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/* -*- coding: utf-8 -*-
* ---------------------------------------------------------------------- * Copyright © 2011-2012, RedJack, LLC. * All rights reserved. * * Please see the COPYING file in this distribution for license * details. * ---------------------------------------------------------------------- */
#include <stdarg.h>
#include <stdio.h>
#include <string.h>
#include "libcork/core/allocator.h"
#include "libcork/core/types.h"
#include "libcork/ds/buffer.h"
#include "libcork/ds/managed-buffer.h"
#include "libcork/ds/stream.h"
#include "libcork/helpers/errors.h"
void cork_buffer_init(struct cork_buffer *buffer) { buffer->buf = NULL; buffer->size = 0; buffer->allocated_size = 0; }
struct cork_buffer * cork_buffer_new(void) { struct cork_buffer *buffer = cork_new(struct cork_buffer); cork_buffer_init(buffer); return buffer; }
void cork_buffer_done(struct cork_buffer *buffer) { if (buffer->buf != NULL) { free(buffer->buf); buffer->buf = NULL; } buffer->size = 0; buffer->allocated_size = 0; }
void cork_buffer_free(struct cork_buffer *buffer) { cork_buffer_done(buffer); free(buffer); }
bool cork_buffer_equal(const struct cork_buffer *buffer1, const struct cork_buffer *buffer2) { if (buffer1 == buffer2) { return true; }
if (buffer1->size != buffer2->size) { return false; }
return (memcmp(buffer1->buf, buffer2->buf, buffer1->size) == 0); }
static void cork_buffer_ensure_size_int(struct cork_buffer *buffer, size_t desired_size) { size_t new_size;
if (CORK_LIKELY(buffer->allocated_size >= desired_size)) { return; }
/* Make sure we at least double the old size when reallocating. */ new_size = buffer->allocated_size * 2; if (desired_size > new_size) { new_size = desired_size; }
buffer->buf = cork_realloc(buffer->buf, new_size); buffer->allocated_size = new_size; }
void cork_buffer_ensure_size(struct cork_buffer *buffer, size_t desired_size) { cork_buffer_ensure_size_int(buffer, desired_size); }
void cork_buffer_clear(struct cork_buffer *buffer) { buffer->size = 0; if (buffer->buf != NULL) { ((char *) buffer->buf)[0] = '\0'; } }
void cork_buffer_truncate(struct cork_buffer *buffer, size_t length) { if (buffer->size > length) { buffer->size = length; if (length == 0) { if (buffer->buf != NULL) { ((char *) buffer->buf)[0] = '\0'; } } else { ((char *) buffer->buf)[length] = '\0'; } } }
void cork_buffer_set(struct cork_buffer *buffer, const void *src, size_t length) { cork_buffer_ensure_size_int(buffer, length+1); memcpy(buffer->buf, src, length); ((char *) buffer->buf)[length] = '\0'; buffer->size = length; }
void cork_buffer_append(struct cork_buffer *buffer, const void *src, size_t length) { cork_buffer_ensure_size_int(buffer, buffer->size + length + 1); memcpy(buffer->buf + buffer->size, src, length); buffer->size += length; ((char *) buffer->buf)[buffer->size] = '\0'; }
void cork_buffer_set_string(struct cork_buffer *buffer, const char *str) { cork_buffer_set(buffer, str, strlen(str)); }
void cork_buffer_append_string(struct cork_buffer *buffer, const char *str) { cork_buffer_append(buffer, str, strlen(str)); }
void cork_buffer_append_vprintf(struct cork_buffer *buffer, const char *format, va_list args) { size_t format_size; va_list args1;
va_copy(args1, args); format_size = vsnprintf(buffer->buf + buffer->size, buffer->allocated_size - buffer->size, format, args1); va_end(args1);
/* If the first call works, then set buffer->size and return. */ if (format_size < (buffer->allocated_size - buffer->size)) { buffer->size += format_size; return; }
/* If the first call fails, resize buffer and try again. */ cork_buffer_ensure_size_int (buffer, buffer->allocated_size + format_size + 1); format_size = vsnprintf(buffer->buf + buffer->size, buffer->allocated_size - buffer->size, format, args); buffer->size += format_size; }
void cork_buffer_vprintf(struct cork_buffer *buffer, const char *format, va_list args) { cork_buffer_clear(buffer); cork_buffer_append_vprintf(buffer, format, args); }
void cork_buffer_append_printf(struct cork_buffer *buffer, const char *format, ...) { va_list args; va_start(args, format); cork_buffer_append_vprintf(buffer, format, args); va_end(args); }
void cork_buffer_printf(struct cork_buffer *buffer, const char *format, ...) { va_list args; va_start(args, format); cork_buffer_vprintf(buffer, format, args); va_end(args); }
void cork_buffer_append_indent(struct cork_buffer *buffer, size_t indent) { cork_buffer_ensure_size_int(buffer, buffer->size + indent + 1); memset(buffer->buf + buffer->size, ' ', indent); buffer->size += indent; ((char *) buffer->buf)[buffer->size] = '\0'; }
/* including space */ #define is_sprint(ch) ((ch) >= 0x20 && (ch) <= 0x7e)
/* not including space */ #define is_print(ch) ((ch) > 0x20 && (ch) <= 0x7e)
#define is_space(ch) \
((ch) == ' ' || \ (ch) == '\f' || \ (ch) == '\n' || \ (ch) == '\r' || \ (ch) == '\t' || \ (ch) == '\v')
#define to_hex(nybble) \
((nybble) < 10? '0' + (nybble): 'a' - 10 + (nybble))
void cork_buffer_append_c_string(struct cork_buffer *dest, const char *chars, size_t length) { size_t i; cork_buffer_append(dest, "\"", 1); for (i = 0; i < length; i++) { char ch = chars[i]; switch (ch) { case '\"': cork_buffer_append_literal(dest, "\\\""); break; case '\\': cork_buffer_append_literal(dest, "\\\\"); break; case '\f': cork_buffer_append_literal(dest, "\\f"); break; case '\n': cork_buffer_append_literal(dest, "\\n"); break; case '\r': cork_buffer_append_literal(dest, "\\r"); break; case '\t': cork_buffer_append_literal(dest, "\\t"); break; case '\v': cork_buffer_append_literal(dest, "\\v"); break; default: if (is_sprint(ch)) { cork_buffer_append(dest, &chars[i], 1); } else { uint8_t byte = ch; cork_buffer_append_printf(dest, "\\x%02" PRIx8, byte); } break; } } cork_buffer_append(dest, "\"", 1); }
void cork_buffer_append_hex_dump(struct cork_buffer *dest, size_t indent, const char *chars, size_t length) { char hex[3 * 16]; char print[16]; char *curr_hex = hex; char *curr_print = print; size_t i; size_t column = 0; for (i = 0; i < length; i++) { char ch = chars[i]; uint8_t u8 = ch; *curr_hex++ = to_hex(u8 >> 4); *curr_hex++ = to_hex(u8 & 0x0f); *curr_hex++ = ' '; *curr_print++ = is_sprint(ch)? ch: '.'; if (column == 0 && i != 0) { cork_buffer_append_literal(dest, "\n"); cork_buffer_append_indent(dest, indent); column++; } else if (column == 15) { cork_buffer_append_printf (dest, "%-48.*s", (int) (curr_hex - hex), hex); cork_buffer_append_literal(dest, " |"); cork_buffer_append(dest, print, curr_print - print); cork_buffer_append_literal(dest, "|"); curr_hex = hex; curr_print = print; column = 0; } else { column++; } }
if (column > 0) { cork_buffer_append_printf(dest, "%-48.*s", (int) (curr_hex - hex), hex); cork_buffer_append_literal(dest, " |"); cork_buffer_append(dest, print, curr_print - print); cork_buffer_append_literal(dest, "|"); } }
void cork_buffer_append_multiline(struct cork_buffer *dest, size_t indent, const char *chars, size_t length) { size_t i; for (i = 0; i < length; i++) { char ch = chars[i]; if (ch == '\n') { cork_buffer_append_literal(dest, "\n"); cork_buffer_append_indent(dest, indent); } else { cork_buffer_append(dest, &chars[i], 1); } } }
void cork_buffer_append_binary(struct cork_buffer *dest, size_t indent, const char *chars, size_t length) { size_t i; bool newline = false;
/* If there are any non-printable characters, print out a hex dump */ for (i = 0; i < length; i++) { if (!is_print(chars[i]) && !is_space(chars[i])) { cork_buffer_append_literal(dest, "(hex)\n"); cork_buffer_append_indent(dest, indent); cork_buffer_append_hex_dump(dest, indent, chars, length); return; } else if (chars[i] == '\n') { newline = true; /* Don't immediately use the multiline format, since there might be
* a non-printable character later on that kicks us over to the hex * dump format. */ } }
if (newline) { cork_buffer_append_literal(dest, "(multiline)\n"); cork_buffer_append_indent(dest, indent); cork_buffer_append_multiline(dest, indent, chars, length); } else { cork_buffer_append(dest, chars, length); } }
struct cork_buffer__managed_buffer { struct cork_managed_buffer parent; struct cork_buffer *buffer; };
static void cork_buffer__managed_free(struct cork_managed_buffer *vself) { struct cork_buffer__managed_buffer *self = cork_container_of(vself, struct cork_buffer__managed_buffer, parent); cork_buffer_free(self->buffer); free(self); }
static struct cork_managed_buffer_iface CORK_BUFFER__MANAGED_BUFFER = { cork_buffer__managed_free };
struct cork_managed_buffer * cork_buffer_to_managed_buffer(struct cork_buffer *buffer) { struct cork_buffer__managed_buffer *self = cork_new(struct cork_buffer__managed_buffer); self->parent.buf = buffer->buf; self->parent.size = buffer->size; self->parent.ref_count = 1; self->parent.iface = &CORK_BUFFER__MANAGED_BUFFER; self->buffer = buffer; return &self->parent; }
int cork_buffer_to_slice(struct cork_buffer *buffer, struct cork_slice *slice) { struct cork_managed_buffer *managed = cork_buffer_to_managed_buffer(buffer);
/* We don't have to check for NULL; cork_managed_buffer_slice_offset
* will do that for us. */ int rc = cork_managed_buffer_slice_offset(slice, managed, 0);
/* Before returning, drop our reference to the managed buffer. If
* the slicing succeeded, then there will be one remaining reference * in the slice. If it didn't succeed, this will free the managed * buffer for us. */ cork_managed_buffer_unref(managed); return rc; }
struct cork_buffer__stream_consumer { struct cork_stream_consumer consumer; struct cork_buffer *buffer; };
static int cork_buffer_stream_consumer_data(struct cork_stream_consumer *consumer, const void *buf, size_t size, bool is_first_chunk) { struct cork_buffer__stream_consumer *bconsumer = cork_container_of (consumer, struct cork_buffer__stream_consumer, consumer);
if (is_first_chunk) { cork_buffer_clear(bconsumer->buffer); }
cork_buffer_append(bconsumer->buffer, buf, size); return 0; }
static int cork_buffer_stream_consumer_eof(struct cork_stream_consumer *consumer) { return 0; }
static void cork_buffer_stream_consumer_free(struct cork_stream_consumer *consumer) { struct cork_buffer__stream_consumer *bconsumer = cork_container_of (consumer, struct cork_buffer__stream_consumer, consumer); free(bconsumer); }
struct cork_stream_consumer * cork_buffer_to_stream_consumer(struct cork_buffer *buffer) { struct cork_buffer__stream_consumer *bconsumer = cork_new(struct cork_buffer__stream_consumer); bconsumer->consumer.data = cork_buffer_stream_consumer_data; bconsumer->consumer.eof = cork_buffer_stream_consumer_eof; bconsumer->consumer.free = cork_buffer_stream_consumer_free; bconsumer->buffer = buffer; return &bconsumer->consumer; }
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