bp/files.c

//
// files.c - Implementation of some file loading functionality.
//

#include <ctype.h>
#include <err.h>
#include <fcntl.h>
#include <limits.h>
#include <stdarg.h>
#include <stdlib.h>
#include <string.h>
#include <sys/mman.h>
#include <sys/stat.h>
#include <unistd.h>

#include "files.h"
#include "pattern.h"
#include "utils.h"

__attribute__((nonnull))
static void populate_lines(file_t *f, size_t len);
__attribute__((pure, nonnull))
static size_t get_char_number(file_t *f, const char *p);

//
// In the file object, populate the `lines` array with pointers to the
// beginning of each line.
//
static void populate_lines(file_t *f, size_t len)
{
    // Calculate line numbers:
    size_t linecap = 10;
    f->lines = xcalloc(sizeof(const char*), linecap);
    f->nlines = 0;
    char *p = f->memory;
    for (size_t n = 0; p && p < &f->memory[len]; ++n) {
        ++f->nlines;
        if (n >= linecap)
            f->lines = xrealloc(f->lines, sizeof(const char*)*(linecap *= 2));
        f->lines[n] = p;
        p = strchr(p, '\n');
        if (p) ++p;
    }
}

//
// Read an entire file into memory, using a printf-style formatting string to
// construct the filename.
//
file_t *load_filef(file_t **files, const char *fmt, ...)
{
    char filename[PATH_MAX+1] = {'\0'};
    va_list args;
    va_start(args, fmt);
    if (vsnprintf(filename, PATH_MAX, fmt, args) > (int)PATH_MAX)
        errx(EXIT_FAILURE, "File name is too large");
    va_end(args);
    return load_file(files, filename);
}

//
// Read an entire file into memory.
//
file_t *load_file(file_t **files, const char *filename)
{
    int fd = filename[0] == '\0' ? STDIN_FILENO : open(filename, O_RDONLY);
    if (fd < 0) {
        // Check for <file>:<line>
        if (strrchr(filename, ':')) {
            char tmp[PATH_MAX] = {0};
            strcpy(tmp, filename);
            char *colon = strrchr(tmp, ':');
            *colon = '\0';
            file_t *f = load_file(files, tmp);
            if (!f) return f;
            long line = strtol(colon+1, &colon, 10);
            f->start = (char*)get_line(f, (size_t)line);
            f->end = (char*)get_line(f, (size_t)line+1);
            return f;
        }
        return NULL;
    }
    size_t length;
    file_t *f = new(file_t);
    f->filename = memcheck(strdup(filename));

    struct stat sb;
    if (fstat(fd, &sb) == -1)
        goto skip_mmap;

    f->memory = mmap(NULL, (size_t)sb.st_size, PROT_READ, MAP_PRIVATE, fd, 0);
    if (f->memory == MAP_FAILED)
        goto skip_mmap;

    f->mmapped = true;
    length = (size_t)sb.st_size;
    goto finished_loading;

  skip_mmap:
    f->mmapped = false;
    size_t capacity = 1000;
    length = 0;
    f->memory = xcalloc(sizeof(char), capacity);
    ssize_t just_read;
    while ((just_read=read(fd, &f->memory[length], capacity - length)) > 0) {
        length += (size_t)just_read;
        if (length >= capacity)
            f->memory = xrealloc(f->memory, sizeof(char)*(capacity *= 2) + 1);
    }

  finished_loading:
    if (fd != STDIN_FILENO) {
        if (close(fd) != 0)
            err(EXIT_FAILURE, "Failed to close file");
    }
    f->start = &f->memory[0];
    f->end = &f->memory[length];
    populate_lines(f, length);
    if (files != NULL) {
        f->next = *files;
        *files = f;
    }
    return f;
}

//
// Set a file struct to represent a region of a different file.
//
void slice_file(file_t *slice, file_t *src, const char *start, const char *end)
{
    memcpy(slice, src, sizeof(file_t));
    slice->start = (char*)start;
    slice->end = (char*)end;
}

//
// Create a virtual file from a string.
//
file_t *spoof_file(file_t **files, const char *filename, const char *text, ssize_t _len)
{
    if (filename == NULL) filename = "";
    file_t *f = new(file_t);
    size_t len = _len == -1 ? strlen(text) : (size_t)_len;
    f->filename = memcheck(strdup(filename));
    f->memory = xcalloc(len+1, sizeof(char));
    memcpy(f->memory, text, len);
    f->start = &f->memory[0];
    f->end = &f->memory[len];
    populate_lines(f, len);
    if (files != NULL) {
        f->next = *files;
        *files = f;
    }
    return f;
}

//
// Free a file and all memory contained inside its members, then set the input
// pointer to NULL.
//
void destroy_file(file_t **f)
{
    if ((*f)->filename) {
        xfree(&((*f)->filename));
    }

    if ((*f)->lines) {
        xfree(&((*f)->lines));
    }

    if ((*f)->memory) {
        if ((*f)->mmapped) {
            if (munmap((*f)->memory, (size_t)((*f)->end - (*f)->memory)) != 0)
                err(EXIT_FAILURE, "Failure to un-memory-map some memory");
            (*f)->memory = NULL;
        } else {
            xfree(&((*f)->memory));
        }
    }

    for (allocated_pat_t *next; (*f)->pats; (*f)->pats = next) {
        next = (*f)->pats->next;
        xfree(&(*f)->pats);
    }

    xfree(f);
}

//
// Given a pointer, determine which line number it points to.
//
size_t get_line_number(file_t *f, const char *p)
{
    if (f->nlines == 0) return 0;
    // Binary search:
    size_t lo = 0, hi = f->nlines-1;
    while (lo <= hi) {
        size_t mid = (lo + hi) / 2;
        if (f->lines[mid] == p)
            return mid + 1;
        else if (f->lines[mid] < p)
            lo = mid + 1;    
        else if (f->lines[mid] > p)
            hi = mid - 1;
    }
    return lo; // Return the line number whose line starts closest before p
}

//
// Given a pointer, determine which character offset within the line it points to.
//
static size_t get_char_number(file_t *f, const char *p)
{
    size_t linenum = get_line_number(f, p);
    return 1 + (size_t)(p - f->lines[linenum-1]);
}

//
// Return a pointer to the line with the specified line number.
//
const char *get_line(file_t *f, size_t line_number)
{
    if (line_number == 0 || line_number > f->nlines) return NULL;
    return f->lines[line_number - 1];
}

//
// Print the filename/line number, followed by the given message, followed by
// the line itself.
//
void fprint_line(FILE *dest, file_t *f, const char *start, const char *end, const char *fmt, ...)
{
    if (start < f->memory) start = f->memory;
    if (start > f->end) start = f->end;
    if (end < f->memory) end = f->memory;
    if (end > f->end) end = f->end;
    size_t linenum = get_line_number(f, start);
    const char *line = get_line(f, linenum);
    size_t charnum = get_char_number(f, start);
    fprintf(dest, "\033[1m%s:%lu:\033[0m ", f->filename[0] ? f->filename : "stdin", linenum);

    va_list args;
    va_start(args, fmt);
    (void)vfprintf(dest, fmt, args);
    va_end(args);
    (void)fputc('\n', dest);

    const char *eol = linenum == f->nlines ? strchr(line, '\0') : strchr(line, '\n');
    if (end == NULL || end > eol) end = eol;
    fprintf(dest, "\033[2m%5lu\033(0\x78\033(B\033[0m%.*s\033[41;30m%.*s\033[0m%.*s\n",
            linenum,
            (int)charnum - 1, line,
            (int)(end - &line[charnum-1]), &line[charnum-1],
            (int)(eol - end), end);
    fprintf(dest, "      \033[34;1m");
    const char *p = line;
    for (; p < start; ++p) (void)fputc(*p == '\t' ? '\t' : ' ', dest);
    if (start == end) ++end;
    for (; p < end; ++p)
        if (*p == '\t')
            // Some janky hacks: 8 ^'s, backtrack 8 spaces, move forward a tab stop, clear any ^'s that overshot
            fprintf(dest, "^^^^^^^^\033[8D\033[I\033[K");
        else
            (void)fputc('^', dest);
    fprintf(dest, "\033[0m\n");
}

// vim: ts=4 sw=0 et cino=L2,l1,(0,W4,m1