180 lines
7.2 KiB
C
180 lines
7.2 KiB
C
#include "kernel.h"
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// This only runs once and from there on forth only interrupts will cause something to happen
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// e.g. displaying to screen and taking input from keyboard
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void _start() {
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// Initialize Global Variables and set up interrrupt handlers
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// These variables are a vulnerability to OS security if someone can adjust
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// the lower value in the kernel code (exploiting, for example, an Intel address hack)
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// than kernel memory and even kernel code can be overwritten
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// https://www.wired.com/story/intel-lab-istare-hack-chips/
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// See libc/globals.h for KMEM_START and KMEM_END values
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// See libc/globals.h for UMEM_START and UMEM_END values
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kmem_addr = KMEM_START;
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kernel_mem_limit = KMEM_END;
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umem_addr = UMEM_START;
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user_mem_limit = UMEM_END;
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global_head = NULL;
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global_id = 0;
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isr_install();
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irq_install();
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kprint("Type something, it will go through the kernel\n"
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"Type HELP to list commands\n> ");
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}
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// An interrupt calls this function to parse what was typed in, this is, essentially, your
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// Command Line Interpreter for now.
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void user_input(char *input) {
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static u32 delete_id = 0; // static persistent variable for incrementing during test
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static node* umem_head = NULL; // static persistent head variable for contiguous block allocations
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if (strcmp(input, "END") == 0) {
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kprint("Stopping the CPU. Bye!\n");
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asm volatile("hlt");
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} else if (strncmp(input, "ADD", 3) == 0) {
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u32 base = 0x10000;
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u32 limit = 0x100;
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bool valid = true;
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if (sstrlen(input, 15) > 4) {
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char *args1 = input + 4;
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base = digit_conver(args1);
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int nDigits = digit_len(base);
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if (sstrlen(args1, 15) > nDigits + 1) {
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char *args2 = args1 + nDigits + 1;
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limit = digit_conver(args2);
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if (limit < 100) {
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kprint("That memory address is to below the min of 0x100.\n");
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valid = false;
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}
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}
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if (base < 10000) {
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kprint("That memory address is reserved by the Kernel, addresses must be 10000+\n");
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valid = false;
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}
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}
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if (valid) {
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umem_head = add_node( umem_head, base, limit, true, global_id++);
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}
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} else if (strcmp(input, "LIST") == 0) {
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kprint("***** FORWARD ****\n");
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print_list( umem_head, true);
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kprint("***** REVERSE ****\n");
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print_list( umem_head, false);
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} else if (strcmp(input, "SHORTLIST") == 0) {
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shortprint_list( umem_head, true);
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kprint("\n******************\n");
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shortprint_list( umem_head, false);
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} else if (strcmp(input, "PAGE") == 0) {
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u32 phys_addr = 0;
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u32 page = umalloc(0x4200, 0, &phys_addr);
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kprint_hex( "Page: ", page, 10);
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kprint_hex(", physical address: ", phys_addr, 10);
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kprint("\n");
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} else if (strcmp(input, "DELETE") == 0) {
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umem_head = remove_node_by_id( umem_head, delete_id++);
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} else if (strcmp(input, "INSERT") == 0) {
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node *new_node = create_node( 0x15000, 0x1100, true, global_id++);
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node *insert_point = find_id( umem_head, 3);
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umem_head = insert_node( umem_head, insert_point, new_node, true);
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new_node = create_node( 0x18000, 0x2100, true, global_id++);
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insert_point = find_id( umem_head, 5);
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umem_head = insert_node( umem_head, insert_point, new_node, false);
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} else if (strcmp(input, "SORTA") == 0) {
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umem_head = hacksort_list( umem_head, true);
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} else if (strcmp(input, "SORTD") == 0) {
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umem_head = hacksort_list( umem_head, false);
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} else if (strcmp(input, "SWAP") == 0) {
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node *n1 = find_id( umem_head, 1);
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node *n2 = find_id( umem_head, 5);
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node *n3 = find_id( umem_head, 3);
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node *n4 = find_id( umem_head, 7);
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swap_node_data( n1, n2);
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swap_node_data( n2, n3);
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swap_node_data( n3, n4);
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} else if (strcmp(input, "TEST") == 0) {
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char s1[10] = "ABCDFFGH\0";
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char s2[10] = "ABCDEGH\0";
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int x = strncmp( s1, s2, 5);
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kprint_hex( "STRNCMP: ", x, 16);
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kprint("\n");
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x = sstrlen( s2, 10);
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kprint_hex( "SSTRLEN: ", x, 10);
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kprint("\n");
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x = strlen( s2);
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kprint_hex( "STRLEN: ", x, 10);
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kprint("\n");
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} else if (strcmp(input, "HELP") == 0) {
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kprint("Current Commands: ADD, LIST, SHORTLIST, PAGE, DELETE,\n");
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kprint(" : END, INSERT, SORTA, SORTD, SWAP, TEST, HELP\n");
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kprint(" Review the kernel.c source code to see what each command does.\n");
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kprint(" These are hard coded and are just examples, modify as you see fit.\n");
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kprint(" for example - TEST was just added so that I could test the strlen commands.\n");
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} else if (strcmp(input, "HOLES") == 0) {
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print_holes(umem_head);
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} else {
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kprint("You said: ");
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kprint(input);
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kprint("\n");
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}
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kprint("> ");
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}
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int digit_len(unsigned digit) {
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if (digit >= 1000000000) return 10;
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if (digit >= 100000000) return 9;
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if (digit >= 10000000) return 8;
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if (digit >= 1000000) return 7;
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if (digit >= 100000) return 6;
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if (digit >= 10000) return 5;
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if (digit >= 1000) return 4;
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if (digit >= 100) return 3;
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if (digit >= 10) return 2;
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return 1;
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}
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int digit_conver(const char *hexString) {
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u32 result = 0;
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while (*hexString != '\0') {
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char hexChar = *hexString;
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if ((hexChar >= '0' && hexChar <= '9') || (hexChar >= 'A' && hexChar <= 'F')) {
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int digit = (hexChar >= '0' && hexChar <= '9') ? (hexChar - '0') : (10 + (hexChar - 'A'));
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result = result * 16 + digit;
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} else {
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break;
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}
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hexString++;
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}
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return result;
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}
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void print_holes(node* umem_head) {
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if (umem_head == NULL) {
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kprint("Holes list is Empty");
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return;
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}
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u32 hole_ids = 0;
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node *hole = NULL;
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while(umem_head != NULL) {
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if (umem_head->previous == NULL) {
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if (umem_head->base_register-0x10000 != 0) {
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hole = add_node( hole, 0x10000, umem_head->base_register-0x10000, true, ++hole_ids);
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}
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} else if (umem_head->next == NULL) {
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node *previous = umem_head->previous;
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hole = add_node( hole, previous->base_register+previous->limit_register, -1, true, ++hole_ids);
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} else {
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node *previous = umem_head->previous;
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node *next = umem_head->next;
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hole = add_node( hole, previous->base_register+previous->limit_register, next->base_register, true, ++hole_ids);
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}
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umem_head = umem_head->next;
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}
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print_list(hole, false);
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} |