apple2a/main.c

#include <string.h>

#include "exporter.h"
#include "platform.h"
#include "runtime.h"

uint8_t *title = "Apple IIa";
uint8_t title_length = 9;

// 6502 instructions.
#define I_CLC 0x18
#define I_JSR 0x20
#define I_SEC 0x38
#define I_RTS 0x60
#define I_STA_ZPG 0x85
#define I_STX_ZPG 0x86
#define I_STA_IND_Y 0x91
#define I_LDY_IMM 0xA0
#define I_LDX 0xA2
#define I_LDA 0xA9

// Tokens.
#define T_HOME 0x80
#define T_PRINT 0x81
#define T_LIST 0x82
#define T_POKE 0x83
#define T_RUN 0x84

// Line number used for "no line number".
#define INVALID_LINE_NUMBER 0xFFFF

// List of tokens. The token value is the index plus 0x80.
static uint8_t *TOKEN[] = {
    "HOME",
    "PRINT",
    "LIST",
    "POKE",
    "RUN",
};
static int16_t TOKEN_COUNT = sizeof(TOKEN)/sizeof(TOKEN[0]);

uint8_t g_input_buffer[40];
int16_t g_input_buffer_length = 0;

// Compiled binary.
uint8_t g_compiled[1024];
int16_t g_compiled_length = 0;
void (*g_compiled_function)() = (void (*)()) g_compiled;

// Stored program. Each line is:
// - Two bytes for pointer to next line (or zero if none).
// - Two bytes for line number.
// - Program line.
// - Nul.
uint8_t g_program[1024];

/**
 * Print the tokenized string, with tokens displayed as their full text.
 * Prints a newline at the end.
 */
static void print_detokenized(uint8_t *s) {
    while (*s != '\0') {
        if (*s >= 0x80) {
            print_char(' ');
            print(TOKEN[*s - 0x80]);
            print_char(' ');
        } else {
            print_char(*s);
        }

        s += 1;
    }

    print_char('\n');
}

/**
 * Get the pointer to the next line in the stored program. Returns 0
 * if we're at the end.
 */
static uint8_t *get_next_line(uint8_t *line) {
    return *((uint8_t **) line);
}

/**
 * Get the line number of a stored program line.
 */
static uint16_t get_line_number(uint8_t *line) {
    return *((uint16_t *) (line + 2));
}

/**
 * Return a pointer to the end of the program. This is one byte PAST the
 * last bytes in the program, which are two nuls. The "line" parameter is
 * an optional starting point, to use as an optimization instead of starting
 * from the beginning.
 */
static uint8_t *get_end_of_program(uint8_t *line) {
    uint8_t *next_line;

    if (line == 0) {
        // Start at the beginning if not specified.
        line = g_program;
    }

    while ((next_line = get_next_line(line)) != 0) {
        line = next_line;
    }

    // Skip the null "next" pointer.
    return line + 2;
}

/**
 * List the stored program.
 */
static void list_statement() {
    uint8_t *line = g_program;
    uint8_t *next_line;

    print_newline();

    while ((next_line = get_next_line(line)) != 0) {
        print_int(get_line_number(line));
        print_char(' ');
        print_detokenized(line + 4);

        line = next_line;
    }
}

/**
 * If a starts with string b, returns the position in a after b. Else returns null.
 */
static uint8_t *skip_over(uint8_t *a, uint8_t *b) {
    while (*a != '\0' && *b != '\0') {
        if (*a != *b) {
            // Doesn't start with b.
            return 0;
        }

        a += 1;
        b += 1;
    }

    // See if we're at the end of b.
    return *b == '\0' ? a : 0;
}

/**
 * Add a function call to the compiled buffer.
 */
static void add_call(void *function) {
    uint16_t addr = (int16_t) function;

    g_compiled[g_compiled_length++] = I_JSR;
    g_compiled[g_compiled_length++] = addr & 0xFF;
    g_compiled[g_compiled_length++] = addr >> 8;
}

/**
 * Add a function return to the compiled buffer.
 */
static void add_return() {
    g_compiled[g_compiled_length++] = I_RTS;
}

/**
 * Parse an unsigned integer, returning the value and moving the pointer
 * past the end of the number. The pointer must already be at the beginning
 * of the number.
 */
static uint16_t parse_uint16(uint8_t **s_ptr) {
    uint16_t value = 0;
    uint8_t *s = *s_ptr;

    while (*s >= '0' && *s <= '9') {
        value = value*10 + (*s - '0');
        s += 1;
    }

    *s_ptr = s;

    return value;
}

/**
 * Parse an expression, generating code to compute it, leaving the
 * result in AX.
 */
static uint8_t *compile_expression(uint8_t *s) {
    int plus_count = 0;
    char have_value_in_ax = 0;

    while (1) {
        if (*s >= '0' && *s <= '9') {
            // Parse number.
            uint16_t value;

            if (have_value_in_ax) {
                // Push on the number stack.
                add_call(pushax);
            }

            value = parse_uint16(&s);
            g_compiled[g_compiled_length++] = I_LDX;
            g_compiled[g_compiled_length++] = value >> 8;
            g_compiled[g_compiled_length++] = I_LDA;
            g_compiled[g_compiled_length++] = value & 0xFF;
            have_value_in_ax = 1;
        } else if (*s == '+') {
            plus_count += 1;
            s += 1;
        } else {
            break;
        }
    }

    while (plus_count > 0) {
        add_call(tosaddax);
        plus_count -= 1;
    }

    return s;
}

/**
 * Tokenize a string in place. Returns (and removes) any line number, or
 * INVALID_LINE_NUMBER if there's none.
 */
static uint16_t tokenize(uint8_t *s) {
    uint8_t *t = s; // Tokenized version.
    int16_t line_number;

    // Parse optional line number.
    if (*s >= '0' && *s <= '9') {
        line_number = parse_uint16(&s);
    } else {
        line_number = INVALID_LINE_NUMBER;
    }

    // Convert tokens.
    while (*s != '\0') {
        if (*s == ' ') {
            // Skip spaces.
            s++;
        } else {
            int16_t i;
            uint8_t *skipped = 0;

            for (i = 0; i < TOKEN_COUNT; i++) {
                skipped = skip_over(s, TOKEN[i]);
                if (skipped != 0) {
                    // Record token.
                    *t++ = 0x80 + i;
                    s = skipped;
                    break;
                }
            }

            if (skipped == 0) {
                // Didn't find a token, just copy text.
                *t++ = *s++;
            }
        }
    }

    // Terminate string.
    *t++ = '\0';

    return line_number;
}

/**
 * Find the stored program line with the given line number. If the line does
 * not exist, returns a pointer to the location where it should be inserted.
 */
static uint8_t *find_line(uint16_t line_number) {
    uint8_t *line = g_program;
    uint8_t *next_line;

    while ((next_line = get_next_line(line)) != 0) {
        // See if we hit it or just blew past it.
        if (get_line_number(line) >= line_number) {
            break;
        }

        line = next_line;
    }

    return line;
}

/**
 * Call to configure the compilation step.
 */
static void set_up_compile(void) {
    g_compiled_length = 0;
}

/**
 * Compile the tokenized line of BASIC, adding it to the g_compiled binary.
 */
static void compile_buffer(uint8_t *buffer) {
    uint8_t *s = buffer;
    uint8_t done;

    do {
        int8_t error = 0;

        // Default to being done after one statement.
        done = 1;

        if (*s == '\0' || *s == ':') {
            // Empty statement. We skip the colon below.
        } else if (*s == T_HOME) {
            s += 1;
            add_call(home);
        } else if (*s == T_PRINT) {
            s += 1;

            if (*s >= '0' && *s <= '9') { // TODO: Add negative sign and open parenthesis.
                // Parse expression.
                s = compile_expression(s);
                add_call(print_int);
            }

            add_call(print_newline);
        } else if (*s == T_LIST) {
            s += 1;
            add_call(list_statement);
        } else if (*s == T_POKE) {
            s += 1;
            // Parse address.
            s = compile_expression(s);
            // Copy from AX to ptr1.
            g_compiled[g_compiled_length++] = I_STA_ZPG;
            g_compiled[g_compiled_length++] = (uint8_t) &ptr1;
            g_compiled[g_compiled_length++] = I_STX_ZPG;
            g_compiled[g_compiled_length++] = (uint8_t) &ptr1 + 1;
            if (*s == ',') {
                s++;
            }
            // Parse value. LSB is in A.
            s = compile_expression(s);
            g_compiled[g_compiled_length++] = I_LDY_IMM;
            g_compiled[g_compiled_length++] = 0;
            g_compiled[g_compiled_length++] = I_STA_IND_Y;
            g_compiled[g_compiled_length++] = (uint8_t) &ptr1;
        } else {
            error = 1;
        }

        // Now we're at the end of our statement.
        if (!error) {
            if (*s == ':') {
                // Skip colon.
                s += 1;

                // Next statement.
                done = 0;
            } else if (*s != '\0') {
                // Junk at the end of the statement.
                error = 1;
            }
        }

        if (error) {
            add_call(syntax_error);
        }
    } while (!done);
}

/**
 * Complete the compilation buffer and run it.
 */
static void complete_compile_and_execute(void) {
    // Return from function.
    add_return();

    // Dump compiled buffer to the terminal.
    {
        int i;
        uint8_t *debug_port = (uint8_t *) 0xBFFE;

        debug_port[0] = g_compiled_length;
        for (i = 0; i < g_compiled_length; i++) {
            debug_port[1] = g_compiled[i];
        }
    }

    if (g_compiled_length > sizeof(g_compiled)) {
        // TODO: Check while adding bytes, not at the end.
        print("\n?Binary length exceeded");
    } else {
        // Call it.
        g_compiled_function();
    }
}

/**
 * Compile the stored program and execute it.
 */
static void compile_stored_program(void) {
    uint8_t *line = g_program;
    uint8_t *next_line;

    while ((next_line = get_next_line(line)) != 0) {
        uint16_t line_number = get_line_number(line);
        compile_buffer(line + 4);

        line = next_line;
    }
}

/**
 * Process the user's line of input, possibly compiling the code.
 * and executing it.
 */
static void process_input_buffer() {
    uint16_t line_number;

    g_input_buffer[g_input_buffer_length] = '\0';

    // Tokenize in-place.
    line_number = tokenize(g_input_buffer);
    if (line_number == INVALID_LINE_NUMBER) {
        // Immediate mode.

        set_up_compile();
        // See if it's the "RUN" command, which we don't compile.
        if (g_input_buffer[0] == T_RUN) {
            compile_stored_program();
        } else {
            // Compile the immediate mode line.
            compile_buffer(g_input_buffer);
        }
        complete_compile_and_execute();
    } else {
        // Stored mode. Add line to program.

        // Return line to replace or delete, or location to insert new line.
        uint8_t *line = find_line(line_number);
        uint8_t *next_line = get_next_line(line);
        uint8_t *end_of_program = get_end_of_program(line);
        int16_t adjustment = 0;

        if (next_line == 0 || get_line_number(line) != line_number) {
            // Didn't find line. Insert it here.

            // Next pointer, line number, line, and nul.
            uint8_t buffer_length = strlen(g_input_buffer);
            adjustment = 4 + buffer_length + 1;

            // Shift rest of program over.
            memmove(line + adjustment, line, end_of_program - line);

            // Next line. Point to yourself initially, we'll adjust below.
            *((uint8_t **) line) = line;

            // Line number.
            *((uint16_t *) (line + 2)) = line_number;

            // Buffer and nul.
            memmove(line + 4, g_input_buffer, buffer_length + 1);
        } else {
            // Found line.

            if (g_input_buffer[0] == '\0') {
                // Empty line, delete old one.

                // Adjustment is negative.
                adjustment = line - next_line;
                memmove(line, next_line, end_of_program - next_line);
            } else {
                // Replace line.

                // Compute adjustment.
                uint8_t buffer_length = strlen(g_input_buffer);
                adjustment = line - next_line + 4 + buffer_length + 1;
                memmove(next_line + adjustment, next_line, end_of_program - next_line);

                // Buffer and nul.
                memmove(line + 4, g_input_buffer, buffer_length + 1);
            }
        }

        if (adjustment != 0) {
            // Adjust all the next pointers.
            while ((next_line = get_next_line(line)) != 0) {
                // Adjust by the amount we inserted or deleted.
                next_line += adjustment;

                *((uint8_t **) line) = next_line;
                line = next_line;
            }
        }
    }
}

int16_t main(void)
{
    int16_t blink;

    /*
    int16_t i, j, k;

    i = 2;
    j = 3;
    k = 4;
    i = i*j;
    */

    // Blank program.
    g_program[0] = '\0';
    g_program[1] = '\0';

    // Initialize UI.
    home();

    // Display the character set.
    /*
    if (1) {
        int16_t i;
        for (i = 0; i < 256; i++) {
            uint8_t *loc;
            // Fails with: unhandled instruction B2
            move_cursor(i % 16, i >> 4);
            // Works.
            // move_cursor(i & 0x0F, i >> 4);
            loc = cursor_pos();
            *loc = i;
        }
        while(1);
    }
    */

    // Print title.
    move_cursor((40 - title_length) / 2, 0);
    print(title);

    // Prompt.
    print("\n\n]");
    // TODO crashes 6502. Delete:
    // asm("ldy #1");
    // asm("sta $FFFF,y");

    // Keyboard input.
    blink = 0;
    g_input_buffer_length = 0;
    show_cursor();
    while(1) {
        // Blink cursor.
        blink += 1;
        if (blink == 3000) {
            if (g_showing_cursor) {
                hide_cursor();
            } else {
                show_cursor();
            }
            blink = 0;
        }

        if(keyboard_test()) {
            hide_cursor();

            while(keyboard_test()) {
                uint8_t key;

                key = keyboard_get();
                if (key == 8) {
                    // Backspace.
                    if (g_input_buffer_length > 0) {
                        move_cursor(g_cursor_x - 1, g_cursor_y);
                        g_input_buffer_length -= 1;
                    }
                } else if (key == 13) {
                    // Return.
                    clear_to_eol();
                    print_char('\n');

                    process_input_buffer();

                    print("\n]");
                    g_input_buffer_length = 0;
                } else {
                    if (g_input_buffer_length < sizeof(g_input_buffer) - 1) {
                        uint8_t *loc = cursor_pos();
                        *loc = key | 0x80;
                        move_cursor(g_cursor_x + 1, g_cursor_y);

                        g_input_buffer[g_input_buffer_length++] = key;
                    }
                }
            }

            show_cursor();
        }
    }

    return 0;
}