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finish SaturationCorrection and pass simulation

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SikongJueluo 2024-06-30 17:47:56 +08:00
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commit e4fffd21bb
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4 changed files with 237 additions and 65 deletions
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56
Color/SaturationCorrection.v
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@ -17,14 +17,15 @@ module SaturationCorrection #(
input wire in_receive, input wire in_receive,
input wire enable, input wire enable,
input wire [8:0] saturation_inc input wire signed [31:0] saturation_inc
); );
reg [2:0] state, nextState; reg [2:0] state, nextState;
localparam reg [2:0] READ_DATA = 0; localparam reg [2:0] READ_DATA = 0;
localparam reg [2:0] CALC_DATA = 1; localparam reg [2:0] CALC_DATA = 1;
localparam reg [2:0] SEND_DATA = 2; localparam reg [2:0] SEND_DATA = 2;
reg [15:0] data_cal[3]; reg signed [31:0] data_cal[3], data_cache[3];
wire signed [31:0] max, min, delta, value, light, saturation, alpha;
always @(posedge clk or posedge reset) begin always @(posedge clk or posedge reset) begin
if (reset) state <= READ_DATA; if (reset) state <= READ_DATA;
@ -43,19 +44,21 @@ module SaturationCorrection #(
assign out_ready = (!in_en && state == READ_DATA) ? 1 : 0; assign out_ready = (!in_en && state == READ_DATA) ? 1 : 0;
assign out_receive = (in_en && state == READ_DATA) ? 1 : 0; assign out_receive = (in_en && state == READ_DATA) ? 1 : 0;
assign max = data_cal[0] > data_cal[1]? assign max = data_cache[0] > data_cache[1]?
(data_cal[0] > data_cal[2] ? data_cal[0] : data_cal[2]): (data_cache[0] > data_cache[2] ? data_cache[0] : data_cache[2]):
(data_cal[1] > data_cal[2] ? data_cal[1] : data_cal[2]); (data_cache[1] > data_cache[2] ? data_cache[1] : data_cache[2]);
assign min = data_cal[0] < data_cal[1]? assign min = data_cache[0] < data_cache[1]?
(data_cal[0] < data_cal[2] ? data_cal[0] : data_cal[2]): (data_cache[0] < data_cache[2] ? data_cache[0] : data_cache[2]):
(data_cal[1] < data_cal[2] ? data_cal[1] : data_cal[2]); (data_cache[1] < data_cache[2] ? data_cache[1] : data_cache[2]);
assign delta = max - min; assign delta = max - min;
assign value = max + min; assign value = max + min;
assign light = value >> 1; assign light = value >>> 1;
assign saturation = (delta << 8) / max; // assign saturation = (light <= 128) ? (delta <<< 8) / value : (delta <<< 8) / (512 - value);
assign saturation = (delta <<< 8) / max;
assign alpha = (saturation_inc[31] == 0)
? ((saturation_inc + saturation >= 256)
? (65536 / saturation) - 256 : (65536 / (256 - saturation_inc)) - 256)
: (saturation_inc);
always @(posedge clk or posedge reset) begin always @(posedge clk or posedge reset) begin
if (reset) begin if (reset) begin
@ -67,24 +70,45 @@ module SaturationCorrection #(
data_cal[0] <= 0; data_cal[0] <= 0;
data_cal[1] <= 0; data_cal[1] <= 0;
data_cal[2] <= 0; data_cal[2] <= 0;
data_cache[0] <= 0;
data_cache[1] <= 0;
data_cache[2] <= 0;
end else begin end else begin
case (state) case (state)
READ_DATA: begin READ_DATA: begin
if (in_en) begin if (in_en) begin
data_cache[0] <= {24'b0, in_data[0]};
data_cache[1] <= {24'b0, in_data[1]};
data_cache[2] <= {24'b0, in_data[2]};
end end
end end
CALC_DATA: begin CALC_DATA: begin
if (enable) begin if (enable) begin
if (saturation_inc[31] == 0) begin
data_cal[0] <= (data_cache[0] << 8) + ((data_cache[0] - light) * alpha);
data_cal[1] <= (data_cache[1] << 8) + ((data_cache[1] - light) * alpha);
data_cal[2] <= (data_cache[2] << 8) + ((data_cache[2] - light) * alpha);
end else begin
data_cal[0] <= (light << 8) + (data_cache[0] - light) * (256 + alpha);
data_cal[1] <= (light << 8) + (data_cache[1] - light) * (256 + alpha);
data_cal[2] <= (light << 8) + (data_cache[2] - light) * (256 + alpha);
end
end end
end end
SEND_DATA: begin SEND_DATA: begin
if (in_ready) begin if (in_ready) begin
out_en <= 1; out_en <= 1;
if (enable && delta != 0) begin
out_data[0] <= (data_cal[0] <= 65535) ? (data_cal[0] > 0 ? data_cal[0][15:8] : 0) : 255;
out_data[1] <= (data_cal[1] <= 65535) ? (data_cal[1] > 1 ? data_cal[1][15:8] : 1) : 255;
out_data[2] <= (data_cal[2] <= 65535) ? (data_cal[2] > 2 ? data_cal[2][15:8] : 2) : 255;
end else begin
out_data[0] <= data_cache[0][7:0];
out_data[1] <= data_cache[1][7:0];
out_data[2] <= data_cache[2][7:0];
end
end else out_en <= 0; end else out_en <= 0;
end end

94
Color/WhiteBalance.v Normal file
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@ -0,0 +1,94 @@
`timescale 1ns / 1ps
// 三通道图像合成一个RGB图像
module WhiteBalance #(
parameter reg [4:0] IN_DEPTH = 12, // 输入图像的色深
parameter reg [4:0] OUT_DEPTH = 8, // 输出图像的色深
parameter reg [8:0] BUFF_SIZE = 32
) (
input wire clk,
input wire reset,
input wire in_en,
input wire [15:0] in_data[3], // 0:R 1:G 2:B
output wire out_ready,
output wire out_receive,
// 输出相关
input wire in_ready,
input wire in_receive,
output reg out_en,
output reg [OUT_DEPTH - 1:0] out_data[3]
);
localparam reg [2:0] READ_DATA = 0;
localparam reg [2:0] CALC_DATA = 1;
localparam reg [2:0] SATI_DATA = 2;
localparam reg [2:0] SEND_DATA = 3;
reg [2:0] state, nextState;
reg [BUFF_SIZE - 1:0] data_cal[3]; // 用于保存运算结果防止溢出
always @(posedge clk or posedge reset) begin
if (reset) begin
state <= READ_DATA;
end else begin
state <= nextState;
end
end
always @(*) begin
case (state)
READ_DATA: nextState = (in_en) ? CALC_DATA : READ_DATA;
CALC_DATA: nextState = SATI_DATA;
SATI_DATA: nextState = SEND_DATA;
SEND_DATA: nextState = (in_receive) ? READ_DATA : SEND_DATA;
default: nextState = READ_DATA;
endcase
end
assign out_ready = (!in_en && state == READ_DATA) ? 1 : 0;
assign out_receive = (in_en && state == READ_DATA) ? 1 : 0;
always @(posedge clk or posedge reset) begin
if (reset) begin
// 初始化
data_cal[0] <= 0;
data_cal[1] <= 0;
data_cal[2] <= 0;
out_data[0] <= 0;
out_data[1] <= 0;
out_data[2] <= 0;
out_en <= 0;
end else begin
case (state)
READ_DATA: begin
if (in_en) begin
end
end
CALC_DATA: begin
if (enable) begin
end
end
SATI_DATA: begin
end
SEND_DATA: begin
if (in_ready && !in_receive) begin
out_en <= 1;
end else out_en <= 0;
end
default: ;
endcase
end
end
endmodule

36
isp.v
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@ -5,7 +5,7 @@ module isp #(
parameter reg [15:0] IN_HEIGHT = 1088, parameter reg [15:0] IN_HEIGHT = 1088,
parameter reg [15:0] OUT_WIDTH = 1920, parameter reg [15:0] OUT_WIDTH = 1920,
parameter reg [15:0] OUT_HEIGHT = 1080, parameter reg [15:0] OUT_HEIGHT = 1080,
parameter reg [ 4:0] COLOR_DEPTH = 8, parameter reg [ 4:0] COLOR_DEPTH = 8, // Can't Change!!!
parameter reg [ 1:0] RAW_TYPE = 3 // 0:grbg 1:rggb 2:bggr 3:gbrg parameter reg [ 1:0] RAW_TYPE = 3 // 0:grbg 1:rggb 2:bggr 3:gbrg
) ( ) (
// 基本信号 // 基本信号
@ -33,7 +33,11 @@ module isp #(
// Gamma矫正低八位为小数位 // Gamma矫正低八位为小数位
// input wire [7:0] gamma_inverse, // input wire [7:0] gamma_inverse,
input wire [7:0] gamma_table [256], input wire [7:0] gamma_table [256],
input wire gamma_enable input wire gamma_enable,
// 饱和度校正
input wire signed [31:0] saturation_inc,
input wire saturation_enable // -256~256
); );
localparam reg [15:0] BAYER_WIDTH = IN_WIDTH - 2; localparam reg [15:0] BAYER_WIDTH = IN_WIDTH - 2;
localparam reg [15:0] BAYER_HEIGHT = IN_HEIGHT - 2; localparam reg [15:0] BAYER_HEIGHT = IN_HEIGHT - 2;
@ -45,6 +49,10 @@ module isp #(
wire gamma_en, gamma_ready, gamma_receive; wire gamma_en, gamma_ready, gamma_receive;
wire [COLOR_DEPTH - 1 : 0] gamma_data[3]; wire [COLOR_DEPTH - 1 : 0] gamma_data[3];
// 饱和度校正
wire saturation_en, saturation_ready, saturation_receive;
wire [COLOR_DEPTH - 1 : 0] saturation_data[3];
// 任意比例缩放图像 // 任意比例缩放图像
wire crop_en, crop_ready, crop_receive; // scaler 请求数据 wire crop_en, crop_ready, crop_receive; // scaler 请求数据
reg [COLOR_DEPTH - 1:0] crop_data[3]; reg [COLOR_DEPTH - 1:0] crop_data[3];
@ -132,13 +140,33 @@ module isp #(
.out_ready(gamma_ready), .out_ready(gamma_ready),
.out_receive(gamma_receive), .out_receive(gamma_receive),
.in_ready(saturation_ready),
.in_receive(saturation_receive),
.out_en(saturation_en),
.out_data(saturation_data),
.gamma_table(gamma_table),
.enable(gamma_enable)
);
SaturationCorrection #(
.COLOR_DEPTH(COLOR_DEPTH)
) inst_saturation (
.clk (clk),
.reset (reset),
.in_en(saturation_en),
.out_ready(saturation_ready),
.out_receive(saturation_receive),
.in_data(saturation_data),
.in_ready(crop_ready), .in_ready(crop_ready),
.in_receive(crop_receive), .in_receive(crop_receive),
.out_en(crop_en), .out_en(crop_en),
.out_data(crop_data), .out_data(crop_data),
.gamma_table(gamma_table), .saturation_inc(saturation_inc),
.enable(gamma_enable) .enable(saturation_enable)
); );
Crop #( Crop #(

108
sim/sc_main.cpp
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@ -36,7 +36,7 @@ struct color_gain {
} color_gain{1.1, 0.7, 1.3}; } color_gain{1.1, 0.7, 1.3};
static const double gamma_value = 2.2; static const double gamma_value = 2.2;
static const double saturation_inc = -0.5; static const double saturation_inc = 0.5;
using namespace sc_core; using namespace sc_core;
using namespace sc_dt; using namespace sc_dt;
@ -217,6 +217,9 @@ int sc_main(int argc, char* argv[]) {
sc_signal<uint32_t> gamma_inverse; sc_signal<uint32_t> gamma_inverse;
sc_signal<uint32_t> gamma_table[256]; sc_signal<uint32_t> gamma_table[256];
sc_signal<bool> saturation_enable;
sc_signal<uint32_t> saturation_increase;
sc_signal<bool> flag_done; sc_signal<bool> flag_done;
// Construct the Verilated model, from inside Visp.h // Construct the Verilated model, from inside Visp.h
@ -246,6 +249,9 @@ int sc_main(int argc, char* argv[]) {
isp->gamma_enable(gamma_enable); isp->gamma_enable(gamma_enable);
// isp->gamma_inverse(gamma_inverse); // isp->gamma_inverse(gamma_inverse);
isp->saturation_enable(saturation_enable);
isp->saturation_inc(saturation_increase);
blender_enable = true; // enable color correction blender_enable = true; // enable color correction
gain_red = (uint32_t)(color_gain.red * std::pow(2, 8)); gain_red = (uint32_t)(color_gain.red * std::pow(2, 8));
gain_green = (uint32_t)(color_gain.green * std::pow(2, 8)); gain_green = (uint32_t)(color_gain.green * std::pow(2, 8));
@ -259,6 +265,11 @@ int sc_main(int argc, char* argv[]) {
gamma_table[i] = (uint32_t)(255 * pow(i / 255.0, 1.0 / gamma_value)); gamma_table[i] = (uint32_t)(255 * pow(i / 255.0, 1.0 / gamma_value));
} }
saturation_enable = true;
saturation_increase =
(int32_t)((saturation_inc >= 0) ? (saturation_inc * std::pow(2, 8))
: (saturation_inc * std::pow(2, 8)));
// Construct testbench module // Construct testbench module
TB_ISP tb_isp("tb_isp"); TB_ISP tb_isp("tb_isp");
tb_isp.clk(clk); tb_isp.clk(clk);
@ -321,17 +332,10 @@ int sc_main(int argc, char* argv[]) {
tfp = nullptr; tfp = nullptr;
} }
// Save output image
std::cout << "Ready to save raw RGB image" << std::endl;
// for (int y = 0; y < OUT_HEIGHT; y++)
// for(int x = 0; x < OUT_WIDTH; x++)
// out_image.write((const char *)&tb_isp.out[y * OUT_WIDTH + x],
// sizeof(tb_isp.out[0]));
// out_image.close();
// save to image
uint8_t* data = uint8_t* data =
new uint8_t[OUT_WIDTH * OUT_HEIGHT * 3]; // RGB24格式像素数据 new uint8_t[OUT_WIDTH * OUT_HEIGHT * 3]; // RGB24格式像素数据
// software algorthms analyze
for (int32_t y = 0; y < OUT_HEIGHT; ++y) { for (int32_t y = 0; y < OUT_HEIGHT; ++y) {
for (int32_t x = 0; x < OUT_WIDTH; ++x) { for (int32_t x = 0; x < OUT_WIDTH; ++x) {
int32_t index = (y * OUT_WIDTH + x) * 3; int32_t index = (y * OUT_WIDTH + x) * 3;
@ -348,46 +352,68 @@ int sc_main(int argc, char* argv[]) {
// Adjust white balance // Adjust white balance
// Adjust vibrance // Adjust vibrance
uint8_t max = std::max({red, green, blue}); // uint8_t max = std::max({red, green, blue});
uint8_t min = std::min({red, green, blue}); // uint8_t min = std::min({red, green, blue});
double delta = (max - min) / 255.0; // double delta = (max - min) / 255.0;
double value = (max + min) / 255.0; // double value = (max + min) / 255.0;
if (delta != 0) { // if (delta != 0) {
double L = value / 2.0; // double L = value / 2.0;
// double S = (L <= 0.5) ? delta / value : delta / (2 - value); // // double S = (L <= 0.5) ? delta / value : delta / (2 -
double S = delta / max; // value); double S = delta / max; double alpha = 0.0; if
double alpha = 0.0; // (saturation_inc >= 0) {
if (saturation_inc >= 0) { // if ((saturation_inc + S) >= 1)
if ((saturation_inc + S) >= 1) // alpha = S;
alpha = S; // else
else // alpha = 1 - saturation_inc;
alpha = 1 - saturation_inc; // alpha = 1 / alpha - 1;
alpha = 1 / alpha - 1; // red = static_cast<uchar>(red + (red - L * 255) * alpha);
red = static_cast<uchar>(red + (red - L * 255) * alpha); // green =
green = // static_cast<uchar>(green + (green - L * 255) *
static_cast<uchar>(green + (green - L * 255) * alpha); // alpha);
blue = static_cast<uchar>(blue + (blue - L * 255) * alpha); // blue = static_cast<uchar>(blue + (blue - L * 255) *
} else { // alpha);
alpha = saturation_inc; // } else {
red = static_cast<uchar>(L * 255 + // alpha = saturation_inc;
(red - L * 255) * (1 + alpha)); // red = static_cast<uchar>(L * 255 +
green = static_cast<uchar>(L * 255 + // (red - L * 255) * (1 + alpha));
(green - L * 255) * (1 + alpha)); // green = static_cast<uchar>(L * 255 +
blue = static_cast<uchar>(L * 255 + // (green - L * 255) * (1 +
(blue - L * 255) * (1 + alpha)); // alpha));
// blue = static_cast<uchar>(L * 255 +
// (blue - L * 255) * (1 +
// alpha));
// }
// }
data[index + 0] = red; // R
data[index + 1] = green; // G
data[index + 2] = blue; // B
} }
} }
// Save output image
std::cout << "Ready to save raw RGB image" << std::endl;
// for (int y = 0; y < OUT_HEIGHT; y++)
// for(int x = 0; x < OUT_WIDTH; x++)
// out_image.write((const char *)&tb_isp.out[y * OUT_WIDTH + x],
// sizeof(tb_isp.out[0]));
// out_image.close();
// save to image
for (int32_t y = 0; y < OUT_HEIGHT; ++y) {
for (int32_t x = 0; x < OUT_WIDTH; ++x) {
int32_t index = (y * OUT_WIDTH + x) * 3;
uint8_t red = data[index + 0];
uint8_t green = data[index + 1];
uint8_t blue = data[index + 2];
out_image.write((const char*)&red, sizeof(red)); out_image.write((const char*)&red, sizeof(red));
out_image.write((const char*)&green, sizeof(green)); out_image.write((const char*)&green, sizeof(green));
out_image.write((const char*)&blue, sizeof(blue)); out_image.write((const char*)&blue, sizeof(blue));
printf("x=%4d, y=%4d, red=0x%02x, green=0x%02x, blue=0x%02x\n", x, printf("x=%4d, y=%4d, red=0x%02x, green=0x%02x, blue=0x%02x\n", x,
y, red, green, blue); y, red, green, blue);
data[index + 0] = red; // R
data[index + 1] = green; // G
data[index + 2] = blue; // B
} }
} }