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Tasmota/tasmota/tasmota_xdrv_driver/xdrv_52_3_berry_pixmat.ino
Christian Baars 41d3ffb98f
add 2 bpp to pixmat class (#24143)
2025-11-20 17:40:24 +01:00

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/*
xdrv_52_3_berry_pixmat.ino - Berry scripting language, native functions
Copyright (C) 2021 Christian Baars & Stephan Hadinger, Berry language by Guan Wenliang https://github.com/Skiars/berry
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 3 of the License, or
(at your option) any later version.
This program 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 General Public License for more details.
You should have received a copy of the GNU General Public License
along with this program. If not, see <http://www.gnu.org/licenses/>.
*/
#ifdef USE_BERRY
#include <berry.h>
#ifdef USE_WS2812
#include "be_constobj.h"
#include <cstdint>
#include <cstring>
#include <algorithm>
#include <limits>
// Forward declare native core so it can appear in signatures
struct PixmatCore;
// Prototypes for helpers
static PixmatCore* self_core(bvm* vm);
static inline bool in_bounds(const PixmatCore* mc, int x, int y);
struct PixmatCore {
uint8_t* data = nullptr;
int width = 0;
int height = 0;
int bpp = 0;
bool serpentine = false;
bool external = false;
inline size_t index(int x, int y) const {
return static_cast<size_t>((y * width + x) * bpp);
}
inline void load(int x, int y, uint8_t* out) const {
int phys_x = (serpentine && (y & 1)) ? (width - 1 - x) : x;
const size_t idx = static_cast<size_t>((y * width + phys_x) * bpp);
memcpy(out, data + idx, bpp);
}
inline void store(int x, int y, const uint8_t* in) {
int phys_x = (serpentine && (y & 1)) ? (width - 1 - x) : x;
const size_t idx = static_cast<size_t>((y * width + phys_x) * bpp);
memcpy(data + idx, in, bpp);
}
inline size_t bytes_size() const {
return static_cast<size_t>(width) * static_cast<size_t>(height) * static_cast<size_t>(bpp);
}
inline void blit(const PixmatCore* src, int dx, int dy) {
uint8_t pix[8]; // enough for max bpp
for (int sy = 0; sy < src->height; ++sy) {
int dypos = sy + dy;
if (dypos < 0 || dypos >= height) continue;
for (int sx = 0; sx < src->width; ++sx) {
int dxpos = sx + dx;
if (dxpos < 0 || dxpos >= width) continue;
src->load(sx, sy, pix);
store(dxpos, dypos, pix);
}
}
}
};
/* fetch native pointer from this .p */
static PixmatCore* self_core(bvm* vm) {
be_getmember(vm, 1, ".p");
PixmatCore* mc = (PixmatCore*) be_tocomptr(vm, -1);
be_pop(vm, 1);
return mc;
}
static inline uint8_t mul8(uint8_t a, uint8_t b){ return (a * b) >> 8; }
static inline bool in_bounds(const PixmatCore* mc, int x, int y) {
return (x >= 0 && x < mc->width && y >= 0 && y < mc->height);
}
/* helper: apply brightness scaling to a pixel */
static inline void apply_brightness(uint8_t *px, int bpp, uint8_t bri) {
if (bri == 255) return;
for (int i = 0; i < bpp; ++i) {
px[i] = mul8(px[i], bri);
}
}
static inline void unpack_color(uint32_t c, int bpp, uint8_t out[8]) {
if (bpp == 1) { out[0] = c & 0xFF; return; }
if (bpp == 2) { out[0] = (c>>8)&0xFF; out[1] = c&0xFF; return; }
if (bpp == 3) { out[0] = (c>>16)&0xFF; out[1] = (c>>8)&0xFF; out[2] = c&0xFF; return; }
if (bpp == 4) { out[0] = (c>>24)&0xFF; out[1] = (c>>16)&0xFF; out[2] = (c>>8)&0xFF; out[3] = c&0xFF; }
}
extern "C" {
// Prototypes for all Berry entry points
int be_pixmat_init(bvm* vm);
int be_pixmat_deinit(bvm* vm);
int be_pixmat_get(bvm* vm);
int be_pixmat_set(bvm* vm);
int be_pixmat_blit(bvm* vm);
int be_pixmat_scroll(bvm* vm);
int be_pixmat_clear(bvm* vm);
int be_pixmat_init(bvm* vm) {
int argc = be_top(vm);
auto* mc = new PixmatCore();
// overload: pixmat(bitplane_bytes, bytes_per_line)
if (be_isbytes(vm, 2) && be_isint(vm, 3) && argc == 3) {
size_t len = 0;
const uint8_t* bits = (const uint8_t*)be_tobytes(vm, 2, &len);
int bytes_per_line = be_toint(vm, 3);
if (bytes_per_line <= 0 || (len % bytes_per_line) != 0) {
delete mc;
be_raise(vm, "value_error", "invalid bitplane dimensions");
}
mc->width = bytes_per_line * 8;
mc->height = (int)(len / bytes_per_line);
mc->bpp = 1;
mc->serpentine = false;
mc->external = false;
size_t need = mc->bytes_size();
mc->data = (uint8_t*)malloc(need);
if (!mc->data) {
delete mc;
be_raise(vm, "runtime_error", "alloc fail");
}
memset(mc->data, 0, need);
// Unpack bits into 1bpp luminance values (0 or 255)
for (int y = 0; y < mc->height; ++y) {
for (int xb = 0; xb < bytes_per_line; ++xb) {
uint8_t b = bits[y * bytes_per_line + xb];
for (int bit = 0; bit < 8; ++bit) {
if (b & (1 << (7 - bit))) {
mc->data[y * mc->width + xb * 8 + bit] = 255;
}
}
}
}
}
// overload: wrap external buffer
else if (be_isbytes(vm, 2)) {
size_t len = 0;
const void* ptr = be_tobytes(vm, 2, &len);
mc->width = be_toint(vm, 3);
mc->height = be_toint(vm, 4);
mc->bpp = be_toint(vm, 5);
mc->serpentine = (argc >= 6) ? be_tobool(vm, 6) : false;
mc->external = true;
if (mc->width <= 0 || mc->height <= 0 || mc->bpp <= 0) {
delete mc; be_raise(vm, "value_error", "invalid dimensions or bpp");
}
size_t need = (size_t)mc->width * (size_t)mc->height;
if (mc->bpp > 0 && need > (std::numeric_limits<size_t>::max)() / (size_t)mc->bpp) {
delete mc; be_raise(vm, "value_error", "size overflow");
}
need *= (size_t)mc->bpp;
if (len < need) { delete mc; be_raise(vm, "value_error", "buffer too small"); }
mc->data = (uint8_t*)ptr;
be_pushvalue(vm, 2);
be_setmember(vm, 1, "_buf");
}
// overload: allocate new buffer
else if (be_isint(vm, 2)) {
mc->width = be_toint(vm, 2);
mc->height = be_toint(vm, 3);
mc->bpp = be_toint(vm, 4);
mc->serpentine = (argc >= 5) ? be_tobool(vm, 5) : false;
mc->external = false;
if (mc->width <= 0 || mc->height <= 0 || mc->bpp <= 0) {
delete mc; be_raise(vm, "value_error", "invalid dimensions or bpp");
}
size_t need = (size_t)mc->width * (size_t)mc->height;
if (mc->bpp > 0 && need > (std::numeric_limits<size_t>::max)() / (size_t)mc->bpp) {
delete mc; be_raise(vm, "value_error", "size overflow");
}
need *= (size_t)mc->bpp;
mc->data = (uint8_t*)malloc(need);
if (!mc->data) { delete mc; be_raise(vm, "runtime_error", "alloc fail"); }
memset(mc->data, 0, need);
}
else {
delete mc;
be_raise(vm, "type_error",
"pixmat(bitlines:bytes,bytes_per_line) or pixmat(buf:bytes,w,h,bpp,[serp]) or pixmat(w,h,bpp,[serp])");
}
be_pushcomptr(vm, (void*)mc);
be_setmember(vm, 1, ".p");
be_return_nil(vm);
}
int be_pixmat_deinit(bvm* vm) {
auto* mc = self_core(vm);
if (mc) {
if (!mc->external && mc->data) free(mc->data);
delete mc;
be_pushnil(vm); be_setmember(vm, 1, ".p");
}
be_return_nil(vm);
}
int be_pixmat_clear(bvm* vm) {
auto* mc = self_core(vm);
if (!mc) be_raise(vm, "type_error", "clear([val:int])");
int val = (be_top(vm) >= 2) ? (be_toint(vm, 2) & 0xFF) : 0;
memset(mc->data, val, mc->bytes_size());
be_return_nil(vm);
}
/* get */
int be_pixmat_get(bvm* vm) {
auto* mc = self_core(vm);
if (!mc || be_top(vm) < 3) be_raise(vm, "type_error", "get(x,y)");
int x = be_toint(vm, 2), y = be_toint(vm, 3);
if (!in_bounds(mc, x, y)) be_return_nil(vm);
uint8_t v[8]; mc->load(x, y, v);
if (mc->bpp == 3) { unsigned int c = (v[0] << 16) | (v[1] << 8) | v[2]; be_pushint(vm, (bint)c); }
else if (mc->bpp == 4) { unsigned int c = (v[0] << 24) | (v[1] << 16) | (v[2] << 8) | v[3]; be_pushint(vm, (bint)c); }
else if (mc->bpp == 1) { be_pushint(vm, v[0]); }
else if (mc->bpp == 2) {
unsigned int c = (v[0] << 8) | v[1];
be_pushint(vm, (bint)c);
}
else { be_newlist(vm); for (int i=0;i<mc->bpp;++i){ be_pushint(vm, v[i]); be_data_push(vm, -2);} }
be_return(vm);
}
int be_pixmat_set(bvm* vm) {
auto* mc = self_core(vm);
int argc = be_top(vm);
if (!mc || argc < 4) {
be_raise(vm, "type_error",
"set(x:int,y:int,val[,bri:int]) or set(x:int,y:int,h:int,s:int,v:int[,bri:int])");
}
int x = be_toint(vm, 2), y = be_toint(vm, 3);
if (!in_bounds(mc, x, y)) return 0;
uint8_t vals[8] = {0};
// default brightness
uint8_t bri = (argc == 5 || argc == 7) ? (uint8_t)be_toint(vm, argc) : 255;
if (be_isint(vm, 4) && (argc == 4 || argc == 5)) {
// RGB packed int path
unsigned int color = (unsigned int)be_toint(vm, 4);
unpack_color(color, mc->bpp, vals);
}
else if (argc >= 6 && argc <= 7) {
// HSV path: set(x,y,h,s,v[,bri])
int h = be_toint(vm, 4);
int s = be_toint(vm, 5);
int v = be_toint(vm, 6);
if (argc == 7) bri = (uint8_t)be_toint(vm, 7);
h %= 360; if (h < 0) h += 360;
uint16_t hue = (uint16_t)((h * 1536L) / 360L);
uint8_t sat = (uint8_t)s, val = (uint8_t)v;
uint8_t sextant = hue >> 8, frac = hue & 0xFF;
uint8_t p = (val * (255 - sat)) >> 8;
uint8_t q = (val * (255 - ((sat * frac) >> 8))) >> 8;
uint8_t t = (val * (255 - ((sat * (255 - frac)) >> 8))) >> 8;
if (mc->bpp >= 3) {
switch (sextant) {
case 0: vals[0] = val; vals[1] = t; vals[2] = p; break;
case 1: vals[0] = q; vals[1] = val; vals[2] = p; break;
case 2: vals[0] = p; vals[1] = val; vals[2] = t; break;
case 3: vals[0] = p; vals[1] = q; vals[2] = val; break;
case 4: vals[0] = t; vals[1] = p; vals[2] = val; break;
default:vals[0] = val; vals[1] = p; vals[2] = q; break;
}
} else if (mc->bpp == 1 || mc->bpp == 2) {
vals[0] = val;
if (mc->bpp == 2) vals[1] = val;
}
}
else {
be_raise(vm, "type_error", "unsupported argument pattern");
}
apply_brightness(vals, mc->bpp, bri);
mc->store(x, y, vals);
be_return_nil(vm);
}
int be_pixmat_blit(bvm* vm) {
auto* dest = self_core(vm);
if (!dest || be_top(vm) < 4) be_raise(vm, "type_error", "blit(src,dx,dy[,bri:int][,tint:int])");
be_getmember(vm, 2, ".p");
PixmatCore* src = (PixmatCore*)be_tocomptr(vm, -1);
be_pop(vm, 1);
if (!src) be_raise(vm, "type_error", "invalid src matrix");
const int dx = be_toint(vm, 3);
const int dy = be_toint(vm, 4);
const bool same_bpp = (src->bpp == dest->bpp);
const bool mono_to_color = (src->bpp == 1);
if (!same_bpp && !mono_to_color) be_raise(vm, "value_error", "unsupported bpp conversion");
int bri = 255;
uint8_t tint[8] = {255,255,255,255,0,0,0,0}; // identity tint by default
bool has_tint = false;
if (be_top(vm) >= 5 && be_isint(vm, 5)) bri = (uint8_t)be_toint(vm, 5);
if (be_top(vm) >= 6 && be_isint(vm, 6)) { unpack_color((uint32_t)be_toint(vm, 6), dest->bpp, tint); has_tint = true; }
// default tint for mono->color if none given: keep identity (white)
if (mono_to_color && !has_tint) has_tint = false; // identity tint
// Fast path
if (same_bpp && bri == 255 && !has_tint) { dest->blit(src, dx, dy); be_return_nil(vm); }
// Slow path
uint8_t s[8], d[8];
for (int sy = 0; sy < src->height; ++sy) {
int dypos = dy + sy; if (dypos < 0 || dypos >= dest->height) continue;
for (int sx = 0; sx < src->width; ++sx) {
int dxpos = dx + sx; if (dxpos < 0 || dxpos >= dest->width) continue;
src->load(sx, sy, s);
if (src->bpp == 1 && s[0] == 0) continue; // skip transparent mono pixel
if (same_bpp) {
memcpy(d, s, dest->bpp);
if (has_tint) for (int c = 0; c < dest->bpp; ++c) d[c] = mul8(d[c], tint[c]);
apply_brightness(d, dest->bpp, bri);
dest->store(dxpos, dypos, d);
} else {
// mono -> color (or mono -> mono)
uint8_t L = s[0];
for (int c = 0; c < dest->bpp; ++c) d[c] = has_tint ? mul8(L, tint[c]) : L;
apply_brightness(d, dest->bpp, bri);
dest->store(dxpos, dypos, d);
}
}
}
be_return_nil(vm);
}
int be_pixmat_scroll(bvm* vm) {
auto* d = self_core(vm);
if (!d || be_top(vm) < 2)
be_raise(vm, "type_error", "scroll(dir[,src])");
int dir = be_toint(vm, 2) & 3;
int w = d->width;
int h = d->height;
int bpp = d->bpp;
PixmatCore* s = nullptr;
if (be_top(vm) >= 3 && !be_isnil(vm, 3)) {
be_getmember(vm, 3, ".p");
s = (PixmatCore*)be_tocomptr(vm, -1);
be_pop(vm, 1);
}
size_t need = (dir < 2 ? w : h) * bpp;
uint8_t edge[256], pix[8];
auto save_row = [&](int y, PixmatCore* m) { for (int x = 0; x < w; ++x) m->load(x, y, edge + x * bpp); };
auto save_col = [&](int x, PixmatCore* m) { for (int y = 0; y < h; ++y) m->load(x, y, edge + y * bpp); };
auto write_row = [&](int y) { for (int x = 0; x < w; ++x) d->store(x, y, edge + x * bpp); };
auto write_col = [&](int x) { for (int y = 0; y < h; ++y) d->store(x, y, edge + y * bpp); };
switch (dir) {
case 0:
save_row(!s || s == d ? 0 : h - 1, !s || s == d ? d : s);
for (int y = 0; y < h - 1; ++y)
for (int x = 0; x < w; ++x) {
d->load(x, y + 1, pix);
d->store(x, y, pix);
}
write_row(h - 1);
break;
case 1:
save_col(!s || s == d ? 0 : w - 1, !s || s == d ? d : s);
for (int y = 0; y < h; ++y)
for (int x = 0; x < w - 1; ++x) {
d->load(x + 1, y, pix);
d->store(x, y, pix);
}
write_col(w - 1);
break;
case 2:
save_row(!s || s == d ? h - 1 : 0, !s || s == d ? d : s);
for (int y = h - 1; y > 0; --y)
for (int x = 0; x < w; ++x) {
d->load(x, y - 1, pix);
d->store(x, y, pix);
}
write_row(0);
break;
case 3:
save_col(!s || s == d ? w - 1 : 0, !s || s == d ? d : s);
for (int y = 0; y < h; ++y)
for (int x = w - 1; x > 0; --x) {
d->load(x - 1, y, pix);
d->store(x, y, pix);
}
write_col(0);
break;
}
be_return_nil(vm);
}
} // extern "C"
#endif // USE_WS2812
#endif // USE_BERRY
/*
pixmat API (Berry)
==================
Constructor overloads:
-----------------------
pixmat(bitplane_bytes:bytes, bytes_per_line:int)
Create 1bpp mono matrix from packed bitplane data.
pixmat(buf:bytes, width:int, height:int, bpp:int[, serpentine:bool])
Wrap an existing pixel buffer (no copy).
pixmat(width:int, height:int, bpp:int[, serpentine:bool])
Allocate a new zerofilled buffer.
Methods:
--------
clear([val:int])
Fill entire matrix with val (default 0).
get(x:int, y:int) -> int | list
1bpp: luminance (0255)
3bpp: packed RGB 0xRRGGBB
4bpp: packed RGBW 0xRRGGBBWW
other bpp: list of channel values.
set(x:int, y:int, rgb:int[, bri:int])
Set pixel from packed RGB, optional brightness scale.
set(x:int, y:int, h:int, s:int, v:int[, bri:int])
Set pixel from HSV (h=0359°, s/v=0255), optional brightness.
blit(src:pixmat, dx:int, dy:int[, bri:int][, tint:int])
Copy pixels from src into this matrix at offset.
Optional brightness scale and RGB tint.
Supports mono→color expansion.
scroll(dir:int[, src:pixmat])
Scroll content by one pixel:
dir=0: up
dir=1: left
dir=2: down
dir=3: right
If src given, fill vacated row/col from src.
Notes:
------
- bpp = bytes per pixel (1=mono, 3=RGB, 4=RGBW)
- serpentine=true reverses odd rows in memory
- All operations are inplace on the underlying buffer
- Brightness/tint use integer perchannel scaling
*/
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