// Copyright 2012 The Chromium Authors // Use of this source code is governed by a BSD-style license that can be // found in the LICENSE file. #include "base/base64.h" #include #include #include "base/check.h" #include "base/numerics/checked_math.h" #include "base/strings/string_util.h" #include "third_party/modp_b64/modp_b64.h" namespace base { namespace { ModpDecodePolicy GetModpPolicy(Base64DecodePolicy policy) { switch (policy) { case Base64DecodePolicy::kStrict: return ModpDecodePolicy::kStrict; case Base64DecodePolicy::kForgiving: return ModpDecodePolicy::kForgiving; } } } // namespace std::string Base64Encode(span input) { std::string output; Base64EncodeAppend(input, &output); return output; } void Base64EncodeAppend(span input, std::string* output) { // Ensure `modp_b64_encode_data_len` will not overflow. CHECK_LE(input.size(), MODP_B64_MAX_INPUT_LEN); size_t encode_data_len = modp_b64_encode_data_len(input.size()); const size_t after_size = base::CheckAdd(encode_data_len, output->size()).ValueOrDie(); output->resize(after_size); span read = base::as_chars(input); span write = base::span(*output).last(encode_data_len); const size_t written_size = modp_b64_encode_data( write.data(), // This must point to `encode_data_len` many chars. read.data(), read.size()); // If this failed it would indicate we wrote OOB or left bytes uninitialized. // It's possible for this to be elided by the compiler, since writing OOB is // UB. CHECK_EQ(written_size, write.size()); } std::string Base64Encode(std::string_view input) { return Base64Encode(base::as_byte_span(input)); } bool Base64Decode(std::string_view input, std::string* output, Base64DecodePolicy policy) { std::string decode_buf; decode_buf.resize(modp_b64_decode_len(input.size())); // Does not NUL-terminate result since result is binary data! size_t written_size = modp_b64_decode(decode_buf.data(), input.data(), input.size(), GetModpPolicy(policy)); // Forgiving mode requires whitespace to be stripped prior to decoding. // We don't do that in the above code to ensure that the "happy path" of // input without whitespace is as fast as possible. Since whitespace in input // will always cause `modp_b64_decode` to fail, just handle whitespace // stripping on failure. This is not much slower than just scanning for // whitespace first, even for input with whitespace. if (written_size == MODP_B64_ERROR && policy == Base64DecodePolicy::kForgiving) { // We could use `output` here to avoid an allocation when decoding is done // in-place, but it violates the API contract that `output` is only modified // on success. std::string input_without_whitespace; RemoveChars(input, kInfraAsciiWhitespace, &input_without_whitespace); // This means that the required size to decode is at most what was needed // above, which means `decode_buf` will fit the decoded bytes at its current // size and we don't need to call `modp_b64_decode_len()` again. CHECK_LE(input_without_whitespace.size(), input.size()); written_size = modp_b64_decode(decode_buf.data(), input_without_whitespace.data(), input_without_whitespace.size(), GetModpPolicy(policy)); } if (written_size == MODP_B64_ERROR) { return false; } // If this failed it would indicate we wrote OOB. It's possible for this to be // elided by the compiler, since writing OOB is UB. CHECK_LE(written_size, decode_buf.size()); // Shrinks the buffer and makes it NUL-terminated. decode_buf.resize(written_size); *output = std::move(decode_buf); return true; } std::optional> Base64Decode(std::string_view input) { std::vector write_buf(modp_b64_decode_len(input.size())); span write = base::as_writable_chars(base::span(write_buf)); size_t written_size = modp_b64_decode(write.data(), input.data(), input.size()); if (written_size == MODP_B64_ERROR) { return std::nullopt; } // If this failed it would indicate we wrote OOB. It's possible for this to be // elided by the compiler, since writing OOB is UB. CHECK_LE(written_size, write.size()); write_buf.resize(written_size); return write_buf; } } // namespace base