame(RedWorker *worker,
Drawable *frame_drawable,
int frames_count,
int gradual_frames_count,
int last_gradual_frame)
{
red_update_copy_graduality(worker, frame_drawable);
frame_drawable->frames_count = frames_count + 1;
frame_drawable->gradual_frames_count = gradual_frames_count;
if (frame_drawable->copy_bitmap_graduality != BITMAP_GRADUAL_LOW) {
if ((frame_drawable->frames_count - last_gradual_frame) >
RED_STREAM_FRAMES_RESET_CONDITION) {
frame_drawable->frames_count = 1;
frame_drawable->gradual_frames_count = 1;
} else {
frame_drawable->gradual_frames_count++;
}
frame_drawable->last_gradual_frame = frame_drawable->frames_count;
} else {
frame_drawable->last_gradual_frame = last_gradual_frame;
}
if (red_is_stream_start(frame_drawable)) {
red_create_stream(worker, frame_drawable);
return TRUE;
}
return FALSE;
}
static inline void red_stream_maintenance(RedWorker *worker, Drawable *candidate, Drawable *prev)
{
Stream *stream;
if (candidate->stream) {
return;
}
if ((stream = prev->stream)) {
int is_next_frame = __red_is_next_stream_frame(worker,
candidate,
stream->width,
stream->height,
&stream->dest_area,
stream->last_time,
stream,
TRUE);
if (is_next_frame != STREAM_FRAME_NONE) {
pre_stream_item_swap(worker, stream, candidate);
red_detach_stream(worker, stream, FALSE);
prev->streamable = FALSE; //prevent item trace
red_attach_stream(worker, candidate, stream);
if (is_next_frame == STREAM_FRAME_CONTAINER) {
candidate->sized_stream = stream;
}
}
} else {
if (red_is_next_stream_frame(worker, candidate, prev) != STREAM_FRAME_NONE) {
red_stream_add_frame(worker, candidate,
prev->frames_count,
prev->gradual_frames_count,
prev->last_gradual_frame);
}
}
}
static inline int is_drawable_independent_from_surfaces(Drawable *drawable)
{
int x;
for (x = 0; x < 3; ++x) {
if (drawable->surfaces_dest[x] != -1) {
return FALSE;
}
}
return TRUE;
}
static inline int red_current_add_equal(RedWorker *worker, DrawItem *item, TreeItem *other)
{
DrawItem *other_draw_item;
Drawable *drawable;
Drawable *other_drawable;
if (other->type != TREE_ITEM_TYPE_DRAWABLE) {
return FALSE;
}
other_draw_item = (DrawItem *)other;
if (item->shadow || other_draw_item->shadow || item->effect != other_draw_item->effect) {
return FALSE;
}
drawable = SPICE_CONTAINEROF(item, Drawable, tree_item);
other_drawable = SPICE_CONTAINEROF(other_draw_item, Drawable, tree_item);
if (item->effect == QXL_EFFECT_OPAQUE) {
int add_after = !!other_drawable->stream &&
is_drawable_independent_from_surfaces(drawable);
red_stream_maintenance(worker, drawable, other_drawable);
__current_add_drawable(worker, drawable, &other->siblings_link);
other_drawable->refs++;
current_remove_drawable(worker, other_drawable);
if (add_after) {
red_pipes_add_drawable_after(worker, drawable, other_drawable);
} else {
red_pipes_add_drawable(worker, drawable);
}
red_pipes_remove_drawable(other_drawable);
release_drawable(worker, other_drawable);
return TRUE;
}
switch (item->effect) {
case QXL_EFFECT_REVERT_ON_DUP:
if (is_same_drawable(worker, drawable, other_drawable)) {
DisplayChannelClient *dcc;
DrawablePipeItem *dpi;
RingItem *worker_ring_item, *dpi_ring_item;
other_drawable->refs++;
current_remove_drawable(worker, other_drawable);
/* sending the drawable to clients that already received
* (or will receive) other_drawable */
worker_ring_item = ring_get_head(&worker->display_channel->common.base.clients);
dpi_ring_item = ring_get_head(&other_drawable->pipes);
/* dpi contains a sublist of dcc's, ordered the same */
while (worker_ring_item) {
dcc = SPICE_CONTAINEROF(worker_ring_item, DisplayChannelClient,
common.base.channel_link);
dpi = SPICE_CONTAINEROF(dpi_ring_item, DrawablePipeItem, base);
while (worker_ring_item && (!dpi || dcc != dpi->dcc)) {
red_pipe_add_drawable(dcc, drawable);
worker_ring_item = ring_next(&worker->display_channel->common.base.clients,
worker_ring_item);
dcc = SPICE_CONTAINEROF(worker_ring_item, DisplayChannelClient,
common.base.channel_link);
}
if (dpi_ring_item) {
dpi_ring_item = ring_next(&other_drawable->pipes, dpi_ring_item);
}
if (worker_ring_item) {
worker_ring_item = ring_next(&worker->display_channel->common.base.clients,
worker_ring_item);
}
}
/* not sending other_drawable where possible */
red_pipes_remove_drawable(other_drawable);
release_drawable(worker, other_drawable);
return TRUE;
}
break;
case QXL_EFFECT_OPAQUE_BRUSH:
if (is_same_geometry(worker, drawable, other_drawable)) {
__current_add_drawable(worker, drawable, &other->siblings_link);
remove_drawable(worker, other_drawable);
red_pipes_add_drawable(worker, drawable);
return TRUE;
}
break;
case QXL_EFFECT_NOP_ON_DUP:
if (is_same_drawable(worker, drawable, other_drawable)) {
return TRUE;
}
break;
}
return FALSE;
}
static inline void red_use_stream_trace(RedWorker *worker, Drawable *drawable)
{
ItemTrace *trace;
ItemTrace *trace_end;
Ring *ring;
RingItem *item;
if (drawable->stream || !drawable->streamable || drawable->frames_count) {
return;
}
ring = &worker->streams;
item = ring_get_head(ring);
while (item) {
Stream *stream = SPICE_CONTAINEROF(item, Stream, link);
int is_next_frame = __red_is_next_stream_frame(worker,
drawable,
stream->width,
stream->height,
&stream->dest_area,
stream->last_time,
stream,
TRUE);
if (is_next_frame != STREAM_FRAME_NONE) {
if (stream->current) {
stream->current->streamable = FALSE; //prevent item trace
pre_stream_item_swap(worker, stream, drawable);
red_detach_stream(worker, stream, FALSE);
}
red_attach_stream(worker, drawable, stream);
if (is_next_frame == STREAM_FRAME_CONTAINER) {
drawable->sized_stream = stream;
}
return;
}
item = ring_next(ring, item);
}
trace = worker->items_trace;
trace_end = trace + NUM_TRACE_ITEMS;
for (; trace < trace_end; trace++) {
if (__red_is_next_stream_frame(worker, drawable, trace->width, trace->height,
&trace->dest_area, trace->time, NULL, FALSE) !=
STREAM_FRAME_NONE) {
if (red_stream_add_frame(worker, drawable,
trace->frames_count,
trace->gradual_frames_count,
trace->last_gradual_frame)) {
return;
}
}
}
}
static void red_reset_stream_trace(RedWorker *worker)
{
Ring *ring = &worker->streams;
RingItem *item = ring_get_head(ring);
while (item) {
Stream *stream = SPICE_CONTAINEROF(item, Stream, link);
item = ring_next(ring, item);
if (!stream->current) {
red_stop_stream(worker, stream);
} else {
spice_info("attached stream");
}
}
worker->next_item_trace = 0;
memset(worker->items_trace, 0, sizeof(worker->items_trace));
}
static inline int red_current_add(RedWorker *worker, Ring *ring, Drawable *drawable)
{
DrawItem *item = &drawable->tree_item;
#ifdef RED_WORKER_STAT
stat_time_t start_time = stat_now();
#endif
RingItem *now;
QRegion exclude_rgn;
RingItem *exclude_base = NULL;
print_base_item("ADD", &item->base);
spice_assert(!region_is_empty(&item->base.rgn));
region_init(&exclude_rgn);
now = ring_next(ring, ring);
while (now) {
TreeItem *sibling = SPICE_CONTAINEROF(now, TreeItem, siblings_link);
int test_res;
if (!region_bounds_intersects(&item->base.rgn, &sibling->rgn)) {
print_base_item("EMPTY", sibling);
now = ring_next(ring, now);
continue;
}
test_res = region_test(&item->base.rgn, &sibling->rgn, REGION_TEST_ALL);
if (!(test_res & REGION_TEST_SHARED)) {
print_base_item("EMPTY", sibling);
now = ring_next(ring, now);
continue;
} else if (sibling->type != TREE_ITEM_TYPE_SHADOW) {
if (!(test_res & REGION_TEST_RIGHT_EXCLUSIVE) &&
!(test_res & REGION_TEST_LEFT_EXCLUSIVE) &&
red_current_add_equal(worker, item, sibling)) {
stat_add(&worker->add_stat, start_time);
return FALSE;
}
if (!(test_res & REGION_TEST_RIGHT_EXCLUSIVE) && item->effect == QXL_EFFECT_OPAQUE) {
Shadow *shadow;
int skip = now == exclude_base;
print_base_item("CONTAIN", sibling);
if ((shadow = __find_shadow(sibling))) {
if (exclude_base) {
TreeItem *next = sibling;
exclude_region(worker, ring, exclude_base, &exclude_rgn, &next, NULL);
if (next != sibling) {
now = next ? &next->siblings_link : NULL;
exclude_base = NULL;
continue;
}
}
region_or(&exclude_rgn, &shadow->on_hold);
}
now = now->prev;
current_remove(worker, sibling);
now = ring_next(ring, now);
if (shadow || skip) {
exclude_base = now;
}
continue;
}
if (!(test_res & REGION_TEST_LEFT_EXCLUSIVE) && is_opaque_item(sibling)) {
Container *container;
if (exclude_base) {
exclude_region(worker, ring, exclude_base, &exclude_rgn, NULL, NULL);
region_clear(&exclude_rgn);
exclude_base = NULL;
}
print_base_item("IN", sibling);
if (sibling->type == TREE_ITEM_TYPE_CONTAINER) {
container = (Container *)sibling;
ring = &container->items;
item->base.container = container;
now = ring_next(ring, ring);
continue;
}
spice_assert(IS_DRAW_ITEM(sibling));
if (!((DrawItem *)sibling)->container_root) {
container = __new_container(worker, (DrawItem *)sibling);
if (!container) {
spice_warning("create new container failed");
region_destroy(&exclude_rgn);
return FALSE;
}
item->base.container = container;
ring = &container->items;
}
}
}
if (!exclude_base) {
exclude_base = now;
}
break;
}
if (item->effect == QXL_EFFECT_OPAQUE) {
region_or(&exclude_rgn, &item->base.rgn);
exclude_region(worker, ring, exclude_base, &exclude_rgn, NULL, drawable);
red_use_stream_trace(worker, drawable);
red_streams_update_visible_region(worker, drawable);
/*
* Performing the insertion after exclude_region for
* safety (todo: Not sure if exclude_region can affect the drawable
* if it is added to the tree before calling exclude_region).
*/
__current_add_drawable(worker, drawable, ring);
} else {
/*
* red_detach_streams_behind can affect the current tree since it may
* trigger calls to update_area. Thus, the drawable should be added to the tree
* before calling red_detach_streams_behind
*/
__current_add_drawable(worker, drawable, ring);
if (drawable->surface_id == 0) {
red_detach_streams_behind(worker, &drawable->tree_item.base.rgn, drawable);
}
}
region_destroy(&exclude_rgn);
stat_add(&worker->add_stat, start_time);
return TRUE;
}
static void add_clip_rects(QRegion *rgn, SpiceClipRects *data)
{
int i;
for (i = 0; i < data->num_rects; i++) {
region_add(rgn, data->rects + i);
}
}
static inline Shadow *__new_shadow(RedWorker *worker, Drawable *item, SpicePoint *delta)
{
if (!delta->x && !delta->y) {
return NULL;
}
Shadow *shadow = spice_new(Shadow, 1);
worker->shadows_count++;
#ifdef PIPE_DEBUG
shadow->base.id = ++worker->last_id;
#endif
shadow->base.type = TREE_ITEM_TYPE_SHADOW;
shadow->base.container = NULL;
shadow->owner = &item->tree_item;
region_clone(&shadow->base.rgn, &item->tree_item.base.rgn);
region_offset(&shadow->base.rgn, delta->x, delta->y);
ring_item_init(&shadow->base.siblings_link);
region_init(&shadow->on_hold);
item->tree_item.shadow = shadow;
return shadow;
}
static inline int red_current_add_with_shadow(RedWorker *worker, Ring *ring, Drawable *item,
SpicePoint *delta)
{
#ifdef RED_WORKER_STAT
stat_time_t start_time = stat_now();
#endif
Shadow *shadow = __new_shadow(worker, item, delta);
if (!shadow) {
stat_add(&worker->add_stat, start_time);
return FALSE;
}
print_base_item("ADDSHADOW", &item->tree_item.base);
// item and his shadow must initially be placed in the same container.
// for now putting them on root.
// only primary surface streams are supported
if (is_primary_surface(worker, item->surface_id)) {
red_detach_streams_behind(worker, &shadow->base.rgn, NULL);
}
ring_add(ring, &shadow->base.siblings_link);
__current_add_drawable(worker, item, ring);
if (item->tree_item.effect == QXL_EFFECT_OPAQUE) {
QRegion exclude_rgn;
region_clone(&exclude_rgn, &item->tree_item.base.rgn);
exclude_region(worker, ring, &shadow->base.siblings_link, &exclude_rgn, NULL, NULL);
region_destroy(&exclude_rgn);
red_streams_update_visible_region(worker, item);
} else {
if (item->surface_id == 0) {
red_detach_streams_behind(worker, &item->tree_item.base.rgn, item);
}
}
stat_add(&worker->add_stat, start_time);
return TRUE;
}
static inline int has_shadow(RedDrawable *drawable)
{
return drawable->type == QXL_COPY_BITS;
}
static inline void red_update_streamable(RedWorker *worker, Drawable *drawable,
RedDrawable *red_drawable)
{
SpiceImage *image;
if (worker->streaming_video == STREAM_VIDEO_OFF) {
return;
}
if (!is_primary_surface(worker, drawable->surface_id)) {
return;
}
if (drawable->tree_item.effect != QXL_EFFECT_OPAQUE ||
red_drawable->type != QXL_DRAW_COPY ||
red_drawable->u.copy.rop_descriptor != SPICE_ROPD_OP_PUT) {
return;
}
image = red_drawable->u.copy.src_bitmap;
if (image == NULL ||
image->descriptor.type != SPICE_IMAGE_TYPE_BITMAP) {
return;
}
if (worker->streaming_video == STREAM_VIDEO_FILTER) {
SpiceRect* rect;
int size;
rect = &drawable->red_drawable->u.copy.src_area;
size = (rect->right - rect->left) * (rect->bottom - rect->top);
if (size < RED_STREAM_MIN_SIZE) {
return;
}
}
drawable->streamable = TRUE;
}
static inline int red_current_add_qxl(RedWorker *worker, Ring *ring, Drawable *drawable,
RedDrawable *red_drawable)
{
int ret;
if (has_shadow(red_drawable)) {
SpicePoint delta;
#ifdef RED_WORKER_STAT
++worker->add_with_shadow_count;
#endif
delta.x = red_drawable->u.copy_bits.src_pos.x - red_drawable->bbox.left;
delta.y = red_drawable->u.copy_bits.src_pos.y - red_drawable->bbox.top;
ret = red_current_add_with_shadow(worker, ring, drawable, &delta);
} else {
red_update_streamable(worker, drawable, red_drawable);
ret = red_current_add(worker, ring, drawable);
}
#ifdef RED_WORKER_STAT
if ((++worker->add_count % 100) == 0) {
stat_time_t total = worker->add_stat.total;
spice_info("add with shadow count %u",
worker->add_with_shadow_count);
worker->add_with_shadow_count = 0;
spice_info("add[%u] %f exclude[%u] %f __exclude[%u] %f",
worker->add_stat.count,
stat_cpu_time_to_sec(total),
worker->exclude_stat.count,
stat_cpu_time_to_sec(worker->exclude_stat.total),
worker->__exclude_stat.count,
stat_cpu_time_to_sec(worker->__exclude_stat.total));
spice_info("add %f%% exclude %f%% exclude2 %f%% __exclude %f%%",
(double)(total - worker->exclude_stat.total) / total * 100,
(double)(worker->exclude_stat.total) / total * 100,
(double)(worker->exclude_stat.total -
worker->__exclude_stat.total) / worker->exclude_stat.total * 100,
(double)(worker->__exclude_stat.total) / worker->exclude_stat.total * 100);
stat_reset(&worker->add_stat);
stat_reset(&worker->exclude_stat);
stat_reset(&worker->__exclude_stat);
}
#endif
return ret;
}
static void red_get_area(RedWorker *worker, int surface_id, const SpiceRect *area, uint8_t *dest,
int dest_stride, int update)
{
SpiceCanvas *canvas;
RedSurface *surface;
surface = &worker->surfaces[surface_id];
if (update) {
red_update_area(worker, area, surface_id);
}
canvas = surface->context.canvas;
canvas->ops->read_bits(canvas, dest, dest_stride, area);
}
static int surface_format_to_image_type(uint32_t surface_format)
{
switch (surface_format) {
case SPICE_SURFACE_FMT_16_555:
return SPICE_BITMAP_FMT_16BIT;
case SPICE_SURFACE_FMT_32_xRGB:
return SPICE_BITMAP_FMT_32BIT;
case SPICE_SURFACE_FMT_32_ARGB:
return SPICE_BITMAP_FMT_RGBA;
case SPICE_SURFACE_FMT_8_A:
return SPICE_BITMAP_FMT_8BIT_A;
default:
spice_critical("Unsupported surface format");
}
return 0;
}
static int rgb32_data_has_alpha(int width, int height, size_t stride,
uint8_t *data, int *all_set_out)
{
uint32_t *line, *end, alpha;
int has_alpha;
has_alpha = FALSE;
while (height-- > 0) {
line = (uint32_t *)data;
end = line + width;
data += stride;
while (line != end) {
alpha = *line & 0xff000000U;
if (alpha != 0) {
has_alpha = TRUE;
if (alpha != 0xff000000U) {
*all_set_out = FALSE;
return TRUE;
}
}
line++;
}
}
*all_set_out = has_alpha;
return has_alpha;
}
static inline int red_handle_self_bitmap(RedWorker *worker, Drawable *drawable)
{
SpiceImage *image;
int32_t width;
int32_t height;
uint8_t *dest;
int dest_stride;
RedSurface *surface;
int bpp;
int all_set;
RedDrawable *red_drawable = drawable->red_drawable;
if (!red_drawable->self_bitmap) {
return TRUE;
}
surface = &worker->surfaces[drawable->surface_id];
bpp = SPICE_SURFACE_FMT_DEPTH(surface->context.format) / 8;
width = red_drawable->self_bitmap_area.right
- red_drawable->self_bitmap_area.left;
height = red_drawable->self_bitmap_area.bottom
- red_drawable->self_bitmap_area.top;
dest_stride = SPICE_ALIGN(width * bpp, 4);
image = spice_new0(SpiceImage, 1);
image->descriptor.type = SPICE_IMAGE_TYPE_BITMAP;
image->descriptor.flags = 0;
QXL_SET_IMAGE_ID(image, QXL_IMAGE_GROUP_RED, ++worker->bits_unique);
image->u.bitmap.flags = surface->context.top_down ? SPICE_BITMAP_FLAGS_TOP_DOWN : 0;
image->u.bitmap.format = surface_format_to_image_type(surface->context.format);
image->u.bitmap.stride = dest_stride;
image->descriptor.width = image->u.bitmap.x = width;
image->descriptor.height = image->u.bitmap.y = height;
image->u.bitmap.palette = NULL;
dest = (uint8_t *)spice_malloc_n(height, dest_stride);
image->u.bitmap.data = spice_chunks_new_linear(dest, height * dest_stride);
image->u.bitmap.data->flags |= SPICE_CHUNKS_FLAGS_FREE;
red_get_area(worker, drawable->surface_id,
&red_drawable->self_bitmap_area, dest, dest_stride, TRUE);
/* For 32bit non-primary surfaces we need to keep any non-zero
high bytes as the surface may be used as source to an alpha_blend */
if (!is_primary_surface(worker, drawable->surface_id) &&
image->u.bitmap.format == SPICE_BITMAP_FMT_32BIT &&
rgb32_data_has_alpha(width, height, dest_stride, dest, &all_set)) {
if (all_set) {
image->descriptor.flags |= SPICE_IMAGE_FLAGS_HIGH_BITS_SET;
} else {
image->u.bitmap.format = SPICE_BITMAP_FMT_RGBA;
}
}
red_drawable->self_bitmap_image = image;
return TRUE;
}
static void free_one_drawable(RedWorker *worker, int force_glz_free)
{
RingItem *ring_item = ring_get_tail(&worker->current_list);
Drawable *drawable;
Container *container;
spice_assert(ring_item);
drawable = SPICE_CONTAINEROF(ring_item, Drawable, list_link);
if (force_glz_free) {
RingItem *glz_item, *next_item;
RedGlzDrawable *glz;
DRAWABLE_FOREACH_GLZ_SAFE(drawable, glz_item, next_item, glz) {
red_display_free_glz_drawable(glz->dcc, glz);
}
}
red_draw_drawable(worker, drawable);
container = drawable->tree_item.base.container;
current_remove_drawable(worker, drawable);
container_cleanup(worker, container);
}
static Drawable *get_drawable(RedWorker *worker, uint8_t effect, RedDrawable *red_drawable,
uint32_t group_id)
{
Drawable *drawable;
struct timespec time;
int x;
while (!(drawable = alloc_drawable(worker))) {
free_one_drawable(worker, FALSE);
}
worker->drawable_count++;
worker->red_drawable_count++;
memset(drawable, 0, sizeof(Drawable));
drawable->refs = 1;
clock_gettime(CLOCK_MONOTONIC, &time);
drawable->creation_time = timespec_to_red_time(&time);
#ifdef PIPE_DEBUG
drawable->tree_item.base.id = ++worker->last_id;
#endif
ring_item_init(&drawable->list_link);
ring_item_init(&drawable->surface_list_link);
#ifdef UPDATE_AREA_BY_TREE
ring_item_init(&drawable->collect_link);
#endif
ring_item_init(&drawable->tree_item.base.siblings_link);
drawable->tree_item.base.type = TREE_ITEM_TYPE_DRAWABLE;
region_init(&drawable->tree_item.base.rgn);
drawable->tree_item.effect = effect;
drawable->red_drawable = ref_red_drawable(red_drawable);
drawable->group_id = group_id;
drawable->surface_id = red_drawable->surface_id;
VALIDATE_SURFACE_RETVAL(worker, drawable->surface_id, NULL)
for (x = 0; x < 3; ++x) {
drawable->surfaces_dest[x] = red_drawable->surfaces_dest[x];
if (drawable->surfaces_dest[x] != -1) {
VALIDATE_SURFACE_RETVAL(worker, drawable->surfaces_dest[x], NULL)
}
}
ring_init(&drawable->pipes);
ring_init(&drawable->glz_ring);
drawable->process_commands_generation = worker->process_commands_generation;
return drawable;
}
static inline int red_handle_depends_on_target_surface(RedWorker *worker, uint32_t surface_id)
{
RedSurface *surface;
RingItem *ring_item;
surface = &worker->surfaces[surface_id];
while ((ring_item = ring_get_tail(&surface->depend_on_me))) {
Drawable *drawable;
DependItem *depended_item = SPICE_CONTAINEROF(ring_item, DependItem, ring_item);
drawable = depended_item->drawable;
surface_flush(worker, drawable->surface_id, &drawable->red_drawable->bbox);
}
return TRUE;
}
static inline void add_to_surface_dependency(RedWorker *worker, int depend_on_surface_id,
DependItem *depend_item, Drawable *drawable)
{
RedSurface *surface;
if (depend_on_surface_id == -1) {
depend_item->drawable = NULL;
return;
}
surface = &worker->surfaces[depend_on_surface_id];
depend_item->drawable = drawable;
ring_add(&surface->depend_on_me, &depend_item->ring_item);
}
static inline int red_handle_surfaces_dependencies(RedWorker *worker, Drawable *drawable)
{
int x;
for (x = 0; x < 3; ++x) {
// surface self dependency is handled by shadows in "current", or by
// handle_self_bitmap
if (drawable->surfaces_dest[x] != drawable->surface_id) {
add_to_surface_dependency(worker, drawable->surfaces_dest[x],
&drawable->depend_items[x], drawable);
if (drawable->surfaces_dest[x] == 0) {
QRegion depend_region;
region_init(&depend_region);
region_add(&depend_region, &drawable->red_drawable->surfaces_rects[x]);
red_detach_streams_behind(worker, &depend_region, NULL);
}
}
}
return TRUE;
}
static inline void red_inc_surfaces_drawable_dependencies(RedWorker *worker, Drawable *drawable)
{
int x;
int surface_id;
RedSurface *surface;
for (x = 0; x < 3; ++x) {
surface_id = drawable->surfaces_dest[x];
if (surface_id == -1) {
continue;
}
surface = &worker->surfaces[surface_id];
surface->refs++;
}
}
static inline void red_process_drawable(RedWorker *worker, RedDrawable *drawable,
uint32_t group_id)
{
int surface_id;
Drawable *item = get_drawable(worker, drawable->effect, drawable, group_id);
if (!item) {
rendering_incorrect("failed to get_drawable");
return;
}
surface_id = item->surface_id;
worker->surfaces[surface_id].refs++;
region_add(&item->tree_item.base.rgn, &drawable->bbox);
#ifdef PIPE_DEBUG
printf("TEST: DRAWABLE: id %u type %s effect %u bbox %u %u %u %u\n",
item->tree_item.base.id,
draw_type_to_str(drawable->type),
item->tree_item.effect,
drawable->bbox.top, drawable->bbox.left, drawable->bbox.bottom, drawable->bbox.right);
#endif
if (drawable->clip.type == SPICE_CLIP_TYPE_RECTS) {
QRegion rgn;
region_init(&rgn);
add_clip_rects(&rgn, drawable->clip.rects);
region_and(&item->tree_item.base.rgn, &rgn);
region_destroy(&rgn);
}
/*
surface->refs is affected by a drawable (that is
dependent on the surface) as long as the drawable is alive.
However, surface->depend_on_me is affected by a drawable only
as long as it is in the current tree (hasn't been rendered yet).
*/
red_inc_surfaces_drawable_dependencies(worker, item);
if (region_is_empty(&item->tree_item.base.rgn)) {
goto cleanup;
}
if (!red_handle_self_bitmap(worker, item)) {
goto cleanup;
}
if (!red_handle_depends_on_target_surface(worker, surface_id)) {
goto cleanup;
}
if (!red_handle_surfaces_dependencies(worker, item)) {
goto cleanup;
}
if (red_current_add_qxl(worker, &worker->surfaces[surface_id].current, item,
drawable)) {
if (item->tree_item.effect != QXL_EFFECT_OPAQUE) {
worker->transparent_count++;
}
red_pipes_add_drawable(worker, item);
#ifdef DRAW_ALL
red_draw_qxl_drawable(worker, item);
#endif
}
cleanup:
release_drawable(worker, item);
}
static inline void red_create_surface(RedWorker *worker, uint32_t surface_id,uint32_t width,
uint32_t height, int32_t stride, uint32_t format,
void *line_0, int data_is_valid, int send_client);
static inline void red_process_surface(RedWorker *worker, RedSurfaceCmd *surface,
uint32_t group_id, int loadvm)
{
int surface_id;
RedSurface *red_surface;
uint8_t *data;
surface_id = surface->surface_id;
__validate_surface(worker, surface_id);
red_surface = &worker->surfaces[surface_id];
switch (surface->type) {
case QXL_SURFACE_CMD_CREATE: {
uint32_t height = surface->u.surface_create.height;
int32_t stride = surface->u.surface_create.stride;
int reloaded_surface = loadvm || (surface->flags & QXL_SURF_FLAG_KEEP_DATA);
data = surface->u.surface_create.data;
if (stride < 0) {
data -= (int32_t)(stride * (height - 1));
}
red_create_surface(worker, surface_id, surface->u.surface_create.width,
height, stride, surface->u.surface_create.format, data,
reloaded_surface,
// reloaded surfaces will be sent on demand
!reloaded_surface);
set_surface_release_info(worker, surface_id, 1, surface->release_info, group_id);
break;
}
case QXL_SURFACE_CMD_DESTROY:
spice_warn_if(!red_surface->context.canvas);
set_surface_release_info(worker, surface_id, 0, surface->release_info, group_id);
red_handle_depends_on_target_surface(worker, surface_id);
/* note that red_handle_depends_on_target_surface must be called before red_current_clear.
otherwise "current" will hold items that other drawables may depend on, and then
red_current_clear will remove them from the pipe. */
red_current_clear(worker, surface_id);
red_clear_surface_drawables_from_pipes(worker, surface_id, FALSE, FALSE);
red_destroy_surface(worker, surface_id);
break;
default:
spice_error("unknown surface command");
};
red_put_surface_cmd(surface);
free(surface);
}
static SpiceCanvas *image_surfaces_get(SpiceImageSurfaces *surfaces,
uint32_t surface_id)
{
RedWorker *worker;
worker = SPICE_CONTAINEROF(surfaces, RedWorker, image_surfaces);
VALIDATE_SURFACE_RETVAL(worker, surface_id, NULL);
return worker->surfaces[surface_id].context.canvas;
}
static void image_surface_init(RedWorker *worker)
{
static SpiceImageSurfacesOps image_surfaces_ops = {
image_surfaces_get,
};
worker->image_surfaces.ops = &image_surfaces_ops;
}
static ImageCacheItem *image_cache_find(ImageCache *cache, uint64_t id)
{
ImageCacheItem *item = cache->hash_table[id % IMAGE_CACHE_HASH_SIZE];
while (item) {
if (item->id == id) {
return item;
}
item = item->next;
}
return NULL;
}
static int image_cache_hit(ImageCache *cache, uint64_t id)
{
ImageCacheItem *item;
if (!(item = image_cache_find(cache, id))) {
return FALSE;
}
#ifdef IMAGE_CACHE_AGE
item->age = cache->age;
#endif
ring_remove(&item->lru_link);
ring_add(&cache->lru, &item->lru_link);
return TRUE;
}
static void image_cache_remove(ImageCache *cache, ImageCacheItem *item)
{
ImageCacheItem **now;
now = &cache->hash_table[item->id % IMAGE_CACHE_HASH_SIZE];
for (;;) {
spice_assert(*now);
if (*now == item) {
*now = item->next;
break;
}
now = &(*now)->next;
}
ring_remove(&item->lru_link);
pixman_image_unref(item->image);
free(item);
#ifndef IMAGE_CACHE_AGE
cache->num_items--;
#endif
}
#define IMAGE_CACHE_MAX_ITEMS 2
static void image_cache_put(SpiceImageCache *spice_cache, uint64_t id, pixman_image_t *image)
{
ImageCache *cache = (ImageCache *)spice_cache;
ImageCacheItem *item;
#ifndef IMAGE_CACHE_AGE
if (cache->num_items == IMAGE_CACHE_MAX_ITEMS) {
ImageCacheItem *tail = (ImageCacheItem *)ring_get_tail(&cache->lru);
spice_assert(tail);
image_cache_remove(cache, tail);
}
#endif
item = spice_new(ImageCacheItem, 1);
item->id = id;
#ifdef IMAGE_CACHE_AGE
item->age = cache->age;
#else
cache->num_items++;
#endif
item->image = pixman_image_ref(image);
ring_item_init(&item->lru_link);
item->next = cache->hash_table[item->id % IMAGE_CACHE_HASH_SIZE];
cache->hash_table[item->id % IMAGE_CACHE_HASH_SIZE] = item;
ring_add(&cache->lru, &item->lru_link);
}
static pixman_image_t *image_cache_get(SpiceImageCache *spice_cache, uint64_t id)
{
ImageCache *cache = (ImageCache *)spice_cache;
ImageCacheItem *item = image_cache_find(cache, id);
if (!item) {
spice_error("not found");
}
return pixman_image_ref(item->image);
}
static void image_cache_init(ImageCache *cache)
{
static SpiceImageCacheOps image_cache_ops = {
image_cache_put,
image_cache_get,
};
cache->base.ops = &image_cache_ops;
memset(cache->hash_table, 0, sizeof(cache->hash_table));
ring_init(&cache->lru);
#ifdef IMAGE_CACHE_AGE
cache->age = 0;
#else
cache->num_items = 0;
#endif
}
static void image_cache_reset(ImageCache *cache)
{
ImageCacheItem *item;
while ((item = (ImageCacheItem *)ring_get_head(&cache->lru))) {
image_cache_remove(cache, item);
}
#ifdef IMAGE_CACHE_AGE
cache->age = 0;
#endif
}
#define IMAGE_CACHE_DEPTH 4
static void image_cache_eaging(ImageCache *cache)
{
#ifdef IMAGE_CACHE_AGE
ImageCacheItem *item;
cache->age++;
while ((item = (ImageCacheItem *)ring_get_tail(&cache->lru)) &&
cache->age - item->age > IMAGE_CACHE_DEPTH) {
image_cache_remove(cache, item);
}
#endif
}
static void localize_bitmap(RedWorker *worker, SpiceImage **image_ptr, SpiceImage *image_store,
Drawable *drawable)
{
SpiceImage *image = *image_ptr;
if (image == NULL) {
spice_assert(drawable != NULL);
spice_assert(drawable->red_drawable->self_bitmap_image != NULL);
*image_ptr = drawable->red_drawable->self_bitmap_image;
return;
}
if (image_cache_hit(&worker->image_cache, image->descriptor.id)) {
image_store->descriptor = image->descriptor;
image_store->descriptor.type = SPICE_IMAGE_TYPE_FROM_CACHE;
image_store->descriptor.flags = 0;
*image_ptr = image_store;
return;
}
switch (image->descriptor.type) {
case SPICE_IMAGE_TYPE_QUIC: {
image_store->descriptor = image->descriptor;
image_store->u.quic = image->u.quic;
*image_ptr = image_store;
#ifdef IMAGE_CACHE_AGE
image_store->descriptor.flags |= SPICE_IMAGE_FLAGS_CACHE_ME;
#else
if (image_store->descriptor.width * image->descriptor.height >= 640 * 480) {
image_store->descriptor.flags |= SPICE_IMAGE_FLAGS_CACHE_ME;
}
#endif
break;
}
case SPICE_IMAGE_TYPE_BITMAP:
case SPICE_IMAGE_TYPE_SURFACE:
/* nothing */
break;
default:
spice_error("invalid image type");
}
}
static void localize_brush(RedWorker *worker, SpiceBrush *brush, SpiceImage *image_store)
{
if (brush->type == SPICE_BRUSH_TYPE_PATTERN) {
localize_bitmap(worker, &brush->u.pattern.pat, image_store, NULL);
}
}
static void localize_mask(RedWorker *worker, SpiceQMask *mask, SpiceImage *image_store)
{
if (mask->bitmap) {
localize_bitmap(worker, &mask->bitmap, image_store, NULL);
}
}
static void red_draw_qxl_drawable(RedWorker *worker, Drawable *drawable)
{
RedSurface *surface;
SpiceCanvas *canvas;
SpiceClip clip = drawable->red_drawable->clip;
surface = &worker->surfaces[drawable->surface_id];
canvas = surface->context.canvas;
image_cache_eaging(&worker->image_cache);
worker->preload_group_id = drawable->group_id;
region_add(&surface->draw_dirty_region, &drawable->red_drawable->bbox);
switch (drawable->red_drawable->type) {
case QXL_DRAW_FILL: {
SpiceFill fill = drawable->red_drawable->u.fill;
SpiceImage img1, img2;
localize_brush(worker, &fill.brush, &img1);
localize_mask(worker, &fill.mask, &img2);
canvas->ops->draw_fill(canvas, &drawable->red_drawable->bbox,
&clip, &fill);
break;
}
case QXL_DRAW_OPAQUE: {
SpiceOpaque opaque = drawable->red_drawable->u.opaque;
SpiceImage img1, img2, img3;
localize_brush(worker, &opaque.brush, &img1);
localize_bitmap(worker, &opaque.src_bitmap, &img2, drawable);
localize_mask(worker, &opaque.mask, &img3);
canvas->ops->draw_opaque(canvas, &drawable->red_drawable->bbox, &clip, &opaque);
break;
}
case QXL_DRAW_COPY: {
SpiceCopy copy = drawable->red_drawable->u.copy;
SpiceImage img1, img2;
localize_bitmap(worker, ©.src_bitmap, &img1, drawable);
localize_mask(worker, ©.mask, &img2);
canvas->ops->draw_copy(canvas, &drawable->red_drawable->bbox,
&clip, ©);
break;
}
case QXL_DRAW_TRANSPARENT: {
SpiceTransparent transparent = drawable->red_drawable->u.transparent;
SpiceImage img1;
localize_bitmap(worker, &transparent.src_bitmap, &img1, drawable);
canvas->ops->draw_transparent(canvas,
&drawable->red_drawable->bbox, &clip, &transparent);
break;
}
case QXL_DRAW_ALPHA_BLEND: {
SpiceAlphaBlend alpha_blend = drawable->red_drawable->u.alpha_blend;
SpiceImage img1;
localize_bitmap(worker, &alpha_blend.src_bitmap, &img1, drawable);
canvas->ops->draw_alpha_blend(canvas,
&drawable->red_drawable->bbox, &clip, &alpha_blend);
break;
}
case QXL_COPY_BITS: {
canvas->ops->copy_bits(canvas, &drawable->red_drawable->bbox,
&clip, &drawable->red_drawable->u.copy_bits.src_pos);
break;
}
case QXL_DRAW_BLEND: {
SpiceBlend blend = drawable->red_drawable->u.blend;
SpiceImage img1, img2;
localize_bitmap(worker, &blend.src_bitmap, &img1, drawable);
localize_mask(worker, &blend.mask, &img2);
canvas->ops->draw_blend(canvas, &drawable->red_drawable->bbox,
&clip, &blend);
break;
}
case QXL_DRAW_BLACKNESS: {
SpiceBlackness blackness = drawable->red_drawable->u.blackness;
SpiceImage img1;
localize_mask(worker, &blackness.mask, &img1);
canvas->ops->draw_blackness(canvas,
&drawable->red_drawable->bbox, &clip, &blackness);
break;
}
case QXL_DRAW_WHITENESS: {
SpiceWhiteness whiteness = drawable->red_drawable->u.whiteness;
SpiceImage img1;
localize_mask(worker, &whiteness.mask, &img1);
canvas->ops->draw_whiteness(canvas,
&drawable->red_drawable->bbox, &clip, &whiteness);
break;
}
case QXL_DRAW_INVERS: {
SpiceInvers invers = drawable->red_drawable->u.invers;
SpiceImage img1;
localize_mask(worker, &invers.mask, &img1);
canvas->ops->draw_invers(canvas,
&drawable->red_drawable->bbox, &clip, &invers);
break;
}
case QXL_DRAW_ROP3: {
SpiceRop3 rop3 = drawable->red_drawable->u.rop3;
SpiceImage img1, img2, img3;
localize_brush(worker, &rop3.brush, &img1);
localize_bitmap(worker, &rop3.src_bitmap, &img2, drawable);
localize_mask(worker, &rop3.mask, &img3);
canvas->ops->draw_rop3(canvas, &drawable->red_drawable->bbox,
&clip, &rop3);
break;
}
case QXL_DRAW_COMPOSITE: {
SpiceComposite composite = drawable->red_drawable->u.composite;
SpiceImage src, mask;
localize_bitmap(worker, &composite.src_bitmap, &src, drawable);
if (composite.mask_bitmap)
localize_bitmap(worker, &composite.mask_bitmap, &mask, drawable);
canvas->ops->draw_composite(canvas, &drawable->red_drawable->bbox,
&clip, &composite);
break;
}
case QXL_DRAW_STROKE: {
SpiceStroke stroke = drawable->red_drawable->u.stroke;
SpiceImage img1;
localize_brush(worker, &stroke.brush, &img1);
canvas->ops->draw_stroke(canvas,
&drawable->red_drawable->bbox, &clip, &stroke);
break;
}
case QXL_DRAW_TEXT: {
SpiceText text = drawable->red_drawable->u.text;
SpiceImage img1, img2;
localize_brush(worker, &text.fore_brush, &img1);
localize_brush(worker, &text.back_brush, &img2);
canvas->ops->draw_text(canvas, &drawable->red_drawable->bbox,
&clip, &text);
break;
}
default:
spice_warning("invalid type");
}
}
#ifndef DRAW_ALL
static void red_draw_drawable(RedWorker *worker, Drawable *drawable)
{
#ifdef UPDATE_AREA_BY_TREE
SpiceCanvas *canvas;
canvas = surface->context.canvas;
//todo: add need top mask flag
canvas->ops->group_start(canvas,
&drawable->tree_item.base.rgn);
#endif
red_flush_source_surfaces(worker, drawable);
red_draw_qxl_drawable(worker, drawable);
#ifdef UPDATE_AREA_BY_TREE
canvas->ops->group_end(canvas);
#endif
}
static void validate_area(RedWorker *worker, const SpiceRect *area, uint32_t surface_id)
{
RedSurface *surface;
surface = &worker->surfaces[surface_id];
if (!surface->context.canvas_draws_on_surface) {
SpiceCanvas *canvas = surface->context.canvas;
int h;
int stride = surface->context.stride;
uint8_t *line_0 = surface->context.line_0;
if (!(h = area->bottom - area->top)) {
return;
}
spice_assert(stride < 0);
uint8_t *dest = line_0 + (area->top * stride) + area->left * sizeof(uint32_t);
dest += (h - 1) * stride;
canvas->ops->read_bits(canvas, dest, -stride, area);
}
}
#ifdef UPDATE_AREA_BY_TREE
static inline void __red_collect_for_update(RedWorker *worker, Ring *ring, RingItem *ring_item,
QRegion *rgn, Ring *items)
{
Ring *top_ring = ring;
for (;;) {
TreeItem *now = SPICE_CONTAINEROF(ring_item, TreeItem, siblings_link);
Container *container = now->container;
if (region_intersects(rgn, &now->rgn)) {
if (IS_DRAW_ITEM(now)) {
Drawable *drawable = SPICE_CONTAINEROF(now, Drawable, tree_item);
ring_add(items, &drawable->collect_link);
region_or(rgn, &now->rgn);
if (drawable->tree_item.shadow) {
region_or(rgn, &drawable->tree_item.shadow->base.rgn);
}
} else if (now->type == TREE_ITEM_TYPE_SHADOW) {
Drawable *owner = SPICE_CONTAINEROF(((Shadow *)now)->owner, Drawable, tree_item);
if (!ring_item_is_linked(&owner->collect_link)) {
region_or(rgn, &now->rgn);
region_or(rgn, &owner->tree_item.base.rgn);
ring_add(items, &owner->collect_link);
}
} else if (now->type == TREE_ITEM_TYPE_CONTAINER) {
Container *container = (Container *)now;
if ((ring_item = ring_get_head(&container->items))) {
ring = &container->items;
spice_assert(((TreeItem *)ring_item)->container);
continue;
}
ring_item = &now->siblings_link;
}
}
while (!(ring_item = ring_next(ring, ring_item))) {
if (ring == top_ring) {
return;
}
ring_item = &container->base.siblings_link;
container = container->base.container;
ring = (container) ? &container->items : top_ring;
}
}
}
static void red_update_area(RedWorker *worker, const SpiceRect *area, int surface_id)
{
RedSurface *surface;
Ring *ring;
RingItem *ring_item;
Ring items;
QRegion rgn;
surface = &worker->surfaces[surface_id];
ring = &surface->current;
if (!(ring_item = ring_get_head(ring))) {
worker->draw_context.validate_area(surface->context.canvas,
&worker->dev_info.surface0_area, area);
return;
}
region_init(&rgn);
region_add(&rgn, area);
ring_init(&items);
__red_collect_for_update(worker, ring, ring_item, &rgn, &items);
region_destroy(&rgn);
while ((ring_item = ring_get_head(&items))) {
Drawable *drawable = SPICE_CONTAINEROF(ring_item, Drawable, collect_link);
Container *container;
ring_remove(ring_item);
red_draw_drawable(worker, drawable);
container = drawable->tree_item.base.container;
current_remove_drawable(worker, drawable);
container_cleanup(worker, container);
}
validate_area(worker, area, surface_id);
}
#else
/*
Renders drawables for updating the requested area, but only drawables that are older
than 'last' (exclusive).
*/
static void red_update_area_till(RedWorker *worker, const SpiceRect *area, int surface_id,
Drawable *last)
{
// TODO: if we use UPDATE_AREA_BY_TREE, a corresponding red_update_area_till
// should be implemented
RedSurface *surface;
Drawable *surface_last = NULL;
Ring *ring;
RingItem *ring_item;
Drawable *now;
QRegion rgn;
spice_assert(last);
spice_assert(ring_item_is_linked(&last->list_link));
surface = &worker->surfaces[surface_id];
if (surface_id != last->surface_id) {
// find the nearest older drawable from the appropriate surface
ring = &worker->current_list;
ring_item = &last->list_link;
while ((ring_item = ring_next(ring, ring_item))) {
now = SPICE_CONTAINEROF(ring_item, Drawable, list_link);
if (now->surface_id == surface_id) {
surface_last = now;
break;
}
}
} else {
ring_item = ring_next(&surface->current_list, &last->surface_list_link);
if (ring_item) {
surface_last = SPICE_CONTAINEROF(ring_item, Drawable, surface_list_link);
}
}
if (!surface_last) {
return;
}
ring = &surface->current_list;
ring_item = &surface_last->surface_list_link;
region_init(&rgn);
region_add(&rgn, area);
// find the first older drawable that intersects with the area
do {
now = SPICE_CONTAINEROF(ring_item, Drawable, surface_list_link);
if (region_intersects(&rgn, &now->tree_item.base.rgn)) {
surface_last = now;
break;
}
} while ((ring_item = ring_next(ring, ring_item)));
region_destroy(&rgn);
if (!surface_last) {
return;
}
do {
Container *container;
ring_item = ring_get_tail(&surface->current_list);
now = SPICE_CONTAINEROF(ring_item, Drawable, surface_list_link);
now->refs++;
container = now->tree_item.base.container;
current_remove_drawable(worker, now);
container_cleanup(worker, container);
/* red_draw_drawable may call red_update_area for the surfaces 'now' depends on. Notice,
that it is valid to call red_update_area in this case and not red_update_area_till:
It is impossible that there was newer item then 'last' in one of the surfaces
that red_update_area is called for, Otherwise, 'now' would have already been rendered.
See the call for red_handle_depends_on_target_surface in red_process_drawable */
red_draw_drawable(worker, now);
release_drawable(worker, now);
} while (now != surface_last);
validate_area(worker, area, surface_id);
}
static void red_update_area(RedWorker *worker, const SpiceRect *area, int surface_id)
{
RedSurface *surface;
Ring *ring;
RingItem *ring_item;
QRegion rgn;
Drawable *last;
Drawable *now;
#ifdef ACYCLIC_SURFACE_DEBUG
int gn;
#endif
spice_debug("surface %d: area ==>", surface_id);
rect_debug(area);
spice_return_if_fail(surface_id >= 0 && surface_id < NUM_SURFACES);
spice_return_if_fail(area);
spice_return_if_fail(area->left >= 0 && area->top >= 0 &&
area->left < area->right && area->top < area->bottom);
surface = &worker->surfaces[surface_id];
last = NULL;
#ifdef ACYCLIC_SURFACE_DEBUG
gn = ++surface->current_gn;
#endif
ring = &surface->current_list;
ring_item = ring;
region_init(&rgn);
region_add(&rgn, area);
while ((ring_item = ring_next(ring, ring_item))) {
now = SPICE_CONTAINEROF(ring_item, Drawable, surface_list_link);
if (region_intersects(&rgn, &now->tree_item.base.rgn)) {
last = now;
break;
}
}
region_destroy(&rgn);
if (!last) {
validate_area(worker, area, surface_id);
return;
}
do {
Container *container;
ring_item = ring_get_tail(&surface->current_list);
now = SPICE_CONTAINEROF(ring_item, Drawable, surface_list_link);
now->refs++;
container = now->tree_item.base.container;
current_remove_drawable(worker, now);
container_cleanup(worker, container);
red_draw_drawable(worker, now);
release_drawable(worker, now);
#ifdef ACYCLIC_SURFACE_DEBUG
if (gn != surface->current_gn) {
spice_error("cyclic surface dependencies");
}
#endif
} while (now != last);
validate_area(worker, area, surface_id);
}
#endif
#endif
static inline void free_cursor_item(RedWorker *worker, CursorItem *item);
static void red_release_cursor(RedWorker *worker, CursorItem *cursor)
{
if (!--cursor->refs) {
QXLReleaseInfoExt release_info_ext;
RedCursorCmd *cursor_cmd;
cursor_cmd = cursor->red_cursor;
release_info_ext.group_id = cursor->group_id;
release_info_ext.info = cursor_cmd->release_info;
worker->qxl->st->qif->release_resource(worker->qxl, release_info_ext);
free_cursor_item(worker, cursor);
red_put_cursor_cmd(cursor_cmd);
free(cursor_cmd);
}
}
static void red_set_cursor(RedWorker *worker, CursorItem *cursor)
{
if (worker->cursor) {
red_release_cursor(worker, worker->cursor);
}
++cursor->refs;
worker->cursor = cursor;
}
#ifdef DEBUG_CURSORS
static int _cursor_count = 0;
#endif
static inline CursorItem *alloc_cursor_item(RedWorker *worker)
{
CursorItem *cursor;
if (!worker->free_cursor_items) {
return NULL;
}
#ifdef DEBUG_CURSORS
--_cursor_count;
#endif
cursor = &worker->free_cursor_items->u.cursor_item;
worker->free_cursor_items = worker->free_cursor_items->u.next;
return cursor;
}
static inline void free_cursor_item(RedWorker *worker, CursorItem *item)
{
((_CursorItem *)item)->u.next = worker->free_cursor_items;
worker->free_cursor_items = (_CursorItem *)item;
#ifdef DEBUG_CURSORS
++_cursor_count;
spice_assert(_cursor_count <= NUM_CURSORS);
#endif
}
static void cursor_items_init(RedWorker *worker)
{
int i;
worker->free_cursor_items = NULL;
for (i = 0; i < NUM_CURSORS; i++) {
free_cursor_item(worker, &worker->cursor_items[i].u.cursor_item);
}
}
static CursorItem *get_cursor_item(RedWorker *worker, RedCursorCmd *cmd, uint32_t group_id)
{
CursorItem *cursor_item;
spice_warn_if(!(cursor_item = alloc_cursor_item(worker)));
cursor_item->refs = 1;
cursor_item->group_id = group_id;
cursor_item->red_cursor = cmd;
return cursor_item;
}
static CursorPipeItem *ref_cursor_pipe_item(CursorPipeItem *item)
{
spice_assert(item);
item->refs++;
return item;
}
static PipeItem *new_cursor_pipe_item(RedChannelClient *rcc, void *data, int num)
{
CursorPipeItem *item = spice_malloc0(sizeof(CursorPipeItem));
red_channel_pipe_item_init(rcc->channel, &item->base, PIPE_ITEM_TYPE_CURSOR);
item->refs = 1;
item->cursor_item = data;
item->cursor_item->refs++;
return &item->base;
}
static void put_cursor_pipe_item(CursorChannelClient *ccc, CursorPipeItem *pipe_item)
{
spice_assert(pipe_item);
if (--pipe_item->refs) {
return;
}
spice_assert(!pipe_item_is_linked(&pipe_item->base));
red_release_cursor(ccc->common.worker, pipe_item->cursor_item);
free(pipe_item);
}
static void qxl_process_cursor(RedWorker *worker, RedCursorCmd *cursor_cmd, uint32_t group_id)
{
CursorItem *cursor_item;
int cursor_show = FALSE;
cursor_item = get_cursor_item(worker, cursor_cmd, group_id);
switch (cursor_cmd->type) {
case QXL_CURSOR_SET:
worker->cursor_visible = cursor_cmd->u.set.visible;
red_set_cursor(worker, cursor_item);
break;
case QXL_CURSOR_MOVE:
cursor_show = !worker->cursor_visible;
worker->cursor_visible = TRUE;
worker->cursor_position = cursor_cmd->u.position;
break;
case QXL_CURSOR_HIDE:
worker->cursor_visible = FALSE;
break;
case QXL_CURSOR_TRAIL:
worker->cursor_trail_length = cursor_cmd->u.trail.length;
worker->cursor_trail_frequency = cursor_cmd->u.trail.frequency;
break;
default:
spice_error("invalid cursor command %u", cursor_cmd->type);
}
if (cursor_is_connected(worker) && (worker->mouse_mode == SPICE_MOUSE_MODE_SERVER ||
cursor_cmd->type != QXL_CURSOR_MOVE || cursor_show)) {
red_channel_pipes_new_add(&worker->cursor_channel->common.base, new_cursor_pipe_item,
(void*)cursor_item);
}
red_release_cursor(worker, cursor_item);
}
static inline uint64_t red_now(void)
{
struct timespec time;
clock_gettime(CLOCK_MONOTONIC, &time);
return ((uint64_t) time.tv_sec) * 1000000000 + time.tv_nsec;
}
static int red_process_cursor(RedWorker *worker, uint32_t max_pipe_size, int *ring_is_empty)
{
QXLCommandExt ext_cmd;
int n = 0;
if (!worker->running) {
*ring_is_empty = TRUE;
return n;
}
*ring_is_empty = FALSE;
while (!cursor_is_connected(worker) ||
red_channel_min_pipe_size(&worker->cursor_channel->common.base) <= max_pipe_size) {
if (!worker->qxl->st->qif->get_cursor_command(worker->qxl, &ext_cmd)) {
*ring_is_empty = TRUE;
if (worker->repoll_cursor_ring < CMD_RING_POLL_RETRIES) {
worker->repoll_cursor_ring++;
worker->event_timeout = MIN(worker->event_timeout, CMD_RING_POLL_TIMEOUT);
break;
}
if (worker->repoll_cursor_ring > CMD_RING_POLL_RETRIES ||
worker->qxl->st->qif->req_cursor_notification(worker->qxl)) {
worker->repoll_cursor_ring++;
break;
}
continue;
}
worker->repoll_cursor_ring = 0;
switch (ext_cmd.cmd.type) {
case QXL_CMD_CURSOR: {
RedCursorCmd *cursor = spice_new0(RedCursorCmd, 1);
if (!red_get_cursor_cmd(&worker->mem_slots, ext_cmd.group_id,
cursor, ext_cmd.cmd.data)) {
qxl_process_cursor(worker, cursor, ext_cmd.group_id);
}
break;
}
default:
spice_error("bad command type");
}
n++;
}
return n;
}
static RedDrawable *red_drawable_new(void)
{
RedDrawable * red = spice_new0(RedDrawable, 1);
red->refs = 1;
return red;
}
static int red_process_commands(RedWorker *worker, uint32_t max_pipe_size, int *ring_is_empty)
{
QXLCommandExt ext_cmd;
int n = 0;
uint64_t start = red_now();
if (!worker->running) {
*ring_is_empty = TRUE;
return n;
}
worker->process_commands_generation++;
*ring_is_empty = FALSE;
while (!display_is_connected(worker) ||
// TODO: change to average pipe size?
red_channel_min_pipe_size(&worker->display_channel->common.base) <= max_pipe_size) {
if (!worker->qxl->st->qif->get_command(worker->qxl, &ext_cmd)) {
*ring_is_empty = TRUE;;
if (worker->repoll_cmd_ring < CMD_RING_POLL_RETRIES) {
worker->repoll_cmd_ring++;
worker->event_timeout = MIN(worker->event_timeout, CMD_RING_POLL_TIMEOUT);
break;
}
if (worker->repoll_cmd_ring > CMD_RING_POLL_RETRIES ||
worker->qxl->st->qif->req_cmd_notification(worker->qxl)) {
worker->repoll_cmd_ring++;
break;
}
continue;
}
stat_inc_counter(worker->command_counter, 1);
worker->repoll_cmd_ring = 0;
switch (ext_cmd.cmd.type) {
case QXL_CMD_DRAW: {
RedDrawable *red_drawable = red_drawable_new(); // returns with 1 ref
if (!red_get_drawable(&worker->mem_slots, ext_cmd.group_id,
red_drawable, ext_cmd.cmd.data, ext_cmd.flags)) {
red_process_drawable(worker, red_drawable, ext_cmd.group_id);
}
// release the red_drawable
put_red_drawable(worker, red_drawable, ext_cmd.group_id);
break;
}
case QXL_CMD_UPDATE: {
RedUpdateCmd update;
QXLReleaseInfoExt release_info_ext;
if (red_get_update_cmd(&worker->mem_slots, ext_cmd.group_id,
&update, ext_cmd.cmd.data)) {
break;
}
if (!validate_surface(worker, update.surface_id)) {
rendering_incorrect("QXL_CMD_UPDATE");
break;
}
red_update_area(worker, &update.area, update.surface_id);
worker->qxl->st->qif->notify_update(worker->qxl, update.update_id);
release_info_ext.group_id = ext_cmd.group_id;
release_info_ext.info = update.release_info;
worker->qxl->st->qif->release_resource(worker->qxl, release_info_ext);
red_put_update_cmd(&update);
break;
}
case QXL_CMD_MESSAGE: {
RedMessage message;
QXLReleaseInfoExt release_info_ext;
if (red_get_message(&worker->mem_slots, ext_cmd.group_id,
&message, ext_cmd.cmd.data)) {
break;
}
#ifdef DEBUG
/* alert: accessing message.data is insecure */
spice_warning("MESSAGE: %s", message.data);
#endif
release_info_ext.group_id = ext_cmd.group_id;
release_info_ext.info = message.release_info;
worker->qxl->st->qif->release_resource(worker->qxl, release_info_ext);
red_put_message(&message);
break;
}
case QXL_CMD_SURFACE: {
RedSurfaceCmd *surface = spice_new0(RedSurfaceCmd, 1);
if (red_get_surface_cmd(&worker->mem_slots, ext_cmd.group_id,
surface, ext_cmd.cmd.data)) {
break;
}
red_process_surface(worker, surface, ext_cmd.group_id, FALSE);
break;
}
default:
spice_error("bad command type");
}
n++;
if ((worker->display_channel &&
red_channel_all_blocked(&worker->display_channel->common.base))
|| red_now() - start > 10 * 1000 * 1000) {
worker->event_timeout = 0;
return n;
}
}
return n;
}
#define RED_RELEASE_BUNCH_SIZE 64
static void red_free_some(RedWorker *worker)
{
int n = 0;
DisplayChannelClient *dcc;
RingItem *item, *next;
spice_debug("#draw=%d, #red_draw=%d, #glz_draw=%d", worker->drawable_count,
worker->red_drawable_count, worker->glz_drawable_count);
WORKER_FOREACH_DCC_SAFE(worker, item, next, dcc) {
GlzSharedDictionary *glz_dict = dcc ? dcc->glz_dict : NULL;
if (glz_dict) {
// encoding using the dictionary is prevented since the following operations might
// change the dictionary
pthread_rwlock_wrlock(&glz_dict->encode_lock);
n = red_display_free_some_independent_glz_drawables(dcc);
}
}
while (!ring_is_empty(&worker->current_list) && n++ < RED_RELEASE_BUNCH_SIZE) {
free_one_drawable(worker, TRUE);
}
WORKER_FOREACH_DCC_SAFE(worker, item, next, dcc) {
GlzSharedDictionary *glz_dict = dcc ? dcc->glz_dict : NULL;
if (glz_dict) {
pthread_rwlock_unlock(&glz_dict->encode_lock);
}
}
}
static void red_current_flush(RedWorker *worker, int surface_id)
{
while (!ring_is_empty(&worker->surfaces[surface_id].current_list)) {
free_one_drawable(worker, FALSE);
}
red_current_clear(worker, surface_id);
}
// adding the pipe item after pos. If pos == NULL, adding to head.
static ImageItem *red_add_surface_area_image(DisplayChannelClient *dcc, int surface_id,
SpiceRect *area, PipeItem *pos, int can_lossy)
{
DisplayChannel *display_channel = DCC_TO_DC(dcc);
RedWorker *worker = display_channel->common.worker;
RedChannel *channel = &display_channel->common.base;
RedSurface *surface = &worker->surfaces[surface_id];
SpiceCanvas *canvas = surface->context.canvas;
ImageItem *item;
int stride;
int width;
int height;
int bpp;
int all_set;
spice_assert(area);
width = area->right - area->left;
height = area->bottom - area->top;
bpp = SPICE_SURFACE_FMT_DEPTH(surface->context.format) / 8;
stride = width * bpp;
item = (ImageItem *)spice_malloc_n_m(height, stride, sizeof(ImageItem));
red_channel_pipe_item_init(channel, &item->link, PIPE_ITEM_TYPE_IMAGE);
item->refs = 1;
item->surface_id = surface_id;
item->image_format =
surface_format_to_image_type(surface->context.format);
item->image_flags = 0;
item->pos.x = area->left;
item->pos.y = area->top;
item->width = width;
item->height = height;
item->stride = stride;
item->top_down = surface->context.top_down;
item->can_lossy = can_lossy;
canvas->ops->read_bits(canvas, item->data, stride, area);
/* For 32bit non-primary surfaces we need to keep any non-zero
high bytes as the surface may be used as source to an alpha_blend */
if (!is_primary_surface(worker, surface_id) &&
item->image_format == SPICE_BITMAP_FMT_32BIT &&
rgb32_data_has_alpha(item->width, item->height, item->stride, item->data, &all_set)) {
if (all_set) {
item->image_flags |= SPICE_IMAGE_FLAGS_HIGH_BITS_SET;
} else {
item->image_format = SPICE_BITMAP_FMT_RGBA;
}
}
if (!pos) {
red_pipe_add_image_item(dcc, item);
} else {
red_pipe_add_image_item_after(dcc, item, pos);
}
release_image_item(item);
return item;
}
static void red_push_surface_image(DisplayChannelClient *dcc, int surface_id)
{
SpiceRect area;
RedSurface *surface;
RedWorker *worker;
if (!dcc) {
return;
}
worker = DCC_TO_WORKER(dcc);
surface = &worker->surfaces[surface_id];
if (!surface->context.canvas) {
return;
}
area.top = area.left = 0;
area.right = surface->context.width;
area.bottom = surface->context.height;
/* not allowing lossy compression because probably, especially if it is a primary surface,
it combines both "picture-like" areas with areas that are more "artificial"*/
red_add_surface_area_image(dcc, surface_id, &area, NULL, FALSE);
red_channel_client_push(&dcc->common.base);
}
typedef struct {
uint32_t type;
void *data;
uint32_t size;
} AddBufInfo;
static void marshaller_add_compressed(SpiceMarshaller *m,
RedCompressBuf *comp_buf, size_t size)
{
size_t max = size;
size_t now;
do {
spice_assert(comp_buf);
now = MIN(sizeof(comp_buf->buf), max);
max -= now;
spice_marshaller_add_ref(m, (uint8_t*)comp_buf->buf, now);
comp_buf = comp_buf->send_next;
} while (max);
}
static void add_buf_from_info(SpiceMarshaller *m, AddBufInfo *info)
{
if (info->data) {
switch (info->type) {
case BUF_TYPE_RAW:
spice_marshaller_add_ref(m, info->data, info->size);
break;
}
}
}
static inline void fill_rects_clip(SpiceMarshaller *m, SpiceClipRects *data)
{
int i;
spice_marshaller_add_uint32(m, data->num_rects);
for (i = 0; i < data->num_rects; i++) {
spice_marshall_Rect(m, data->rects + i);
}
}
static void fill_base(SpiceMarshaller *base_marshaller, Drawable *drawable)
{
SpiceMsgDisplayBase base;
base.surface_id = drawable->surface_id;
base.box = drawable->red_drawable->bbox;
base.clip = drawable->red_drawable->clip;
spice_marshall_DisplayBase(base_marshaller, &base);
}
static inline void fill_palette(DisplayChannelClient *dcc,
SpicePalette *palette,
uint8_t *flags)
{
if (palette == NULL) {
return;
}
if (palette->unique) {
if (red_palette_cache_find(dcc, palette->unique)) {
*flags |= SPICE_BITMAP_FLAGS_PAL_FROM_CACHE;
return;
}
if (red_palette_cache_add(dcc, palette->unique, 1)) {
*flags |= SPICE_BITMAP_FLAGS_PAL_CACHE_ME;
}
}
}
static inline RedCompressBuf *red_display_alloc_compress_buf(DisplayChannelClient *dcc)
{
DisplayChannel *display_channel = DCC_TO_DC(dcc);
RedCompressBuf *ret;
if (display_channel->free_compress_bufs) {
ret = display_channel->free_compress_bufs;
display_channel->free_compress_bufs = ret->next;
} else {
ret = spice_new(RedCompressBuf, 1);
}
ret->next = dcc->send_data.used_compress_bufs;
dcc->send_data.used_compress_bufs = ret;
return ret;
}
static inline void __red_display_free_compress_buf(DisplayChannel *dc,
RedCompressBuf *buf)
{
buf->next = dc->free_compress_bufs;
dc->free_compress_bufs = buf;
}
static void red_display_free_compress_buf(DisplayChannelClient *dcc,
RedCompressBuf *buf)
{
DisplayChannel *display_channel = DCC_TO_DC(dcc);
RedCompressBuf **curr_used = &dcc->send_data.used_compress_bufs;
for (;;) {
spice_assert(*curr_used);
if (*curr_used == buf) {
*curr_used = buf->next;
break;
}
curr_used = &(*curr_used)->next;
}
__red_display_free_compress_buf(display_channel, buf);
}
static void red_display_reset_compress_buf(DisplayChannelClient *dcc)
{
while (dcc->send_data.used_compress_bufs) {
RedCompressBuf *buf = dcc->send_data.used_compress_bufs;
dcc->send_data.used_compress_bufs = buf->next;
__red_display_free_compress_buf(DCC_TO_DC(dcc), buf);
}
}
static void red_display_destroy_compress_bufs(DisplayChannel *display_channel)
{
spice_assert(!red_channel_is_connected(&display_channel->common.base));
while (display_channel->free_compress_bufs) {
RedCompressBuf *buf = display_channel->free_compress_bufs;
display_channel->free_compress_bufs = buf->next;
free(buf);
}
}
/******************************************************
* Global lz red drawables routines
*******************************************************/
/* if already exists, returns it. Otherwise allocates and adds it (1) to the ring tail
in the channel (2) to the Drawable*/
static RedGlzDrawable *red_display_get_glz_drawable(DisplayChannelClient *dcc, Drawable *drawable)
{
RedGlzDrawable *ret;
RingItem *item, *next;
// TODO - I don't really understand what's going on here, so doing the technical equivalent
// now that we have multiple glz_dicts, so the only way to go from dcc to drawable glz is to go
// over the glz_ring (unless adding some better data structure then a ring)
DRAWABLE_FOREACH_GLZ_SAFE(drawable, item, next, ret) {
if (ret->dcc == dcc) {
return ret;
}
}
ret = spice_new(RedGlzDrawable, 1);
ret->dcc = dcc;
ret->red_drawable = ref_red_drawable(drawable->red_drawable);
ret->drawable = drawable;
ret->group_id = drawable->group_id;
ret->instances_count = 0;
ring_init(&ret->instances);
ring_item_init(&ret->link);
ring_item_init(&ret->drawable_link);
ring_add_before(&ret->link, &dcc->glz_drawables);
ring_add(&drawable->glz_ring, &ret->drawable_link);
dcc->common.worker->glz_drawable_count++;
return ret;
}
/* allocates new instance and adds it to instances in the given drawable.
NOTE - the caller should set the glz_instance returned by the encoder by itself.*/
static GlzDrawableInstanceItem *red_display_add_glz_drawable_instance(RedGlzDrawable *glz_drawable)
{
spice_assert(glz_drawable->instances_count < MAX_GLZ_DRAWABLE_INSTANCES);
// NOTE: We assume the additions are performed consecutively, without removals in the middle
GlzDrawableInstanceItem *ret = glz_drawable->instances_pool + glz_drawable->instances_count;
glz_drawable->instances_count++;
ring_item_init(&ret->free_link);
ring_item_init(&ret->glz_link);
ring_add(&glz_drawable->instances, &ret->glz_link);
ret->glz_instance = NULL;
ret->red_glz_drawable = glz_drawable;
return ret;
}
/* Remove from the to_free list and the instances_list.
When no instance is left - the RedGlzDrawable is released too. (and the qxl drawable too, if
it is not used by Drawable).
NOTE - 1) can be called only by the display channel that created the drawable
2) it is assumed that the instance was already removed from the dictionary*/
static void red_display_free_glz_drawable_instance(DisplayChannelClient *dcc,
GlzDrawableInstanceItem *glz_drawable_instance)
{
DisplayChannel *display_channel = DCC_TO_DC(dcc);
RedWorker *worker = display_channel->common.worker;
RedGlzDrawable *glz_drawable;
spice_assert(glz_drawable_instance);
spice_assert(glz_drawable_instance->red_glz_drawable);
glz_drawable = glz_drawable_instance->red_glz_drawable;
spice_assert(glz_drawable->dcc == dcc);
spice_assert(glz_drawable->instances_count);
ring_remove(&glz_drawable_instance->glz_link);
glz_drawable->instances_count--;
// when the remove callback is performed from the channel that the
// drawable belongs to, the instance is not added to the 'to_free' list
if (ring_item_is_linked(&glz_drawable_instance->free_link)) {
ring_remove(&glz_drawable_instance->free_link);
}
if (ring_is_empty(&glz_drawable->instances)) {
spice_assert(!glz_drawable->instances_count);
Drawable *drawable = glz_drawable->drawable;
if (drawable) {
ring_remove(&glz_drawable->drawable_link);
}
put_red_drawable(worker, glz_drawable->red_drawable,
glz_drawable->group_id);
worker->glz_drawable_count--;
if (ring_item_is_linked(&glz_drawable->link)) {
ring_remove(&glz_drawable->link);
}
free(glz_drawable);
}
}
static void red_display_handle_glz_drawables_to_free(DisplayChannelClient* dcc)
{
RingItem *ring_link;
if (!dcc->glz_dict) {
return;
}
pthread_mutex_lock(&dcc->glz_drawables_inst_to_free_lock);
while ((ring_link = ring_get_head(&dcc->glz_drawables_inst_to_free))) {
GlzDrawableInstanceItem *drawable_instance = SPICE_CONTAINEROF(ring_link,
GlzDrawableInstanceItem,
free_link);
red_display_free_glz_drawable_instance(dcc, drawable_instance);
}
pthread_mutex_unlock(&dcc->glz_drawables_inst_to_free_lock);
}
/*
* Releases all the instances of the drawable from the dictionary and the display channel client.
* The release of the last instance will also release the drawable itself and the qxl drawable
* if possible.
* NOTE - the caller should prevent encoding using the dictionary during this operation
*/
static void red_display_free_glz_drawable(DisplayChannelClient *dcc, RedGlzDrawable *drawable)
{
RingItem *head_instance = ring_get_head(&drawable->instances);
int cont = (head_instance != NULL);
while (cont) {
if (drawable->instances_count == 1) {
/* Last instance: red_display_free_glz_drawable_instance will free the drawable */
cont = FALSE;
}
GlzDrawableInstanceItem *instance = SPICE_CONTAINEROF(head_instance,
GlzDrawableInstanceItem,
glz_link);
if (!ring_item_is_linked(&instance->free_link)) {
// the instance didn't get out from window yet
glz_enc_dictionary_remove_image(dcc->glz_dict->dict,
instance->glz_instance,
&dcc->glz_data.usr);
}
red_display_free_glz_drawable_instance(dcc, instance);
if (cont) {
head_instance = ring_get_head(&drawable->instances);
}
}
}
/* Clear all lz drawables - enforce their removal from the global dictionary.
NOTE - prevents encoding using the dictionary during the operation*/
static void red_display_client_clear_glz_drawables(DisplayChannelClient *dcc)
{
RingItem *ring_link;
GlzSharedDictionary *glz_dict = dcc ? dcc->glz_dict : NULL;
if (!glz_dict) {
return;
}
// assure no display channel is during global lz encoding
pthread_rwlock_wrlock(&glz_dict->encode_lock);
while ((ring_link = ring_get_head(&dcc->glz_drawables))) {
RedGlzDrawable *drawable = SPICE_CONTAINEROF(ring_link, RedGlzDrawable, link);
// no need to lock the to_free list, since we assured no other thread is encoding and
// thus not other thread access the to_free list of the channel
red_display_free_glz_drawable(dcc, drawable);
}
pthread_rwlock_unlock(&glz_dict->encode_lock);
}
static void red_display_clear_glz_drawables(DisplayChannel *display_channel)
{
RingItem *link, *next;
DisplayChannelClient *dcc;
if (!display_channel) {
return;
}
DCC_FOREACH_SAFE(link, next, dcc, &display_channel->common.base) {
red_display_client_clear_glz_drawables(dcc);
}
}
/*
* Remove from the global lz dictionary some glz_drawables that have no reference to
* Drawable (their qxl drawables are released too).
* NOTE - the caller should prevent encoding using the dictionary during the operation
*/
static int red_display_free_some_independent_glz_drawables(DisplayChannelClient *dcc)
{
RingItem *ring_link;
int n = 0;
if (!dcc) {
return 0;
}
ring_link = ring_get_head(&dcc->glz_drawables);
while ((n < RED_RELEASE_BUNCH_SIZE) && (ring_link != NULL)) {
RedGlzDrawable *glz_drawable = SPICE_CONTAINEROF(ring_link, RedGlzDrawable, link);
ring_link = ring_next(&dcc->glz_drawables, ring_link);
if (!glz_drawable->drawable) {
red_display_free_glz_drawable(dcc, glz_drawable);
n++;
}
}
return n;
}
/******************************************************
* Encoders callbacks
*******************************************************/
static SPICE_GNUC_NORETURN SPICE_GNUC_PRINTF(2, 3) void
quic_usr_error(QuicUsrContext *usr, const char *fmt, ...)
{
EncoderData *usr_data = &(((QuicData *)usr)->data);
va_list ap;
va_start(ap, fmt);
vsnprintf(usr_data->message_buf, sizeof(usr_data->message_buf), fmt, ap);
va_end(ap);
spice_critical("%s", usr_data->message_buf);
longjmp(usr_data->jmp_env, 1);
}
static SPICE_GNUC_NORETURN SPICE_GNUC_PRINTF(2, 3) void
lz_usr_error(LzUsrContext *usr, const char *fmt, ...)
{
EncoderData *usr_data = &(((LzData *)usr)->data);
va_list ap;
va_start(ap, fmt);
vsnprintf(usr_data->message_buf, sizeof(usr_data->message_buf), fmt, ap);
va_end(ap);
spice_critical("%s", usr_data->message_buf);
longjmp(usr_data->jmp_env, 1);
}
static SPICE_GNUC_PRINTF(2, 3) void glz_usr_error(GlzEncoderUsrContext *usr, const char *fmt, ...)
{
EncoderData *usr_data = &(((GlzData *)usr)->data);
va_list ap;
va_start(ap, fmt);
vsnprintf(usr_data->message_buf, sizeof(usr_data->message_buf), fmt, ap);
va_end(ap);
spice_critical("%s", usr_data->message_buf); // if global lz fails in the middle
// the consequences are not predictable since the window
// can turn to be unsynchronized between the server and
// and the client
}
static SPICE_GNUC_PRINTF(2, 3) void quic_usr_warn(QuicUsrContext *usr, const char *fmt, ...)
{
EncoderData *usr_data = &(((QuicData *)usr)->data);
va_list ap;
va_start(ap, fmt);
vsnprintf(usr_data->message_buf, sizeof(usr_data->message_buf), fmt, ap);
va_end(ap);
spice_warning("%s", usr_data->message_buf);
}
static SPICE_GNUC_PRINTF(2, 3) void lz_usr_warn(LzUsrContext *usr, const char *fmt, ...)
{
EncoderData *usr_data = &(((LzData *)usr)->data);
va_list ap;
va_start(ap, fmt);
vsnprintf(usr_data->message_buf, sizeof(usr_data->message_buf), fmt, ap);
va_end(ap);
spice_warning("%s", usr_data->message_buf);
}
static SPICE_GNUC_PRINTF(2, 3) void glz_usr_warn(GlzEncoderUsrContext *usr, const char *fmt, ...)
{
EncoderData *usr_data = &(((GlzData *)usr)->data);
va_list ap;
va_start(ap, fmt);
vsnprintf(usr_data->message_buf, sizeof(usr_data->message_buf), fmt, ap);
va_end(ap);
spice_warning("%s", usr_data->message_buf);
}
static void *quic_usr_malloc(QuicUsrContext *usr, int size)
{
return spice_malloc(size);
}
static void *lz_usr_malloc(LzUsrContext *usr, int size)
{
return spice_malloc(size);
}
static void *glz_usr_malloc(GlzEncoderUsrContext *usr, int size)
{
return spice_malloc(size);
}
static void quic_usr_free(QuicUsrContext *usr, void *ptr)
{
free(ptr);
}
static void lz_usr_free(LzUsrContext *usr, void *ptr)
{
free(ptr);
}
static void glz_usr_free(GlzEncoderUsrContext *usr, void *ptr)
{
free(ptr);
}
static inline int encoder_usr_more_space(EncoderData *enc_data, uint32_t **io_ptr)
{
RedCompressBuf *buf;
if (!(buf = red_display_alloc_compress_buf(enc_data->dcc))) {
return 0;
}
enc_data->bufs_tail->send_next = buf;
enc_data->bufs_tail = buf;
buf->send_next = NULL;
*io_ptr = buf->buf;
return sizeof(buf->buf) >> 2;
}
static int quic_usr_more_space(QuicUsrContext *usr, uint32_t **io_ptr, int rows_completed)
{
EncoderData *usr_data = &(((QuicData *)usr)->data);
return encoder_usr_more_space(usr_data, io_ptr);
}
static int lz_usr_more_space(LzUsrContext *usr, uint8_t **io_ptr)
{
EncoderData *usr_data = &(((LzData *)usr)->data);
return (encoder_usr_more_space(usr_data, (uint32_t **)io_ptr) << 2);
}
static int glz_usr_more_space(GlzEncoderUsrContext *usr, uint8_t **io_ptr)
{
EncoderData *usr_data = &(((GlzData *)usr)->data);
return (encoder_usr_more_space(usr_data, (uint32_t **)io_ptr) << 2);
}
static int jpeg_usr_more_space(JpegEncoderUsrContext *usr, uint8_t **io_ptr)
{
EncoderData *usr_data = &(((JpegData *)usr)->data);
return (encoder_usr_more_space(usr_data, (uint32_t **)io_ptr) << 2);
}
static int zlib_usr_more_space(ZlibEncoderUsrContext *usr, uint8_t **io_ptr)
{
EncoderData *usr_data = &(((ZlibData *)usr)->data);
return (encoder_usr_more_space(usr_data, (uint32_t **)io_ptr) << 2);
}
static inline int encoder_usr_more_lines(EncoderData *enc_data, uint8_t **lines)
{
struct SpiceChunk *chunk;
if (enc_data->u.lines_data.reverse) {
if (!(enc_data->u.lines_data.next >= 0)) {
return 0;
}
} else {
if (!(enc_data->u.lines_data.next < enc_data->u.lines_data.chunks->num_chunks)) {
return 0;
}
}
chunk = &enc_data->u.lines_data.chunks->chunk[enc_data->u.lines_data.next];
if (chunk->len % enc_data->u.lines_data.stride) {
return 0;
}
if (enc_data->u.lines_data.reverse) {
enc_data->u.lines_data.next--;
*lines = chunk->data + chunk->len - enc_data->u.lines_data.stride;
} else {
enc_data->u.lines_data.next++;
*lines = chunk->data;
}
return chunk->len / enc_data->u.lines_data.stride;
}
static int quic_usr_more_lines(QuicUsrContext *usr, uint8_t **lines)
{
EncoderData *usr_data = &(((QuicData *)usr)->data);
return encoder_usr_more_lines(usr_data, lines);
}
static int lz_usr_more_lines(LzUsrContext *usr, uint8_t **lines)
{
EncoderData *usr_data = &(((LzData *)usr)->data);
return encoder_usr_more_lines(usr_data, lines);
}
static int glz_usr_more_lines(GlzEncoderUsrContext *usr, uint8_t **lines)
{
EncoderData *usr_data = &(((GlzData *)usr)->data);
return encoder_usr_more_lines(usr_data, lines);
}
static int jpeg_usr_more_lines(JpegEncoderUsrContext *usr, uint8_t **lines)
{
EncoderData *usr_data = &(((JpegData *)usr)->data);
return encoder_usr_more_lines(usr_data, lines);
}
static int zlib_usr_more_input(ZlibEncoderUsrContext *usr, uint8_t** input)
{
EncoderData *usr_data = &(((ZlibData *)usr)->data);
int buf_size;
if (!usr_data->u.compressed_data.next) {
spice_assert(usr_data->u.compressed_data.size_left == 0);
return 0;
}
*input = (uint8_t*)usr_data->u.compressed_data.next->buf;
buf_size = MIN(sizeof(usr_data->u.compressed_data.next->buf),
usr_data->u.compressed_data.size_left);
usr_data->u.compressed_data.next = usr_data->u.compressed_data.next->send_next;
usr_data->u.compressed_data.size_left -= buf_size;
return buf_size;
}
static void glz_usr_free_image(GlzEncoderUsrContext *usr, GlzUsrImageContext *image)
{
GlzData *lz_data = (GlzData *)usr;
GlzDrawableInstanceItem *glz_drawable_instance = (GlzDrawableInstanceItem *)image;
DisplayChannelClient *drawable_cc = glz_drawable_instance->red_glz_drawable->dcc;
DisplayChannelClient *this_cc = SPICE_CONTAINEROF(lz_data, DisplayChannelClient, glz_data);
if (this_cc == drawable_cc) {
red_display_free_glz_drawable_instance(drawable_cc, glz_drawable_instance);
} else {
/* The glz dictionary is shared between all DisplayChannelClient
* instances that belong to the same client, and glz_usr_free_image
* can be called by the dictionary code
* (glz_dictionary_window_remove_head). Thus this function can be
* called from any DisplayChannelClient thread, hence the need for
* this check.
*/
pthread_mutex_lock(&drawable_cc->glz_drawables_inst_to_free_lock);
ring_add_before(&glz_drawable_instance->free_link,
&drawable_cc->glz_drawables_inst_to_free);
pthread_mutex_unlock(&drawable_cc->glz_drawables_inst_to_free_lock);
}
}
static inline void red_init_quic(RedWorker *worker)
{
worker->quic_data.usr.error = quic_usr_error;
worker->quic_data.usr.warn = quic_usr_warn;
worker->quic_data.usr.info = quic_usr_warn;
worker->quic_data.usr.malloc = quic_usr_malloc;
worker->quic_data.usr.free = quic_usr_free;
worker->quic_data.usr.more_space = quic_usr_more_space;
worker->quic_data.usr.more_lines = quic_usr_more_lines;
worker->quic = quic_create(&worker->quic_data.usr);
if (!worker->quic) {
spice_critical("create quic failed");
}
}
static inline void red_init_lz(RedWorker *worker)
{
worker->lz_data.usr.error = lz_usr_error;
worker->lz_data.usr.warn = lz_usr_warn;
worker->lz_data.usr.info = lz_usr_warn;
worker->lz_data.usr.malloc = lz_usr_malloc;
worker->lz_data.usr.free = lz_usr_free;
worker->lz_data.usr.more_space = lz_usr_more_space;
worker->lz_data.usr.more_lines = lz_usr_more_lines;
worker->lz = lz_create(&worker->lz_data.usr);
if (!worker->lz) {
spice_critical("create lz failed");
}
}
/* TODO: split off to DisplayChannel? avoid just copying those cb pointers */
static inline void red_display_init_glz_data(DisplayChannelClient *dcc)
{
dcc->glz_data.usr.error = glz_usr_error;
dcc->glz_data.usr.warn = glz_usr_warn;
dcc->glz_data.usr.info = glz_usr_warn;
dcc->glz_data.usr.malloc = glz_usr_malloc;
dcc->glz_data.usr.free = glz_usr_free;
dcc->glz_data.usr.more_space = glz_usr_more_space;
dcc->glz_data.usr.more_lines = glz_usr_more_lines;
dcc->glz_data.usr.free_image = glz_usr_free_image;
}
static inline void red_init_jpeg(RedWorker *worker)
{
worker->jpeg_data.usr.more_space = jpeg_usr_more_space;
worker->jpeg_data.usr.more_lines = jpeg_usr_more_lines;
worker->jpeg = jpeg_encoder_create(&worker->jpeg_data.usr);
if (!worker->jpeg) {
spice_critical("create jpeg encoder failed");
}
}
static inline void red_init_zlib(RedWorker *worker)
{
worker->zlib_data.usr.more_space = zlib_usr_more_space;
worker->zlib_data.usr.more_input = zlib_usr_more_input;
worker->zlib = zlib_encoder_create(&worker->zlib_data.usr, ZLIB_DEFAULT_COMPRESSION_LEVEL);
if (!worker->zlib) {
spice_critical("create zlib encoder failed");
}
}
#ifdef __GNUC__
#define ATTR_PACKED __attribute__ ((__packed__))
#else
#define ATTR_PACKED
#pragma pack(push)
#pragma pack(1)
#endif
typedef struct ATTR_PACKED rgb32_pixel_t {
uint8_t b;
uint8_t g;
uint8_t r;
uint8_t pad;
} rgb32_pixel_t;
typedef struct ATTR_PACKED rgb24_pixel_t {
uint8_t b;
uint8_t g;
uint8_t r;
} rgb24_pixel_t;
typedef uint16_t rgb16_pixel_t;
#ifndef __GNUC__
#pragma pack(pop)
#endif
#undef ATTR_PACKED
#define RED_BITMAP_UTILS_RGB16
#include "red_bitmap_utils.h"
#define RED_BITMAP_UTILS_RGB24
#include "red_bitmap_utils.h"
#define RED_BITMAP_UTILS_RGB32
#include "red_bitmap_utils.h"
#define GRADUAL_HIGH_RGB24_TH -0.03
#define GRADUAL_HIGH_RGB16_TH 0
// setting a more permissive threshold for stream identification in order
// not to miss streams that were artificially scaled on the guest (e.g., full screen view
// in window media player 12). see red_stream_add_frame
#define GRADUAL_MEDIUM_SCORE_TH 0.002
// assumes that stride doesn't overflow
static BitmapGradualType _get_bitmap_graduality_level(RedWorker *worker, SpiceBitmap *bitmap,
uint32_t group_id)
{
double score = 0.0;
int num_samples = 0;
int num_lines;
double chunk_score = 0.0;
int chunk_num_samples = 0;
uint32_t x, i;
SpiceChunk *chunk;
chunk = bitmap->data->chunk;
for (i = 0; i < bitmap->data->num_chunks; i++) {
num_lines = chunk[i].len / bitmap->stride;
x = bitmap->x;
switch (bitmap->format) {
case SPICE_BITMAP_FMT_16BIT:
compute_lines_gradual_score_rgb16((rgb16_pixel_t *)chunk[i].data, x, num_lines,
&chunk_score, &chunk_num_samples);
break;
case SPICE_BITMAP_FMT_24BIT:
compute_lines_gradual_score_rgb24((rgb24_pixel_t *)chunk[i].data, x, num_lines,
&chunk_score, &chunk_num_samples);
break;
case SPICE_BITMAP_FMT_32BIT:
case SPICE_BITMAP_FMT_RGBA:
compute_lines_gradual_score_rgb32((rgb32_pixel_t *)chunk[i].data, x, num_lines,
&chunk_score, &chunk_num_samples);
break;
default:
spice_error("invalid bitmap format (not RGB) %u", bitmap->format);
}
score += chunk_score;
num_samples += chunk_num_samples;
}
spice_assert(num_samples);
score /= num_samples;
if (bitmap->format == SPICE_BITMAP_FMT_16BIT) {
if (score < GRADUAL_HIGH_RGB16_TH) {
return BITMAP_GRADUAL_HIGH;
}
} else {
if (score < GRADUAL_HIGH_RGB24_TH) {
return BITMAP_GRADUAL_HIGH;
}
}
if (score < GRADUAL_MEDIUM_SCORE_TH) {
return BITMAP_GRADUAL_MEDIUM;
} else {
return BITMAP_GRADUAL_LOW;
}
}
static inline int _stride_is_extra(SpiceBitmap *bitmap)
{
spice_assert(bitmap);
if (bitmap_fmt_is_rgb(bitmap->format)) {
return ((bitmap->x * BITMAP_FMP_BYTES_PER_PIXEL[bitmap->format]) < bitmap->stride);
} else {
switch (bitmap->format) {
case SPICE_BITMAP_FMT_8BIT:
return (bitmap->x < bitmap->stride);
case SPICE_BITMAP_FMT_4BIT_BE:
case SPICE_BITMAP_FMT_4BIT_LE: {
int bytes_width = SPICE_ALIGN(bitmap->x, 2) >> 1;
return bytes_width < bitmap->stride;
}
case SPICE_BITMAP_FMT_1BIT_BE:
case SPICE_BITMAP_FMT_1BIT_LE: {
int bytes_width = SPICE_ALIGN(bitmap->x, 8) >> 3;
return bytes_width < bitmap->stride;
}
default:
spice_error("invalid image type %u", bitmap->format);
return 0;
}
}
return 0;
}
typedef struct compress_send_data_t {
void* comp_buf;
uint32_t comp_buf_size;
SpicePalette *lzplt_palette;
int is_lossy;
} compress_send_data_t;
static inline int red_glz_compress_image(DisplayChannelClient *dcc,
SpiceImage *dest, SpiceBitmap *src, Drawable *drawable,
compress_send_data_t* o_comp_data)
{
DisplayChannel *display_channel = DCC_TO_DC(dcc);
RedWorker *worker = display_channel->common.worker;
#ifdef COMPRESS_STAT
stat_time_t start_time = stat_now();
#endif
spice_assert(bitmap_fmt_is_rgb(src->format));
GlzData *glz_data = &dcc->glz_data;
ZlibData *zlib_data;
LzImageType type = MAP_BITMAP_FMT_TO_LZ_IMAGE_TYPE[src->format];
RedGlzDrawable *glz_drawable;
GlzDrawableInstanceItem *glz_drawable_instance;
int glz_size;
int zlib_size;
glz_data->data.bufs_tail = red_display_alloc_compress_buf(dcc);
glz_data->data.bufs_head = glz_data->data.bufs_tail;
if (!glz_data->data.bufs_head) {
return FALSE;
}
glz_data->data.bufs_head->send_next = NULL;
glz_data->data.dcc = dcc;
glz_drawable = red_display_get_glz_drawable(dcc, drawable);
glz_drawable_instance = red_display_add_glz_drawable_instance(glz_drawable);
glz_data->data.u.lines_data.chunks = src->data;
glz_data->data.u.lines_data.stride = src->stride;
glz_data->data.u.lines_data.next = 0;
glz_data->data.u.lines_data.reverse = 0;
glz_data->usr.more_lines = glz_usr_more_lines;
glz_size = glz_encode(dcc->glz, type, src->x, src->y,
(src->flags & SPICE_BITMAP_FLAGS_TOP_DOWN), NULL, 0,
src->stride, (uint8_t*)glz_data->data.bufs_head->buf,
sizeof(glz_data->data.bufs_head->buf),
glz_drawable_instance,
&glz_drawable_instance->glz_instance);
stat_compress_add(&display_channel->glz_stat, start_time, src->stride * src->y, glz_size);
if (!display_channel->enable_zlib_glz_wrap || (glz_size < MIN_GLZ_SIZE_FOR_ZLIB)) {
goto glz;
}
#ifdef COMPRESS_STAT
start_time = stat_now();
#endif
zlib_data = &worker->zlib_data;
zlib_data->data.bufs_tail = red_display_alloc_compress_buf(dcc);
zlib_data->data.bufs_head = zlib_data->data.bufs_tail;
if (!zlib_data->data.bufs_head) {
spice_warning("failed to allocate zlib compress buffer");
goto glz;
}
zlib_data->data.bufs_head->send_next = NULL;
zlib_data->data.dcc = dcc;
zlib_data->data.u.compressed_data.next = glz_data->data.bufs_head;
zlib_data->data.u.compressed_data.size_left = glz_size;
zlib_size = zlib_encode(worker->zlib, display_channel->zlib_level,
glz_size, (uint8_t*)zlib_data->data.bufs_head->buf,
sizeof(zlib_data->data.bufs_head->buf));
// the compressed buffer is bigger than the original data
if (zlib_size >= glz_size) {
while (zlib_data->data.bufs_head) {
RedCompressBuf *buf = zlib_data->data.bufs_head;
zlib_data->data.bufs_head = buf->send_next;
red_display_free_compress_buf(dcc, buf);
}
goto glz;
}
dest->descriptor.type = SPICE_IMAGE_TYPE_ZLIB_GLZ_RGB;
dest->u.zlib_glz.glz_data_size = glz_size;
dest->u.zlib_glz.data_size = zlib_size;
o_comp_data->comp_buf = zlib_data->data.bufs_head;
o_comp_data->comp_buf_size = zlib_size;
stat_compress_add(&display_channel->zlib_glz_stat, start_time, glz_size, zlib_size);
return TRUE;
glz:
dest->descriptor.type = SPICE_IMAGE_TYPE_GLZ_RGB;
dest->u.lz_rgb.data_size = glz_size;
o_comp_data->comp_buf = glz_data->data.bufs_head;
o_comp_data->comp_buf_size = glz_size;
return TRUE;
}
static inline int red_lz_compress_image(DisplayChannelClient *dcc,
SpiceImage *dest, SpiceBitmap *src,
compress_send_data_t* o_comp_data, uint32_t group_id)
{
DisplayChannel *display_channel = DCC_TO_DC(dcc);
RedWorker *worker = display_channel->common.worker;
LzData *lz_data = &worker->lz_data;
LzContext *lz = worker->lz;
LzImageType type = MAP_BITMAP_FMT_TO_LZ_IMAGE_TYPE[src->format];
int size; // size of the compressed data
#ifdef COMPRESS_STAT
stat_time_t start_time = stat_now();
#endif
lz_data->data.bufs_tail = red_display_alloc_compress_buf(dcc);
lz_data->data.bufs_head = lz_data->data.bufs_tail;
if (!lz_data->data.bufs_head) {
return FALSE;
}
lz_data->data.bufs_head->send_next = NULL;
lz_data->data.dcc = dcc;
if (setjmp(lz_data->data.jmp_env)) {
while (lz_data->data.bufs_head) {
RedCompressBuf *buf = lz_data->data.bufs_head;
lz_data->data.bufs_head = buf->send_next;
red_display_free_compress_buf(dcc, buf);
}
return FALSE;
}
lz_data->data.u.lines_data.chunks = src->data;
lz_data->data.u.lines_data.stride = src->stride;
lz_data->data.u.lines_data.next = 0;
lz_data->data.u.lines_data.reverse = 0;
lz_data->usr.more_lines = lz_usr_more_lines;
size = lz_encode(lz, type, src->x, src->y,
!!(src->flags & SPICE_BITMAP_FLAGS_TOP_DOWN),
NULL, 0, src->stride,
(uint8_t*)lz_data->data.bufs_head->buf,
sizeof(lz_data->data.bufs_head->buf));
// the compressed buffer is bigger than the original data
if (size > (src->y * src->stride)) {
longjmp(lz_data->data.jmp_env, 1);
}
if (bitmap_fmt_is_rgb(src->format)) {
dest->descriptor.type = SPICE_IMAGE_TYPE_LZ_RGB;
dest->u.lz_rgb.data_size = size;
o_comp_data->comp_buf = lz_data->data.bufs_head;
o_comp_data->comp_buf_size = size;
} else {
/* masks are 1BIT bitmaps without palettes, but they are not compressed
* (see fill_mask) */
spice_assert(src->palette);
dest->descriptor.type = SPICE_IMAGE_TYPE_LZ_PLT;
dest->u.lz_plt.data_size = size;
dest->u.lz_plt.flags = src->flags & SPICE_BITMAP_FLAGS_TOP_DOWN;
dest->u.lz_plt.palette = src->palette;
dest->u.lz_plt.palette_id = src->palette->unique;
o_comp_data->comp_buf = lz_data->data.bufs_head;
o_comp_data->comp_buf_size = size;
fill_palette(dcc, dest->u.lz_plt.palette, &(dest->u.lz_plt.flags));
o_comp_data->lzplt_palette = dest->u.lz_plt.palette;
}
stat_compress_add(&display_channel->lz_stat, start_time, src->stride * src->y,
o_comp_data->comp_buf_size);
return TRUE;
}
static int red_jpeg_compress_image(DisplayChannelClient *dcc, SpiceImage *dest,
SpiceBitmap *src, compress_send_data_t* o_comp_data,
uint32_t group_id)
{
DisplayChannel *display_channel = DCC_TO_DC(dcc);
RedWorker *worker = display_channel->common.worker;
JpegData *jpeg_data = &worker->jpeg_data;
LzData *lz_data = &worker->lz_data;
JpegEncoderContext *jpeg = worker->jpeg;
LzContext *lz = worker->lz;
volatile JpegEncoderImageType jpeg_in_type;
int jpeg_size = 0;
volatile int has_alpha = FALSE;
int alpha_lz_size = 0;
int comp_head_filled;
int comp_head_left;
int stride;
uint8_t *lz_out_start_byte;
#ifdef COMPRESS_STAT
stat_time_t start_time = stat_now();
#endif
switch (src->format) {
case SPICE_BITMAP_FMT_16BIT:
jpeg_in_type = JPEG_IMAGE_TYPE_RGB16;
break;
case SPICE_BITMAP_FMT_24BIT:
jpeg_in_type = JPEG_IMAGE_TYPE_BGR24;
break;
case SPICE_BITMAP_FMT_32BIT:
jpeg_in_type = JPEG_IMAGE_TYPE_BGRX32;
break;
case SPICE_BITMAP_FMT_RGBA:
jpeg_in_type = JPEG_IMAGE_TYPE_BGRX32;
has_alpha = TRUE;
break;
default:
return FALSE;
}
jpeg_data->data.bufs_tail = red_display_alloc_compress_buf(dcc);
jpeg_data->data.bufs_head = jpeg_data->data.bufs_tail;
if (!jpeg_data->data.bufs_head) {
spice_warning("failed to allocate compress buffer");
return FALSE;
}
jpeg_data->data.bufs_head->send_next = NULL;
jpeg_data->data.dcc = dcc;
if (setjmp(jpeg_data->data.jmp_env)) {
while (jpeg_data->data.bufs_head) {
RedCompressBuf *buf = jpeg_data->data.bufs_head;
jpeg_data->data.bufs_head = buf->send_next;
red_display_free_compress_buf(dcc, buf);
}
return FALSE;
}
if (src->data->flags & SPICE_CHUNKS_FLAGS_UNSTABLE) {
spice_chunks_linearize(src->data);
}
jpeg_data->data.u.lines_data.chunks = src->data;
jpeg_data->data.u.lines_data.stride = src->stride;
jpeg_data->usr.more_lines = jpeg_usr_more_lines;
if ((src->flags & SPICE_BITMAP_FLAGS_TOP_DOWN)) {
jpeg_data->data.u.lines_data.next = 0;
jpeg_data->data.u.lines_data.reverse = 0;
stride = src->stride;
} else {
jpeg_data->data.u.lines_data.next = src->data->num_chunks - 1;
jpeg_data->data.u.lines_data.reverse = 1;
stride = -src->stride;
}
jpeg_size = jpeg_encode(jpeg, display_channel->jpeg_quality, jpeg_in_type,
src->x, src->y, NULL,
0, stride, (uint8_t*)jpeg_data->data.bufs_head->buf,
sizeof(jpeg_data->data.bufs_head->buf));
// the compressed buffer is bigger than the original data
if (jpeg_size > (src->y * src->stride)) {
longjmp(jpeg_data->data.jmp_env, 1);
}
if (!has_alpha) {
dest->descriptor.type = SPICE_IMAGE_TYPE_JPEG;
dest->u.jpeg.data_size = jpeg_size;
o_comp_data->comp_buf = jpeg_data->data.bufs_head;
o_comp_data->comp_buf_size = jpeg_size;
o_comp_data->is_lossy = TRUE;
stat_compress_add(&display_channel->jpeg_stat, start_time, src->stride * src->y,
o_comp_data->comp_buf_size);
return TRUE;
}
lz_data->data.bufs_head = jpeg_data->data.bufs_tail;
lz_data->data.bufs_tail = lz_data->data.bufs_head;
comp_head_filled = jpeg_size % sizeof(lz_data->data.bufs_head->buf);
comp_head_left = sizeof(lz_data->data.bufs_head->buf) - comp_head_filled;
lz_out_start_byte = ((uint8_t *)lz_data->data.bufs_head->buf) + comp_head_filled;
lz_data->data.dcc = dcc;
lz_data->data.u.lines_data.chunks = src->data;
lz_data->data.u.lines_data.stride = src->stride;
lz_data->data.u.lines_data.next = 0;
lz_data->data.u.lines_data.reverse = 0;
lz_data->usr.more_lines = lz_usr_more_lines;
alpha_lz_size = lz_encode(lz, LZ_IMAGE_TYPE_XXXA, src->x, src->y,
!!(src->flags & SPICE_BITMAP_FLAGS_TOP_DOWN),
NULL, 0, src->stride,
lz_out_start_byte,
comp_head_left);
// the compressed buffer is bigger than the original data
if ((jpeg_size + alpha_lz_size) > (src->y * src->stride)) {
longjmp(jpeg_data->data.jmp_env, 1);
}
dest->descriptor.type = SPICE_IMAGE_TYPE_JPEG_ALPHA;
dest->u.jpeg_alpha.flags = 0;
if (src->flags & SPICE_BITMAP_FLAGS_TOP_DOWN) {
dest->u.jpeg_alpha.flags |= SPICE_JPEG_ALPHA_FLAGS_TOP_DOWN;
}
dest->u.jpeg_alpha.jpeg_size = jpeg_size;
dest->u.jpeg_alpha.data_size = jpeg_size + alpha_lz_size;
o_comp_data->comp_buf = jpeg_data->data.bufs_head;
o_comp_data->comp_buf_size = jpeg_size + alpha_lz_size;
o_comp_data->is_lossy = TRUE;
stat_compress_add(&display_channel->jpeg_alpha_stat, start_time, src->stride * src->y,
o_comp_data->comp_buf_size);
return TRUE;
}
static inline int red_quic_compress_image(DisplayChannelClient *dcc, SpiceImage *dest,
SpiceBitmap *src, compress_send_data_t* o_comp_data,
uint32_t group_id)
{
DisplayChannel *display_channel = DCC_TO_DC(dcc);
RedWorker *worker = display_channel->common.worker;
QuicData *quic_data = &worker->quic_data;
QuicContext *quic = worker->quic;
volatile QuicImageType type;
int size, stride;
#ifdef COMPRESS_STAT
stat_time_t start_time = stat_now();
#endif
switch (src->format) {
case SPICE_BITMAP_FMT_32BIT:
type = QUIC_IMAGE_TYPE_RGB32;
break;
case SPICE_BITMAP_FMT_RGBA:
type = QUIC_IMAGE_TYPE_RGBA;
break;
case SPICE_BITMAP_FMT_16BIT:
type = QUIC_IMAGE_TYPE_RGB16;
break;
case SPICE_BITMAP_FMT_24BIT:
type = QUIC_IMAGE_TYPE_RGB24;
break;
default:
return FALSE;
}
quic_data->data.bufs_tail = red_display_alloc_compress_buf(dcc);
quic_data->data.bufs_head = quic_data->data.bufs_tail;
if (!quic_data->data.bufs_head) {
return FALSE;
}
quic_data->data.bufs_head->send_next = NULL;
quic_data->data.dcc = dcc;
if (setjmp(quic_data->data.jmp_env)) {
while (quic_data->data.bufs_head) {
RedCompressBuf *buf = quic_data->data.bufs_head;
quic_data->data.bufs_head = buf->send_next;
red_display_free_compress_buf(dcc, buf);
}
return FALSE;
}
if (src->data->flags & SPICE_CHUNKS_FLAGS_UNSTABLE) {
spice_chunks_linearize(src->data);
}
quic_data->data.u.lines_data.chunks = src->data;
quic_data->data.u.lines_data.stride = src->stride;
quic_data->usr.more_lines = quic_usr_more_lines;
if ((src->flags & SPICE_BITMAP_FLAGS_TOP_DOWN)) {
quic_data->data.u.lines_data.next = 0;
quic_data->data.u.lines_data.reverse = 0;
stride = src->stride;
} else {
quic_data->data.u.lines_data.next = src->data->num_chunks - 1;
quic_data->data.u.lines_data.reverse = 1;
stride = -src->stride;
}
size = quic_encode(quic, type, src->x, src->y, NULL, 0, stride,
quic_data->data.bufs_head->buf,
sizeof(quic_data->data.bufs_head->buf) >> 2);
// the compressed buffer is bigger than the original data
if ((size << 2) > (src->y * src->stride)) {
longjmp(quic_data->data.jmp_env, 1);
}
dest->descriptor.type = SPICE_IMAGE_TYPE_QUIC;
dest->u.quic.data_size = size << 2;
o_comp_data->comp_buf = quic_data->data.bufs_head;
o_comp_data->comp_buf_size = size << 2;
stat_compress_add(&display_channel->quic_stat, start_time, src->stride * src->y,
o_comp_data->comp_buf_size);
return TRUE;
}
#define MIN_SIZE_TO_COMPRESS 54
#define MIN_DIMENSION_TO_QUIC 3
static inline int red_compress_image(DisplayChannelClient *dcc,
SpiceImage *dest, SpiceBitmap *src, Drawable *drawable,
int can_lossy,
compress_send_data_t* o_comp_data)
{
DisplayChannel *display_channel = DCC_TO_DC(dcc);
spice_image_compression_t image_compression =
display_channel->common.worker->image_compression;
int quic_compress = FALSE;
if ((image_compression == SPICE_IMAGE_COMPRESS_OFF) ||
((src->y * src->stride) < MIN_SIZE_TO_COMPRESS)) { // TODO: change the size cond
return FALSE;
} else if (image_compression == SPICE_IMAGE_COMPRESS_QUIC) {
if (BITMAP_FMT_IS_PLT[src->format]) {
return FALSE;
} else {
quic_compress = TRUE;
}
} else {
/*
lz doesn't handle (1) bitmaps with strides that are larger than the width
of the image in bytes (2) unstable bitmaps
*/
if (_stride_is_extra(src) || (src->data->flags & SPICE_CHUNKS_FLAGS_UNSTABLE)) {
if ((image_compression == SPICE_IMAGE_COMPRESS_LZ) ||
(image_compression == SPICE_IMAGE_COMPRESS_GLZ) ||
BITMAP_FMT_IS_PLT[src->format]) {
return FALSE;
} else {
quic_compress = TRUE;
}
} else {
if ((image_compression == SPICE_IMAGE_COMPRESS_AUTO_LZ) ||
(image_compression == SPICE_IMAGE_COMPRESS_AUTO_GLZ)) {
if ((src->x < MIN_DIMENSION_TO_QUIC) || (src->y < MIN_DIMENSION_TO_QUIC)) {
quic_compress = FALSE;
} else {
if (drawable->copy_bitmap_graduality == BITMAP_GRADUAL_INVALID) {
quic_compress = BITMAP_FMT_HAS_GRADUALITY(src->format) &&
(_get_bitmap_graduality_level(display_channel->common.worker, src,
drawable->group_id) ==
BITMAP_GRADUAL_HIGH);
} else {
quic_compress = (drawable->copy_bitmap_graduality == BITMAP_GRADUAL_HIGH);
}
}
} else {
quic_compress = FALSE;
}
}
}
if (quic_compress) {
#ifdef COMPRESS_DEBUG
spice_info("QUIC compress");
#endif
// if bitmaps is picture-like, compress it using jpeg
if (can_lossy && display_channel->enable_jpeg &&
((image_compression == SPICE_IMAGE_COMPRESS_AUTO_LZ) ||
(image_compression == SPICE_IMAGE_COMPRESS_AUTO_GLZ))) {
// if we use lz for alpha, the stride can't be extra
if (src->format != SPICE_BITMAP_FMT_RGBA || !_stride_is_extra(src)) {
return red_jpeg_compress_image(dcc, dest,
src, o_comp_data, drawable->group_id);
}
}
return red_quic_compress_image(dcc, dest,
src, o_comp_data, drawable->group_id);
} else {
int glz;
int ret;
if ((image_compression == SPICE_IMAGE_COMPRESS_AUTO_GLZ) ||
(image_compression == SPICE_IMAGE_COMPRESS_GLZ)) {
glz = BITMAP_FMT_HAS_GRADUALITY(src->format) && (
(src->x * src->y) < glz_enc_dictionary_get_size(
dcc->glz_dict->dict));
} else if ((image_compression == SPICE_IMAGE_COMPRESS_AUTO_LZ) ||
(image_compression == SPICE_IMAGE_COMPRESS_LZ)) {
glz = FALSE;
} else {
spice_error("invalid image compression type %u", image_compression);
return FALSE;
}
if (glz) {
/* using the global dictionary only if it is not frozen */
pthread_rwlock_rdlock(&dcc->glz_dict->encode_lock);
if (!dcc->glz_dict->migrate_freeze) {
ret = red_glz_compress_image(dcc,
dest, src,
drawable, o_comp_data);
} else {
glz = FALSE;
}
pthread_rwlock_unlock(&dcc->glz_dict->encode_lock);
}
if (!glz) {
ret = red_lz_compress_image(dcc, dest, src, o_comp_data,
drawable->group_id);
#ifdef COMPRESS_DEBUG
spice_info("LZ LOCAL compress");
#endif
}
#ifdef COMPRESS_DEBUG
else {
spice_info("LZ global compress fmt=%d", src->format);
}
#endif
return ret;
}
}
static inline void red_display_add_image_to_pixmap_cache(RedChannelClient *rcc,
SpiceImage *image, SpiceImage *io_image,
int is_lossy)
{
DisplayChannel *display_channel = SPICE_CONTAINEROF(rcc->channel, DisplayChannel, common.base);
DisplayChannelClient *dcc = RCC_TO_DCC(rcc);
if ((image->descriptor.flags & SPICE_IMAGE_FLAGS_CACHE_ME)) {
spice_assert(image->descriptor.width * image->descriptor.height > 0);
if (!(io_image->descriptor.flags & SPICE_IMAGE_FLAGS_CACHE_REPLACE_ME)) {
if (pixmap_cache_add(dcc->pixmap_cache, image->descriptor.id,
image->descriptor.width * image->descriptor.height, is_lossy,
dcc)) {
io_image->descriptor.flags |= SPICE_IMAGE_FLAGS_CACHE_ME;
dcc->send_data.pixmap_cache_items[dcc->send_data.num_pixmap_cache_items++] =
image->descriptor.id;
stat_inc_counter(display_channel->add_to_cache_counter, 1);
}
}
}
if (!(io_image->descriptor.flags & SPICE_IMAGE_FLAGS_CACHE_ME)) {
stat_inc_counter(display_channel->non_cache_counter, 1);
}
}
typedef enum {
FILL_BITS_TYPE_INVALID,
FILL_BITS_TYPE_CACHE,
FILL_BITS_TYPE_SURFACE,
FILL_BITS_TYPE_COMPRESS_LOSSLESS,
FILL_BITS_TYPE_COMPRESS_LOSSY,
FILL_BITS_TYPE_BITMAP,
} FillBitsType;
/* if the number of times fill_bits can be called per one qxl_drawable increases -
MAX_LZ_DRAWABLE_INSTANCES must be increased as well */
static FillBitsType fill_bits(DisplayChannelClient *dcc, SpiceMarshaller *m,
SpiceImage *simage, Drawable *drawable, int can_lossy)
{
RedChannelClient *rcc = &dcc->common.base;
DisplayChannel *display_channel = SPICE_CONTAINEROF(rcc->channel, DisplayChannel, common.base);
RedWorker *worker = dcc->common.worker;
SpiceImage image;
compress_send_data_t comp_send_data = {0};
SpiceMarshaller *bitmap_palette_out, *lzplt_palette_out;
if (simage == NULL) {
spice_assert(drawable->red_drawable->self_bitmap_image);
simage = drawable->red_drawable->self_bitmap_image;
}
image.descriptor = simage->descriptor;
image.descriptor.flags = 0;
if (simage->descriptor.flags & SPICE_IMAGE_FLAGS_HIGH_BITS_SET) {
image.descriptor.flags = SPICE_IMAGE_FLAGS_HIGH_BITS_SET;
}
if ((simage->descriptor.flags & SPICE_IMAGE_FLAGS_CACHE_ME)) {
int lossy_cache_item;
if (pixmap_cache_hit(dcc->pixmap_cache, image.descriptor.id,
&lossy_cache_item, dcc)) {
dcc->send_data.pixmap_cache_items[dcc->send_data.num_pixmap_cache_items++] =
image.descriptor.id;
if (can_lossy || !lossy_cache_item) {
if (!display_channel->enable_jpeg || lossy_cache_item) {
image.descriptor.type = SPICE_IMAGE_TYPE_FROM_CACHE;
} else {
// making sure, in multiple monitor scenario, that lossy items that
// should have been replaced with lossless data by one display channel,
// will be retrieved as lossless by another display channel.
image.descriptor.type = SPICE_IMAGE_TYPE_FROM_CACHE_LOSSLESS;
}
spice_marshall_Image(m, &image,
&bitmap_palette_out, &lzplt_palette_out);
spice_assert(bitmap_palette_out == NULL);
spice_assert(lzplt_palette_out == NULL);
stat_inc_counter(display_channel->cache_hits_counter, 1);
return FILL_BITS_TYPE_CACHE;
} else {
pixmap_cache_set_lossy(dcc->pixmap_cache, simage->descriptor.id,
FALSE);
image.descriptor.flags |= SPICE_IMAGE_FLAGS_CACHE_REPLACE_ME;
}
}
}
switch (simage->descriptor.type) {
case SPICE_IMAGE_TYPE_SURFACE: {
int surface_id;
RedSurface *surface;
surface_id = simage->u.surface.surface_id;
if (!validate_surface(worker, surface_id)) {
rendering_incorrect("SPICE_IMAGE_TYPE_SURFACE");
return FILL_BITS_TYPE_SURFACE;
}
surface = &worker->surfaces[surface_id];
image.descriptor.type = SPICE_IMAGE_TYPE_SURFACE;
image.descriptor.flags = 0;
image.descriptor.width = surface->context.width;
image.descriptor.height = surface->context.height;
image.u.surface.surface_id = surface_id;
spice_marshall_Image(m, &image,
&bitmap_palette_out, &lzplt_palette_out);
spice_assert(bitmap_palette_out == NULL);
spice_assert(lzplt_palette_out == NULL);
return FILL_BITS_TYPE_SURFACE;
}
case SPICE_IMAGE_TYPE_BITMAP: {
SpiceBitmap *bitmap = &image.u.bitmap;
#ifdef DUMP_BITMAP
dump_bitmap(display_channel->common.worker, &simage->u.bitmap, drawable->group_id);
#endif
/* Images must be added to the cache only after they are compressed
in order to prevent starvation in the client between pixmap_cache and
global dictionary (in cases of multiple monitors) */
if (!red_compress_image(dcc, &image, &simage->u.bitmap,
drawable, can_lossy, &comp_send_data)) {
SpicePalette *palette;
red_display_add_image_to_pixmap_cache(rcc, simage, &image, FALSE);
*bitmap = simage->u.bitmap;
bitmap->flags = bitmap->flags & SPICE_BITMAP_FLAGS_TOP_DOWN;
palette = bitmap->palette;
fill_palette(dcc, palette, &bitmap->flags);
spice_marshall_Image(m, &image,
&bitmap_palette_out, &lzplt_palette_out);
spice_assert(lzplt_palette_out == NULL);
if (bitmap_palette_out && palette) {
spice_marshall_Palette(bitmap_palette_out, palette);
}
spice_marshaller_add_ref_chunks(m, bitmap->data);
return FILL_BITS_TYPE_BITMAP;
} else {
red_display_add_image_to_pixmap_cache(rcc, simage, &image,
comp_send_data.is_lossy);
spice_marshall_Image(m, &image,
&bitmap_palette_out, &lzplt_palette_out);
spice_assert(bitmap_palette_out == NULL);
marshaller_add_compressed(m, comp_send_data.comp_buf,
comp_send_data.comp_buf_size);
if (lzplt_palette_out && comp_send_data.lzplt_palette) {
spice_marshall_Palette(lzplt_palette_out, comp_send_data.lzplt_palette);
}
spice_assert(!comp_send_data.is_lossy || can_lossy);
return (comp_send_data.is_lossy ? FILL_BITS_TYPE_COMPRESS_LOSSY :
FILL_BITS_TYPE_COMPRESS_LOSSLESS);
}
break;
}
case SPICE_IMAGE_TYPE_QUIC:
red_display_add_image_to_pixmap_cache(rcc, simage, &image, FALSE);
image.u.quic = simage->u.quic;
spice_marshall_Image(m, &image,
&bitmap_palette_out, &lzplt_palette_out);
spice_assert(bitmap_palette_out == NULL);
spice_assert(lzplt_palette_out == NULL);
spice_marshaller_add_ref_chunks(m, image.u.quic.data);
return FILL_BITS_TYPE_COMPRESS_LOSSLESS;
default:
spice_error("invalid image type %u", image.descriptor.type);
}
return 0;
}
static void fill_mask(RedChannelClient *rcc, SpiceMarshaller *m,
SpiceImage *mask_bitmap, Drawable *drawable)
{
DisplayChannel *display_channel = SPICE_CONTAINEROF(rcc->channel, DisplayChannel, common.base);
DisplayChannelClient *dcc = RCC_TO_DCC(rcc);
if (mask_bitmap && m) {
if (display_channel->common.worker->image_compression != SPICE_IMAGE_COMPRESS_OFF) {
spice_image_compression_t save_img_comp =
display_channel->common.worker->image_compression;
display_channel->common.worker->image_compression = SPICE_IMAGE_COMPRESS_OFF;
fill_bits(dcc, m, mask_bitmap, drawable, FALSE);
display_channel->common.worker->image_compression = save_img_comp;
} else {
fill_bits(dcc, m, mask_bitmap, drawable, FALSE);
}
}
}
static void fill_attr(SpiceMarshaller *m, SpiceLineAttr *attr, uint32_t group_id)
{
int i;
if (m && attr->style_nseg) {
for (i = 0 ; i < attr->style_nseg; i++) {
spice_marshaller_add_uint32(m, attr->style[i]);
}
}
}
static void fill_cursor(CursorChannelClient *ccc, SpiceCursor *red_cursor,
CursorItem *cursor, AddBufInfo *addbuf)
{
RedCursorCmd *cursor_cmd;
addbuf->data = NULL;
if (!cursor) {
red_cursor->flags = SPICE_CURSOR_FLAGS_NONE;
return;
}
cursor_cmd = cursor->red_cursor;
*red_cursor = cursor_cmd->u.set.shape;
if (red_cursor->header.unique) {
if (red_cursor_cache_find(ccc, red_cursor->header.unique)) {
red_cursor->flags |= SPICE_CURSOR_FLAGS_FROM_CACHE;
return;
}
if (red_cursor_cache_add(ccc, red_cursor->header.unique, 1)) {
red_cursor->flags |= SPICE_CURSOR_FLAGS_CACHE_ME;
}
}
if (red_cursor->data_size) {
addbuf->type = BUF_TYPE_RAW;
addbuf->data = red_cursor->data;
addbuf->size = red_cursor->data_size;
}
}
static inline void red_display_reset_send_data(DisplayChannelClient *dcc)
{
red_display_reset_compress_buf(dcc);
dcc->send_data.free_list.res->count = 0;
dcc->send_data.num_pixmap_cache_items = 0;
memset(dcc->send_data.free_list.sync, 0, sizeof(dcc->send_data.free_list.sync));
}
/* set area=NULL for testing the whole surface */
static int is_surface_area_lossy(DisplayChannelClient *dcc, uint32_t surface_id,
const SpiceRect *area, SpiceRect *out_lossy_area)
{
RedSurface *surface;
QRegion *surface_lossy_region;
QRegion lossy_region;
RedWorker *worker = dcc->common.worker;
VALIDATE_SURFACE_RETVAL(worker, surface_id, FALSE);
surface = &worker->surfaces[surface_id];
surface_lossy_region = &dcc->surface_client_lossy_region[surface_id];
if (!area) {
if (region_is_empty(surface_lossy_region)) {
return FALSE;
} else {
out_lossy_area->top = 0;
out_lossy_area->left = 0;
out_lossy_area->bottom = surface->context.height;
out_lossy_area->right = surface->context.width;
return TRUE;
}
}
region_init(&lossy_region);
region_add(&lossy_region, area);
region_and(&lossy_region, surface_lossy_region);
if (!region_is_empty(&lossy_region)) {
out_lossy_area->left = lossy_region.extents.x1;
out_lossy_area->top = lossy_region.extents.y1;
out_lossy_area->right = lossy_region.extents.x2;
out_lossy_area->bottom = lossy_region.extents.y2;
region_destroy(&lossy_region);
return TRUE;
} else {
return FALSE;
}
}
/* returns if the bitmap was already sent lossy to the client. If the bitmap hasn't been sent yet
to the client, returns false. "area" is for surfaces. If area = NULL,
all the surface is considered. out_lossy_data will hold info about the bitmap, and its lossy
area in case it is lossy and part of a surface. */
static int is_bitmap_lossy(RedChannelClient *rcc, SpiceImage *image, SpiceRect *area,
Drawable *drawable, BitmapData *out_data)
{
DisplayChannelClient *dcc = RCC_TO_DCC(rcc);
if (image == NULL) {
// self bitmap
out_data->type = BITMAP_DATA_TYPE_BITMAP;
return FALSE;
}
if ((image->descriptor.flags & SPICE_IMAGE_FLAGS_CACHE_ME)) {
int is_hit_lossy;
out_data->id = image->descriptor.id;
if (pixmap_cache_hit(dcc->pixmap_cache, image->descriptor.id,
&is_hit_lossy, dcc)) {
out_data->type = BITMAP_DATA_TYPE_CACHE;
if (is_hit_lossy) {
return TRUE;
} else {
return FALSE;
}
} else {
out_data->type = BITMAP_DATA_TYPE_BITMAP_TO_CACHE;
}
} else {
out_data->type = BITMAP_DATA_TYPE_BITMAP;
}
if (image->descriptor.type != SPICE_IMAGE_TYPE_SURFACE) {
return FALSE;
}
out_data->type = BITMAP_DATA_TYPE_SURFACE;
out_data->id = image->u.surface.surface_id;
if (is_surface_area_lossy(dcc, out_data->id,
area, &out_data->lossy_rect))
{
return TRUE;
} else {
return FALSE;
}
}
static int is_brush_lossy(RedChannelClient *rcc, SpiceBrush *brush,
Drawable *drawable, BitmapData *out_data)
{
if (brush->type == SPICE_BRUSH_TYPE_PATTERN) {
return is_bitmap_lossy(rcc, brush->u.pattern.pat, NULL,
drawable, out_data);
} else {
out_data->type = BITMAP_DATA_TYPE_INVALID;
return FALSE;
}
}
static void surface_lossy_region_update(RedWorker *worker, DisplayChannelClient *dcc,
Drawable *item, int has_mask, int lossy)
{
QRegion *surface_lossy_region;
RedDrawable *drawable;
if (has_mask && !lossy) {
return;
}
surface_lossy_region = &dcc->surface_client_lossy_region[item->surface_id];
drawable = item->red_drawable;
if (drawable->clip.type == SPICE_CLIP_TYPE_RECTS ) {
QRegion clip_rgn;
QRegion draw_region;
region_init(&clip_rgn);
region_init(&draw_region);
region_add(&draw_region, &drawable->bbox);
add_clip_rects(&clip_rgn, drawable->clip.rects);
region_and(&draw_region, &clip_rgn);
if (lossy) {
region_or(surface_lossy_region, &draw_region);
} else {
region_exclude(surface_lossy_region, &draw_region);
}
region_destroy(&clip_rgn);
region_destroy(&draw_region);
} else { /* no clip */
if (!lossy) {
region_remove(surface_lossy_region, &drawable->bbox);
} else {
region_add(surface_lossy_region, &drawable->bbox);
}
}
}
static inline int drawable_intersects_with_areas(Drawable *drawable, int surface_ids[],
SpiceRect *surface_areas[],
int num_surfaces)
{
int i;
for (i = 0; i < num_surfaces; i++) {
if (surface_ids[i] == drawable->red_drawable->surface_id) {
if (rect_intersects(surface_areas[i], &drawable->red_drawable->bbox)) {
return TRUE;
}
}
}
return FALSE;
}
static inline int drawable_depends_on_areas(Drawable *drawable,
int surface_ids[],
SpiceRect surface_areas[],
int num_surfaces)
{
int i;
RedDrawable *red_drawable;
int drawable_has_shadow;
SpiceRect shadow_rect = {0, 0, 0, 0};
red_drawable = drawable->red_drawable;
drawable_has_shadow = has_shadow(red_drawable);
if (drawable_has_shadow) {
int delta_x = red_drawable->u.copy_bits.src_pos.x - red_drawable->bbox.left;
int delta_y = red_drawable->u.copy_bits.src_pos.y - red_drawable->bbox.top;
shadow_rect.left = red_drawable->u.copy_bits.src_pos.x;
shadow_rect.top = red_drawable->u.copy_bits.src_pos.y;
shadow_rect.right = red_drawable->bbox.right + delta_x;
shadow_rect.bottom = red_drawable->bbox.bottom + delta_y;
}
for (i = 0; i < num_surfaces; i++) {
int x;
int dep_surface_id;
for (x = 0; x < 3; ++x) {
dep_surface_id = drawable->surfaces_dest[x];
if (dep_surface_id == surface_ids[i]) {
if (rect_intersects(&surface_areas[i], &red_drawable->surfaces_rects[x])) {
return TRUE;
}
}
}
if (surface_ids[i] == red_drawable->surface_id) {
if (drawable_has_shadow) {
if (rect_intersects(&surface_areas[i], &shadow_rect)) {
return TRUE;
}
}
// not dependent on dest
if (red_drawable->effect == QXL_EFFECT_OPAQUE) {
continue;
}
if (rect_intersects(&surface_areas[i], &red_drawable->bbox)) {
return TRUE;
}
}
}
return FALSE;
}
static int pipe_rendered_drawables_intersect_with_areas(RedWorker *worker,
DisplayChannelClient *dcc,
int surface_ids[],
SpiceRect *surface_areas[],
int num_surfaces)
{
PipeItem *pipe_item;
Ring *pipe;
spice_assert(num_surfaces);
pipe = &dcc->common.base.pipe;
for (pipe_item = (PipeItem *)ring_get_head(pipe);
pipe_item;
pipe_item = (PipeItem *)ring_next(pipe, &pipe_item->link))
{
Drawable *drawable;
if (pipe_item->type != PIPE_ITEM_TYPE_DRAW)
continue;
drawable = SPICE_CONTAINEROF(pipe_item, DrawablePipeItem, dpi_pipe_item)->drawable;
if (ring_item_is_linked(&drawable->list_link))
continue; // item hasn't been rendered
if (drawable_intersects_with_areas(drawable, surface_ids, surface_areas, num_surfaces)) {
return TRUE;
}
}
return FALSE;
}
static void red_pipe_replace_rendered_drawables_with_images(RedWorker *worker,
DisplayChannelClient *dcc,
int first_surface_id,
SpiceRect *first_area)
{
/* TODO: can't have those statics with multiple clients */
static int resent_surface_ids[MAX_PIPE_SIZE];
static SpiceRect resent_areas[MAX_PIPE_SIZE]; // not pointers since drawbales may be released
int num_resent;
PipeItem *pipe_item;
Ring *pipe;
resent_surface_ids[0] = first_surface_id;
resent_areas[0] = *first_area;
num_resent = 1;
pipe = &dcc->common.base.pipe;
// going from the oldest to the newest
for (pipe_item = (PipeItem *)ring_get_tail(pipe);
pipe_item;
pipe_item = (PipeItem *)ring_prev(pipe, &pipe_item->link)) {
Drawable *drawable;
DrawablePipeItem *dpi;
ImageItem *image;
if (pipe_item->type != PIPE_ITEM_TYPE_DRAW)
continue;
dpi = SPICE_CONTAINEROF(pipe_item, DrawablePipeItem, dpi_pipe_item);
drawable = dpi->drawable;
if (ring_item_is_linked(&drawable->list_link))
continue; // item hasn't been rendered
// When a drawable command, X, depends on bitmaps that were resent,
// these bitmaps state at the client might not be synchronized with X
// (i.e., the bitmaps can be more futuristic w.r.t X). Thus, X shouldn't
// be rendered at the client, and we replace it with an image as well.
if (!drawable_depends_on_areas(drawable,
resent_surface_ids,
resent_areas,
num_resent)) {
continue;
}
image = red_add_surface_area_image(dcc, drawable->red_drawable->surface_id,
&drawable->red_drawable->bbox, pipe_item, TRUE);
resent_surface_ids[num_resent] = drawable->red_drawable->surface_id;
resent_areas[num_resent] = drawable->red_drawable->bbox;
num_resent++;
spice_assert(image);
red_channel_client_pipe_remove_and_release(&dcc->common.base, &dpi->dpi_pipe_item);
pipe_item = &image->link;
}
}
static void red_add_lossless_drawable_dependencies(RedWorker *worker,
RedChannelClient *rcc,
Drawable *item,
int deps_surfaces_ids[],
SpiceRect *deps_areas[],
int num_deps)
{
RedDrawable *drawable = item->red_drawable;
DisplayChannelClient *dcc = RCC_TO_DCC(rcc);
int sync_rendered = FALSE;
int i;
if (!ring_item_is_linked(&item->list_link)) {
/* drawable was already rendered, we may not be able to retrieve the lossless data
for the lossy areas */
sync_rendered = TRUE;
// checking if the drawable itself or one of the other commands
// that were rendered, affected the areas that need to be resent
if (!drawable_intersects_with_areas(item, deps_surfaces_ids,
deps_areas, num_deps)) {
if (pipe_rendered_drawables_intersect_with_areas(worker, dcc,
deps_surfaces_ids,
deps_areas,
num_deps)) {
sync_rendered = TRUE;
}
} else {
sync_rendered = TRUE;
}
} else {
sync_rendered = FALSE;
for (i = 0; i < num_deps; i++) {
red_update_area_till(worker, deps_areas[i],
deps_surfaces_ids[i], item);
}
}
if (!sync_rendered) {
// pushing the pipe item back to the pipe
red_pipe_add_drawable_to_tail(dcc, item);
// the surfaces areas will be sent as DRAW_COPY commands, that
// will be executed before the current drawable
for (i = 0; i < num_deps; i++) {
red_add_surface_area_image(dcc, deps_surfaces_ids[i], deps_areas[i],
red_pipe_get_tail(dcc), FALSE);
}
} else {
int drawable_surface_id[1];
SpiceRect *drawable_bbox[1];
drawable_surface_id[0] = drawable->surface_id;
drawable_bbox[0] = &drawable->bbox;
// check if the other rendered images in the pipe have updated the drawable bbox
if (pipe_rendered_drawables_intersect_with_areas(worker, dcc,
drawable_surface_id,
drawable_bbox,
1)) {
red_pipe_replace_rendered_drawables_with_images(worker, dcc,
drawable->surface_id,
&drawable->bbox);
}
red_add_surface_area_image(dcc, drawable->surface_id, &drawable->bbox,
red_pipe_get_tail(dcc), TRUE);
}
}
static void red_marshall_qxl_draw_fill(RedWorker *worker,
RedChannelClient *rcc,
SpiceMarshaller *base_marshaller,
DrawablePipeItem *dpi)
{
Drawable *item = dpi->drawable;
RedDrawable *drawable = item->red_drawable;
DisplayChannelClient *dcc = RCC_TO_DCC(rcc);
SpiceMarshaller *brush_pat_out;
SpiceMarshaller *mask_bitmap_out;
SpiceFill fill;
red_channel_client_init_send_data(rcc, SPICE_MSG_DISPLAY_DRAW_FILL, &dpi->dpi_pipe_item);
fill_base(base_marshaller, item);
fill = drawable->u.fill;
spice_marshall_Fill(base_marshaller,
&fill,
&brush_pat_out,
&mask_bitmap_out);
if (brush_pat_out) {
fill_bits(dcc, brush_pat_out, fill.brush.u.pattern.pat, item, FALSE);
}
fill_mask(rcc, mask_bitmap_out, fill.mask.bitmap, item);
}
static void red_lossy_marshall_qxl_draw_fill(RedWorker *worker,
RedChannelClient *rcc,
SpiceMarshaller *m,
DrawablePipeItem *dpi)
{
Drawable *item = dpi->drawable;
DisplayChannelClient *dcc = RCC_TO_DCC(rcc);
RedDrawable *drawable = item->red_drawable;
int dest_allowed_lossy = FALSE;
int dest_is_lossy = FALSE;
SpiceRect dest_lossy_area;
int brush_is_lossy;
BitmapData brush_bitmap_data;
uint16_t rop;
rop = drawable->u.fill.rop_descriptor;
dest_allowed_lossy = !((rop & SPICE_ROPD_OP_OR) ||
(rop & SPICE_ROPD_OP_AND) ||
(rop & SPICE_ROPD_OP_XOR));
brush_is_lossy = is_brush_lossy(rcc, &drawable->u.fill.brush, item,
&brush_bitmap_data);
if (!dest_allowed_lossy) {
dest_is_lossy = is_surface_area_lossy(dcc, item->surface_id, &drawable->bbox,
&dest_lossy_area);
}
if (!dest_is_lossy &&
!(brush_is_lossy && (brush_bitmap_data.type == BITMAP_DATA_TYPE_SURFACE))) {
int has_mask = !!drawable->u.fill.mask.bitmap;
red_marshall_qxl_draw_fill(worker, rcc, m, dpi);
// either the brush operation is opaque, or the dest is not lossy
surface_lossy_region_update(worker, dcc, item, has_mask, FALSE);
} else {
int resend_surface_ids[2];
SpiceRect *resend_areas[2];
int num_resend = 0;
if (dest_is_lossy) {
resend_surface_ids[num_resend] = item->surface_id;
resend_areas[num_resend] = &dest_lossy_area;
num_resend++;
}
if (brush_is_lossy && (brush_bitmap_data.type == BITMAP_DATA_TYPE_SURFACE)) {
resend_surface_ids[num_resend] = brush_bitmap_data.id;
resend_areas[num_resend] = &brush_bitmap_data.lossy_rect;
num_resend++;
}
red_add_lossless_drawable_dependencies(worker, rcc, item,
resend_surface_ids, resend_areas, num_resend);
}
}
static FillBitsType red_marshall_qxl_draw_opaque(RedWorker *worker,
RedChannelClient *rcc,
SpiceMarshaller *base_marshaller,
DrawablePipeItem *dpi, int src_allowed_lossy)
{
Drawable *item = dpi->drawable;
DisplayChannelClient *dcc = RCC_TO_DCC(rcc);
RedDrawable *drawable = item->red_drawable;
SpiceMarshaller *brush_pat_out;
SpiceMarshaller *src_bitmap_out;
SpiceMarshaller *mask_bitmap_out;
SpiceOpaque opaque;
FillBitsType src_send_type;
red_channel_client_init_send_data(rcc, SPICE_MSG_DISPLAY_DRAW_OPAQUE, &dpi->dpi_pipe_item);
fill_base(base_marshaller, item);
opaque = drawable->u.opaque;
spice_marshall_Opaque(base_marshaller,
&opaque,
&src_bitmap_out,
&brush_pat_out,
&mask_bitmap_out);
src_send_type = fill_bits(dcc, src_bitmap_out, opaque.src_bitmap, item,
src_allowed_lossy);
if (brush_pat_out) {
fill_bits(dcc, brush_pat_out, opaque.brush.u.pattern.pat, item, FALSE);
}
fill_mask(rcc, mask_bitmap_out, opaque.mask.bitmap, item);
return src_send_type;
}
static void red_lossy_marshall_qxl_draw_opaque(RedWorker *worker,
RedChannelClient *rcc,
SpiceMarshaller *m,
DrawablePipeItem *dpi)
{
Drawable *item = dpi->drawable;
DisplayChannelClient *dcc = RCC_TO_DCC(rcc);
RedDrawable *drawable = item->red_drawable;
int src_allowed_lossy;
int rop;
int src_is_lossy = FALSE;
int brush_is_lossy = FALSE;
BitmapData src_bitmap_data;
BitmapData brush_bitmap_data;
rop = drawable->u.opaque.rop_descriptor;
src_allowed_lossy = !((rop & SPICE_ROPD_OP_OR) ||
(rop & SPICE_ROPD_OP_AND) ||
(rop & SPICE_ROPD_OP_XOR));
brush_is_lossy = is_brush_lossy(rcc, &drawable->u.opaque.brush, item,
&brush_bitmap_data);
if (!src_allowed_lossy) {
src_is_lossy = is_bitmap_lossy(rcc, drawable->u.opaque.src_bitmap,
&drawable->u.opaque.src_area,
item,
&src_bitmap_data);
}
if (!(brush_is_lossy && (brush_bitmap_data.type == BITMAP_DATA_TYPE_SURFACE)) &&
!(src_is_lossy && (src_bitmap_data.type == BITMAP_DATA_TYPE_SURFACE))) {
FillBitsType src_send_type;
int has_mask = !!drawable->u.opaque.mask.bitmap;
src_send_type = red_marshall_qxl_draw_opaque(worker, rcc, m, dpi, src_allowed_lossy);
if (src_send_type == FILL_BITS_TYPE_COMPRESS_LOSSY) {
src_is_lossy = TRUE;
} else if (src_send_type == FILL_BITS_TYPE_COMPRESS_LOSSLESS) {
src_is_lossy = FALSE;
}
surface_lossy_region_update(worker, dcc, item, has_mask, src_is_lossy);
} else {
int resend_surface_ids[2];
SpiceRect *resend_areas[2];
int num_resend = 0;
if (src_is_lossy && (src_bitmap_data.type == BITMAP_DATA_TYPE_SURFACE)) {
resend_surface_ids[num_resend] = src_bitmap_data.id;
resend_areas[num_resend] = &src_bitmap_data.lossy_rect;
num_resend++;
}
if (brush_is_lossy && (brush_bitmap_data.type == BITMAP_DATA_TYPE_SURFACE)) {
resend_surface_ids[num_resend] = brush_bitmap_data.id;
resend_areas[num_resend] = &brush_bitmap_data.lossy_rect;
num_resend++;
}
red_add_lossless_drawable_dependencies(worker, rcc, item,
resend_surface_ids, resend_areas, num_resend);
}
}
static FillBitsType red_marshall_qxl_draw_copy(RedWorker *worker,
RedChannelClient *rcc,
SpiceMarshaller *base_marshaller,
DrawablePipeItem *dpi, int src_allowed_lossy)
{
Drawable *item = dpi->drawable;
RedDrawable *drawable = item->red_drawable;
DisplayChannelClient *dcc = RCC_TO_DCC(rcc);
SpiceMarshaller *src_bitmap_out;
SpiceMarshaller *mask_bitmap_out;
SpiceCopy copy;
FillBitsType src_send_type;
red_channel_client_init_send_data(rcc, SPICE_MSG_DISPLAY_DRAW_COPY, &dpi->dpi_pipe_item);
fill_base(base_marshaller, item);
copy = drawable->u.copy;
spice_marshall_Copy(base_marshaller,
©,
&src_bitmap_out,
&mask_bitmap_out);
src_send_type = fill_bits(dcc, src_bitmap_out, copy.src_bitmap, item, src_allowed_lossy);
fill_mask(rcc, mask_bitmap_out, copy.mask.bitmap, item);
return src_send_type;
}
static void red_lossy_marshall_qxl_draw_copy(RedWorker *worker,
RedChannelClient *rcc,
SpiceMarshaller *base_marshaller,
DrawablePipeItem *dpi)
{
Drawable *item = dpi->drawable;
DisplayChannelClient *dcc = RCC_TO_DCC(rcc);
RedDrawable *drawable = item->red_drawable;
int has_mask = !!drawable->u.copy.mask.bitmap;
int src_is_lossy;
BitmapData src_bitmap_data;
FillBitsType src_send_type;
src_is_lossy = is_bitmap_lossy(rcc, drawable->u.copy.src_bitmap,
&drawable->u.copy.src_area, item, &src_bitmap_data);
src_send_type = red_marshall_qxl_draw_copy(worker, rcc, base_marshaller, dpi, TRUE);
if (src_send_type == FILL_BITS_TYPE_COMPRESS_LOSSY) {
src_is_lossy = TRUE;
} else if (src_send_type == FILL_BITS_TYPE_COMPRESS_LOSSLESS) {
src_is_lossy = FALSE;
}
surface_lossy_region_update(worker, dcc, item, has_mask,
src_is_lossy);
}
static void red_marshall_qxl_draw_transparent(RedWorker *worker,
RedChannelClient *rcc,
SpiceMarshaller *base_marshaller,
DrawablePipeItem *dpi)
{
Drawable *item = dpi->drawable;
DisplayChannelClient *dcc = RCC_TO_DCC(rcc);
RedDrawable *drawable = item->red_drawable;
SpiceMarshaller *src_bitmap_out;
SpiceTransparent transparent;
red_channel_client_init_send_data(rcc, SPICE_MSG_DISPLAY_DRAW_TRANSPARENT,
&dpi->dpi_pipe_item);
fill_base(base_marshaller, item);
transparent = drawable->u.transparent;
spice_marshall_Transparent(base_marshaller,
&transparent,
&src_bitmap_out);
fill_bits(dcc, src_bitmap_out, transparent.src_bitmap, item, FALSE);
}
static void red_lossy_marshall_qxl_draw_transparent(RedWorker *worker,
RedChannelClient *rcc,
SpiceMarshaller *base_marshaller,
DrawablePipeItem *dpi)
{
Drawable *item = dpi->drawable;
RedDrawable *drawable = item->red_drawable;
int src_is_lossy;
BitmapData src_bitmap_data;
src_is_lossy = is_bitmap_lossy(rcc, drawable->u.transparent.src_bitmap,
&drawable->u.transparent.src_area, item, &src_bitmap_data);
if (!src_is_lossy || (src_bitmap_data.type != BITMAP_DATA_TYPE_SURFACE)) {
red_marshall_qxl_draw_transparent(worker, rcc, base_marshaller, dpi);
// don't update surface lossy region since transperent areas might be lossy
} else {
int resend_surface_ids[1];
SpiceRect *resend_areas[1];
resend_surface_ids[0] = src_bitmap_data.id;
resend_areas[0] = &src_bitmap_data.lossy_rect;
red_add_lossless_drawable_dependencies(worker, rcc, item,
resend_surface_ids, resend_areas, 1);
}
}
static FillBitsType red_marshall_qxl_draw_alpha_blend(RedWorker *worker,
RedChannelClient *rcc,
SpiceMarshaller *base_marshaller,
DrawablePipeItem *dpi,
int src_allowed_lossy)
{
Drawable *item = dpi->drawable;
DisplayChannelClient *dcc = RCC_TO_DCC(rcc);
RedDrawable *drawable = item->red_drawable;
SpiceMarshaller *src_bitmap_out;
SpiceAlphaBlend alpha_blend;
FillBitsType src_send_type;
red_channel_client_init_send_data(rcc, SPICE_MSG_DISPLAY_DRAW_ALPHA_BLEND,
&dpi->dpi_pipe_item);
fill_base(base_marshaller, item);
alpha_blend = drawable->u.alpha_blend;
spice_marshall_AlphaBlend(base_marshaller,
&alpha_blend,
&src_bitmap_out);
src_send_type = fill_bits(dcc, src_bitmap_out, alpha_blend.src_bitmap, item,
src_allowed_lossy);
return src_send_type;
}
static void red_lossy_marshall_qxl_draw_alpha_blend(RedWorker *worker,
RedChannelClient *rcc,
SpiceMarshaller *base_marshaller,
DrawablePipeItem *dpi)
{
Drawable *item = dpi->drawable;
DisplayChannelClient *dcc = RCC_TO_DCC(rcc);
RedDrawable *drawable = item->red_drawable;
int src_is_lossy;
BitmapData src_bitmap_data;
FillBitsType src_send_type;
src_is_lossy = is_bitmap_lossy(rcc, drawable->u.alpha_blend.src_bitmap,
&drawable->u.alpha_blend.src_area, item, &src_bitmap_data);
src_send_type = red_marshall_qxl_draw_alpha_blend(worker, rcc, base_marshaller, dpi, TRUE);
if (src_send_type == FILL_BITS_TYPE_COMPRESS_LOSSY) {
src_is_lossy = TRUE;
} else if (src_send_type == FILL_BITS_TYPE_COMPRESS_LOSSLESS) {
src_is_lossy = FALSE;
}
if (src_is_lossy) {
surface_lossy_region_update(worker, dcc, item, FALSE, src_is_lossy);
} // else, the area stays lossy/lossless as the destination
}
static void red_marshall_qxl_copy_bits(RedWorker *worker,
RedChannelClient *rcc,
SpiceMarshaller *base_marshaller,
DrawablePipeItem *dpi)
{
Drawable *item = dpi->drawable;
RedDrawable *drawable = item->red_drawable;
SpicePoint copy_bits;
red_channel_client_init_send_data(rcc, SPICE_MSG_DISPLAY_COPY_BITS, &dpi->dpi_pipe_item);
fill_base(base_marshaller, item);
copy_bits = drawable->u.copy_bits.src_pos;
spice_marshall_Point(base_marshaller,
©_bits);
}
static void red_lossy_marshall_qxl_copy_bits(RedWorker *worker,
RedChannelClient *rcc,
SpiceMarshaller *base_marshaller,
DrawablePipeItem *dpi)
{
Drawable *item = dpi->drawable;
DisplayChannelClient *dcc = RCC_TO_DCC(rcc);
RedDrawable *drawable = item->red_drawable;
SpiceRect src_rect;
int horz_offset;
int vert_offset;
int src_is_lossy;
SpiceRect src_lossy_area;
red_marshall_qxl_copy_bits(worker, rcc, base_marshaller, dpi);
horz_offset = drawable->u.copy_bits.src_pos.x - drawable->bbox.left;
vert_offset = drawable->u.copy_bits.src_pos.y - drawable->bbox.top;
src_rect.left = drawable->u.copy_bits.src_pos.x;
src_rect.top = drawable->u.copy_bits.src_pos.y;
src_rect.right = drawable->bbox.right + horz_offset;
src_rect.bottom = drawable->bbox.bottom + vert_offset;
src_is_lossy = is_surface_area_lossy(dcc, item->surface_id,
&src_rect, &src_lossy_area);
surface_lossy_region_update(worker, dcc, item, FALSE,
src_is_lossy);
}
static void red_marshall_qxl_draw_blend(RedWorker *worker,
RedChannelClient *rcc,
SpiceMarshaller *base_marshaller,
DrawablePipeItem *dpi)
{
Drawable *item = dpi->drawable;
DisplayChannelClient *dcc = RCC_TO_DCC(rcc);
RedDrawable *drawable = item->red_drawable;
SpiceMarshaller *src_bitmap_out;
SpiceMarshaller *mask_bitmap_out;
SpiceBlend blend;
red_channel_client_init_send_data(rcc, SPICE_MSG_DISPLAY_DRAW_BLEND, &dpi->dpi_pipe_item);
fill_base(base_marshaller, item);
blend = drawable->u.blend;
spice_marshall_Blend(base_marshaller,
&blend,
&src_bitmap_out,
&mask_bitmap_out);
fill_bits(dcc, src_bitmap_out, blend.src_bitmap, item, FALSE);
fill_mask(rcc, mask_bitmap_out, blend.mask.bitmap, item);
}
static void red_lossy_marshall_qxl_draw_blend(RedWorker *worker,
RedChannelClient *rcc,
SpiceMarshaller *base_marshaller,
DrawablePipeItem *dpi)
{
Drawable *item = dpi->drawable;
DisplayChannelClient *dcc = RCC_TO_DCC(rcc);
RedDrawable *drawable = item->red_drawable;
int src_is_lossy;
BitmapData src_bitmap_data;
int dest_is_lossy;
SpiceRect dest_lossy_area;
src_is_lossy = is_bitmap_lossy(rcc, drawable->u.blend.src_bitmap,
&drawable->u.blend.src_area, item, &src_bitmap_data);
dest_is_lossy = is_surface_area_lossy(dcc, drawable->surface_id,
&drawable->bbox, &dest_lossy_area);
if (!dest_is_lossy &&
(!src_is_lossy || (src_bitmap_data.type != BITMAP_DATA_TYPE_SURFACE))) {
red_marshall_qxl_draw_blend(worker, rcc, base_marshaller, dpi);
} else {
int resend_surface_ids[2];
SpiceRect *resend_areas[2];
int num_resend = 0;
if (src_is_lossy && (src_bitmap_data.type == BITMAP_DATA_TYPE_SURFACE)) {
resend_surface_ids[num_resend] = src_bitmap_data.id;
resend_areas[num_resend] = &src_bitmap_data.lossy_rect;
num_resend++;
}
if (dest_is_lossy) {
resend_surface_ids[num_resend] = item->surface_id;
resend_areas[num_resend] = &dest_lossy_area;
num_resend++;
}
red_add_lossless_drawable_dependencies(worker, rcc, item,
resend_surface_ids, resend_areas, num_resend);
}
}
static void red_marshall_qxl_draw_blackness(RedWorker *worker,
RedChannelClient *rcc,
SpiceMarshaller *base_marshaller,
DrawablePipeItem *dpi)
{
Drawable *item = dpi->drawable;
RedDrawable *drawable = item->red_drawable;
SpiceMarshaller *mask_bitmap_out;
SpiceBlackness blackness;
red_channel_client_init_send_data(rcc, SPICE_MSG_DISPLAY_DRAW_BLACKNESS, &dpi->dpi_pipe_item);
fill_base(base_marshaller, item);
blackness = drawable->u.blackness;
spice_marshall_Blackness(base_marshaller,
&blackness,
&mask_bitmap_out);
fill_mask(rcc, mask_bitmap_out, blackness.mask.bitmap, item);
}
static void red_lossy_marshall_qxl_draw_blackness(RedWorker *worker,
RedChannelClient *rcc,
SpiceMarshaller *base_marshaller,
DrawablePipeItem *dpi)
{
Drawable *item = dpi->drawable;
DisplayChannelClient *dcc = RCC_TO_DCC(rcc);
RedDrawable *drawable = item->red_drawable;
int has_mask = !!drawable->u.blackness.mask.bitmap;
red_marshall_qxl_draw_blackness(worker, rcc, base_marshaller, dpi);
surface_lossy_region_update(worker, dcc, item, has_mask, FALSE);
}
static void red_marshall_qxl_draw_whiteness(RedWorker *worker,
RedChannelClient *rcc,
SpiceMarshaller *base_marshaller,
DrawablePipeItem *dpi)
{
Drawable *item = dpi->drawable;
RedDrawable *drawable = item->red_drawable;
SpiceMarshaller *mask_bitmap_out;
SpiceWhiteness whiteness;
red_channel_client_init_send_data(rcc, SPICE_MSG_DISPLAY_DRAW_WHITENESS, &dpi->dpi_pipe_item);
fill_base(base_marshaller, item);
whiteness = drawable->u.whiteness;
spice_marshall_Whiteness(base_marshaller,
&whiteness,
&mask_bitmap_out);
fill_mask(rcc, mask_bitmap_out, whiteness.mask.bitmap, item);
}
static void red_lossy_marshall_qxl_draw_whiteness(RedWorker *worker,
RedChannelClient *rcc,
SpiceMarshaller *base_marshaller,
DrawablePipeItem *dpi)
{
Drawable *item = dpi->drawable;
DisplayChannelClient *dcc = RCC_TO_DCC(rcc);
RedDrawable *drawable = item->red_drawable;
int has_mask = !!drawable->u.whiteness.mask.bitmap;
red_marshall_qxl_draw_whiteness(worker, rcc, base_marshaller, dpi);
surface_lossy_region_update(worker, dcc, item, has_mask, FALSE);
}
static void red_marshall_qxl_draw_inverse(RedWorker *worker,
RedChannelClient *rcc,
SpiceMarshaller *base_marshaller,
Drawable *item)
{
RedDrawable *drawable = item->red_drawable;
SpiceMarshaller *mask_bitmap_out;
SpiceInvers inverse;
red_channel_client_init_send_data(rcc, SPICE_MSG_DISPLAY_DRAW_INVERS, NULL);
fill_base(base_marshaller, item);
inverse = drawable->u.invers;
spice_marshall_Invers(base_marshaller,
&inverse,
&mask_bitmap_out);
fill_mask(rcc, mask_bitmap_out, inverse.mask.bitmap, item);
}
static void red_lossy_marshall_qxl_draw_inverse(RedWorker *worker,
RedChannelClient *rcc,
SpiceMarshaller *base_marshaller,
Drawable *item)
{
red_marshall_qxl_draw_inverse(worker, rcc, base_marshaller, item);
}
static void red_marshall_qxl_draw_rop3(RedWorker *worker,
RedChannelClient *rcc,
SpiceMarshaller *base_marshaller,
DrawablePipeItem *dpi)
{
Drawable *item = dpi->drawable;
DisplayChannelClient *dcc = RCC_TO_DCC(rcc);
RedDrawable *drawable = item->red_drawable;
SpiceRop3 rop3;
SpiceMarshaller *src_bitmap_out;
SpiceMarshaller *brush_pat_out;
SpiceMarshaller *mask_bitmap_out;
red_channel_client_init_send_data(rcc, SPICE_MSG_DISPLAY_DRAW_ROP3, &dpi->dpi_pipe_item);
fill_base(base_marshaller, item);
rop3 = drawable->u.rop3;
spice_marshall_Rop3(base_marshaller,
&rop3,
&src_bitmap_out,
&brush_pat_out,
&mask_bitmap_out);
fill_bits(dcc, src_bitmap_out, rop3.src_bitmap, item, FALSE);
if (brush_pat_out) {
fill_bits(dcc, brush_pat_out, rop3.brush.u.pattern.pat, item, FALSE);
}
fill_mask(rcc, mask_bitmap_out, rop3.mask.bitmap, item);
}
static void red_lossy_marshall_qxl_draw_rop3(RedWorker *worker,
RedChannelClient *rcc,
SpiceMarshaller *base_marshaller,
DrawablePipeItem *dpi)
{
Drawable *item = dpi->drawable;
DisplayChannelClient *dcc = RCC_TO_DCC(rcc);
RedDrawable *drawable = item->red_drawable;
int src_is_lossy;
BitmapData src_bitmap_data;
int brush_is_lossy;
BitmapData brush_bitmap_data;
int dest_is_lossy;
SpiceRect dest_lossy_area;
src_is_lossy = is_bitmap_lossy(rcc, drawable->u.rop3.src_bitmap,
&drawable->u.rop3.src_area, item, &src_bitmap_data);
brush_is_lossy = is_brush_lossy(rcc, &drawable->u.rop3.brush, item,
&brush_bitmap_data);
dest_is_lossy = is_surface_area_lossy(dcc, drawable->surface_id,
&drawable->bbox, &dest_lossy_area);
if ((!src_is_lossy || (src_bitmap_data.type != BITMAP_DATA_TYPE_SURFACE)) &&
(!brush_is_lossy || (brush_bitmap_data.type != BITMAP_DATA_TYPE_SURFACE)) &&
!dest_is_lossy) {
int has_mask = !!drawable->u.rop3.mask.bitmap;
red_marshall_qxl_draw_rop3(worker, rcc, base_marshaller, dpi);
surface_lossy_region_update(worker, dcc, item, has_mask, FALSE);
} else {
int resend_surface_ids[3];
SpiceRect *resend_areas[3];
int num_resend = 0;
if (src_is_lossy && (src_bitmap_data.type == BITMAP_DATA_TYPE_SURFACE)) {
resend_surface_ids[num_resend] = src_bitmap_data.id;
resend_areas[num_resend] = &src_bitmap_data.lossy_rect;
num_resend++;
}
if (brush_is_lossy && (brush_bitmap_data.type == BITMAP_DATA_TYPE_SURFACE)) {
resend_surface_ids[num_resend] = brush_bitmap_data.id;
resend_areas[num_resend] = &brush_bitmap_data.lossy_rect;
num_resend++;
}
if (dest_is_lossy) {
resend_surface_ids[num_resend] = item->surface_id;
resend_areas[num_resend] = &dest_lossy_area;
num_resend++;
}
red_add_lossless_drawable_dependencies(worker, rcc, item,
resend_surface_ids, resend_areas, num_resend);
}
}
static void red_marshall_qxl_draw_composite(RedWorker *worker,
RedChannelClient *rcc,
SpiceMarshaller *base_marshaller,
DrawablePipeItem *dpi)
{
Drawable *item = dpi->drawable;
DisplayChannelClient *dcc = RCC_TO_DCC(rcc);
RedDrawable *drawable = item->red_drawable;
SpiceMarshaller *src_bitmap_out;
SpiceMarshaller *mask_bitmap_out;
SpiceComposite composite;
red_channel_client_init_send_data(rcc, SPICE_MSG_DISPLAY_DRAW_COMPOSITE, &dpi->dpi_pipe_item);
fill_base(base_marshaller, item);
composite = drawable->u.composite;
spice_marshall_Composite(base_marshaller,
&composite,
&src_bitmap_out,
&mask_bitmap_out);
fill_bits(dcc, src_bitmap_out, composite.src_bitmap, item, FALSE);
if (mask_bitmap_out) {
fill_bits(dcc, mask_bitmap_out, composite.mask_bitmap, item, FALSE);
}
}
static void red_lossy_marshall_qxl_draw_composite(RedWorker *worker,
RedChannelClient *rcc,
SpiceMarshaller *base_marshaller,
DrawablePipeItem *dpi)
{
Drawable *item = dpi->drawable;
DisplayChannelClient *dcc = RCC_TO_DCC(rcc);
RedDrawable *drawable = item->red_drawable;
int src_is_lossy;
BitmapData src_bitmap_data;
int mask_is_lossy;
BitmapData mask_bitmap_data;
int dest_is_lossy;
SpiceRect dest_lossy_area;
src_is_lossy = is_bitmap_lossy(rcc, drawable->u.composite.src_bitmap,
NULL, item, &src_bitmap_data);
mask_is_lossy = drawable->u.composite.mask_bitmap &&
is_bitmap_lossy(rcc, drawable->u.composite.mask_bitmap, NULL, item, &mask_bitmap_data);
dest_is_lossy = is_surface_area_lossy(dcc, drawable->surface_id,
&drawable->bbox, &dest_lossy_area);
if ((!src_is_lossy || (src_bitmap_data.type != BITMAP_DATA_TYPE_SURFACE)) &&
(!mask_is_lossy || (mask_bitmap_data.type != BITMAP_DATA_TYPE_SURFACE)) &&
!dest_is_lossy) {
red_marshall_qxl_draw_composite(worker, rcc, base_marshaller, dpi);
surface_lossy_region_update(worker, dcc, item, FALSE, FALSE);
}
else {
int resend_surface_ids[3];
SpiceRect *resend_areas[3];
int num_resend = 0;
if (src_is_lossy && (src_bitmap_data.type == BITMAP_DATA_TYPE_SURFACE)) {
resend_surface_ids[num_resend] = src_bitmap_data.id;
resend_areas[num_resend] = &src_bitmap_data.lossy_rect;
num_resend++;
}
if (mask_is_lossy && (mask_bitmap_data.type == BITMAP_DATA_TYPE_SURFACE)) {
resend_surface_ids[num_resend] = mask_bitmap_data.id;
resend_areas[num_resend] = &mask_bitmap_data.lossy_rect;
num_resend++;
}
if (dest_is_lossy) {
resend_surface_ids[num_resend] = item->surface_id;
resend_areas[num_resend] = &dest_lossy_area;
num_resend++;
}
red_add_lossless_drawable_dependencies(worker, rcc, item,
resend_surface_ids, resend_areas, num_resend);
}
}
static void red_marshall_qxl_draw_stroke(RedWorker *worker,
RedChannelClient *rcc,
SpiceMarshaller *base_marshaller,
DrawablePipeItem *dpi)
{
Drawable *item = dpi->drawable;
DisplayChannelClient *dcc = RCC_TO_DCC(rcc);
RedDrawable *drawable = item->red_drawable;
SpiceStroke stroke;
SpiceMarshaller *brush_pat_out;
SpiceMarshaller *style_out;
red_channel_client_init_send_data(rcc, SPICE_MSG_DISPLAY_DRAW_STROKE, &dpi->dpi_pipe_item);
fill_base(base_marshaller, item);
stroke = drawable->u.stroke;
spice_marshall_Stroke(base_marshaller,
&stroke,
&style_out,
&brush_pat_out);
fill_attr(style_out, &stroke.attr, item->group_id);
if (brush_pat_out) {
fill_bits(dcc, brush_pat_out, stroke.brush.u.pattern.pat, item, FALSE);
}
}
static void red_lossy_marshall_qxl_draw_stroke(RedWorker *worker,
RedChannelClient *rcc,
SpiceMarshaller *base_marshaller,
DrawablePipeItem *dpi)
{
Drawable *item = dpi->drawable;
DisplayChannelClient *dcc = RCC_TO_DCC(rcc);
RedDrawable *drawable = item->red_drawable;
int brush_is_lossy;
BitmapData brush_bitmap_data;
int dest_is_lossy = FALSE;
SpiceRect dest_lossy_area;
int rop;
brush_is_lossy = is_brush_lossy(rcc, &drawable->u.stroke.brush, item,
&brush_bitmap_data);
// back_mode is not used at the client. Ignoring.
rop = drawable->u.stroke.fore_mode;
// assuming that if the brush type is solid, the destination can
// be lossy, no matter what the rop is.
if (drawable->u.stroke.brush.type != SPICE_BRUSH_TYPE_SOLID &&
((rop & SPICE_ROPD_OP_OR) || (rop & SPICE_ROPD_OP_AND) ||
(rop & SPICE_ROPD_OP_XOR))) {
dest_is_lossy = is_surface_area_lossy(dcc, drawable->surface_id,
&drawable->bbox, &dest_lossy_area);
}
if (!dest_is_lossy &&
(!brush_is_lossy || (brush_bitmap_data.type != BITMAP_DATA_TYPE_SURFACE)))
{
red_marshall_qxl_draw_stroke(worker, rcc, base_marshaller, dpi);
} else {
int resend_surface_ids[2];
SpiceRect *resend_areas[2];
int num_resend = 0;
if (brush_is_lossy && (brush_bitmap_data.type == BITMAP_DATA_TYPE_SURFACE)) {
resend_surface_ids[num_resend] = brush_bitmap_data.id;
resend_areas[num_resend] = &brush_bitmap_data.lossy_rect;
num_resend++;
}
// TODO: use the path in order to resend smaller areas
if (dest_is_lossy) {
resend_surface_ids[num_resend] = drawable->surface_id;
resend_areas[num_resend] = &dest_lossy_area;
num_resend++;
}
red_add_lossless_drawable_dependencies(worker, rcc, item,
resend_surface_ids, resend_areas, num_resend);
}
}
static void red_marshall_qxl_draw_text(RedWorker *worker,
RedChannelClient *rcc,
SpiceMarshaller *base_marshaller,
DrawablePipeItem *dpi)
{
Drawable *item = dpi->drawable;
DisplayChannelClient *dcc = RCC_TO_DCC(rcc);
RedDrawable *drawable = item->red_drawable;
SpiceText text;
SpiceMarshaller *brush_pat_out;
SpiceMarshaller *back_brush_pat_out;
red_channel_client_init_send_data(rcc, SPICE_MSG_DISPLAY_DRAW_TEXT, &dpi->dpi_pipe_item);
fill_base(base_marshaller, item);
text = drawable->u.text;
spice_marshall_Text(base_marshaller,
&text,
&brush_pat_out,
&back_brush_pat_out);
if (brush_pat_out) {
fill_bits(dcc, brush_pat_out, text.fore_brush.u.pattern.pat, item, FALSE);
}
if (back_brush_pat_out) {
fill_bits(dcc, back_brush_pat_out, text.back_brush.u.pattern.pat, item, FALSE);
}
}
static void red_lossy_marshall_qxl_draw_text(RedWorker *worker,
RedChannelClient *rcc,
SpiceMarshaller *base_marshaller,
DrawablePipeItem *dpi)
{
Drawable *item = dpi->drawable;
DisplayChannelClient *dcc = RCC_TO_DCC(rcc);
RedDrawable *drawable = item->red_drawable;
int fg_is_lossy;
BitmapData fg_bitmap_data;
int bg_is_lossy;
BitmapData bg_bitmap_data;
int dest_is_lossy = FALSE;
SpiceRect dest_lossy_area;
int rop = 0;
fg_is_lossy = is_brush_lossy(rcc, &drawable->u.text.fore_brush, item,
&fg_bitmap_data);
bg_is_lossy = is_brush_lossy(rcc, &drawable->u.text.back_brush, item,
&bg_bitmap_data);
// assuming that if the brush type is solid, the destination can
// be lossy, no matter what the rop is.
if (drawable->u.text.fore_brush.type != SPICE_BRUSH_TYPE_SOLID) {
rop = drawable->u.text.fore_mode;
}
if (drawable->u.text.back_brush.type != SPICE_BRUSH_TYPE_SOLID) {
rop |= drawable->u.text.back_mode;
}
if ((rop & SPICE_ROPD_OP_OR) || (rop & SPICE_ROPD_OP_AND) ||
(rop & SPICE_ROPD_OP_XOR)) {
dest_is_lossy = is_surface_area_lossy(dcc, drawable->surface_id,
&drawable->bbox, &dest_lossy_area);
}
if (!dest_is_lossy &&
(!fg_is_lossy || (fg_bitmap_data.type != BITMAP_DATA_TYPE_SURFACE)) &&
(!bg_is_lossy || (bg_bitmap_data.type != BITMAP_DATA_TYPE_SURFACE))) {
red_marshall_qxl_draw_text(worker, rcc, base_marshaller, dpi);
} else {
int resend_surface_ids[3];
SpiceRect *resend_areas[3];
int num_resend = 0;
if (fg_is_lossy && (fg_bitmap_data.type == BITMAP_DATA_TYPE_SURFACE)) {
resend_surface_ids[num_resend] = fg_bitmap_data.id;
resend_areas[num_resend] = &fg_bitmap_data.lossy_rect;
num_resend++;
}
if (bg_is_lossy && (bg_bitmap_data.type == BITMAP_DATA_TYPE_SURFACE)) {
resend_surface_ids[num_resend] = bg_bitmap_data.id;
resend_areas[num_resend] = &bg_bitmap_data.lossy_rect;
num_resend++;
}
if (dest_is_lossy) {
resend_surface_ids[num_resend] = drawable->surface_id;
resend_areas[num_resend] = &dest_lossy_area;
num_resend++;
}
red_add_lossless_drawable_dependencies(worker, rcc, item,
resend_surface_ids, resend_areas, num_resend);
}
}
static void red_lossy_marshall_qxl_drawable(RedWorker *worker, RedChannelClient *rcc,
SpiceMarshaller *base_marshaller, DrawablePipeItem *dpi)
{
Drawable *item = dpi->drawable;
switch (item->red_drawable->type) {
case QXL_DRAW_FILL:
red_lossy_marshall_qxl_draw_fill(worker, rcc, base_marshaller, dpi);
break;
case QXL_DRAW_OPAQUE:
red_lossy_marshall_qxl_draw_opaque(worker, rcc, base_marshaller, dpi);
break;
case QXL_DRAW_COPY:
red_lossy_marshall_qxl_draw_copy(worker, rcc, base_marshaller, dpi);
break;
case QXL_DRAW_TRANSPARENT:
red_lossy_marshall_qxl_draw_transparent(worker, rcc, base_marshaller, dpi);
break;
case QXL_DRAW_ALPHA_BLEND:
red_lossy_marshall_qxl_draw_alpha_blend(worker, rcc, base_marshaller, dpi);
break;
case QXL_COPY_BITS:
red_lossy_marshall_qxl_copy_bits(worker, rcc, base_marshaller, dpi);
break;
case QXL_DRAW_BLEND:
red_lossy_marshall_qxl_draw_blend(worker, rcc, base_marshaller, dpi);
break;
case QXL_DRAW_BLACKNESS:
red_lossy_marshall_qxl_draw_blackness(worker, rcc, base_marshaller, dpi);
break;
case QXL_DRAW_WHITENESS:
red_lossy_marshall_qxl_draw_whiteness(worker, rcc, base_marshaller, dpi);
break;
case QXL_DRAW_INVERS:
red_lossy_marshall_qxl_draw_inverse(worker, rcc, base_marshaller, item);
break;
case QXL_DRAW_ROP3:
red_lossy_marshall_qxl_draw_rop3(worker, rcc, base_marshaller, dpi);
break;
case QXL_DRAW_COMPOSITE:
red_lossy_marshall_qxl_draw_composite(worker, rcc, base_marshaller, dpi);
break;
case QXL_DRAW_STROKE:
red_lossy_marshall_qxl_draw_stroke(worker, rcc, base_marshaller, dpi);
break;
case QXL_DRAW_TEXT:
red_lossy_marshall_qxl_draw_text(worker, rcc, base_marshaller, dpi);
break;
default:
spice_error("invalid type");
}
}
static inline void red_marshall_qxl_drawable(RedWorker *worker, RedChannelClient *rcc,
SpiceMarshaller *m, DrawablePipeItem *dpi)
{
Drawable *item = dpi->drawable;
RedDrawable *drawable = item->red_drawable;
switch (drawable->type) {
case QXL_DRAW_FILL:
red_marshall_qxl_draw_fill(worker, rcc, m, dpi);
break;
case QXL_DRAW_OPAQUE:
red_marshall_qxl_draw_opaque(worker, rcc, m, dpi, FALSE);
break;
case QXL_DRAW_COPY:
red_marshall_qxl_draw_copy(worker, rcc, m, dpi, FALSE);
break;
case QXL_DRAW_TRANSPARENT:
red_marshall_qxl_draw_transparent(worker, rcc, m, dpi);
break;
case QXL_DRAW_ALPHA_BLEND:
red_marshall_qxl_draw_alpha_blend(worker, rcc, m, dpi, FALSE);
break;
case QXL_COPY_BITS:
red_marshall_qxl_copy_bits(worker, rcc, m, dpi);
break;
case QXL_DRAW_BLEND:
red_marshall_qxl_draw_blend(worker, rcc, m, dpi);
break;
case QXL_DRAW_BLACKNESS:
red_marshall_qxl_draw_blackness(worker, rcc, m, dpi);
break;
case QXL_DRAW_WHITENESS:
red_marshall_qxl_draw_whiteness(worker, rcc, m, dpi);
break;
case QXL_DRAW_INVERS:
red_marshall_qxl_draw_inverse(worker, rcc, m, item);
break;
case QXL_DRAW_ROP3:
red_marshall_qxl_draw_rop3(worker, rcc, m, dpi);
break;
case QXL_DRAW_STROKE:
red_marshall_qxl_draw_stroke(worker, rcc, m, dpi);
break;
case QXL_DRAW_COMPOSITE:
red_marshall_qxl_draw_composite(worker, rcc, m, dpi);
break;
case QXL_DRAW_TEXT:
red_marshall_qxl_draw_text(worker, rcc, m, dpi);
break;
default:
spice_error("invalid type");
}
}
static void display_channel_push_release(DisplayChannelClient *dcc, uint8_t type, uint64_t id,
uint64_t* sync_data)
{
FreeList *free_list = &dcc->send_data.free_list;
int i;
for (i = 0; i < MAX_CACHE_CLIENTS; i++) {
free_list->sync[i] = MAX(free_list->sync[i], sync_data[i]);
}
if (free_list->res->count == free_list->res_size) {
SpiceResourceList *new_list;
new_list = spice_malloc(sizeof(*new_list) +
free_list->res_size * sizeof(SpiceResourceID) * 2);
new_list->count = free_list->res->count;
memcpy(new_list->resources, free_list->res->resources,
new_list->count * sizeof(SpiceResourceID));
free(free_list->res);
free_list->res = new_list;
free_list->res_size *= 2;
}
free_list->res->resources[free_list->res->count].type = type;
free_list->res->resources[free_list->res->count++].id = id;
}
static inline void display_marshal_sub_msg_inval_list(SpiceMarshaller *m,
FreeList *free_list)
{
/* type + size + submessage */
spice_marshaller_add_uint16(m, SPICE_MSG_DISPLAY_INVAL_LIST);
spice_marshaller_add_uint32(m, sizeof(*free_list->res) +
free_list->res->count * sizeof(free_list->res->resources[0]));
spice_marshall_msg_display_inval_list(m, free_list->res);
}
static inline void display_marshal_sub_msg_inval_list_wait(SpiceMarshaller *m,
FreeList *free_list)
{
/* type + size + submessage */
spice_marshaller_add_uint16(m, SPICE_MSG_WAIT_FOR_CHANNELS);
spice_marshaller_add_uint32(m, sizeof(free_list->wait.header) +
free_list->wait.header.wait_count * sizeof(free_list->wait.buf[0]));
spice_marshall_msg_wait_for_channels(m, &free_list->wait.header);
}
/* use legacy SpiceDataHeader (with sub_list) */
static inline void display_channel_send_free_list_legacy(RedChannelClient *rcc)
{
DisplayChannelClient *dcc = RCC_TO_DCC(rcc);
FreeList *free_list = &dcc->send_data.free_list;
SpiceMarshaller *marshaller;
int sub_list_len = 1;
SpiceMarshaller *wait_m = NULL;
SpiceMarshaller *inval_m;
SpiceMarshaller *sub_list_m;
marshaller = red_channel_client_get_marshaller(rcc);
inval_m = spice_marshaller_get_submarshaller(marshaller);
display_marshal_sub_msg_inval_list(inval_m, free_list);
if (free_list->wait.header.wait_count) {
wait_m = spice_marshaller_get_submarshaller(marshaller);
display_marshal_sub_msg_inval_list_wait(wait_m, free_list);
sub_list_len++;
}
sub_list_m = spice_marshaller_get_submarshaller(marshaller);
spice_marshaller_add_uint16(sub_list_m, sub_list_len);
if (wait_m) {
spice_marshaller_add_uint32(sub_list_m, spice_marshaller_get_offset(wait_m));
}
spice_marshaller_add_uint32(sub_list_m, spice_marshaller_get_offset(inval_m));
red_channel_client_set_header_sub_list(rcc, spice_marshaller_get_offset(sub_list_m));
}
/* use mini header and SPICE_MSG_LIST */
static inline void display_channel_send_free_list(RedChannelClient *rcc)
{
DisplayChannelClient *dcc = RCC_TO_DCC(rcc);
FreeList *free_list = &dcc->send_data.free_list;
int sub_list_len = 1;
SpiceMarshaller *urgent_marshaller;
SpiceMarshaller *wait_m = NULL;
SpiceMarshaller *inval_m;
uint32_t sub_arr_offset;
uint32_t wait_offset = 0;
uint32_t inval_offset = 0;
int i;
urgent_marshaller = red_channel_client_switch_to_urgent_sender(rcc);
for (i = 0; i < dcc->send_data.num_pixmap_cache_items; i++) {
int dummy;
/* When using the urgent marshaller, the serial number of the message that is
* going to be sent right after the SPICE_MSG_LIST, is increased by one.
* But all this message pixmaps cache references used its old serial.
* we use pixmap_cache_items to collect these pixmaps, and we update their serial
* by calling pixmap_cache_hit. */
pixmap_cache_hit(dcc->pixmap_cache, dcc->send_data.pixmap_cache_items[i],
&dummy, dcc);
}
if (free_list->wait.header.wait_count) {
red_channel_client_init_send_data(rcc, SPICE_MSG_LIST, NULL);
} else { /* only one message, no need for a list */
red_channel_client_init_send_data(rcc, SPICE_MSG_DISPLAY_INVAL_LIST, NULL);
spice_marshall_msg_display_inval_list(urgent_marshaller, free_list->res);
return;
}
inval_m = spice_marshaller_get_submarshaller(urgent_marshaller);
display_marshal_sub_msg_inval_list(inval_m, free_list);
if (free_list->wait.header.wait_count) {
wait_m = spice_marshaller_get_submarshaller(urgent_marshaller);
display_marshal_sub_msg_inval_list_wait(wait_m, free_list);
sub_list_len++;
}
sub_arr_offset = sub_list_len * sizeof(uint32_t);
spice_marshaller_add_uint16(urgent_marshaller, sub_list_len);
inval_offset = spice_marshaller_get_offset(inval_m); // calc the offset before
// adding the sub list
// offsets array to the marshaller
/* adding the array of offsets */
if (wait_m) {
wait_offset = spice_marshaller_get_offset(wait_m);
spice_marshaller_add_uint32(urgent_marshaller, wait_offset + sub_arr_offset);
}
spice_marshaller_add_uint32(urgent_marshaller, inval_offset + sub_arr_offset);
}
static inline void display_begin_send_message(RedChannelClient *rcc)
{
DisplayChannelClient *dcc = RCC_TO_DCC(rcc);
FreeList *free_list = &dcc->send_data.free_list;
if (free_list->res->count) {
int sync_count = 0;
int i;
for (i = 0; i < MAX_CACHE_CLIENTS; i++) {
if (i != dcc->common.id && free_list->sync[i] != 0) {
free_list->wait.header.wait_list[sync_count].channel_type = SPICE_CHANNEL_DISPLAY;
free_list->wait.header.wait_list[sync_count].channel_id = i;
free_list->wait.header.wait_list[sync_count++].message_serial = free_list->sync[i];
}
}
free_list->wait.header.wait_count = sync_count;
if (rcc->is_mini_header) {
display_channel_send_free_list(rcc);
} else {
display_channel_send_free_list_legacy(rcc);
}
}
red_channel_client_begin_send_message(rcc);
}
static inline uint8_t *red_get_image_line(SpiceChunks *chunks, size_t *offset,
int *chunk_nr, int stride)
{
uint8_t *ret;
SpiceChunk *chunk;
chunk = &chunks->chunk[*chunk_nr];
if (*offset == chunk->len) {
if (*chunk_nr == chunks->num_chunks - 1) {
return NULL; /* Last chunk */
}
*offset = 0;
(*chunk_nr)++;
chunk = &chunks->chunk[*chunk_nr];
}
if (chunk->len - *offset < stride) {
spice_warning("bad chunk alignment");
return NULL;
}
ret = chunk->data + *offset;
*offset += stride;
return ret;
}
static int encode_frame(DisplayChannelClient *dcc, const SpiceRect *src,
const SpiceBitmap *image, Stream *stream)
{
SpiceChunks *chunks;
uint32_t image_stride;
size_t offset;
int i, chunk;
StreamAgent *agent = &dcc->stream_agents[stream - dcc->common.worker->streams_buf];
chunks = image->data;
offset = 0;
chunk = 0;
image_stride = image->stride;
const int skip_lines = stream->top_down ? src->top : image->y - (src->bottom - 0);
for (i = 0; i < skip_lines; i++) {
red_get_image_line(chunks, &offset, &chunk, image_stride);
}
const unsigned int stream_height = src->bottom - src->top;
const unsigned int stream_width = src->right - src->left;
for (i = 0; i < stream_height; i++) {
uint8_t *src_line =
(uint8_t *)red_get_image_line(chunks, &offset, &chunk, image_stride);
if (!src_line) {
return FALSE;
}
src_line += src->left * mjpeg_encoder_get_bytes_per_pixel(agent->mjpeg_encoder);
if (mjpeg_encoder_encode_scanline(agent->mjpeg_encoder, src_line, stream_width) == 0)
return FALSE;
}
return TRUE;
}
static inline int red_marshall_stream_data(RedChannelClient *rcc,
SpiceMarshaller *base_marshaller, Drawable *drawable)
{
DisplayChannelClient *dcc = RCC_TO_DCC(rcc);
DisplayChannel *display_channel = SPICE_CONTAINEROF(rcc->channel, DisplayChannel, common.base);
Stream *stream = drawable->stream;
SpiceImage *image;
RedWorker *worker = dcc->common.worker;
uint32_t frame_mm_time;
int n;
int width, height;
int ret;
if (!stream) {
spice_assert(drawable->sized_stream);
stream = drawable->sized_stream;
}
spice_assert(drawable->red_drawable->type == QXL_DRAW_COPY);
worker = display_channel->common.worker;
image = drawable->red_drawable->u.copy.src_bitmap;
if (image->descriptor.type != SPICE_IMAGE_TYPE_BITMAP) {
return FALSE;
}
if (drawable->sized_stream) {
if (red_channel_client_test_remote_cap(rcc, SPICE_DISPLAY_CAP_SIZED_STREAM)) {
SpiceRect *src_rect = &drawable->red_drawable->u.copy.src_area;
width = src_rect->right - src_rect->left;
height = src_rect->bottom - src_rect->top;
} else {
return FALSE;
}
} else {
width = stream->width;
height = stream->height;
}
StreamAgent *agent = &dcc->stream_agents[get_stream_id(worker, stream)];
uint64_t time_now = red_now();
size_t outbuf_size;
if (!dcc->use_mjpeg_encoder_rate_control) {
if (time_now - agent->last_send_time < (1000 * 1000 * 1000) / agent->fps) {
agent->frames--;
#ifdef STREAM_STATS
agent->stats.num_drops_fps++;
#endif
return TRUE;
}
}
/* workaround for vga streams */
frame_mm_time = drawable->red_drawable->mm_time ?
drawable->red_drawable->mm_time :
reds_get_mm_time();
outbuf_size = dcc->send_data.stream_outbuf_size;
ret = mjpeg_encoder_start_frame(agent->mjpeg_encoder, image->u.bitmap.format,
width, height,
&dcc->send_data.stream_outbuf,
&outbuf_size,
frame_mm_time);
switch (ret) {
case MJPEG_ENCODER_FRAME_DROP:
spice_assert(dcc->use_mjpeg_encoder_rate_control);
#ifdef STREAM_STATS
agent->stats.num_drops_fps++;
#endif
return TRUE;
case MJPEG_ENCODER_FRAME_UNSUPPORTED:
return FALSE;
case MJPEG_ENCODER_FRAME_ENCODE_START:
break;
default:
spice_error("bad return value (%d) from mjpeg_encoder_start_frame", ret);
return FALSE;
}
if (!encode_frame(dcc, &drawable->red_drawable->u.copy.src_area,
&image->u.bitmap, stream)) {
return FALSE;
}
n = mjpeg_encoder_end_frame(agent->mjpeg_encoder);
dcc->send_data.stream_outbuf_size = outbuf_size;
if (!drawable->sized_stream) {
SpiceMsgDisplayStreamData stream_data;
red_channel_client_init_send_data(rcc, SPICE_MSG_DISPLAY_STREAM_DATA, NULL);
stream_data.base.id = get_stream_id(worker, stream);
stream_data.base.multi_media_time = frame_mm_time;
stream_data.data_size = n;
spice_marshall_msg_display_stream_data(base_marshaller, &stream_data);
} else {
SpiceMsgDisplayStreamDataSized stream_data;
red_channel_client_init_send_data(rcc, SPICE_MSG_DISPLAY_STREAM_DATA_SIZED, NULL);
stream_data.base.id = get_stream_id(worker, stream);
stream_data.base.multi_media_time = frame_mm_time;
stream_data.data_size = n;
stream_data.width = width;
stream_data.height = height;
stream_data.dest = drawable->red_drawable->bbox;
spice_debug("stream %d: sized frame: dest ==> ", stream_data.base.id);
rect_debug(&stream_data.dest);
spice_marshall_msg_display_stream_data_sized(base_marshaller, &stream_data);
}
spice_marshaller_add_ref(base_marshaller,
dcc->send_data.stream_outbuf, n);
agent->last_send_time = time_now;
#ifdef STREAM_STATS
agent->stats.num_frames_sent++;
agent->stats.size_sent += n;
agent->stats.end = frame_mm_time;
#endif
return TRUE;
}
static inline void marshall_qxl_drawable(RedChannelClient *rcc,
SpiceMarshaller *m, DrawablePipeItem *dpi)
{
Drawable *item = dpi->drawable;
DisplayChannel *display_channel = SPICE_CONTAINEROF(rcc->channel, DisplayChannel, common.base);
spice_assert(display_channel && rcc);
/* allow sized frames to be streamed, even if they where replaced by another frame, since
* newer frames might not cover sized frames completely if they are bigger */
if ((item->stream || item->sized_stream) && red_marshall_stream_data(rcc, m, item)) {
return;
}
if (!display_channel->enable_jpeg)
red_marshall_qxl_drawable(display_channel->common.worker, rcc, m, dpi);
else
red_lossy_marshall_qxl_drawable(display_channel->common.worker, rcc, m, dpi);
}
static inline void red_marshall_verb(RedChannelClient *rcc, uint16_t verb)
{
spice_assert(rcc);
red_channel_client_init_send_data(rcc, verb, NULL);
}
static inline void red_marshall_inval(RedChannelClient *rcc,
SpiceMarshaller *base_marshaller, CacheItem *cach_item)
{
SpiceMsgDisplayInvalOne inval_one;
red_channel_client_init_send_data(rcc, cach_item->inval_type, NULL);
inval_one.id = *(uint64_t *)&cach_item->id;
spice_marshall_msg_cursor_inval_one(base_marshaller, &inval_one);
}
static void display_channel_marshall_migrate_data_surfaces(DisplayChannelClient *dcc,
SpiceMarshaller *m,
int lossy)
{
SpiceMarshaller *m2 = spice_marshaller_get_ptr_submarshaller(m, 0);
uint32_t *num_surfaces_created;
uint32_t i;
num_surfaces_created = (uint32_t *)spice_marshaller_reserve_space(m2, sizeof(uint32_t));
*num_surfaces_created = 0;
for (i = 0; i < NUM_SURFACES; i++) {
SpiceRect lossy_rect;
if (!dcc->surface_client_created[i]) {
continue;
}
spice_marshaller_add_uint32(m2, i);
(*num_surfaces_created)++;
if (!lossy) {
continue;
}
region_extents(&dcc->surface_client_lossy_region[i], &lossy_rect);
spice_marshaller_add_int32(m2, lossy_rect.left);
spice_marshaller_add_int32(m2, lossy_rect.top);
spice_marshaller_add_int32(m2, lossy_rect.right);
spice_marshaller_add_int32(m2, lossy_rect.bottom);
}
}
static void display_channel_marshall_migrate_data(RedChannelClient *rcc,
SpiceMarshaller *base_marshaller)
{
DisplayChannel *display_channel;
DisplayChannelClient *dcc = RCC_TO_DCC(rcc);
SpiceMigrateDataDisplay display_data = {0,};
display_channel = SPICE_CONTAINEROF(rcc->channel, DisplayChannel, common.base);
red_channel_client_init_send_data(rcc, SPICE_MSG_MIGRATE_DATA, NULL);
spice_marshaller_add_uint32(base_marshaller, SPICE_MIGRATE_DATA_DISPLAY_MAGIC);
spice_marshaller_add_uint32(base_marshaller, SPICE_MIGRATE_DATA_DISPLAY_VERSION);
spice_assert(dcc->pixmap_cache);
spice_assert(MIGRATE_DATA_DISPLAY_MAX_CACHE_CLIENTS == 4 &&
MIGRATE_DATA_DISPLAY_MAX_CACHE_CLIENTS == MAX_CACHE_CLIENTS);
display_data.message_serial = red_channel_client_get_message_serial(rcc);
display_data.low_bandwidth_setting = dcc->common.is_low_bandwidth;
display_data.pixmap_cache_freezer = pixmap_cache_freeze(dcc->pixmap_cache);
display_data.pixmap_cache_id = dcc->pixmap_cache->id;
display_data.pixmap_cache_size = dcc->pixmap_cache->size;
memcpy(display_data.pixmap_cache_clients, dcc->pixmap_cache->sync,
sizeof(display_data.pixmap_cache_clients));
spice_assert(dcc->glz_dict);
red_freeze_glz(dcc);
display_data.glz_dict_id = dcc->glz_dict->id;
glz_enc_dictionary_get_restore_data(dcc->glz_dict->dict,
&display_data.glz_dict_data,
&dcc->glz_data.usr);
/* all data besided the surfaces ref */
spice_marshaller_add(base_marshaller,
(uint8_t *)&display_data, sizeof(display_data) - sizeof(uint32_t));
display_channel_marshall_migrate_data_surfaces(dcc, base_marshaller,
display_channel->enable_jpeg);
}
static void display_channel_marshall_pixmap_sync(RedChannelClient *rcc,
SpiceMarshaller *base_marshaller)
{
DisplayChannelClient *dcc = RCC_TO_DCC(rcc);
SpiceMsgWaitForChannels wait;
PixmapCache *pixmap_cache;
red_channel_client_init_send_data(rcc, SPICE_MSG_WAIT_FOR_CHANNELS, NULL);
pixmap_cache = dcc->pixmap_cache;
pthread_mutex_lock(&pixmap_cache->lock);
wait.wait_count = 1;
wait.wait_list[0].channel_type = SPICE_CHANNEL_DISPLAY;
wait.wait_list[0].channel_id = pixmap_cache->generation_initiator.client;
wait.wait_list[0].message_serial = pixmap_cache->generation_initiator.message;
dcc->pixmap_cache_generation = pixmap_cache->generation;
dcc->pending_pixmaps_sync = FALSE;
pthread_mutex_unlock(&pixmap_cache->lock);
spice_marshall_msg_wait_for_channels(base_marshaller, &wait);
}
static void display_channel_marshall_reset_cache(RedChannelClient *rcc,
SpiceMarshaller *base_marshaller)
{
DisplayChannelClient *dcc = RCC_TO_DCC(rcc);
SpiceMsgWaitForChannels wait;
red_channel_client_init_send_data(rcc, SPICE_MSG_DISPLAY_INVAL_ALL_PIXMAPS, NULL);
pixmap_cache_reset(dcc->pixmap_cache, dcc, &wait);
spice_marshall_msg_display_inval_all_pixmaps(base_marshaller,
&wait);
}
static void red_marshall_image(RedChannelClient *rcc, SpiceMarshaller *m, ImageItem *item)
{
DisplayChannelClient *dcc = RCC_TO_DCC(rcc);
DisplayChannel *display_channel = DCC_TO_DC(dcc);
SpiceImage red_image;
RedWorker *worker;
SpiceBitmap bitmap;
SpiceChunks *chunks;
QRegion *surface_lossy_region;
int comp_succeeded;
int lossy_comp = FALSE;
int lz_comp = FALSE;
spice_image_compression_t comp_mode;
SpiceMsgDisplayDrawCopy copy;
SpiceMarshaller *src_bitmap_out, *mask_bitmap_out;
SpiceMarshaller *bitmap_palette_out, *lzplt_palette_out;
spice_assert(rcc && display_channel && item);
worker = display_channel->common.worker;
QXL_SET_IMAGE_ID(&red_image, QXL_IMAGE_GROUP_RED, ++worker->bits_unique);
red_image.descriptor.type = SPICE_IMAGE_TYPE_BITMAP;
red_image.descriptor.flags = item->image_flags;
red_image.descriptor.width = item->width;
red_image.descriptor.height = item->height;
bitmap.format = item->image_format;
bitmap.flags = 0;
if (item->top_down) {
bitmap.flags |= SPICE_BITMAP_FLAGS_TOP_DOWN;
}
bitmap.x = item->width;
bitmap.y = item->height;
bitmap.stride = item->stride;
bitmap.palette = 0;
bitmap.palette_id = 0;
chunks = spice_chunks_new_linear(item->data, bitmap.stride * bitmap.y);
bitmap.data = chunks;
red_channel_client_init_send_data(rcc, SPICE_MSG_DISPLAY_DRAW_COPY, &item->link);
copy.base.surface_id = item->surface_id;
copy.base.box.left = item->pos.x;
copy.base.box.top = item->pos.y;
copy.base.box.right = item->pos.x + bitmap.x;
copy.base.box.bottom = item->pos.y + bitmap.y;
copy.base.clip.type = SPICE_CLIP_TYPE_NONE;
copy.data.rop_descriptor = SPICE_ROPD_OP_PUT;
copy.data.src_area.left = 0;
copy.data.src_area.top = 0;
copy.data.src_area.right = bitmap.x;
copy.data.src_area.bottom = bitmap.y;
copy.data.scale_mode = 0;
copy.data.src_bitmap = 0;
copy.data.mask.flags = 0;
copy.data.mask.flags = 0;
copy.data.mask.pos.x = 0;
copy.data.mask.pos.y = 0;
copy.data.mask.bitmap = 0;
spice_marshall_msg_display_draw_copy(m, ©,
&src_bitmap_out, &mask_bitmap_out);
compress_send_data_t comp_send_data = {0};
comp_mode = display_channel->common.worker->image_compression;
if (((comp_mode == SPICE_IMAGE_COMPRESS_AUTO_LZ) ||
(comp_mode == SPICE_IMAGE_COMPRESS_AUTO_GLZ)) && !_stride_is_extra(&bitmap)) {
if (BITMAP_FMT_HAS_GRADUALITY(item->image_format)) {
BitmapGradualType grad_level;
grad_level = _get_bitmap_graduality_level(display_channel->common.worker,
&bitmap,
worker->mem_slots.internal_groupslot_id);
if (grad_level == BITMAP_GRADUAL_HIGH) {
// if we use lz for alpha, the stride can't be extra
lossy_comp = display_channel->enable_jpeg && item->can_lossy;
} else {
lz_comp = TRUE;
}
} else {
lz_comp = TRUE;
}
}
if (lossy_comp) {
comp_succeeded = red_jpeg_compress_image(dcc, &red_image,
&bitmap, &comp_send_data,
worker->mem_slots.internal_groupslot_id);
} else {
if (!lz_comp) {
comp_succeeded = red_quic_compress_image(dcc, &red_image, &bitmap,
&comp_send_data,
worker->mem_slots.internal_groupslot_id);
} else {
comp_succeeded = red_lz_compress_image(dcc, &red_image, &bitmap,
&comp_send_data,
worker->mem_slots.internal_groupslot_id);
}
}
surface_lossy_region = &dcc->surface_client_lossy_region[item->surface_id];
if (comp_succeeded) {
spice_marshall_Image(src_bitmap_out, &red_image,
&bitmap_palette_out, &lzplt_palette_out);
marshaller_add_compressed(src_bitmap_out,
comp_send_data.comp_buf, comp_send_data.comp_buf_size);
if (lzplt_palette_out && comp_send_data.lzplt_palette) {
spice_marshall_Palette(lzplt_palette_out, comp_send_data.lzplt_palette);
}
if (lossy_comp) {
region_add(surface_lossy_region, ©.base.box);
} else {
region_remove(surface_lossy_region, ©.base.box);
}
} else {
red_image.descriptor.type = SPICE_IMAGE_TYPE_BITMAP;
red_image.u.bitmap = bitmap;
spice_marshall_Image(src_bitmap_out, &red_image,
&bitmap_palette_out, &lzplt_palette_out);
spice_marshaller_add_ref(src_bitmap_out, item->data,
bitmap.y * bitmap.stride);
region_remove(surface_lossy_region, ©.base.box);
}
spice_chunks_destroy(chunks);
}
static void red_display_marshall_upgrade(RedChannelClient *rcc, SpiceMarshaller *m,
UpgradeItem *item)
{
DisplayChannelClient *dcc = RCC_TO_DCC(rcc);
RedDrawable *red_drawable;
SpiceMsgDisplayDrawCopy copy;
SpiceMarshaller *src_bitmap_out, *mask_bitmap_out;
spice_assert(rcc && rcc->channel && item && item->drawable);
red_channel_client_init_send_data(rcc, SPICE_MSG_DISPLAY_DRAW_COPY, &item->base);
red_drawable = item->drawable->red_drawable;
spice_assert(red_drawable->type == QXL_DRAW_COPY);
spice_assert(red_drawable->u.copy.rop_descriptor == SPICE_ROPD_OP_PUT);
spice_assert(red_drawable->u.copy.mask.bitmap == 0);
copy.base.surface_id = 0;
copy.base.box = red_drawable->bbox;
copy.base.clip.type = SPICE_CLIP_TYPE_RECTS;
copy.base.clip.rects = item->rects;
copy.data = red_drawable->u.copy;
spice_marshall_msg_display_draw_copy(m, ©,
&src_bitmap_out, &mask_bitmap_out);
fill_bits(dcc, src_bitmap_out, copy.data.src_bitmap, item->drawable, FALSE);
}
static void red_display_marshall_stream_start(RedChannelClient *rcc,
SpiceMarshaller *base_marshaller, StreamAgent *agent)
{
DisplayChannelClient *dcc = RCC_TO_DCC(rcc);
Stream *stream = agent->stream;
agent->last_send_time = 0;
spice_assert(stream);
red_channel_client_init_send_data(rcc, SPICE_MSG_DISPLAY_STREAM_CREATE, NULL);
SpiceMsgDisplayStreamCreate stream_create;
SpiceClipRects clip_rects;
stream_create.surface_id = 0;
stream_create.id = get_stream_id(dcc->common.worker, stream);
stream_create.flags = stream->top_down ? SPICE_STREAM_FLAGS_TOP_DOWN : 0;
stream_create.codec_type = SPICE_VIDEO_CODEC_TYPE_MJPEG;
stream_create.src_width = stream->width;
stream_create.src_height = stream->height;
stream_create.stream_width = stream_create.src_width;
stream_create.stream_height = stream_create.src_height;
stream_create.dest = stream->dest_area;
if (stream->current) {
RedDrawable *red_drawable = stream->current->red_drawable;
stream_create.clip = red_drawable->clip;
} else {
stream_create.clip.type = SPICE_CLIP_TYPE_RECTS;
clip_rects.num_rects = 0;
stream_create.clip.rects = &clip_rects;
}
stream_create.stamp = 0;
spice_marshall_msg_display_stream_create(base_marshaller, &stream_create);
}
static void red_display_marshall_stream_clip(RedChannelClient *rcc,
SpiceMarshaller *base_marshaller,
StreamClipItem *item)
{
DisplayChannelClient *dcc = RCC_TO_DCC(rcc);
StreamAgent *agent = item->stream_agent;
spice_assert(agent->stream);
red_channel_client_init_send_data(rcc, SPICE_MSG_DISPLAY_STREAM_CLIP, &item->base);
SpiceMsgDisplayStreamClip stream_clip;
stream_clip.id = get_stream_id(dcc->common.worker, agent->stream);
stream_clip.clip.type = item->clip_type;
stream_clip.clip.rects = item->rects;
spice_marshall_msg_display_stream_clip(base_marshaller, &stream_clip);
}
static void red_display_marshall_stream_end(RedChannelClient *rcc,
SpiceMarshaller *base_marshaller, StreamAgent* agent)
{
DisplayChannelClient *dcc = RCC_TO_DCC(rcc);
SpiceMsgDisplayStreamDestroy destroy;
red_channel_client_init_send_data(rcc, SPICE_MSG_DISPLAY_STREAM_DESTROY, NULL);
destroy.id = get_stream_id(dcc->common.worker, agent->stream);
red_display_stream_agent_stop(dcc, agent);
spice_marshall_msg_display_stream_destroy(base_marshaller, &destroy);
}
static void red_cursor_marshall_inval(RedChannelClient *rcc,
SpiceMarshaller *m, CacheItem *cach_item)
{
spice_assert(rcc);
red_marshall_inval(rcc, m, cach_item);
}
static void red_marshall_cursor_init(RedChannelClient *rcc, SpiceMarshaller *base_marshaller,
PipeItem *pipe_item)
{
CursorChannel *cursor_channel;
CursorChannelClient *ccc = RCC_TO_CCC(rcc);
RedWorker *worker;
SpiceMsgCursorInit msg;
AddBufInfo info;
spice_assert(rcc);
cursor_channel = SPICE_CONTAINEROF(rcc->channel, CursorChannel, common.base);
worker = cursor_channel->common.worker;
red_channel_client_init_send_data(rcc, SPICE_MSG_CURSOR_INIT, NULL);
msg.visible = worker->cursor_visible;
msg.position = worker->cursor_position;
msg.trail_length = worker->cursor_trail_length;
msg.trail_frequency = worker->cursor_trail_frequency;
fill_cursor(ccc, &msg.cursor, worker->cursor, &info);
spice_marshall_msg_cursor_init(base_marshaller, &msg);
add_buf_from_info(base_marshaller, &info);
}
static void red_marshall_cursor(RedChannelClient *rcc,
SpiceMarshaller *m, CursorPipeItem *cursor_pipe_item)
{
CursorChannel *cursor_channel = SPICE_CONTAINEROF(rcc->channel, CursorChannel, common.base);
CursorChannelClient *ccc = RCC_TO_CCC(rcc);
CursorItem *cursor = cursor_pipe_item->cursor_item;
PipeItem *pipe_item = &cursor_pipe_item->base;
RedCursorCmd *cmd;
RedWorker *worker;
spice_assert(cursor_channel);
worker = cursor_channel->common.worker;
cmd = cursor->red_cursor;
switch (cmd->type) {
case QXL_CURSOR_MOVE:
{
SpiceMsgCursorMove cursor_move;
red_channel_client_init_send_data(rcc, SPICE_MSG_CURSOR_MOVE, pipe_item);
cursor_move.position = cmd->u.position;
spice_marshall_msg_cursor_move(m, &cursor_move);
break;
}
case QXL_CURSOR_SET:
{
SpiceMsgCursorSet cursor_set;
AddBufInfo info;
red_channel_client_init_send_data(rcc, SPICE_MSG_CURSOR_SET, pipe_item);
cursor_set.position = cmd->u.set.position;
cursor_set.visible = worker->cursor_visible;
fill_cursor(ccc, &cursor_set.cursor, cursor, &info);
spice_marshall_msg_cursor_set(m, &cursor_set);
add_buf_from_info(m, &info);
break;
}
case QXL_CURSOR_HIDE:
red_channel_client_init_send_data(rcc, SPICE_MSG_CURSOR_HIDE, pipe_item);
break;
case QXL_CURSOR_TRAIL:
{
SpiceMsgCursorTrail cursor_trail;
red_channel_client_init_send_data(rcc, SPICE_MSG_CURSOR_TRAIL, pipe_item);
cursor_trail.length = cmd->u.trail.length;
cursor_trail.frequency = cmd->u.trail.frequency;
spice_marshall_msg_cursor_trail(m, &cursor_trail);
}
break;
default:
spice_error("bad cursor command %d", cmd->type);
}
}
static void red_marshall_surface_create(RedChannelClient *rcc,
SpiceMarshaller *base_marshaller, SpiceMsgSurfaceCreate *surface_create)
{
DisplayChannelClient *dcc = RCC_TO_DCC(rcc);
region_init(&dcc->surface_client_lossy_region[surface_create->surface_id]);
red_channel_client_init_send_data(rcc, SPICE_MSG_DISPLAY_SURFACE_CREATE, NULL);
spice_marshall_msg_display_surface_create(base_marshaller, surface_create);
}
static void red_marshall_surface_destroy(RedChannelClient *rcc,
SpiceMarshaller *base_marshaller, uint32_t surface_id)
{
DisplayChannelClient *dcc = RCC_TO_DCC(rcc);
SpiceMsgSurfaceDestroy surface_destroy;
region_destroy(&dcc->surface_client_lossy_region[surface_id]);
red_channel_client_init_send_data(rcc, SPICE_MSG_DISPLAY_SURFACE_DESTROY, NULL);
surface_destroy.surface_id = surface_id;
spice_marshall_msg_display_surface_destroy(base_marshaller, &surface_destroy);
}
static void red_marshall_monitors_config(RedChannelClient *rcc, SpiceMarshaller *base_marshaller,
MonitorsConfig *monitors_config)
{
int heads_size = sizeof(SpiceHead) * monitors_config->count;
int i;
SpiceMsgDisplayMonitorsConfig *msg = spice_malloc0(sizeof(*msg) + heads_size);
int count = 0; // ignore monitors_config->count, it may contain zero width monitors, remove them now
red_channel_client_init_send_data(rcc, SPICE_MSG_DISPLAY_MONITORS_CONFIG, NULL);
for (i = 0 ; i < monitors_config->count; ++i) {
if (monitors_config->heads[i].width == 0 || monitors_config->heads[i].height == 0) {
continue;
}
msg->heads[count].id = monitors_config->heads[i].id;
msg->heads[count].surface_id = monitors_config->heads[i].surface_id;
msg->heads[count].width = monitors_config->heads[i].width;
msg->heads[count].height = monitors_config->heads[i].height;
msg->heads[count].x = monitors_config->heads[i].x;
msg->heads[count].y = monitors_config->heads[i].y;
count++;
}
msg->count = count;
msg->max_allowed = monitors_config->max_allowed;
spice_marshall_msg_display_monitors_config(base_marshaller, msg);
free(msg);
}
static void red_marshall_stream_activate_report(RedChannelClient *rcc,
SpiceMarshaller *base_marshaller,
uint32_t stream_id)
{
DisplayChannelClient *dcc = RCC_TO_DCC(rcc);
StreamAgent *agent = &dcc->stream_agents[stream_id];
SpiceMsgDisplayStreamActivateReport msg;
red_channel_client_init_send_data(rcc, SPICE_MSG_DISPLAY_STREAM_ACTIVATE_REPORT, NULL);
msg.stream_id = stream_id;
msg.unique_id = agent->report_id;
msg.max_window_size = RED_STREAM_CLIENT_REPORT_WINDOW;
msg.timeout_ms = RED_STREAM_CLIENT_REPORT_TIMEOUT;
spice_marshall_msg_display_stream_activate_report(base_marshaller, &msg);
}
static void display_channel_send_item(RedChannelClient *rcc, PipeItem *pipe_item)
{
SpiceMarshaller *m = red_channel_client_get_marshaller(rcc);
DisplayChannelClient *dcc = RCC_TO_DCC(rcc);
red_display_reset_send_data(dcc);
switch (pipe_item->type) {
case PIPE_ITEM_TYPE_DRAW: {
DrawablePipeItem *dpi = SPICE_CONTAINEROF(pipe_item, DrawablePipeItem, dpi_pipe_item);
marshall_qxl_drawable(rcc, m, dpi);
break;
}
case PIPE_ITEM_TYPE_INVAL_ONE:
red_marshall_inval(rcc, m, (CacheItem *)pipe_item);
break;
case PIPE_ITEM_TYPE_STREAM_CREATE: {
StreamAgent *agent = SPICE_CONTAINEROF(pipe_item, StreamAgent, create_item);
red_display_marshall_stream_start(rcc, m, agent);
break;
}
case PIPE_ITEM_TYPE_STREAM_CLIP: {
StreamClipItem* clip_item = (StreamClipItem *)pipe_item;
red_display_marshall_stream_clip(rcc, m, clip_item);
break;
}
case PIPE_ITEM_TYPE_STREAM_DESTROY: {
StreamAgent *agent = SPICE_CONTAINEROF(pipe_item, StreamAgent, destroy_item);
red_display_marshall_stream_end(rcc, m, agent);
break;
}
case PIPE_ITEM_TYPE_UPGRADE:
red_display_marshall_upgrade(rcc, m, (UpgradeItem *)pipe_item);
break;
case PIPE_ITEM_TYPE_VERB:
red_marshall_verb(rcc, ((VerbItem*)pipe_item)->verb);
break;
case PIPE_ITEM_TYPE_MIGRATE_DATA:
display_channel_marshall_migrate_data(rcc, m);
break;
case PIPE_ITEM_TYPE_IMAGE:
red_marshall_image(rcc, m, (ImageItem *)pipe_item);
break;
case PIPE_ITEM_TYPE_PIXMAP_SYNC:
display_channel_marshall_pixmap_sync(rcc, m);
break;
case PIPE_ITEM_TYPE_PIXMAP_RESET:
display_channel_marshall_reset_cache(rcc, m);
break;
case PIPE_ITEM_TYPE_INVAL_PALLET_CACHE:
red_reset_palette_cache(dcc);
red_marshall_verb(rcc, SPICE_MSG_DISPLAY_INVAL_ALL_PALETTES);
break;
case PIPE_ITEM_TYPE_CREATE_SURFACE: {
SurfaceCreateItem *surface_create = SPICE_CONTAINEROF(pipe_item, SurfaceCreateItem,
pipe_item);
red_marshall_surface_create(rcc, m, &surface_create->surface_create);
break;
}
case PIPE_ITEM_TYPE_DESTROY_SURFACE: {
SurfaceDestroyItem *surface_destroy = SPICE_CONTAINEROF(pipe_item, SurfaceDestroyItem,
pipe_item);
red_marshall_surface_destroy(rcc, m, surface_destroy->surface_destroy.surface_id);
break;
}
case PIPE_ITEM_TYPE_MONITORS_CONFIG: {
MonitorsConfigItem *monconf_item = SPICE_CONTAINEROF(pipe_item,
MonitorsConfigItem, pipe_item);
red_marshall_monitors_config(rcc, m, monconf_item->monitors_config);
break;
}
case PIPE_ITEM_TYPE_STREAM_ACTIVATE_REPORT: {
StreamActivateReportItem *report_item = SPICE_CONTAINEROF(pipe_item,
StreamActivateReportItem,
pipe_item);
red_marshall_stream_activate_report(rcc, m, report_item->stream_id);
break;
}
default:
spice_error("invalid pipe item type");
}
display_channel_client_release_item_before_push(dcc, pipe_item);
// a message is pending
if (red_channel_client_send_message_pending(rcc)) {
display_begin_send_message(rcc);
}
}
static void cursor_channel_send_item(RedChannelClient *rcc, PipeItem *pipe_item)
{
SpiceMarshaller *m = red_channel_client_get_marshaller(rcc);
CursorChannelClient *ccc = RCC_TO_CCC(rcc);
switch (pipe_item->type) {
case PIPE_ITEM_TYPE_CURSOR:
red_marshall_cursor(rcc, m, SPICE_CONTAINEROF(pipe_item, CursorPipeItem, base));
break;
case PIPE_ITEM_TYPE_INVAL_ONE:
red_cursor_marshall_inval(rcc, m, (CacheItem *)pipe_item);
break;
case PIPE_ITEM_TYPE_VERB:
red_marshall_verb(rcc, ((VerbItem*)pipe_item)->verb);
break;
case PIPE_ITEM_TYPE_CURSOR_INIT:
red_reset_cursor_cache(rcc);
red_marshall_cursor_init(rcc, m, pipe_item);
break;
case PIPE_ITEM_TYPE_INVAL_CURSOR_CACHE:
red_reset_cursor_cache(rcc);
red_marshall_verb(rcc, SPICE_MSG_CURSOR_INVAL_ALL);
break;
default:
spice_error("invalid pipe item type");
}
cursor_channel_client_release_item_before_push(ccc, pipe_item);
red_channel_client_begin_send_message(rcc);
}
static inline void red_push(RedWorker *worker)
{
if (worker->cursor_channel) {
red_channel_push(&worker->cursor_channel->common.base);
}
if (worker->display_channel) {
red_channel_push(&worker->display_channel->common.base);
}
}
typedef struct ShowTreeData {
RedWorker *worker;
int level;
Container *container;
} ShowTreeData;
static void __show_tree_call(TreeItem *item, void *data)
{
ShowTreeData *tree_data = data;
const char *item_prefix = "|--";
int i;
while (tree_data->container != item->container) {
spice_assert(tree_data->container);
tree_data->level--;
tree_data->container = tree_data->container->base.container;
}
switch (item->type) {
case TREE_ITEM_TYPE_DRAWABLE: {
Drawable *drawable = SPICE_CONTAINEROF(item, Drawable, tree_item);
const int max_indent = 200;
char indent_str[max_indent + 1];
int indent_str_len;
for (i = 0; i < tree_data->level; i++) {
printf(" ");
}
printf(item_prefix, 0);
show_red_drawable(tree_data->worker, drawable->red_drawable, NULL);
for (i = 0; i < tree_data->level; i++) {
printf(" ");
}
printf("| ");
show_draw_item(tree_data->worker, &drawable->tree_item, NULL);
indent_str_len = MIN(max_indent, strlen(item_prefix) + tree_data->level * 2);
memset(indent_str, ' ', indent_str_len);
indent_str[indent_str_len] = 0;
region_dump(&item->rgn, indent_str);
printf("\n");
break;
}
case TREE_ITEM_TYPE_CONTAINER:
tree_data->level++;
tree_data->container = (Container *)item;
break;
case TREE_ITEM_TYPE_SHADOW:
break;
}
}
void red_show_tree(RedWorker *worker)
{
int x;
ShowTreeData show_tree_data;
show_tree_data.worker = worker;
show_tree_data.level = 0;
show_tree_data.container = NULL;
for (x = 0; x < NUM_SURFACES; ++x) {
if (worker->surfaces[x].context.canvas) {
current_tree_for_each(&worker->surfaces[x].current, __show_tree_call,
&show_tree_data);
}
}
}
static void display_channel_client_on_disconnect(RedChannelClient *rcc)
{
DisplayChannel *display_channel;
DisplayChannelClient *dcc = RCC_TO_DCC(rcc);
CommonChannel *common;
RedWorker *worker;
if (!rcc) {
return;
}
spice_info(NULL);
common = SPICE_CONTAINEROF(rcc->channel, CommonChannel, base);
worker = common->worker;
display_channel = (DisplayChannel *)rcc->channel;
spice_assert(display_channel == worker->display_channel);
#ifdef COMPRESS_STAT
print_compress_stats(display_channel);
#endif
red_release_pixmap_cache(dcc);
red_release_glz(dcc);
red_reset_palette_cache(dcc);
free(dcc->send_data.stream_outbuf);
red_display_reset_compress_buf(dcc);
free(dcc->send_data.free_list.res);
red_display_destroy_streams_agents(dcc);
// this was the last channel client
if (!red_channel_is_connected(rcc->channel)) {
red_display_destroy_compress_bufs(display_channel);
}
spice_debug("#draw=%d, #red_draw=%d, #glz_draw=%d",
worker->drawable_count, worker->red_drawable_count,
worker->glz_drawable_count);
}
void red_disconnect_all_display_TODO_remove_me(RedChannel *channel)
{
// TODO: we need to record the client that actually causes the timeout. So
// we need to check the locations of the various pipe heads when counting,
// and disconnect only those/that.
if (!channel) {
return;
}
red_channel_apply_clients(channel, red_channel_client_disconnect);
}
static void red_destroy_streams(RedWorker *worker)
{
RingItem *stream_item;
spice_debug(NULL);
while ((stream_item = ring_get_head(&worker->streams))) {
Stream *stream = SPICE_CONTAINEROF(stream_item, Stream, link);
red_detach_stream_gracefully(worker, stream, NULL);
red_stop_stream(worker, stream);
}
}
static void red_migrate_display(RedWorker *worker, RedChannelClient *rcc)
{
/* We need to stop the streams, and to send upgrade_items to the client.
* Otherwise, (1) the client might display lossy regions that we don't track
* (streams are not part of the migration data) (2) streams_timeout may occur
* after the MIGRATE message has been sent. This can result in messages
* being sent to the client after MSG_MIGRATE and before MSG_MIGRATE_DATA (e.g.,
* STREAM_CLIP, STREAM_DESTROY, DRAW_COPY)
* No message besides MSG_MIGRATE_DATA should be sent after MSG_MIGRATE.
* Notice that red_destroy_streams won't lead to any dev ram changes, since
* handle_dev_stop already took care of releasing all the dev ram resources.
*/
red_destroy_streams(worker);
if (red_channel_client_is_connected(rcc)) {
red_channel_client_default_migrate(rcc);
}
}
#ifdef USE_OPENGL
static SpiceCanvas *create_ogl_context_common(RedWorker *worker, OGLCtx *ctx, uint32_t width,
uint32_t height, int32_t stride, uint8_t depth)
{
SpiceCanvas *canvas;
oglctx_make_current(ctx);
if (!(canvas = gl_canvas_create(width, height, depth, &worker->image_cache.base,
&worker->image_surfaces, NULL, NULL, NULL))) {
return NULL;
}
spice_canvas_set_usr_data(canvas, ctx, (spice_destroy_fn_t)oglctx_destroy);
canvas->ops->clear(canvas);
return canvas;
}
static SpiceCanvas *create_ogl_pbuf_context(RedWorker *worker, uint32_t width, uint32_t height,
int32_t stride, uint8_t depth)
{
OGLCtx *ctx;
SpiceCanvas *canvas;
if (!(ctx = pbuf_create(width, height))) {
return NULL;
}
if (!(canvas = create_ogl_context_common(worker, ctx, width, height, stride, depth))) {
oglctx_destroy(ctx);
return NULL;
}
return canvas;
}
static SpiceCanvas *create_ogl_pixmap_context(RedWorker *worker, uint32_t width, uint32_t height,
int32_t stride, uint8_t depth) {
OGLCtx *ctx;
SpiceCanvas *canvas;
if (!(ctx = pixmap_create(width, height))) {
return NULL;
}
if (!(canvas = create_ogl_context_common(worker, ctx, width, height, stride, depth))) {
oglctx_destroy(ctx);
return NULL;
}
return canvas;
}
#endif
static inline void *create_canvas_for_surface(RedWorker *worker, RedSurface *surface,
uint32_t renderer, uint32_t width, uint32_t height,
int32_t stride, uint32_t format, void *line_0)
{
SpiceCanvas *canvas;
switch (renderer) {
case RED_RENDERER_SW:
canvas = canvas_create_for_data(width, height, format,
line_0, stride,
&worker->image_cache.base,
&worker->image_surfaces, NULL, NULL, NULL);
surface->context.top_down = TRUE;
surface->context.canvas_draws_on_surface = TRUE;
return canvas;
#ifdef USE_OPENGL
case RED_RENDERER_OGL_PBUF:
canvas = create_ogl_pbuf_context(worker, width, height, stride,
SPICE_SURFACE_FMT_DEPTH(format));
surface->context.top_down = FALSE;
return canvas;
case RED_RENDERER_OGL_PIXMAP:
canvas = create_ogl_pixmap_context(worker, width, height, stride,
SPICE_SURFACE_FMT_DEPTH(format));
surface->context.top_down = FALSE;
return canvas;
#endif
default:
spice_error("invalid renderer type");
};
return NULL;
}
static SurfaceCreateItem *get_surface_create_item(
RedChannel* channel,
uint32_t surface_id, uint32_t width,
uint32_t height, uint32_t format, uint32_t flags)
{
SurfaceCreateItem *create;
create = (SurfaceCreateItem *)malloc(sizeof(SurfaceCreateItem));
spice_warn_if(!create);
create->surface_create.surface_id = surface_id;
create->surface_create.width = width;
create->surface_create.height = height;
create->surface_create.flags = flags;
create->surface_create.format = format;
red_channel_pipe_item_init(channel,
&create->pipe_item, PIPE_ITEM_TYPE_CREATE_SURFACE);
return create;
}
static inline void red_create_surface_item(DisplayChannelClient *dcc, int surface_id)
{
RedSurface *surface;
SurfaceCreateItem *create;
RedWorker *worker = dcc ? dcc->common.worker : NULL;
uint32_t flags = is_primary_surface(worker, surface_id) ? SPICE_SURFACE_FLAGS_PRIMARY : 0;
/* don't send redundant create surface commands to client */
if (!dcc || worker->display_channel->common.during_target_migrate ||
dcc->surface_client_created[surface_id]) {
return;
}
surface = &worker->surfaces[surface_id];
create = get_surface_create_item(dcc->common.base.channel,
surface_id, surface->context.width, surface->context.height,
surface->context.format, flags);
dcc->surface_client_created[surface_id] = TRUE;
red_channel_client_pipe_add(&dcc->common.base, &create->pipe_item);
}
static void red_worker_create_surface_item(RedWorker *worker, int surface_id)
{
DisplayChannelClient *dcc;
RingItem *item, *next;
WORKER_FOREACH_DCC_SAFE(worker, item, next, dcc) {
red_create_surface_item(dcc, surface_id);
}
}
static void red_worker_push_surface_image(RedWorker *worker, int surface_id)
{
DisplayChannelClient *dcc;
RingItem *item, *next;
WORKER_FOREACH_DCC_SAFE(worker, item, next, dcc) {
red_push_surface_image(dcc, surface_id);
}
}
static inline void red_create_surface(RedWorker *worker, uint32_t surface_id, uint32_t width,
uint32_t height, int32_t stride, uint32_t format,
void *line_0, int data_is_valid, int send_client)
{
RedSurface *surface = &worker->surfaces[surface_id];
uint32_t i;
spice_warn_if(surface->context.canvas);
surface->context.canvas_draws_on_surface = FALSE;
surface->context.width = width;
surface->context.height = height;
surface->context.format = format;
surface->context.stride = stride;
surface->context.line_0 = line_0;
if (!data_is_valid) {
memset((char *)line_0 + (int32_t)(stride * (height - 1)), 0, height*abs(stride));
}
surface->create.info = NULL;
surface->destroy.info = NULL;
ring_init(&surface->current);
ring_init(&surface->current_list);
ring_init(&surface->depend_on_me);
region_init(&surface->draw_dirty_region);
surface->refs = 1;
if (worker->renderer != RED_RENDERER_INVALID) {
surface->context.canvas = create_canvas_for_surface(worker, surface, worker->renderer,
width, height, stride,
surface->context.format, line_0);
if (!surface->context.canvas) {
spice_critical("drawing canvas creating failed - can`t create same type canvas");
}
if (send_client) {
red_worker_create_surface_item(worker, surface_id);
if (data_is_valid) {
red_worker_push_surface_image(worker, surface_id);
}
}
return;
}
for (i = 0; i < worker->num_renderers; i++) {
surface->context.canvas = create_canvas_for_surface(worker, surface, worker->renderers[i],
width, height, stride,
surface->context.format, line_0);
if (surface->context.canvas) { //no need canvas check
worker->renderer = worker->renderers[i];
if (send_client) {
red_worker_create_surface_item(worker, surface_id);
if (data_is_valid) {
red_worker_push_surface_image(worker, surface_id);
}
}
return;
}
}
spice_critical("unable to create drawing canvas");
}
static inline void flush_display_commands(RedWorker *worker)
{
RedChannel *display_red_channel = &worker->display_channel->common.base;
for (;;) {
uint64_t end_time;
int ring_is_empty;
red_process_commands(worker, MAX_PIPE_SIZE, &ring_is_empty);
if (ring_is_empty) {
break;
}
while (red_process_commands(worker, MAX_PIPE_SIZE, &ring_is_empty)) {
red_channel_push(&worker->display_channel->common.base);
}
if (ring_is_empty) {
break;
}
end_time = red_now() + DISPLAY_CLIENT_TIMEOUT * 10;
int sleep_count = 0;
for (;;) {
red_channel_push(&worker->display_channel->common.base);
if (!display_is_connected(worker) ||
red_channel_max_pipe_size(display_red_channel) <= MAX_PIPE_SIZE) {
break;
}
RedChannel *channel = (RedChannel *)worker->display_channel;
red_channel_receive(channel);
red_channel_send(channel);
// TODO: MC: the whole timeout will break since it takes lowest timeout, should
// do it client by client.
if (red_now() >= end_time) {
spice_warning("update timeout");
red_disconnect_all_display_TODO_remove_me(channel);
} else {
sleep_count++;
usleep(DISPLAY_CLIENT_RETRY_INTERVAL);
}
}
}
}
static inline void flush_cursor_commands(RedWorker *worker)
{
RedChannel *cursor_red_channel = &worker->cursor_channel->common.base;
for (;;) {
uint64_t end_time;
int ring_is_empty = FALSE;
red_process_cursor(worker, MAX_PIPE_SIZE, &ring_is_empty);
if (ring_is_empty) {
break;
}
while (red_process_cursor(worker, MAX_PIPE_SIZE, &ring_is_empty)) {
red_channel_push(&worker->cursor_channel->common.base);
}
if (ring_is_empty) {
break;
}
end_time = red_now() + DISPLAY_CLIENT_TIMEOUT * 10;
int sleep_count = 0;
for (;;) {
red_channel_push(&worker->cursor_channel->common.base);
if (!cursor_is_connected(worker)
|| red_channel_min_pipe_size(cursor_red_channel) <= MAX_PIPE_SIZE) {
break;
}
RedChannel *channel = (RedChannel *)worker->cursor_channel;
red_channel_receive(channel);
red_channel_send(channel);
if (red_now() >= end_time) {
spice_warning("flush cursor timeout");
red_disconnect_cursor(channel);
} else {
sleep_count++;
usleep(DISPLAY_CLIENT_RETRY_INTERVAL);
}
}
}
}
// TODO: on timeout, don't disconnect all channeld immeduiatly - try to disconnect the slowest ones
// first and maybe turn timeouts to several timeouts in order to disconnect channels gradually.
// Should use disconnect or shutdown?
static inline void flush_all_qxl_commands(RedWorker *worker)
{
flush_display_commands(worker);
flush_cursor_commands(worker);
}
static void push_new_primary_surface(DisplayChannelClient *dcc)
{
RedChannelClient *rcc = &dcc->common.base;
red_channel_client_pipe_add_type(rcc, PIPE_ITEM_TYPE_INVAL_PALLET_CACHE);
red_create_surface_item(dcc, 0);
red_channel_client_push(rcc);
}
/* TODO: this function is evil^Wsynchronous, fix */
static int display_channel_client_wait_for_init(DisplayChannelClient *dcc)
{
dcc->expect_init = TRUE;
uint64_t end_time = red_now() + DISPLAY_CLIENT_TIMEOUT;
for (;;) {
red_channel_client_receive(&dcc->common.base);
if (!red_channel_client_is_connected(&dcc->common.base)) {
break;
}
if (dcc->pixmap_cache && dcc->glz_dict) {
dcc->pixmap_cache_generation = dcc->pixmap_cache->generation;
/* TODO: move common.id? if it's used for a per client structure.. */
spice_info("creating encoder with id == %d", dcc->common.id);
dcc->glz = glz_encoder_create(dcc->common.id, dcc->glz_dict->dict, &dcc->glz_data.usr);
if (!dcc->glz) {
spice_critical("create global lz failed");
}
return TRUE;
}
if (red_now() > end_time) {
spice_warning("timeout");
red_channel_client_disconnect(&dcc->common.base);
break;
}
usleep(DISPLAY_CLIENT_RETRY_INTERVAL);
}
return FALSE;
}
static void on_new_display_channel_client(DisplayChannelClient *dcc)
{
DisplayChannel *display_channel = DCC_TO_DC(dcc);
RedWorker *worker = display_channel->common.worker;
RedChannelClient *rcc = &dcc->common.base;
red_channel_client_push_set_ack(&dcc->common.base);
if (red_channel_client_waits_for_migrate_data(rcc)) {
return;
}
if (!display_channel_client_wait_for_init(dcc)) {
return;
}
red_channel_client_ack_zero_messages_window(&dcc->common.base);
if (worker->surfaces[0].context.canvas) {
red_current_flush(worker, 0);
push_new_primary_surface(dcc);
red_push_surface_image(dcc, 0);
red_push_monitors_config(dcc);
red_pipe_add_verb(rcc, SPICE_MSG_DISPLAY_MARK);
red_disply_start_streams(dcc);
}
}
static GlzSharedDictionary *_red_find_glz_dictionary(RedClient *client, uint8_t dict_id)
{
RingItem *now;
GlzSharedDictionary *ret = NULL;
now = &glz_dictionary_list;
while ((now = ring_next(&glz_dictionary_list, now))) {
GlzSharedDictionary *dict = (GlzSharedDictionary *)now;
if ((dict->client == client) && (dict->id == dict_id)) {
ret = dict;
break;
}
}
return ret;
}
static GlzSharedDictionary *_red_create_glz_dictionary(RedClient *client, uint8_t id,
GlzEncDictContext *opaque_dict)
{
GlzSharedDictionary *shared_dict = spice_new0(GlzSharedDictionary, 1);
shared_dict->dict = opaque_dict;
shared_dict->id = id;
shared_dict->refs = 1;
shared_dict->migrate_freeze = FALSE;
shared_dict->client = client;
ring_item_init(&shared_dict->base);
pthread_rwlock_init(&shared_dict->encode_lock, NULL);
return shared_dict;
}
static GlzSharedDictionary *red_create_glz_dictionary(DisplayChannelClient *dcc,
uint8_t id, int window_size)
{
GlzEncDictContext *glz_dict = glz_enc_dictionary_create(window_size,
MAX_LZ_ENCODERS,
&dcc->glz_data.usr);
#ifdef COMPRESS_DEBUG
spice_info("Lz Window %d Size=%d", id, window_size);
#endif
if (!glz_dict) {
spice_critical("failed creating lz dictionary");
return NULL;
}
return _red_create_glz_dictionary(dcc->common.base.client, id, glz_dict);
}
static GlzSharedDictionary *red_create_restored_glz_dictionary(DisplayChannelClient *dcc,
uint8_t id,
GlzEncDictRestoreData *restore_data)
{
GlzEncDictContext *glz_dict = glz_enc_dictionary_restore(restore_data,
&dcc->glz_data.usr);
if (!glz_dict) {
spice_critical("failed creating lz dictionary");
return NULL;
}
return _red_create_glz_dictionary(dcc->common.base.client, id, glz_dict);
}
static GlzSharedDictionary *red_get_glz_dictionary(DisplayChannelClient *dcc,
uint8_t id, int window_size)
{
GlzSharedDictionary *shared_dict = NULL;
pthread_mutex_lock(&glz_dictionary_list_lock);
shared_dict = _red_find_glz_dictionary(dcc->common.base.client, id);
if (!shared_dict) {
shared_dict = red_create_glz_dictionary(dcc, id, window_size);
ring_add(&glz_dictionary_list, &shared_dict->base);
} else {
shared_dict->refs++;
}
pthread_mutex_unlock(&glz_dictionary_list_lock);
return shared_dict;
}
static GlzSharedDictionary *red_restore_glz_dictionary(DisplayChannelClient *dcc,
uint8_t id,
GlzEncDictRestoreData *restore_data)
{
GlzSharedDictionary *shared_dict = NULL;
pthread_mutex_lock(&glz_dictionary_list_lock);
shared_dict = _red_find_glz_dictionary(dcc->common.base.client, id);
if (!shared_dict) {
shared_dict = red_create_restored_glz_dictionary(dcc, id, restore_data);
ring_add(&glz_dictionary_list, &shared_dict->base);
} else {
shared_dict->refs++;
}
pthread_mutex_unlock(&glz_dictionary_list_lock);
return shared_dict;
}
static void red_freeze_glz(DisplayChannelClient *dcc)
{
pthread_rwlock_wrlock(&dcc->glz_dict->encode_lock);
if (!dcc->glz_dict->migrate_freeze) {
dcc->glz_dict->migrate_freeze = TRUE;
}
pthread_rwlock_unlock(&dcc->glz_dict->encode_lock);
}
/* destroy encoder, and dictionary if no one uses it*/
static void red_release_glz(DisplayChannelClient *dcc)
{
GlzSharedDictionary *shared_dict;
red_display_client_clear_glz_drawables(dcc);
glz_encoder_destroy(dcc->glz);
dcc->glz = NULL;
if (!(shared_dict = dcc->glz_dict)) {
return;
}
dcc->glz_dict = NULL;
pthread_mutex_lock(&glz_dictionary_list_lock);
if (--shared_dict->refs) {
pthread_mutex_unlock(&glz_dictionary_list_lock);
return;
}
ring_remove(&shared_dict->base);
pthread_mutex_unlock(&glz_dictionary_list_lock);
glz_enc_dictionary_destroy(shared_dict->dict, &dcc->glz_data.usr);
free(shared_dict);
}
static PixmapCache *red_create_pixmap_cache(RedClient *client, uint8_t id, int64_t size)
{
PixmapCache *cache = spice_new0(PixmapCache, 1);
ring_item_init(&cache->base);
pthread_mutex_init(&cache->lock, NULL);
cache->id = id;
cache->refs = 1;
ring_init(&cache->lru);
cache->available = size;
cache->size = size;
cache->client = client;
return cache;
}
static PixmapCache *red_get_pixmap_cache(RedClient *client, uint8_t id, int64_t size)
{
PixmapCache *ret = NULL;
RingItem *now;
pthread_mutex_lock(&cache_lock);
now = &pixmap_cache_list;
while ((now = ring_next(&pixmap_cache_list, now))) {
PixmapCache *cache = (PixmapCache *)now;
if ((cache->client == client) && (cache->id == id)) {
ret = cache;
ret->refs++;
break;
}
}
if (!ret) {
ret = red_create_pixmap_cache(client, id, size);
ring_add(&pixmap_cache_list, &ret->base);
}
pthread_mutex_unlock(&cache_lock);
return ret;
}
static void red_release_pixmap_cache(DisplayChannelClient *dcc)
{
PixmapCache *cache;
if (!(cache = dcc->pixmap_cache)) {
return;
}
dcc->pixmap_cache = NULL;
pthread_mutex_lock(&cache_lock);
if (--cache->refs) {
pthread_mutex_unlock(&cache_lock);
return;
}
ring_remove(&cache->base);
pthread_mutex_unlock(&cache_lock);
pixmap_cache_destroy(cache);
free(cache);
}
static int display_channel_init_cache(DisplayChannelClient *dcc, SpiceMsgcDisplayInit *init_info)
{
spice_assert(!dcc->pixmap_cache);
return !!(dcc->pixmap_cache = red_get_pixmap_cache(dcc->common.base.client,
init_info->pixmap_cache_id,
init_info->pixmap_cache_size));
}
static int display_channel_init_glz_dictionary(DisplayChannelClient *dcc,
SpiceMsgcDisplayInit *init_info)
{
spice_assert(!dcc->glz_dict);
ring_init(&dcc->glz_drawables);
ring_init(&dcc->glz_drawables_inst_to_free);
pthread_mutex_init(&dcc->glz_drawables_inst_to_free_lock, NULL);
return !!(dcc->glz_dict = red_get_glz_dictionary(dcc,
init_info->glz_dictionary_id,
init_info->glz_dictionary_window_size));
}
static int display_channel_init(DisplayChannelClient *dcc, SpiceMsgcDisplayInit *init_info)
{
return (display_channel_init_cache(dcc, init_info) &&
display_channel_init_glz_dictionary(dcc, init_info));
}
static int display_channel_handle_migrate_glz_dictionary(DisplayChannelClient *dcc,
SpiceMigrateDataDisplay *migrate_info)
{
spice_assert(!dcc->glz_dict);
ring_init(&dcc->glz_drawables);
ring_init(&dcc->glz_drawables_inst_to_free);
pthread_mutex_init(&dcc->glz_drawables_inst_to_free_lock, NULL);
return !!(dcc->glz_dict = red_restore_glz_dictionary(dcc,
migrate_info->glz_dict_id,
&migrate_info->glz_dict_data));
}
static int display_channel_handle_migrate_mark(RedChannelClient *rcc)
{
DisplayChannel *display_channel = SPICE_CONTAINEROF(rcc->channel, DisplayChannel, common.base);
RedChannel *channel = &display_channel->common.base;
red_channel_pipes_add_type(channel, PIPE_ITEM_TYPE_MIGRATE_DATA);
return TRUE;
}
static uint64_t display_channel_handle_migrate_data_get_serial(
RedChannelClient *rcc, uint32_t size, void *message)
{
SpiceMigrateDataDisplay *migrate_data;
migrate_data = (SpiceMigrateDataDisplay *)((uint8_t *)message + sizeof(SpiceMigrateDataHeader));
return migrate_data->message_serial;
}
static int display_channel_client_restore_surface(DisplayChannelClient *dcc, uint32_t surface_id)
{
/* we don't process commands till we receive the migration data, thus,
* we should have not sent any surface to the client. */
if (dcc->surface_client_created[surface_id]) {
spice_warning("surface %u is already marked as client_created", surface_id);
return FALSE;
}
dcc->surface_client_created[surface_id] = TRUE;
return TRUE;
}
static int display_channel_client_restore_surfaces_lossless(DisplayChannelClient *dcc,
MigrateDisplaySurfacesAtClientLossless *mig_surfaces)
{
uint32_t i;
spice_debug(NULL);
for (i = 0; i < mig_surfaces->num_surfaces; i++) {
uint32_t surface_id = mig_surfaces->surfaces[i].id;
if (!display_channel_client_restore_surface(dcc, surface_id)) {
return FALSE;
}
}
return TRUE;
}
static int display_channel_client_restore_surfaces_lossy(DisplayChannelClient *dcc,
MigrateDisplaySurfacesAtClientLossy *mig_surfaces)
{
uint32_t i;
spice_debug(NULL);
for (i = 0; i < mig_surfaces->num_surfaces; i++) {
uint32_t surface_id = mig_surfaces->surfaces[i].id;
SpiceMigrateDataRect *mig_lossy_rect;
SpiceRect lossy_rect;
if (!display_channel_client_restore_surface(dcc, surface_id)) {
return FALSE;
}
spice_assert(dcc->surface_client_created[surface_id]);
mig_lossy_rect = &mig_surfaces->surfaces[i].lossy_rect;
lossy_rect.left = mig_lossy_rect->left;
lossy_rect.top = mig_lossy_rect->top;
lossy_rect.right = mig_lossy_rect->right;
lossy_rect.bottom = mig_lossy_rect->bottom;
region_init(&dcc->surface_client_lossy_region[surface_id]);
region_add(&dcc->surface_client_lossy_region[surface_id], &lossy_rect);
}
return TRUE;
}
static int display_channel_handle_migrate_data(RedChannelClient *rcc, uint32_t size,
void *message)
{
SpiceMigrateDataHeader *header;
SpiceMigrateDataDisplay *migrate_data;
DisplayChannel *display_channel = SPICE_CONTAINEROF(rcc->channel, DisplayChannel, common.base);
DisplayChannelClient *dcc = RCC_TO_DCC(rcc);
uint8_t *surfaces;
int surfaces_restored = FALSE;
int i;
spice_debug(NULL);
if (size < sizeof(*migrate_data) + sizeof(SpiceMigrateDataHeader)) {
spice_error("bad message size");
return FALSE;
}
header = (SpiceMigrateDataHeader *)message;
migrate_data = (SpiceMigrateDataDisplay *)(header + 1);
if (!migration_protocol_validate_header(header,
SPICE_MIGRATE_DATA_DISPLAY_MAGIC,
SPICE_MIGRATE_DATA_DISPLAY_VERSION)) {
spice_error("bad header");
return FALSE;
}
/* size is set to -1 in order to keep the cache frozen until the original
* channel client that froze the cache on the src size receives the migrate
* data and unfreezes the cache by setting its size > 0 and by triggering
* pixmap_cache_reset */
dcc->pixmap_cache = red_get_pixmap_cache(dcc->common.base.client,
migrate_data->pixmap_cache_id, -1);
if (!dcc->pixmap_cache) {
return FALSE;
}
pthread_mutex_lock(&dcc->pixmap_cache->lock);
for (i = 0; i < MAX_CACHE_CLIENTS; i++) {
dcc->pixmap_cache->sync[i] = MAX(dcc->pixmap_cache->sync[i],
migrate_data->pixmap_cache_clients[i]);
}
pthread_mutex_unlock(&dcc->pixmap_cache->lock);
if (migrate_data->pixmap_cache_freezer) {
/* activating the cache. The cache will start to be active after
* pixmap_cache_reset is called, when handling PIPE_ITEM_TYPE_PIXMAP_RESET */
dcc->pixmap_cache->size = migrate_data->pixmap_cache_size;
red_channel_client_pipe_add_type(rcc,
PIPE_ITEM_TYPE_PIXMAP_RESET);
}
if (display_channel_handle_migrate_glz_dictionary(dcc, migrate_data)) {
dcc->glz = glz_encoder_create(dcc->common.id,
dcc->glz_dict->dict, &dcc->glz_data.usr);
if (!dcc->glz) {
spice_critical("create global lz failed");
}
} else {
spice_critical("restoring global lz dictionary failed");
}
dcc->common.is_low_bandwidth = migrate_data->low_bandwidth_setting;
if (migrate_data->low_bandwidth_setting) {
red_channel_client_ack_set_client_window(rcc, WIDE_CLIENT_ACK_WINDOW);
if (dcc->common.worker->jpeg_state == SPICE_WAN_COMPRESSION_AUTO) {
display_channel->enable_jpeg = TRUE;
}
if (dcc->common.worker->zlib_glz_state == SPICE_WAN_COMPRESSION_AUTO) {
display_channel->enable_zlib_glz_wrap = TRUE;
}
}
surfaces = (uint8_t *)message + migrate_data->surfaces_at_client_ptr;
if (display_channel->enable_jpeg) {
surfaces_restored = display_channel_client_restore_surfaces_lossy(dcc,
(MigrateDisplaySurfacesAtClientLossy *)surfaces);
} else {
surfaces_restored = display_channel_client_restore_surfaces_lossless(dcc,
(MigrateDisplaySurfacesAtClientLossless*)surfaces);
}
if (!surfaces_restored) {
return FALSE;
}
red_channel_client_pipe_add_type(rcc, PIPE_ITEM_TYPE_INVAL_PALLET_CACHE);
/* enable sending messages */
red_channel_client_ack_zero_messages_window(rcc);
return TRUE;
}
static int display_channel_handle_stream_report(DisplayChannelClient *dcc,
SpiceMsgcDisplayStreamReport *stream_report)
{
StreamAgent *stream_agent;
if (stream_report->stream_id >= NUM_STREAMS) {
spice_warning("stream_report: invalid stream id %u", stream_report->stream_id);
return FALSE;
}
stream_agent = &dcc->stream_agents[stream_report->stream_id];
if (!stream_agent->mjpeg_encoder) {
spice_info("stream_report: no encoder for stream id %u."
"Probably the stream has been destroyed", stream_report->stream_id);
return TRUE;
}
if (stream_report->unique_id != stream_agent->report_id) {
spice_warning("local reoprt-id (%u) != msg report-id (%u)",
stream_agent->report_id, stream_report->unique_id);
return TRUE;
}
mjpeg_encoder_client_stream_report(stream_agent->mjpeg_encoder,
stream_report->num_frames,
stream_report->num_drops,
stream_report->start_frame_mm_time,
stream_report->end_frame_mm_time,
stream_report->last_frame_delay,
stream_report->audio_delay);
return TRUE;
}
static int display_channel_handle_message(RedChannelClient *rcc, uint32_t size, uint16_t type,
void *message)
{
DisplayChannelClient *dcc = RCC_TO_DCC(rcc);
switch (type) {
case SPICE_MSGC_DISPLAY_INIT:
if (!dcc->expect_init) {
spice_warning("unexpected SPICE_MSGC_DISPLAY_INIT");
return FALSE;
}
dcc->expect_init = FALSE;
return display_channel_init(dcc, (SpiceMsgcDisplayInit *)message);
case SPICE_MSGC_DISPLAY_STREAM_REPORT:
return display_channel_handle_stream_report(dcc,
(SpiceMsgcDisplayStreamReport *)message);
default:
return red_channel_client_handle_message(rcc, size, type, message);
}
}
static int common_channel_config_socket(RedChannelClient *rcc)
{
RedClient *client = red_channel_client_get_client(rcc);
MainChannelClient *mcc = red_client_get_main(client);
RedsStream *stream = red_channel_client_get_stream(rcc);
CommonChannelClient *ccc = SPICE_CONTAINEROF(rcc, CommonChannelClient, base);
int flags;
int delay_val;
if ((flags = fcntl(stream->socket, F_GETFL)) == -1) {
spice_warning("accept failed, %s", strerror(errno));
return FALSE;
}
if (fcntl(stream->socket, F_SETFL, flags | O_NONBLOCK) == -1) {
spice_warning("accept failed, %s", strerror(errno));
return FALSE;
}
// TODO - this should be dynamic, not one time at channel creation
ccc->is_low_bandwidth = main_channel_client_is_low_bandwidth(mcc);
delay_val = ccc->is_low_bandwidth ? 0 : 1;
/* FIXME: Using Nagle's Algorithm can lead to apparent delays, depending
* on the delayed ack timeout on the other side.
* Instead of using Nagle's, we need to implement message buffering on
* the application level.
* see: http://www.stuartcheshire.org/papers/NagleDelayedAck/
*/
if (setsockopt(stream->socket, IPPROTO_TCP, TCP_NODELAY, &delay_val,
sizeof(delay_val)) == -1) {
if (errno != ENOTSUP) {
spice_warning("setsockopt failed, %s", strerror(errno));
}
}
return TRUE;
}
static void worker_watch_update_mask(SpiceWatch *watch, int event_mask)
{
struct RedWorker *worker;
int i;
if (!watch) {
return;
}
worker = watch->worker;
i = watch - worker->watches;
worker->poll_fds[i].events = 0;
if (event_mask & SPICE_WATCH_EVENT_READ) {
worker->poll_fds[i].events |= POLLIN;
}
if (event_mask & SPICE_WATCH_EVENT_WRITE) {
worker->poll_fds[i].events |= POLLOUT;
}
}
static SpiceWatch *worker_watch_add(int fd, int event_mask, SpiceWatchFunc func, void *opaque)
{
/* Since we are a channel core implementation, we always get called from
red_channel_client_create(), so opaque always is our rcc */
RedChannelClient *rcc = opaque;
struct RedWorker *worker;
int i;
/* Since we are called from red_channel_client_create()
CommonChannelClient->worker has not been set yet! */
worker = SPICE_CONTAINEROF(rcc->channel, CommonChannel, base)->worker;
/* Search for a free slot in our poll_fds & watches arrays */
for (i = 0; i < MAX_EVENT_SOURCES; i++) {
if (worker->poll_fds[i].fd == -1) {
break;
}
}
if (i == MAX_EVENT_SOURCES) {
spice_warning("could not add a watch for channel type %u id %u",
rcc->channel->type, rcc->channel->id);
return NULL;
}
worker->poll_fds[i].fd = fd;
worker->watches[i].worker = worker;
worker->watches[i].watch_func = func;
worker->watches[i].watch_func_opaque = opaque;
worker_watch_update_mask(&worker->watches[i], event_mask);
return &worker->watches[i];
}
static void worker_watch_remove(SpiceWatch *watch)
{
if (!watch) {
return;
}
/* Note we don't touch the poll_fd here, to avoid the
poll_fds/watches table entry getting re-used in the same
red_worker_main loop over the fds as it is removed.
This is done because re-using it while events were pending on
the fd previously occupying the slot would lead to incorrectly
calling the watch_func for the new fd. */
memset(watch, 0, sizeof(SpiceWatch));
}
SpiceCoreInterface worker_core = {
.timer_add = spice_timer_queue_add,
.timer_start = spice_timer_set,
.timer_cancel = spice_timer_cancel,
.timer_remove = spice_timer_remove,
.watch_update_mask = worker_watch_update_mask,
.watch_add = worker_watch_add,
.watch_remove = worker_watch_remove,
};
static CommonChannelClient *common_channel_client_create(int size,
CommonChannel *common,
RedClient *client,
RedsStream *stream,
int mig_target,
int monitor_latency,
uint32_t *common_caps,
int num_common_caps,
uint32_t *caps,
int num_caps)
{
RedChannelClient *rcc =
red_channel_client_create(size, &common->base, client, stream, monitor_latency,
num_common_caps, common_caps, num_caps, caps);
if (!rcc) {
return NULL;
}
CommonChannelClient *common_cc = (CommonChannelClient*)rcc;
common_cc->worker = common->worker;
common_cc->id = common->worker->id;
common->during_target_migrate = mig_target;
// TODO: move wide/narrow ack setting to red_channel.
red_channel_client_ack_set_client_window(rcc,
common_cc->is_low_bandwidth ?
WIDE_CLIENT_ACK_WINDOW : NARROW_CLIENT_ACK_WINDOW);
return common_cc;
}
DisplayChannelClient *display_channel_client_create(CommonChannel *common,
RedClient *client, RedsStream *stream,
int mig_target,
uint32_t *common_caps, int num_common_caps,
uint32_t *caps, int num_caps)
{
DisplayChannelClient *dcc =
(DisplayChannelClient*)common_channel_client_create(
sizeof(DisplayChannelClient), common, client, stream,
mig_target,
TRUE,
common_caps, num_common_caps,
caps, num_caps);
if (!dcc) {
return NULL;
}
ring_init(&dcc->palette_cache_lru);
dcc->palette_cache_available = CLIENT_PALETTE_CACHE_SIZE;
return dcc;
}
CursorChannelClient *cursor_channel_create_rcc(CommonChannel *common,
RedClient *client, RedsStream *stream,
int mig_target,
uint32_t *common_caps, int num_common_caps,
uint32_t *caps, int num_caps)
{
CursorChannelClient *ccc =
(CursorChannelClient*)common_channel_client_create(
sizeof(CursorChannelClient), common, client, stream,
mig_target,
FALSE,
common_caps,
num_common_caps,
caps,
num_caps);
if (!ccc) {
return NULL;
}
ring_init(&ccc->cursor_cache_lru);
ccc->cursor_cache_available = CLIENT_CURSOR_CACHE_SIZE;
return ccc;
}
static RedChannel *__new_channel(RedWorker *worker, int size, uint32_t channel_type,
int migration_flags,
channel_disconnect_proc on_disconnect,
channel_send_pipe_item_proc send_item,
channel_hold_pipe_item_proc hold_item,
channel_release_pipe_item_proc release_item,
channel_handle_parsed_proc handle_parsed,
channel_handle_migrate_flush_mark_proc handle_migrate_flush_mark,
channel_handle_migrate_data_proc handle_migrate_data,
channel_handle_migrate_data_get_serial_proc migrate_get_serial)
{
RedChannel *channel = NULL;
CommonChannel *common;
ChannelCbs channel_cbs = { NULL, };
channel_cbs.config_socket = common_channel_config_socket;
channel_cbs.on_disconnect = on_disconnect;
channel_cbs.send_item = send_item;
channel_cbs.hold_item = hold_item;
channel_cbs.release_item = release_item;
channel_cbs.alloc_recv_buf = common_alloc_recv_buf;
channel_cbs.release_recv_buf = common_release_recv_buf;
channel_cbs.handle_migrate_flush_mark = handle_migrate_flush_mark;
channel_cbs.handle_migrate_data = handle_migrate_data;
channel_cbs.handle_migrate_data_get_serial = migrate_get_serial;
channel = red_channel_create_parser(size, &worker_core,
channel_type, worker->id,
TRUE /* handle_acks */,
spice_get_client_channel_parser(channel_type, NULL),
handle_parsed,
&channel_cbs,
migration_flags);
common = (CommonChannel *)channel;
if (!channel) {
goto error;
}
common->worker = worker;
return channel;
error:
free(channel);
return NULL;
}
static void display_channel_hold_pipe_item(RedChannelClient *rcc, PipeItem *item)
{
spice_assert(item);
switch (item->type) {
case PIPE_ITEM_TYPE_DRAW:
ref_drawable_pipe_item(SPICE_CONTAINEROF(item, DrawablePipeItem, dpi_pipe_item));
break;
case PIPE_ITEM_TYPE_STREAM_CLIP:
((StreamClipItem *)item)->refs++;
break;
case PIPE_ITEM_TYPE_UPGRADE:
((UpgradeItem *)item)->refs++;
break;
case PIPE_ITEM_TYPE_IMAGE:
((ImageItem *)item)->refs++;
break;
default:
spice_critical("invalid item type");
}
}
static void display_channel_client_release_item_after_push(DisplayChannelClient *dcc,
PipeItem *item)
{
RedWorker *worker = dcc->common.worker;
switch (item->type) {
case PIPE_ITEM_TYPE_DRAW:
put_drawable_pipe_item(SPICE_CONTAINEROF(item, DrawablePipeItem, dpi_pipe_item));
break;
case PIPE_ITEM_TYPE_STREAM_CLIP:
red_display_release_stream_clip(worker, (StreamClipItem *)item);
break;
case PIPE_ITEM_TYPE_UPGRADE:
release_upgrade_item(worker, (UpgradeItem *)item);
break;
case PIPE_ITEM_TYPE_IMAGE:
release_image_item((ImageItem *)item);
break;
case PIPE_ITEM_TYPE_VERB:
free(item);
break;
case PIPE_ITEM_TYPE_MONITORS_CONFIG: {
MonitorsConfigItem *monconf_item = SPICE_CONTAINEROF(item,
MonitorsConfigItem, pipe_item);
monitors_config_decref(monconf_item->monitors_config);
free(item);
break;
}
default:
spice_critical("invalid item type");
}
}
// TODO: share code between before/after_push since most of the items need the same
// release
static void display_channel_client_release_item_before_push(DisplayChannelClient *dcc,
PipeItem *item)
{
RedWorker *worker = dcc->common.worker;
switch (item->type) {
case PIPE_ITEM_TYPE_DRAW: {
DrawablePipeItem *dpi = SPICE_CONTAINEROF(item, DrawablePipeItem, dpi_pipe_item);
ring_remove(&dpi->base);
put_drawable_pipe_item(dpi);
break;
}
case PIPE_ITEM_TYPE_STREAM_CREATE: {
StreamAgent *agent = SPICE_CONTAINEROF(item, StreamAgent, create_item);
red_display_release_stream(worker, agent);
break;
}
case PIPE_ITEM_TYPE_STREAM_CLIP:
red_display_release_stream_clip(worker, (StreamClipItem *)item);
break;
case PIPE_ITEM_TYPE_STREAM_DESTROY: {
StreamAgent *agent = SPICE_CONTAINEROF(item, StreamAgent, destroy_item);
red_display_release_stream(worker, agent);
break;
}
case PIPE_ITEM_TYPE_UPGRADE:
release_upgrade_item(worker, (UpgradeItem *)item);
break;
case PIPE_ITEM_TYPE_IMAGE:
release_image_item((ImageItem *)item);
break;
case PIPE_ITEM_TYPE_CREATE_SURFACE: {
SurfaceCreateItem *surface_create = SPICE_CONTAINEROF(item, SurfaceCreateItem,
pipe_item);
free(surface_create);
break;
}
case PIPE_ITEM_TYPE_DESTROY_SURFACE: {
SurfaceDestroyItem *surface_destroy = SPICE_CONTAINEROF(item, SurfaceDestroyItem,
pipe_item);
free(surface_destroy);
break;
}
case PIPE_ITEM_TYPE_MONITORS_CONFIG: {
MonitorsConfigItem *monconf_item = SPICE_CONTAINEROF(item,
MonitorsConfigItem, pipe_item);
monitors_config_decref(monconf_item->monitors_config);
free(item);
break;
}
case PIPE_ITEM_TYPE_INVAL_ONE:
case PIPE_ITEM_TYPE_VERB:
case PIPE_ITEM_TYPE_MIGRATE_DATA:
case PIPE_ITEM_TYPE_PIXMAP_SYNC:
case PIPE_ITEM_TYPE_PIXMAP_RESET:
case PIPE_ITEM_TYPE_INVAL_PALLET_CACHE:
case PIPE_ITEM_TYPE_STREAM_ACTIVATE_REPORT:
free(item);
break;
default:
spice_critical("invalid item type");
}
}
static void display_channel_release_item(RedChannelClient *rcc, PipeItem *item, int item_pushed)
{
DisplayChannelClient *dcc = RCC_TO_DCC(rcc);
spice_assert(item);
if (item_pushed) {
display_channel_client_release_item_after_push(dcc, item);
} else {
spice_debug("not pushed (%d)", item->type);
display_channel_client_release_item_before_push(dcc, item);
}
}
static void display_channel_create(RedWorker *worker, int migrate)
{
DisplayChannel *display_channel;
if (worker->display_channel) {
return;
}
spice_info("create display channel");
if (!(worker->display_channel = (DisplayChannel *)__new_channel(
worker, sizeof(*display_channel),
SPICE_CHANNEL_DISPLAY,
SPICE_MIGRATE_NEED_FLUSH | SPICE_MIGRATE_NEED_DATA_TRANSFER,
display_channel_client_on_disconnect,
display_channel_send_item,
display_channel_hold_pipe_item,
display_channel_release_item,
display_channel_handle_message,
display_channel_handle_migrate_mark,
display_channel_handle_migrate_data,
display_channel_handle_migrate_data_get_serial
))) {
spice_warning("failed to create display channel");
return;
}
display_channel = worker->display_channel;
#ifdef RED_STATISTICS
display_channel->stat = stat_add_node(worker->stat, "display_channel", TRUE);
display_channel->common.base.out_bytes_counter = stat_add_counter(display_channel->stat,
"out_bytes", TRUE);
display_channel->cache_hits_counter = stat_add_counter(display_channel->stat,
"cache_hits", TRUE);
display_channel->add_to_cache_counter = stat_add_counter(display_channel->stat,
"add_to_cache", TRUE);
display_channel->non_cache_counter = stat_add_counter(display_channel->stat,
"non_cache", TRUE);
#endif
stat_compress_init(&display_channel->lz_stat, lz_stat_name);
stat_compress_init(&display_channel->glz_stat, glz_stat_name);
stat_compress_init(&display_channel->quic_stat, quic_stat_name);
stat_compress_init(&display_channel->jpeg_stat, jpeg_stat_name);
stat_compress_init(&display_channel->zlib_glz_stat, zlib_stat_name);
stat_compress_init(&display_channel->jpeg_alpha_stat, jpeg_alpha_stat_name);
}
static void guest_set_client_capabilities(RedWorker *worker)
{
int i;
DisplayChannelClient *dcc;
RedChannelClient *rcc;
RingItem *link, *next;
uint8_t caps[58] = { 0 };
int caps_available[] = {
SPICE_DISPLAY_CAP_SIZED_STREAM,
SPICE_DISPLAY_CAP_MONITORS_CONFIG,
SPICE_DISPLAY_CAP_COMPOSITE,
SPICE_DISPLAY_CAP_A8_SURFACE,
};
if (worker->qxl->st->qif->base.major_version < 3 ||
(worker->qxl->st->qif->base.major_version == 3 &&
worker->qxl->st->qif->base.minor_version < 2) ||
!worker->qxl->st->qif->set_client_capabilities) {
return;
}
#define SET_CAP(a,c) \
((a)[(c) / 8] |= (1 << ((c) % 8)))
#define CLEAR_CAP(a,c) \
((a)[(c) / 8] &= ~(1 << ((c) % 8)))
if (!worker->running) {
worker->set_client_capabilities_pending = 1;
return;
}
if ((worker->display_channel == NULL) ||
(worker->display_channel->common.base.clients_num == 0)) {
worker->qxl->st->qif->set_client_capabilities(worker->qxl, FALSE, caps);
} else {
// Take least common denominator
for (i = 0 ; i < sizeof(caps_available) / sizeof(caps_available[0]); ++i) {
SET_CAP(caps, caps_available[i]);
}
DCC_FOREACH_SAFE(link, next, dcc, &worker->display_channel->common.base) {
rcc = (RedChannelClient *)dcc;
for (i = 0 ; i < sizeof(caps_available) / sizeof(caps_available[0]); ++i) {
if (!red_channel_client_test_remote_cap(rcc, caps_available[i]))
CLEAR_CAP(caps, caps_available[i]);
}
}
worker->qxl->st->qif->set_client_capabilities(worker->qxl, TRUE, caps);
}
worker->set_client_capabilities_pending = 0;
}
static void handle_new_display_channel(RedWorker *worker, RedClient *client, RedsStream *stream,
int migrate,
uint32_t *common_caps, int num_common_caps,
uint32_t *caps, int num_caps)
{
DisplayChannel *display_channel;
DisplayChannelClient *dcc;
size_t stream_buf_size;
if (!worker->display_channel) {
spice_warning("Display channel was not created");
return;
}
display_channel = worker->display_channel;
spice_info("add display channel client");
dcc = display_channel_client_create(&display_channel->common, client, stream,
migrate,
common_caps, num_common_caps,
caps, num_caps);
if (!dcc) {
return;
}
spice_info("New display (client %p) dcc %p stream %p", client, dcc, stream);
stream_buf_size = 32*1024;
dcc->send_data.stream_outbuf = spice_malloc(stream_buf_size);
dcc->send_data.stream_outbuf_size = stream_buf_size;
red_display_init_glz_data(dcc);
dcc->send_data.free_list.res =
spice_malloc(sizeof(SpiceResourceList) +
DISPLAY_FREE_LIST_DEFAULT_SIZE * sizeof(SpiceResourceID));
dcc->send_data.free_list.res_size = DISPLAY_FREE_LIST_DEFAULT_SIZE;
if (worker->jpeg_state == SPICE_WAN_COMPRESSION_AUTO) {
display_channel->enable_jpeg = dcc->common.is_low_bandwidth;
} else {
display_channel->enable_jpeg = (worker->jpeg_state == SPICE_WAN_COMPRESSION_ALWAYS);
}
// todo: tune quality according to bandwidth
display_channel->jpeg_quality = 85;
if (worker->zlib_glz_state == SPICE_WAN_COMPRESSION_AUTO) {
display_channel->enable_zlib_glz_wrap = dcc->common.is_low_bandwidth;
} else {
display_channel->enable_zlib_glz_wrap = (worker->zlib_glz_state ==
SPICE_WAN_COMPRESSION_ALWAYS);
}
spice_info("jpeg %s", display_channel->enable_jpeg ? "enabled" : "disabled");
spice_info("zlib-over-glz %s", display_channel->enable_zlib_glz_wrap ? "enabled" : "disabled");
guest_set_client_capabilities(worker);
// todo: tune level according to bandwidth
display_channel->zlib_level = ZLIB_DEFAULT_COMPRESSION_LEVEL;
red_display_client_init_streams(dcc);
on_new_display_channel_client(dcc);
}
static void cursor_channel_client_on_disconnect(RedChannelClient *rcc)
{
if (!rcc) {
return;
}
red_reset_cursor_cache(rcc);
}
static void red_disconnect_cursor(RedChannel *channel)
{
CommonChannel *common;
if (!channel || !red_channel_is_connected(channel)) {
return;
}
common = SPICE_CONTAINEROF(channel, CommonChannel, base);
spice_assert(channel == (RedChannel *)common->worker->cursor_channel);
common->worker->cursor_channel = NULL;
red_channel_apply_clients(channel, red_reset_cursor_cache);
red_channel_disconnect(channel);
}
static void red_migrate_cursor(RedWorker *worker, RedChannelClient *rcc)
{
if (red_channel_client_is_connected(rcc)) {
red_channel_client_pipe_add_type(rcc,
PIPE_ITEM_TYPE_INVAL_CURSOR_CACHE);
red_channel_client_default_migrate(rcc);
}
}
static void on_new_cursor_channel(RedWorker *worker, RedChannelClient *rcc)
{
CursorChannel *channel = worker->cursor_channel;
spice_assert(channel);
red_channel_client_ack_zero_messages_window(rcc);
red_channel_client_push_set_ack(rcc);
// TODO: why do we check for context.canvas? defer this to after display cc is connected
// and test it's canvas? this is just a test to see if there is an active renderer?
if (worker->surfaces[0].context.canvas && !channel->common.during_target_migrate) {
red_channel_client_pipe_add_type(rcc, PIPE_ITEM_TYPE_CURSOR_INIT);
}
}
static void cursor_channel_hold_pipe_item(RedChannelClient *rcc, PipeItem *item)
{
CursorPipeItem *cursor_pipe_item;
spice_assert(item);
cursor_pipe_item = SPICE_CONTAINEROF(item, CursorPipeItem, base);
ref_cursor_pipe_item(cursor_pipe_item);
}
// TODO: share code between before/after_push since most of the items need the same
// release
static void cursor_channel_client_release_item_before_push(CursorChannelClient *ccc,
PipeItem *item)
{
switch (item->type) {
case PIPE_ITEM_TYPE_CURSOR: {
CursorPipeItem *cursor_pipe_item = SPICE_CONTAINEROF(item, CursorPipeItem, base);
put_cursor_pipe_item(ccc, cursor_pipe_item);
break;
}
case PIPE_ITEM_TYPE_INVAL_ONE:
case PIPE_ITEM_TYPE_VERB:
case PIPE_ITEM_TYPE_CURSOR_INIT:
case PIPE_ITEM_TYPE_INVAL_CURSOR_CACHE:
free(item);
break;
default:
spice_error("invalid pipe item type");
}
}
static void cursor_channel_client_release_item_after_push(CursorChannelClient *ccc,
PipeItem *item)
{
switch (item->type) {
case PIPE_ITEM_TYPE_CURSOR: {
CursorPipeItem *cursor_pipe_item = SPICE_CONTAINEROF(item, CursorPipeItem, base);
put_cursor_pipe_item(ccc, cursor_pipe_item);
break;
}
default:
spice_critical("invalid item type");
}
}
static void cursor_channel_release_item(RedChannelClient *rcc, PipeItem *item, int item_pushed)
{
CursorChannelClient *ccc = RCC_TO_CCC(rcc);
spice_assert(item);
if (item_pushed) {
cursor_channel_client_release_item_after_push(ccc, item);
} else {
spice_debug("not pushed (%d)", item->type);
cursor_channel_client_release_item_before_push(ccc, item);
}
}
static void cursor_channel_create(RedWorker *worker, int migrate)
{
if (worker->cursor_channel != NULL) {
return;
}
spice_info("create cursor channel");
worker->cursor_channel = (CursorChannel *)__new_channel(
worker, sizeof(*worker->cursor_channel),
SPICE_CHANNEL_CURSOR,
0,
cursor_channel_client_on_disconnect,
cursor_channel_send_item,
cursor_channel_hold_pipe_item,
cursor_channel_release_item,
red_channel_client_handle_message,
NULL,
NULL,
NULL);
}
static void red_connect_cursor(RedWorker *worker, RedClient *client, RedsStream *stream,
int migrate,
uint32_t *common_caps, int num_common_caps,
uint32_t *caps, int num_caps)
{
CursorChannel *channel;
CursorChannelClient *ccc;
if (worker->cursor_channel == NULL) {
spice_warning("cursor channel was not created");
return;
}
channel = worker->cursor_channel;
spice_info("add cursor channel client");
ccc = cursor_channel_create_rcc(&channel->common, client, stream,
migrate,
common_caps, num_common_caps,
caps, num_caps);
if (!ccc) {
return;
}
#ifdef RED_STATISTICS
channel->stat = stat_add_node(worker->stat, "cursor_channel", TRUE);
channel->common.base.out_bytes_counter = stat_add_counter(channel->stat, "out_bytes", TRUE);
#endif
on_new_cursor_channel(worker, &ccc->common.base);
}
typedef struct __attribute__ ((__packed__)) CursorData {
uint32_t visible;
SpicePoint16 position;
uint16_t trail_length;
uint16_t trail_frequency;
uint32_t data_size;
SpiceCursor _cursor;
} CursorData;
static void red_wait_outgoing_item(RedChannelClient *rcc)
{
uint64_t end_time;
int blocked;
if (!red_channel_client_blocked(rcc)) {
return;
}
end_time = red_now() + DETACH_TIMEOUT;
spice_info("blocked");
do {
usleep(DETACH_SLEEP_DURATION);
red_channel_client_receive(rcc);
red_channel_client_send(rcc);
} while ((blocked = red_channel_client_blocked(rcc)) && red_now() < end_time);
if (blocked) {
spice_warning("timeout");
// TODO - shutting down the socket but we still need to trigger
// disconnection. Right now we wait for main channel to error for that.
red_channel_client_shutdown(rcc);
} else {
spice_assert(red_channel_client_no_item_being_sent(rcc));
}
}
static void rcc_shutdown_if_pending_send(RedChannelClient *rcc)
{
if (red_channel_client_blocked(rcc) || rcc->pipe_size > 0) {
red_channel_client_shutdown(rcc);
} else {
spice_assert(red_channel_client_no_item_being_sent(rcc));
}
}
static void red_wait_all_sent(RedChannel *channel)
{
uint64_t end_time;
uint32_t max_pipe_size;
int blocked = FALSE;
end_time = red_now() + DETACH_TIMEOUT;
red_channel_push(channel);
while (((max_pipe_size = red_channel_max_pipe_size(channel)) ||
(blocked = red_channel_any_blocked(channel))) &&
red_now() < end_time) {
spice_debug("pipe-size %u blocked %d", max_pipe_size, blocked);
usleep(DETACH_SLEEP_DURATION);
red_channel_receive(channel);
red_channel_send(channel);
red_channel_push(channel);
}
if (max_pipe_size || blocked) {
spice_printerr("timeout: pending out messages exist (pipe-size %u, blocked %d)",
max_pipe_size, blocked);
red_channel_apply_clients(channel, rcc_shutdown_if_pending_send);
} else {
spice_assert(red_channel_no_item_being_sent(channel));
}
}
/* TODO: more evil sync stuff. anything with the word wait in it's name. */
static void red_wait_pipe_item_sent(RedChannelClient *rcc, PipeItem *item)
{
DrawablePipeItem *dpi;
uint64_t end_time;
int item_in_pipe;
spice_info(NULL);
dpi = SPICE_CONTAINEROF(item, DrawablePipeItem, dpi_pipe_item);
ref_drawable_pipe_item(dpi);
end_time = red_now() + CHANNEL_PUSH_TIMEOUT;
if (red_channel_client_blocked(rcc)) {
red_channel_client_receive(rcc);
red_channel_client_send(rcc);
}
red_channel_client_push(rcc);
while((item_in_pipe = ring_item_is_linked(&item->link)) && (red_now() < end_time)) {
usleep(CHANNEL_PUSH_SLEEP_DURATION);
red_channel_client_receive(rcc);
red_channel_client_send(rcc);
red_channel_client_push(rcc);
}
if (item_in_pipe) {
spice_warning("timeout");
red_channel_client_disconnect(rcc);
} else {
red_wait_outgoing_item(rcc);
}
put_drawable_pipe_item(dpi);
}
static void surface_dirty_region_to_rects(RedSurface *surface,
QXLRect *qxl_dirty_rects,
uint32_t num_dirty_rects,
int clear_dirty_region)
{
QRegion *surface_dirty_region;
SpiceRect *dirty_rects;
int i;
surface_dirty_region = &surface->draw_dirty_region;
dirty_rects = spice_new0(SpiceRect, num_dirty_rects);
region_ret_rects(surface_dirty_region, dirty_rects, num_dirty_rects);
if (clear_dirty_region) {
region_clear(surface_dirty_region);
}
for (i = 0; i < num_dirty_rects; i++) {
qxl_dirty_rects[i].top = dirty_rects[i].top;
qxl_dirty_rects[i].left = dirty_rects[i].left;
qxl_dirty_rects[i].bottom = dirty_rects[i].bottom;
qxl_dirty_rects[i].right = dirty_rects[i].right;
}
free(dirty_rects);
}
void handle_dev_update_async(void *opaque, void *payload)
{
RedWorker *worker = opaque;
RedWorkerMessageUpdateAsync *msg = payload;
SpiceRect rect;
QXLRect *qxl_dirty_rects;
uint32_t num_dirty_rects;
RedSurface *surface;
uint32_t surface_id = msg->surface_id;
QXLRect qxl_area = msg->qxl_area;
uint32_t clear_dirty_region = msg->clear_dirty_region;
red_get_rect_ptr(&rect, &qxl_area);
flush_display_commands(worker);
spice_assert(worker->running);
VALIDATE_SURFACE_RET(worker, surface_id);
red_update_area(worker, &rect, surface_id);
if (!worker->qxl->st->qif->update_area_complete) {
return;
}
surface = &worker->surfaces[surface_id];
num_dirty_rects = pixman_region32_n_rects(&surface->draw_dirty_region);
if (num_dirty_rects == 0) {
return;
}
qxl_dirty_rects = spice_new0(QXLRect, num_dirty_rects);
surface_dirty_region_to_rects(surface, qxl_dirty_rects, num_dirty_rects,
clear_dirty_region);
worker->qxl->st->qif->update_area_complete(worker->qxl, surface_id,
qxl_dirty_rects, num_dirty_rects);
free(qxl_dirty_rects);
}
void handle_dev_update(void *opaque, void *payload)
{
RedWorker *worker = opaque;
RedWorkerMessageUpdate *msg = payload;
SpiceRect *rect = spice_new0(SpiceRect, 1);
RedSurface *surface;
uint32_t surface_id = msg->surface_id;
const QXLRect *qxl_area = msg->qxl_area;
uint32_t num_dirty_rects = msg->num_dirty_rects;
QXLRect *qxl_dirty_rects = msg->qxl_dirty_rects;
uint32_t clear_dirty_region = msg->clear_dirty_region;
surface = &worker->surfaces[surface_id];
red_get_rect_ptr(rect, qxl_area);
flush_display_commands(worker);
spice_assert(worker->running);
if (validate_surface(worker, surface_id)) {
red_update_area(worker, rect, surface_id);
} else {
rendering_incorrect(__func__);
}
free(rect);
surface_dirty_region_to_rects(surface, qxl_dirty_rects, num_dirty_rects,
clear_dirty_region);
}
static void dev_add_memslot(RedWorker *worker, QXLDevMemSlot mem_slot)
{
red_memslot_info_add_slot(&worker->mem_slots, mem_slot.slot_group_id, mem_slot.slot_id,
mem_slot.addr_delta, mem_slot.virt_start, mem_slot.virt_end,
mem_slot.generation);
}
void handle_dev_add_memslot(void *opaque, void *payload)
{
RedWorker *worker = opaque;
RedWorkerMessageAddMemslot *msg = payload;
QXLDevMemSlot mem_slot = msg->mem_slot;
red_memslot_info_add_slot(&worker->mem_slots, mem_slot.slot_group_id, mem_slot.slot_id,
mem_slot.addr_delta, mem_slot.virt_start, mem_slot.virt_end,
mem_slot.generation);
}
void handle_dev_del_memslot(void *opaque, void *payload)
{
RedWorker *worker = opaque;
RedWorkerMessageDelMemslot *msg = payload;
uint32_t slot_id = msg->slot_id;
uint32_t slot_group_id = msg->slot_group_id;
red_memslot_info_del_slot(&worker->mem_slots, slot_group_id, slot_id);
}
/* TODO: destroy_surface_wait, dev_destroy_surface_wait - confusing. one asserts
* surface_id == 0, maybe move the assert upward and merge the two functions? */
static inline void destroy_surface_wait(RedWorker *worker, int surface_id)
{
if (!worker->surfaces[surface_id].context.canvas) {
return;
}
red_handle_depends_on_target_surface(worker, surface_id);
/* note that red_handle_depends_on_target_surface must be called before red_current_clear.
otherwise "current" will hold items that other drawables may depend on, and then
red_current_clear will remove them from the pipe. */
red_current_clear(worker, surface_id);
red_clear_surface_drawables_from_pipes(worker, surface_id, TRUE, TRUE);
}
static void dev_destroy_surface_wait(RedWorker *worker, uint32_t surface_id)
{
spice_assert(surface_id == 0);
flush_all_qxl_commands(worker);
if (worker->surfaces[0].context.canvas) {
destroy_surface_wait(worker, 0);
}
}
void handle_dev_destroy_surface_wait(void *opaque, void *payload)
{
RedWorkerMessageDestroySurfaceWait *msg = payload;
RedWorker *worker = opaque;
dev_destroy_surface_wait(worker, msg->surface_id);
}
static inline void red_cursor_reset(RedWorker *worker)
{
if (worker->cursor) {
red_release_cursor(worker, worker->cursor);
worker->cursor = NULL;
}
worker->cursor_visible = TRUE;
worker->cursor_position.x = worker->cursor_position.y = 0;
worker->cursor_trail_length = worker->cursor_trail_frequency = 0;
if (cursor_is_connected(worker)) {
red_channel_pipes_add_type(&worker->cursor_channel->common.base,
PIPE_ITEM_TYPE_INVAL_CURSOR_CACHE);
if (!worker->cursor_channel->common.during_target_migrate) {
red_pipes_add_verb(&worker->cursor_channel->common.base, SPICE_MSG_CURSOR_RESET);
}
red_wait_all_sent(&worker->cursor_channel->common.base);
}
}
/* called upon device reset */
/* TODO: split me*/
static inline void dev_destroy_surfaces(RedWorker *worker)
{
int i;
spice_debug(NULL);
flush_all_qxl_commands(worker);
//to handle better
for (i = 0; i < NUM_SURFACES; ++i) {
if (worker->surfaces[i].context.canvas) {
destroy_surface_wait(worker, i);
if (worker->surfaces[i].context.canvas) {
red_destroy_surface(worker, i);
}
spice_assert(!worker->surfaces[i].context.canvas);
}
}
spice_assert(ring_is_empty(&worker->streams));
if (display_is_connected(worker)) {
red_channel_pipes_add_type(&worker->display_channel->common.base,
PIPE_ITEM_TYPE_INVAL_PALLET_CACHE);
red_pipes_add_verb(&worker->display_channel->common.base,
SPICE_MSG_DISPLAY_STREAM_DESTROY_ALL);
}
red_display_clear_glz_drawables(worker->display_channel);
red_cursor_reset(worker);
}
void handle_dev_destroy_surfaces(void *opaque, void *payload)
{
RedWorker *worker = opaque;
dev_destroy_surfaces(worker);
}
static MonitorsConfigItem *get_monitors_config_item(
RedChannel* channel, MonitorsConfig *monitors_config)
{
MonitorsConfigItem *mci;
mci = (MonitorsConfigItem *)spice_malloc(sizeof(*mci));
mci->monitors_config = monitors_config;
red_channel_pipe_item_init(channel,
&mci->pipe_item, PIPE_ITEM_TYPE_MONITORS_CONFIG);
return mci;
}
static inline void red_monitors_config_item_add(DisplayChannelClient *dcc)
{
MonitorsConfigItem *mci;
RedWorker *worker = dcc->common.worker;
mci = get_monitors_config_item(dcc->common.base.channel,
monitors_config_getref(worker->monitors_config));
red_channel_client_pipe_add(&dcc->common.base, &mci->pipe_item);
}
static void worker_update_monitors_config(RedWorker *worker,
QXLMonitorsConfig *dev_monitors_config)
{
int heads_size;
MonitorsConfig *monitors_config;
int i;
monitors_config_decref(worker->monitors_config);
spice_debug("monitors config %d(%d)",
dev_monitors_config->count,
dev_monitors_config->max_allowed);
for (i = 0; i < dev_monitors_config->count; i++) {
spice_debug("+%d+%d %dx%d",
dev_monitors_config->heads[i].x,
dev_monitors_config->heads[i].y,
dev_monitors_config->heads[i].width,
dev_monitors_config->heads[i].height);
}
heads_size = dev_monitors_config->count * sizeof(QXLHead);
worker->monitors_config = monitors_config =
spice_malloc(sizeof(*monitors_config) + heads_size);
monitors_config->refs = 1;
monitors_config->worker = worker;
monitors_config->count = dev_monitors_config->count;
monitors_config->max_allowed = dev_monitors_config->max_allowed;
memcpy(monitors_config->heads, dev_monitors_config->heads, heads_size);
}
static void red_push_monitors_config(DisplayChannelClient *dcc)
{
MonitorsConfig *monitors_config = DCC_TO_WORKER(dcc)->monitors_config;
if (monitors_config == NULL) {
spice_warning("monitors_config is NULL");
return;
}
if (!red_channel_client_test_remote_cap(&dcc->common.base,
SPICE_DISPLAY_CAP_MONITORS_CONFIG)) {
return;
}
red_monitors_config_item_add(dcc);
red_channel_client_push(&dcc->common.base);
}
static void red_worker_push_monitors_config(RedWorker *worker)
{
DisplayChannelClient *dcc;
RingItem *item, *next;
WORKER_FOREACH_DCC_SAFE(worker, item, next, dcc) {
red_push_monitors_config(dcc);
}
}
static void set_monitors_config_to_primary(RedWorker *worker)
{
QXLHead *head;
DrawContext *context;
if (!worker->surfaces[0].context.canvas) {
spice_warning("no primary surface");
return;
}
monitors_config_decref(worker->monitors_config);
context = &worker->surfaces[0].context;
worker->monitors_config =
spice_malloc(sizeof(*worker->monitors_config) + sizeof(QXLHead));
worker->monitors_config->refs = 1;
worker->monitors_config->worker = worker;
worker->monitors_config->count = 1;
worker->monitors_config->max_allowed = 1;
head = worker->monitors_config->heads;
head->id = 0;
head->surface_id = 0;
head->width = context->width;
head->height = context->height;
head->x = 0;
head->y = 0;
}
static void dev_create_primary_surface(RedWorker *worker, uint32_t surface_id,
QXLDevSurfaceCreate surface)
{
uint8_t *line_0;
int error;
spice_debug(NULL);
spice_warn_if(surface_id != 0);
spice_warn_if(surface.height == 0);
spice_warn_if(((uint64_t)abs(surface.stride) * (uint64_t)surface.height) !=
abs(surface.stride) * surface.height);
line_0 = (uint8_t*)get_virt(&worker->mem_slots, surface.mem,
surface.height * abs(surface.stride),
surface.group_id, &error);
if (error) {
return;
}
if (surface.stride < 0) {
line_0 -= (int32_t)(surface.stride * (surface.height -1));
}
red_create_surface(worker, 0, surface.width, surface.height, surface.stride, surface.format,
line_0, surface.flags & QXL_SURF_FLAG_KEEP_DATA, TRUE);
set_monitors_config_to_primary(worker);
if (display_is_connected(worker) && !worker->display_channel->common.during_target_migrate) {
/* guest created primary, so it will (hopefully) send a monitors_config
* now, don't send our own temporary one */
if (!worker->driver_cap_monitors_config) {
red_worker_push_monitors_config(worker);
}
red_pipes_add_verb(&worker->display_channel->common.base,
SPICE_MSG_DISPLAY_MARK);
red_channel_push(&worker->display_channel->common.base);
}
if (cursor_is_connected(worker) && !worker->cursor_channel->common.during_target_migrate) {
red_channel_pipes_add_type(&worker->cursor_channel->common.base,
PIPE_ITEM_TYPE_CURSOR_INIT);
}
}
void handle_dev_create_primary_surface(void *opaque, void *payload)
{
RedWorkerMessageCreatePrimarySurface *msg = payload;
RedWorker *worker = opaque;
dev_create_primary_surface(worker, msg->surface_id, msg->surface);
}
static void dev_destroy_primary_surface(RedWorker *worker, uint32_t surface_id)
{
spice_warn_if(surface_id != 0);
spice_debug(NULL);
if (!worker->surfaces[surface_id].context.canvas) {
spice_warning("double destroy of primary surface");
return;
}
flush_all_qxl_commands(worker);
dev_destroy_surface_wait(worker, 0);
red_destroy_surface(worker, 0);
spice_assert(ring_is_empty(&worker->streams));
spice_assert(!worker->surfaces[surface_id].context.canvas);
red_cursor_reset(worker);
}
void handle_dev_destroy_primary_surface(void *opaque, void *payload)
{
RedWorkerMessageDestroyPrimarySurface *msg = payload;
RedWorker *worker = opaque;
uint32_t surface_id = msg->surface_id;
dev_destroy_primary_surface(worker, surface_id);
}
void handle_dev_destroy_primary_surface_async(void *opaque, void *payload)
{
RedWorkerMessageDestroyPrimarySurfaceAsync *msg = payload;
RedWorker *worker = opaque;
uint32_t surface_id = msg->surface_id;
dev_destroy_primary_surface(worker, surface_id);
}
static void flush_all_surfaces(RedWorker *worker)
{
int x;
for (x = 0; x < NUM_SURFACES; ++x) {
if (worker->surfaces[x].context.canvas) {
red_current_flush(worker, x);
}
}
}
static void dev_flush_surfaces(RedWorker *worker)
{
flush_all_qxl_commands(worker);
flush_all_surfaces(worker);
}
void handle_dev_flush_surfaces(void *opaque, void *payload)
{
RedWorker *worker = opaque;
dev_flush_surfaces(worker);
}
void handle_dev_flush_surfaces_async(void *opaque, void *payload)
{
RedWorker *worker = opaque;
dev_flush_surfaces(worker);
}
void handle_dev_stop(void *opaque, void *payload)
{
RedWorker *worker = opaque;
spice_info("stop");
spice_assert(worker->running);
worker->running = FALSE;
red_display_clear_glz_drawables(worker->display_channel);
flush_all_surfaces(worker);
/* todo: when the waiting is expected to take long (slow connection and
* overloaded pipe), don't wait, and in case of migration,
* purge the pipe, send destroy_all_surfaces
* to the client (there is no such message right now), and start
* from scratch on the destination side */
red_wait_all_sent(&worker->display_channel->common.base);
red_wait_all_sent(&worker->cursor_channel->common.base);
}
static int display_channel_wait_for_migrate_data(DisplayChannel *display)
{
uint64_t end_time = red_now() + DISPLAY_CLIENT_MIGRATE_DATA_TIMEOUT;
RedChannel *channel = &display->common.base;
RedChannelClient *rcc;
spice_debug(NULL);
spice_assert(channel->clients_num == 1);
rcc = SPICE_CONTAINEROF(ring_get_head(&channel->clients), RedChannelClient, channel_link);
spice_assert(red_channel_client_waits_for_migrate_data(rcc));
for (;;) {
red_channel_client_receive(rcc);
if (!red_channel_client_is_connected(rcc)) {
break;
}
if (!red_channel_client_waits_for_migrate_data(rcc)) {
return TRUE;
}
if (red_now() > end_time) {
spice_warning("timeout");
red_channel_client_disconnect(rcc);
break;
}
usleep(DISPLAY_CLIENT_RETRY_INTERVAL);
}
return FALSE;
}
void handle_dev_start(void *opaque, void *payload)
{
RedWorker *worker = opaque;
spice_assert(!worker->running);
if (worker->cursor_channel) {
worker->cursor_channel->common.during_target_migrate = FALSE;
}
if (worker->display_channel) {
worker->display_channel->common.during_target_migrate = FALSE;
if (red_channel_waits_for_migrate_data(&worker->display_channel->common.base)) {
display_channel_wait_for_migrate_data(worker->display_channel);
}
}
worker->running = TRUE;
guest_set_client_capabilities(worker);
}
void handle_dev_wakeup(void *opaque, void *payload)
{
RedWorker *worker = opaque;
clear_bit(RED_WORKER_PENDING_WAKEUP, worker->pending);
stat_inc_counter(worker->wakeup_counter, 1);
}
void handle_dev_oom(void *opaque, void *payload)
{
RedWorker *worker = opaque;
RedChannel *display_red_channel = &worker->display_channel->common.base;
int ring_is_empty;
spice_assert(worker->running);
// streams? but without streams also leak
spice_debug("OOM1 #draw=%u, #red_draw=%u, #glz_draw=%u current %u pipes %u",
worker->drawable_count,
worker->red_drawable_count,
worker->glz_drawable_count,
worker->current_size,
worker->display_channel ?
red_channel_sum_pipes_size(display_red_channel) : 0);
while (red_process_commands(worker, MAX_PIPE_SIZE, &ring_is_empty)) {
red_channel_push(&worker->display_channel->common.base);
}
if (worker->qxl->st->qif->flush_resources(worker->qxl) == 0) {
red_free_some(worker);
worker->qxl->st->qif->flush_resources(worker->qxl);
}
spice_debug("OOM2 #draw=%u, #red_draw=%u, #glz_draw=%u current %u pipes %u",
worker->drawable_count,
worker->red_drawable_count,
worker->glz_drawable_count,
worker->current_size,
worker->display_channel ?
red_channel_sum_pipes_size(display_red_channel) : 0);
clear_bit(RED_WORKER_PENDING_OOM, worker->pending);
}
void handle_dev_reset_cursor(void *opaque, void *payload)
{
red_cursor_reset((RedWorker *)opaque);
}
void handle_dev_reset_image_cache(void *opaque, void *payload)
{
image_cache_reset(&((RedWorker *)opaque)->image_cache);
}
void handle_dev_destroy_surface_wait_async(void *opaque, void *payload)
{
RedWorkerMessageDestroySurfaceWaitAsync *msg = payload;
RedWorker *worker = opaque;
dev_destroy_surface_wait(worker, msg->surface_id);
}
void handle_dev_destroy_surfaces_async(void *opaque, void *payload)
{
RedWorker *worker = opaque;
dev_destroy_surfaces(worker);
}
void handle_dev_create_primary_surface_async(void *opaque, void *payload)
{
RedWorkerMessageCreatePrimarySurfaceAsync *msg = payload;
RedWorker *worker = opaque;
dev_create_primary_surface(worker, msg->surface_id, msg->surface);
}
/* exception for Dispatcher, data going from red_worker to main thread,
* TODO: use a different dispatcher?
* TODO: leave direct usage of channel(fd)? It's only used right after the
* pthread is created, since the channel duration is the lifetime of the spice
* server. */
void handle_dev_display_channel_create(void *opaque, void *payload)
{
RedWorker *worker = opaque;
RedChannel *red_channel;
// TODO: handle seemless migration. Temp, setting migrate to FALSE
display_channel_create(worker, FALSE);
red_channel = &worker->display_channel->common.base;
send_data(worker->channel, &red_channel, sizeof(RedChannel *));
}
void handle_dev_display_connect(void *opaque, void *payload)
{
RedWorkerMessageDisplayConnect *msg = payload;
RedWorker *worker = opaque;
RedsStream *stream = msg->stream;
RedClient *client = msg->client;
int migration = msg->migration;
spice_info("connect");
handle_new_display_channel(worker, client, stream, migration,
msg->common_caps, msg->num_common_caps,
msg->caps, msg->num_caps);
free(msg->caps);
free(msg->common_caps);
}
void handle_dev_display_disconnect(void *opaque, void *payload)
{
RedWorkerMessageDisplayDisconnect *msg = payload;
RedChannelClient *rcc = msg->rcc;
RedWorker *worker = opaque;
spice_info("disconnect display client");
spice_assert(rcc);
guest_set_client_capabilities(worker);
red_channel_client_disconnect(rcc);
}
void handle_dev_display_migrate(void *opaque, void *payload)
{
RedWorkerMessageDisplayMigrate *msg = payload;
RedWorker *worker = opaque;
RedChannelClient *rcc = msg->rcc;
spice_info("migrate display client");
spice_assert(rcc);
red_migrate_display(worker, rcc);
}
static void handle_dev_monitors_config_async(void *opaque, void *payload)
{
RedWorkerMessageMonitorsConfigAsync *msg = payload;
RedWorker *worker = opaque;
int min_size = sizeof(QXLMonitorsConfig) + sizeof(QXLHead);
int error;
QXLMonitorsConfig *dev_monitors_config =
(QXLMonitorsConfig*)get_virt(&worker->mem_slots, msg->monitors_config,
min_size, msg->group_id, &error);
if (error) {
/* TODO: raise guest bug (requires added QXL interface) */
return;
}
worker->driver_cap_monitors_config = 1;
if (dev_monitors_config->count == 0) {
spice_warning("ignoring an empty monitors config message from driver");
return;
}
if (dev_monitors_config->count > dev_monitors_config->max_allowed) {
spice_warning("ignoring malformed monitors_config from driver, "
"count > max_allowed %d > %d",
dev_monitors_config->count,
dev_monitors_config->max_allowed);
return;
}
worker_update_monitors_config(worker, dev_monitors_config);
red_worker_push_monitors_config(worker);
}
/* TODO: special, perhaps use another dispatcher? */
void handle_dev_cursor_channel_create(void *opaque, void *payload)
{
RedWorker *worker = opaque;
RedChannel *red_channel;
// TODO: handle seemless migration. Temp, setting migrate to FALSE
cursor_channel_create(worker, FALSE);
red_channel = &worker->cursor_channel->common.base;
send_data(worker->channel, &red_channel, sizeof(RedChannel *));
}
void handle_dev_cursor_connect(void *opaque, void *payload)
{
RedWorkerMessageCursorConnect *msg = payload;
RedWorker *worker = opaque;
RedsStream *stream = msg->stream;
RedClient *client = msg->client;
int migration = msg->migration;
spice_info("cursor connect");
red_connect_cursor(worker, client, stream, migration,
msg->common_caps, msg->num_common_caps,
msg->caps, msg->num_caps);
free(msg->caps);
free(msg->common_caps);
}
void handle_dev_cursor_disconnect(void *opaque, void *payload)
{
RedWorkerMessageCursorDisconnect *msg = payload;
RedChannelClient *rcc = msg->rcc;
spice_info("disconnect cursor client");
spice_assert(rcc);
red_channel_client_disconnect(rcc);
}
void handle_dev_cursor_migrate(void *opaque, void *payload)
{
RedWorkerMessageCursorMigrate *msg = payload;
RedWorker *worker = opaque;
RedChannelClient *rcc = msg->rcc;
spice_info("migrate cursor client");
spice_assert(rcc);
red_migrate_cursor(worker, rcc);
}
void handle_dev_set_compression(void *opaque, void *payload)
{
RedWorkerMessageSetCompression *msg = payload;
RedWorker *worker = opaque;
worker->image_compression = msg->image_compression;
switch (worker->image_compression) {
case SPICE_IMAGE_COMPRESS_AUTO_LZ:
spice_info("ic auto_lz");
break;
case SPICE_IMAGE_COMPRESS_AUTO_GLZ:
spice_info("ic auto_glz");
break;
case SPICE_IMAGE_COMPRESS_QUIC:
spice_info("ic quic");
break;
case SPICE_IMAGE_COMPRESS_LZ:
spice_info("ic lz");
break;
case SPICE_IMAGE_COMPRESS_GLZ:
spice_info("ic glz");
break;
case SPICE_IMAGE_COMPRESS_OFF:
spice_info("ic off");
break;
default:
spice_warning("ic invalid");
}
#ifdef COMPRESS_STAT
print_compress_stats(worker->display_channel);
if (worker->display_channel) {
stat_reset(&worker->display_channel->quic_stat);
stat_reset(&worker->display_channel->lz_stat);
stat_reset(&worker->display_channel->glz_stat);
stat_reset(&worker->display_channel->jpeg_stat);
stat_reset(&worker->display_channel->zlib_glz_stat);
stat_reset(&worker->display_channel->jpeg_alpha_stat);
}
#endif
}
void handle_dev_set_streaming_video(void *opaque, void *payload)
{
RedWorkerMessageSetStreamingVideo *msg = payload;
RedWorker *worker = opaque;
worker->streaming_video = msg->streaming_video;
spice_assert(worker->streaming_video != STREAM_VIDEO_INVALID);
switch(worker->streaming_video) {
case STREAM_VIDEO_ALL:
spice_info("sv all");
break;
case STREAM_VIDEO_FILTER:
spice_info("sv filter");
break;
case STREAM_VIDEO_OFF:
spice_info("sv off");
break;
default:
spice_warning("sv invalid");
}
}
void handle_dev_set_mouse_mode(void *opaque, void *payload)
{
RedWorkerMessageSetMouseMode *msg = payload;
RedWorker *worker = opaque;
worker->mouse_mode = msg->mode;
spice_info("mouse mode %u", worker->mouse_mode);
}
void handle_dev_add_memslot_async(void *opaque, void *payload)
{
RedWorkerMessageAddMemslotAsync *msg = payload;
RedWorker *worker = opaque;
dev_add_memslot(worker, msg->mem_slot);
}
void handle_dev_reset_memslots(void *opaque, void *payload)
{
RedWorker *worker = opaque;
red_memslot_info_reset(&worker->mem_slots);
}
void handle_dev_driver_unload(void *opaque, void *payload)
{
RedWorker *worker = opaque;
worker->driver_cap_monitors_config = 0;
}
void handle_dev_loadvm_commands(void *opaque, void *payload)
{
RedWorkerMessageLoadvmCommands *msg = payload;
RedWorker *worker = opaque;
uint32_t i;
RedCursorCmd *cursor_cmd;
RedSurfaceCmd *surface_cmd;
uint32_t count = msg->count;
QXLCommandExt *ext = msg->ext;
spice_info("loadvm_commands");
for (i = 0 ; i < count ; ++i) {
switch (ext[i].cmd.type) {
case QXL_CMD_CURSOR:
cursor_cmd = spice_new0(RedCursorCmd, 1);
if (red_get_cursor_cmd(&worker->mem_slots, ext[i].group_id,
cursor_cmd, ext[i].cmd.data)) {
/* XXX allow failure in loadvm? */
spice_warning("failed loadvm command type (%d)",
ext[i].cmd.type);
continue;
}
qxl_process_cursor(worker, cursor_cmd, ext[i].group_id);
break;
case QXL_CMD_SURFACE:
surface_cmd = spice_new0(RedSurfaceCmd, 1);
red_get_surface_cmd(&worker->mem_slots, ext[i].group_id,
surface_cmd, ext[i].cmd.data);
red_process_surface(worker, surface_cmd, ext[i].group_id, TRUE);
break;
default:
spice_warning("unhandled loadvm command type (%d)", ext[i].cmd.type);
break;
}
}
}
static void worker_handle_dispatcher_async_done(void *opaque,
uint32_t message_type,
void *payload)
{
RedWorker *worker = opaque;
RedWorkerMessageAsync *msg_async = payload;
spice_debug(NULL);
red_dispatcher_async_complete(worker->red_dispatcher, msg_async->cmd);
}
static void register_callbacks(Dispatcher *dispatcher)
{
dispatcher_register_async_done_callback(
dispatcher,
worker_handle_dispatcher_async_done);
dispatcher_register_handler(dispatcher,
RED_WORKER_MESSAGE_DISPLAY_CONNECT,
handle_dev_display_connect,
sizeof(RedWorkerMessageDisplayConnect),
DISPATCHER_NONE);
dispatcher_register_handler(dispatcher,
RED_WORKER_MESSAGE_DISPLAY_DISCONNECT,
handle_dev_display_disconnect,
sizeof(RedWorkerMessageDisplayDisconnect),
DISPATCHER_ACK);
dispatcher_register_handler(dispatcher,
RED_WORKER_MESSAGE_DISPLAY_MIGRATE,
handle_dev_display_migrate,
sizeof(RedWorkerMessageDisplayMigrate),
DISPATCHER_NONE);
dispatcher_register_handler(dispatcher,
RED_WORKER_MESSAGE_CURSOR_CONNECT,
handle_dev_cursor_connect,
sizeof(RedWorkerMessageCursorConnect),
DISPATCHER_NONE);
dispatcher_register_handler(dispatcher,
RED_WORKER_MESSAGE_CURSOR_DISCONNECT,
handle_dev_cursor_disconnect,
sizeof(RedWorkerMessageCursorDisconnect),
DISPATCHER_ACK);
dispatcher_register_handler(dispatcher,
RED_WORKER_MESSAGE_CURSOR_MIGRATE,
handle_dev_cursor_migrate,
sizeof(RedWorkerMessageCursorMigrate),
DISPATCHER_NONE);
dispatcher_register_handler(dispatcher,
RED_WORKER_MESSAGE_UPDATE,
handle_dev_update,
sizeof(RedWorkerMessageUpdate),
DISPATCHER_ACK);
dispatcher_register_handler(dispatcher,
RED_WORKER_MESSAGE_UPDATE_ASYNC,
handle_dev_update_async,
sizeof(RedWorkerMessageUpdateAsync),
DISPATCHER_ASYNC);
dispatcher_register_handler(dispatcher,
RED_WORKER_MESSAGE_ADD_MEMSLOT,
handle_dev_add_memslot,
sizeof(RedWorkerMessageAddMemslot),
DISPATCHER_ACK);
dispatcher_register_handler(dispatcher,
RED_WORKER_MESSAGE_ADD_MEMSLOT_ASYNC,
handle_dev_add_memslot_async,
sizeof(RedWorkerMessageAddMemslotAsync),
DISPATCHER_ASYNC);
dispatcher_register_handler(dispatcher,
RED_WORKER_MESSAGE_DEL_MEMSLOT,
handle_dev_del_memslot,
sizeof(RedWorkerMessageDelMemslot),
DISPATCHER_NONE);
dispatcher_register_handler(dispatcher,
RED_WORKER_MESSAGE_DESTROY_SURFACES,
handle_dev_destroy_surfaces,
sizeof(RedWorkerMessageDestroySurfaces),
DISPATCHER_ACK);
dispatcher_register_handler(dispatcher,
RED_WORKER_MESSAGE_DESTROY_SURFACES_ASYNC,
handle_dev_destroy_surfaces_async,
sizeof(RedWorkerMessageDestroySurfacesAsync),
DISPATCHER_ASYNC);
dispatcher_register_handler(dispatcher,
RED_WORKER_MESSAGE_DESTROY_PRIMARY_SURFACE,
handle_dev_destroy_primary_surface,
sizeof(RedWorkerMessageDestroyPrimarySurface),
DISPATCHER_ACK);
dispatcher_register_handler(dispatcher,
RED_WORKER_MESSAGE_DESTROY_PRIMARY_SURFACE_ASYNC,
handle_dev_destroy_primary_surface_async,
sizeof(RedWorkerMessageDestroyPrimarySurfaceAsync),
DISPATCHER_ASYNC);
dispatcher_register_handler(dispatcher,
RED_WORKER_MESSAGE_CREATE_PRIMARY_SURFACE_ASYNC,
handle_dev_create_primary_surface_async,
sizeof(RedWorkerMessageCreatePrimarySurfaceAsync),
DISPATCHER_ASYNC);
dispatcher_register_handler(dispatcher,
RED_WORKER_MESSAGE_CREATE_PRIMARY_SURFACE,
handle_dev_create_primary_surface,
sizeof(RedWorkerMessageCreatePrimarySurface),
DISPATCHER_ACK);
dispatcher_register_handler(dispatcher,
RED_WORKER_MESSAGE_RESET_IMAGE_CACHE,
handle_dev_reset_image_cache,
sizeof(RedWorkerMessageResetImageCache),
DISPATCHER_ACK);
dispatcher_register_handler(dispatcher,
RED_WORKER_MESSAGE_RESET_CURSOR,
handle_dev_reset_cursor,
sizeof(RedWorkerMessageResetCursor),
DISPATCHER_ACK);
dispatcher_register_handler(dispatcher,
RED_WORKER_MESSAGE_WAKEUP,
handle_dev_wakeup,
sizeof(RedWorkerMessageWakeup),
DISPATCHER_NONE);
dispatcher_register_handler(dispatcher,
RED_WORKER_MESSAGE_OOM,
handle_dev_oom,
sizeof(RedWorkerMessageOom),
DISPATCHER_NONE);
dispatcher_register_handler(dispatcher,
RED_WORKER_MESSAGE_START,
handle_dev_start,
sizeof(RedWorkerMessageStart),
DISPATCHER_NONE);
dispatcher_register_handler(dispatcher,
RED_WORKER_MESSAGE_FLUSH_SURFACES_ASYNC,
handle_dev_flush_surfaces_async,
sizeof(RedWorkerMessageFlushSurfacesAsync),
DISPATCHER_ASYNC);
dispatcher_register_handler(dispatcher,
RED_WORKER_MESSAGE_STOP,
handle_dev_stop,
sizeof(RedWorkerMessageStop),
DISPATCHER_ACK);
dispatcher_register_handler(dispatcher,
RED_WORKER_MESSAGE_LOADVM_COMMANDS,
handle_dev_loadvm_commands,
sizeof(RedWorkerMessageLoadvmCommands),
DISPATCHER_ACK);
dispatcher_register_handler(dispatcher,
RED_WORKER_MESSAGE_SET_COMPRESSION,
handle_dev_set_compression,
sizeof(RedWorkerMessageSetCompression),
DISPATCHER_NONE);
dispatcher_register_handler(dispatcher,
RED_WORKER_MESSAGE_SET_STREAMING_VIDEO,
handle_dev_set_streaming_video,
sizeof(RedWorkerMessageSetStreamingVideo),
DISPATCHER_NONE);
dispatcher_register_handler(dispatcher,
RED_WORKER_MESSAGE_SET_MOUSE_MODE,
handle_dev_set_mouse_mode,
sizeof(RedWorkerMessageSetMouseMode),
DISPATCHER_NONE);
dispatcher_register_handler(dispatcher,
RED_WORKER_MESSAGE_DISPLAY_CHANNEL_CREATE,
handle_dev_display_channel_create,
sizeof(RedWorkerMessageDisplayChannelCreate),
DISPATCHER_NONE);
dispatcher_register_handler(dispatcher,
RED_WORKER_MESSAGE_CURSOR_CHANNEL_CREATE,
handle_dev_cursor_channel_create,
sizeof(RedWorkerMessageCursorChannelCreate),
DISPATCHER_NONE);
dispatcher_register_handler(dispatcher,
RED_WORKER_MESSAGE_DESTROY_SURFACE_WAIT,
handle_dev_destroy_surface_wait,
sizeof(RedWorkerMessageDestroySurfaceWait),
DISPATCHER_ACK);
dispatcher_register_handler(dispatcher,
RED_WORKER_MESSAGE_DESTROY_SURFACE_WAIT_ASYNC,
handle_dev_destroy_surface_wait_async,
sizeof(RedWorkerMessageDestroySurfaceWaitAsync),
DISPATCHER_ASYNC);
dispatcher_register_handler(dispatcher,
RED_WORKER_MESSAGE_RESET_MEMSLOTS,
handle_dev_reset_memslots,
sizeof(RedWorkerMessageResetMemslots),
DISPATCHER_NONE);
dispatcher_register_handler(dispatcher,
RED_WORKER_MESSAGE_MONITORS_CONFIG_ASYNC,
handle_dev_monitors_config_async,
sizeof(RedWorkerMessageMonitorsConfigAsync),
DISPATCHER_ASYNC);
dispatcher_register_handler(dispatcher,
RED_WORKER_MESSAGE_DRIVER_UNLOAD,
handle_dev_driver_unload,
sizeof(RedWorkerMessageDriverUnload),
DISPATCHER_NONE);
}
static void handle_dev_input(int fd, int event, void *opaque)
{
RedWorker *worker = opaque;
dispatcher_handle_recv_read(red_dispatcher_get_dispatcher(worker->red_dispatcher));
}
static void red_init(RedWorker *worker, WorkerInitData *init_data)
{
RedWorkerMessage message;
Dispatcher *dispatcher;
int i;
spice_assert(sizeof(CursorItem) <= QXL_CURSUR_DEVICE_DATA_SIZE);
memset(worker, 0, sizeof(RedWorker));
dispatcher = red_dispatcher_get_dispatcher(init_data->red_dispatcher);
dispatcher_set_opaque(dispatcher, worker);
worker->red_dispatcher = init_data->red_dispatcher;
worker->qxl = init_data->qxl;
worker->id = init_data->id;
worker->channel = dispatcher_get_recv_fd(dispatcher);
register_callbacks(dispatcher);
worker->pending = init_data->pending;
worker->cursor_visible = TRUE;
spice_assert(init_data->num_renderers > 0);
worker->num_renderers = init_data->num_renderers;
memcpy(worker->renderers, init_data->renderers, sizeof(worker->renderers));
worker->renderer = RED_RENDERER_INVALID;
worker->mouse_mode = SPICE_MOUSE_MODE_SERVER;
worker->image_compression = init_data->image_compression;
worker->jpeg_state = init_data->jpeg_state;
worker->zlib_glz_state = init_data->zlib_glz_state;
worker->streaming_video = init_data->streaming_video;
worker->driver_cap_monitors_config = 0;
ring_init(&worker->current_list);
image_cache_init(&worker->image_cache);
image_surface_init(worker);
drawables_init(worker);
cursor_items_init(worker);
red_init_streams(worker);
stat_init(&worker->add_stat, add_stat_name);
stat_init(&worker->exclude_stat, exclude_stat_name);
stat_init(&worker->__exclude_stat, __exclude_stat_name);
#ifdef RED_STATISTICS
char worker_str[20];
sprintf(worker_str, "display[%d]", worker->id);
worker->stat = stat_add_node(INVALID_STAT_REF, worker_str, TRUE);
worker->wakeup_counter = stat_add_counter(worker->stat, "wakeups", TRUE);
worker->command_counter = stat_add_counter(worker->stat, "commands", TRUE);
#endif
for (i = 0; i < MAX_EVENT_SOURCES; i++) {
worker->poll_fds[i].fd = -1;
}
worker->poll_fds[0].fd = worker->channel;
worker->poll_fds[0].events = POLLIN;
worker->watches[0].worker = worker;
worker->watches[0].watch_func = handle_dev_input;
worker->watches[0].watch_func_opaque = worker;
red_memslot_info_init(&worker->mem_slots,
init_data->num_memslots_groups,
init_data->num_memslots,
init_data->memslot_gen_bits,
init_data->memslot_id_bits,
init_data->internal_groupslot_id);
spice_warn_if(init_data->n_surfaces > NUM_SURFACES);
worker->n_surfaces = init_data->n_surfaces;
if (!spice_timer_queue_create()) {
spice_error("failed to create timer queue");
}
srand(time(NULL));
message = RED_WORKER_MESSAGE_READY;
write_message(worker->channel, &message);
}
static void red_display_cc_free_glz_drawables(RedChannelClient *rcc)
{
DisplayChannelClient *dcc = RCC_TO_DCC(rcc);
red_display_handle_glz_drawables_to_free(dcc);
}
SPICE_GNUC_NORETURN void *red_worker_main(void *arg)
{
RedWorker *worker = spice_malloc(sizeof(RedWorker));
spice_info("begin");
spice_assert(MAX_PIPE_SIZE > WIDE_CLIENT_ACK_WINDOW &&
MAX_PIPE_SIZE > NARROW_CLIENT_ACK_WINDOW); //ensure wakeup by ack message
#if defined(RED_WORKER_STAT) || defined(COMPRESS_STAT)
if (pthread_getcpuclockid(pthread_self(), &clock_id)) {
spice_error("pthread_getcpuclockid failed");
}
#endif
red_init(worker, (WorkerInitData *)arg);
red_init_quic(worker);
red_init_lz(worker);
red_init_jpeg(worker);
red_init_zlib(worker);
worker->event_timeout = INF_EVENT_WAIT;
for (;;) {
int i, num_events;
unsigned int timers_queue_timeout;
timers_queue_timeout = spice_timer_queue_get_timeout_ms();
worker->event_timeout = MIN(red_get_streams_timout(worker), worker->event_timeout);
worker->event_timeout = MIN(timers_queue_timeout, worker->event_timeout);
num_events = poll(worker->poll_fds, MAX_EVENT_SOURCES, worker->event_timeout);
red_handle_streams_timout(worker);
spice_timer_queue_cb();
if (worker->display_channel) {
/* during migration, in the dest, the display channel can be initialized
while the global lz data not since migrate data msg hasn't been
received yet */
red_channel_apply_clients(&worker->display_channel->common.base,
red_display_cc_free_glz_drawables);
}
worker->event_timeout = INF_EVENT_WAIT;
if (num_events == -1) {
if (errno != EINTR) {
spice_error("poll failed, %s", strerror(errno));
}
}
for (i = 0; i < MAX_EVENT_SOURCES; i++) {
/* The watch may have been removed by the watch-func from
another fd (ie a disconnect through the dispatcher),
in this case watch_func is NULL. */
if (worker->poll_fds[i].revents && worker->watches[i].watch_func) {
int events = 0;
if (worker->poll_fds[i].revents & POLLIN) {
events |= SPICE_WATCH_EVENT_READ;
}
if (worker->poll_fds[i].revents & POLLOUT) {
events |= SPICE_WATCH_EVENT_WRITE;
}
worker->watches[i].watch_func(worker->poll_fds[i].fd, events,
worker->watches[i].watch_func_opaque);
}
}
/* Clear the poll_fd for any removed watches, see the comment in
watch_remove for why we don't do this there. */
for (i = 0; i < MAX_EVENT_SOURCES; i++) {
if (!worker->watches[i].watch_func) {
worker->poll_fds[i].fd = -1;
}
}
if (worker->running) {
int ring_is_empty;
red_process_cursor(worker, MAX_PIPE_SIZE, &ring_is_empty);
red_process_commands(worker, MAX_PIPE_SIZE, &ring_is_empty);
}
red_push(worker);
}
abort();
}
#ifdef DUMP_BITMAP
#include
static void dump_palette(FILE *f, SpicePalette* plt)
{
int i;
for (i = 0; i < plt->num_ents; i++) {
fwrite(plt->ents + i, sizeof(uint32_t), 1, f);
}
}
static void dump_line(FILE *f, uint8_t* line, uint16_t n_pixel_bits, int width, int row_size)
{
int i;
int copy_bytes_size = SPICE_ALIGN(n_pixel_bits * width, 8) / 8;
fwrite(line, 1, copy_bytes_size, f);
if (row_size > copy_bytes_size) {
// each line should be 4 bytes aligned
for (i = copy_bytes_size; i < row_size; i++) {
fprintf(f, "%c", 0);
}
}
}
#define RAM_PATH "/tmp/tmpfs"
static void dump_bitmap(RedWorker *worker, SpiceBitmap *bitmap, uint32_t group_id)
{
static uint32_t file_id = 0;
char file_str[200];
int rgb = TRUE;
uint16_t n_pixel_bits;
SpicePalette *plt = NULL;
uint32_t id;
int row_size;
uint32_t file_size;
int alpha = 0;
uint32_t header_size = 14 + 40;
uint32_t bitmap_data_offset;
uint32_t tmp_u32;
int32_t tmp_32;
uint16_t tmp_u16;
FILE *f;
int i;
switch (bitmap->format) {
case SPICE_BITMAP_FMT_1BIT_BE:
case SPICE_BITMAP_FMT_1BIT_LE:
rgb = FALSE;
n_pixel_bits = 1;
break;
case SPICE_BITMAP_FMT_4BIT_BE:
case SPICE_BITMAP_FMT_4BIT_LE:
rgb = FALSE;
n_pixel_bits = 4;
break;
case SPICE_BITMAP_FMT_8BIT:
rgb = FALSE;
n_pixel_bits = 8;
break;
case SPICE_BITMAP_FMT_16BIT:
n_pixel_bits = 16;
break;
case SPICE_BITMAP_FMT_24BIT:
n_pixel_bits = 24;
break;
case SPICE_BITMAP_FMT_32BIT:
n_pixel_bits = 32;
break;
case SPICE_BITMAP_FMT_RGBA:
n_pixel_bits = 32;
alpha = 1;
break;
default:
spice_error("invalid bitmap format %u", bitmap->format);
}
if (!rgb) {
if (!bitmap->palette) {
return; // dont dump masks.
}
plt = bitmap->palette;
}
row_size = (((bitmap->x * n_pixel_bits) + 31) / 32) * 4;
bitmap_data_offset = header_size;
if (plt) {
bitmap_data_offset += plt->num_ents * 4;
}
file_size = bitmap_data_offset + (bitmap->y * row_size);
id = ++file_id;
sprintf(file_str, "%s/%u.bmp", RAM_PATH, id);
f = fopen(file_str, "wb");
if (!f) {
spice_error("Error creating bmp");
return;
}
/* writing the bmp v3 header */
fprintf(f, "BM");
fwrite(&file_size, sizeof(file_size), 1, f);
tmp_u16 = alpha ? 1 : 0;
fwrite(&tmp_u16, sizeof(tmp_u16), 1, f); // reserved for application
tmp_u16 = 0;
fwrite(&tmp_u16, sizeof(tmp_u16), 1, f);
fwrite(&bitmap_data_offset, sizeof(bitmap_data_offset), 1, f);
tmp_u32 = header_size - 14;
fwrite(&tmp_u32, sizeof(tmp_u32), 1, f); // sub header size
tmp_32 = bitmap->x;
fwrite(&tmp_32, sizeof(tmp_32), 1, f);
tmp_32 = bitmap->y;
fwrite(&tmp_32, sizeof(tmp_32), 1, f);
tmp_u16 = 1;
fwrite(&tmp_u16, sizeof(tmp_u16), 1, f); // color plane
fwrite(&n_pixel_bits, sizeof(n_pixel_bits), 1, f); // pixel depth
tmp_u32 = 0;
fwrite(&tmp_u32, sizeof(tmp_u32), 1, f); // compression method
tmp_u32 = 0; //file_size - bitmap_data_offset;
fwrite(&tmp_u32, sizeof(tmp_u32), 1, f); // image size
tmp_32 = 0;
fwrite(&tmp_32, sizeof(tmp_32), 1, f);
fwrite(&tmp_32, sizeof(tmp_32), 1, f);
tmp_u32 = (!plt) ? 0 : plt->num_ents; // plt entries
fwrite(&tmp_u32, sizeof(tmp_u32), 1, f);
tmp_u32 = 0;
fwrite(&tmp_u32, sizeof(tmp_u32), 1, f);
if (plt) {
dump_palette(f, plt);
}
/* writing the data */
for (i = 0; i < bitmap->data->num_chunks; i++) {
SpiceChunk *chunk = &bitmap->data->chunk[i];
int num_lines = chunk->len / bitmap->stride;
for (i = 0; i < num_lines; i++) {
dump_line(f, chunk->data + (i * bitmap->stride), n_pixel_bits, bitmap->x, row_size);
}
}
fclose(f);
}
#endif