// Copyright (c) 2008 The Chromium Authors. All rights reserved. // Use of this source code is governed by a BSD-style license that can be // found in the LICENSE file. // Written in NSPR style to also be suitable for adding to the NSS demo suite /* memio is a simple NSPR I/O layer that lets you decouple NSS from * the real network. It's rather like openssl's memory bio, * and is useful when your app absolutely, positively doesn't * want to let NSS do its own networking. */ #include #include #include #include #include #include "nss_memio.h" /*--------------- private memio types -----------------------*/ /*---------------------------------------------------------------------- Simple private circular buffer class. Size cannot be changed once allocated. ----------------------------------------------------------------------*/ struct memio_buffer { int head; /* where to take next byte out of buf */ int tail; /* where to put next byte into buf */ int bufsize; /* number of bytes allocated to buf */ /* TODO(port): error handling is pessimistic right now. * Once an error is set, the socket is considered broken * (PR_WOULD_BLOCK_ERROR not included). */ PRErrorCode last_err; char *buf; }; /* The 'secret' field of a PRFileDesc created by memio_CreateIOLayer points * to one of these. * In the public header, we use struct memio_Private as a typesafe alias * for this. This causes a few ugly typecasts in the private file, but * seems safer. */ struct PRFilePrivate { /* read requests are satisfied from this buffer */ struct memio_buffer readbuf; /* write requests are satisfied from this buffer */ struct memio_buffer writebuf; /* SSL needs to know socket peer's name */ PRNetAddr peername; /* if set, empty I/O returns EOF instead of EWOULDBLOCK */ int eof; /* if set, the number of bytes requested from readbuf that were not * fulfilled (due to readbuf being empty) */ int read_requested; }; /*--------------- private memio_buffer functions ---------------------*/ /* Forward declarations. */ /* Allocate a memio_buffer of given size. */ static void memio_buffer_new(struct memio_buffer *mb, int size); /* Deallocate a memio_buffer allocated by memio_buffer_new. */ static void memio_buffer_destroy(struct memio_buffer *mb); /* How many bytes can be read out of the buffer without wrapping */ static int memio_buffer_used_contiguous(const struct memio_buffer *mb); /* How many bytes exist after the wrap? */ static int memio_buffer_wrapped_bytes(const struct memio_buffer *mb); /* How many bytes can be written into the buffer without wrapping */ static int memio_buffer_unused_contiguous(const struct memio_buffer *mb); /* Write n bytes into the buffer. Returns number of bytes written. */ static int memio_buffer_put(struct memio_buffer *mb, const char *buf, int n); /* Read n bytes from the buffer. Returns number of bytes read. */ static int memio_buffer_get(struct memio_buffer *mb, char *buf, int n); /* Allocate a memio_buffer of given size. */ static void memio_buffer_new(struct memio_buffer *mb, int size) { mb->head = 0; mb->tail = 0; mb->bufsize = size; mb->buf = malloc(size); } /* Deallocate a memio_buffer allocated by memio_buffer_new. */ static void memio_buffer_destroy(struct memio_buffer *mb) { free(mb->buf); mb->buf = NULL; mb->bufsize = 0; mb->head = 0; mb->tail = 0; } /* How many bytes can be read out of the buffer without wrapping */ static int memio_buffer_used_contiguous(const struct memio_buffer *mb) { return (((mb->tail >= mb->head) ? mb->tail : mb->bufsize) - mb->head); } /* How many bytes exist after the wrap? */ static int memio_buffer_wrapped_bytes(const struct memio_buffer *mb) { return (mb->tail >= mb->head) ? 0 : mb->tail; } /* How many bytes can be written into the buffer without wrapping */ static int memio_buffer_unused_contiguous(const struct memio_buffer *mb) { if (mb->head > mb->tail) return mb->head - mb->tail - 1; return mb->bufsize - mb->tail - (mb->head == 0); } /* Write n bytes into the buffer. Returns number of bytes written. */ static int memio_buffer_put(struct memio_buffer *mb, const char *buf, int n) { int len; int transferred = 0; /* Handle part before wrap */ len = PR_MIN(n, memio_buffer_unused_contiguous(mb)); if (len > 0) { /* Buffer not full */ memcpy(&mb->buf[mb->tail], buf, len); mb->tail += len; if (mb->tail == mb->bufsize) mb->tail = 0; n -= len; buf += len; transferred += len; /* Handle part after wrap */ len = PR_MIN(n, memio_buffer_unused_contiguous(mb)); if (len > 0) { /* Output buffer still not full, input buffer still not empty */ memcpy(&mb->buf[mb->tail], buf, len); mb->tail += len; if (mb->tail == mb->bufsize) mb->tail = 0; transferred += len; } } return transferred; } /* Read n bytes from the buffer. Returns number of bytes read. */ static int memio_buffer_get(struct memio_buffer *mb, char *buf, int n) { int len; int transferred = 0; /* Handle part before wrap */ len = PR_MIN(n, memio_buffer_used_contiguous(mb)); if (len) { memcpy(buf, &mb->buf[mb->head], len); mb->head += len; if (mb->head == mb->bufsize) mb->head = 0; n -= len; buf += len; transferred += len; /* Handle part after wrap */ len = PR_MIN(n, memio_buffer_used_contiguous(mb)); if (len) { memcpy(buf, &mb->buf[mb->head], len); mb->head += len; if (mb->head == mb->bufsize) mb->head = 0; transferred += len; } } return transferred; } /*--------------- private memio functions -----------------------*/ static PRStatus PR_CALLBACK memio_Close(PRFileDesc *fd) { struct PRFilePrivate *secret = fd->secret; memio_buffer_destroy(&secret->readbuf); memio_buffer_destroy(&secret->writebuf); free(secret); fd->dtor(fd); return PR_SUCCESS; } static PRStatus PR_CALLBACK memio_Shutdown(PRFileDesc *fd, PRIntn how) { /* TODO: pass shutdown status to app somehow */ return PR_SUCCESS; } /* If there was a network error in the past taking bytes * out of the buffer, return it to the next call that * tries to read from an empty buffer. */ static int PR_CALLBACK memio_Recv(PRFileDesc *fd, void *buf, PRInt32 len, PRIntn flags, PRIntervalTime timeout) { struct PRFilePrivate *secret; struct memio_buffer *mb; int rv; if (flags) { PR_SetError(PR_NOT_IMPLEMENTED_ERROR, 0); return -1; } secret = fd->secret; mb = &secret->readbuf; PR_ASSERT(mb->bufsize); rv = memio_buffer_get(mb, buf, len); if (rv == 0 && !secret->eof) { secret->read_requested = len; /* If there is no more data in the buffer, report any pending errors * that were previously observed. Note that both the readbuf and the * writebuf are checked for errors, since the application may have * encountered a socket error while writing that would otherwise not * be reported until the application attempted to write again - which * it may never do. */ if (mb->last_err) PR_SetError(mb->last_err, 0); else if (secret->writebuf.last_err) PR_SetError(secret->writebuf.last_err, 0); else PR_SetError(PR_WOULD_BLOCK_ERROR, 0); return -1; } secret->read_requested = 0; return rv; } static int PR_CALLBACK memio_Read(PRFileDesc *fd, void *buf, PRInt32 len) { /* pull bytes from buffer */ return memio_Recv(fd, buf, len, 0, PR_INTERVAL_NO_TIMEOUT); } static int PR_CALLBACK memio_Send(PRFileDesc *fd, const void *buf, PRInt32 len, PRIntn flags, PRIntervalTime timeout) { struct PRFilePrivate *secret; struct memio_buffer *mb; int rv; secret = fd->secret; mb = &secret->writebuf; PR_ASSERT(mb->bufsize); /* Note that the read error state is not reported, because it cannot be * reported until all buffered data has been read. If there is an error * with the next layer, attempting to call Send again will report the * error appropriately. */ if (mb->last_err) { PR_SetError(mb->last_err, 0); return -1; } rv = memio_buffer_put(mb, buf, len); if (rv == 0) { PR_SetError(PR_WOULD_BLOCK_ERROR, 0); return -1; } return rv; } static int PR_CALLBACK memio_Write(PRFileDesc *fd, const void *buf, PRInt32 len) { /* append bytes to buffer */ return memio_Send(fd, buf, len, 0, PR_INTERVAL_NO_TIMEOUT); } static PRStatus PR_CALLBACK memio_GetPeerName(PRFileDesc *fd, PRNetAddr *addr) { /* TODO: fail if memio_SetPeerName has not been called */ struct PRFilePrivate *secret = fd->secret; *addr = secret->peername; return PR_SUCCESS; } static PRStatus memio_GetSocketOption(PRFileDesc *fd, PRSocketOptionData *data) { /* * Even in the original version for real tcp sockets, * PR_SockOpt_Nonblocking is a special case that does not * translate to a getsockopt() call */ if (PR_SockOpt_Nonblocking == data->option) { data->value.non_blocking = PR_TRUE; return PR_SUCCESS; } PR_SetError(PR_OPERATION_NOT_SUPPORTED_ERROR, 0); return PR_FAILURE; } /*--------------- private memio data -----------------------*/ /* * Implement just the bare minimum number of methods needed to make ssl happy. * * Oddly, PR_Recv calls ssl_Recv calls ssl_SocketIsBlocking calls * PR_GetSocketOption, so we have to provide an implementation of * PR_GetSocketOption that just says "I'm nonblocking". */ static struct PRIOMethods memio_layer_methods = { PR_DESC_LAYERED, memio_Close, memio_Read, memio_Write, NULL, NULL, NULL, NULL, NULL, NULL, NULL, NULL, NULL, NULL, NULL, NULL, memio_Shutdown, memio_Recv, memio_Send, NULL, NULL, NULL, NULL, NULL, NULL, memio_GetPeerName, NULL, NULL, memio_GetSocketOption, NULL, NULL, NULL, NULL, NULL, NULL, NULL, }; static PRDescIdentity memio_identity = PR_INVALID_IO_LAYER; static PRStatus memio_InitializeLayerName(void) { memio_identity = PR_GetUniqueIdentity("memio"); return PR_SUCCESS; } /*--------------- public memio functions -----------------------*/ PRFileDesc *memio_CreateIOLayer(int readbufsize, int writebufsize) { PRFileDesc *fd; struct PRFilePrivate *secret; static PRCallOnceType once; PR_CallOnce(&once, memio_InitializeLayerName); fd = PR_CreateIOLayerStub(memio_identity, &memio_layer_methods); secret = malloc(sizeof(struct PRFilePrivate)); memset(secret, 0, sizeof(*secret)); memio_buffer_new(&secret->readbuf, readbufsize); memio_buffer_new(&secret->writebuf, writebufsize); fd->secret = secret; return fd; } void memio_SetPeerName(PRFileDesc *fd, const PRNetAddr *peername) { PRFileDesc *memiofd = PR_GetIdentitiesLayer(fd, memio_identity); struct PRFilePrivate *secret = memiofd->secret; secret->peername = *peername; } memio_Private *memio_GetSecret(PRFileDesc *fd) { PRFileDesc *memiofd = PR_GetIdentitiesLayer(fd, memio_identity); struct PRFilePrivate *secret = memiofd->secret; return (memio_Private *)secret; } int memio_GetReadRequest(memio_Private *secret) { return ((PRFilePrivate *)secret)->read_requested; } int memio_GetReadParams(memio_Private *secret, char **buf) { struct memio_buffer* mb = &((PRFilePrivate *)secret)->readbuf; PR_ASSERT(mb->bufsize); *buf = &mb->buf[mb->tail]; return memio_buffer_unused_contiguous(mb); } int memio_GetReadableBufferSize(memio_Private *secret) { struct memio_buffer* mb = &((PRFilePrivate *)secret)->readbuf; PR_ASSERT(mb->bufsize); return memio_buffer_used_contiguous(mb); } void memio_PutReadResult(memio_Private *secret, int bytes_read) { struct memio_buffer* mb = &((PRFilePrivate *)secret)->readbuf; PR_ASSERT(mb->bufsize); if (bytes_read > 0) { mb->tail += bytes_read; if (mb->tail == mb->bufsize) mb->tail = 0; } else if (bytes_read == 0) { /* Record EOF condition and report to caller when buffer runs dry */ ((PRFilePrivate *)secret)->eof = PR_TRUE; } else /* if (bytes_read < 0) */ { mb->last_err = bytes_read; } } int memio_GetWriteParams(memio_Private *secret, const char **buf1, unsigned int *len1, const char **buf2, unsigned int *len2) { struct memio_buffer* mb = &((PRFilePrivate *)secret)->writebuf; PR_ASSERT(mb->bufsize); if (mb->last_err) return mb->last_err; *buf1 = &mb->buf[mb->head]; *len1 = memio_buffer_used_contiguous(mb); *buf2 = mb->buf; *len2 = memio_buffer_wrapped_bytes(mb); return 0; } void memio_PutWriteResult(memio_Private *secret, int bytes_written) { struct memio_buffer* mb = &((PRFilePrivate *)secret)->writebuf; PR_ASSERT(mb->bufsize); if (bytes_written > 0) { mb->head += bytes_written; if (mb->head >= mb->bufsize) mb->head -= mb->bufsize; } else if (bytes_written < 0) { mb->last_err = bytes_written; } } /*--------------- private memio_buffer self-test -----------------*/ /* Even a trivial unit test is very helpful when doing circular buffers. */ /*#define TRIVIAL_SELF_TEST*/ #ifdef TRIVIAL_SELF_TEST #include #define TEST_BUFLEN 7 #define CHECKEQ(a, b) { \ if ((a) != (b)) { \ printf("%d != %d, Test failed line %d\n", a, b, __LINE__); \ exit(1); \ } \ } int main() { struct memio_buffer mb; char buf[100]; int i; memio_buffer_new(&mb, TEST_BUFLEN); CHECKEQ(memio_buffer_unused_contiguous(&mb), TEST_BUFLEN-1); CHECKEQ(memio_buffer_used_contiguous(&mb), 0); CHECKEQ(memio_buffer_put(&mb, "howdy", 5), 5); CHECKEQ(memio_buffer_unused_contiguous(&mb), TEST_BUFLEN-1-5); CHECKEQ(memio_buffer_used_contiguous(&mb), 5); CHECKEQ(memio_buffer_wrapped_bytes(&mb), 0); CHECKEQ(memio_buffer_put(&mb, "!", 1), 1); CHECKEQ(memio_buffer_unused_contiguous(&mb), 0); CHECKEQ(memio_buffer_used_contiguous(&mb), 6); CHECKEQ(memio_buffer_wrapped_bytes(&mb), 0); CHECKEQ(memio_buffer_get(&mb, buf, 6), 6); CHECKEQ(memcmp(buf, "howdy!", 6), 0); CHECKEQ(memio_buffer_unused_contiguous(&mb), 1); CHECKEQ(memio_buffer_used_contiguous(&mb), 0); CHECKEQ(memio_buffer_put(&mb, "01234", 5), 5); CHECKEQ(memio_buffer_used_contiguous(&mb), 1); CHECKEQ(memio_buffer_wrapped_bytes(&mb), 4); CHECKEQ(memio_buffer_unused_contiguous(&mb), TEST_BUFLEN-1-5); CHECKEQ(memio_buffer_put(&mb, "5", 1), 1); CHECKEQ(memio_buffer_unused_contiguous(&mb), 0); CHECKEQ(memio_buffer_used_contiguous(&mb), 1); /* TODO: add more cases */ printf("Test passed\n"); exit(0); } #endif