metasploit-framework/external/source/byakugan/csv_parser.cpp

496 lines
12 KiB
C++
Executable File

/* INCLUDING HEADER FILES */
#include "csv_parser.hpp"
/* BEGIN DEFINITION FOR PUBLIC METHODS */
bool csv_parser::init(FILE * input_file_pointer)
{
input_fp = input_file_pointer;
if (input_fp == NULL)
{
//dprintf("Fatal error : unable to open input file from file pointer\n");
return false;
}
/* Resetting the internal pointer to the beginning of the stream */
rewind(input_fp);
more_rows = true;
_skip_lines();
return true;
}
bool csv_parser::init(const char * input_file)
{
const size_t filename_length = strlen(input_file);
if (!filename_length)
{
fprintf(stderr, "Fatal error : invalid input file %s\n", input_file);
return false;
}
input_filename = (char *) malloc(filename_length + 1);
if (input_filename == NULL)
{
//dprintf("Fatal error : unable to allocate memory for file name buffer %s\n", input_file);
return false;
}
memset(input_filename, 0, filename_length + 1);
strcpy(input_filename, input_file);
input_fp = fopen(input_file, "r");
if (input_fp == NULL)
{
//dprintf("Fatal error : unable to open input file %s\n", input_file);
CSV_PARSER_FREE_BUFFER_PTR(input_filename);
return false;
}
more_rows = true;
_skip_lines();
return true;
}
void csv_parser::set_enclosed_char(char fields_enclosed_by, enclosure_type_t enclosure_mode)
{
if (fields_enclosed_by != 0)
{
enclosed_char = fields_enclosed_by;
enclosed_length = 1U;
enclosure_type = enclosure_mode;
}
}
void csv_parser::set_field_term_char(char fields_terminated_by)
{
if (fields_terminated_by != 0)
{
field_term_char = fields_terminated_by;
field_term_length = 1U;
}
}
void csv_parser::set_line_term_char(char lines_terminated_by)
{
if (lines_terminated_by != 0)
{
line_term_char = lines_terminated_by;
line_term_length = 1U;
}
}
csv_row csv_parser::get_row(void)
{
csv_row current_row;
/* This will store the length of the buffer */
unsigned int line_length = 0U;
/* Character array buffer for the current record */
char * line = NULL;
/* Grab one record */
_read_single_line(&line, &line_length);
/* Select the most suitable field extractor based on the enclosure length */
switch(enclosure_type)
{
case ENCLOSURE_NONE : /* The fields are not enclosed by any character */
_get_fields_without_enclosure(&current_row, line, &line_length);
break;
case ENCLOSURE_REQUIRED : /* The fields are enclosed by a character */
_get_fields_with_enclosure(&current_row, line, &line_length);
break;
case ENCLOSURE_OPTIONAL : /* The fields may or may not be enclosed */
_get_fields_with_optional_enclosure(&current_row, line, &line_length);
break;
default :
_get_fields_with_optional_enclosure(&current_row, line, &line_length);
break;
}
/* Deallocate the current buffer */
CSV_PARSER_FREE_BUFFER_PTR(line);
/* Keeps track of how many times this has method has been called */
record_count++;
return current_row;
}
/* BEGIN DEFINITION FOR PROTECTED METHODS */
/* BEGIN DEFINITION FOR PRIVATE METHODS */
void csv_parser::_skip_lines(void)
{
/* Just in case the user accidentally sets ignore_num_lines to a negative number */
unsigned int number_of_lines_to_ignore = abs((int) ignore_num_lines);
while(has_more_rows() && number_of_lines_to_ignore)
{
const csv_row row = get_row();
number_of_lines_to_ignore--;
}
record_count = 0U;
}
void csv_parser::_get_fields_without_enclosure(csv_row_ptr row, const char * line, const unsigned int * line_length)
{
char * field = NULL;
if (*line_length > 0)
{
field = (char *) malloc(*line_length);
memset(field, 0, *line_length);
register unsigned int field_start = 0U;
register unsigned int field_end = 0U;
register unsigned int char_pos = 0U;
while(char_pos < *line_length)
{
char curr_char = line[char_pos];
if (curr_char == field_term_char)
{
field_end = char_pos;
const char * field_starts_at = line + field_start;
/* Field width must exclude field delimiter characters */
const unsigned int field_width = field_end - field_start;
/* Copy exactly field_width bytes from field_starts_at to field */
memcpy(field, field_starts_at, field_width);
/* This must be a null-terminated character array */
field[field_width] = 0x00;
string field_string_obj = field;
row->push_back(field_string_obj);
/* This is the starting point of the next field */
field_start = char_pos + 1;
} else if (curr_char == line_term_char)
{
field_end = char_pos;
const char * field_starts_at = line + field_start;
/* Field width must exclude line terminating characters */
const unsigned int field_width = field_end - field_start;
/* Copy exactly field_width bytes from field_starts_at to field */
memcpy(field, field_starts_at, field_width);
/* This must be a null-terminated character array */
field[field_width] = 0x00;
string field_string_obj = field;
row->push_back(field_string_obj);
}
/* Move to the next character in the current line */
char_pos++;
}
/* Deallocate memory for field buffer */
CSV_PARSER_FREE_BUFFER_PTR(field);
}
}
void csv_parser::_get_fields_with_enclosure(csv_row_ptr row, const char * line, const unsigned int * line_length)
{
char * field = NULL;
if (*line_length > 0)
{
field = (char *) malloc(*line_length);
memset(field, 0, *line_length);
register unsigned int current_state = 0U;
register unsigned int field_start = 0U;
register unsigned int field_end = 0U;
register unsigned int char_pos = 0U;
while(char_pos < *line_length)
{
char curr_char = line[char_pos];
if (curr_char == enclosed_char)
{
current_state++;
/* Lets find out if the enclosure character encountered is
* a 'real' enclosure character or if it is an embedded character that
* has been escaped within the field.
*/
register char previous_char = 0x00;
if (char_pos > 0U)
{
/* The escaped char will have to be the 2rd or later character. */
previous_char = line[char_pos - 1];
if (previous_char == escaped_char)
{
--current_state;
}
}
if (current_state == 1U && previous_char != escaped_char)
{
/* This marks the beginning of the column */
field_start = char_pos;
} else if (current_state == 2U)
{
/* We have found the end of the current field */
field_end = char_pos;
/* We do not need the enclosure characters */
const char * field_starts_at = line + field_start + 1U;
/* Field width must exclude beginning and ending enclosure characters */
const unsigned int field_width = field_end - field_start - 1U;
/* Copy exactly field_width bytes from field_starts_at to field */
memcpy(field, field_starts_at, field_width);
/* This must be a null-terminated character array */
field[field_width] = 0x00;
string field_string_obj = field;
row->push_back(field_string_obj);
/* Reset the state to zero value for the next field */
current_state = 0U;
}
}
/* Move to the next character in the current line */
char_pos++;
}
/* If no enclosures were found in this line, the entire line becomes the only field. */
if (0 == row->size())
{
string entire_line = line;
row->push_back(entire_line);
} else if (current_state == 1U)
{
/* The beginning enclosure character was found but
* we could not locate the closing enclosure in the current line
* So we need to copy the remainder of the line into the last field.
*/
/* We do not need the starting enclosure character */
const char * field_starts_at = line + field_start + 1U;
/* Field width must exclude beginning characters */
const unsigned int field_width = *line_length - field_start - 1U;
/* Copy exactly field_width bytes from field_starts_at to field */
memcpy(field, field_starts_at, field_width);
/* This must be a null-terminated character array */
field[field_width] = 0x00;
string field_string_obj = field;
row->push_back(field_string_obj);
}
/* Release the buffer for the field */
CSV_PARSER_FREE_BUFFER_PTR(field);
}
}
void csv_parser::_get_fields_with_optional_enclosure(csv_row_ptr row, const char * line, const unsigned int * line_length)
{
char * field = NULL;
/*
* How to extract the fields, when the enclosure char is optional.
*
* This is very similar to parsing the document without enclosure but with the following conditions.
*
* If the beginning char is an enclosure character, adjust the starting position of the string by + 1.
* If the ending char is an enclosure character, adjust the ending position by -1
*/
if (*line_length > 0)
{
field = (char *) malloc(*line_length);
memset(field, 0, *line_length);
register unsigned int field_start = 0U;
register unsigned int field_end = 0U;
register unsigned int char_pos = 0U;
while(char_pos < *line_length)
{
char curr_char = line[char_pos];
if (curr_char == field_term_char)
{
field_end = char_pos;
const char * field_starts_at = line + field_start;
/* Field width must exclude field delimiter characters */
unsigned int field_width = field_end - field_start;
const char line_first_char = field_starts_at[0];
const char line_final_char = field_starts_at[field_width - 1];
/* If the enclosure char is found at either ends of the string */
unsigned int first_adjustment = (line_first_char == enclosed_char) ? 1U : 0U;
unsigned int final_adjustment = (line_final_char == enclosed_char) ? 2U : 0U;
/* We do not want to have any negative or zero field widths */
field_width = (field_width > 2U) ? (field_width - final_adjustment) : field_width;
/* Copy exactly field_width bytes from field_starts_at to field */
memcpy(field, field_starts_at + first_adjustment, field_width);
/* This must be a null-terminated character array */
field[field_width] = 0x00;
string field_string_obj = field;
row->push_back(field_string_obj);
/* This is the starting point of the next field */
field_start = char_pos + 1;
} else if (curr_char == line_term_char)
{
field_end = char_pos;
const char * field_starts_at = line + field_start;
/* Field width must exclude line terminating characters */
unsigned int field_width = field_end - field_start;
const char line_first_char = field_starts_at[0];
const char line_final_char = field_starts_at[field_width - 1];
/* If the enclosure char is found at either ends of the string */
unsigned int first_adjustment = (line_first_char == enclosed_char) ? 1U : 0U;
unsigned int final_adjustment = (line_final_char == enclosed_char) ? 2U : 0U;
/* We do not want to have any negative or zero field widths */
field_width = (field_width > 2U) ? (field_width - final_adjustment) : field_width;
/* Copy exactly field_width bytes from field_starts_at to field */
memcpy(field, field_starts_at + first_adjustment, field_width);
/* This must be a null-terminated character array */
field[field_width] = 0x00;
string field_string_obj = field;
row->push_back(field_string_obj);
}
/* Move to the next character in the current line */
char_pos++;
}
/* Deallocate memory for field buffer */
CSV_PARSER_FREE_BUFFER_PTR(field);
}
}
void csv_parser::_read_single_line(char ** buffer, unsigned int * buffer_len)
{
long int original_pos = ftell(input_fp);
long int current_pos = original_pos;
register int current_char = 0;
/* Checking one character at a time until the end of a line is found */
while(true)
{
current_char = fgetc(input_fp);
if (current_char == EOF)
{
/* We have reached the end of the file */
more_rows = false;
break;
} else if (current_char == line_term_char)
{
/* We have reached the end of the row */
current_pos++;
break;
} else {
current_pos++;
}
}
/* Let's try to peek one character ahead to see if we are at the end of the file */
if (more_rows)
{
current_char = fgetc(input_fp);
more_rows = (current_char == EOF) ? false : true;
}
/* Find out how long this row is */
const size_t length_of_row = current_pos - original_pos;
if (length_of_row > 0)
{
*buffer_len = length_of_row * sizeof(char) + 1;
*buffer = (char *) realloc(*buffer, *buffer_len);
memset(*buffer, 0, *buffer_len);
/* Reset the internal pointer to the original position */
fseek(input_fp, original_pos, SEEK_SET);
/* Copy the contents of the line into the buffer */
fread(*buffer, 1, length_of_row, input_fp);
}
}