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|
// © 2024 and later: Unicode, Inc. and others.
// License & terms of use: http://www.unicode.org/copyright.html
#include "unicode/utypes.h"
#if !UCONFIG_NO_FORMATTING
#if !UCONFIG_NO_MF2
#include "unicode/messageformat2_arguments.h"
#include "unicode/messageformat2_data_model.h"
#include "unicode/messageformat2_formattable.h"
#include "unicode/messageformat2.h"
#include "unicode/unistr.h"
#include "messageformat2_allocation.h"
#include "messageformat2_evaluation.h"
#include "messageformat2_macros.h"
U_NAMESPACE_BEGIN
namespace message2 {
using namespace data_model;
// ------------------------------------------------------
// Formatting
// The result of formatting a literal is just itself.
static Formattable evalLiteral(const Literal& lit) {
return Formattable(lit.unquoted());
}
// Assumes that `var` is a message argument; returns the argument's value.
[[nodiscard]] FormattedPlaceholder MessageFormatter::evalArgument(const VariableName& var, MessageContext& context, UErrorCode& errorCode) const {
if (U_SUCCESS(errorCode)) {
// The fallback for a variable name is itself.
UnicodeString str(DOLLAR);
str += var;
const Formattable* val = context.getGlobal(var, errorCode);
if (U_SUCCESS(errorCode)) {
return (FormattedPlaceholder(*val, str));
}
}
return {};
}
// Returns the contents of the literal
[[nodiscard]] FormattedPlaceholder MessageFormatter::formatLiteral(const Literal& lit) const {
// The fallback for a literal is itself.
return FormattedPlaceholder(evalLiteral(lit), lit.quoted());
}
[[nodiscard]] FormattedPlaceholder MessageFormatter::formatOperand(const Environment& env,
const Operand& rand,
MessageContext& context,
UErrorCode &status) const {
if (U_FAILURE(status)) {
return {};
}
if (rand.isNull()) {
return FormattedPlaceholder();
}
if (rand.isVariable()) {
// Check if it's local or global
// Note: there is no name shadowing; this is enforced by the parser
const VariableName& var = rand.asVariable();
// TODO: Currently, this code implements lazy evaluation of locals.
// That is, the environment binds names to a closure, not a resolved value.
// Eager vs. lazy evaluation is an open issue:
// see https://github.com/unicode-org/message-format-wg/issues/299
// Look up the variable in the environment
if (env.has(var)) {
// `var` is a local -- look it up
const Closure& rhs = env.lookup(var);
// Format the expression using the environment from the closure
return formatExpression(rhs.getEnv(), rhs.getExpr(), context, status);
}
// Variable wasn't found in locals -- check if it's global
FormattedPlaceholder result = evalArgument(var, context, status);
if (status == U_ILLEGAL_ARGUMENT_ERROR) {
status = U_ZERO_ERROR;
// Unbound variable -- set a resolution error
context.getErrors().setUnresolvedVariable(var, status);
// Use fallback per
// https://github.com/unicode-org/message-format-wg/blob/main/spec/formatting.md#fallback-resolution
UnicodeString str(DOLLAR);
str += var;
return FormattedPlaceholder(str);
}
return result;
} else {
U_ASSERT(rand.isLiteral());
return formatLiteral(rand.asLiteral());
}
}
// Resolves a function's options
FunctionOptions MessageFormatter::resolveOptions(const Environment& env, const OptionMap& options, MessageContext& context, UErrorCode& status) const {
LocalPointer<UVector> optionsVector(createUVector(status));
if (U_FAILURE(status)) {
return {};
}
LocalPointer<ResolvedFunctionOption> resolvedOpt;
for (int i = 0; i < options.size(); i++) {
const Option& opt = options.getOption(i, status);
if (U_FAILURE(status)) {
return {};
}
const UnicodeString& k = opt.getName();
const Operand& v = opt.getValue();
// Options are fully evaluated before calling the function
// Format the operand
FormattedPlaceholder rhsVal = formatOperand(env, v, context, status);
if (U_FAILURE(status)) {
return {};
}
if (!rhsVal.isFallback()) {
resolvedOpt.adoptInstead(create<ResolvedFunctionOption>(ResolvedFunctionOption(k, rhsVal.asFormattable()), status));
if (U_FAILURE(status)) {
return {};
}
optionsVector->adoptElement(resolvedOpt.orphan(), status);
}
}
return FunctionOptions(std::move(*optionsVector), status);
}
// Overload that dispatches on argument type. Syntax doesn't provide for options in this case.
[[nodiscard]] FormattedPlaceholder MessageFormatter::evalFormatterCall(FormattedPlaceholder&& argument,
MessageContext& context,
UErrorCode& status) const {
if (U_FAILURE(status)) {
return {};
}
// These cases should have been checked for already
U_ASSERT(!argument.isFallback() && !argument.isNullOperand());
const Formattable& toFormat = argument.asFormattable();
switch (toFormat.getType()) {
case UFMT_OBJECT: {
const FormattableObject* obj = toFormat.getObject(status);
U_ASSERT(U_SUCCESS(status));
U_ASSERT(obj != nullptr);
const UnicodeString& type = obj->tag();
FunctionName functionName;
if (!getDefaultFormatterNameByType(type, functionName)) {
// No formatter for this type -- follow default behavior
break;
}
return evalFormatterCall(functionName,
std::move(argument),
FunctionOptions(),
context,
status);
}
default: {
// TODO: The array case isn't handled yet; not sure whether it's desirable
// to have a default list formatter
break;
}
}
// No formatter for this type, or it's a primitive type (which will be formatted later)
// -- just return the argument itself
return std::move(argument);
}
// Overload that dispatches on function name
[[nodiscard]] FormattedPlaceholder MessageFormatter::evalFormatterCall(const FunctionName& functionName,
FormattedPlaceholder&& argument,
FunctionOptions&& options,
MessageContext& context,
UErrorCode& status) const {
if (U_FAILURE(status)) {
return {};
}
DynamicErrors& errs = context.getErrors();
UnicodeString fallback(COLON);
fallback += functionName;
if (!argument.isNullOperand()) {
fallback = argument.fallback;
}
if (isFormatter(functionName)) {
LocalPointer<Formatter> formatterImpl(getFormatter(functionName, status));
if (U_FAILURE(status)) {
if (status == U_MF_FORMATTING_ERROR) {
errs.setFormattingError(functionName, status);
status = U_ZERO_ERROR;
return {};
}
if (status == U_MF_UNKNOWN_FUNCTION_ERROR) {
errs.setUnknownFunction(functionName, status);
status = U_ZERO_ERROR;
return {};
}
// Other errors are non-recoverable
return {};
}
U_ASSERT(formatterImpl != nullptr);
UErrorCode savedStatus = status;
FormattedPlaceholder result = formatterImpl->format(std::move(argument), std::move(options), status);
// Update errors
if (savedStatus != status) {
if (U_FAILURE(status)) {
if (status == U_MF_OPERAND_MISMATCH_ERROR) {
status = U_ZERO_ERROR;
errs.setOperandMismatchError(functionName, status);
} else {
status = U_ZERO_ERROR;
// Convey any error generated by the formatter
// as a formatting error, except for operand mismatch errors
errs.setFormattingError(functionName, status);
}
return FormattedPlaceholder(fallback);
} else {
// Ignore warnings
status = savedStatus;
}
}
// Ignore the output if any errors occurred
if (errs.hasFormattingError()) {
return FormattedPlaceholder(fallback);
}
return result;
}
// No formatter with this name -- set error
if (isSelector(functionName)) {
errs.setFormattingError(functionName, status);
} else {
errs.setUnknownFunction(functionName, status);
}
return FormattedPlaceholder(fallback);
}
// Per https://github.com/unicode-org/message-format-wg/blob/main/spec/formatting.md#fallback-resolution
static UnicodeString reservedFallback (const Expression& e) {
UErrorCode localErrorCode = U_ZERO_ERROR;
const Operator* rator = e.getOperator(localErrorCode);
U_ASSERT(U_SUCCESS(localErrorCode));
const Reserved& r = rator->asReserved();
// An empty Reserved isn't representable in the syntax
U_ASSERT(r.numParts() > 0);
const UnicodeString& contents = r.getPart(0).unquoted();
// Parts should never be empty
U_ASSERT(contents.length() > 0);
// Return first character of string
return UnicodeString(contents, 0, 1);
}
// Formats an expression using `globalEnv` for the values of variables
[[nodiscard]] FormattedPlaceholder MessageFormatter::formatExpression(const Environment& globalEnv,
const Expression& expr,
MessageContext& context,
UErrorCode &status) const {
if (U_FAILURE(status)) {
return {};
}
// Formatting error
if (expr.isReserved()) {
context.getErrors().setReservedError(status);
return FormattedPlaceholder(reservedFallback(expr));
}
const Operand& rand = expr.getOperand();
// Format the operand (formatOperand handles the case of a null operand)
FormattedPlaceholder randVal = formatOperand(globalEnv, rand, context, status);
// Don't call the function on error values
if (randVal.isFallback()) {
return randVal;
}
if (!expr.isFunctionCall()) {
// Dispatch based on type of `randVal`
return evalFormatterCall(std::move(randVal),
context,
status);
} else {
const Operator* rator = expr.getOperator(status);
U_ASSERT(U_SUCCESS(status));
const FunctionName& functionName = rator->getFunctionName();
const OptionMap& options = rator->getOptionsInternal();
// Resolve the options
FunctionOptions resolvedOptions = resolveOptions(globalEnv, options, context, status);
// Call the formatter function
// The fallback for a nullary function call is the function name
UnicodeString fallback;
if (rand.isNull()) {
fallback = UnicodeString(COLON);
fallback += functionName;
} else {
fallback = randVal.fallback;
}
return evalFormatterCall(functionName,
std::move(randVal),
std::move(resolvedOptions),
context,
status);
}
}
// Formats each text and expression part of a pattern, appending the results to `result`
void MessageFormatter::formatPattern(MessageContext& context, const Environment& globalEnv, const Pattern& pat, UErrorCode &status, UnicodeString& result) const {
CHECK_ERROR(status);
for (int32_t i = 0; i < pat.numParts(); i++) {
const PatternPart& part = pat.getPart(i);
if (part.isText()) {
result += part.asText();
} else if (part.isMarkup()) {
// Markup is ignored
} else {
// Format the expression
FormattedPlaceholder partVal = formatExpression(globalEnv, part.contents(), context, status);
// Force full evaluation, e.g. applying default formatters to
// unformatted input (or formatting numbers as strings)
UnicodeString partResult = partVal.formatToString(locale, status);
result += partResult;
// Handle formatting errors. `formatToString()` can't take a context and thus can't
// register an error directly
if (status == U_MF_FORMATTING_ERROR) {
status = U_ZERO_ERROR;
// TODO: The name of the formatter that failed is unavailable.
// Not ideal, but it's hard for `formatToString()`
// to pass along more detailed diagnostics
context.getErrors().setFormattingError(status);
}
}
}
}
// ------------------------------------------------------
// Selection
// See https://github.com/unicode-org/message-format-wg/blob/main/spec/formatting.md#resolve-selectors
// `res` is a vector of ResolvedSelectors
void MessageFormatter::resolveSelectors(MessageContext& context, const Environment& env, UErrorCode &status, UVector& res) const {
CHECK_ERROR(status);
U_ASSERT(!dataModel.hasPattern());
const Expression* selectors = dataModel.getSelectorsInternal();
// 1. Let res be a new empty list of resolved values that support selection.
// (Implicit, since `res` is an out-parameter)
// 2. For each expression exp of the message's selectors
for (int32_t i = 0; i < dataModel.numSelectors(); i++) {
// 2i. Let rv be the resolved value of exp.
ResolvedSelector rv = formatSelectorExpression(env, selectors[i], context, status);
if (rv.hasSelector()) {
// 2ii. If selection is supported for rv:
// (True if this code has been reached)
} else {
// 2iii. Else:
// Let nomatch be a resolved value for which selection always fails.
// Append nomatch as the last element of the list res.
// Emit a Selection Error.
// (Note: in this case, rv, being a fallback, serves as `nomatch`)
#if U_DEBUG
const DynamicErrors& err = context.getErrors();
U_ASSERT(err.hasError());
U_ASSERT(rv.argument().isFallback());
#endif
}
// 2ii(a). Append rv as the last element of the list res.
// (Also fulfills 2iii)
LocalPointer<ResolvedSelector> v(create<ResolvedSelector>(std::move(rv), status));
CHECK_ERROR(status);
res.adoptElement(v.orphan(), status);
}
}
// See https://github.com/unicode-org/message-format-wg/blob/main/spec/formatting.md#resolve-preferences
// `keys` and `matches` are vectors of strings
void MessageFormatter::matchSelectorKeys(const UVector& keys,
MessageContext& context,
ResolvedSelector&& rv,
UVector& keysOut,
UErrorCode& status) const {
CHECK_ERROR(status);
if (!rv.hasSelector()) {
// Return an empty list of matches
return;
}
auto selectorImpl = rv.getSelector();
U_ASSERT(selectorImpl != nullptr);
UErrorCode savedStatus = status;
// Convert `keys` to an array
int32_t keysLen = keys.size();
UnicodeString* keysArr = new UnicodeString[keysLen];
if (keysArr == nullptr) {
status = U_MEMORY_ALLOCATION_ERROR;
return;
}
for (int32_t i = 0; i < keysLen; i++) {
const UnicodeString* k = static_cast<UnicodeString*>(keys[i]);
U_ASSERT(k != nullptr);
keysArr[i] = *k;
}
LocalArray<UnicodeString> adoptedKeys(keysArr);
// Create an array to hold the output
UnicodeString* prefsArr = new UnicodeString[keysLen];
if (prefsArr == nullptr) {
status = U_MEMORY_ALLOCATION_ERROR;
return;
}
LocalArray<UnicodeString> adoptedPrefs(prefsArr);
int32_t prefsLen = 0;
// Call the selector
selectorImpl->selectKey(rv.takeArgument(), rv.takeOptions(),
adoptedKeys.getAlias(), keysLen, adoptedPrefs.getAlias(), prefsLen,
status);
// Update errors
if (savedStatus != status) {
if (U_FAILURE(status)) {
status = U_ZERO_ERROR;
context.getErrors().setSelectorError(rv.getSelectorName(), status);
} else {
// Ignore warnings
status = savedStatus;
}
}
CHECK_ERROR(status);
// Copy the resulting keys (if there was no error)
keysOut.removeAllElements();
for (int32_t i = 0; i < prefsLen; i++) {
UnicodeString* k = message2::create<UnicodeString>(std::move(prefsArr[i]), status);
if (k == nullptr) {
status = U_MEMORY_ALLOCATION_ERROR;
return;
}
keysOut.adoptElement(k, status);
CHECK_ERROR(status);
}
}
// See https://github.com/unicode-org/message-format-wg/blob/main/spec/formatting.md#resolve-preferences
// `res` is a vector of FormattedPlaceholders;
// `pref` is a vector of vectors of strings
void MessageFormatter::resolvePreferences(MessageContext& context, UVector& res, UVector& pref, UErrorCode &status) const {
CHECK_ERROR(status);
// 1. Let pref be a new empty list of lists of strings.
// (Implicit, since `pref` is an out-parameter)
UnicodeString ks;
LocalPointer<UnicodeString> ksP;
int32_t numVariants = dataModel.numVariants();
const Variant* variants = dataModel.getVariantsInternal();
// 2. For each index i in res
for (int32_t i = 0; i < (int32_t) res.size(); i++) {
// 2i. Let keys be a new empty list of strings.
LocalPointer<UVector> keys(createUVector(status));
CHECK_ERROR(status);
// 2ii. For each variant `var` of the message
for (int32_t variantNum = 0; variantNum < numVariants; variantNum++) {
const SelectorKeys& selectorKeys = variants[variantNum].getKeys();
// Note: Here, `var` names the key list of `var`,
// not a Variant itself
const Key* var = selectorKeys.getKeysInternal();
// 2ii(a). Let `key` be the `var` key at position i.
U_ASSERT(i < selectorKeys.len); // established by semantic check in formatSelectors()
const Key& key = var[i];
// 2ii(b). If `key` is not the catch-all key '*'
if (!key.isWildcard()) {
// 2ii(b)(a) Assert that key is a literal.
// (Not needed)
// 2ii(b)(b) Let `ks` be the resolved value of `key`.
ks = key.asLiteral().unquoted();
// 2ii(b)(c) Append `ks` as the last element of the list `keys`.
ksP.adoptInstead(create<UnicodeString>(std::move(ks), status));
CHECK_ERROR(status);
keys->adoptElement(ksP.orphan(), status);
}
}
// 2iii. Let `rv` be the resolved value at index `i` of `res`.
U_ASSERT(i < res.size());
ResolvedSelector rv = std::move(*(static_cast<ResolvedSelector*>(res[i])));
// 2iv. Let matches be the result of calling the method MatchSelectorKeys(rv, keys)
LocalPointer<UVector> matches(createUVector(status));
matchSelectorKeys(*keys, context, std::move(rv), *matches, status);
// 2v. Append `matches` as the last element of the list `pref`
pref.adoptElement(matches.orphan(), status);
}
}
// `v` is assumed to be a vector of strings
static int32_t vectorFind(const UVector& v, const UnicodeString& k) {
for (int32_t i = 0; i < v.size(); i++) {
if (*static_cast<UnicodeString*>(v[i]) == k) {
return i;
}
}
return -1;
}
static UBool vectorContains(const UVector& v, const UnicodeString& k) {
return (vectorFind(v, k) != -1);
}
// See https://github.com/unicode-org/message-format-wg/blob/main/spec/formatting.md#filter-variants
// `pref` is a vector of vectors of strings. `vars` is a vector of PrioritizedVariants
void MessageFormatter::filterVariants(const UVector& pref, UVector& vars, UErrorCode& status) const {
const Variant* variants = dataModel.getVariantsInternal();
// 1. Let `vars` be a new empty list of variants.
// (Not needed since `vars` is an out-parameter)
// 2. For each variant `var` of the message:
for (int32_t j = 0; j < dataModel.numVariants(); j++) {
const SelectorKeys& selectorKeys = variants[j].getKeys();
const Pattern& p = variants[j].getPattern();
// Note: Here, `var` names the key list of `var`,
// not a Variant itself
const Key* var = selectorKeys.getKeysInternal();
// 2i. For each index `i` in `pref`:
bool noMatch = false;
for (int32_t i = 0; i < (int32_t) pref.size(); i++) {
// 2i(a). Let `key` be the `var` key at position `i`.
U_ASSERT(i < selectorKeys.len);
const Key& key = var[i];
// 2i(b). If key is the catch-all key '*':
if (key.isWildcard()) {
// 2i(b)(a). Continue the inner loop on pref.
continue;
}
// 2i(c). Assert that `key` is a literal.
// (Not needed)
// 2i(d). Let `ks` be the resolved value of `key`.
UnicodeString ks = key.asLiteral().unquoted();
// 2i(e). Let `matches` be the list of strings at index `i` of `pref`.
const UVector& matches = *(static_cast<UVector*>(pref[i])); // `matches` is a vector of strings
// 2i(f). If `matches` includes `ks`
if (vectorContains(matches, ks)) {
// 2i(f)(a). Continue the inner loop on `pref`.
continue;
}
// 2i(g). Else:
// 2i(g)(a). Continue the outer loop on message variants.
noMatch = true;
break;
}
if (!noMatch) {
// Append `var` as the last element of the list `vars`.
PrioritizedVariant* tuple = create<PrioritizedVariant>(PrioritizedVariant(-1, selectorKeys, p), status);
CHECK_ERROR(status);
vars.adoptElement(tuple, status);
}
}
}
// See https://github.com/unicode-org/message-format-wg/blob/main/spec/formatting.md#sort-variants
// Leaves the preferred variant as element 0 in `sortable`
// Note: this sorts in-place, so `sortable` is just `vars`
// `pref` is a vector of vectors of strings; `vars` is a vector of PrioritizedVariants
void MessageFormatter::sortVariants(const UVector& pref, UVector& vars, UErrorCode& status) const {
CHECK_ERROR(status);
// Note: steps 1 and 2 are omitted since we use `vars` as `sortable` (we sort in-place)
// 1. Let `sortable` be a new empty list of (integer, variant) tuples.
// (Not needed since `sortable` is an out-parameter)
// 2. For each variant `var` of `vars`
// 2i. Let tuple be a new tuple (-1, var).
// 2ii. Append `tuple` as the last element of the list `sortable`.
// 3. Let `len` be the integer count of items in `pref`.
int32_t len = pref.size();
// 4. Let `i` be `len` - 1.
int32_t i = len - 1;
// 5. While i >= 0:
while (i >= 0) {
// 5i. Let `matches` be the list of strings at index `i` of `pref`.
U_ASSERT(pref[i] != nullptr);
const UVector& matches = *(static_cast<UVector*>(pref[i])); // `matches` is a vector of strings
// 5ii. Let `minpref` be the integer count of items in `matches`.
int32_t minpref = matches.size();
// 5iii. For each tuple `tuple` of `sortable`:
for (int32_t j = 0; j < vars.size(); j++) {
U_ASSERT(vars[j] != nullptr);
PrioritizedVariant& tuple = *(static_cast<PrioritizedVariant*>(vars[j]));
// 5iii(a). Let matchpref be an integer with the value minpref.
int32_t matchpref = minpref;
// 5iii(b). Let `key` be the tuple variant key at position `i`.
const Key* tupleVariantKeys = tuple.keys.getKeysInternal();
U_ASSERT(i < tuple.keys.len); // Given by earlier semantic checking
const Key& key = tupleVariantKeys[i];
// 5iii(c) If `key` is not the catch-all key '*':
if (!key.isWildcard()) {
// 5iii(c)(a). Assert that `key` is a literal.
// (Not needed)
// 5iii(c)(b). Let `ks` be the resolved value of `key`.
UnicodeString ks = key.asLiteral().unquoted();
// 5iii(c)(c) Let matchpref be the integer position of ks in `matches`.
matchpref = vectorFind(matches, ks);
U_ASSERT(matchpref >= 0);
}
// 5iii(d) Set the `tuple` integer value as matchpref.
tuple.priority = matchpref;
}
// 5iv. Set `sortable` to be the result of calling the method SortVariants(`sortable`)
vars.sort(comparePrioritizedVariants, status);
CHECK_ERROR(status);
// 5v. Set `i` to be `i` - 1.
i--;
}
// The caller is responsible for steps 6 and 7
// 6. Let `var` be the `variant` element of the first element of `sortable`.
// 7. Select the pattern of `var`
}
// Evaluate the operand
ResolvedSelector MessageFormatter::resolveVariables(const Environment& env, const Operand& rand, MessageContext& context, UErrorCode &status) const {
if (U_FAILURE(status)) {
return {};
}
if (rand.isNull()) {
return ResolvedSelector(FormattedPlaceholder());
}
if (rand.isLiteral()) {
return ResolvedSelector(formatLiteral(rand.asLiteral()));
}
// Must be variable
const VariableName& var = rand.asVariable();
// Resolve the variable
if (env.has(var)) {
const Closure& referent = env.lookup(var);
// Resolve the referent
return resolveVariables(referent.getEnv(), referent.getExpr(), context, status);
}
// Either this is a global var or an unbound var --
// either way, it can't be bound to a function call.
// Check globals
FormattedPlaceholder val = evalArgument(var, context, status);
if (status == U_ILLEGAL_ARGUMENT_ERROR) {
status = U_ZERO_ERROR;
// Unresolved variable -- could be a previous warning. Nothing to resolve
U_ASSERT(context.getErrors().hasUnresolvedVariableError());
return ResolvedSelector(FormattedPlaceholder(var));
}
// Pass through other errors
return ResolvedSelector(std::move(val));
}
// Evaluate the expression except for not performing the top-level function call
// (which is expected to be a selector, but may not be, in error cases)
ResolvedSelector MessageFormatter::resolveVariables(const Environment& env,
const Expression& expr,
MessageContext& context,
UErrorCode &status) const {
if (U_FAILURE(status)) {
return {};
}
// A `reserved` is an error
if (expr.isReserved()) {
context.getErrors().setReservedError(status);
return ResolvedSelector(FormattedPlaceholder(reservedFallback(expr)));
}
// Function call -- resolve the operand and options
if (expr.isFunctionCall()) {
const Operator* rator = expr.getOperator(status);
U_ASSERT(U_SUCCESS(status));
// Already checked that rator is non-reserved
const FunctionName& selectorName = rator->getFunctionName();
if (isSelector(selectorName)) {
auto selector = getSelector(context, selectorName, status);
if (U_SUCCESS(status)) {
FunctionOptions resolvedOptions = resolveOptions(env, rator->getOptionsInternal(), context, status);
// Operand may be the null argument, but resolveVariables() handles that
FormattedPlaceholder argument = formatOperand(env, expr.getOperand(), context, status);
return ResolvedSelector(selectorName, selector, std::move(resolvedOptions), std::move(argument));
}
} else if (isFormatter(selectorName)) {
context.getErrors().setSelectorError(selectorName, status);
} else {
context.getErrors().setUnknownFunction(selectorName, status);
}
// Non-selector used as selector; an error would have been recorded earlier
UnicodeString fallback(COLON);
fallback += selectorName;
if (!expr.getOperand().isNull()) {
fallback = formatOperand(env, expr.getOperand(), context, status).fallback;
}
return ResolvedSelector(FormattedPlaceholder(fallback));
} else {
// Might be a variable reference, so expand one more level of variable
return resolveVariables(env, expr.getOperand(), context, status);
}
}
ResolvedSelector MessageFormatter::formatSelectorExpression(const Environment& globalEnv, const Expression& expr, MessageContext& context, UErrorCode &status) const {
if (U_FAILURE(status)) {
return {};
}
// Resolve expression to determine if it's a function call
ResolvedSelector exprResult = resolveVariables(globalEnv, expr, context, status);
DynamicErrors& err = context.getErrors();
// If there is a selector, then `resolveVariables()` recorded it in the context
if (exprResult.hasSelector()) {
// Check if there was an error
if (exprResult.argument().isFallback()) {
// Use a null expression if it's a syntax or data model warning;
// create a valid (non-fallback) formatted placeholder from the
// fallback string otherwise
if (err.hasSyntaxError() || err.hasDataModelError()) {
return ResolvedSelector(FormattedPlaceholder()); // Null operand
} else {
return ResolvedSelector(exprResult.takeArgument());
}
}
return exprResult;
}
// No selector was found; error should already have been set
U_ASSERT(err.hasMissingSelectorAnnotationError() || err.hasUnknownFunctionError() || err.hasSelectorError());
return ResolvedSelector(FormattedPlaceholder(exprResult.argument().fallback));
}
void MessageFormatter::formatSelectors(MessageContext& context, const Environment& env, UErrorCode &status, UnicodeString& result) const {
CHECK_ERROR(status);
// See https://github.com/unicode-org/message-format-wg/blob/main/spec/formatting.md#pattern-selection
// Resolve Selectors
// res is a vector of FormattedPlaceholders
LocalPointer<UVector> res(createUVector(status));
CHECK_ERROR(status);
resolveSelectors(context, env, status, *res);
// Resolve Preferences
// pref is a vector of vectors of strings
LocalPointer<UVector> pref(createUVector(status));
CHECK_ERROR(status);
resolvePreferences(context, *res, *pref, status);
// Filter Variants
// vars is a vector of PrioritizedVariants
LocalPointer<UVector> vars(createUVector(status));
CHECK_ERROR(status);
filterVariants(*pref, *vars, status);
// Sort Variants and select the final pattern
// Note: `sortable` in the spec is just `vars` here,
// which is sorted in-place
sortVariants(*pref, *vars, status);
CHECK_ERROR(status);
// 6. Let `var` be the `variant` element of the first element of `sortable`.
U_ASSERT(vars->size() > 0); // This should have been checked earlier (having 0 variants would be a data model error)
const PrioritizedVariant& var = *(static_cast<PrioritizedVariant*>(vars->elementAt(0)));
// 7. Select the pattern of `var`
const Pattern& pat = var.pat;
// Format the pattern
formatPattern(context, env, pat, status, result);
}
// Note: this is non-const due to the function registry being non-const, which is in turn
// due to the values (`FormatterFactory` objects in the map) having mutable state.
// In other words, formatting a message can mutate the underlying `MessageFormatter` by changing
// state within the factory objects that represent custom formatters.
UnicodeString MessageFormatter::formatToString(const MessageArguments& arguments, UErrorCode &status) {
EMPTY_ON_ERROR(status);
// Create a new environment that will store closures for all local variables
Environment* env = Environment::create(status);
// Create a new context with the given arguments and the `errors` structure
MessageContext context(arguments, *errors, status);
// Check for unresolved variable errors
checkDeclarations(context, env, status);
LocalPointer<Environment> globalEnv(env);
UnicodeString result;
if (dataModel.hasPattern()) {
formatPattern(context, *globalEnv, dataModel.getPattern(), status, result);
} else {
// Check for errors/warnings -- if so, then the result of pattern selection is the fallback value
// See https://github.com/unicode-org/message-format-wg/blob/main/spec/formatting.md#pattern-selection
const DynamicErrors& err = context.getErrors();
if (err.hasSyntaxError() || err.hasDataModelError()) {
result += REPLACEMENT;
} else {
formatSelectors(context, *globalEnv, status, result);
}
}
// Update status according to all errors seen while formatting
context.checkErrors(status);
return result;
}
// ----------------------------------------
// Checking for resolution errors
void MessageFormatter::check(MessageContext& context, const Environment& localEnv, const OptionMap& options, UErrorCode& status) const {
// Check the RHS of each option
for (int32_t i = 0; i < options.size(); i++) {
const Option& opt = options.getOption(i, status);
CHECK_ERROR(status);
check(context, localEnv, opt.getValue(), status);
}
}
void MessageFormatter::check(MessageContext& context, const Environment& localEnv, const Operand& rand, UErrorCode& status) const {
// Nothing to check for literals
if (rand.isLiteral() || rand.isNull()) {
return;
}
// Check that variable is in scope
const VariableName& var = rand.asVariable();
// Check local scope
if (localEnv.has(var)) {
return;
}
// Check global scope
context.getGlobal(var, status);
if (status == U_ILLEGAL_ARGUMENT_ERROR) {
status = U_ZERO_ERROR;
context.getErrors().setUnresolvedVariable(var, status);
}
// Either `var` is a global, or some other error occurred.
// Nothing more to do either way
return;
}
void MessageFormatter::check(MessageContext& context, const Environment& localEnv, const Expression& expr, UErrorCode& status) const {
// Check for unresolved variable errors
if (expr.isFunctionCall()) {
const Operator* rator = expr.getOperator(status);
U_ASSERT(U_SUCCESS(status));
const Operand& rand = expr.getOperand();
check(context, localEnv, rand, status);
check(context, localEnv, rator->getOptionsInternal(), status);
}
}
// Check for resolution errors
void MessageFormatter::checkDeclarations(MessageContext& context, Environment*& env, UErrorCode &status) const {
CHECK_ERROR(status);
const Binding* decls = getDataModel().getLocalVariablesInternal();
U_ASSERT(env != nullptr && decls != nullptr);
for (int32_t i = 0; i < getDataModel().bindingsLen; i++) {
const Binding& decl = decls[i];
const Expression& rhs = decl.getValue();
check(context, *env, rhs, status);
// Add a closure to the global environment,
// memoizing the value of localEnv up to this point
// Add the LHS to the environment for checking the next declaration
env = Environment::create(decl.getVariable(), Closure(rhs, *env), env, status);
CHECK_ERROR(status);
}
}
} // namespace message2
U_NAMESPACE_END
#endif /* #if !UCONFIG_NO_MF2 */
#endif /* #if !UCONFIG_NO_FORMATTING */
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