Merge branch 'jh/sparse-index-expand-to-path-fix'

[thirdparty/git.git] / csum-file.c

/*
 * csum-file.c
 *
 * Copyright (C) 2005 Linus Torvalds
 *
 * Simple file write infrastructure for writing SHA1-summed
 * files. Useful when you write a file that you want to be
 * able to verify hasn't been messed with afterwards.
 */
#include "git-compat-util.h"
#include "progress.h"
#include "csum-file.h"
#include "hash.h"

static void verify_buffer_or_die(struct hashfile *f,
                                 const void *buf,
                                 unsigned int count)
{
        ssize_t ret = read_in_full(f->check_fd, f->check_buffer, count);

        if (ret < 0)
                die_errno("%s: sha1 file read error", f->name);
        if (ret != count)
                die("%s: sha1 file truncated", f->name);
        if (memcmp(buf, f->check_buffer, count))
                die("sha1 file '%s' validation error", f->name);
}

static void flush(struct hashfile *f, const void *buf, unsigned int count)
{
        if (0 <= f->check_fd && count)
                verify_buffer_or_die(f, buf, count);

        if (write_in_full(f->fd, buf, count) < 0) {
                if (errno == ENOSPC)
                        die("sha1 file '%s' write error. Out of diskspace", f->name);
                die_errno("sha1 file '%s' write error", f->name);
        }

        f->total += count;
        display_throughput(f->tp, f->total);
}

void hashflush(struct hashfile *f)
{
        unsigned offset = f->offset;

        if (offset) {
                if (!f->skip_hash)
                        the_hash_algo->update_fn(&f->ctx, f->buffer, offset);
                flush(f, f->buffer, offset);
                f->offset = 0;
        }
}

static void free_hashfile(struct hashfile *f)
{
        free(f->buffer);
        free(f->check_buffer);
        free(f);
}

int finalize_hashfile(struct hashfile *f, unsigned char *result,
                      enum fsync_component component, unsigned int flags)
{
        int fd;

        hashflush(f);

        if (f->skip_hash)
                hashclr(f->buffer);
        else
                the_hash_algo->final_fn(f->buffer, &f->ctx);

        if (result)
                hashcpy(result, f->buffer);
        if (flags & CSUM_HASH_IN_STREAM)
                flush(f, f->buffer, the_hash_algo->rawsz);
        if (flags & CSUM_FSYNC)
                fsync_component_or_die(component, f->fd, f->name);
        if (flags & CSUM_CLOSE) {
                if (close(f->fd))
                        die_errno("%s: sha1 file error on close", f->name);
                fd = 0;
        } else
                fd = f->fd;
        if (0 <= f->check_fd) {
                char discard;
                int cnt = read_in_full(f->check_fd, &discard, 1);
                if (cnt < 0)
                        die_errno("%s: error when reading the tail of sha1 file",
                                  f->name);
                if (cnt)
                        die("%s: sha1 file has trailing garbage", f->name);
                if (close(f->check_fd))
                        die_errno("%s: sha1 file error on close", f->name);
        }
        free_hashfile(f);
        return fd;
}

void hashwrite(struct hashfile *f, const void *buf, unsigned int count)
{
        while (count) {
                unsigned left = f->buffer_len - f->offset;
                unsigned nr = count > left ? left : count;

                if (f->do_crc)
                        f->crc32 = crc32(f->crc32, buf, nr);

                if (nr == f->buffer_len) {
                        /*
                         * Flush a full batch worth of data directly
                         * from the input, skipping the memcpy() to
                         * the hashfile's buffer. In this block,
                         * f->offset is necessarily zero.
                         */
                        if (!f->skip_hash)
                                the_hash_algo->update_fn(&f->ctx, buf, nr);
                        flush(f, buf, nr);
                } else {
                        /*
                         * Copy to the hashfile's buffer, flushing only
                         * if it became full.
                         */
                        memcpy(f->buffer + f->offset, buf, nr);
                        f->offset += nr;
                        left -= nr;
                        if (!left)
                                hashflush(f);
                }

                count -= nr;
                buf = (char *) buf + nr;
        }
}

struct hashfile *hashfd_check(const char *name)
{
        int sink, check;
        struct hashfile *f;

        sink = xopen("/dev/null", O_WRONLY);
        check = xopen(name, O_RDONLY);
        f = hashfd(sink, name);
        f->check_fd = check;
        f->check_buffer = xmalloc(f->buffer_len);

        return f;
}

static struct hashfile *hashfd_internal(int fd, const char *name,
                                        struct progress *tp,
                                        size_t buffer_len)
{
        struct hashfile *f = xmalloc(sizeof(*f));
        f->fd = fd;
        f->check_fd = -1;
        f->offset = 0;
        f->total = 0;
        f->tp = tp;
        f->name = name;
        f->do_crc = 0;
        f->skip_hash = 0;
        the_hash_algo->init_fn(&f->ctx);

        f->buffer_len = buffer_len;
        f->buffer = xmalloc(buffer_len);
        f->check_buffer = NULL;

        return f;
}

struct hashfile *hashfd(int fd, const char *name)
{
        /*
         * Since we are not going to use a progress meter to
         * measure the rate of data passing through this hashfile,
         * use a larger buffer size to reduce fsync() calls.
         */
        return hashfd_internal(fd, name, NULL, 128 * 1024);
}

struct hashfile *hashfd_throughput(int fd, const char *name, struct progress *tp)
{
        /*
         * Since we are expecting to report progress of the
         * write into this hashfile, use a smaller buffer
         * size so the progress indicators arrive at a more
         * frequent rate.
         */
        return hashfd_internal(fd, name, tp, 8 * 1024);
}

void hashfile_checkpoint(struct hashfile *f, struct hashfile_checkpoint *checkpoint)
{
        hashflush(f);
        checkpoint->offset = f->total;
        the_hash_algo->clone_fn(&checkpoint->ctx, &f->ctx);
}

int hashfile_truncate(struct hashfile *f, struct hashfile_checkpoint *checkpoint)
{
        off_t offset = checkpoint->offset;

        if (ftruncate(f->fd, offset) ||
            lseek(f->fd, offset, SEEK_SET) != offset)
                return -1;
        f->total = offset;
        the_hash_algo->clone_fn(&f->ctx, &checkpoint->ctx);
        f->offset = 0; /* hashflush() was called in checkpoint */
        return 0;
}

void crc32_begin(struct hashfile *f)
{
        f->crc32 = crc32(0, NULL, 0);
        f->do_crc = 1;
}

uint32_t crc32_end(struct hashfile *f)
{
        f->do_crc = 0;
        return f->crc32;
}

int hashfile_checksum_valid(const unsigned char *data, size_t total_len)
{
        unsigned char got[GIT_MAX_RAWSZ];
        git_hash_ctx ctx;
        size_t data_len = total_len - the_hash_algo->rawsz;

        if (total_len < the_hash_algo->rawsz)
                return 0; /* say "too short"? */

        the_hash_algo->init_fn(&ctx);
        the_hash_algo->update_fn(&ctx, data, data_len);
        the_hash_algo->final_fn(got, &ctx);

        return hasheq(got, data + data_len);
}