timesynk/test/vm_compile.c

#include "vm_compile.h"
#include "vm.h"
#include <stdlib.h>
#include <stdio.h>
#include <string.h>
#include <ctype.h> // isdigit

/*** DEFINES ***/
char *vm_datatypes[] = {
  #define MAX_TYPES 7
  #define TYPE_CHAR 0
  "Char",
  #define TYPE_INT 1
  "Int",
  #define TYPE_FLOAT 2
  "Float",
  #define TYPE_STRING 3
  "String",
  #define TYPE_TABLE 4
  "Table",
  #define TYPE_TILE 5
  "Tile",
  #define TYPE_MAP 6
  "Map",
  #define TYPE_PLAYER 7
  "Player"
};

char *vm_expressions[] = {
  #define MAX_EXPS 3
  "return",
  #define EXP_RETURN 0
  "if",
  #define EXP_IF 1
  "while",
  #define EXP_WHILE 2
  "for"
  #define EXP_FOR 3
};

char *vm_assignments[] = {
  #define MAX_ASS 4
  #define ASS_EQ 0
  "=",
  #define ASS_ADD 1
  "+=",
  #define ASS_MIN 2
  "-=",
  #define ASS_MUL 3
  "*=",
  #define ASS_DIV 4
  "/="
};

char *vm_operations[] = {
  #define MAX_OPS 3
  #define OP_ADD 0
  "+",
  #define OP_MIN 1
  "-",
  #define OP_MUL 2
  "*",
  #define OP_DIV 3
  "/"
};

const char *vm_pc_binary_operators[] = {
#define PC_BINOPS 12
  "*",
#define PC_BINOP_MUL 0
  "/",
#define PC_BINOP_DIV 1
  "%",
#define PC_BINOP_MOD 2
  "+",
#define PC_BINOP_ADD 3
  "-",
#define PC_BINOP_SUB 4
  "<",
#define PC_BINOP_LT 5
  ">",
#define PC_BINOP_GT 6
  "<=",
#define PC_BINOP_LTE 7
  ">=",
#define PC_BINOP_GTE 8
  "==",
#define PC_BINOP_EQ 9
  "!=",
#define PC_BINOP_NEQ 10
  "&&",
#define PC_BINOP_AND 11
  "||"
#define PC_BINOP_OR 12
};

const char *vm_pc_assignment_operators[] = {
#define PC_ASSOPS 5
  "=",
#define PC_ASSOP_EQ 0
  "+=",
#define PC_ASSOP_AEQ 1
  "-=",
#define PC_ASSOP_SEQ 2
  "*=",
#define PC_ASSOP_MEQ 3
  "/=",
#define PC_ASSOP_DEQ 4
  "%="
#define PC_ASSOP_MOQ 5
};

const char *vm_pc_operators[][6] = {
#define PC_BINOP 0
  {
    "*",
    "/",
    "%",
    "+",
    "-"
  },
#define PC_ASSOP 0
  {
    "=",
    "+=",
    "-=",
    "*=",
    "/=",
    "%="
  }
};

/*** MAIN ***/
int main(int argc, char *argv[]) {
  vm_pc_global_scope.variables = newTable(32);
  vm_pc_global_scope.functions = newTable(32);
  vm_pc_group_scopes = newTable(32);
  vm_pc_local_scopes = newTable(32);

  char *code_dir = "code/";
  struct LList *code_files = dirToLList(code_dir, F_FILES);

  struct LList *current_file = code_files;
  while(current_file) {
    if(strstr((char *)current_file->data, ".vmc") != NULL) {
      char temp_string[strlen((char *)current_file->data)+strlen(code_dir)+1];
      sprintf(temp_string, "%s%s", code_dir, (char *)current_file->data);
      printf("-> precompiling %s\n", temp_string);
      int errors = 0;
      switch(errors = vm_precompileFile(temp_string)) {
        case 0:
          printf("-> OK: successfully read %s\n", temp_string);
          break;
        case -1:
          printf("ERROR, could not open file for reading\n");
          break;
        default:
          printf("%d ERRORS encountered while compiling %s\n", errors, temp_string);
          break;
      }
    }
    current_file = current_file->next;
  }
  return 0;
}

/*** PARSING ***/
/*
================================
int vm_precompileFile(const char *file_name)

This function takes in a given file name, opens it, and begins processing the file text character-by-character. When a valid code block is found, such as:

{
  // GLOBAL
}

0 {
  // GROUP
}

0:0 {
  // LOCAL
}

The appropriate scopes are created and passed to vm_precompileSection for actual precompilation.
================================
*/
int vm_precompileFile(const char *file_name) {
  FILE *file = fopen(file_name, "r");
  if (file == NULL) {
    return -1;
  }
  // NOTE: Temporarily switching to buffer access rather than file, for parsing reasons. Might keep, but we'll see.
  char chunk_buffer[16];
  int chunk_pos = 0;
  int bytes_read = 0;
  char *file_buffer = NULL;
  int file_size = 0;
  int file_pos = 0;

  fseek(file, 0, SEEK_END);
  file_size = ftell(file);
  fseek(file, 0, SEEK_SET);
  printf("allocated %d bytes for buffer\n", file_size);
  file_buffer = malloc(file_size+1); // +1 for /0
  while ((bytes_read = fread(chunk_buffer, 1, 16, file))) {
    for (chunk_pos = 0;chunk_pos < bytes_read;chunk_pos++) {
      file_buffer[file_pos++] = chunk_buffer[chunk_pos];
    }
  }
  file_buffer[file_pos] = '\0';
  file_pos = 0; // reset file pos!
  //fclose(file);

  char c; // current char!
  int cpos = 1; // char position
  int lpos = 1; // line position
  char first[128]; // max 128 characters for group or id string
  int fpos = 0; // char pos for ^
  char second[128]; // max 128 for id string
  int spos = -1; // char pos for ^, we cheat by using -1 as a way to use spos and fpos for our mode (e.g., group scope == -1, local scope >= 0)
  int errors = 0; // error count returned by precompileSection
  int total_errors = 0; // total error count, used in return
  //while(( c = fgetc(file)) != EOF) {
  while(( c = file_buffer[file_pos++]) != '\0') {
    if (isdigit(c)) {
      if (spos >= 0) {
        second[spos++] = c;
      } else {
        first[fpos++] = c;
      }
    } else if (c == ':') {
      if (spos >= 0) {
        printf("second ':' encountered\n");
      }
      if (fpos == 0) {
        first[fpos++] = '0';
      }
      first[fpos] = '\0';
      spos = 0;
    } else if (c == '{') {
      first[fpos] = '\0';
      if (fpos == 0) {
        printf("[%d,%d]: starting precompile for global code block\n", lpos, cpos);
        //if ((errors = vm_precompileSection(file, &lpos, &cpos, &vm_pc_global_scope, NULL, NULL)) != 0) {
        if ((errors = vm_precompileSection(file_buffer, &file_pos, &lpos, &cpos, &vm_pc_global_scope, NULL, NULL)) != 0) {
          printf("%d ERRORS encountered while compiling global code block!\n", errors);
          total_errors += errors;
        }
        printf("[%d,%d]: finished precompile for global code block\n", lpos, cpos);
        printf(" * dumping precompiled global\n");
        vm_pc_dumpScope(&vm_pc_global_scope);
      } else if (spos == -1) {
        struct vm_pc_Scope *group_scope = getTablePairValue(vm_pc_group_scopes, first);
        if (group_scope == NULL) { // create if does not exist
          group_scope = malloc(sizeof(struct vm_pc_Scope));
          group_scope->functions = newTable(32);
          group_scope->variables = newTable(32);
          addTablePairPointer(vm_pc_group_scopes, first, group_scope, T_TABLE); // FIXME: define VOID_POINTER in data.c/.h
        }
        printf("[%d,%d]: starting precompile for group code block %s\n", lpos, cpos, first);
        //if ((errors = vm_precompileSection(file, &lpos, &cpos, &vm_pc_global_scope, group_scope, NULL)) != 0) {
        if ((errors = vm_precompileSection(file_buffer, &file_pos, &lpos, &cpos, &vm_pc_global_scope, group_scope, NULL)) != 0) {
          printf("%d ERRORS encountered while compiling group code block %s!\n", errors, first);
          total_errors += errors;
          // TODO: perhaps allow potentially broken code?
          // TODO: return 1 on failure
          vm_pc_freeVariables(group_scope->variables);
        }
        printf("[%d,%d]: finished precompile for group code block %s\n", lpos, cpos, first);
        printf(" * dumping precompiled group\n");
        vm_pc_dumpScope(group_scope);
        fpos = 0;
        first[fpos] = '\0';
      } else {
        second[spos] = '\0';
        // Get/create our scope Table vm_pc_local_scopes[first]
        struct Table *local_scopes = getTablePairValue(vm_pc_local_scopes, first);
        if (local_scopes == NULL) {
          local_scopes = newTable(32);
          addTablePairPointer(vm_pc_local_scopes, first, local_scopes, T_TABLE);
        }
        // Get/create Scope from vm_pc_local_scopes[first][second]
        struct vm_pc_Scope *local_scope = getTablePairValue(local_scopes, second);
        if (local_scope == NULL) {
          local_scope = malloc(sizeof(struct vm_pc_Scope));
          local_scope->functions = newTable(32);
          local_scope->variables = newTable(32);
          addTablePairPointer(local_scopes, second, local_scope, T_TABLE); // FIXME: define VOID_POINTER in data.c/.h
        }
        // Get/create group scope from vm_pc_group_scopes[first]
        struct vm_pc_Scope *group_scope = getTablePairValue(vm_pc_group_scopes, first);
        if (group_scope == NULL) {
          group_scope = malloc(sizeof(struct vm_pc_Scope));
          group_scope->functions = newTable(32);
          group_scope->variables = newTable(32);
          addTablePairPointer(vm_pc_group_scopes, first, group_scope, T_TABLE); // FIXME: define VOID_POINTER in data.c/.h
        }
        printf("[%d,%d]: starting precompile for local code block %s:%s\n", lpos, cpos, first, second);
        //if ((errors = vm_precompileSection(file, &lpos, &cpos, &vm_pc_global_scope, group_scope, local_scope)) != 0) {
        if ((errors = vm_precompileSection(file_buffer, &file_pos, &lpos, &cpos, &vm_pc_global_scope, group_scope, local_scope)) != 0) {
          printf("%d ERRORS encountered while compiling local code block %s:%s!\n", errors, first, second);
          total_errors += errors;
        }
        printf("[%d,%d]: finished precompile for local code block %s:%s\n", lpos, cpos, first, second);
        /*printf(" * dumping precompiled global variables\n");
        vm_pc_dumpScope(&vm_pc_global_scope);
        printf(" * dumping precompiled group variables\n");
        vm_pc_dumpScope(group_scope);*/
        printf(" * dumping precompiled local\n");
        vm_pc_dumpScope(local_scope);
        fpos = 0;
        first[fpos] = '\0';
        spos = -1;
        second[spos] = '\0';
      }
    }
    if (c == '\n') {
      lpos++;
      cpos = 1;
    } else {
      cpos++;
    }
  }
  //fclose(file);
  //free(file_buffer);
  return total_errors; // success, baby
}

//int vm_precompileSection(FILE *file, int *lpos_, int *cpos_, struct vm_pc_Scope *global, struct vm_pc_Scope *group, struct vm_pc_Scope *local) {
int vm_precompileSection(char *file_buffer, int *file_pos_, int *lpos_, int *cpos_, struct vm_pc_Scope *global, struct vm_pc_Scope *group, struct vm_pc_Scope *local) {
  int file_pos = *file_pos_;
  int lpos = *lpos_;
  int cpos = *cpos_;
  int depth = 0;
  int pdepth = 0; // parenthesis depth
  char words[31][128]; // word list [X][Y]
  int wpos = 0; // word position, i.e., X
  int wcpos = 0; // word character position, i.e., Y
  int error = 0;
  int ret = 0;
  struct vm_pc_Scope *current_scope; // default scope is local
  // if local is NULL, that means we are in group scope. If group is NULL, we are in global
  if (local == NULL) {
    if (group == NULL) {
      //printf("  * Precompiling global\n");
      current_scope = global;
    } else {
      //printf("  * Precompiling group\n");
      current_scope = group;
    }
  } else {
    //printf("  * Precompiling local\n");
    current_scope = local;
  }
  memset(&words, '\0', 31*128);
  char c; // current char!
  //while(( c = fgetc(file)) != EOF) {
  while(( c = file_buffer[file_pos++]) != '\0') {
    if (c == '{') {
      depth++;
    } else if (c == '}') {
      depth--;
    }
    if (c == '\n') {
      lpos++;
      cpos = 1;
    } else {
      cpos++;
    }
    if (depth < 0)
      break;
    // actual conversion of lines to words
    // '/' discard double '//' as it is 
    if (c == '/') {
      if (words[wpos][wcpos-1] == '/') {
        // step back and remove old line
        words[wpos][--wcpos] = '\0';
        // discard chars until newline or EOF
        char nc; // new char - used in following consumption loop
        //while((nc = fgetc(file)) != '\n' && nc != '\r' && nc != EOF);
        while((nc = file_buffer[file_pos++]) != '\n' && nc != '\r' && nc != EOF);
        lpos++;
        cpos = 1;
      } else {
        words[wpos][wcpos++] = c;
        cpos++;
      }
    // when ( is encountered and parenthesis depth is 0, end the current word, and start new word with '('. Otherwise, add parenthesis to current word.
    } else if (c == '(') {
      if (pdepth == 0) {
        words[wpos++][wcpos] = '\0';
        wcpos = 0;
        words[wpos][wcpos++] = c;
      } else {
        words[wpos][wcpos++] = c;
      }
      pdepth++;
    // when ) is encountered, decrease depth and add to current word.
    } else if (c == ')') {
      pdepth--;
      words[wpos][wcpos++] = c;
      if (pdepth > 0) {
        words[wpos++][wcpos] = '\0';
        wcpos = 0;
      }
    // if parenthesis depth is greater than zero, then add spaces or tabs to the current word. If not, end current word and start new word.
    // TODO: quotations should enable skipping of the following
    } else if (c == ' ' || c == '\t') {
      if (pdepth > 0) {
        words[wpos][wcpos++] = c;
      } else {
        if (wcpos != 0) {
          //words[wpos][wcpos++] = c;
          words[wpos++][wcpos] = '\0';
          wcpos = 0;
        }
      }
    // consume newlines with greed.
    } else if (c == '\n' || c == '\r') {

    // when a ';' is encountered, this equates to a variable or function declaration.
    } else if (c == ';') {
      int wwpos = 0;
      int wtypes[wpos];
      // BEGIN VARIABLE PARSING
      for (wwpos=0;wwpos <= wpos;wwpos++) {
        // BEGIN VARIABLE DECLARATION
        // first we set the first word's type by checking against reserved words
        if (wwpos == 0) { // "_int_"
          int wtype = vm_isReserved(words[wwpos]);
          wtypes[wwpos] = wtype;
          if (wpos == 0) {
            printf("[%d,%d]: ERROR, floating statement \"%s\".\n", lpos, cpos, words[wwpos]);
            error++;
          }
          if (wtype != 1) {
            printf("[%d,%d]: ERROR, \"%s\" is not a valid data type.\n", lpos, cpos, words[wwpos]);
            error++;
          }
        } else if (wwpos == 1) {
          // now we check if the first word's type is "1" - a built-in data type
          if (wtypes[wwpos-1] == 1) { // "int _x_ . . ."
            // we check against a second datatype declaration, such as "int int" - this is invalid
            wtypes[wwpos] = vm_isReserved(words[wwpos]);
            // TODO: check if variable name is valid (alpha-only)
            if (wtypes[wwpos] == 0) {
              // now add to our current scope's variable Table
              if ((ret = vm_pc_addVariableToScope(current_scope, words[wwpos-1], words[wwpos])) != 0) {
                switch(ret) {
                  case 1:
                    printf("[%d,%d]: ERROR, could not add \"%s\", as \"%s\" was already defined.\n", lpos, cpos, words[wwpos], words[wwpos]);
                    error++;
                    break;
                  case 2:
                    printf("[%d,%d]: ERROR, could not add \"%s\", as type \"%s\" is undefined.\n", lpos, cpos, words[wwpos], words[wwpos-1]);
                    error++;
                    break;
                  case 3:
                    printf("[%d,%d]: ERROR, could not add \"%s\", as type \"%s\" is undefined in translation function.\n", lpos, cpos, words[wwpos], words[wwpos-1]);
                    error++;
                    break;
                  case -1:
                    printf("[%d,%d]: ERROR, could not add \"%s\", as scope is NULL\n", lpos, cpos, words[wwpos]);
                    error++;
                    break;
                  default:
                    printf("[%d,%d]: ERROR, unhandled error while adding variable!\n", lpos, cpos);
                    error++;
                    break;
                }
              }
            } else {
              printf("[%d,%d]: ERROR, bad variable name, \"%s\" is reserved\n", lpos, cpos, words[wwpos]);
              error++;
              break;
            }
          }
        // END VARIABLE DECLARATION
        // now we parse for assignment operations, if available
        // BEGIN VARIABLE SETTING
        } else if (wwpos == 2) {
          wtypes[wwpos] = vm_isReserved(words[wwpos]);
          if (wtypes[wwpos-1] == 0) { // variable name
            if (wtypes[wwpos] == 0) { // "int _int_"
              printf("[%d,%d]: ERROR, \"%s\" given after \"%s\" already provided - perhaps a forgotten assignment op?\n", lpos, cpos, words[wwpos], words[wwpos-1]);
              error++;
              break;
            } else if (wtypes[wwpos] == 4) { // "="
              if (wtypes[wwpos-1] == 0) {
                if (wwpos+1 > wpos || words[wwpos+1][0] == '\0') {
                  printf("[%d,%d]: ERROR, right-hand of assignment for \"%s\" empty!\n", lpos, cpos, words[wwpos-1]);
                  error++;
                  break;
                } else {
                  // TODO: check if is a value or variable. if right-hand of assignment is a variable and does not exist, complain.
                  if ((ret = vm_pc_setVariable((struct vm_pc_Variable*)getTablePairValue(current_scope->variables, words[wwpos-1]), words[wwpos+1])) != 0) {
                    switch(ret) {
                      case -1:
                        printf("[%d,%d]: ERROR, variable \"%s\" undeclared!\n", lpos, cpos, words[wwpos-1]);
                        error++;
                        break;
                      default:
                        printf("[%d,%d]: ERROR, unhandled error while setting variable \"%s\"!\n", lpos, cpos, words[wwpos-1]);
                        error++;
                        break;
                    }
                  } else {
                    //printf("  SET (%s)%s=>%s\n", ((struct vm_pc_Variable *)getTablePairValue(current_scope->variables, words[wwpos-1]))->type, words[wwpos-1], ((struct vm_pc_Variable *)getTablePairValue(current_scope->variables, words[wwpos-1]))->data);
                  }
                }
              } else {
                printf("[%d,%d]: ERROR, \"%s\" after \"%s\" is invalid!\n", lpos, cpos, words[wwpos], words[wwpos-1]);
                error++;
              }
            }
          }
        // VARIABLE SETTING cont'd
        } else {
          wtypes[wwpos] = vm_isReserved(words[wwpos]);
          if (wtypes[wwpos] == 4) { // "="
            if (wtypes[wwpos-1] == 0) {
              if (wwpos+1 > wpos) {
                printf("[%d,%d]: ERROR, right-hand of assignment for \"%s\" empty!\n", lpos, cpos, words[wwpos-1]);
                error++;
                break;
              } else {
                  // TODO: check if is a value or variable. if right-hand of assignment is a variable and does not exist, complain.
                if ((ret = vm_pc_setVariable((struct vm_pc_Variable*)getTablePairValue(current_scope->variables, words[wwpos-1]), words[wwpos+1])) != 0) {
                  switch(ret) {
                    case -1:
                      printf("[%d,%d]: ERROR, variable \"%s\" undeclared!\n", lpos, cpos, words[wwpos-1]);
                      error++;
                      break;
                    default:
                      printf("[%d,%d]: ERROR, unhandled error while setting variable!\n", lpos, cpos);
                      error++;
                      break;
                  }
                } else {
                  printf("  SET (%s)%s=>%s\n", ((struct vm_pc_Variable *)getTablePairValue(current_scope->variables, words[wwpos-1]))->type, words[wwpos-1], ((struct vm_pc_Variable *)getTablePairValue(current_scope->variables, words[wwpos-1]))->data);
                }
              }
            } else {
              printf("[%d,%d]: ERROR, \"%s\" after \"%s\" is invalid!\n", lpos, cpos, words[wwpos], words[wwpos-1]);
              error++;
            }
          }
        }
        // END VARIABLE SETTING
      }
      // END VARIABLE PARSING
      /*printf("\t\t");
      for(wwpos = 0;wwpos <= wpos;wwpos++) {
        printf("%s ", words[wwpos]);
      }
      printf("\n");*/
      // RESET
      wpos = 0;
      wcpos = 0;
      memset(&words, '\0', 31*128);
    // when a '{' is encountered, what follows should be a function.
    // BEGIN FUNCTION PARSING
    } else if (c == '{') {
      // Check if first word is a Type or an expression
      int wwpos = 0;
      if (wpos != 3) { // wordcount is always three for function declaration
        printf("[%d,%d]: ERROR, general improper function declaration\n", lpos, cpos);
        error++;
      } else {
        ret = vm_isReserved(words[wwpos]);
        if (ret != 1) {
          switch(ret) {
            case 2: // expression
              printf("[%d,%d]: ERROR, expressions not allowed outside of function\n", lpos, cpos);
              break;
            case 3: // operation
              printf("[%d,%d]: ERROR, operations not allowed outside of function\n", lpos, cpos);
              break;
            case 4: // assignment
              printf("[%d,%d]: ERROR, assignment not allowed outside of function\n", lpos, cpos);
              break;
            default: // unhandled
              printf("[%d,%d]: ERROR, unknown return type \"%s\" in function declaration\n", lpos, cpos, words[wwpos]);
              break;
          }
          error++;
        } else {
          ret = vm_isReserved(words[++wwpos]);
          if (ret != 0) {
            printf("[%d,%d]: ERROR, function cannot be named \"%s\"\n", lpos, cpos, words[wwpos]);
            error++;
          } else {
            if (words[++wwpos][0] != '(') {
              printf("[%d,%d]: ERROR, function parameters missing left-hand parenthesis!\n", lpos, cpos);
              error++;
            } else {
              struct vm_pc_Function *func = vm_pc_newFunction(words[0]);
              if (func == NULL) {
                printf("[%d,%d]: PC_CRIT_ERR, could not create new function!\n", lpos, cpos);
                error++;
              } else {
                // TODO: parse parameters into vm_pc_Variable(s) and add to function's params
                //if ((ret = vm_precompileFunction(file, &lpos, &cpos, global, group, local, func)) != 0) {
                if ((ret = vm_precompileFunction(file_buffer, &file_pos, &lpos, &cpos, global, group, local, func)) != 0) {
                  printf("[%d,%d]: %d ERRORS while precompiling function \"%s\"!\n", lpos, cpos, ret, words[1]);
                  error += ret;
                } else {
                  depth--;
                }
                ret = vm_pc_addFunctionToScope(current_scope, func, words[1]);
                if (ret != 0) {
                  switch(ret) {
                    case -1:
                      printf("[%d,%d]: PC_CRIT_ERR, local scope is NULL!\n", lpos, cpos);
                      error++;
                      break;
                    case -2:
                      printf("[%d,%d]: PC_CRIT_ERR, new function is NULL!\n", lpos, cpos);
                      error++;
                      break;
                    case 1:
                      printf("[%d,%d]: ERROR, function %s already declared!\n", lpos, cpos, words[1]);
                      error++;
                      break;
                    case 2:
                      printf("[%d,%d]: PC_CRIT_ERR, unknown function return Type!\n", lpos, cpos);
                      error++;
                      break;
                  }
                } else {
                  printf("Added function %s with return %s\n", words[1], words[0]);
                }
              }
            }
          }
        }
      }
      // RESET
      wpos = 0;
      wcpos = 0;
      memset(&words, '\0', 31*128);
    } else if (c == '}') {
      // I guess leave current vm_pc_Function scope here if depth == 0?
      /*int wwpos = 0;
      for(wwpos = 0;wwpos <= wpos;wwpos++) {
        printf("%d: %s\n", wwpos, words[wwpos]);
      }*/
      // RESET
      wpos = 0;
      wcpos = 0;
      memset(&words, '\0', 31*128);
    // END FUNCTION PARSING
    } else {
      words[wpos][wcpos++] = c;
    }
  }
  *lpos_ = lpos;
  *cpos_ = cpos;
  *file_pos_ = file_pos;
  return error;
}

//int vm_precompileFunction(FILE *file, int *lpos_, int *cpos_, struct vm_pc_Scope *global, struct vm_pc_Scope *group, struct vm_pc_Scope *individual, struct vm_pc_Function *func) {
int vm_precompileFunction(char *file_buffer, int *file_pos_, int *lpos_, int *cpos_, struct vm_pc_Scope *global, struct vm_pc_Scope *group, struct vm_pc_Scope *individual, struct vm_pc_Function *func) {
  int file_pos = *file_pos_;
  int lpos = *lpos_;
  int cpos = *cpos_;
  int error = 0;
  int depth = 1;
  char c;
  char words[255][255]; // temp
  int word = 0;
  int wpos = 0;
  //while(( c = fgetc(file)) != EOF) {
  //while(( c = fgetc(file)) != EOF) {
  while(( c = file_buffer[file_pos++]) != '\0') {
    if (c == '{') {
      depth++;
    } else if (c == '}') {
      depth--;
    }
    if (c == '\n') {
      lpos++;
      cpos = 1;
    } else {
      cpos++;
    }
    if (depth <= 0)
      break;

    if (c == '\n' || c == '\r' || c == '\t' || c == ' ')
      continue;
    words[word][wpos] = c;
    words[word][wpos+1] = '\0';
    // now we check against possible expressions
    int op_code;
    int reserved = 0;
    int match = 0;
    for(op_code = 0;op_code < PC_ASSOPS;op_code++) {
      int op_length = strlen(vm_pc_assignment_operators[op_code])-1;
      // see if current char matches operator's last char
      if (words[word][wpos] == vm_pc_assignment_operators[op_code][op_length]) {
        reserved = 1;
        // potential match, step backwards into word, checking against operator's chars
        int op_pos = 1;
        while(op_pos <= op_length) {
          if (wpos-op_pos < 0) {
            // word is not long enough :(
            match = 0;
            printf("word not long enough\n");
            break;
          }
          if (words[word][wpos-op_pos] == vm_pc_assignment_operators[op_code][op_length-op_pos]) {
            printf("    %c matches %c\n", words[word][wpos-op_pos], vm_pc_assignment_operators[op_code][op_length-op_pos]);
            if (op_pos == op_length) {
              printf("we are equal\n");
              match = 1;
              break;
            }
          }
          op_pos++;
        }
        if (match == 0) {
          printf("no match, continuing...\n");
        } else {
          printf("match found, op is %s!! :o\n", vm_pc_assignment_operators[op_code]);
          word++;
          break;
        }
      }
    }
    if (reserved == 1 && match == 0){ 
      printf("hah, could not find op for %s\n", words[word]);
    }
    wpos++;
    // potential code to process:
    // Int a, b, c;
    // a = b;
    // a += c;
    // func(a+b);
    // a = func(b+c);
    // Int d = a + func(c);
    // if (d == func(a) || func(b+c)) {
    //   // . . .
    // }
    // So our steps would be to identify declaration from expression
    // So the first word is checked against types. If found, next word is a variable. If ';' thereafter, end of declaration. if '=', then assignment to some expression.
    //  expressions are parsed by building an expression tree(ETree). An ETree parses an operation-based expression(i.e., "1 + 2 * my_var / function(2+3) - 3"). This breaks down into:
    //        +
    //       / \
    //      1   -
    //         / \
    //        *   3
    //       / \
    //      2   /
    //         / \
    //    my_var  function(+)
    //                    / \
    //                   2   3
    //
    // logical operations (if a == b || a == c):
    //    < ?? >
    //      ||
    //     /  \
    //   ==    ==
    //  / \   / \
    // a   b a   c
    //
    // (if a+b == c && b+c == d):
    //      < ?? >
    //        &&
    //       /  \
    //     ==    ==
    //    / \    / \
    //   +   c  +   d
    //  / \    / \
    // a   b  b   c
    //
    // a source code expression is parsed into an expression tree as expression nodes by creating nodes in a specific order. This order begins with operators such as +, -, *, /, and so on. Once an expression tree is complete, it is converted into operations in a left-most inner-most fashion. :3
  }
  *lpos_ = lpos;
  *cpos_ = cpos;
  *file_pos_ = file_pos;
  return error;
}

/*** POPULATING ***/
/*
Returns:
  0 on success
  1 if the variable is already defined
  2 if the data type does not exist
*/
int vm_pc_addVariableToScope(struct vm_pc_Scope *scope, const char *data_type, const char *data_name) {
  if (scope == NULL) {
    return -1; // FIXME
  }
  if (getTablePair(scope->variables, data_name) != NULL) {
    return 1;
  }
  int type;
  for (type = 0;type <= MAX_TYPES;type++) {
    if (strcmp(data_type, vm_datatypes[type]) == 0) {
      struct vm_pc_Variable *new_var = vm_pc_newVariable(data_type, "undef");
      addTablePairPointer(scope->variables, data_name, new_var, T_POINTER);
      //printf("  ADDED (%s)%s=>%s\n", ((struct vm_pc_Variable *)getTablePairValue(scope->variables, data_name))->type, data_name, ((struct vm_pc_Variable *)getTablePairValue(scope->variables, data_name))->data);
      return 0;
    }
  }
  return 2;
}

int vm_pc_addFunctionToScope(struct vm_pc_Scope *scope, struct vm_pc_Function *func, const char *func_name) {
  if (scope == NULL) {
    return -1; // FIXME
  }
  if (func == NULL) {
    return -2;
  }
  if (getTablePair(scope->functions, func_name) != NULL) {
    return 1;
  }
  int type;
  for (type = 0;type <= MAX_TYPES;type++) {
    if (strcmp(func->ret->type, vm_datatypes[type]) == 0) {
      addTablePairPointer(scope->functions, func_name, func, T_POINTER);
      //printf("  ADDED (%s)%s=>%s\n", ((struct vm_pc_Variable *)getTablePairValue(scope->variables, data_name))->type, data_name, ((struct vm_pc_Variable *)getTablePairValue(scope->variables, data_name))->data);
      return 0;
    }
  }
  return 2;
}

int vm_pc_setVariable(struct vm_pc_Variable *var, const char *data) {
  // TODO: check for var types - do not set strings to ints, etc.
  if (var == NULL) {
    return -1;
  }
  int data_size = strlen(data)+1;
  var->data = realloc(var->data, data_size);
  memcpy(var->data, data, data_size);
  return 0;
}

/*** ALLOC ***/
struct vm_pc_Variable *vm_pc_newVariable(const char *type, const char *value) {
  struct vm_pc_Variable *var = malloc(sizeof(struct vm_pc_Variable));
  if (var == NULL) {
    printf("!!! PC_CRIT_ERR, could not malloc memory for variable\n");
    return NULL;
  }
  int type_size = strlen(type)+1;
  if ((var->type = malloc(type_size)) == NULL) {
    printf("!!! PC_CRIT_ERR, could not malloc memory for variable type\n");
    return NULL;
  } else {
    memcpy(var->type, type, type_size);
  }

  int value_size = strlen(value)+1;
  if ((var->data = malloc(value_size)) == NULL) {
    printf("!!! PC_CRIT_ERR, could not malloc memory for variable data\n");
    free(var->type);
    return NULL;
  } else {
    memcpy(var->data, value, value_size);
  }
  return var;
}

struct vm_pc_Function *vm_pc_newFunction(const char *return_type) {
  struct vm_pc_Function *func = malloc(sizeof(struct vm_pc_Function));
  if (func == NULL) {
    printf("!!! PC_CRIT_ERR, could not malloc memory for function\n");
    return NULL;
  }
  if ((func->parameters = newTable(8)) == NULL) {
    printf("!!! PC_CRIT_ERR, could not create new Table for function parameters\n");
    return NULL;
  }
  if ((func->variables = newTable(32)) == NULL) {
    printf("!!! PC_CRIT_ERR, could not create new Table for function variables\n");
    return NULL;
  }
  if ((func->operations = newTable(64)) == NULL) {
    printf("!!! PC_CRIT_ERR, could not create new Table for function operations\n");
    return NULL;
  }
  if ((func->ret = vm_pc_newVariable(return_type, "undef")) == NULL) {
    printf("!!! PC_CRIT_ERR, could not create new return Variable for function\n");
    return NULL;
  }
  return func;
}

struct vm_pc_ENode *vm_pc_newENode(char type, void *data) {
  struct vm_pc_ENode *enode = malloc(sizeof(struct vm_pc_ENode));
  enode->type = type;
  enode->data = data;
  enode->left = NULL;
  enode->right = NULL;
  return enode;
}

/*** FREE ***/
int vm_pc_freeVariable(struct vm_pc_Variable *variable) {
  if (variable == NULL) return 1;
  if (variable->type != NULL) free(variable->type);
  if (variable->data != NULL) free(variable->data);
  free(variable);
  return 0;
}

int vm_pc_freeVariables(struct Table *variables) {
  if (variables == NULL) return 1;
  int i = 0;
  while (i < variables->size) {
    struct TablePair *entry = variables->pair[i];
    struct TablePair *next_entry = NULL;
    while (entry != NULL) {
      next_entry = entry->next;
      struct vm_pc_Variable *var = entry->value;
      vm_pc_freeVariable(var);
      freeTablePair(entry);
      variables->count--;
      entry = next_entry;
    }
    variables->pair[i] = NULL;
    i++;
  }
  return 0;
}

int vm_pc_freeFunction(struct vm_pc_Function *function) {
  if (function == NULL) return 1;
  if (function->variables) vm_pc_freeVariables(function->variables);
  // TODO: free ops
  free(function);
  return 0;
}

int vm_pc_freeFunctions(struct Table *functions) {
  int i =0;
  while (i < functions->size) {
    struct TablePair *entry = functions->pair[i];
    struct TablePair *next_entry = NULL;
    while (entry != NULL) {
      next_entry = entry->next;
      struct vm_pc_Function *func = entry->value;
      vm_pc_freeFunction(func);
      freeTablePair(entry);
      functions->count--;
      entry = next_entry;
    }
    i++;
  }
  return 0;
}

int vm_pc_freeScope(struct vm_pc_Scope *scope) {
  if (scope == NULL) return 1;
  vm_pc_freeVariables(scope->variables);
  vm_pc_freeFunctions(scope->functions);
  return 0;
}

/*** ETC ***/
int vm_isReserved(char *word) {
  int checkpos;
  for (checkpos = 0;checkpos <= MAX_TYPES;checkpos++) {
    if (strcmp(word, vm_datatypes[checkpos]) == 0) {
      return 1;
    }
  }
  for (checkpos = 0;checkpos <= MAX_EXPS;checkpos++) {
    if (strcmp(word, vm_expressions[checkpos]) == 0) {
      return 2;
    }
  }
  for (checkpos = 0;checkpos <= MAX_OPS;checkpos++) {
    if (strcmp(word, vm_operations[checkpos]) == 0) {
      return 3;
    }
  }
  for (checkpos = 0;checkpos <= MAX_ASS;checkpos++) {
    if (strcmp(word, vm_assignments[checkpos]) == 0) {
      return 4;
    }
  }
  return 0;
}

int vm_pc_dumpScope(struct vm_pc_Scope *scope) {
  int i = 0;
  printf("  * variables\n");
  while (i < scope->variables->size) {
    struct TablePair *entry = scope->variables->pair[i];
    while (entry != NULL) {
      struct vm_pc_Variable *var = entry->value;
      printf("  %s %s = %s\n", var->type, entry->key, var->data);
      entry = entry->next;
    }
    i++;
  }
  i = 0;
  printf("  * functions\n");
  while (i < scope->functions->size) {
    struct TablePair *entry = scope->functions->pair[i];
    while (entry != NULL) {
      struct vm_pc_Function *var = entry->value;
      printf("  %s %s()\n", var->ret->type, entry->key);
      entry = entry->next;
    }
    i++;
  }
  return 0;
}