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// Copyright 2021-2022 Nick Brassel (@tzarc)
// Copyright 2021 Paul Cotter (@gr1mr3aver)
// SPDX-License-Identifier: GPL-2.0-or-later
# include "qp_internal.h"
# include "qp_comms.h"
# include "qp_draw.h"
# include "qgf.h"
_Static_assert ( ( QUANTUM_PAINTER_PIXDATA_BUFFER_SIZE > 0 ) & & ( QUANTUM_PAINTER_PIXDATA_BUFFER_SIZE % 16 ) = = 0 , " QUANTUM_PAINTER_PIXDATA_BUFFER_SIZE needs to be a non-zero multiple of 16 " ) ;
////////////////////////////////////////////////////////////////////////////////////////////////////////////////////////
// Global variables
//
// NOTE: The variables in this section are intentionally outside a stack frame. They are able to be defined with larger
// sizes than the normal stack frames would allow, and as such need to be external.
//
// **** DO NOT refactor this and decide to place the variables inside the function calling them -- you will ****
// **** very likely get artifacts rendered to the screen as a result. ****
//
// Buffer used for transmitting native pixel data to the downstream device.
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__attribute__ ( ( __aligned__ ( 4 ) ) ) uint8_t qp_internal_global_pixdata_buffer [ QUANTUM_PAINTER_PIXDATA_BUFFER_SIZE ] ;
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// Static buffer to contain a generated color palette
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static bool generated_palette = false ;
static int16_t generated_steps = - 1 ;
__attribute__ ( ( __aligned__ ( 4 ) ) ) static qp_pixel_t interpolated_fg_hsv888 ;
__attribute__ ( ( __aligned__ ( 4 ) ) ) static qp_pixel_t interpolated_bg_hsv888 ;
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# if QUANTUM_PAINTER_SUPPORTS_256_PALETTE
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__attribute__ ( ( __aligned__ ( 4 ) ) ) qp_pixel_t qp_internal_global_pixel_lookup_table [ 256 ] ;
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# else
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__attribute__ ( ( __aligned__ ( 4 ) ) ) qp_pixel_t qp_internal_global_pixel_lookup_table [ 16 ] ;
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# endif
////////////////////////////////////////////////////////////////////////////////////////////////////////////////////////
// Helpers
uint32_t qp_internal_num_pixels_in_buffer ( painter_device_t device ) {
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painter_driver_t * driver = ( painter_driver_t * ) device ;
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return ( ( QUANTUM_PAINTER_PIXDATA_BUFFER_SIZE * 8 ) / driver - > native_bits_per_pixel ) ;
}
// qp_setpixel internal implementation, but accepts a buffer with pre-converted native pixel. Only the first pixel is used.
bool qp_internal_setpixel_impl ( painter_device_t device , uint16_t x , uint16_t y ) {
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painter_driver_t * driver = ( painter_driver_t * ) device ;
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return driver - > driver_vtable - > viewport ( device , x , y , x , y ) & & driver - > driver_vtable - > pixdata ( device , qp_internal_global_pixdata_buffer , 1 ) ;
}
// Fills the global native pixel buffer with equivalent pixels matching the supplied HSV
void qp_internal_fill_pixdata ( painter_device_t device , uint32_t num_pixels , uint8_t hue , uint8_t sat , uint8_t val ) {
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painter_driver_t * driver = ( painter_driver_t * ) device ;
uint32_t pixels_in_pixdata = qp_internal_num_pixels_in_buffer ( device ) ;
num_pixels = QP_MIN ( pixels_in_pixdata , num_pixels ) ;
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// Convert the color to native pixel format
qp_pixel_t color = { . hsv888 = { . h = hue , . s = sat , . v = val } } ;
driver - > driver_vtable - > palette_convert ( device , 1 , & color ) ;
// Append the required number of pixels
uint8_t palette_idx = 0 ;
for ( uint32_t i = 0 ; i < num_pixels ; + + i ) {
driver - > driver_vtable - > append_pixels ( device , qp_internal_global_pixdata_buffer , & color , i , 1 , & palette_idx ) ;
}
}
// Resets the global palette so that it can be regenerated. Only needed if the colors are identical, but a different display is used with a different internal pixel format.
void qp_internal_invalidate_palette ( void ) {
generated_palette = false ;
generated_steps = - 1 ;
}
// Interpolates between two colors to generate a palette
bool qp_internal_interpolate_palette ( qp_pixel_t fg_hsv888 , qp_pixel_t bg_hsv888 , int16_t steps ) {
// Check if we need to generate a new palette -- if the input parameters match then assume the palette can stay unchanged.
// This may present a problem if using the same parameters but a different screen converts pixels -- use qp_internal_invalidate_palette() to reset.
if ( generated_palette = = true & & generated_steps = = steps & & memcmp ( & interpolated_fg_hsv888 , & fg_hsv888 , sizeof ( fg_hsv888 ) ) = = 0 & & memcmp ( & interpolated_bg_hsv888 , & bg_hsv888 , sizeof ( bg_hsv888 ) ) = = 0 ) {
// We already have the correct palette, no point regenerating it.
return false ;
}
// Save the parameters so we know whether we can skip generation
generated_palette = true ;
generated_steps = steps ;
interpolated_fg_hsv888 = fg_hsv888 ;
interpolated_bg_hsv888 = bg_hsv888 ;
int16_t hue_fg = fg_hsv888 . hsv888 . h ;
int16_t hue_bg = bg_hsv888 . hsv888 . h ;
// Make sure we take the "shortest" route from one hue to the other
if ( ( hue_fg - hue_bg ) > = 128 ) {
hue_bg + = 256 ;
} else if ( ( hue_fg - hue_bg ) < = - 128 ) {
hue_bg - = 256 ;
}
// Interpolate each of the lookup table entries
for ( int16_t i = 0 ; i < steps ; + + i ) {
qp_internal_global_pixel_lookup_table [ i ] . hsv888 . h = ( uint8_t ) ( ( hue_fg - hue_bg ) * i / ( steps - 1 ) + hue_bg ) ;
qp_internal_global_pixel_lookup_table [ i ] . hsv888 . s = ( uint8_t ) ( ( fg_hsv888 . hsv888 . s - bg_hsv888 . hsv888 . s ) * i / ( steps - 1 ) + bg_hsv888 . hsv888 . s ) ;
qp_internal_global_pixel_lookup_table [ i ] . hsv888 . v = ( uint8_t ) ( ( fg_hsv888 . hsv888 . v - bg_hsv888 . hsv888 . v ) * i / ( steps - 1 ) + bg_hsv888 . hsv888 . v ) ;
qp_dprintf ( " qp_internal_interpolate_palette: %3d of %d -- H: %3d, S: %3d, V: %3d \n " , ( int ) ( i + 1 ) , ( int ) steps , ( int ) qp_internal_global_pixel_lookup_table [ i ] . hsv888 . h , ( int ) qp_internal_global_pixel_lookup_table [ i ] . hsv888 . s , ( int ) qp_internal_global_pixel_lookup_table [ i ] . hsv888 . v ) ;
}
return true ;
}
// Helper shared between image and font rendering -- sets up the global palette to match the palette block specified in the asset. Expects the stream to be positioned at the start of the block header.
bool qp_internal_load_qgf_palette ( qp_stream_t * stream , uint8_t bpp ) {
qgf_palette_v1_t palette_descriptor ;
if ( qp_stream_read ( & palette_descriptor , sizeof ( qgf_palette_v1_t ) , 1 , stream ) ! = 1 ) {
qp_dprintf ( " Failed to read palette_descriptor, expected length was not %d \n " , ( int ) sizeof ( qgf_palette_v1_t ) ) ;
return false ;
}
// BPP determines the number of palette entries, each entry is a HSV888 triplet.
const uint16_t palette_entries = 1u < < bpp ;
// Ensure we aren't reusing any palette
qp_internal_invalidate_palette ( ) ;
// Read the palette entries
for ( uint16_t i = 0 ; i < palette_entries ; + + i ) {
// Read the palette entry
qgf_palette_entry_v1_t entry ;
if ( qp_stream_read ( & entry , sizeof ( qgf_palette_entry_v1_t ) , 1 , stream ) ! = 1 ) {
return false ;
}
// Update the lookup table
qp_internal_global_pixel_lookup_table [ i ] . hsv888 . h = entry . h ;
qp_internal_global_pixel_lookup_table [ i ] . hsv888 . s = entry . s ;
qp_internal_global_pixel_lookup_table [ i ] . hsv888 . v = entry . v ;
qp_dprintf ( " qp_internal_load_qgf_palette: %3d of %d -- H: %3d, S: %3d, V: %3d \n " , ( int ) ( i + 1 ) , ( int ) palette_entries , ( int ) qp_internal_global_pixel_lookup_table [ i ] . hsv888 . h , ( int ) qp_internal_global_pixel_lookup_table [ i ] . hsv888 . s , ( int ) qp_internal_global_pixel_lookup_table [ i ] . hsv888 . v ) ;
}
return true ;
}
////////////////////////////////////////////////////////////////////////////////////////////////////////////////////////
// Quantum Painter External API: qp_setpixel
bool qp_setpixel ( painter_device_t device , uint16_t x , uint16_t y , uint8_t hue , uint8_t sat , uint8_t val ) {
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painter_driver_t * driver = ( painter_driver_t * ) device ;
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if ( ! driver - > validate_ok ) {
qp_dprintf ( " qp_setpixel: fail (validation_ok == false) \n " ) ;
return false ;
}
if ( ! qp_comms_start ( device ) ) {
qp_dprintf ( " Failed to start comms in qp_setpixel \n " ) ;
return false ;
}
qp_internal_fill_pixdata ( device , 1 , hue , sat , val ) ;
bool ret = qp_internal_setpixel_impl ( device , x , y ) ;
qp_comms_stop ( device ) ;
qp_dprintf ( " qp_setpixel: %s \n " , ret ? " ok " : " fail " ) ;
return ret ;
}
////////////////////////////////////////////////////////////////////////////////////////////////////////////////////////
// Quantum Painter External API: qp_line
bool qp_line ( painter_device_t device , uint16_t x0 , uint16_t y0 , uint16_t x1 , uint16_t y1 , uint8_t hue , uint8_t sat , uint8_t val ) {
if ( x0 = = x1 | | y0 = = y1 ) {
qp_dprintf ( " qp_line(%d, %d, %d, %d): entry (deferring to qp_rect) \n " , ( int ) x0 , ( int ) y0 , ( int ) x1 , ( int ) y1 ) ;
bool ret = qp_rect ( device , x0 , y0 , x1 , y1 , hue , sat , val , true ) ;
qp_dprintf ( " qp_line(%d, %d, %d, %d): %s (deferred to qp_rect) \n " , ( int ) x0 , ( int ) y0 , ( int ) x1 , ( int ) y1 , ret ? " ok " : " fail " ) ;
return ret ;
}
qp_dprintf ( " qp_line(%d, %d, %d, %d): entry \n " , ( int ) x0 , ( int ) y0 , ( int ) x1 , ( int ) y1 ) ;
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painter_driver_t * driver = ( painter_driver_t * ) device ;
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if ( ! driver - > validate_ok ) {
qp_dprintf ( " qp_line: fail (validation_ok == false) \n " ) ;
return false ;
}
if ( ! qp_comms_start ( device ) ) {
qp_dprintf ( " Failed to start comms in qp_line \n " ) ;
return false ;
}
qp_internal_fill_pixdata ( device , 1 , hue , sat , val ) ;
// draw angled line using Bresenham's algo
int16_t x = ( ( int16_t ) x0 ) ;
int16_t y = ( ( int16_t ) y0 ) ;
int16_t slopex = ( ( int16_t ) x0 ) < ( ( int16_t ) x1 ) ? 1 : - 1 ;
int16_t slopey = ( ( int16_t ) y0 ) < ( ( int16_t ) y1 ) ? 1 : - 1 ;
int16_t dx = abs ( ( ( int16_t ) x1 ) - ( ( int16_t ) x0 ) ) ;
int16_t dy = - abs ( ( ( int16_t ) y1 ) - ( ( int16_t ) y0 ) ) ;
int16_t e = dx + dy ;
int16_t e2 = 2 * e ;
bool ret = true ;
while ( x ! = x1 | | y ! = y1 ) {
if ( ! qp_internal_setpixel_impl ( device , x , y ) ) {
ret = false ;
break ;
}
e2 = 2 * e ;
if ( e2 > = dy ) {
e + = dy ;
x + = slopex ;
}
if ( e2 < = dx ) {
e + = dx ;
y + = slopey ;
}
}
// draw the last pixel
if ( ! qp_internal_setpixel_impl ( device , x , y ) ) {
ret = false ;
}
qp_comms_stop ( device ) ;
qp_dprintf ( " qp_line(%d, %d, %d, %d): %s \n " , ( int ) x0 , ( int ) y0 , ( int ) x1 , ( int ) y1 , ret ? " ok " : " fail " ) ;
return ret ;
}
////////////////////////////////////////////////////////////////////////////////////////////////////////////////////////
// Quantum Painter External API: qp_rect
bool qp_internal_fillrect_helper_impl ( painter_device_t device , uint16_t left , uint16_t top , uint16_t right , uint16_t bottom ) {
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uint32_t pixels_in_pixdata = qp_internal_num_pixels_in_buffer ( device ) ;
painter_driver_t * driver = ( painter_driver_t * ) device ;
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uint16_t l = QP_MIN ( left , right ) ;
uint16_t r = QP_MAX ( left , right ) ;
uint16_t t = QP_MIN ( top , bottom ) ;
uint16_t b = QP_MAX ( top , bottom ) ;
uint16_t w = r - l + 1 ;
uint16_t h = b - t + 1 ;
uint32_t remaining = w * h ;
driver - > driver_vtable - > viewport ( device , l , t , r , b ) ;
while ( remaining > 0 ) {
uint32_t transmit = QP_MIN ( remaining , pixels_in_pixdata ) ;
if ( ! driver - > driver_vtable - > pixdata ( device , qp_internal_global_pixdata_buffer , transmit ) ) {
return false ;
}
remaining - = transmit ;
}
return true ;
}
bool qp_rect ( painter_device_t device , uint16_t left , uint16_t top , uint16_t right , uint16_t bottom , uint8_t hue , uint8_t sat , uint8_t val , bool filled ) {
qp_dprintf ( " qp_rect(%d, %d, %d, %d): entry \n " , ( int ) left , ( int ) top , ( int ) right , ( int ) bottom ) ;
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painter_driver_t * driver = ( painter_driver_t * ) device ;
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if ( ! driver - > validate_ok ) {
qp_dprintf ( " qp_rect: fail (validation_ok == false) \n " ) ;
return false ;
}
// Cater for cases where people have submitted the coordinates backwards
uint16_t l = QP_MIN ( left , right ) ;
uint16_t r = QP_MAX ( left , right ) ;
uint16_t t = QP_MIN ( top , bottom ) ;
uint16_t b = QP_MAX ( top , bottom ) ;
uint16_t w = r - l + 1 ;
uint16_t h = b - t + 1 ;
bool ret = true ;
if ( ! qp_comms_start ( device ) ) {
qp_dprintf ( " Failed to start comms in qp_rect \n " ) ;
return false ;
}
if ( filled ) {
// Fill up the pixdata buffer with the required number of native pixels
qp_internal_fill_pixdata ( device , w * h , hue , sat , val ) ;
// Perform the draw
ret = qp_internal_fillrect_helper_impl ( device , l , t , r , b ) ;
} else {
// Fill up the pixdata buffer with the required number of native pixels
qp_internal_fill_pixdata ( device , QP_MAX ( w , h ) , hue , sat , val ) ;
// Draw 4x filled single-width rects to create an outline
if ( ! qp_internal_fillrect_helper_impl ( device , l , t , r , t ) | | ! qp_internal_fillrect_helper_impl ( device , l , b , r , b ) | | ! qp_internal_fillrect_helper_impl ( device , l , t + 1 , l , b - 1 ) | | ! qp_internal_fillrect_helper_impl ( device , r , t + 1 , r , b - 1 ) ) {
ret = false ;
}
}
qp_comms_stop ( device ) ;
qp_dprintf ( " qp_rect(%d, %d, %d, %d): %s \n " , ( int ) l , ( int ) t , ( int ) r , ( int ) b , ret ? " ok " : " fail " ) ;
return ret ;
}