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android / platform / external / chromium_org / 3240926 / . / components / autofill / core / browser / form_structure.cc
blob: d502a0dee7660ec040f354d163048e01cdc0bb9c [file] [log] [blame]
// Copyright 2013 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.
#include "components/autofill/core/browser/form_structure.h"
#include <utility>
#include "base/basictypes.h"
#include "base/command_line.h"
#include "base/logging.h"
#include "base/memory/scoped_ptr.h"
#include "base/sha1.h"
#include "base/strings/string_number_conversions.h"
#include "base/strings/string_util.h"
#include "base/strings/stringprintf.h"
#include "base/strings/utf_string_conversions.h"
#include "base/time/time.h"
#include "components/autofill/content/browser/autocheckout_page_meta_data.h"
#include "components/autofill/core/browser/autofill_metrics.h"
#include "components/autofill/core/browser/autofill_type.h"
#include "components/autofill/core/browser/autofill_xml_parser.h"
#include "components/autofill/core/browser/field_types.h"
#include "components/autofill/core/browser/form_field.h"
#include "components/autofill/core/common/autofill_constants.h"
#include "components/autofill/core/common/form_data.h"
#include "components/autofill/core/common/form_data_predictions.h"
#include "components/autofill/core/common/form_field_data.h"
#include "components/autofill/core/common/form_field_data_predictions.h"
#include "third_party/icu/source/i18n/unicode/regex.h"
#include "third_party/libjingle/source/talk/xmllite/xmlelement.h"
namespace autofill {
namespace {
const char kFormMethodPost[] = "post";
// XML elements and attributes.
const char kAttributeAcceptedFeatures[] = "accepts";
const char kAttributeAutofillUsed[] = "autofillused";
const char kAttributeAutofillType[] = "autofilltype";
const char kAttributeClientVersion[] = "clientversion";
const char kAttributeDataPresent[] = "datapresent";
const char kAttributeFieldID[] = "fieldid";
const char kAttributeFieldType[] = "fieldtype";
const char kAttributeFormSignature[] = "formsignature";
const char kAttributeName[] = "name";
const char kAttributeSignature[] = "signature";
const char kAttributeUrlprefixSignature[] = "urlprefixsignature";
const char kAcceptedFeaturesExperiment[] = "e"; // e=experiments
const char kAcceptedFeaturesAutocheckoutExperiment[] = "a,e"; // a=autocheckout
const char kClientVersion[] = "6.1.1715.1442/en (GGLL)";
const char kXMLDeclaration[] = "<?xml version=\"1.0\" encoding=\"UTF-8\"?>";
const char kXMLElementAutofillQuery[] = "autofillquery";
const char kXMLElementAutofillUpload[] = "autofillupload";
const char kXMLElementFieldAssignments[] = "fieldassignments";
const char kXMLElementField[] = "field";
const char kXMLElementFields[] = "fields";
const char kXMLElementForm[] = "form";
const char kBillingSection[] = "billing";
const char kShippingSection[] = "shipping";
// Stip away >= 5 consecutive digits.
const char kIgnorePatternInFieldName[] = "\\d{5,}+";
// Helper for |EncodeUploadRequest()| that creates a bit field corresponding to
// |available_field_types| and returns the hex representation as a string.
std::string EncodeFieldTypes(const ServerFieldTypeSet& available_field_types) {
// There are |MAX_VALID_FIELD_TYPE| different field types and 8 bits per byte,
// so we need ceil(MAX_VALID_FIELD_TYPE / 8) bytes to encode the bit field.
const size_t kNumBytes = (MAX_VALID_FIELD_TYPE + 0x7) / 8;
// Pack the types in |available_field_types| into |bit_field|.
std::vector<uint8> bit_field(kNumBytes, 0);
for (ServerFieldTypeSet::const_iterator field_type =
available_field_types.begin();
field_type != available_field_types.end();
++field_type) {
// Set the appropriate bit in the field. The bit we set is the one
// |field_type| % 8 from the left of the byte.
const size_t byte = *field_type / 8;
const size_t bit = 0x80 >> (*field_type % 8);
DCHECK(byte < bit_field.size());
bit_field[byte] |= bit;
}
// Discard any trailing zeroes.
// If there are no available types, we return the empty string.
size_t data_end = bit_field.size();
for (; data_end > 0 && !bit_field[data_end - 1]; --data_end) {
}
// Print all meaningfull bytes into a string.
std::string data_presence;
data_presence.reserve(data_end * 2 + 1);
for (size_t i = 0; i < data_end; ++i) {
base::StringAppendF(&data_presence, "%02x", bit_field[i]);
}
return data_presence;
}
// Helper for |EncodeFormRequest()| that creates XmlElements for the given field
// in upload xml, and also add them to the parent XmlElement.
void EncodeFieldForUpload(const AutofillField& field,
buzz::XmlElement* parent) {
// Don't upload checkable fields.
if (field.is_checkable)
return;
ServerFieldTypeSet types = field.possible_types();
// |types| could be empty in unit-tests only.
for (ServerFieldTypeSet::iterator field_type = types.begin();
field_type != types.end(); ++field_type) {
buzz::XmlElement *field_element = new buzz::XmlElement(
buzz::QName(kXMLElementField));
field_element->SetAttr(buzz::QName(kAttributeSignature),
field.FieldSignature());
field_element->SetAttr(buzz::QName(kAttributeAutofillType),
base::IntToString(*field_type));
parent->AddElement(field_element);
}
}
// Helper for |EncodeFormRequest()| that creates XmlElement for the given field
// in query xml, and also add it to the parent XmlElement.
void EncodeFieldForQuery(const AutofillField& field,
buzz::XmlElement* parent) {
buzz::XmlElement *field_element = new buzz::XmlElement(
buzz::QName(kXMLElementField));
field_element->SetAttr(buzz::QName(kAttributeSignature),
field.FieldSignature());
parent->AddElement(field_element);
}
// Helper for |EncodeFormRequest()| that creates XmlElements for the given field
// in field assignments xml, and also add them to the parent XmlElement.
void EncodeFieldForFieldAssignments(const AutofillField& field,
buzz::XmlElement* parent) {
ServerFieldTypeSet types = field.possible_types();
for (ServerFieldTypeSet::iterator field_type = types.begin();
field_type != types.end(); ++field_type) {
buzz::XmlElement *field_element = new buzz::XmlElement(
buzz::QName(kXMLElementFields));
field_element->SetAttr(buzz::QName(kAttributeFieldID),
field.FieldSignature());
field_element->SetAttr(buzz::QName(kAttributeFieldType),
base::IntToString(*field_type));
field_element->SetAttr(buzz::QName(kAttributeName),
UTF16ToUTF8(field.name));
parent->AddElement(field_element);
}
}
// Returns |true| iff the |token| is a type hint for a contact field, as
// specified in the implementation section of http://is.gd/whatwg_autocomplete
// Note that "fax" and "pager" are intentionally ignored, as Chrome does not
// support filling either type of information.
bool IsContactTypeHint(const std::string& token) {
return token == "home" || token == "work" || token == "mobile";
}
// Returns |true| iff the |token| is a type hint appropriate for a field of the
// given |field_type|, as specified in the implementation section of
// http://is.gd/whatwg_autocomplete
// TODO(isherman): This should use HTML field types, not native ones.
bool ContactTypeHintMatchesFieldType(const std::string& token,
ServerFieldType field_type) {
// The "home" and "work" type hints are only appropriate for email and phone
// number field types.
if (token == "home" || token == "work") {
return field_type == EMAIL_ADDRESS ||
(field_type >= PHONE_HOME_NUMBER &&
field_type <= PHONE_HOME_WHOLE_NUMBER);
}
// The "mobile" type hint is only appropriate for phone number field types.
// Note that "fax" and "pager" are intentionally ignored, as Chrome does not
// support filling either type of information.
if (token == "mobile") {
return field_type >= PHONE_HOME_NUMBER &&
field_type <= PHONE_HOME_WHOLE_NUMBER;
}
return false;
}
// Returns the Chrome Autofill-supported field type corresponding to the given
// |autocomplete_type|, if there is one, in the context of the given |field|.
// Chrome Autofill supports a subset of the field types listed at
// http://is.gd/whatwg_autocomplete
// TODO(isherman): This should use HTML field types, not native ones.
ServerFieldType FieldTypeFromAutocompleteType(
const std::string& autocomplete_type,
const AutofillField& field) {
if (autocomplete_type == "name")
return NAME_FULL;
if (autocomplete_type == "given-name")
return NAME_FIRST;
if (autocomplete_type == "additional-name") {
if (field.max_length == 1)
return NAME_MIDDLE_INITIAL;
else
return NAME_MIDDLE;
}
if (autocomplete_type == "family-name")
return NAME_LAST;
if (autocomplete_type == "honorific-suffix")
return NAME_SUFFIX;
if (autocomplete_type == "organization")
return COMPANY_NAME;
if (autocomplete_type == "address-line1")
return ADDRESS_HOME_LINE1;
if (autocomplete_type == "address-line2")
return ADDRESS_HOME_LINE2;
if (autocomplete_type == "locality")
return ADDRESS_HOME_CITY;
if (autocomplete_type == "region")
return ADDRESS_HOME_STATE;
if (autocomplete_type == "country")
return ADDRESS_HOME_COUNTRY;
if (autocomplete_type == "postal-code")
return ADDRESS_HOME_ZIP;
if (autocomplete_type == "cc-name")
return CREDIT_CARD_NAME;
if (autocomplete_type == "cc-number")
return CREDIT_CARD_NUMBER;
if (autocomplete_type == "cc-exp") {
if (field.max_length == 5)
return CREDIT_CARD_EXP_DATE_2_DIGIT_YEAR;
else
return CREDIT_CARD_EXP_DATE_4_DIGIT_YEAR;
}
if (autocomplete_type == "cc-exp-month")
return CREDIT_CARD_EXP_MONTH;
if (autocomplete_type == "cc-exp-year") {
if (field.max_length == 2)
return CREDIT_CARD_EXP_2_DIGIT_YEAR;
else
return CREDIT_CARD_EXP_4_DIGIT_YEAR;
}
if (autocomplete_type == "cc-csc")
return CREDIT_CARD_VERIFICATION_CODE;
if (autocomplete_type == "cc-type")
return CREDIT_CARD_TYPE;
if (autocomplete_type == "tel")
return PHONE_HOME_WHOLE_NUMBER;
if (autocomplete_type == "tel-country-code")
return PHONE_HOME_COUNTRY_CODE;
if (autocomplete_type == "tel-national")
return PHONE_HOME_CITY_AND_NUMBER;
if (autocomplete_type == "tel-area-code")
return PHONE_HOME_CITY_CODE;
if (autocomplete_type == "tel-local")
return PHONE_HOME_NUMBER;
if (autocomplete_type == "tel-local-prefix")
return PHONE_HOME_NUMBER;
if (autocomplete_type == "tel-local-suffix")
return PHONE_HOME_NUMBER;
if (autocomplete_type == "email")
return EMAIL_ADDRESS;
return UNKNOWN_TYPE;
}
std::string StripDigitsIfRequired(const base::string16& input) {
UErrorCode status = U_ZERO_ERROR;
CR_DEFINE_STATIC_LOCAL(icu::UnicodeString, icu_pattern,
(kIgnorePatternInFieldName));
CR_DEFINE_STATIC_LOCAL(icu::RegexMatcher, matcher,
(icu_pattern, UREGEX_CASE_INSENSITIVE, status));
DCHECK_EQ(status, U_ZERO_ERROR);
icu::UnicodeString icu_input(input.data(), input.length());
matcher.reset(icu_input);
icu::UnicodeString replaced_string = matcher.replaceAll("", status);
std::string return_string;
status = U_ZERO_ERROR;
UTF16ToUTF8(replaced_string.getBuffer(),
static_cast<size_t>(replaced_string.length()),
&return_string);
if (status != U_ZERO_ERROR) {
DVLOG(1) << "Couldn't strip digits in " << UTF16ToUTF8(input);
return UTF16ToUTF8(input);
}
return return_string;
}
} // namespace
FormStructure::FormStructure(const FormData& form,
const std::string& autocheckout_url_prefix)
: form_name_(form.name),
source_url_(form.origin),
target_url_(form.action),
autofill_count_(0),
active_field_count_(0),
upload_required_(USE_UPLOAD_RATES),
server_experiment_id_("no server response"),
has_author_specified_types_(false),
autocheckout_url_prefix_(autocheckout_url_prefix),
filled_by_autocheckout_(false) {
// Copy the form fields.
std::map<base::string16, size_t> unique_names;
for (std::vector<FormFieldData>::const_iterator field =
form.fields.begin();
field != form.fields.end(); field++) {
if (!ShouldSkipField(*field)) {
// Add all supported form fields (including with empty names) to the
// signature. This is a requirement for Autofill servers.
form_signature_field_names_.append("&");
form_signature_field_names_.append(StripDigitsIfRequired(field->name));
++active_field_count_;
}
// Generate a unique name for this field by appending a counter to the name.
// Make sure to prepend the counter with a non-numeric digit so that we are
// guaranteed to avoid collisions.
if (!unique_names.count(field->name))
unique_names[field->name] = 1;
else
++unique_names[field->name];
base::string16 unique_name = field->name + ASCIIToUTF16("_") +
base::IntToString16(unique_names[field->name]);
fields_.push_back(new AutofillField(*field, unique_name));
}
std::string method = UTF16ToUTF8(form.method);
if (StringToLowerASCII(method) == kFormMethodPost) {
method_ = POST;
} else {
// Either the method is 'get', or we don't know. In this case we default
// to GET.
method_ = GET;
}
}
FormStructure::~FormStructure() {}
void FormStructure::DetermineHeuristicTypes(
const AutofillMetrics& metric_logger) {
// First, try to detect field types based on each field's |autocomplete|
// attribute value. If there is at least one form field that specifies an
// autocomplete type hint, don't try to apply other heuristics to match fields
// in this form.
bool has_author_specified_sections;
ParseFieldTypesFromAutocompleteAttributes(PARSE_FOR_AUTOFILL,
&has_author_specified_types_,
&has_author_specified_sections);
if (!has_author_specified_types_) {
ServerFieldTypeMap field_type_map;
FormField::ParseFormFields(fields_.get(), &field_type_map);
for (size_t i = 0; i < field_count(); ++i) {
AutofillField* field = fields_[i];
ServerFieldTypeMap::iterator iter =
field_type_map.find(field->unique_name());
if (iter != field_type_map.end())
field->set_heuristic_type(iter->second);
}
}
UpdateAutofillCount();
IdentifySections(has_author_specified_sections);
if (IsAutofillable(true)) {
metric_logger.LogDeveloperEngagementMetric(
AutofillMetrics::FILLABLE_FORM_PARSED);
if (has_author_specified_types_) {
metric_logger.LogDeveloperEngagementMetric(
AutofillMetrics::FILLABLE_FORM_CONTAINS_TYPE_HINTS);
}
}
}
bool FormStructure::EncodeUploadRequest(
const ServerFieldTypeSet& available_field_types,
bool form_was_autofilled,
std::string* encoded_xml) const {
DCHECK(ShouldBeCrowdsourced());
// Verify that |available_field_types| agrees with the possible field types we
// are uploading.
for (std::vector<AutofillField*>::const_iterator field = begin();
field != end();
++field) {
for (ServerFieldTypeSet::const_iterator type =
(*field)->possible_types().begin();
type != (*field)->possible_types().end();
++type) {
DCHECK(*type == UNKNOWN_TYPE ||
*type == EMPTY_TYPE ||
available_field_types.count(*type));
}
}
// Set up the <autofillupload> element and its attributes.
buzz::XmlElement autofill_request_xml(
(buzz::QName(kXMLElementAutofillUpload)));
autofill_request_xml.SetAttr(buzz::QName(kAttributeClientVersion),
kClientVersion);
autofill_request_xml.SetAttr(buzz::QName(kAttributeFormSignature),
FormSignature());
autofill_request_xml.SetAttr(buzz::QName(kAttributeAutofillUsed),
form_was_autofilled ? "true" : "false");
autofill_request_xml.SetAttr(buzz::QName(kAttributeDataPresent),
EncodeFieldTypes(available_field_types).c_str());
if (!EncodeFormRequest(FormStructure::UPLOAD, &autofill_request_xml))
return false; // Malformed form, skip it.
// Obtain the XML structure as a string.
*encoded_xml = kXMLDeclaration;
*encoded_xml += autofill_request_xml.Str().c_str();
// To enable this logging, run with the flag --vmodule="form_structure=2".
VLOG(2) << "\n" << *encoded_xml;
return true;
}
bool FormStructure::EncodeFieldAssignments(
const ServerFieldTypeSet& available_field_types,
std::string* encoded_xml) const {
DCHECK(ShouldBeCrowdsourced());
// Set up the <fieldassignments> element and its attributes.
buzz::XmlElement autofill_request_xml(
(buzz::QName(kXMLElementFieldAssignments)));
autofill_request_xml.SetAttr(buzz::QName(kAttributeFormSignature),
FormSignature());
if (!EncodeFormRequest(FormStructure::FIELD_ASSIGNMENTS,
&autofill_request_xml))
return false; // Malformed form, skip it.
// Obtain the XML structure as a string.
*encoded_xml = kXMLDeclaration;
*encoded_xml += autofill_request_xml.Str().c_str();
return true;
}
// static
bool FormStructure::EncodeQueryRequest(
const std::vector<FormStructure*>& forms,
std::vector<std::string>* encoded_signatures,
std::string* encoded_xml) {
DCHECK(encoded_signatures);
DCHECK(encoded_xml);
encoded_xml->clear();
encoded_signatures->clear();
encoded_signatures->reserve(forms.size());
// Set up the <autofillquery> element and attributes.
buzz::XmlElement autofill_request_xml(
(buzz::QName(kXMLElementAutofillQuery)));
autofill_request_xml.SetAttr(buzz::QName(kAttributeClientVersion),
kClientVersion);
// autocheckout_url_prefix tells the Autofill server where the forms in the
// request came from, and the the Autofill server checks internal status and
// decide to enable Autocheckout or not and may return Autocheckout related
// data in the response accordingly.
// There is no page/frame level object associated with FormStructure that
// we could extract URL prefix from. But, all the forms should come from the
// same frame, so they should have the same Autocheckout URL prefix. Thus we
// use URL prefix from the first form with Autocheckout enabled.
std::string autocheckout_url_prefix;
// Some badly formatted web sites repeat forms - detect that and encode only
// one form as returned data would be the same for all the repeated forms.
std::set<std::string> processed_forms;
for (ScopedVector<FormStructure>::const_iterator it = forms.begin();
it != forms.end();
++it) {
std::string signature((*it)->FormSignature());
if (processed_forms.find(signature) != processed_forms.end())
continue;
processed_forms.insert(signature);
scoped_ptr<buzz::XmlElement> encompassing_xml_element(
new buzz::XmlElement(buzz::QName(kXMLElementForm)));
encompassing_xml_element->SetAttr(buzz::QName(kAttributeSignature),
signature);
if (!(*it)->EncodeFormRequest(FormStructure::QUERY,
encompassing_xml_element.get()))
continue; // Malformed form, skip it.
if ((*it)->IsAutocheckoutEnabled()) {
if (autocheckout_url_prefix.empty()) {
autocheckout_url_prefix = (*it)->autocheckout_url_prefix_;
} else {
// Making sure all the forms in the request has the same url_prefix.
DCHECK_EQ(autocheckout_url_prefix, (*it)->autocheckout_url_prefix_);
}
}
autofill_request_xml.AddElement(encompassing_xml_element.release());
encoded_signatures->push_back(signature);
}
if (!encoded_signatures->size())
return false;
if (autocheckout_url_prefix.empty()) {
autofill_request_xml.SetAttr(buzz::QName(kAttributeAcceptedFeatures),
kAcceptedFeaturesExperiment);
} else {
autofill_request_xml.SetAttr(buzz::QName(kAttributeAcceptedFeatures),
kAcceptedFeaturesAutocheckoutExperiment);
autofill_request_xml.SetAttr(buzz::QName(kAttributeUrlprefixSignature),
Hash64Bit(autocheckout_url_prefix));
}
// Obtain the XML structure as a string.
*encoded_xml = kXMLDeclaration;
*encoded_xml += autofill_request_xml.Str().c_str();
return true;
}
// static
void FormStructure::ParseQueryResponse(
const std::string& response_xml,
const std::vector<FormStructure*>& forms,
autofill::AutocheckoutPageMetaData* page_meta_data,
const AutofillMetrics& metric_logger) {
metric_logger.LogServerQueryMetric(AutofillMetrics::QUERY_RESPONSE_RECEIVED);
// Parse the field types from the server response to the query.
std::vector<AutofillServerFieldInfo> field_infos;
UploadRequired upload_required;
std::string experiment_id;
AutofillQueryXmlParser parse_handler(&field_infos,
&upload_required,
&experiment_id,
page_meta_data);
buzz::XmlParser parser(&parse_handler);
parser.Parse(response_xml.c_str(), response_xml.length(), true);
if (!parse_handler.succeeded())
return;
metric_logger.LogServerQueryMetric(AutofillMetrics::QUERY_RESPONSE_PARSED);
metric_logger.LogServerExperimentIdForQuery(experiment_id);
bool heuristics_detected_fillable_field = false;
bool query_response_overrode_heuristics = false;
// Copy the field types into the actual form.
std::vector<AutofillServerFieldInfo>::iterator current_info =
field_infos.begin();
for (std::vector<FormStructure*>::const_iterator iter = forms.begin();
iter != forms.end(); ++iter) {
FormStructure* form = *iter;
form->upload_required_ = upload_required;
form->server_experiment_id_ = experiment_id;
for (std::vector<AutofillField*>::iterator field = form->fields_.begin();
field != form->fields_.end(); ++field) {
if (form->ShouldSkipField(**field))
continue;
// In some cases *successful* response does not return all the fields.
// Quit the update of the types then.
if (current_info == field_infos.end())
break;
// UNKNOWN_TYPE is reserved for use by the client.
DCHECK_NE(current_info->field_type, UNKNOWN_TYPE);
ServerFieldType heuristic_type = (*field)->heuristic_type();
if (heuristic_type != UNKNOWN_TYPE)
heuristics_detected_fillable_field = true;
(*field)->set_server_type(current_info->field_type);
if (heuristic_type != (*field)->Type().server_type())
query_response_overrode_heuristics = true;
// Copy default value into the field if available.
if (!current_info->default_value.empty())
(*field)->set_default_value(current_info->default_value);
++current_info;
}
form->UpdateAutofillCount();
form->IdentifySections(false);
}
AutofillMetrics::ServerQueryMetric metric;
if (query_response_overrode_heuristics) {
if (heuristics_detected_fillable_field) {
metric = AutofillMetrics::QUERY_RESPONSE_OVERRODE_LOCAL_HEURISTICS;
} else {
metric = AutofillMetrics::QUERY_RESPONSE_WITH_NO_LOCAL_HEURISTICS;
}
} else {
metric = AutofillMetrics::QUERY_RESPONSE_MATCHED_LOCAL_HEURISTICS;
}
metric_logger.LogServerQueryMetric(metric);
}
// static
void FormStructure::GetFieldTypePredictions(
const std::vector<FormStructure*>& form_structures,
std::vector<FormDataPredictions>* forms) {
forms->clear();
forms->reserve(form_structures.size());
for (size_t i = 0; i < form_structures.size(); ++i) {
FormStructure* form_structure = form_structures[i];
FormDataPredictions form;
form.data.name = form_structure->form_name_;
form.data.method =
ASCIIToUTF16((form_structure->method_ == POST) ? "POST" : "GET");
form.data.origin = form_structure->source_url_;
form.data.action = form_structure->target_url_;
form.signature = form_structure->FormSignature();
form.experiment_id = form_structure->server_experiment_id_;
for (std::vector<AutofillField*>::const_iterator field =
form_structure->fields_.begin();
field != form_structure->fields_.end(); ++field) {
form.data.fields.push_back(FormFieldData(**field));
FormFieldDataPredictions annotated_field;
annotated_field.signature = (*field)->FieldSignature();
annotated_field.heuristic_type =
AutofillType::FieldTypeToString((*field)->heuristic_type());
annotated_field.server_type =
AutofillType::FieldTypeToString((*field)->server_type());
annotated_field.overall_type =
AutofillType::FieldTypeToString((*field)->Type().server_type());
form.fields.push_back(annotated_field);
}
forms->push_back(form);
}
}
std::string FormStructure::FormSignature() const {
std::string scheme(target_url_.scheme());
std::string host(target_url_.host());
// If target host or scheme is empty, set scheme and host of source url.
// This is done to match the Toolbar's behavior.
if (scheme.empty() || host.empty()) {
scheme = source_url_.scheme();
host = source_url_.host();
}
std::string form_string = scheme + "://" + host + "&" +
UTF16ToUTF8(form_name_) +
form_signature_field_names_;
return Hash64Bit(form_string);
}
bool FormStructure::IsAutocheckoutEnabled() const {
return !autocheckout_url_prefix_.empty();
}
bool FormStructure::ShouldSkipField(const FormFieldData& field) const {
return (field.is_checkable || field.form_control_type == "password") &&
!IsAutocheckoutEnabled();
}
size_t FormStructure::RequiredFillableFields() const {
return IsAutocheckoutEnabled() ? 0 : kRequiredAutofillFields;
}
bool FormStructure::IsAutofillable(bool require_method_post) const {
if (autofill_count() < RequiredFillableFields())
return false;
return ShouldBeParsed(require_method_post);
}
void FormStructure::UpdateAutofillCount() {
autofill_count_ = 0;
for (std::vector<AutofillField*>::const_iterator iter = begin();
iter != end(); ++iter) {
AutofillField* field = *iter;
if (field && field->IsFieldFillable())
++autofill_count_;
}
}
bool FormStructure::ShouldBeParsed(bool require_method_post) const {
if (active_field_count() < RequiredFillableFields())
return false;
// Rule out http(s)://*/search?...
// e.g. http://www.google.com/search?q=...
// http://search.yahoo.com/search?p=...
if (target_url_.path() == "/search")
return false;
if (!IsAutocheckoutEnabled()) {
// Make sure there is at least one text field when Autocheckout is
// not enabled.
bool has_text_field = false;
for (std::vector<AutofillField*>::const_iterator it = begin();
it != end() && !has_text_field; ++it) {
has_text_field |= (*it)->form_control_type != "select-one";
}
if (!has_text_field)
return false;
}
return !require_method_post || (method_ == POST);
}
bool FormStructure::ShouldBeCrowdsourced() const {
// Allow all forms in Autocheckout flow to be crowdsourced.
return (!has_author_specified_types_ && ShouldBeParsed(true)) ||
IsAutocheckoutEnabled();
}
void FormStructure::UpdateFromCache(const FormStructure& cached_form) {
// Map from field signatures to cached fields.
std::map<std::string, const AutofillField*> cached_fields;
for (size_t i = 0; i < cached_form.field_count(); ++i) {
const AutofillField* field = cached_form.field(i);
cached_fields[field->FieldSignature()] = field;
}
for (std::vector<AutofillField*>::const_iterator iter = begin();
iter != end(); ++iter) {
AutofillField* field = *iter;
std::map<std::string, const AutofillField*>::const_iterator
cached_field = cached_fields.find(field->FieldSignature());
if (cached_field != cached_fields.end()) {
if (field->form_control_type != "select-one" &&
field->value == cached_field->second->value) {
// From the perspective of learning user data, text fields containing
// default values are equivalent to empty fields.
field->value = base::string16();
}
field->set_heuristic_type(cached_field->second->heuristic_type());
field->set_server_type(cached_field->second->server_type());
}
}
UpdateAutofillCount();
filled_by_autocheckout_ = cached_form.filled_by_autocheckout();
server_experiment_id_ = cached_form.server_experiment_id();
// The form signature should match between query and upload requests to the
// server. On many websites, form elements are dynamically added, removed, or
// rearranged via JavaScript between page load and form submission, so we
// copy over the |form_signature_field_names_| corresponding to the query
// request.
DCHECK_EQ(cached_form.form_name_, form_name_);
DCHECK_EQ(cached_form.source_url_, source_url_);
DCHECK_EQ(cached_form.target_url_, target_url_);
form_signature_field_names_ = cached_form.form_signature_field_names_;
}
void FormStructure::LogQualityMetrics(
const AutofillMetrics& metric_logger,
const base::TimeTicks& load_time,
const base::TimeTicks& interaction_time,
const base::TimeTicks& submission_time) const {
std::string experiment_id = server_experiment_id();
metric_logger.LogServerExperimentIdForUpload(experiment_id);
size_t num_detected_field_types = 0;
bool did_autofill_all_possible_fields = true;
bool did_autofill_some_possible_fields = false;
for (size_t i = 0; i < field_count(); ++i) {
const AutofillField* field = this->field(i);
metric_logger.LogQualityMetric(AutofillMetrics::FIELD_SUBMITTED,
experiment_id);
// No further logging for empty fields nor for fields where the entered data
// does not appear to already exist in the user's stored Autofill data.
const ServerFieldTypeSet& field_types = field->possible_types();
DCHECK(!field_types.empty());
if (field_types.count(EMPTY_TYPE) || field_types.count(UNKNOWN_TYPE))
continue;
++num_detected_field_types;
if (field->is_autofilled)
did_autofill_some_possible_fields = true;
else
did_autofill_all_possible_fields = false;
// Collapse field types that Chrome treats as identical, e.g. home and
// billing address fields.
ServerFieldTypeSet collapsed_field_types;
for (ServerFieldTypeSet::const_iterator it = field_types.begin();
it != field_types.end();
++it) {
// Since we currently only support US phone numbers, the (city code + main
// digits) number is almost always identical to the whole phone number.
// TODO(isherman): Improve this logic once we add support for
// international numbers.
if (*it == PHONE_HOME_CITY_AND_NUMBER)
collapsed_field_types.insert(PHONE_HOME_WHOLE_NUMBER);
else
collapsed_field_types.insert(AutofillType::GetEquivalentFieldType(*it));
}
// Capture the field's type, if it is unambiguous.
ServerFieldType field_type = UNKNOWN_TYPE;
if (collapsed_field_types.size() == 1)
field_type = *collapsed_field_types.begin();
ServerFieldType heuristic_type = field->heuristic_type();
ServerFieldType server_type = field->server_type();
ServerFieldType predicted_type = field->Type().server_type();
// Log heuristic, server, and overall type quality metrics, independently of
// whether the field was autofilled.
if (heuristic_type == UNKNOWN_TYPE) {
metric_logger.LogHeuristicTypePrediction(AutofillMetrics::TYPE_UNKNOWN,
field_type, experiment_id);
} else if (field_types.count(heuristic_type)) {
metric_logger.LogHeuristicTypePrediction(AutofillMetrics::TYPE_MATCH,
field_type, experiment_id);
} else {
metric_logger.LogHeuristicTypePrediction(AutofillMetrics::TYPE_MISMATCH,
field_type, experiment_id);
}
if (server_type == NO_SERVER_DATA) {
metric_logger.LogServerTypePrediction(AutofillMetrics::TYPE_UNKNOWN,
field_type, experiment_id);
} else if (field_types.count(server_type)) {
metric_logger.LogServerTypePrediction(AutofillMetrics::TYPE_MATCH,
field_type, experiment_id);
} else {
metric_logger.LogServerTypePrediction(AutofillMetrics::TYPE_MISMATCH,
field_type, experiment_id);
}
if (predicted_type == UNKNOWN_TYPE) {
metric_logger.LogOverallTypePrediction(AutofillMetrics::TYPE_UNKNOWN,
field_type, experiment_id);
} else if (field_types.count(predicted_type)) {
metric_logger.LogOverallTypePrediction(AutofillMetrics::TYPE_MATCH,
field_type, experiment_id);
} else {
metric_logger.LogOverallTypePrediction(AutofillMetrics::TYPE_MISMATCH,
field_type, experiment_id);
}
// TODO(isherman): <select> fields don't support |is_autofilled()|, so we
// have to skip them for the remaining metrics.
if (field->form_control_type == "select-one")
continue;
if (field->is_autofilled) {
metric_logger.LogQualityMetric(AutofillMetrics::FIELD_AUTOFILLED,
experiment_id);
} else {
metric_logger.LogQualityMetric(AutofillMetrics::FIELD_NOT_AUTOFILLED,
experiment_id);
if (heuristic_type == UNKNOWN_TYPE) {
metric_logger.LogQualityMetric(
AutofillMetrics::NOT_AUTOFILLED_HEURISTIC_TYPE_UNKNOWN,
experiment_id);
} else if (field_types.count(heuristic_type)) {
metric_logger.LogQualityMetric(
AutofillMetrics::NOT_AUTOFILLED_HEURISTIC_TYPE_MATCH,
experiment_id);
} else {
metric_logger.LogQualityMetric(
AutofillMetrics::NOT_AUTOFILLED_HEURISTIC_TYPE_MISMATCH,
experiment_id);
}
if (server_type == NO_SERVER_DATA) {
metric_logger.LogQualityMetric(
AutofillMetrics::NOT_AUTOFILLED_SERVER_TYPE_UNKNOWN,
experiment_id);
} else if (field_types.count(server_type)) {
metric_logger.LogQualityMetric(
AutofillMetrics::NOT_AUTOFILLED_SERVER_TYPE_MATCH,
experiment_id);
} else {
metric_logger.LogQualityMetric(
AutofillMetrics::NOT_AUTOFILLED_SERVER_TYPE_MISMATCH,
experiment_id);
}
}
}
if (num_detected_field_types < RequiredFillableFields()) {
metric_logger.LogUserHappinessMetric(
AutofillMetrics::SUBMITTED_NON_FILLABLE_FORM);
} else {
if (did_autofill_all_possible_fields) {
metric_logger.LogUserHappinessMetric(
AutofillMetrics::SUBMITTED_FILLABLE_FORM_AUTOFILLED_ALL);
} else if (did_autofill_some_possible_fields) {
metric_logger.LogUserHappinessMetric(
AutofillMetrics::SUBMITTED_FILLABLE_FORM_AUTOFILLED_SOME);
} else {
metric_logger.LogUserHappinessMetric(
AutofillMetrics::SUBMITTED_FILLABLE_FORM_AUTOFILLED_NONE);
}
// Unlike the other times, the |submission_time| should always be available.
DCHECK(!submission_time.is_null());
// The |load_time| might be unset, in the case that the form was dynamically
// added to the DOM.
if (!load_time.is_null()) {
// Submission should always chronologically follow form load.
DCHECK(submission_time > load_time);
base::TimeDelta elapsed = submission_time - load_time;
if (did_autofill_some_possible_fields)
metric_logger.LogFormFillDurationFromLoadWithAutofill(elapsed);
else
metric_logger.LogFormFillDurationFromLoadWithoutAutofill(elapsed);
}
// The |interaction_time| might be unset, in the case that the user
// submitted a blank form.
if (!interaction_time.is_null()) {
// Submission should always chronologically follow interaction.
DCHECK(submission_time > interaction_time);
base::TimeDelta elapsed = submission_time - interaction_time;
if (did_autofill_some_possible_fields) {
metric_logger.LogFormFillDurationFromInteractionWithAutofill(elapsed);
} else {
metric_logger.LogFormFillDurationFromInteractionWithoutAutofill(
elapsed);
}
}
}
}
const AutofillField* FormStructure::field(size_t index) const {
if (index >= fields_.size()) {
NOTREACHED();
return NULL;
}
return fields_[index];
}
AutofillField* FormStructure::field(size_t index) {
return const_cast<AutofillField*>(
static_cast<const FormStructure*>(this)->field(index));
}
size_t FormStructure::field_count() const {
return fields_.size();
}
size_t FormStructure::active_field_count() const {
return active_field_count_;
}
std::string FormStructure::server_experiment_id() const {
return server_experiment_id_;
}
FormData FormStructure::ToFormData() const {
// |data.user_submitted| will always be false.
FormData data;
data.name = form_name_;
data.origin = source_url_;
data.action = target_url_;
data.method = ASCIIToUTF16(method_ == POST ? "POST" : "GET");
for (size_t i = 0; i < fields_.size(); ++i) {
data.fields.push_back(FormFieldData(*fields_[i]));
}
return data;
}
bool FormStructure::operator==(const FormData& form) const {
// TODO(jhawkins): Is this enough to differentiate a form?
if (form_name_ == form.name &&
source_url_ == form.origin &&
target_url_ == form.action) {
return true;
}
// TODO(jhawkins): Compare field names, IDs and labels once we have labels
// set up.
return false;
}
bool FormStructure::operator!=(const FormData& form) const {
return !operator==(form);
}
std::string FormStructure::Hash64Bit(const std::string& str) {
std::string hash_bin = base::SHA1HashString(str);
DCHECK_EQ(20U, hash_bin.length());
uint64 hash64 = (((static_cast<uint64>(hash_bin[0])) & 0xFF) << 56) |
(((static_cast<uint64>(hash_bin[1])) & 0xFF) << 48) |
(((static_cast<uint64>(hash_bin[2])) & 0xFF) << 40) |
(((static_cast<uint64>(hash_bin[3])) & 0xFF) << 32) |
(((static_cast<uint64>(hash_bin[4])) & 0xFF) << 24) |
(((static_cast<uint64>(hash_bin[5])) & 0xFF) << 16) |
(((static_cast<uint64>(hash_bin[6])) & 0xFF) << 8) |
((static_cast<uint64>(hash_bin[7])) & 0xFF);
return base::Uint64ToString(hash64);
}
bool FormStructure::EncodeFormRequest(
FormStructure::EncodeRequestType request_type,
buzz::XmlElement* encompassing_xml_element) const {
if (!field_count()) // Nothing to add.
return false;
// Some badly formatted web sites repeat fields - limit number of fields to
// 48, which is far larger than any valid form and XML still fits into 2K.
// Do not send requests for forms with more than this many fields, as they are
// near certainly not valid/auto-fillable.
const size_t kMaxFieldsOnTheForm = 48;
if (field_count() > kMaxFieldsOnTheForm)
return false;
// Add the child nodes for the form fields.
for (size_t index = 0; index < field_count(); ++index) {
const AutofillField* field = fields_[index];
switch (request_type) {
case FormStructure::UPLOAD:
EncodeFieldForUpload(*field, encompassing_xml_element);
break;
case FormStructure::QUERY:
if (ShouldSkipField(*field))
continue;
EncodeFieldForQuery(*field, encompassing_xml_element);
break;
case FormStructure::FIELD_ASSIGNMENTS:
EncodeFieldForFieldAssignments(*field, encompassing_xml_element);
break;
}
}
return true;
}
void FormStructure::ParseFieldTypesFromAutocompleteAttributes(
ParseTarget parse_target,
bool* found_types,
bool* found_sections) {
const std::string kDefaultSection = "-default";
*found_types = false;
*found_sections = false;
for (std::vector<AutofillField*>::iterator it = fields_.begin();
it != fields_.end(); ++it) {
AutofillField* field = *it;
// To prevent potential section name collisions, add a default suffix for
// other fields. Without this, 'autocomplete' attribute values
// "section--shipping street-address" and "shipping street-address" would be
// parsed identically, given the section handling code below. We do this
// before any validation so that fields with invalid attributes still end up
// in the default section. These default section names will be overridden
// by subsequent heuristic parsing steps if there are no author-specified
// section names.
field->set_section(kDefaultSection);
// Canonicalize the attribute value by trimming whitespace, collapsing
// non-space characters (e.g. tab) to spaces, and converting to lowercase.
std::string autocomplete_attribute =
CollapseWhitespaceASCII(field->autocomplete_attribute, false);
autocomplete_attribute = StringToLowerASCII(autocomplete_attribute);
// The autocomplete attribute is overloaded: it can specify either a field
// type hint or whether autocomplete should be enabled at all. Ignore the
// latter type of attribute value.
if (autocomplete_attribute.empty() ||
autocomplete_attribute == "on" ||
autocomplete_attribute == "off") {
continue;
}
// Any other value, even it is invalid, is considered to be a type hint.
// This allows a website's author to specify an attribute like
// autocomplete="other" on a field to disable all Autofill heuristics for
// the form.
*found_types = true;
// Tokenize the attribute value. Per the spec, the tokens are parsed in
// reverse order.
std::vector<std::string> tokens;
Tokenize(autocomplete_attribute, " ", &tokens);
// The final token must be the field type.
// If it is not one of the known types, abort.
DCHECK(!tokens.empty());
std::string field_type_token = tokens.back();
tokens.pop_back();
ServerFieldType field_type =
FieldTypeFromAutocompleteType(field_type_token, *field);
if (field_type == UNKNOWN_TYPE)
continue;
// The preceding token, if any, may be a type hint.
if (!tokens.empty() && IsContactTypeHint(tokens.back())) {
// If it is, it must match the field type; otherwise, abort.
// Note that an invalid token invalidates the entire attribute value, even
// if the other tokens are valid.
if (!ContactTypeHintMatchesFieldType(tokens.back(), field_type))
continue;
// Chrome Autofill ignores these type hints.
tokens.pop_back();
}
// The preceding token, if any, may be a fixed string that is either
// "shipping" or "billing". Chrome Autofill treats these as implicit
// section name suffixes.
DCHECK_EQ(kDefaultSection, field->section());
std::string section = field->section();
if (!tokens.empty() &&
(tokens.back() == kShippingSection ||
tokens.back() == kBillingSection)) {
// Set Autofill field type to billing if section is billing.
if (tokens.back() == kBillingSection) {
field_type = AutofillType::GetEquivalentBillingFieldType(field_type);
// The Autofill dialog uses the type CREDIT_CARD_NAME to refer to both
// the credit card holder's name and the name on the billing address.
if (parse_target == PARSE_FOR_AUTOFILL_DIALOG &&
field_type == NAME_FULL) {
field_type = CREDIT_CARD_NAME;
}
}
section = "-" + tokens.back();
tokens.pop_back();
}
// The preceding token, if any, may be a named section.
const std::string kSectionPrefix = "section-";
if (!tokens.empty() &&
StartsWithASCII(tokens.back(), kSectionPrefix, true)) {
// Prepend this section name to the suffix set in the preceding block.
section = tokens.back().substr(kSectionPrefix.size()) + section;
tokens.pop_back();
}
// No other tokens are allowed. If there are any remaining, abort.
if (!tokens.empty())
continue;
if (section != kDefaultSection) {
*found_sections = true;
field->set_section(section);
}
// No errors encountered while parsing!
// Update the |field|'s type based on what was parsed from the attribute.
field->set_heuristic_type(field_type);
if (field_type_token == "tel-local-prefix")
field->set_phone_part(AutofillField::PHONE_PREFIX);
else if (field_type_token == "tel-local-suffix")
field->set_phone_part(AutofillField::PHONE_SUFFIX);
}
}
void FormStructure::IdentifySections(bool has_author_specified_sections) {
if (fields_.empty())
return;
if (!has_author_specified_sections) {
// Name sections after the first field in the section.
base::string16 current_section = fields_.front()->unique_name();
// Keep track of the types we've seen in this section.
std::set<ServerFieldType> seen_types;
ServerFieldType previous_type = UNKNOWN_TYPE;
for (std::vector<AutofillField*>::iterator field = fields_.begin();
field != fields_.end(); ++field) {
const ServerFieldType current_type =
AutofillType::GetEquivalentFieldType((*field)->Type().server_type());
bool already_saw_current_type = seen_types.count(current_type) > 0;
// Forms often ask for multiple phone numbers -- e.g. both a daytime and
// evening phone number. Our phone number detection is also generally a
// little off. Hence, ignore this field type as a signal here.
if (AutofillType(current_type).group() == PHONE_HOME)
already_saw_current_type = false;
// Some forms have adjacent fields of the same type. Two common examples:
// * Forms with two email fields, where the second is meant to "confirm"
// the first.
// * Forms with a <select> menu for states in some countries, and a
// freeform <input> field for states in other countries. (Usually,
// only one of these two will be visible for any given choice of
// country.)
// Generally, adjacent fields of the same type belong in the same logical
// section.
if (current_type == previous_type)
already_saw_current_type = false;
previous_type = current_type;
if (current_type != UNKNOWN_TYPE && already_saw_current_type) {
// We reached the end of a section, so start a new section.
seen_types.clear();
current_section = (*field)->unique_name();
}
seen_types.insert(current_type);
(*field)->set_section(UTF16ToUTF8(current_section));
}
}
// Ensure that credit card and address fields are in separate sections.
// This simplifies the section-aware logic in autofill_manager.cc.
for (std::vector<AutofillField*>::iterator field = fields_.begin();
field != fields_.end(); ++field) {
FieldTypeGroup field_type_group = (*field)->Type().group();
if (field_type_group == CREDIT_CARD)
(*field)->set_section((*field)->section() + "-cc");
else
(*field)->set_section((*field)->section() + "-default");
}
}
} // namespace autofill