/* gui.c
This file is part of the "First" CPU simulator project.
Copyright (c) 2024 Efthymios Kritikos
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 . */
#include
#include
#include "simdata.h"
#include "assembly.h"
#include
#include "cpu.h"
#include "gui.h"
#include
#define GENERAL_STACK_MAX_WIDTH 16
#define GENERAL_DISAS_WIDTH 41
int terminal_width;
int terminal_height;
struct gui_settings_t *gui_settings;
WINDOW *tabs;
WINDOW *general_memdump;
WINDOW *general_stack;
WINDOW *general_disas;
WINDOW *general_registers;
WINDOW *general_terminal_output;
WINDOW *memory_memdump;
WINDOW *pipeline_pipeline;
WINDOW *pipeline_disas;
WINDOW *debug_simdata;
int monochrome;
int get_terminal_size(){
int new_height,new_width;
getmaxyx(stdscr,new_height,new_width);
int changed=(new_width!=terminal_width)||(new_height!=terminal_height);
terminal_width=new_width;
terminal_height=new_height;
return changed;
}
char *tab_name[]={"Overview","Memory","Pipeline","Debug"};
unsigned int CURRENT_TAB=1;
int gui_ncurses_refresh(){
if(refresh()==ERR)
return 1;
if(wrefresh(tabs)==ERR)
return 1;
if(CURRENT_TAB==1){
if(wrefresh(general_memdump)==ERR)
return 1;
if(wrefresh(general_stack)==ERR)
return 1;
if(wrefresh(general_disas)==ERR)
return 1;
if(wrefresh(general_registers)==ERR)
return 1;
if(wrefresh(general_terminal_output)==ERR)
return 1;
}else if(CURRENT_TAB==2){
if(wrefresh(memory_memdump)==ERR)
return 1;
}else if(CURRENT_TAB==3){
if(wrefresh(pipeline_disas)==ERR)
return 1;
if(wrefresh(pipeline_pipeline)==ERR)
return 1;
}else if(CURRENT_TAB==4){
if(wrefresh(debug_simdata)==ERR)
return 1;
}
return 0;
}
enum GUI_CPU_STATE_t GUI_CPU_STATE=GUI_CPU_SINGLE_STEPPING;
void update_tabs(){
wattron(tabs,A_BOLD);
wattron(tabs,COLOR_PAIR(2));
for(int i=0;iGENERAL_DISAS_WIDTH?GENERAL_DISAS_WIDTH:(terminal_width/6);
general_disas=newwin(y2_divider,len,4,x);
x+=len;
x+=3;
len=(terminal_width/6)>GENERAL_STACK_MAX_WIDTH?GENERAL_STACK_MAX_WIDTH:(terminal_width/6);
general_stack=newwin(y2_divider,len,4,x);
x+=len;
general_registers=newwin(terminal_height-y1_divider-border-1,terminal_width/2,y1_divider+border+1,border);
x+=terminal_width/2;
x++;
general_terminal_output=newwin(terminal_height-y2_divider-border-1,terminal_width/2-3*border,y2_divider+border+1,middle);
scrollok(general_terminal_output,TRUE);
x+=terminal_width/2;
x++;
memory_memdump=newwin(terminal_height-1-border*2,terminal_width-border*2,1+border,border);
debug_simdata=newwin(terminal_height-1-border*2,terminal_width-border*2,1+border,border);
pipeline_pipeline=newwin(terminal_height-1-border*2,terminal_width-border*3-GENERAL_DISAS_WIDTH,1+border,border);
pipeline_disas=newwin(terminal_height-1-border*2,GENERAL_DISAS_WIDTH,1+border,border+terminal_width-border*3-GENERAL_DISAS_WIDTH);
gui_settings=malloc(sizeof(struct gui_settings_t));
gui_settings->cycles_per_frame=100;
if(gui_ncurses_refresh())
return 1;
return 0;
}
int gui_error(char *str){
WINDOW *error_win = newwin(3,40,terminal_height/2-1,terminal_width/2-20);
box(error_win, 0 , 0);
if(!monochrome)
wattron(error_win,COLOR_PAIR(1));
mvwprintw(error_win,1,1,"%s",str);
if(wrefresh(error_win)==ERR)
return 1;
getch();
delwin(error_win);
return 0;
if(!monochrome)
wattroff(error_win,COLOR_PAIR(1));
}
//// WARNING!! THIS ASSUMES THAT ADDRESS IS CORRECTLY ALIGNED WITH THE INSTRUCTION START/END!!
int select_instruction_color(struct simdata_t *simdata, WINDOW* window,uint32_t ADDRESS, int applyremove){
if(simdata->cpu_gui_hints){
struct instr_list_t* pointer;
pointer=simdata->cpu_gui_hints->fetching_list;
while(pointer!=NULL){
if(pointer->address==ADDRESS){
if(applyremove)
wattron(window,COLOR_PAIR(9));
else
wattroff(window,COLOR_PAIR(9));
return 0;
}
pointer=pointer->next;
}
pointer=simdata->cpu_gui_hints->decoding_list;
while(pointer!=NULL){
if(pointer->address==ADDRESS){
if(applyremove)
wattron(window,COLOR_PAIR(10));
else
wattroff(window,COLOR_PAIR(10));
return 0;
}
pointer=pointer->next;
}
pointer=simdata->cpu_gui_hints->executing_list;
while(pointer!=NULL){
if(pointer->address==ADDRESS){
if(applyremove)
wattron(window,COLOR_PAIR(11));
else
wattroff(window,COLOR_PAIR(11));
return 0;
}
pointer=pointer->next;
}
}
return 1;
}
int update_disas(WINDOW *win,struct simdata_t *simdata){
werase(win);
int width,height;
getmaxyx(win,height,width);
box(win, 0 , 0);
mvwprintw(win,0,width/2-7,"[ DISASSEMBLY ]");
if(simdata->registers==NULL||simdata->RAM==NULL){
mvwprintw(win,1,1,"Data not initialised");
return 0;
}
int offset_arrow;
int have_legend=(width>29);
int usable_height=height-2-have_legend;
if(width<41)
offset_arrow=2;
else
offset_arrow=3;
if(width<18){
mvwprintw(win,1,1,"too small window");
}else{
uint32_t ADDRESS=(simdata->registers->PC-(usable_height/2-2)*4)&0x00FFFFFF;
for (int i=2;iregisters->PC)
wattron(win,A_BOLD);
mvwprintw(win,i,4+overall_offset,"%06X",ADDRESS);
char* disas=disassemble(*(uint32_t*)(simdata->RAM+ADDRESS));
int space_left=width-14-2+(overall_offset?0:1);
if(space_left<25)
disas[space_left+1]=0;
select_instruction_color(simdata,win,ADDRESS,1);
mvwprintw(win,i,13+overall_offset,"%s",disas);
select_instruction_color(simdata,win,ADDRESS,0);
if(ADDRESS==simdata->registers->PC)
wattroff(win,A_BOLD);
ADDRESS=(ADDRESS+4)&0xFFFFFF;
free(disas);
}
mvwaddch(win,usable_height/2,offset_arrow,ACS_RARROW);
mvwaddch(win,usable_height/2,offset_arrow-1,ACS_ULCORNER);
mvwaddch(win,usable_height/2+1,offset_arrow-1,ACS_VLINE);
mvwaddch(win,usable_height/2+2,offset_arrow-1,ACS_VLINE);
mvwaddch(win,usable_height/2+3,offset_arrow-1,ACS_VLINE);
mvwaddch(win,usable_height/2+4,offset_arrow-1,ACS_VLINE);
mvwaddch(win,usable_height/2+5,offset_arrow-1,ACS_VLINE);
mvwaddch(win,usable_height/2+6,offset_arrow-1,'P');
if(offset_arrow==2)
mvwaddch(win,usable_height/2+7,offset_arrow-1,'C');
else
mvwaddch(win,usable_height/2+6,offset_arrow,'C');
if(have_legend){
wattron(win,COLOR_PAIR(12));
mvwprintw(win,height-2,2," ");
wattroff(win,COLOR_PAIR(12));
mvwprintw(win,height-2,4,"=Fetch");
wattron(win,COLOR_PAIR(13));
mvwprintw(win,height-2,11," ");
wattroff(win,COLOR_PAIR(13));
mvwprintw(win,height-2,13,"=Decode");
wattron(win,COLOR_PAIR(14));
mvwprintw(win,height-2,21," ");
wattroff(win,COLOR_PAIR(14));
mvwprintw(win,height-2,23,"=Exec");
}
}
return 0;
}
int update_general_stack(struct simdata_t *simdata){
int width,height;
getmaxyx(general_stack,height,width);
box(general_stack, 0 , 0);
mvwprintw(general_stack,0,width/2-4,"[ STACK ]");
if(simdata->registers==NULL||simdata->RAM==NULL){
mvwprintw(general_stack,1,1,"Data not initialised");
return 0;
}
if(width<13){
mvwprintw(general_stack,1,1,"too small window");
}else{
// Calculate config based on window size
int offset_data,offset_arrow;
if(width<14){
offset_data=3;
offset_arrow=2;
}else{
offset_data=5;
offset_arrow=3;
}
// draw data
uint32_t ADDRESS=(simdata->registers->SP-(height/2-2)*4)&0x00FFFFFF;
for(int i=0;iregisters->SP)
wattron(general_stack,A_BOLD);
mvwprintw(general_stack,i+2,offset_data,"%08X",*(uint32_t*)(simdata->RAM+ADDRESS));
if(ADDRESS==simdata->registers->SP)
wattroff(general_stack,A_BOLD);
ADDRESS=(ADDRESS+4)&0xFFFFFF;
}
// draw graphics
mvwaddch(general_stack,height/4-2,offset_arrow-1,ACS_UARROW);
mvwaddch(general_stack,height/4-1,offset_arrow-1,ACS_VLINE);
mvwaddch(general_stack,height/4 ,offset_arrow-1,ACS_VLINE);
mvwaddch(general_stack,height/4+1,offset_arrow-1,ACS_VLINE);
if(offset_arrow!=2)
mvwprintw(general_stack,height/4+2,1,"(+)");
else
mvwprintw(general_stack,height/4+2,offset_arrow-1,"+");
mvwaddch(general_stack,height/2,offset_arrow,ACS_RARROW);
mvwaddch(general_stack,height/2,offset_arrow-1,ACS_ULCORNER);
mvwaddch(general_stack,height/2+1,offset_arrow-1,ACS_VLINE);
mvwaddch(general_stack,height/2+2,offset_arrow-1,ACS_VLINE);
mvwaddch(general_stack,height/2+3,offset_arrow-1,ACS_VLINE);
mvwaddch(general_stack,height/2+4,offset_arrow-1,'S');
if(offset_arrow==2)
mvwaddch(general_stack,height/2+5,offset_arrow-1,'P');
else
mvwaddch(general_stack,height/2+4,offset_arrow,'P');
}
return 0;
}
//address: If within legal limit (address<0x00FFFFFF) then address*bytes_per_line will be used for the center of the memdump
// otherwise PC will be used
int update_memdump(WINDOW *win,uint32_t address,struct simdata_t *simdata){
int width,height;
getmaxyx(win,height,width);
box(win, 0 , 0);
mvwprintw(win,0,width/2-5,"[ MEMORY ]");
if(simdata->registers==NULL||simdata->RAM==NULL){
mvwprintw(win,1,1,"Data not initialised");
return 0;
}
if(width<16){
mvwprintw(win,1,1,"too small window");
}else{
int n=(width-12)/4; // bytes in each line
int usable_height=height-3-(width-12)%2;
uint32_t center_address;
if(address<=0x00FFFFFF)
center_address=address*n;
else
center_address=simdata->registers->PC;
uint32_t ADDRESS=(center_address-n*usable_height/2)&0x00FFFFFF;
uint32_t color_addr;
int have_color=0;
for(int h=0;h=simdata->registers->PC&&ADDRESS<=simdata->registers->PC+3)
wattron(win,A_BOLD);
else
wattroff(win,A_BOLD);
if(select_instruction_color(simdata,win,ADDRESS,1)==0){
have_color=5;
color_addr=ADDRESS;
}else if(have_color)
select_instruction_color(simdata,win,color_addr,1);
if(have_color){
have_color--;
if(!have_color)
select_instruction_color(simdata,win,color_addr,0);
}
wprintw(win,"%02x ",simdata->RAM[ADDRESS]);
ADDRESS=(ADDRESS+1)&0xFFFFFF;
}
if(have_color)
select_instruction_color(simdata,win,color_addr,0);
ADDRESS=temp_address;
for (int i=0;i=simdata->registers->PC&&ADDRESS<=simdata->registers->PC+3)
wattron(win,A_BOLD);
else
wattroff(win,A_BOLD);
wprintw(win,"%c",(simdata->RAM[ADDRESS]>=0x20&&simdata->RAM[ADDRESS]<0x7F)?simdata->RAM[ADDRESS]:'.');
ADDRESS=(ADDRESS+1)&0xFFFFFF;
}
}
}
return 0;
}
uint32_t memory_window_address=0x00000000;
int update_memory_memdump(struct simdata_t *simdata){
return update_memdump(memory_memdump,memory_window_address,simdata);
}
int update_general_memdump(struct simdata_t *simdata){
return update_memdump(general_memdump,0xFFFFFFFF,simdata);
}
int update_general_registers(struct simdata_t *simdata){
int width,height;
werase(general_registers);
getmaxyx(general_registers,height,width);
box(general_registers, 0 , 0);
mvwprintw(general_registers,0,width/2-7,"[ REGISTERS ]");
if(simdata->registers==NULL){
mvwprintw(general_registers,1,1,"Data not initialised");
return 0;
}
if(simdata->registers==NULL)
mvwprintw(general_registers,1,1,"Registers data structure not initialised");
else{
int per_line=width/35;
if(per_line==0)
mvwprintw(general_registers,1,1,"too small window");
else{
int center_x_offset=((width-2)-35*per_line)/2;
int lines_used=(8/(int)per_line<8/(float)per_line)?8/per_line+1:8/per_line;
int lines_for_special_registers;
lines_for_special_registers=( width < 22+27+8 )?2:1;
int center_y_offset=((height-2)-(lines_used+lines_for_special_registers+1))/2;
if((lines_used+lines_for_special_registers+1)>(height-2)||width<37)
mvwprintw(general_registers,1,1,"too small window");
else{
int n=0,y=0;
while(y!=lines_used){
for(int i=0;iregisters->GPR+n);
if(float_equiv<9999999999.0&&float_equiv>-9999999999.0)
mvwprintw(general_registers,1+y+center_y_offset,1+i*35+center_x_offset,"R%d: %08X (%08f) ",n,simdata->registers->GPR[n],float_equiv);
else
mvwprintw(general_registers,1+y+center_y_offset,1+i*35+center_x_offset,"R%d: %08X (%cinf) ",n,simdata->registers->GPR[n],(float_equiv>0)?'+':'-');
n++;
}
}
y++;
}
for(int i=0;i<35*per_line;i++)
mvwaddch(general_registers,1+center_y_offset+lines_used,center_x_offset+i,ACS_HLINE);
int spec_reg_1_offset, spec_reg_2_offset;
if(lines_for_special_registers==2){
spec_reg_1_offset=((width-2)/2)-(23/2);
spec_reg_2_offset=((width-2)/2)-(27/2);
}else{
spec_reg_1_offset=((width-2)/2)-(22+27+8)/2;
spec_reg_2_offset=spec_reg_1_offset+22+8;
}
wattron(general_registers,A_BOLD);
mvwprintw(general_registers,1+center_y_offset+lines_used+1,spec_reg_1_offset," PC");
wattroff(general_registers,A_BOLD);
wprintw(general_registers,": %06X ",simdata->registers->PC);
wattron(general_registers,A_BOLD);
wprintw(general_registers,"SP");
wattroff(general_registers,A_BOLD);
wprintw(general_registers,": %06X ",simdata->registers->SP);
wattron(general_registers,A_BOLD);
mvwprintw(general_registers,center_y_offset+lines_used+1+lines_for_special_registers,spec_reg_2_offset," ZERO");
wattroff(general_registers,A_BOLD);
wprintw(general_registers,": %c ",(simdata->registers->FLAGS&1)?'1':'0');
wattron(general_registers,A_BOLD);
wprintw(general_registers,"CARRY");
wattroff(general_registers,A_BOLD);
wprintw(general_registers,": %c ",(simdata->registers->FLAGS&2)?'1':'0');
wattron(general_registers,A_BOLD);
wprintw(general_registers,"SIGN");
wattroff(general_registers,A_BOLD);
wprintw(general_registers,": %c ",(simdata->registers->FLAGS&4)?'1':'0');
}
}
}
return 0;
}
int term_curs_x,term_curs_y;
wchar_t braille_lookup[256]={
L'⠀',L'⠁',L'⠂',L'⠃',L'⠄',L'⠅',L'⠆',L'⠇',L'⠈',L'⠉',L'⠊',L'⠋',L'⠌',L'⠍',L'⠎',L'⠏',L'⠐',L'⠑',L'⠒',L'⠓',L'⠔',L'⠕',L'⠖',L'⠗',L'⠘',L'⠙',L'⠚',L'⠛',L'⠜',L'⠝',L'⠞',L'⠟',
L'⠠',L'⠡',L'⠢',L'⠣',L'⠤',L'⠥',L'⠦',L'⠧',L'⠨',L'⠩',L'⠪',L'⠫',L'⠬',L'⠭',L'⠮',L'⠯',L'⠰',L'⠱',L'⠲',L'⠳',L'⠴',L'⠵',L'⠶',L'⠷',L'⠸',L'⠹',L'⠺',L'⠻',L'⠼',L'⠽',L'⠾',L'⠿',
L'⡀',L'⡁',L'⡂',L'⡃',L'⡄',L'⡅',L'⡆',L'⡇',L'⡈',L'⡉',L'⡊',L'⡋',L'⡌',L'⡍',L'⡎',L'⡏',L'⡐',L'⡑',L'⡒',L'⡓',L'⡔',L'⡕',L'⡖',L'⡗',L'⡘',L'⡙',L'⡚',L'⡛',L'⡜',L'⡝',L'⡞',L'⡟',L'⡠',L'⡡',L'⡢',L'⡣',L'⡤',L'⡥',L'⡦',L'⡧',L'⡨',L'⡩',L'⡪',L'⡫',L'⡬',L'⡭',L'⡮',L'⡯',L'⡰',L'⡱',L'⡲',L'⡳',L'⡴',L'⡵',L'⡶',L'⡷',L'⡸',L'⡹',L'⡺',L'⡻',L'⡼',L'⡽',L'⡾',L'⡿',
L'⢀',L'⢁',L'⢂',L'⢃',L'⢄',L'⢅',L'⢆',L'⢇',L'⢈',L'⢉',L'⢊',L'⢋',L'⢌',L'⢍',L'⢎',L'⢏',L'⢐',L'⢑',L'⢒',L'⢓',L'⢔',L'⢕',L'⢖',L'⢗',L'⢘',L'⢙',L'⢚',L'⢛',L'⢜',L'⢝',L'⢞',L'⢟',L'⢠',L'⢡',L'⢢',L'⢣',L'⢤',L'⢥',L'⢦',L'⢧',L'⢨',L'⢩',L'⢪',L'⢫',L'⢬',L'⢭',L'⢮',L'⢯',L'⢰',L'⢱',L'⢲',L'⢳',L'⢴',L'⢵',L'⢶',L'⢷',L'⢸',L'⢹',L'⢺',L'⢻',L'⢼',L'⢽',L'⢾',L'⢿',
L'⣀',L'⣁',L'⣂',L'⣃',L'⣄',L'⣅',L'⣆',L'⣇',L'⣈',L'⣉',L'⣊',L'⣋',L'⣌',L'⣍',L'⣎',L'⣏',L'⣐',L'⣑',L'⣒',L'⣓',L'⣔',L'⣕',L'⣖',L'⣗',L'⣘',L'⣙',L'⣚',L'⣛',L'⣜',L'⣝',L'⣞',L'⣟',L'⣠',L'⣡',L'⣢',L'⣣',L'⣤',L'⣥',L'⣦',L'⣧',L'⣨',L'⣩',L'⣪',L'⣫',L'⣬',L'⣭',L'⣮',L'⣯',L'⣰',L'⣱',L'⣲',L'⣳',L'⣴',L'⣵',L'⣶',L'⣷',L'⣸',L'⣹',L'⣺',L'⣻',L'⣼',L'⣽',L'⣾',L'⣿',
};
int print_braille_frame_buffer(WINDOW* win,uint8_t *buffer,int width,int height){
for(int h=0;hdy ? dx : -dy)/2, e2;
uint32_t addr;
for(;;){
addr=x0+y0*buffer_width;
if(addr>0&&addr<(uint64_t)(buffer_width*buffer_height)&&x00)
buffer[addr]=1;
if (x0==x1 && y0==y1) break;
e2 = err;
if (e2 >-dx) { err -= dy; x0 += sx; }
if (e2 < dy) { err += dx; y0 += sy; }
}
}
int update_general_terminal_output(struct simdata_t *simdata){
int width,height;
werase(general_terminal_output);
getmaxyx(general_terminal_output,height,width);
term_curs_x=0;
term_curs_y=0;
uint8_t* vector_working_frame_buffer=malloc((height*4)*(width*2));
uint8_t* vector_display_frame_buffer=malloc((height*4)*(width*2));
memset(vector_working_frame_buffer,0,(height*4)*(width*2));
memset(vector_display_frame_buffer,0,(height*4)*(width*2));
int vector=0;
int vstate=0;
int vfb_width=(width-2)*2;
int vfb_height=(height-2)*4;
float x0,y0,x1,y1;
for(uint64_t i=0;i < simdata->terminal_output_size/4;i++){
uint32_t c=simdata->terminal_output[i];
if(vector){
switch(vstate){
case 0: /*start of line*/
if(c==0x00000001)
vector=0;
else if(c==0x00000002)
memset(vector_working_frame_buffer,0,(height*4)*(width*2));
else if(c==0x00000003)
memcpy(vector_display_frame_buffer,vector_working_frame_buffer,(height*4)*(width*2));
else
vstate++;
break;
case 1: /*x of start*/
x0=uint32_to_ieee754_float(c);
vstate++;
break;
case 2: /*y of start*/
y0=uint32_to_ieee754_float(c);
vstate++;
break;
case 3: /*x of end*/
x1=uint32_to_ieee754_float(c);
vstate++;
break;
case 4: /*y of end*/
y1=uint32_to_ieee754_float(c);
float min_dim=(vfb_width>vfb_height)?vfb_height:vfb_width;
int xoff=0,yoff=0;
x0*=1.25;
x1*=1.25;
if(vfb_width>vfb_height)
xoff=(vfb_width-vfb_height)/2;
else
yoff=(vfb_height-vfb_width)/2;
braille_frame_buffer_line(vector_working_frame_buffer,vfb_width,vfb_height,xoff+(x0+1)*(min_dim/2),yoff+(y0+1)*(min_dim/2),xoff+(x1+1)*(min_dim/2),yoff+(y1+1)*(min_dim/2));
vstate=0;
break;
}
}else{
if(c>=' '&&c<='~'){
mvwprintw(general_terminal_output,term_curs_y+1,term_curs_x+1,"%c",c);
term_curs_x++;
if(term_curs_x>=width-2){
term_curs_x=0;
term_curs_y++;
}
if(term_curs_y>=height-2){
wscrl(general_terminal_output,1);
term_curs_y--;
for(int i=0;i=height-2){
wscrl(general_terminal_output,1);
term_curs_y--;
box(general_terminal_output, 0 , 0);
mvwprintw(general_terminal_output,0,width/2-7,"[ TERM OUTPUT ]");
}
break;
default:
werase(general_terminal_output);
box(general_terminal_output, 0 , 0);
mvwprintw(general_terminal_output,0,width/2-7,"[ TERM OUTPUT ]");
mvwprintw(general_terminal_output,1,1,"Invalid output");
return 0;
}
}
}
}
box(general_terminal_output, 0 , 0);
if(!vector){
mvwchgat(general_terminal_output,term_curs_y+1,term_curs_x+1, 1, A_REVERSE, 0, NULL);
mvwprintw(general_terminal_output,0,width/2-7,"[ TERM OUTPUT ]");
}else{
print_braille_frame_buffer(general_terminal_output,vector_display_frame_buffer,(width-2)*2,(height-2)*4);
mvwprintw(general_terminal_output,0,width/2-9,"[ VECTOR DISPLAY ]");
}
free(vector_working_frame_buffer);
free(vector_display_frame_buffer);
return 0;
}
int update_debug_simdata(struct simdata_t *simdata){
int width,height;
werase(debug_simdata);
getmaxyx(debug_simdata,height,width);
box(debug_simdata, 0 , 0);
mvwprintw(debug_simdata,0,width/2-5,"[ SIMDATA ]");
if(simdata->registers==NULL){
mvwprintw(debug_simdata,1,1,"Data not initialised");
return 0;
}
int term_size;
char* term_size_unit;
if(simdata->terminal_output_size<(1024))
term_size=simdata->terminal_output_size,term_size_unit="Bytes";
else if(simdata->terminal_output_size<(1024*1024))
term_size=simdata->terminal_output_size/1024,term_size_unit="KiB";
else if(simdata->terminal_output_size<(1024*1024*1024))
term_size=simdata->terminal_output_size/(1024*1024),term_size_unit="MiB";
else
term_size=simdata->terminal_output_size/(1024*1024*1024),term_size_unit="GiB";
mvwprintw(debug_simdata,1,1,"simdata->terminal_output_size: ");
if(simdata->terminal_output_size<100*1024)
wattron(debug_simdata,COLOR_PAIR(11));
else if (simdata->terminal_output_size<500*1024)
wattron(debug_simdata,COLOR_PAIR(10));
else
wattron(debug_simdata,COLOR_PAIR(15));
wprintw(debug_simdata,"%d%s",term_size,term_size_unit);
if(simdata->terminal_output_size<100*1024)
wattroff(debug_simdata,COLOR_PAIR(11));
else if (simdata->terminal_output_size<500*1024)
wattroff(debug_simdata,COLOR_PAIR(10));
else
wattroff(debug_simdata,COLOR_PAIR(15));
if(height==3)
return 0;
else
return 0;
}
int update_pipeline(WINDOW *win,struct simdata_t *simdata){
int width,height;
werase(win);
getmaxyx(win,height,width);
box(win, 0 , 0);
mvwprintw(win,0,width/2-6,"[ PIPELINE ]");
if(simdata->registers==NULL||simdata->exec_data==NULL){
mvwprintw(win,1,1,"Data not initialised");
return 0;
}
wattron(win,A_BOLD);
mvwprintw(win,1,1,"-------------- fetch --------------");
wattroff(win,A_BOLD);
mvwprintw(win,2,1," wait_for_exec=%d",simdata->fetch_data->wait_for_exec);
wattron(win,A_BOLD);
mvwprintw(win,5,1,"-------------- decode -------------");
wattroff(win,A_BOLD);
mvwprintw(win,6,1," valid=%d in_bytecode=%08X address=%06X",simdata->decode_data->valid,simdata->decode_data->in_bytecode,simdata->decode_data->address);
wattron(win,A_BOLD);
mvwprintw(win,9,1,"-------------- execute -------------");
wattroff(win,A_BOLD);
char *tofree;
mvwprintw(win,10,1," valid=%d EXEC_ACTION=%s",simdata->exec_data->valid, (tofree=EXEC_ACTION_t_to_string(simdata->exec_data->EXEC_ACTION)) );
free(tofree);
mvwprintw(win,10,35,"ALU_OP=%s", (tofree=ALU_OP_t_to_string(simdata->exec_data->ALU_OP)) );
free(tofree);
mvwprintw(win,10,52,"COND=%s", (tofree=COND_t_to_string(simdata->exec_data->COND)) );
free(tofree);
mvwprintw(win,10,70,"address=%06X", simdata->exec_data->address);
int y=12;
struct exec_op_t *cur;
for(int i=0;i<3;i++){
mvwprintw(win,y,2,"------ [ %s ] -----",i==0?"OPERAND 1":(1==1?"OPERAND 2":"OUTPUT OPERAND"));
y++;
switch(i){
case 0:cur=simdata->exec_data->in_op1;break;
case 1:cur=simdata->exec_data->in_op2;break;
case 2:cur=simdata->exec_data->out_op;break;
}
mvwprintw(win,y,2,"OP_ADDR=%s", (tofree=OP_ADDR_t_to_string(cur->OP_ADDR)) );
free(tofree);
mvwprintw(win,y,24,"data=%06X", cur->data );
y+=2;
}
if(height==3)
return 0;
else
return 0;
}
int clear_back_window=1;
int update_gui(struct simdata_t *simdata){
if(simdata->cpu_state==CPU_HALTED)
GUI_CPU_STATE=GUI_CPU_STOPPED;
if(clear_back_window){
clear();
clear_back_window=0;
}
if((simdata->current_clock)%(gui_settings->cycles_per_frame)==0 || GUI_CPU_STATE!=GUI_CPU_RUNNING ){
update_tabs();
if(CURRENT_TAB==1){
if(update_general_memdump(simdata))
return 1;
if(update_general_stack(simdata))
return 1;
if(update_disas(general_disas,simdata))
return 1;
if(update_general_registers(simdata))
return 1;
if(update_general_terminal_output(simdata))
return 1;
}else if(CURRENT_TAB==2){
if(update_memory_memdump(simdata))
return 1;
}else if(CURRENT_TAB==3){
if(update_disas(pipeline_disas,simdata))
return 1;
if(update_pipeline(pipeline_pipeline,simdata))
return 1;
}else if(CURRENT_TAB==4){
if(update_debug_simdata(simdata))
return 1;
}
}
if(gui_ncurses_refresh())
return 1;
return 0;
}
int gui_continue_request(struct simdata_t *simdata){
int inch;
int release=0;
while(release==0){
if(((inch=getch())==ERR)){
if(GUI_CPU_STATE==GUI_CPU_SINGLE_STEPPING)
return 1;
else
release=1;
}
switch(inch){
case 'r':
if(simdata->cpu_state!=CPU_HALTED){
if(GUI_CPU_STATE==GUI_CPU_RUNNING){
GUI_CPU_STATE=GUI_CPU_SINGLE_STEPPING;
update_gui(simdata);
nodelay(stdscr, FALSE);
}else{
GUI_CPU_STATE=GUI_CPU_RUNNING;
nodelay(stdscr, TRUE);
}
}
break;
case 'q':
return 2;
case '\n':
release=1;
break;
case '1':
if(CURRENT_TAB!=1){
CURRENT_TAB=1;
clear();
update_gui(simdata);
}
break;
case '2':
if(CURRENT_TAB!=2){
CURRENT_TAB=2;
clear();
update_gui(simdata);
}
break;
case '3':
if(CURRENT_TAB!=3){
CURRENT_TAB=3;
clear();
update_gui(simdata);
}
break;
case '4':
if(CURRENT_TAB!=4){
CURRENT_TAB=4;
clear();
update_gui(simdata);
}
break;
case 'j':
if(CURRENT_TAB==2){
memory_window_address++;
if(memory_window_address==0x01000000)
memory_window_address=0x00000000;
update_gui(simdata);
}
break;
case 'k':
if(CURRENT_TAB==2){
memory_window_address--;
if(memory_window_address==0xFFFFFFFF)
memory_window_address=0x00FFFFFF;
update_gui(simdata);
}
break;
default:
break;
}
}
return 0;
}
int clean_cpu_output(struct simdata_t *simdata){
uint32_t last_vect_disp=0;
uint32_t second_last_vect_disp=simdata->terminal_output_size/4;//TODO: I shouldn't have to initialise this. GCC gives a warning erroneously
int vector=0;
int vstate=0;
uint32_t disps_found=0;
if(!simdata)
return 0;
for(uint64_t i=0;i < simdata->terminal_output_size/4;i++){
uint32_t c=simdata->terminal_output[i];
if(vector){
switch(vstate){
case 0: /*start of line*/
if(c==0x00000001)
vector=0;
else if(c==0x00000003){
second_last_vect_disp=last_vect_disp;
last_vect_disp=i*4;
disps_found++;
}else
vstate++;
break;
case 1:
case 2:
case 3:
vstate++;
break;
case 4:
vstate=0;
break;
}
}else{
switch(c){
case 0xffffffff:
vector=1;
break;
}
}
}
if(disps_found>=2){
int final_data_size=simdata->terminal_output_size-(second_last_vect_disp+4);
memmove((uint8_t*)simdata->terminal_output+4,(uint8_t*)simdata->terminal_output+simdata->terminal_output_size-final_data_size,final_data_size);
simdata->terminal_output[0]=0xFFFFFFFF;
simdata->terminal_output=realloc(simdata->terminal_output,final_data_size+4);
simdata->terminal_output_size=final_data_size+4;
}
return 0;
}
int end_gui(){
if(endwin()==ERR)
return 1;
return 0;
}