erc-c/src/apple2.draw.c

/*
 * apple2.draw.c
 */

#include "apple2.h"

static int lores_colors[][3] = {
    { 0x00, 0x00, 0x00 },   // black
    { 0xff, 0x28, 0x97 },   // magenta
    { 0x60, 0x4d, 0xbc },   // dark blue
    { 0xff, 0x44, 0xfd },   // purple
    { 0x00, 0xa3, 0x60 },   // dark green
    { 0x9c, 0x9c, 0x9c },   // gray
    { 0x14, 0xcf, 0xfd },   // medium blue
    { 0xd0, 0xc3, 0xff },   // light blue
    { 0x60, 0x72, 0x03 },   // brown
    { 0xff, 0x6a, 0x3c },   // orange
    { 0x9c, 0x9c, 0x9c },   // gray
    { 0xff, 0xa0, 0xd0 },   // pink
    { 0x14, 0xf5, 0x3c },   // light green
    { 0xd0, 0xdd, 0x81 },   // yellow
    { 0x72, 0xff, 0xd0 },   // aquamarine
    { 0xff, 0xff, 0xff },   // white
};

void
apple2_draw_pixel(apple2 *mach, vm_16bit addr)
{
}

/*
 * In single lo-res mode, pixels are 40x40 on the screen. But since our
 * single mode has 280 pixels that _we_ show, this means that a pixel in
 * single lo-res is really 7 columns wide. (Confusing yet?) Each "row" in
 * text page 1 is just a row of visible dots, and 4 rows are equivalent
 * to one "pixel" in lo-res mode.
 *
 * Without text, you get 40x48 pixels.
 */
void
apple2_draw_pixel_lores(apple2 *mach, vm_16bit addr)
{
    vm_8bit color = vm_segment_get(mach->memory, addr);
    vm_8bit top, bottom;
    SDL_Rect loc;
    int *colors;

    // The top color is the low order nibble, so we can blank out the
    // high order nibble by AND-ing a mask of 0x0f (which is b00001111,
    // 15 decimal). The bottom color, ergo, is the high order nibble;
    // for that, we simply shift the color 4 positions to the right.
    top = color & 0x0F;
    bottom = color >> 4;

    // The next thing we need to consider is where we draw the pixel
    loc.x = (addr & 0xff) * mach->sysfont->width;
    loc.y = (addr >> 8) * mach->sysfont->height;
    loc.w = mach->sysfont->width;
    loc.h = mach->sysfont->height / 2;

    colors = lores_colors[top];
    vm_screen_set_color(mach->screen, colors[0], colors[1], colors[2], 255);
    vm_screen_draw_rect(mach->screen, loc.x, loc.y, loc.w, loc.h); 

    colors = lores_colors[bottom];
    vm_screen_set_color(mach->screen, colors[0], colors[1], colors[2], 255);
    vm_screen_draw_rect(mach->screen, loc.x, loc.y + loc.h, loc.w, loc.h);
}

void
apple2_draw_text(apple2 *mach, vm_16bit addr)
{
    vm_8bit lsb, msb;
    vm_16bit page_base;
    vm_area dest;
    char ch;

    // The text display buffers are located at "Page 1" and "Page 2",
    // which are at byte 1024-2047 (0x0400-0x07FF) and byte 2048-3071
    // (0x0800-0x0BFF) respectively. If the given address is not in
    // those (contiguous) ranges, then let's bail.
    if (addr < 0x0400 || addr > 0x0BFF) {
        return;
    }

    // If we're updating a page 2 address and we're not in some kind of
    // double resolution mode, then we shouldn't actually render the
    // thing.
    if (addr > 0x07FF && !apple2_is_double_video(mach)) {
        return;
    }

    // In a given page for 40-column mode, you get 960 grid parts that
    // you may use. In 80-column mode, it's more like 1920 grid parts
    // (40x24 = 960, 80x24 = 1920). The way we look at this is the
    // address indicates the place on the grid where text should go. We
    // don't care how it got there. Let's figure out that position
    // on-screen.
    msb = (addr >> 8) & 0xff;   // row
    lsb = addr & 0xff;          // column

    // Regardless of which page we're rendering into, we can only use 40
    // cells on the grid (that is, 0-39 from whatever value the msb is).
    // It's possible to have an lsb greater than that, but if so, it's
    // not anything we can render to the screen.
    if (lsb > 39) {
        return;
    }

    if ((addr & 0xff80) % 128 != 0) {
        return;
    }

    // By default, we assume we're in text page 1. If the address ends
    // up being greater than 0x07FF, then we must be in page 2.
    page_base = 0x0400;
    if (addr > 0x07FF) {
        page_base = 0x0800;
    }

    // The absolute column position will be the font width times the
    // lsb.
    dest.xoff = lsb * mach->sysfont->width;

    // The absolute row position will be the font height times the msb
    // minus the page base (because the height is the same regardless of
    // what page we're in). So if we're msb $0400, then we're starting
    // on pixel row 0; but if we're msb $0480, then we are starting on
    // pixel row 8 (where the font height is 8); etc.
    dest.yoff = ((addr & 0xff80) - page_base) * mach->sysfont->height;

    // Our width and height must be that of the font.
    dest.width = mach->sysfont->width;
    dest.height = mach->sysfont->height;

    // And...lastly...what's in the address?
    ch = (char)vm_segment_get(mach->memory, addr);

    // Let's firstly blank out that space on screen.
    vm_bitfont_render(mach->sysfont, mach->screen, &dest, ' ');

    // Now show the goddamned thing
    vm_bitfont_render(mach->sysfont, mach->screen, &dest, ch);
}
Add the bones of the draw functions and file 2017-12-21 03:33:15 +00:00			`/*`
			`* apple2.draw.c`
			`*/`

Implement draw text functionality 2017-12-22 21:48:48 +00:00			`#include "apple2.h"`

Beginnings of lo-res graphics 2017-12-24 21:07:24 +00:00			`static int lores_colors[][3] = {`
			`{ 0x00, 0x00, 0x00 }, // black`
			`{ 0xff, 0x28, 0x97 }, // magenta`
			`{ 0x60, 0x4d, 0xbc }, // dark blue`
			`{ 0xff, 0x44, 0xfd }, // purple`
			`{ 0x00, 0xa3, 0x60 }, // dark green`
			`{ 0x9c, 0x9c, 0x9c }, // gray`
			`{ 0x14, 0xcf, 0xfd }, // medium blue`
			`{ 0xd0, 0xc3, 0xff }, // light blue`
			`{ 0x60, 0x72, 0x03 }, // brown`
			`{ 0xff, 0x6a, 0x3c }, // orange`
			`{ 0x9c, 0x9c, 0x9c }, // gray`
			`{ 0xff, 0xa0, 0xd0 }, // pink`
			`{ 0x14, 0xf5, 0x3c }, // light green`
			`{ 0xd0, 0xdd, 0x81 }, // yellow`
			`{ 0x72, 0xff, 0xd0 }, // aquamarine`
			`{ 0xff, 0xff, 0xff }, // white`
			`};`

Add the bones of the draw functions and file 2017-12-21 03:33:15 +00:00			`void`
			`apple2_draw_pixel(apple2 *mach, vm_16bit addr)`
			`{`
			`}`

Beginnings of lo-res graphics 2017-12-24 21:07:24 +00:00			`/*`
			`* In single lo-res mode, pixels are 40x40 on the screen. But since our`
			`* single mode has 280 pixels that _we_ show, this means that a pixel in`
			`* single lo-res is really 7 columns wide. (Confusing yet?) Each "row" in`
			`* text page 1 is just a row of visible dots, and 4 rows are equivalent`
			`* to one "pixel" in lo-res mode.`
			`*`
			`* Without text, you get 40x48 pixels.`
			`*/`
			`void`
			`apple2_draw_pixel_lores(apple2 *mach, vm_16bit addr)`
			`{`
			`vm_8bit color = vm_segment_get(mach->memory, addr);`
			`vm_8bit top, bottom;`
			`SDL_Rect loc;`
			`int *colors;`

			`// The top color is the low order nibble, so we can blank out the`
			`// high order nibble by AND-ing a mask of 0x0f (which is b00001111,`
			`// 15 decimal). The bottom color, ergo, is the high order nibble;`
			`// for that, we simply shift the color 4 positions to the right.`
			`top = color & 0x0F;`
			`bottom = color >> 4;`

			`// The next thing we need to consider is where we draw the pixel`
			`loc.x = (addr & 0xff) * mach->sysfont->width;`
			`loc.y = (addr >> 8) * mach->sysfont->height;`
			`loc.w = mach->sysfont->width;`
			`loc.h = mach->sysfont->height / 2;`

			`colors = lores_colors[top];`
			`vm_screen_set_color(mach->screen, colors[0], colors[1], colors[2], 255);`
			`vm_screen_draw_rect(mach->screen, loc.x, loc.y, loc.w, loc.h);`

			`colors = lores_colors[bottom];`
			`vm_screen_set_color(mach->screen, colors[0], colors[1], colors[2], 255);`
			`vm_screen_draw_rect(mach->screen, loc.x, loc.y + loc.h, loc.w, loc.h);`
			`}`

Add the bones of the draw functions and file 2017-12-21 03:33:15 +00:00			`void`
			`apple2_draw_text(apple2 *mach, vm_16bit addr)`
			`{`
Implement draw text functionality 2017-12-22 21:48:48 +00:00			`vm_8bit lsb, msb;`
			`vm_16bit page_base;`
Switch references from SDL_Rect to vm_area We still use SDL_Rect internally, but we want to abstract the use of it in our API. The only thing the rest of the app should care about is the vm_area struct. 2017-12-27 22:31:02 +00:00			`vm_area dest;`
Implement draw text functionality 2017-12-22 21:48:48 +00:00			`char ch;`

			`// The text display buffers are located at "Page 1" and "Page 2",`
			`// which are at byte 1024-2047 (0x0400-0x07FF) and byte 2048-3071`
			`// (0x0800-0x0BFF) respectively. If the given address is not in`
			`// those (contiguous) ranges, then let's bail.`
			`if (addr < 0x0400 \|\| addr > 0x0BFF) {`
			`return;`
			`}`

Beginnings of lo-res graphics 2017-12-24 21:07:24 +00:00			`// If we're updating a page 2 address and we're not in some kind of`
			`// double resolution mode, then we shouldn't actually render the`
			`// thing.`
			`if (addr > 0x07FF && !apple2_is_double_video(mach)) {`
			`return;`
			`}`

Implement draw text functionality 2017-12-22 21:48:48 +00:00			`// In a given page for 40-column mode, you get 960 grid parts that`
			`// you may use. In 80-column mode, it's more like 1920 grid parts`
			`// (40x24 = 960, 80x24 = 1920). The way we look at this is the`
			`// address indicates the place on the grid where text should go. We`
			`// don't care how it got there. Let's figure out that position`
			`// on-screen.`
			`msb = (addr >> 8) & 0xff; // row`
			`lsb = addr & 0xff; // column`

			`// Regardless of which page we're rendering into, we can only use 40`
			`// cells on the grid (that is, 0-39 from whatever value the msb is).`
			`// It's possible to have an lsb greater than that, but if so, it's`
			`// not anything we can render to the screen.`
			`if (lsb > 39) {`
			`return;`
			`}`

			`if ((addr & 0xff80) % 128 != 0) {`
			`return;`
			`}`

			`// By default, we assume we're in text page 1. If the address ends`
			`// up being greater than 0x07FF, then we must be in page 2.`
			`page_base = 0x0400;`
			`if (addr > 0x07FF) {`
			`page_base = 0x0800;`
			`}`

			`// The absolute column position will be the font width times the`
			`// lsb.`
Switch references from SDL_Rect to vm_area We still use SDL_Rect internally, but we want to abstract the use of it in our API. The only thing the rest of the app should care about is the vm_area struct. 2017-12-27 22:31:02 +00:00			`dest.xoff = lsb * mach->sysfont->width;`
Implement draw text functionality 2017-12-22 21:48:48 +00:00
			`// The absolute row position will be the font height times the msb`
			`// minus the page base (because the height is the same regardless of`
			`// what page we're in). So if we're msb $0400, then we're starting`
			`// on pixel row 0; but if we're msb $0480, then we are starting on`
			`// pixel row 8 (where the font height is 8); etc.`
Switch references from SDL_Rect to vm_area We still use SDL_Rect internally, but we want to abstract the use of it in our API. The only thing the rest of the app should care about is the vm_area struct. 2017-12-27 22:31:02 +00:00			`dest.yoff = ((addr & 0xff80) - page_base) * mach->sysfont->height;`
Implement draw text functionality 2017-12-22 21:48:48 +00:00
			`// Our width and height must be that of the font.`
Switch references from SDL_Rect to vm_area We still use SDL_Rect internally, but we want to abstract the use of it in our API. The only thing the rest of the app should care about is the vm_area struct. 2017-12-27 22:31:02 +00:00			`dest.width = mach->sysfont->width;`
			`dest.height = mach->sysfont->height;`
Implement draw text functionality 2017-12-22 21:48:48 +00:00
			`// And...lastly...what's in the address?`
			`ch = (char)vm_segment_get(mach->memory, addr);`

			`// Let's firstly blank out that space on screen.`
Blank out the space we want to render a character 2017-12-22 23:49:36 +00:00			`vm_bitfont_render(mach->sysfont, mach->screen, &dest, ' ');`
Implement draw text functionality 2017-12-22 21:48:48 +00:00
			`// Now show the goddamned thing`
			`vm_bitfont_render(mach->sysfont, mach->screen, &dest, ch);`
Add the bones of the draw functions and file 2017-12-21 03:33:15 +00:00			`}`