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kurl.c
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kurl.c
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#include <stdio.h>
#include <fcntl.h>
#include <ctype.h>
#include <assert.h>
#include <stdint.h>
#include <stdlib.h>
#include <unistd.h>
#include <string.h>
#include <curl/curl.h>
#include "kurl.h"
/**********************
*** Core kurl APIs ***
**********************/
#define KU_DEF_BUFLEN 0x8000
#define KU_MAX_SKIP (KU_DEF_BUFLEN<<1) // if seek step is smaller than this, skip
#define kurl_isfile(u) ((u)->fd >= 0)
#ifndef kroundup32
#define kroundup32(x) (--(x), (x)|=(x)>>1, (x)|=(x)>>2, (x)|=(x)>>4, (x)|=(x)>>8, (x)|=(x)>>16, ++(x))
#endif
struct kurl_t {
CURLM *multi; // cURL multi handler
CURL *curl; // cURL easy handle
uint8_t *buf; // buffer
off_t off0; // offset of the first byte in the buffer; the actual file offset equals off0 + p_buf
int fd; // file descriptor for a normal file; <0 for a remote file
int m_buf; // max buffer size; for a remote file, CURL_MAX_WRITE_SIZE*2 is recommended
int l_buf; // length of the buffer; l_buf == 0 iff the input read entirely; l_buf <= m_buf
int p_buf; // file position in the buffer; p_buf <= l_buf
int done_reading; // true if we can read nothing from the file; buffer may not be empty even if done_reading is set
int err; // error code
struct curl_slist *hdr;
};
typedef struct {
char *url, *date, *auth;
} s3aux_t;
int kurl_init(void) // required for SSL and win32 socket; NOT thread safe
{
return curl_global_init(CURL_GLOBAL_DEFAULT);
}
void kurl_destroy(void)
{
curl_global_cleanup();
}
static int prepare(kurl_t *ku, int do_seek)
{
if (kurl_isfile(ku)) {
if (do_seek && lseek(ku->fd, ku->off0, SEEK_SET) != ku->off0)
return -1;
} else { // FIXME: for S3, we need to re-authorize
int rc;
rc = curl_multi_remove_handle(ku->multi, ku->curl);
rc = curl_easy_setopt(ku->curl, CURLOPT_RESUME_FROM, ku->off0);
rc = curl_multi_add_handle(ku->multi, ku->curl);
}
ku->p_buf = ku->l_buf = 0; // empty the buffer
return 0;
}
static size_t write_cb(char *ptr, size_t size, size_t nmemb, void *data) // callback required by cURL
{
kurl_t *ku = (kurl_t*)data;
ssize_t nbytes = size * nmemb;
if (nbytes + ku->l_buf > ku->m_buf)
return CURL_WRITEFUNC_PAUSE;
memcpy(ku->buf + ku->l_buf, ptr, nbytes);
ku->l_buf += nbytes;
return nbytes;
}
static int fill_buffer(kurl_t *ku) // fill the buffer
{
assert(ku->p_buf == ku->l_buf); // buffer is always used up when fill_buffer() is called; otherwise a bug
ku->off0 += ku->l_buf;
ku->p_buf = ku->l_buf = 0;
if (ku->done_reading) return 0;
if (kurl_isfile(ku)) {
// The following block is equivalent to "ku->l_buf = read(ku->fd, ku->buf, ku->m_buf)" on Mac.
// On Linux, the man page does not specify whether read() guarantees to read ku->m_buf bytes
// even if ->fd references a normal file with sufficient remaining bytes.
while (ku->l_buf < ku->m_buf) {
int l;
l = read(ku->fd, ku->buf + ku->l_buf, ku->m_buf - ku->l_buf);
if (l == 0) break;
ku->l_buf += l;
}
if (ku->l_buf < ku->m_buf) ku->done_reading = 1;
} else {
int n_running, rc;
fd_set fdr, fdw, fde;
do {
int maxfd = -1;
long curl_to = -1;
struct timeval to;
// the following is adaped from docs/examples/fopen.c
to.tv_sec = 10, to.tv_usec = 0; // 10 seconds
curl_multi_timeout(ku->multi, &curl_to);
if (curl_to >= 0) {
to.tv_sec = curl_to / 1000;
if (to.tv_sec > 1) to.tv_sec = 1;
else to.tv_usec = (curl_to % 1000) * 1000;
}
FD_ZERO(&fdr); FD_ZERO(&fdw); FD_ZERO(&fde);
curl_multi_fdset(ku->multi, &fdr, &fdw, &fde, &maxfd); // FIXME: check return code
if (maxfd >= 0 && (rc = select(maxfd+1, &fdr, &fdw, &fde, &to)) < 0) break;
if (maxfd < 0) { // check curl_multi_fdset.3 about why we wait for 100ms here
struct timespec req, rem;
req.tv_sec = 0; req.tv_nsec = 100000000; // this is 100ms
nanosleep(&req, &rem);
}
curl_easy_pause(ku->curl, CURLPAUSE_CONT);
rc = curl_multi_perform(ku->multi, &n_running); // FIXME: check return code
} while (n_running && ku->l_buf < ku->m_buf - CURL_MAX_WRITE_SIZE);
if (ku->l_buf < ku->m_buf - CURL_MAX_WRITE_SIZE) ku->done_reading = 1;
}
return ku->l_buf;
}
int kurl_close(kurl_t *ku)
{
if (ku == 0) return 0;
if (ku->fd < 0) {
curl_multi_remove_handle(ku->multi, ku->curl);
curl_easy_cleanup(ku->curl);
curl_multi_cleanup(ku->multi);
if (ku->hdr) curl_slist_free_all(ku->hdr);
} else close(ku->fd);
free(ku->buf);
free(ku);
return 0;
}
kurl_t *kurl_open(const char *url, kurl_opt_t *opt)
{
extern s3aux_t s3_parse(const char *url, const char *_id, const char *_secret, const char *fn);
const char *p, *q;
kurl_t *ku;
int fd = -1, is_file = 1, failed = 0;
p = strstr(url, "://");
if (p && *p) {
for (q = url; q != p; ++q)
if (!isalnum(*q)) break;
if (q == p) is_file = 0;
}
if (is_file && (fd = open(url, O_RDONLY)) < 0) return 0;
ku = (kurl_t*)calloc(1, sizeof(kurl_t));
ku->fd = is_file? fd : -1;
if (!kurl_isfile(ku)) {
ku->multi = curl_multi_init();
ku->curl = curl_easy_init();
if (strstr(url, "s3://") == url) {
s3aux_t a;
a = s3_parse(url, (opt? opt->s3keyid : 0), (opt? opt->s3secretkey : 0), (opt? opt->s3key_fn : 0));
if (a.url == 0 || a.date == 0 || a.auth == 0) {
kurl_close(ku);
return 0;
}
ku->hdr = curl_slist_append(ku->hdr, a.date);
ku->hdr = curl_slist_append(ku->hdr, a.auth);
curl_easy_setopt(ku->curl, CURLOPT_URL, a.url);
curl_easy_setopt(ku->curl, CURLOPT_HTTPHEADER, ku->hdr);
free(a.date); free(a.auth); free(a.url);
} else curl_easy_setopt(ku->curl, CURLOPT_URL, url);
curl_easy_setopt(ku->curl, CURLOPT_WRITEDATA, ku);
curl_easy_setopt(ku->curl, CURLOPT_VERBOSE, 0L);
curl_easy_setopt(ku->curl, CURLOPT_NOSIGNAL, 1L);
curl_easy_setopt(ku->curl, CURLOPT_WRITEFUNCTION, write_cb);
curl_easy_setopt(ku->curl, CURLOPT_SSL_VERIFYPEER, 0L);
curl_easy_setopt(ku->curl, CURLOPT_SSL_VERIFYHOST, 0L);
curl_easy_setopt(ku->curl, CURLOPT_FOLLOWLOCATION, 1L);
}
ku->m_buf = KU_DEF_BUFLEN;
if (!kurl_isfile(ku) && ku->m_buf < CURL_MAX_WRITE_SIZE * 2)
ku->m_buf = CURL_MAX_WRITE_SIZE * 2; // for remote files, the buffer set to 2*CURL_MAX_WRITE_SIZE
ku->buf = (uint8_t*)calloc(ku->m_buf, 1);
if (kurl_isfile(ku)) failed = (fill_buffer(ku) <= 0);
else failed = (prepare(ku, 0) < 0 || fill_buffer(ku) <= 0);
if (failed) {
kurl_close(ku);
return 0;
}
return ku;
}
kurl_t *kurl_dopen(int fd)
{
kurl_t *ku;
ku = (kurl_t*)calloc(1, sizeof(kurl_t));
ku->fd = fd;
ku->m_buf = KU_DEF_BUFLEN;
ku->buf = (uint8_t*)calloc(ku->m_buf, 1);
if (prepare(ku, 0) < 0 || fill_buffer(ku) <= 0) {
kurl_close(ku);
return 0;
}
return ku;
}
int kurl_buflen(kurl_t *ku, int len)
{
if (len <= 0 || len < ku->l_buf) return ku->m_buf;
if (!kurl_isfile(ku) && len < CURL_MAX_WRITE_SIZE * 2) return ku->m_buf;
ku->m_buf = len;
kroundup32(ku->m_buf);
ku->buf = (uint8_t*)realloc(ku->buf, ku->m_buf);
return ku->m_buf;
}
ssize_t kurl_read(kurl_t *ku, void *buf, size_t nbytes)
{
ssize_t rest = nbytes;
if (ku->l_buf == 0) return 0; // end-of-file
while (rest) {
if (ku->l_buf - ku->p_buf >= rest) {
if (buf) memcpy((uint8_t*)buf + (nbytes - rest), ku->buf + ku->p_buf, rest);
ku->p_buf += rest;
rest = 0;
} else {
int ret;
if (buf && ku->l_buf > ku->p_buf)
memcpy((uint8_t*)buf + (nbytes - rest), ku->buf + ku->p_buf, ku->l_buf - ku->p_buf);
rest -= ku->l_buf - ku->p_buf;
ku->p_buf = ku->l_buf;
ret = fill_buffer(ku);
if (ret <= 0) break;
}
}
return nbytes - rest;
}
off_t kurl_seek(kurl_t *ku, off_t offset, int whence) // FIXME: sometimes when seek() fails, read() will fail as well.
{
off_t new_off = -1, cur_off;
int failed = 0, seek_end = 0;
if (ku == 0) return -1;
cur_off = ku->off0 + ku->p_buf;
if (whence == SEEK_SET) new_off = offset;
else if (whence == SEEK_CUR) new_off += cur_off + offset;
else if (whence == SEEK_END && kurl_isfile(ku)) new_off = lseek(ku->fd, offset, SEEK_END), seek_end = 1;
else { // not supported whence
ku->err = KURL_INV_WHENCE;
return -1;
}
if (new_off < 0) { // negtive absolute offset
ku->err = KURL_SEEK_OUT;
return -1;
}
if (!seek_end && new_off >= cur_off && new_off - cur_off + ku->p_buf < ku->l_buf) {
ku->p_buf += new_off - cur_off;
return ku->off0 + ku->p_buf;
}
if (seek_end || new_off < cur_off || new_off - cur_off > KU_MAX_SKIP) { // if jump is large, do actual seek
ku->off0 = new_off;
ku->done_reading = 0;
if (prepare(ku, 1) < 0 || fill_buffer(ku) <= 0) failed = 1;
} else { // if jump is small, read through
off_t r;
r = kurl_read(ku, 0, new_off - cur_off);
if (r + cur_off != new_off) failed = 1; // out of range
}
if (failed) ku->err = KURL_SEEK_OUT, ku->l_buf = ku->p_buf = 0, new_off = -1;
return new_off;
}
off_t kurl_tell(const kurl_t *ku)
{
if (ku == 0) return -1;
return ku->off0 + ku->p_buf;
}
int kurl_eof(const kurl_t *ku)
{
if (ku == 0) return 1;
return (ku->l_buf == 0); // unless file end, buffer should never be empty
}
int kurl_fileno(const kurl_t *ku)
{
if (ku == 0) return -1;
return ku->fd;
}
int kurl_error(const kurl_t *ku)
{
if (ku == 0) return KURL_NULL;
return ku->err;
}
/*****************
*** HMAC-SHA1 ***
*****************/
/* This code is public-domain - it is based on libcrypt placed in the public domain by Wei Dai and other contributors. */
#define HASH_LENGTH 20
#define BLOCK_LENGTH 64
typedef struct sha1nfo {
union { uint8_t b[BLOCK_LENGTH]; uint32_t w[BLOCK_LENGTH/4]; } buf;
uint8_t bufOffset;
union { uint8_t b[HASH_LENGTH]; uint32_t w[HASH_LENGTH/4]; } state;
uint32_t byteCount;
uint8_t keyBuffer[BLOCK_LENGTH];
uint8_t innerHash[HASH_LENGTH];
} sha1nfo;
void sha1_init(sha1nfo *s)
{
const uint8_t table[] = { 0x01,0x23,0x45,0x67, 0x89,0xab,0xcd,0xef, 0xfe,0xdc,0xba,0x98, 0x76,0x54,0x32,0x10, 0xf0,0xe1,0xd2,0xc3 };
memcpy(s->state.b, table, HASH_LENGTH);
s->byteCount = 0;
s->bufOffset = 0;
}
#define rol32(value, bits) (((value) << (bits)) | ((value) >> (32 - (bits))))
static void sha1_hashBlock(sha1nfo *s)
{
uint32_t i, t, a = s->state.w[0], b = s->state.w[1], c = s->state.w[2], d = s->state.w[3], e = s->state.w[4];
for (i = 0; i < 80; i++) {
if (i >= 16) {
t = s->buf.w[(i+13)&15] ^ s->buf.w[(i+8)&15] ^ s->buf.w[(i+2)&15] ^ s->buf.w[i&15];
s->buf.w[i&15] = rol32(t, 1);
}
if (i < 20) t = 0x5a827999 + (d ^ (b & (c ^ d)));
else if (i < 40) t = 0x6ed9eba1 + (b ^ c ^ d);
else if (i < 60) t = 0x8f1bbcdc + ((b & c) | (d & (b | c)));
else t = 0xca62c1d6 + (b ^ c ^ d);
t += rol32(a, 5) + e + s->buf.w[i&15];
e = d; d = c; c = rol32(b, 30); b = a; a = t;
}
s->state.w[0] += a; s->state.w[1] += b; s->state.w[2] += c; s->state.w[3] += d; s->state.w[4] += e;
}
static inline void sha1_add(sha1nfo *s, uint8_t data)
{
s->buf.b[s->bufOffset ^ 3] = data;
if (++s->bufOffset == BLOCK_LENGTH) {
sha1_hashBlock(s);
s->bufOffset = 0;
}
}
void sha1_write1(sha1nfo *s, uint8_t data)
{
++s->byteCount;
sha1_add(s, data);
}
void sha1_write(sha1nfo *s, const char *data, size_t len)
{
while (len--) sha1_write1(s, (uint8_t)*data++);
}
const uint8_t *sha1_final(sha1nfo *s)
{
int i;
sha1_add(s, 0x80);
while (s->bufOffset != 56) sha1_add(s, 0);
sha1_add(s, 0);
sha1_add(s, 0);
sha1_add(s, 0);
sha1_add(s, s->byteCount >> 29);
sha1_add(s, s->byteCount >> 21);
sha1_add(s, s->byteCount >> 13);
sha1_add(s, s->byteCount >> 5);
sha1_add(s, s->byteCount << 3);
for (i = 0; i < 5; ++i) {
uint32_t a = s->state.w[i];
s->state.w[i] = a<<24 | (a<<8&0x00ff0000) | (a>>8&0x0000ff00) | a>>24;
}
return s->state.b;
}
#define HMAC_IPAD 0x36
#define HMAC_OPAD 0x5c
void sha1_init_hmac(sha1nfo *s, const uint8_t* key, int l_key)
{
uint8_t i;
memset(s->keyBuffer, 0, BLOCK_LENGTH);
if (l_key > BLOCK_LENGTH) {
sha1_init(s);
while (l_key--) sha1_write1(s, *key++);
memcpy(s->keyBuffer, sha1_final(s), HASH_LENGTH);
} else memcpy(s->keyBuffer, key, l_key);
sha1_init(s);
for (i = 0; i < BLOCK_LENGTH; ++i)
sha1_write1(s, s->keyBuffer[i] ^ HMAC_IPAD);
}
const uint8_t *sha1_final_hmac(sha1nfo *s)
{
uint8_t i;
memcpy(s->innerHash, sha1_final(s), HASH_LENGTH);
sha1_init(s);
for (i = 0; i < BLOCK_LENGTH; ++i) sha1_write1(s, s->keyBuffer[i] ^ HMAC_OPAD);
for (i = 0; i < HASH_LENGTH; ++i) sha1_write1(s, s->innerHash[i]);
return sha1_final(s);
}
/*******************
*** S3 protocol ***
*******************/
#include <time.h>
#include <ctype.h>
static void s3_sign(const char *key, const char *data, char out[29])
{
const char *b64tab = "ABCDEFGHIJKLMNOPQRSTUVWXYZabcdefghijklmnopqrstuvwxyz0123456789+/";
const uint8_t *digest;
int i, j, rest;
sha1nfo s;
sha1_init_hmac(&s, (uint8_t*)key, strlen(key));
sha1_write(&s, data, strlen(data));
digest = sha1_final_hmac(&s);
for (j = i = 0, rest = 8; i < 20; ++j) { // base64 encoding
if (rest <= 6) {
int next = i < 19? digest[i+1] : 0;
out[j] = b64tab[(int)(digest[i] << (6-rest) & 0x3f) | next >> (rest+2)], ++i, rest += 2;
} else out[j] = b64tab[(int)digest[i] >> (rest-6) & 0x3f], rest -= 6;
}
out[j++] = '='; out[j] = 0; // SHA1 digest always has 160 bits, or 20 bytes. We need one '=' at the end.
}
static char *s3_read_awssecret(const char *fn)
{
char *p, *secret, buf[128], *path;
FILE *fp;
int l;
if (fn == 0) {
char *home;
home = getenv("HOME");
if (home == 0) return 0;
l = strlen(home) + 12;
path = (char*)malloc(strlen(home) + 12);
strcat(strcpy(path, home), "/.awssecret");
} else path = (char*)fn;
fp = fopen(path, "r");
if (path != fn) free(path);
if (fp == 0) return 0;
l = fread(buf, 1, 127, fp);
fclose(fp);
buf[l] = 0;
for (p = buf; *p != 0 && *p != '\n'; ++p);
if (*p == 0) return 0;
*p = 0; secret = p + 1;
for (++p; *p != 0 && *p != '\n'; ++p);
*p = 0;
l = p - buf + 1;
p = (char*)malloc(l);
memcpy(p, buf, l);
return p;
}
typedef struct { int l, m; char *s; } kstring_t;
static inline int kputsn(const char *p, int l, kstring_t *s)
{
if (s->l + l + 1 >= s->m) {
s->m = s->l + l + 2;
kroundup32(s->m);
s->s = (char*)realloc(s->s, s->m);
}
memcpy(s->s + s->l, p, l);
s->l += l;
s->s[s->l] = 0;
return l;
}
s3aux_t s3_parse(const char *url, const char *_id, const char *_secret, const char *fn_secret)
{
const char *id, *secret, *bucket, *obj;
char *id_secret = 0, date[64], sig[29];
time_t t;
struct tm tmt;
s3aux_t a = {0,0};
kstring_t str = {0,0,0};
// parse URL
if (strstr(url, "s3://") != url) return a;
bucket = url + 5;
for (obj = bucket; *obj && *obj != '/'; ++obj);
if (*obj == 0) return a; // no object
// acquire AWS credential and time
if (_id == 0 || _secret == 0) {
id_secret = s3_read_awssecret(fn_secret);
if (id_secret == 0) return a; // fail to read the AWS credential
id = id_secret;
secret = id_secret + strlen(id) + 1;
} else id = _id, secret = _secret;
// compose URL for curl
kputsn("https://", 8, &str);
kputsn(bucket, obj - bucket, &str);
kputsn(".s3.amazonaws.com", 17, &str);
kputsn(obj, strlen(obj), &str);
a.url = str.s;
// compose the Date line
str.l = str.m = 0; str.s = 0;
t = time(0);
strftime(date, 64, "%a, %d %b %Y %H:%M:%S +0000", gmtime_r(&t, &tmt));
kputsn("Date: ", 6, &str);
kputsn(date, strlen(date), &str);
a.date = str.s;
// compose the string to sign and sign it
str.l = str.m = 0; str.s = 0;
kputsn("GET\n\n\n", 6, &str);
kputsn(date, strlen(date), &str);
kputsn("\n", 1, &str);
kputsn(bucket-1, strlen(bucket-1), &str);
s3_sign(secret, str.s, sig);
// compose the Authorization line
str.l = 0;
kputsn("Authorization: AWS ", 19, &str);
kputsn(id, strlen(id), &str);
kputsn(":", 1, &str);
kputsn(sig, strlen(sig), &str);
a.auth = str.s;
// printf("curl -H '%s' -H '%s' %s\n", a.date, a.auth, a.url);
return a;
}
/*********************
*** Main function ***
*********************/
#ifdef KURL_MAIN
int main(int argc, char *argv[])
{
kurl_t *f;
int c, l, l_buf = 0x10000;
off_t start = 0, rest = -1;
uint8_t *buf;
char *p;
kurl_opt_t opt;
memset(&opt, 0, sizeof(kurl_opt_t));
while ((c = getopt(argc, argv, "c:l:a:")) >= 0) {
if (c == 'c') start = strtol(optarg, &p, 0);
else if (c == 'l') rest = strtol(optarg, &p, 0);
else if (c == 'a') opt.s3key_fn = optarg;
}
if (optind == argc) {
fprintf(stderr, "Usage: kurl [-c start] [-l length] <url>\n");
return 1;
}
kurl_init();
f = kurl_open(argv[optind], &opt);
if (f == 0) {
fprintf(stderr, "ERROR: fail to open URL\n");
return 2;
}
if (start > 0) {
if (kurl_seek(f, start, SEEK_SET) < 0) {
kurl_close(f);
fprintf(stderr, "ERROR: fail to seek\n");
return 3;
}
}
buf = (uint8_t*)calloc(l_buf, 1);
while (rest != 0) {
int to_read = rest > 0 && rest < l_buf? rest : l_buf;
l = kurl_read(f, buf, to_read);
if (l == 0) break;
fwrite(buf, 1, l, stdout);
rest -= l;
}
free(buf);
kurl_close(f);
kurl_destroy();
return 0;
}
#endif