rockbox/apps/plugins/pictureflow/pictureflow.c
Tomer Shalev 47ddbaa47b Cowon D2: Rename COWOND2_PAD -> COWON_D2_PAD to match macro used in manual, and
to target naming conventions in general


git-svn-id: svn://svn.rockbox.org/rockbox/trunk@24010 a1c6a512-1295-4272-9138-f99709370657
2009-12-15 20:51:41 +00:00

2769 lines
78 KiB
C

/***************************************************************************
* __________ __ ___.
* Open \______ \ ____ ____ | | _\_ |__ _______ ___
* Source | _// _ \_/ ___\| |/ /| __ \ / _ \ \/ /
* Jukebox | | ( <_> ) \___| < | \_\ ( <_> > < <
* Firmware |____|_ /\____/ \___ >__|_ \|___ /\____/__/\_ \
* \/ \/ \/ \/ \/
* $Id$
*
* Copyright (C) 2007 Jonas Hurrelmann (j@outpo.st)
* Copyright (C) 2007 Nicolas Pennequin
* Copyright (C) 2007 Ariya Hidayat (ariya@kde.org) (original Qt Version)
*
* Original code: http://code.google.com/p/pictureflow/
*
* This program is free software; you can redistribute it and/or
* modify it under the terms of the GNU General Public License
* as published by the Free Software Foundation; either version 2
* of the License, or (at your option) any later version.
*
* This software is distributed on an "AS IS" basis, WITHOUT WARRANTY OF ANY
* KIND, either express or implied.
*
****************************************************************************/
#include "plugin.h"
#include <albumart.h>
#include "lib/read_image.h"
#include "lib/pluginlib_actions.h"
#include "lib/helper.h"
#include "lib/configfile.h"
#include "lib/grey.h"
#include "lib/feature_wrappers.h"
#include "lib/buflib.h"
PLUGIN_HEADER
/******************************* Globals ***********************************/
/*
* Targets which use plugin_get_audio_buffer() can't have playback from
* within pictureflow itself, as the whole core audio buffer is occupied */
#define PF_PLAYBACK_CAPABLE (PLUGIN_BUFFER_SIZE > 0x10000)
#if PF_PLAYBACK_CAPABLE
#include "lib/playback_control.h"
#endif
#define PF_PREV ACTION_STD_PREV
#define PF_PREV_REPEAT ACTION_STD_PREVREPEAT
#define PF_NEXT ACTION_STD_NEXT
#define PF_NEXT_REPEAT ACTION_STD_NEXTREPEAT
#define PF_SELECT ACTION_STD_OK
#define PF_CONTEXT ACTION_STD_CONTEXT
#define PF_BACK ACTION_STD_CANCEL
#define PF_MENU ACTION_STD_MENU
#define PF_WPS ACTION_TREE_WPS
#define PF_QUIT (LAST_ACTION_PLACEHOLDER + 1)
#if defined(HAVE_SCROLLWHEEL) || CONFIG_KEYPAD == IRIVER_H10_PAD || \
CONFIG_KEYPAD == SAMSUNG_YH_PAD
#define USE_CORE_PREVNEXT
#endif
#ifndef USE_CORE_PREVNEXT
/* scrollwheel targets use the wheel, just as they do in lists,
* so there's no need for a special context,
* others use left/right here too (as oppsed to up/down in lists) */
const struct button_mapping pf_context_album_scroll[] =
{
#ifdef HAVE_TOUCHSCREEN
{PF_PREV, BUTTON_MIDLEFT, BUTTON_NONE},
{PF_PREV_REPEAT, BUTTON_MIDLEFT|BUTTON_REPEAT, BUTTON_NONE},
{PF_NEXT, BUTTON_MIDRIGHT, BUTTON_NONE},
{PF_NEXT_REPEAT, BUTTON_MIDRIGHT|BUTTON_REPEAT, BUTTON_NONE},
#endif
#if (CONFIG_KEYPAD == IAUDIO_M3_PAD || CONFIG_KEYPAD == MROBE500_PAD)
{PF_PREV, BUTTON_RC_REW, BUTTON_NONE},
{PF_PREV_REPEAT, BUTTON_RC_REW|BUTTON_REPEAT,BUTTON_NONE},
{PF_NEXT, BUTTON_RC_FF, BUTTON_NONE},
{PF_NEXT_REPEAT, BUTTON_RC_FF|BUTTON_REPEAT, BUTTON_NONE},
#else
{PF_PREV, BUTTON_LEFT, BUTTON_NONE},
{PF_PREV_REPEAT, BUTTON_LEFT|BUTTON_REPEAT, BUTTON_NONE},
{PF_NEXT, BUTTON_RIGHT, BUTTON_NONE},
{PF_NEXT_REPEAT, BUTTON_RIGHT|BUTTON_REPEAT, BUTTON_NONE},
{ACTION_NONE, BUTTON_LEFT|BUTTON_REL, BUTTON_LEFT},
{ACTION_NONE, BUTTON_RIGHT|BUTTON_REL, BUTTON_RIGHT},
{ACTION_NONE, BUTTON_LEFT|BUTTON_REPEAT, BUTTON_LEFT},
{ACTION_NONE, BUTTON_RIGHT|BUTTON_REPEAT, BUTTON_RIGHT},
#endif
#if CONFIG_KEYPAD == ONDIO_PAD
{PF_SELECT, BUTTON_UP|BUTTON_REL, BUTTON_UP},
{PF_CONTEXT, BUTTON_UP|BUTTON_REPEAT, BUTTON_UP},
{ACTION_NONE, BUTTON_UP, BUTTON_NONE},
{ACTION_NONE, BUTTON_DOWN, BUTTON_NONE},
{ACTION_NONE, BUTTON_DOWN|BUTTON_REPEAT, BUTTON_NONE},
#endif
LAST_ITEM_IN_LIST__NEXTLIST(CONTEXT_PLUGIN|1)
};
#endif /* !USE_CORE_PREVNEXT */
const struct button_mapping pf_context_buttons[] =
{
#ifdef HAVE_TOUCHSCREEN
{PF_SELECT, BUTTON_CENTER, BUTTON_NONE},
{PF_BACK, BUTTON_BOTTOMRIGHT, BUTTON_NONE},
#endif
#if CONFIG_KEYPAD == ARCHOS_AV300_PAD
{PF_QUIT, BUTTON_OFF, BUTTON_NONE},
#elif CONFIG_KEYPAD == SANSA_C100_PAD
{PF_QUIT, BUTTON_MENU|BUTTON_REPEAT, BUTTON_MENU},
#elif CONFIG_KEYPAD == CREATIVEZV_PAD || CONFIG_KEYPAD == CREATIVEZVM_PAD || \
CONFIG_KEYPAD == PHILIPS_HDD1630_PAD || CONFIG_KEYPAD == IAUDIO67_PAD || \
CONFIG_KEYPAD == GIGABEAT_PAD || CONFIG_KEYPAD == GIGABEAT_S_PAD || \
CONFIG_KEYPAD == MROBE100_PAD || CONFIG_KEYPAD == MROBE500_PAD || \
CONFIG_KEYPAD == PHILIPS_SA9200_PAD || CONFIG_KEYPAD == SANSA_CLIP_PAD
{PF_QUIT, BUTTON_POWER, BUTTON_NONE},
#elif CONFIG_KEYPAD == SANSA_FUZE_PAD
{PF_QUIT, BUTTON_HOME|BUTTON_REPEAT, BUTTON_NONE},
/* These all use short press of BUTTON_POWER for menu, map long POWER to quit
*/
#elif CONFIG_KEYPAD == SANSA_C200_PAD || CONFIG_KEYPAD == SANSA_M200_PAD || \
CONFIG_KEYPAD == IRIVER_H10_PAD || CONFIG_KEYPAD == COWON_D2_PAD
{PF_QUIT, BUTTON_POWER|BUTTON_REPEAT, BUTTON_POWER},
#if CONFIG_KEYPAD == COWON_D2_PAD
{PF_BACK, BUTTON_POWER|BUTTON_REL, BUTTON_POWER},
{ACTION_NONE, BUTTON_POWER, BUTTON_NONE},
#endif
#elif CONFIG_KEYPAD == SANSA_E200_PAD
{PF_QUIT, BUTTON_POWER, BUTTON_NONE},
#elif CONFIG_KEYPAD == IRIVER_IFP7XX_PAD
{PF_QUIT, BUTTON_EQ, BUTTON_NONE},
#elif (CONFIG_KEYPAD == IPOD_1G2G_PAD) \
|| (CONFIG_KEYPAD == IPOD_3G_PAD) \
|| (CONFIG_KEYPAD == IPOD_4G_PAD)
{PF_QUIT, BUTTON_MENU|BUTTON_REPEAT, BUTTON_MENU},
#elif CONFIG_KEYPAD == LOGIK_DAX_PAD
{PF_QUIT, BUTTON_POWERPLAY|BUTTON_REPEAT, BUTTON_POWERPLAY},
#elif CONFIG_KEYPAD == IAUDIO_M3_PAD
{PF_QUIT, BUTTON_RC_REC, BUTTON_NONE},
#elif CONFIG_KEYPAD == MEIZU_M6SL_PAD
{PF_QUIT, BUTTON_MENU|BUTTON_REPEAT, BUTTON_MENU},
#elif CONFIG_KEYPAD == IRIVER_H100_PAD || CONFIG_KEYPAD == IRIVER_H300_PAD || \
CONFIG_KEYPAD == RECORDER_PAD || CONFIG_KEYPAD == ONDIO_PAD
{PF_QUIT, BUTTON_OFF, BUTTON_NONE},
#endif
#if CONFIG_KEYPAD == IAUDIO_M3_PAD
LAST_ITEM_IN_LIST__NEXTLIST(CONTEXT_STD|CONTEXT_REMOTE)
#else
LAST_ITEM_IN_LIST__NEXTLIST(CONTEXT_TREE)
#endif
};
const struct button_mapping *pf_contexts[] =
{
#ifndef USE_CORE_PREVNEXT
pf_context_album_scroll,
#endif
pf_context_buttons
};
#if LCD_DEPTH < 8
#if LCD_DEPTH > 1
#define N_BRIGHT(y) LCD_BRIGHTNESS(y)
#else /* LCD_DEPTH <= 1 */
#define N_BRIGHT(y) ((y > 127) ? 0 : 1)
#ifdef HAVE_NEGATIVE_LCD /* m:robe 100, Clip */
#define PICTUREFLOW_DRMODE DRMODE_SOLID
#else
#define PICTUREFLOW_DRMODE (DRMODE_SOLID|DRMODE_INVERSEVID)
#endif
#endif /* LCD_DEPTH <= 1 */
#define USEGSLIB
GREY_INFO_STRUCT
#define LCD_BUF _grey_info.buffer
#define MYLCD(fn) grey_ ## fn
#define G_PIX(r,g,b) \
(77 * (unsigned)(r) + 150 * (unsigned)(g) + 29 * (unsigned)(b)) / 256
#define N_PIX(r,g,b) N_BRIGHT(G_PIX(r,g,b))
#define G_BRIGHT(y) (y)
#define BUFFER_WIDTH _grey_info.width
#define BUFFER_HEIGHT _grey_info.height
typedef unsigned char pix_t;
#else /* LCD_DEPTH >= 8 */
#define LCD_BUF rb->lcd_framebuffer
#define MYLCD(fn) rb->lcd_ ## fn
#define G_PIX LCD_RGBPACK
#define N_PIX LCD_RGBPACK
#define G_BRIGHT(y) LCD_RGBPACK(y,y,y)
#define N_BRIGHT(y) LCD_RGBPACK(y,y,y)
#define BUFFER_WIDTH LCD_WIDTH
#define BUFFER_HEIGHT LCD_HEIGHT
typedef fb_data pix_t;
#endif /* LCD_DEPTH >= 8 */
/* for fixed-point arithmetic, we need minimum 32-bit long
long long (64-bit) might be useful for multiplication and division */
#define PFreal long
#define PFREAL_SHIFT 10
#define PFREAL_FACTOR (1 << PFREAL_SHIFT)
#define PFREAL_ONE (1 << PFREAL_SHIFT)
#define PFREAL_HALF (PFREAL_ONE >> 1)
#define IANGLE_MAX 1024
#define IANGLE_MASK 1023
#define REFLECT_TOP (LCD_HEIGHT * 2 / 3)
#define REFLECT_HEIGHT (LCD_HEIGHT - REFLECT_TOP)
#define DISPLAY_HEIGHT REFLECT_TOP
#define DISPLAY_WIDTH MAX((LCD_HEIGHT * LCD_PIXEL_ASPECT_HEIGHT / \
LCD_PIXEL_ASPECT_WIDTH / 2), (LCD_WIDTH * 2 / 5))
#define REFLECT_SC ((0x10000U * 3 + (REFLECT_HEIGHT * 5 - 1)) / \
(REFLECT_HEIGHT * 5))
#define DISPLAY_OFFS ((LCD_HEIGHT / 2) - REFLECT_HEIGHT)
#define CAM_DIST MAX(MIN(LCD_HEIGHT,LCD_WIDTH),120)
#define CAM_DIST_R (CAM_DIST << PFREAL_SHIFT)
#define DISPLAY_LEFT_R (PFREAL_HALF - LCD_WIDTH * PFREAL_HALF)
#define MAXSLIDE_LEFT_R (PFREAL_HALF - DISPLAY_WIDTH * PFREAL_HALF)
#define SLIDE_CACHE_SIZE 64 /* probably more than can be loaded */
#define MAX_SLIDES_COUNT 10
#define THREAD_STACK_SIZE DEFAULT_STACK_SIZE + 0x200
#define CACHE_PREFIX PLUGIN_DEMOS_DIR "/pictureflow"
#define EV_EXIT 9999
#define EV_WAKEUP 1337
#define EMPTY_SLIDE CACHE_PREFIX "/emptyslide.pfraw"
#define EMPTY_SLIDE_BMP PLUGIN_DEMOS_DIR "/pictureflow_emptyslide.bmp"
#define SPLASH_BMP PLUGIN_DEMOS_DIR "/pictureflow_splash.bmp"
/* Error return values */
#define ERROR_NO_ALBUMS -1
#define ERROR_BUFFER_FULL -2
/* current version for cover cache */
#define CACHE_VERSION 3
#define CONFIG_VERSION 1
#define CONFIG_FILE "pictureflow.cfg"
/** structs we use */
struct slide_data {
int slide_index;
int angle;
PFreal cx;
PFreal cy;
PFreal distance;
};
struct slide_cache {
int index; /* index of the cached slide */
int hid; /* handle ID of the cached slide */
short next; /* "next" slide, with LRU last */
short prev; /* "previous" slide */
};
struct album_data {
int name_idx;
long seek;
};
struct track_data {
uint32_t sort;
int name_idx; /* offset to the track name */
long seek;
#if PF_PLAYBACK_CAPABLE
/* offset to the filename in the string, needed for playlist generation */
int filename_idx;
#endif
};
struct rect {
int left;
int right;
int top;
int bottom;
};
struct load_slide_event_data {
int slide_index;
int cache_index;
};
struct pfraw_header {
int32_t width; /* bmap width in pixels */
int32_t height; /* bmap height in pixels */
};
enum show_album_name_values { album_name_hide = 0, album_name_bottom,
album_name_top };
static char* show_album_name_conf[] =
{
"hide",
"bottom",
"top"
};
#define MAX_SPACING 40
#define MAX_MARGIN 80
/* config values and their defaults */
static int slide_spacing = DISPLAY_WIDTH / 4;
static int center_margin = (LCD_WIDTH - DISPLAY_WIDTH) / 12;
static int num_slides = 4;
static int zoom = 100;
static bool show_fps = false;
static bool resize = true;
static int cache_version = 0;
static int show_album_name = (LCD_HEIGHT > 100)
? album_name_top : album_name_bottom;
static struct configdata config[] =
{
{ TYPE_INT, 0, MAX_SPACING, { .int_p = &slide_spacing }, "slide spacing",
NULL },
{ TYPE_INT, 0, MAX_MARGIN, { .int_p = &center_margin }, "center margin",
NULL },
{ TYPE_INT, 0, MAX_SLIDES_COUNT, { .int_p = &num_slides }, "slides count",
NULL },
{ TYPE_INT, 0, 300, { .int_p = &zoom }, "zoom", NULL },
{ TYPE_BOOL, 0, 1, { .bool_p = &show_fps }, "show fps", NULL },
{ TYPE_BOOL, 0, 1, { .bool_p = &resize }, "resize", NULL },
{ TYPE_INT, 0, 100, { .int_p = &cache_version }, "cache version", NULL },
{ TYPE_ENUM, 0, 2, { .int_p = &show_album_name }, "show album name",
show_album_name_conf }
};
#define CONFIG_NUM_ITEMS (sizeof(config) / sizeof(struct configdata))
/** below we allocate the memory we want to use **/
static pix_t *buffer; /* for now it always points to the lcd framebuffer */
static uint8_t reflect_table[REFLECT_HEIGHT];
static struct slide_data center_slide;
static struct slide_data left_slides[MAX_SLIDES_COUNT];
static struct slide_data right_slides[MAX_SLIDES_COUNT];
static int slide_frame;
static int step;
static int target;
static int fade;
static int center_index = 0; /* index of the slide that is in the center */
static int itilt;
static PFreal offsetX;
static PFreal offsetY;
static int number_of_slides;
static struct slide_cache cache[SLIDE_CACHE_SIZE];
static int cache_free;
static int cache_used = -1;
static int cache_left_index = -1;
static int cache_right_index = -1;
static int cache_center_index = -1;
/* use long for aligning */
unsigned long thread_stack[THREAD_STACK_SIZE / sizeof(long)];
/* queue (as array) for scheduling load_surface */
static int empty_slide_hid;
unsigned int thread_id;
struct event_queue thread_q;
static struct tagcache_search tcs;
static struct buflib_context buf_ctx;
static struct album_data *album;
static char *album_names;
static int album_count;
static struct track_data *tracks;
static char *track_names;
static size_t borrowed = 0;
static int track_count;
static int track_index;
static int selected_track;
static int selected_track_pulse;
void reset_track_list(void);
void * buf;
size_t buf_size;
static bool thread_is_running;
static int cover_animation_keyframe;
static int extra_fade;
static int albumtxt_x = 0;
static int albumtxt_dir = -1;
static int prev_center_index = -1;
static int start_index_track_list = 0;
static int track_list_visible_entries = 0;
static int track_list_y;
static int track_list_h;
static int track_scroll_index = 0;
static int track_scroll_dir = 1;
/*
Proposals for transitions:
pf_idle -> pf_scrolling : NEXT_ALBUM/PREV_ALBUM pressed
-> pf_cover_in -> pf_show_tracks : SELECT_ALBUM clicked
pf_scrolling -> pf_idle : NEXT_ALBUM/PREV_ALBUM released
pf_show_tracks -> pf_cover_out -> pf_idle : SELECT_ALBUM pressed
TODO:
pf_show_tracks -> pf_cover_out -> pf_idle : MENU_PRESSED pressed
pf_show_tracks -> play_track() -> exit() : SELECT_ALBUM pressed
pf_idle, pf_scrolling -> show_menu(): MENU_PRESSED
*/
enum pf_states {
pf_idle = 0,
pf_scrolling,
pf_cover_in,
pf_show_tracks,
pf_cover_out
};
static int pf_state;
/** code */
static bool free_slide_prio(int prio);
static inline unsigned fade_color(pix_t c, unsigned a);
bool save_pfraw(char* filename, struct bitmap *bm);
bool load_new_slide(void);
int load_surface(int);
static inline PFreal fmul(PFreal a, PFreal b)
{
return (a*b) >> PFREAL_SHIFT;
}
/**
* This version preshifts each operand, which is useful when we know how many
* of the least significant bits will be empty, or are worried about overflow
* in a particular calculation
*/
static inline PFreal fmuln(PFreal a, PFreal b, int ps1, int ps2)
{
return ((a >> ps1) * (b >> ps2)) >> (PFREAL_SHIFT - ps1 - ps2);
}
/* ARMv5+ has a clz instruction equivalent to our function.
*/
#if (defined(CPU_ARM) && (ARM_ARCH > 4))
static inline int clz(uint32_t v)
{
return __builtin_clz(v);
}
/* Otherwise, use our clz, which can be inlined */
#elif defined(CPU_COLDFIRE)
/* This clz is based on the log2(n) implementation at
* http://graphics.stanford.edu/~seander/bithacks.html#IntegerLog
* A clz benchmark plugin showed this to be about 14% faster on coldfire
* than the LUT-based version.
*/
static inline int clz(uint32_t v)
{
int r = 32;
if (v >= 0x10000)
{
v >>= 16;
r -= 16;
}
if (v & 0xff00)
{
v >>= 8;
r -= 8;
}
if (v & 0xf0)
{
v >>= 4;
r -= 4;
}
if (v & 0xc)
{
v >>= 2;
r -= 2;
}
if (v & 2)
{
v >>= 1;
r -= 1;
}
r -= v;
return r;
}
#else
static const char clz_lut[16] = { 4, 3, 2, 2, 1, 1, 1, 1,
0, 0, 0, 0, 0, 0, 0, 0 };
/* This clz is based on the log2(n) implementation at
* http://graphics.stanford.edu/~seander/bithacks.html#IntegerLogLookup
* It is not any faster than the one above, but trades 16B in the lookup table
* for a savings of 12B per each inlined call.
*/
static inline int clz(uint32_t v)
{
int r = 28;
if (v >= 0x10000)
{
v >>= 16;
r -= 16;
}
if (v & 0xff00)
{
v >>= 8;
r -= 8;
}
if (v & 0xf0)
{
v >>= 4;
r -= 4;
}
return r + clz_lut[v];
}
#endif
/* Return the maximum possible left shift for a signed int32, without
* overflow
*/
static inline int allowed_shift(int32_t val)
{
uint32_t uval = val ^ (val >> 31);
return clz(uval) - 1;
}
/* Calculate num/den, with the result shifted left by PFREAL_SHIFT, by shifting
* num and den before dividing.
*/
static inline PFreal fdiv(PFreal num, PFreal den)
{
int shift = allowed_shift(num);
shift = MIN(PFREAL_SHIFT, shift);
num <<= shift;
den >>= PFREAL_SHIFT - shift;
return num / den;
}
#define fmin(a,b) (((a) < (b)) ? (a) : (b))
#define fmax(a,b) (((a) > (b)) ? (a) : (b))
#define fabs(a) (a < 0 ? -a : a)
#define fbound(min,val,max) (fmax((min),fmin((max),(val))))
#if CONFIG_CPU == SH7034
/* 16*16->32 bit multiplication is a single instrcution on the SH1 */
#define MULUQ(a, b) ((uint32_t) (((uint16_t) (a)) * ((uint16_t) (b))))
#else
#define MULUQ(a, b) ((a) * (b))
#endif
#if 0
#define fmul(a,b) ( ((a)*(b)) >> PFREAL_SHIFT )
#define fdiv(n,m) ( ((n)<< PFREAL_SHIFT ) / m )
#define fconv(a, q1, q2) (((q2)>(q1)) ? (a)<<((q2)-(q1)) : (a)>>((q1)-(q2)))
#define tofloat(a, q) ( (float)(a) / (float)(1<<(q)) )
static inline PFreal fmul(PFreal a, PFreal b)
{
return (a*b) >> PFREAL_SHIFT;
}
static inline PFreal fdiv(PFreal n, PFreal m)
{
return (n<<(PFREAL_SHIFT))/m;
}
#endif
/* warning: regenerate the table if IANGLE_MAX and PFREAL_SHIFT are changed! */
static const short sin_tab[] = {
0, 100, 200, 297, 392, 483, 569, 650,
724, 792, 851, 903, 946, 980, 1004, 1019,
1024, 1019, 1004, 980, 946, 903, 851, 792,
724, 650, 569, 483, 392, 297, 200, 100,
0, -100, -200, -297, -392, -483, -569, -650,
-724, -792, -851, -903, -946, -980, -1004, -1019,
-1024, -1019, -1004, -980, -946, -903, -851, -792,
-724, -650, -569, -483, -392, -297, -200, -100,
0
};
static inline PFreal fsin(int iangle)
{
iangle &= IANGLE_MASK;
int i = (iangle >> 4);
PFreal p = sin_tab[i];
PFreal q = sin_tab[(i+1)];
PFreal g = (q - p);
return p + g * (iangle-i*16)/16;
}
static inline PFreal fcos(int iangle)
{
return fsin(iangle + (IANGLE_MAX >> 2));
}
static inline unsigned scale_val(unsigned val, unsigned bits)
{
val = val * ((1 << bits) - 1);
return ((val >> 8) + val + 128) >> 8;
}
static void output_row_8_transposed(uint32_t row, void * row_in,
struct scaler_context *ctx)
{
pix_t *dest = (pix_t*)ctx->bm->data + row;
pix_t *end = dest + ctx->bm->height * ctx->bm->width;
#ifdef USEGSLIB
uint8_t *qp = (uint8_t*)row_in;
for (; dest < end; dest += ctx->bm->height)
*dest = *qp++;
#else
struct uint8_rgb *qp = (struct uint8_rgb*)row_in;
unsigned r, g, b;
for (; dest < end; dest += ctx->bm->height)
{
r = scale_val(qp->red, 5);
g = scale_val(qp->green, 6);
b = scale_val((qp++)->blue, 5);
*dest = LCD_RGBPACK_LCD(r,g,b);
}
#endif
}
static void output_row_32_transposed(uint32_t row, void * row_in,
struct scaler_context *ctx)
{
pix_t *dest = (pix_t*)ctx->bm->data + row;
pix_t *end = dest + ctx->bm->height * ctx->bm->width;
#ifdef USEGSLIB
uint32_t *qp = (uint32_t*)row_in;
for (; dest < end; dest += ctx->bm->height)
*dest = SC_OUT(*qp++, ctx);
#else
struct uint32_rgb *qp = (struct uint32_rgb*)row_in;
int r, g, b;
for (; dest < end; dest += ctx->bm->height)
{
r = scale_val(SC_OUT(qp->r, ctx), 5);
g = scale_val(SC_OUT(qp->g, ctx), 6);
b = scale_val(SC_OUT(qp->b, ctx), 5);
qp++;
*dest = LCD_RGBPACK_LCD(r,g,b);
}
#endif
}
#ifdef HAVE_LCD_COLOR
static void output_row_32_transposed_fromyuv(uint32_t row, void * row_in,
struct scaler_context *ctx)
{
pix_t *dest = (pix_t*)ctx->bm->data + row;
pix_t *end = dest + ctx->bm->height * ctx->bm->width;
struct uint32_rgb *qp = (struct uint32_rgb*)row_in;
for (; dest < end; dest += ctx->bm->height)
{
unsigned r, g, b, y, u, v;
y = SC_OUT(qp->b, ctx);
u = SC_OUT(qp->g, ctx);
v = SC_OUT(qp->r, ctx);
qp++;
yuv_to_rgb(y, u, v, &r, &g, &b);
r = scale_val(r, 5);
g = scale_val(g, 6);
b = scale_val(b, 5);
*dest = LCD_RGBPACK_LCD(r, g, b);
}
}
#endif
static unsigned int get_size(struct bitmap *bm)
{
return bm->width * bm->height * sizeof(pix_t);
}
const struct custom_format format_transposed = {
.output_row_8 = output_row_8_transposed,
#ifdef HAVE_LCD_COLOR
.output_row_32 = {
output_row_32_transposed,
output_row_32_transposed_fromyuv
},
#else
.output_row_32 = output_row_32_transposed,
#endif
.get_size = get_size
};
static const struct button_mapping* get_context_map(int context)
{
return pf_contexts[context & ~CONTEXT_PLUGIN];
}
/* Create the lookup table with the scaling values for the reflections */
void init_reflect_table(void)
{
int i;
for (i = 0; i < REFLECT_HEIGHT; i++)
reflect_table[i] =
(768 * (REFLECT_HEIGHT - i) + (5 * REFLECT_HEIGHT / 2)) /
(5 * REFLECT_HEIGHT);
}
/**
Create an index of all albums from the database.
Also store the album names so we can access them later.
*/
int create_album_index(void)
{
album = ((struct album_data *)(buf_size + (char *) buf)) - 1;
rb->memset(&tcs, 0, sizeof(struct tagcache_search) );
album_count = 0;
rb->tagcache_search(&tcs, tag_album);
unsigned int l, old_l = 0;
album_names = buf;
album[0].name_idx = 0;
while (rb->tagcache_get_next(&tcs))
{
buf_size -= sizeof(struct album_data);
l = tcs.result_len;
if ( album_count > 0 )
album[-album_count].name_idx = album[1-album_count].name_idx + old_l;
if ( l > buf_size )
/* not enough memory */
return ERROR_BUFFER_FULL;
rb->strcpy(buf, tcs.result);
buf_size -= l;
buf = l + (char *)buf;
album[-album_count].seek = tcs.result_seek;
old_l = l;
album_count++;
}
rb->tagcache_search_finish(&tcs);
ALIGN_BUFFER(buf, buf_size, 4);
int i;
struct album_data* tmp_album = (struct album_data*)buf;
for (i = album_count - 1; i >= 0; i--)
tmp_album[i] = album[-i];
album = tmp_album;
buf = album + album_count;
return (album_count > 0) ? 0 : ERROR_NO_ALBUMS;
}
/**
Return a pointer to the album name of the given slide_index
*/
char* get_album_name(const int slide_index)
{
return album_names + album[slide_index].name_idx;
}
/**
Return a pointer to the track name of the active album
create_track_index has to be called first.
*/
char* get_track_name(const int track_index)
{
if ( track_index < track_count )
return track_names + tracks[track_index].name_idx;
return 0;
}
#if PF_PLAYBACK_CAPABLE
char* get_track_filename(const int track_index)
{
if ( track_index < track_count )
return track_names + tracks[track_index].filename_idx;
return 0;
}
#endif
/**
Compare two unsigned ints passed via pointers.
*/
int compare_tracks (const void *a_v, const void *b_v)
{
uint32_t a = ((struct track_data *)a_v)->sort;
uint32_t b = ((struct track_data *)b_v)->sort;
return (int)(a - b);
}
/**
Create the track index of the given slide_index.
*/
void create_track_index(const int slide_index)
{
if ( slide_index == track_index )
return;
track_index = slide_index;
if (!rb->tagcache_search(&tcs, tag_title))
goto fail;
rb->tagcache_search_add_filter(&tcs, tag_album, album[slide_index].seek);
track_count=0;
int string_index = 0, track_num;
int disc_num;
size_t out = 0;
track_names = (char *)buflib_buffer_out(&buf_ctx, &out);
borrowed += out;
int avail = borrowed;
tracks = (struct track_data*)(track_names + borrowed);
while (rb->tagcache_get_next(&tcs))
{
int len = 0, fn_idx = 0;
avail -= sizeof(struct track_data);
track_num = rb->tagcache_get_numeric(&tcs, tag_tracknumber) - 1;
disc_num = rb->tagcache_get_numeric(&tcs, tag_discnumber);
if (disc_num < 0)
disc_num = 0;
retry:
if (track_num >= 0)
{
if (disc_num)
fn_idx = 1 + rb->snprintf(track_names + string_index , avail,
"%d.%02d: %s", disc_num, track_num + 1, tcs.result);
else
fn_idx = 1 + rb->snprintf(track_names + string_index , avail,
"%d: %s", track_num + 1, tcs.result);
}
else
{
track_num = 0;
fn_idx = 1 + rb->snprintf(track_names + string_index, avail,
"%s", tcs.result);
}
if (fn_idx <= 0)
goto fail;
#if PF_PLAYBACK_CAPABLE
int remain = avail - fn_idx;
if (remain >= MAX_PATH)
{ /* retrieve filename for building the playlist */
rb->tagcache_retrieve(&tcs, tcs.idx_id, tag_filename,
track_names + string_index + fn_idx, remain);
len = fn_idx + rb->strlen(track_names + string_index + fn_idx) + 1;
/* make sure track name and file name are really split by a \0, else
* get_track_name might fail */
*(track_names + string_index + fn_idx -1) = '\0';
}
else /* request more buffer so that track and filename fit */
len = (avail - remain) + MAX_PATH;
#else
len = fn_idx;
#endif
if (len > avail)
{
while (len > avail)
{
if (!free_slide_prio(0))
goto fail;
out = 0;
buflib_buffer_out(&buf_ctx, &out);
avail += out;
borrowed += out;
if (track_count)
{
struct track_data *new_tracks = (struct track_data *)(out + (uintptr_t)tracks);
unsigned int bytes = track_count * sizeof(struct track_data);
rb->memmove(new_tracks, tracks, bytes);
tracks = new_tracks;
}
}
goto retry;
}
avail -= len;
tracks--;
tracks->sort = ((disc_num - 1) << 24) + (track_num << 14) + track_count;
tracks->name_idx = string_index;
tracks->seek = tcs.result_seek;
#if PF_PLAYBACK_CAPABLE
tracks->filename_idx = fn_idx + string_index;
#endif
track_count++;
string_index += len;
}
rb->tagcache_search_finish(&tcs);
/* now fix the track list order */
rb->qsort(tracks, track_count, sizeof(struct track_data), compare_tracks);
return;
fail:
track_count = 0;
return;
}
/**
Determine filename of the album art for the given slide_index and
store the result in buf.
The algorithm looks for the first track of the given album uses
find_albumart to find the filename.
*/
bool get_albumart_for_index_from_db(const int slide_index, char *buf,
int buflen)
{
if ( slide_index == -1 )
{
rb->strlcpy( buf, EMPTY_SLIDE, buflen );
}
if (!rb->tagcache_search(&tcs, tag_filename))
return false;
bool result;
/* find the first track of the album */
rb->tagcache_search_add_filter(&tcs, tag_album, album[slide_index].seek);
if ( rb->tagcache_get_next(&tcs) ) {
struct mp3entry id3;
int fd;
#ifdef HAVE_TC_RAMCACHE
if (rb->tagcache_fill_tags(&id3, tcs.result))
{
rb->strlcpy(id3.path, tcs.result, sizeof(id3.path));
}
else
#endif
{
fd = rb->open(tcs.result, O_RDONLY);
rb->get_metadata(&id3, fd, tcs.result);
rb->close(fd);
}
if ( search_albumart_files(&id3, ":", buf, buflen) )
result = true;
else
result = false;
}
else {
/* did not find a matching track */
result = false;
}
rb->tagcache_search_finish(&tcs);
return result;
}
/**
Draw the PictureFlow logo
*/
void draw_splashscreen(void)
{
unsigned char * buf_tmp = buf;
size_t buf_tmp_size = buf_size;
struct screen* display = rb->screens[0];
#if FB_DATA_SZ > 1
ALIGN_BUFFER(buf_tmp, buf_tmp_size, sizeof(fb_data));
#endif
struct bitmap logo = {
#if LCD_WIDTH < 200
.width = 100,
.height = 18,
#else
.width = 193,
.height = 34,
#endif
.data = buf_tmp
};
int ret = rb->read_bmp_file(SPLASH_BMP, &logo, buf_tmp_size, FORMAT_NATIVE,
NULL);
#if LCD_DEPTH > 1
rb->lcd_set_background(N_BRIGHT(0));
rb->lcd_set_foreground(N_BRIGHT(255));
#else
rb->lcd_set_drawmode(PICTUREFLOW_DRMODE);
#endif
rb->lcd_clear_display();
if (ret > 0)
{
#if LCD_DEPTH == 1 /* Mono LCDs need the logo inverted */
rb->lcd_set_drawmode(PICTUREFLOW_DRMODE ^ DRMODE_INVERSEVID);
#endif
display->bitmap(logo.data, (LCD_WIDTH - logo.width) / 2, 10,
logo.width, logo.height);
#if LCD_DEPTH == 1 /* Mono LCDs need the logo inverted */
rb->lcd_set_drawmode(PICTUREFLOW_DRMODE);
#endif
}
rb->lcd_update();
}
/**
Draw a simple progress bar
*/
void draw_progressbar(int step)
{
int txt_w, txt_h;
const int bar_height = 22;
const int w = LCD_WIDTH - 20;
const int x = 10;
rb->lcd_getstringsize("Preparing album artwork", &txt_w, &txt_h);
int y = (LCD_HEIGHT - txt_h)/2;
rb->lcd_putsxy((LCD_WIDTH - txt_w)/2, y, "Preparing album artwork");
y += (txt_h + 5);
#if LCD_DEPTH > 1
rb->lcd_set_foreground(N_BRIGHT(100));
#endif
rb->lcd_drawrect(x, y, w+2, bar_height);
#if LCD_DEPTH > 1
rb->lcd_set_foreground(N_PIX(165, 231, 82));
#endif
rb->lcd_fillrect(x+1, y+1, step * w / album_count, bar_height-2);
#if LCD_DEPTH > 1
rb->lcd_set_foreground(N_BRIGHT(255));
#endif
rb->lcd_update();
rb->yield();
}
/**
Precomupte the album art images and store them in CACHE_PREFIX.
*/
bool create_albumart_cache(void)
{
int ret;
int i, slides = 0;
struct bitmap input_bmp;
char pfraw_file[MAX_PATH];
char albumart_file[MAX_PATH];
unsigned int format = FORMAT_NATIVE;
cache_version = 0;
configfile_save(CONFIG_FILE, config, CONFIG_NUM_ITEMS, CONFIG_VERSION);
if (resize)
format |= FORMAT_RESIZE|FORMAT_KEEP_ASPECT;
for (i=0; i < album_count; i++)
{
rb->snprintf(pfraw_file, sizeof(pfraw_file), CACHE_PREFIX "/%d.pfraw",
i);
/* delete existing cache, so it's a true rebuild */
if(rb->file_exists(pfraw_file))
rb->remove(pfraw_file);
draw_progressbar(i);
if (!get_albumart_for_index_from_db(i, albumart_file, MAX_PATH))
continue;
input_bmp.data = buf;
input_bmp.width = DISPLAY_WIDTH;
input_bmp.height = DISPLAY_HEIGHT;
ret = read_image_file(albumart_file, &input_bmp,
buf_size, format, &format_transposed);
if (ret <= 0) {
rb->splash(HZ, "Could not read bmp");
continue; /* skip missing/broken files */
}
if (!save_pfraw(pfraw_file, &input_bmp))
{
rb->splash(HZ, "Could not write bmp");
}
slides++;
if ( rb->button_get(false) == PF_MENU ) return false;
}
if ( slides == 0 ) {
/* Warn the user that we couldn't find any albumart */
rb->splash(2*HZ, "No album art found");
return false;
}
return true;
}
/**
Thread used for loading and preparing bitmaps in the background
*/
void thread(void)
{
long sleep_time = 5 * HZ;
struct queue_event ev;
while (1) {
rb->queue_wait_w_tmo(&thread_q, &ev, sleep_time);
switch (ev.id) {
case EV_EXIT:
return;
case EV_WAKEUP:
/* we just woke up */
break;
}
while ( load_new_slide() ) {
rb->yield();
switch (ev.id) {
case EV_EXIT:
return;
}
}
}
}
/**
End the thread by posting the EV_EXIT event
*/
void end_pf_thread(void)
{
if ( thread_is_running ) {
rb->queue_post(&thread_q, EV_EXIT, 0);
rb->thread_wait(thread_id);
/* remove the thread's queue from the broadcast list */
rb->queue_delete(&thread_q);
thread_is_running = false;
}
}
/**
Create the thread an setup the event queue
*/
bool create_pf_thread(void)
{
/* put the thread's queue in the bcast list */
rb->queue_init(&thread_q, true);
if ((thread_id = rb->create_thread(
thread,
thread_stack,
sizeof(thread_stack),
0,
"Picture load thread"
IF_PRIO(, MAX(PRIORITY_USER_INTERFACE / 2,
PRIORITY_REALTIME + 1))
IF_COP(, CPU)
)
) == 0) {
return false;
}
thread_is_running = true;
rb->queue_post(&thread_q, EV_WAKEUP, 0);
return true;
}
/**
Safe the given bitmap as filename in the pfraw format
*/
bool save_pfraw(char* filename, struct bitmap *bm)
{
struct pfraw_header bmph;
bmph.width = bm->width;
bmph.height = bm->height;
int fh = rb->creat( filename );
if( fh < 0 ) return false;
rb->write( fh, &bmph, sizeof( struct pfraw_header ) );
int y;
for( y = 0; y < bm->height; y++ )
{
pix_t *d = (pix_t*)( bm->data ) + (y*bm->width);
rb->write( fh, d, sizeof( pix_t ) * bm->width );
}
rb->close( fh );
return true;
}
/*
* The following functions implement the linked-list-in-array used to manage
* the LRU cache of slides, and the list of free cache slots.
*/
#define seek_right_while(start, cond) \
({ \
int ind_, next_ = (start); \
do { \
ind_ = next_; \
next_ = cache[ind_].next; \
} while (next_ != cache_used && (cond)); \
ind_; \
})
#define seek_left_while(start, cond) \
({ \
int ind_, next_ = (start); \
do { \
ind_ = next_; \
next_ = cache[ind_].prev; \
} while (ind_ != cache_used && (cond)); \
ind_; \
})
/**
Pop the given item from the linked list starting at *head, returning the next
item, or -1 if the list is now empty.
*/
static inline int lla_pop_item (int *head, int i)
{
int prev = cache[i].prev;
int next = cache[i].next;
if (i == next)
{
*head = -1;
return -1;
}
else if (i == *head)
*head = next;
cache[next].prev = prev;
cache[prev].next = next;
return next;
}
/**
Pop the head item from the list starting at *head, returning the index of the
item, or -1 if the list is already empty.
*/
static inline int lla_pop_head (int *head)
{
int i = *head;
if (i != -1)
lla_pop_item(head, i);
return i;
}
/**
Insert the item at index i before the one at index p.
*/
static inline void lla_insert (int i, int p)
{
int next = p;
int prev = cache[next].prev;
cache[next].prev = i;
cache[prev].next = i;
cache[i].next = next;
cache[i].prev = prev;
}
/**
Insert the item at index i at the end of the list starting at *head.
*/
static inline void lla_insert_tail (int *head, int i)
{
if (*head == -1)
{
*head = i;
cache[i].next = i;
cache[i].prev = i;
} else
lla_insert(i, *head);
}
/**
Insert the item at index i before the one at index p.
*/
static inline void lla_insert_after(int i, int p)
{
p = cache[p].next;
lla_insert(i, p);
}
/**
Insert the item at index i before the one at index p in the list starting at
*head
*/
static inline void lla_insert_before(int *head, int i, int p)
{
lla_insert(i, p);
if (*head == p)
*head = i;
}
/**
Free the used slide at index i, and its buffer, and move it to the free
slides list.
*/
static inline void free_slide(int i)
{
if (cache[i].hid != empty_slide_hid)
buflib_free(&buf_ctx, cache[i].hid);
cache[i].index = -1;
lla_pop_item(&cache_used, i);
lla_insert_tail(&cache_free, i);
if (cache_used == -1)
{
cache_right_index = -1;
cache_left_index = -1;
cache_center_index = -1;
}
}
/**
Free one slide ranked above the given priority. If no such slide can be found,
return false.
*/
static bool free_slide_prio(int prio)
{
if (cache_used == -1)
return false;
int i, l = cache_used, r = cache[cache_used].prev, prio_max;
int prio_l = cache[l].index < center_index ?
center_index - cache[l].index : 0;
int prio_r = cache[r].index > center_index ?
cache[r].index - center_index : 0;
if (prio_l > prio_r)
{
i = l;
prio_max = prio_l;
} else {
i = r;
prio_max = prio_r;
}
if (prio_max > prio)
{
if (i == cache_left_index)
cache_left_index = cache[i].next;
if (i == cache_right_index)
cache_right_index = cache[i].prev;
free_slide(i);
return true;
} else
return false;
}
/**
Read the pfraw image given as filename and return the hid of the buffer
*/
int read_pfraw(char* filename, int prio)
{
struct pfraw_header bmph;
int fh = rb->open(filename, O_RDONLY);
if( fh < 0 )
return empty_slide_hid;
else
rb->read(fh, &bmph, sizeof(struct pfraw_header));
int size = sizeof(struct bitmap) + sizeof( pix_t ) *
bmph.width * bmph.height;
int hid;
while (!(hid = buflib_alloc(&buf_ctx, size)) && free_slide_prio(prio));
if (!hid) {
rb->close( fh );
return 0;
}
struct dim *bm = buflib_get_data(&buf_ctx, hid);
bm->width = bmph.width;
bm->height = bmph.height;
pix_t *data = (pix_t*)(sizeof(struct dim) + (char *)bm);
int y;
for( y = 0; y < bm->height; y++ )
{
rb->read( fh, data , sizeof( pix_t ) * bm->width );
data += bm->width;
}
rb->close( fh );
return hid;
}
/**
Load the surface for the given slide_index into the cache at cache_index.
*/
static inline bool load_and_prepare_surface(const int slide_index,
const int cache_index,
const int prio)
{
char tmp_path_name[MAX_PATH+1];
rb->snprintf(tmp_path_name, sizeof(tmp_path_name), CACHE_PREFIX "/%d.pfraw",
slide_index);
int hid = read_pfraw(tmp_path_name, prio);
if (!hid)
return false;
cache[cache_index].hid = hid;
if ( cache_index < SLIDE_CACHE_SIZE ) {
cache[cache_index].index = slide_index;
}
return true;
}
/**
Load the "next" slide that we can load, freeing old slides if needed, provided
that they are further from center_index than the current slide
*/
bool load_new_slide(void)
{
int i = -1;
if (cache_center_index != -1)
{
int next, prev;
if (cache[cache_center_index].index != center_index)
{
if (cache[cache_center_index].index < center_index)
{
cache_center_index = seek_right_while(cache_center_index,
cache[next_].index <= center_index);
prev = cache_center_index;
next = cache[cache_center_index].next;
}
else
{
cache_center_index = seek_left_while(cache_center_index,
cache[next_].index >= center_index);
next = cache_center_index;
prev = cache[cache_center_index].prev;
}
if (cache[cache_center_index].index != center_index)
{
if (cache_free == -1)
free_slide_prio(0);
i = lla_pop_head(&cache_free);
if (!load_and_prepare_surface(center_index, i, 0))
goto fail_and_refree;
if (cache[next].index == -1)
{
if (cache[prev].index == -1)
goto insert_first_slide;
else
next = cache[prev].next;
}
lla_insert(i, next);
if (cache[i].index < cache[cache_used].index)
cache_used = i;
cache_center_index = i;
cache_left_index = i;
cache_right_index = i;
return true;
}
}
if (cache[cache_left_index].index >
cache[cache_center_index].index)
cache_left_index = cache_center_index;
if (cache[cache_right_index].index <
cache[cache_center_index].index)
cache_right_index = cache_center_index;
cache_left_index = seek_left_while(cache_left_index,
cache[ind_].index - 1 == cache[next_].index);
cache_right_index = seek_right_while(cache_right_index,
cache[ind_].index - 1 == cache[next_].index);
int prio_l = cache[cache_center_index].index -
cache[cache_left_index].index + 1;
int prio_r = cache[cache_right_index].index -
cache[cache_center_index].index + 1;
if ((prio_l < prio_r ||
cache[cache_right_index].index >= number_of_slides) &&
cache[cache_left_index].index > 0)
{
if (cache_free == -1 && !free_slide_prio(prio_l))
return false;
i = lla_pop_head(&cache_free);
if (load_and_prepare_surface(cache[cache_left_index].index
- 1, i, prio_l))
{
lla_insert_before(&cache_used, i, cache_left_index);
cache_left_index = i;
return true;
}
} else if(cache[cache_right_index].index < number_of_slides - 1)
{
if (cache_free == -1 && !free_slide_prio(prio_r))
return false;
i = lla_pop_head(&cache_free);
if (load_and_prepare_surface(cache[cache_right_index].index
+ 1, i, prio_r))
{
lla_insert_after(i, cache_right_index);
cache_right_index = i;
return true;
}
}
} else {
i = lla_pop_head(&cache_free);
if (load_and_prepare_surface(center_index, i, 0))
{
insert_first_slide:
cache[i].next = i;
cache[i].prev = i;
cache_center_index = i;
cache_left_index = i;
cache_right_index = i;
cache_used = i;
return true;
}
}
fail_and_refree:
if (i != -1)
{
lla_insert_tail(&cache_free, i);
}
return false;
}
/**
Get a slide from the buffer
*/
static inline struct dim *get_slide(const int hid)
{
if (!hid)
return NULL;
struct dim *bmp;
bmp = buflib_get_data(&buf_ctx, hid);
return bmp;
}
/**
Return the requested surface
*/
static inline struct dim *surface(const int slide_index)
{
if (slide_index < 0)
return 0;
if (slide_index >= number_of_slides)
return 0;
int i;
if ((i = cache_used ) != -1)
{
do {
if (cache[i].index == slide_index)
return get_slide(cache[i].hid);
i = cache[i].next;
} while (i != cache_used);
}
return get_slide(empty_slide_hid);
}
/**
adjust slides so that they are in "steady state" position
*/
void reset_slides(void)
{
center_slide.angle = 0;
center_slide.cx = 0;
center_slide.cy = 0;
center_slide.distance = 0;
center_slide.slide_index = center_index;
int i;
for (i = 0; i < num_slides; i++) {
struct slide_data *si = &left_slides[i];
si->angle = itilt;
si->cx = -(offsetX + slide_spacing * i * PFREAL_ONE);
si->cy = offsetY;
si->slide_index = center_index - 1 - i;
si->distance = 0;
}
for (i = 0; i < num_slides; i++) {
struct slide_data *si = &right_slides[i];
si->angle = -itilt;
si->cx = offsetX + slide_spacing * i * PFREAL_ONE;
si->cy = offsetY;
si->slide_index = center_index + 1 + i;
si->distance = 0;
}
}
/**
Updates look-up table and other stuff necessary for the rendering.
Call this when the viewport size or slide dimension is changed.
*
* To calculate the offset that will provide the proper margin, we use the same
* projection used to render the slides. The solution for xc, the slide center,
* is:
* xp * (zo + xs * sin(r))
* xc = xp - xs * cos(r) + ───────────────────────
* z
* TODO: support moving the side slides toward or away from the camera
*/
void recalc_offsets(void)
{
PFreal xs = PFREAL_HALF - DISPLAY_WIDTH * PFREAL_HALF;
PFreal zo;
PFreal xp = (DISPLAY_WIDTH * PFREAL_HALF - PFREAL_HALF + center_margin *
PFREAL_ONE) * zoom / 100;
PFreal cosr, sinr;
itilt = 70 * IANGLE_MAX / 360; /* approx. 70 degrees tilted */
cosr = fcos(-itilt);
sinr = fsin(-itilt);
zo = CAM_DIST_R * 100 / zoom - CAM_DIST_R +
fmuln(MAXSLIDE_LEFT_R, sinr, PFREAL_SHIFT - 2, 0);
offsetX = xp - fmul(xs, cosr) + fmuln(xp,
zo + fmuln(xs, sinr, PFREAL_SHIFT - 2, 0), PFREAL_SHIFT - 2, 0)
/ CAM_DIST;
offsetY = DISPLAY_WIDTH / 2 * (fsin(itilt) + PFREAL_ONE / 2);
}
/**
Fade the given color by spreading the fb_data (ushort)
to an uint, multiply and compress the result back to a ushort.
*/
#if (LCD_PIXELFORMAT == RGB565SWAPPED)
static inline unsigned fade_color(pix_t c, unsigned a)
{
unsigned int result;
c = swap16(c);
a = (a + 2) & 0x1fc;
result = ((c & 0xf81f) * a) & 0xf81f00;
result |= ((c & 0x7e0) * a) & 0x7e000;
result >>= 8;
return swap16(result);
}
#elif LCD_PIXELFORMAT == RGB565
static inline unsigned fade_color(pix_t c, unsigned a)
{
unsigned int result;
a = (a + 2) & 0x1fc;
result = ((c & 0xf81f) * a) & 0xf81f00;
result |= ((c & 0x7e0) * a) & 0x7e000;
result >>= 8;
return result;
}
#else
static inline unsigned fade_color(pix_t c, unsigned a)
{
unsigned val = c;
return MULUQ(val, a) >> 8;
}
#endif
/**
* Render a single slide
* Where xc is the slide's horizontal offset from center, xs is the horizontal
* on the slide from its center, zo is the slide's depth offset from the plane
* of the display, r is the angle at which the slide is tilted, and xp is the
* point on the display corresponding to xs on the slide, the projection
* formulas are:
*
* z * (xc + xs * cos(r))
* xp = ──────────────────────
* z + zo + xs * sin(r)
*
* z * (xc - xp) - xp * zo
* xs = ────────────────────────
* xp * sin(r) - z * cos(r)
*
* We use the xp projection once, to find the left edge of the slide on the
* display. From there, we use the xs reverse projection to find the horizontal
* offset from the slide center of each column on the screen, until we reach
* the right edge of the slide, or the screen. The reverse projection can be
* optimized by saving the numerator and denominator of the fraction, which can
* then be incremented by (z + zo) and sin(r) respectively.
*/
void render_slide(struct slide_data *slide, const int alpha)
{
struct dim *bmp = surface(slide->slide_index);
if (!bmp) {
return;
}
if (slide->angle > 255 || slide->angle < -255)
return;
pix_t *src = (pix_t*)(sizeof(struct dim) + (char *)bmp);
const int sw = bmp->width;
const int sh = bmp->height;
const PFreal slide_left = -sw * PFREAL_HALF + PFREAL_HALF;
const int w = LCD_WIDTH;
uint8_t reftab[REFLECT_HEIGHT]; /* on stack, which is in IRAM on several targets */
if (alpha == 256) { /* opaque -> copy table */
rb->memcpy(reftab, reflect_table, sizeof(reftab));
} else { /* precalculate faded table */
int i, lalpha;
for (i = 0; i < REFLECT_HEIGHT; i++) {
lalpha = reflect_table[i];
reftab[i] = (MULUQ(lalpha, alpha) + 129) >> 8;
}
}
PFreal cosr = fcos(slide->angle);
PFreal sinr = fsin(slide->angle);
PFreal zo = PFREAL_ONE * slide->distance + CAM_DIST_R * 100 / zoom
- CAM_DIST_R - fmuln(MAXSLIDE_LEFT_R, fabs(sinr), PFREAL_SHIFT - 2, 0);
PFreal xs = slide_left, xsnum, xsnumi, xsden, xsdeni;
PFreal xp = fdiv(CAM_DIST * (slide->cx + fmul(xs, cosr)),
(CAM_DIST_R + zo + fmul(xs,sinr)));
/* Since we're finding the screen position of the left edge of the slide,
* we round up.
*/
int xi = (fmax(DISPLAY_LEFT_R, xp) - DISPLAY_LEFT_R + PFREAL_ONE - 1)
>> PFREAL_SHIFT;
xp = DISPLAY_LEFT_R + xi * PFREAL_ONE;
if (xi >= w) {
return;
}
xsnum = CAM_DIST * (slide->cx - xp) - fmuln(xp, zo, PFREAL_SHIFT - 2, 0);
xsden = fmuln(xp, sinr, PFREAL_SHIFT - 2, 0) - CAM_DIST * cosr;
xs = fdiv(xsnum, xsden);
xsnumi = -CAM_DIST_R - zo;
xsdeni = sinr;
int x;
int dy = PFREAL_ONE;
for (x = xi; x < w; x++) {
int column = (xs - slide_left) / PFREAL_ONE;
if (column >= sw)
break;
if (zo || slide->angle)
dy = (CAM_DIST_R + zo + fmul(xs, sinr)) / CAM_DIST;
const pix_t *ptr = &src[column * bmp->height];
#if defined(LCD_STRIDEFORMAT) && LCD_STRIDEFORMAT == VERTICAL_STRIDE
#define PIXELSTEP_Y 1
#define LCDADDR(x, y) (&buffer[BUFFER_HEIGHT*(x) + (y)])
#else
#define PIXELSTEP_Y BUFFER_WIDTH
#define LCDADDR(x, y) (&buffer[(y)*BUFFER_WIDTH + (x)])
#endif
int p = (bmp->height-1-DISPLAY_OFFS) * PFREAL_ONE;
int plim = MAX(0, p - (LCD_HEIGHT/2-1) * dy);
pix_t *pixel = LCDADDR(x, (LCD_HEIGHT/2)-1 );
if (alpha == 256) {
while (p >= plim) {
*pixel = ptr[((unsigned)p) >> PFREAL_SHIFT];
p -= dy;
pixel -= PIXELSTEP_Y;
}
} else {
while (p >= plim) {
*pixel = fade_color(ptr[((unsigned)p) >> PFREAL_SHIFT], alpha);
p -= dy;
pixel -= PIXELSTEP_Y;
}
}
p = (bmp->height-DISPLAY_OFFS) * PFREAL_ONE;
plim = MIN(sh * PFREAL_ONE, p + (LCD_HEIGHT/2) * dy);
int plim2 = MIN(MIN(sh + REFLECT_HEIGHT, sh * 2) * PFREAL_ONE,
p + (LCD_HEIGHT/2) * dy);
pixel = LCDADDR(x, (LCD_HEIGHT/2) );
if (alpha == 256) {
while (p < plim) {
*pixel = ptr[((unsigned)p) >> PFREAL_SHIFT];
p += dy;
pixel += PIXELSTEP_Y;
}
} else {
while (p < plim) {
*pixel = fade_color(ptr[((unsigned)p) >> PFREAL_SHIFT], alpha);
p += dy;
pixel += PIXELSTEP_Y;
}
}
while (p < plim2) {
int ty = (((unsigned)p) >> PFREAL_SHIFT) - sh;
int lalpha = reftab[ty];
*pixel = fade_color(ptr[sh - 1 - ty], lalpha);
p += dy;
pixel += PIXELSTEP_Y;
}
if (zo || slide->angle)
{
xsnum += xsnumi;
xsden += xsdeni;
xs = fdiv(xsnum, xsden);
} else
xs += PFREAL_ONE;
}
/* let the music play... */
rb->yield();
return;
}
/**
Jump the the given slide_index
*/
static inline void set_current_slide(const int slide_index)
{
int old_center_index = center_index;
step = 0;
center_index = fbound(slide_index, 0, number_of_slides - 1);
if (old_center_index != center_index)
rb->queue_post(&thread_q, EV_WAKEUP, 0);
target = center_index;
slide_frame = slide_index << 16;
reset_slides();
}
/**
Start the animation for changing slides
*/
void start_animation(void)
{
step = (target < center_slide.slide_index) ? -1 : 1;
pf_state = pf_scrolling;
}
/**
Go to the previous slide
*/
void show_previous_slide(void)
{
if (step == 0) {
if (center_index > 0) {
target = center_index - 1;
start_animation();
}
} else if ( step > 0 ) {
target = center_index;
start_animation();
} else {
target = fmax(0, center_index - 2);
}
}
/**
Go to the next slide
*/
void show_next_slide(void)
{
if (step == 0) {
if (center_index < number_of_slides - 1) {
target = center_index + 1;
start_animation();
}
} else if ( step < 0 ) {
target = center_index;
start_animation();
} else {
target = fmin(center_index + 2, number_of_slides - 1);
}
}
/**
Render the slides. Updates only the offscreen buffer.
*/
void render_all_slides(void)
{
MYLCD(set_background)(G_BRIGHT(0));
/* TODO: Optimizes this by e.g. invalidating rects */
MYLCD(clear_display)();
int nleft = num_slides;
int nright = num_slides;
int index;
if (step == 0) {
/* no animation, boring plain rendering */
for (index = nleft - 2; index >= 0; index--) {
int alpha = (index < nleft - 2) ? 256 : 128;
alpha -= extra_fade;
if (alpha > 0 )
render_slide(&left_slides[index], alpha);
}
for (index = nright - 2; index >= 0; index--) {
int alpha = (index < nright - 2) ? 256 : 128;
alpha -= extra_fade;
if (alpha > 0 )
render_slide(&right_slides[index], alpha);
}
} else {
/* the first and last slide must fade in/fade out */
for (index = nleft - 1; index >= 0; index--) {
int alpha = 256;
if (index == nleft - 1)
alpha = (step > 0) ? 0 : 128 - fade / 2;
if (index == nleft - 2)
alpha = (step > 0) ? 128 - fade / 2 : 256 - fade / 2;
if (index == nleft - 3)
alpha = (step > 0) ? 256 - fade / 2 : 256;
render_slide(&left_slides[index], alpha);
}
for (index = nright - 1; index >= 0; index--) {
int alpha = (index < nright - 2) ? 256 : 128;
if (index == nright - 1)
alpha = (step > 0) ? fade / 2 : 0;
if (index == nright - 2)
alpha = (step > 0) ? 128 + fade / 2 : fade / 2;
if (index == nright - 3)
alpha = (step > 0) ? 256 : 128 + fade / 2;
render_slide(&right_slides[index], alpha);
}
}
render_slide(&center_slide, 256);
}
/**
Updates the animation effect. Call this periodically from a timer.
*/
void update_scroll_animation(void)
{
if (step == 0)
return;
int speed = 16384;
int i;
/* deaccelerate when approaching the target */
if (true) {
const int max = 2 * 65536;
int fi = slide_frame;
fi -= (target << 16);
if (fi < 0)
fi = -fi;
fi = fmin(fi, max);
int ia = IANGLE_MAX * (fi - max / 2) / (max * 2);
speed = 512 + 16384 * (PFREAL_ONE + fsin(ia)) / PFREAL_ONE;
}
slide_frame += speed * step;
int index = slide_frame >> 16;
int pos = slide_frame & 0xffff;
int neg = 65536 - pos;
int tick = (step < 0) ? neg : pos;
PFreal ftick = (tick * PFREAL_ONE) >> 16;
/* the leftmost and rightmost slide must fade away */
fade = pos / 256;
if (step < 0)
index++;
if (center_index != index) {
center_index = index;
rb->queue_post(&thread_q, EV_WAKEUP, 0);
slide_frame = index << 16;
center_slide.slide_index = center_index;
for (i = 0; i < num_slides; i++)
left_slides[i].slide_index = center_index - 1 - i;
for (i = 0; i < num_slides; i++)
right_slides[i].slide_index = center_index + 1 + i;
}
center_slide.angle = (step * tick * itilt) >> 16;
center_slide.cx = -step * fmul(offsetX, ftick);
center_slide.cy = fmul(offsetY, ftick);
if (center_index == target) {
reset_slides();
pf_state = pf_idle;
step = 0;
fade = 256;
return;
}
for (i = 0; i < num_slides; i++) {
struct slide_data *si = &left_slides[i];
si->angle = itilt;
si->cx =
-(offsetX + slide_spacing * i * PFREAL_ONE + step
* slide_spacing * ftick);
si->cy = offsetY;
}
for (i = 0; i < num_slides; i++) {
struct slide_data *si = &right_slides[i];
si->angle = -itilt;
si->cx =
offsetX + slide_spacing * i * PFREAL_ONE - step
* slide_spacing * ftick;
si->cy = offsetY;
}
if (step > 0) {
PFreal ftick = (neg * PFREAL_ONE) >> 16;
right_slides[0].angle = -(neg * itilt) >> 16;
right_slides[0].cx = fmul(offsetX, ftick);
right_slides[0].cy = fmul(offsetY, ftick);
} else {
PFreal ftick = (pos * PFREAL_ONE) >> 16;
left_slides[0].angle = (pos * itilt) >> 16;
left_slides[0].cx = -fmul(offsetX, ftick);
left_slides[0].cy = fmul(offsetY, ftick);
}
/* must change direction ? */
if (target < index)
if (step > 0)
step = -1;
if (target > index)
if (step < 0)
step = 1;
}
/**
Cleanup the plugin
*/
void cleanup(void *parameter)
{
(void) parameter;
#ifdef HAVE_ADJUSTABLE_CPU_FREQ
rb->cpu_boost(false);
#endif
end_pf_thread();
/* Turn on backlight timeout (revert to settings) */
backlight_use_settings(); /* backlight control in lib/helper.c */
#ifdef USEGSLIB
grey_release();
#endif
}
/**
Create the "?" slide, that is shown while loading
or when no cover was found.
*/
int create_empty_slide(bool force)
{
if ( force || ! rb->file_exists( EMPTY_SLIDE ) ) {
struct bitmap input_bmp;
int ret;
input_bmp.width = DISPLAY_WIDTH;
input_bmp.height = DISPLAY_HEIGHT;
#if LCD_DEPTH > 1
input_bmp.format = FORMAT_NATIVE;
#endif
input_bmp.data = (char*)buf;
ret = scaled_read_bmp_file(EMPTY_SLIDE_BMP, &input_bmp,
buf_size,
FORMAT_NATIVE|FORMAT_RESIZE|FORMAT_KEEP_ASPECT,
&format_transposed);
if (!save_pfraw(EMPTY_SLIDE, &input_bmp))
return false;
}
return true;
}
/**
Shows the settings menu
*/
int settings_menu(void)
{
int selection = 0;
bool old_val;
MENUITEM_STRINGLIST(settings_menu, "PictureFlow Settings", NULL, "Show FPS",
"Spacing", "Centre margin", "Number of slides", "Zoom",
"Show album title", "Resize Covers", "Rebuild cache");
static const struct opt_items album_name_options[] = {
{ "Hide album title", -1 },
{ "Show at the bottom", -1 },
{ "Show at the top", -1 }
};
do {
selection=rb->do_menu(&settings_menu,&selection, NULL, false);
switch(selection) {
case 0:
rb->set_bool("Show FPS", &show_fps);
reset_track_list();
break;
case 1:
rb->set_int("Spacing between slides", "", 1,
&slide_spacing,
NULL, 1, 0, 100, NULL );
recalc_offsets();
reset_slides();
break;
case 2:
rb->set_int("Centre margin", "", 1,
&center_margin,
NULL, 1, 0, 80, NULL );
recalc_offsets();
reset_slides();
break;
case 3:
rb->set_int("Number of slides", "", 1, &num_slides,
NULL, 1, 1, MAX_SLIDES_COUNT, NULL );
recalc_offsets();
reset_slides();
break;
case 4:
rb->set_int("Zoom", "", 1, &zoom,
NULL, 1, 10, 300, NULL );
recalc_offsets();
reset_slides();
break;
case 5:
rb->set_option("Show album title", &show_album_name,
INT, album_name_options, 3, NULL);
reset_track_list();
recalc_offsets();
reset_slides();
break;
case 6:
old_val = resize;
rb->set_bool("Resize Covers", &resize);
if (old_val == resize) /* changed? */
break;
/* fallthrough if changed, since cache needs to be rebuilt */
case 7:
cache_version = 0;
rb->remove(EMPTY_SLIDE);
rb->splash(HZ, "Cache will be rebuilt on next restart");
break;
case MENU_ATTACHED_USB:
return PLUGIN_USB_CONNECTED;
}
} while ( selection >= 0 );
configfile_save(CONFIG_FILE, config, CONFIG_NUM_ITEMS, CONFIG_VERSION);
return 0;
}
/**
Show the main menu
*/
enum {
PF_GOTO_WPS,
#if PF_PLAYBACK_CAPABLE
PF_MENU_PLAYBACK_CONTROL,
#endif
PF_MENU_SETTINGS,
PF_MENU_RETURN,
PF_MENU_QUIT,
};
int main_menu(void)
{
int selection = 0;
int result;
#if LCD_DEPTH > 1
rb->lcd_set_foreground(N_BRIGHT(255));
#endif
MENUITEM_STRINGLIST(main_menu,"PictureFlow Main Menu",NULL,
"Go to WPS",
#if PF_PLAYBACK_CAPABLE
"Playback Control",
#endif
"Settings", "Return", "Quit");
while (1) {
switch (rb->do_menu(&main_menu,&selection, NULL, false)) {
case PF_GOTO_WPS: /* WPS */
return -2;
#if PF_PLAYBACK_CAPABLE
case PF_MENU_PLAYBACK_CONTROL: /* Playback Control */
playback_control(NULL);
break;
#endif
case PF_MENU_SETTINGS:
result = settings_menu();
if ( result != 0 ) return result;
break;
case PF_MENU_RETURN:
return 0;
case PF_MENU_QUIT:
return -1;
case MENU_ATTACHED_USB:
return PLUGIN_USB_CONNECTED;
default:
return 0;
}
}
}
/**
Animation step for zooming into the current cover
*/
void update_cover_in_animation(void)
{
cover_animation_keyframe++;
if( cover_animation_keyframe < 20 ) {
center_slide.distance-=5;
center_slide.angle+=1;
extra_fade += 13;
}
else if( cover_animation_keyframe < 35 ) {
center_slide.angle+=16;
}
else {
cover_animation_keyframe = 0;
pf_state = pf_show_tracks;
}
}
/**
Animation step for zooming out the current cover
*/
void update_cover_out_animation(void)
{
cover_animation_keyframe++;
if( cover_animation_keyframe <= 15 ) {
center_slide.angle-=16;
}
else if( cover_animation_keyframe < 35 ) {
center_slide.distance+=5;
center_slide.angle-=1;
extra_fade -= 13;
}
else {
cover_animation_keyframe = 0;
pf_state = pf_idle;
}
}
/**
Draw a blue gradient at y with height h
*/
static inline void draw_gradient(int y, int h)
{
static int r, inc, c;
inc = (100 << 8) / h;
c = 0;
selected_track_pulse = (selected_track_pulse+1) % 10;
int c2 = selected_track_pulse - 5;
for (r=0; r<h; r++) {
#ifdef HAVE_LCD_COLOR
MYLCD(set_foreground)(G_PIX(c2+80-(c >> 9), c2+100-(c >> 9),
c2+250-(c >> 8)));
#else
MYLCD(set_foreground)(G_BRIGHT(c2+160-(c >> 8)));
#endif
MYLCD(hline)(0, LCD_WIDTH, r+y);
if ( r > h/2 )
c-=inc;
else
c+=inc;
}
}
static void track_list_yh(int char_height)
{
switch (show_album_name)
{
case album_name_hide:
track_list_y = (show_fps ? char_height : 0);
track_list_h = LCD_HEIGHT - track_list_y;
break;
case album_name_bottom:
track_list_y = (show_fps ? char_height : 0);
track_list_h = LCD_HEIGHT - track_list_y - char_height * 2;
break;
default: /* case album_name_top */
track_list_y = char_height * 2;
track_list_h = LCD_HEIGHT - track_list_y -
(show_fps ? char_height : 0);
break;
}
}
/**
Reset the track list after a album change
*/
void reset_track_list(void)
{
int albumtxt_h = rb->screens[SCREEN_MAIN]->getcharheight();
track_list_yh(albumtxt_h);
track_list_visible_entries = fmin( track_list_h/albumtxt_h , track_count );
start_index_track_list = 0;
track_scroll_index = 0;
track_scroll_dir = 1;
selected_track = 0;
/* let the tracklist start more centered
* if the screen isn't filled with tracks */
if (track_count*albumtxt_h < track_list_h)
{
track_list_h = track_count * albumtxt_h;
track_list_y = LCD_HEIGHT / 2 - (track_list_h / 2);
}
}
/**
Display the list of tracks
*/
void show_track_list(void)
{
MYLCD(clear_display)();
if ( center_slide.slide_index != track_index ) {
create_track_index(center_slide.slide_index);
reset_track_list();
}
static int titletxt_w, titletxt_x, color, titletxt_h;
titletxt_h = rb->screens[SCREEN_MAIN]->getcharheight();
int titletxt_y = track_list_y;
int track_i;
track_i = start_index_track_list;
for (;track_i < track_list_visible_entries+start_index_track_list;
track_i++)
{
MYLCD(getstringsize)(get_track_name(track_i), &titletxt_w, NULL);
titletxt_x = (LCD_WIDTH-titletxt_w)/2;
if ( track_i == selected_track ) {
draw_gradient(titletxt_y, titletxt_h);
MYLCD(set_foreground)(G_BRIGHT(255));
if (titletxt_w > LCD_WIDTH ) {
if ( titletxt_w + track_scroll_index <= LCD_WIDTH )
track_scroll_dir = 1;
else if ( track_scroll_index >= 0 ) track_scroll_dir = -1;
track_scroll_index += track_scroll_dir*2;
titletxt_x = track_scroll_index;
}
MYLCD(putsxy)(titletxt_x,titletxt_y,get_track_name(track_i));
}
else {
color = 250 - (abs(selected_track - track_i) * 200 / track_count);
MYLCD(set_foreground)(G_BRIGHT(color));
MYLCD(putsxy)(titletxt_x,titletxt_y,get_track_name(track_i));
}
titletxt_y += titletxt_h;
}
}
void select_next_track(void)
{
if ( selected_track < track_count - 1 ) {
selected_track++;
track_scroll_index = 0;
track_scroll_dir = 1;
if (selected_track==(track_list_visible_entries+start_index_track_list))
start_index_track_list++;
}
}
void select_prev_track(void)
{
if (selected_track > 0 ) {
if (selected_track==start_index_track_list) start_index_track_list--;
track_scroll_index = 0;
track_scroll_dir = 1;
selected_track--;
}
}
#if PF_PLAYBACK_CAPABLE
/*
* Puts the current tracklist into a newly created playlist and starts playling
*/
void start_playback(void)
{
static int old_playlist = -1, old_shuffle = 0;
int count = 0;
int position = selected_track;
int shuffle = rb->global_settings->playlist_shuffle;
/* reuse existing playlist if possible
* regenerate if shuffle is on or changed, since playlist index and
* selected track are "out of sync" */
if (!shuffle && center_slide.slide_index == old_playlist
&& (old_shuffle == shuffle))
{
goto play;
}
/* First, replace the current playlist with a new one */
else if (rb->playlist_remove_all_tracks(NULL) == 0
&& rb->playlist_create(NULL, NULL) == 0)
{
do {
rb->yield();
if (rb->playlist_insert_track(NULL, get_track_filename(count),
PLAYLIST_INSERT_LAST, false, true) < 0)
break;
} while(++count < track_count);
rb->playlist_sync(NULL);
}
else
return;
if (rb->global_settings->playlist_shuffle)
position = rb->playlist_shuffle(*rb->current_tick, selected_track);
play:
/* TODO: can we adjust selected_track if !play_selected ?
* if shuffle, we can't predict the playing track easily, and for either
* case the track list doesn't get auto scrolled*/
rb->playlist_start(position, 0);
old_playlist = center_slide.slide_index;
old_shuffle = shuffle;
}
#endif
/**
Draw the current album name
*/
void draw_album_text(void)
{
if (0 == show_album_name)
return;
int albumtxt_w, albumtxt_h;
int albumtxt_y = 0;
char *albumtxt;
int c;
/* Draw album text */
if ( pf_state == pf_scrolling ) {
c = ((slide_frame & 0xffff )/ 255);
if (step < 0) c = 255-c;
if (c > 128 ) { /* half way to next slide .. still not perfect! */
albumtxt = get_album_name(center_index+step);
c = (c-128)*2;
}
else {
albumtxt = get_album_name(center_index);
c = (128-c)*2;
}
}
else {
c= 255;
albumtxt = get_album_name(center_index);
}
MYLCD(set_foreground)(G_BRIGHT(c));
MYLCD(getstringsize)(albumtxt, &albumtxt_w, &albumtxt_h);
if (center_index != prev_center_index) {
albumtxt_x = 0;
albumtxt_dir = -1;
prev_center_index = center_index;
}
if (show_album_name == album_name_top)
albumtxt_y = albumtxt_h / 2;
else
albumtxt_y = LCD_HEIGHT - albumtxt_h - albumtxt_h/2;
if (albumtxt_w > LCD_WIDTH ) {
MYLCD(putsxy)(albumtxt_x, albumtxt_y , albumtxt);
if ( pf_state == pf_idle || pf_state == pf_show_tracks ) {
if ( albumtxt_w + albumtxt_x <= LCD_WIDTH ) albumtxt_dir = 1;
else if ( albumtxt_x >= 0 ) albumtxt_dir = -1;
albumtxt_x += albumtxt_dir;
}
}
else {
MYLCD(putsxy)((LCD_WIDTH - albumtxt_w) /2, albumtxt_y , albumtxt);
}
}
/**
Display an error message and wait for input.
*/
void error_wait(const char *message)
{
rb->splashf(0, "%s. Press any button to continue.", message);
while (rb->get_action(CONTEXT_STD, 1) == ACTION_NONE)
rb->yield();
rb->sleep(2 * HZ);
}
/**
Main function that also contain the main plasma
algorithm.
*/
int main(void)
{
int ret;
rb->lcd_setfont(FONT_UI);
draw_splashscreen();
if ( ! rb->dir_exists( CACHE_PREFIX ) ) {
if ( rb->mkdir( CACHE_PREFIX ) < 0 ) {
error_wait("Could not create directory " CACHE_PREFIX);
return PLUGIN_ERROR;
}
}
configfile_load(CONFIG_FILE, config, CONFIG_NUM_ITEMS, CONFIG_VERSION);
init_reflect_table();
ALIGN_BUFFER(buf, buf_size, 4);
ret = create_album_index();
if (ret == ERROR_BUFFER_FULL) {
error_wait("Not enough memory for album names");
return PLUGIN_ERROR;
} else if (ret == ERROR_NO_ALBUMS) {
error_wait("No albums found. Please enable database");
return PLUGIN_ERROR;
}
ALIGN_BUFFER(buf, buf_size, 4);
number_of_slides = album_count;
if ((cache_version != CACHE_VERSION) && !create_albumart_cache()) {
error_wait("Could not create album art cache");
return PLUGIN_ERROR;
}
if (!create_empty_slide(cache_version != CACHE_VERSION)) {
error_wait("Could not load the empty slide");
return PLUGIN_ERROR;
}
cache_version = CACHE_VERSION;
configfile_save(CONFIG_FILE, config, CONFIG_NUM_ITEMS, CONFIG_VERSION);
#ifdef USEGSLIB
long grey_buf_used;
if (!grey_init(buf, buf_size, GREY_BUFFERED|GREY_ON_COP,
LCD_WIDTH, LCD_HEIGHT, &grey_buf_used))
{
error_wait("Greylib init failed!");
return PLUGIN_ERROR;
}
grey_setfont(FONT_UI);
buf_size -= grey_buf_used;
buf = (void*)(grey_buf_used + (char*)buf);
#endif
buflib_init(&buf_ctx, (void *)buf, buf_size);
if (!(empty_slide_hid = read_pfraw(EMPTY_SLIDE, 0)))
{
error_wait("Unable to load empty slide image");
return PLUGIN_ERROR;
}
if (!create_pf_thread()) {
error_wait("Cannot create thread!");
return PLUGIN_ERROR;
}
int i;
/* initialize */
for (i = 0; i < SLIDE_CACHE_SIZE; i++) {
cache[i].hid = 0;
cache[i].index = 0;
cache[i].next = i + 1;
cache[i].prev = i - 1;
}
cache[0].prev = i - 1;
cache[i - 1].next = 0;
cache_free = 0;
buffer = LCD_BUF;
pf_state = pf_idle;
track_index = -1;
extra_fade = 0;
slide_frame = 0;
step = 0;
target = 0;
fade = 256;
recalc_offsets();
reset_slides();
char fpstxt[10];
int button;
int frames = 0;
long last_update = *rb->current_tick;
long current_update;
long update_interval = 100;
int fps = 0;
int fpstxt_y;
bool instant_update;
#ifdef USEGSLIB
grey_show(true);
grey_set_drawmode(DRMODE_FG);
#endif
rb->lcd_set_drawmode(DRMODE_FG);
while (true) {
current_update = *rb->current_tick;
frames++;
/* Initial rendering */
instant_update = false;
/* Handle states */
switch ( pf_state ) {
case pf_scrolling:
update_scroll_animation();
render_all_slides();
instant_update = true;
break;
case pf_cover_in:
update_cover_in_animation();
render_all_slides();
instant_update = true;
break;
case pf_cover_out:
update_cover_out_animation();
render_all_slides();
instant_update = true;
break;
case pf_show_tracks:
show_track_list();
break;
case pf_idle:
render_all_slides();
break;
}
/* Calculate FPS */
if (current_update - last_update > update_interval) {
fps = frames * HZ / (current_update - last_update);
last_update = current_update;
frames = 0;
}
/* Draw FPS */
if (show_fps)
{
#ifdef USEGSLIB
MYLCD(set_foreground)(G_BRIGHT(255));
#else
MYLCD(set_foreground)(G_PIX(255,0,0));
#endif
rb->snprintf(fpstxt, sizeof(fpstxt), "FPS: %d", fps);
if (show_album_name == album_name_top)
fpstxt_y = LCD_HEIGHT -
rb->screens[SCREEN_MAIN]->getcharheight();
else
fpstxt_y = 0;
MYLCD(putsxy)(0, fpstxt_y, fpstxt);
}
draw_album_text();
/* Copy offscreen buffer to LCD and give time to other threads */
MYLCD(update)();
rb->yield();
/*/ Handle buttons */
button = rb->get_custom_action(CONTEXT_PLUGIN
#ifndef USE_CORE_PREVNEXT
|(pf_state == pf_show_tracks ? 1 : 0)
#endif
,instant_update ? 0 : HZ/16,
get_context_map);
switch (button) {
case PF_QUIT:
return PLUGIN_OK;
case PF_WPS:
return PLUGIN_GOTO_WPS;
case PF_BACK:
if ( pf_state == pf_show_tracks )
{
buflib_buffer_in(&buf_ctx, borrowed);
borrowed = 0;
track_index = -1;
pf_state = pf_cover_out;
}
if (pf_state == pf_idle || pf_state == pf_scrolling)
return PLUGIN_OK;
break;
case PF_MENU:
#ifdef USEGSLIB
grey_show(false);
#endif
ret = main_menu();
if ( ret == -2 ) return PLUGIN_GOTO_WPS;
if ( ret == -1 ) return PLUGIN_OK;
if ( ret != 0 ) return ret;
#ifdef USEGSLIB
grey_show(true);
#endif
MYLCD(set_drawmode)(DRMODE_FG);
break;
case PF_NEXT:
case PF_NEXT_REPEAT:
if ( pf_state == pf_show_tracks )
select_next_track();
if ( pf_state == pf_idle || pf_state == pf_scrolling )
show_next_slide();
break;
case PF_PREV:
case PF_PREV_REPEAT:
if ( pf_state == pf_show_tracks )
select_prev_track();
if ( pf_state == pf_idle || pf_state == pf_scrolling )
show_previous_slide();
break;
case PF_SELECT:
if ( pf_state == pf_idle ) {
pf_state = pf_cover_in;
}
else if ( pf_state == pf_show_tracks ) {
#if PF_PLAYBACK_CAPABLE
start_playback();
#endif
}
break;
default:
if (rb->default_event_handler_ex(button, cleanup, NULL)
== SYS_USB_CONNECTED)
return PLUGIN_USB_CONNECTED;
break;
}
}
}
/*************************** Plugin entry point ****************************/
enum plugin_status plugin_start(const void *parameter)
{
int ret;
(void) parameter;
#if LCD_DEPTH > 1
rb->lcd_set_backdrop(NULL);
#endif
/* Turn off backlight timeout */
backlight_force_on(); /* backlight control in lib/helper.c */
#ifdef HAVE_ADJUSTABLE_CPU_FREQ
rb->cpu_boost(true);
#endif
#if PF_PLAYBACK_CAPABLE
buf = rb->plugin_get_buffer(&buf_size);
#else
buf = rb->plugin_get_audio_buffer(&buf_size);
#ifndef SIMULATOR
if ((uintptr_t)buf < (uintptr_t)plugin_start_addr)
{
uint32_t tmp_size = (uintptr_t)plugin_start_addr - (uintptr_t)buf;
buf_size = MIN(buf_size, tmp_size);
}
#endif
#endif
ret = main();
if ( ret == PLUGIN_OK ) {
if (configfile_save(CONFIG_FILE, config, CONFIG_NUM_ITEMS,
CONFIG_VERSION))
{
rb->splash(HZ, "Error writing config.");
ret = PLUGIN_ERROR;
}
}
cleanup(NULL);
return ret;
}